Emerson Axp1406 Users Manual AXP IPMI Subsystem Reference

2015-01-05

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AXP1406/AXP1600 Subsystem IPMI
Programmer’s Reference
6806800B66C
April 2008
© Copyright 2008 Emerson
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Contact Address
Emerson Network Power - Embedded Computing
2900 South Diablo Way, Suite 190
Tempe, AZ 85282
USA
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 3
About this Manual . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
1 Supported IPMI Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
1.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
1.2 Standard IPMI Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
1.2.1 Global IPMI Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
1.2.2 BMC WatchDog Timer Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
1.2.3 BMC Device and Messaging Commands. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
1.2.4 Chassis Device Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
1.2.5 Event Commands. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
1.2.6 PEF and Alerting Commands. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
1.2.7 Sensor Device Commands. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
1.2.8 FRU Device Commands. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
1.2.9 SDR Device Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
1.2.10 SEL Device Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
1.2.11 LAN Device Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
1.2.12 Serial/Modem Device Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
1.3 PICMG 3.0 Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
1.4 Emerson and Pigeon Point OEM Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
2 FRU Information and Sensor Data Records . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
2.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
2.2 Total Power Consumption . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
2.3 SAM1000 Physical Shelf Manager . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
2.3.1 SAM Physical FRU Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
2.3.1.1 Physical Shelf Manager FRU Data, AXP1406 . . . . . . . . . . . . . . . . . . . . . . . . 26
2.3.1.2 Physical Shelf Manager FRU Data, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . 27
2.3.2 E-Keying. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
2.3.3 Power Configuration. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
2.3.4 Sensor Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
2.3.5 SAM Physical Shelf Manager Analog Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
2.3.5.1 Voltage Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
2.3.5.2 Temperature Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
2.3.6 SAM Module Discrete Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
2.3.6.1 Hot Swap Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
2.3.6.2 IPMB Link Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
2.3.6.3 PEM A Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
2.3.6.4 PEM B Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
2.3.6.5 AXP Backplane ID Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
Contents
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
Contents
4
2.3.6.6 +12 V B Valid Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
2.3.6.7 +12 V A Valid Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
2.3.6.8 Fault Event Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
2.3.6.9 POST Results Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
2.3.6.10 Shelf FRU Info Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
2.3.6.11 CPLD State Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
2.4 SAM1000 Active (Virtual) Shelf Manager . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
2.4.1 FRU Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
2.4.1.1 Active Shelf Manager FRU Data, AXP1406 . . . . . . . . . . . . . . . . . . . . . . . . . . 44
2.4.1.2 Active Shelf Manager FRU Data, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . 46
2.4.1.3 SAM1000 Shelf Manager FRU Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48
2.4.1.4 Fan Tray FRU Data, AXP1406 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49
2.4.1.5 Fan Tray FRUs 1,2, and 3 Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
2.4.1.6 Fan Tray FRUs 4, 5, and 6 Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
2.4.1.7 Fan Tray FRUs 7 and 8 Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
2.4.1.8 Fan Tray FRU Data, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
2.4.1.9 Fan Tray FRUs 1, 2, and 3 Data, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . 53
2.4.1.10 Fan Tray FRUs 4, 5, and 6 Data, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . 54
2.4.1.11 Fan Tray FRUs 7, 8 and 9 Data, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . 55
2.4.2 E-Keying. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55
2.4.3 Power Configuration. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56
2.4.4 Active SAM1000 Sensor Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56
2.4.5 Active SAM1000 Analog Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61
2.4.5.1 Fan Speed Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61
2.4.5.2 Fan Voltage Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70
2.4.6 SAM Active Shelf Manager Discrete Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 92
2.4.6.1 Hot Swap Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93
2.4.6.2 Shm Fault Event Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98
2.4.6.3 IPMB Link Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99
2.4.6.4 Telco Alarm Sensor. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 112
2.4.6.5 BMC Watchdog Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113
2.4.6.6 System Event . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113
2.4.6.7 Fan Tray Presence Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 114
2.4.6.8 Fan Tray -48 V Fuse Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119
2.5 Power Entry Module Sensor Data Records . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 124
2.5.1 PEM FRU Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 124
2.5.2 E-Keying. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125
2.5.3 Power Configuration. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125
2.5.4 Power Entry Module Sensor Overview. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126
2.5.5 Power Entry Module Analog Sensors. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126
2.5.5.1 Voltage Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 127
2.5.5.2 Current Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 131
2.5.5.3 Temperature Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 132
2.5.6 Power Entry Module Discrete Sensors. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 132
2.5.6.1 Hot Swap Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 132
2.5.6.2 IPMB Link Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 133
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Contents
2.5.7 Circuit Breaker State Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 134
3 OEM Sensors. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 137
3.1 OEM Sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 137
3.1.1 Telco Alarms (Pigeon Point OEM) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 137
3.1.2 AXP Backplane ID (Emerson OEM) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 138
3.1.3 POST Results (Emerson OEM) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 138
3.1.4 Shelf FRU Info (Emerson OEM). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 139
3.1.5 FT -48 V Fuse (Emerson OEM) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 139
3.1.6 Shm Fault Event (Emerson OEM) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 140
A System Behavior in Response to Sensor Events . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 141
A.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 141
A.2 Cooling Management in Normal Operation Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 141
A.3 Cooling Management in Abnormal Operation Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 141
A.4 Adaptive Adjustment of the Minimum Fan Level . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 142
A.5 FRU State Management . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 144
B Related Documentation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 147
B.1 Emerson Network Power - Embedded Computing Documents . . . . . . . . . . . . . . . . . . . . . . . 147
B.2 Manufacturers’ Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 148
B.3 Related Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 148
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 7
Table 1-1 Supported Global IPMI Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
Table 1-2 Supported BMC WatchDog Timer Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
Table 1-3 Supported BMC Device and Messaging Commands . . . . . . . . . . . . . . . . . . . . . . . . . . 16
Table 1-4 Supported Chassis Device Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
Table 1-5 Supported Event Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
Table 1-6 Supported PEF and Alerting Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
Table 1-7 Supported Sensor Device Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
Table 1-8 Supported FRU Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
Table 1-9 Supported SDR Device Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
Table 1-10 Supported SEL Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
Table 1-11 Supported LAN Device Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
Table 1-12 Supported Serial/Modem Device Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
Table 1-13 Supported PICMG 3.0 Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
Table 1-14 OEM Command Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Table 1-15 Get Shelf Configuration Record (Cmd = 0x01) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Table 1-16 Shelf Manager Switchover (Cmd = 0x02) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
Table 1-17 Set FRU Extracted (Cmd = 0x03) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
Table 2-1 Total Power Consumption for AXP 1406 and AXP1600 Shelves . . . . . . . . . . . . . . . . . 25
Table 2-2 SAM Physical Power Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
Table 2-3 Sensor Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
Table 2-4 Sensor No. 2 Vbat . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
Table 2-5 Sensor No. 3 3.3 V Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
Table 2-6 Sensor No. 4 +12 V Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
Table 2-7 Sensor No. 5 +1.8 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
Table 2-8 Sensor No. 6 MAX6656 INT@1A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
Table 2-9 Sensor No. 7 MAX6656 EXT1@1A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
Table 2-10 Sensor No. 8 MAX6656 EXT2@1A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
Table 2-11 Sensor No. 0 FRU 0 HOT_SWAP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
Table 2-12 Sensor No. 1 IPMB Link . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
Table 2-13 Sensor No. 9 PEM A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
Table 2-14 Sensor No. 10 PEM B . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
Table 2-15 Sensor No. 11 NSC A (AXP1600 Only) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
Table 2-16 Sensor No. 12 NSC B (AXP1600 Only) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
Table 2-17 Sensor No. 13 AXP Backplane ID . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
Table 2-18 Sensor No. 14 12 V B Valid . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
Table 2-19 Sensor No. 15 12 V A Valid . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
Table 2-20 Sensor No. 16 Fault Event . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
Table 2-21 Sensor No. 17 POST Results . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
Table 2-22 Sensor No. 18 Shelf FRU Info . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
Table 2-23 Sensor No. 128 CPLD State . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
List of Tables
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
List of Tables
8
Table 2-24 SAM1000 Active Power Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56
Table 2-25 Active SAM1000 Sensor Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56
Table 2-26 Sensor No. 141 (0x8D) FT 1 Fan 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61
Table 2-27 Sensor No. 142 (0x8E) FT 1 Fan 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61
Table 2-28 Sensor No. 143 (0x8F) FT 2 Fan 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62
Table 2-29 Sensor No. 144 (0x90) FT2 Fan 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62
Table 2-30 Sensor No. 145 (0x91) FT 3 Fan 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63
Table 2-31 Sensor No. 146 (0x92) FT 3 Fan 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63
Table 2-32 Sensor No. 147 (0x93) FT 4 Fan 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64
Table 2-33 Sensor No. 148 (0x94) FT 4 Fan 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64
Table 2-34 Sensor No. 149 (0x95) FT 5 Fan 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65
Table 2-35 Sensor No. 150 (0x96) FT 5 Fan 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65
Table 2-36 Sensor No. 151 (0x97) FT 6 Fan 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 66
Table 2-37 Sensor No. 152 (0x98) FT 6 Fan 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 66
Table 2-38 Sensor No. 153 (0x99) FT 7 Fan 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67
Table 2-39 Sensor No. 154 (0x9A) FT 7 Fan 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67
Table 2-40 Sensor No. 155 (0x9B) FT 8 Fan 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
Table 2-41 Sensor No. 156 (0x9C) FT 8 Fan 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
Table 2-42 Sensor No. 157 (0x9D) FT 9 Fan 1, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69
Table 2-43 Sensor No. 158 (0x9E) FT 9 Fan 2, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70
Table 2-44 Sensor No. 171 (0xAB) FT 1 Fan 1 12 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70
Table 2-45 Sensor No. 172 (0xAC) FT 1 Fan 1 VBias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71
Table 2-46 Sensor No. 173 (0xAD) FT 1 Fan 2 12 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71
Table 2-47 Sensor No. 174 (0xAE) FT 1 Fan 2 VBias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72
Table 2-48 Sensor No. 175 (0xAF) FT 2 Fan 1 12 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73
Table 2-49 Sensor No. 176 (0xB0) FT 2 Fan 1 VBias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73
Table 2-50 Sensor No. 177 (0xB1) FT 2 Fan 2 12 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74
Table 2-51 Sensor No. 178 (0xB2) FT 2 Fan 2 VBias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74
Table 2-52 Sensor No. 179 (0xB3) FT 3 Fan 1 12 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75
Table 2-53 Sensor No. 180 (0xB4) FT 3 Fan 1 VBias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76
Table 2-54 Sensor No. 181 (0xB5) FT 3 Fan 2 12 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76
Table 2-55 Sensor No. 182 (0xB6) FT 3 Fan 2 VBias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 77
Table 2-56 Sensor No. 183 (0xB7) FT 4 Fan 1 12 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 77
Table 2-57 Sensor No. 184 (0xB8) FT 4 Fan 1 VBias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78
Table 2-58 Sensor No. 185 (0xB9) FT 4 Fan 2 12 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79
Table 2-59 Sensor No. 186 (0xBA) FT 4 Fan 2 VBias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79
Table 2-60 Sensor No. 187 (0xBB) FT 5 Fan 1 12 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80
Table 2-61 Sensor No. 188 (0xBC) FT 5 Fan 1 VBias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80
Table 2-62 Sensor No. 189 (0xBD) FT 5 Fan 2 12 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81
Table 2-63 Sensor No. 190 (0xBE) FT 5 Fan 2 VBias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 82
Table 2-64 Sensor No. 191 (0xBF) FT 6 Fan 1 12 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 82
Table 2-65 Sensor No. 192 (0xC0) FT 6 Fan 1 VBias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83
Table 2-66 Sensor No. 193 (0xC1) FT 6 Fan 2 12 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83
Table 2-67 Sensor No. 194 (0xC2) FT 6 Fan 2 VBias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84
Table 2-68 Sensor No. 195 (0xC3) FT 7 Fan 1 +12V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85
Table 2-69 Sensor No. 196 (0xC4) FT 7 Fan 1 VBias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 9
List of Tables
Table 2-70 Sensor No. 197 (0xC5) FT 7 Fan 2 12 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86
Table 2-71 Sensor No. 198 (0xC6) FT 7 Fan 2 VBias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86
Table 2-72 Sensor No. 199 (0xC7) FT 8 Fan 1 12 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87
Table 2-73 Sensor No. 200 (0xC8) FT 8 Fan 1 VBias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88
Table 2-74 Sensor No. 201 (0xC9) FT 8 Fan 2 12 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88
Table 2-75 Sensor No. 202 (0xCA) FT 8 Fan 2 VBias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89
Table 2-76 Sensor No. 203 (0xCB) FT 9 Fan 1 12 V, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . . 90
Table 2-77 Sensor No. 204 (0xCC) FT 9 Fan 1 VBias, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . 90
Table 2-78 Sensor No. 205 (0xCD) FT 9 Fan 2 12 V, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . 91
Table 2-79 Sensor No. 206 (0xCE) FT 9 Fan 2 VBias, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . 91
Table 2-80 Sensor No. 0 (0x00) FRU 0 HOT_SWAP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93
Table 2-81 Sensor No. 2 (0x02) FRU 1 HOT_SWAP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93
Table 2-82 Sensor No. 3 (0x03) FRU 2 HOT_SWAP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94
Table 2-83 Sensor No. 4 (0x04) FRU 3 HOT_SWAP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94
Table 2-84 Sensor No. 5 (0x05) FRU 4 HOT_SWAP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95
Table 2-85 Sensor No. 6 (0x06) FRU 5 HOT_SWAP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95
Table 2-86 Sensor No. 7 (0x07) FRU 6 HOT_SWAP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96
Table 2-87 Sensor No. 8 (0x08) FRU 7 HOT_SWAP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97
Table 2-88 Sensor No. 9 (0x09) FRU 8 HOT_SWAP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97
Table 2-89 Sensor No. 10 (0x0A) FRU 9 HOT_SWAP, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . 98
Table 2-90 Sensor No. 11 (0x20) Fault Event Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98
Table 2-91 Sensor No. 12 (0x0B) IPMB LINK 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99
Table 2-92 Sensor No. 13 (0x0C) IPMB LINK 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100
Table 2-93 Sensor No. 14 (0x0D) IPMB LINK 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100
Table 2-94 Sensor No. 15 (0x0E) IPMB LINK 4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101
Table 2-95 Sensor No. 16 (0x0F) IPMB LINK 5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101
Table 2-96 Sensor No. 17 (0x10) IPMB LINK 6 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102
Table 2-97 Sensor No. 18 (0x11) IPMB LINK 7 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103
Table 2-98 Sensor No. 19 (0x12) IPMB LINK 8 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103
Table 2-99 Sensor No. 20 (0x14) IPMB LINK 9 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104
Table 2-100 Sensor No. 21 (0x14) IPMB LINK 10 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104
Table 2-101 Sensor No. 22 (0x15) IPMB LINK 11 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105
Table 2-102 Sensor No. 23 (0x16) IPMB LINK 12 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106
Table 2-103 Sensor No. 24 (0x17) IPMB LINK 13 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106
Table 2-104 Sensor No. 25 (0x18) IPMB LINK 14 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107
Table 2-105 Sensor No. 26 (0x19) IPMB LINK 15, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 108
Table 2-106 Sensor No. 27 (0x1A) IPMB LINK 16, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 108
Table 2-107 Sensor No. 28 (0x1B) IPMB LINK 17 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109
Table 2-108 Sensor No. 29 (0x1C) IPMB LINK 18, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109
Table 2-109 Sensor No. 30 (0x1D) IPMB LINK 19, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110
Table 2-110 Sensor No. 31 (0x1E) IPMB LINK 20, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 111
Table 2-111 Sensor No. 32 (0x1F) IPMB LINK 21, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 111
Table 2-112 Sensor No. 131 (0x83) TELCO Alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 112
Table 2-113 Sensor No. 132 (0x84) BMC Watchdog . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113
Table 2-114 Sensor No. 133 (0x85) SYSTEM EVENT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113
Table 2-115 Sensor No. 220 (0xDC) Fan Tray 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 114
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
List of Tables
10
Table 2-116 Sensor No. 221 (0xDD) Fan Tray 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115
Table 2-117 Sensor No. 222 (0xDE) Fan Tray 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115
Table 2-118 Sensor No. 223 (0xDF) Fan Tray 4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116
Table 2-119 Sensor No. 224 (0xE0) Fan Tray 5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116
Table 2-120 Sensor No. 225 (0xE1) Fan Tray 6 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117
Table 2-121 Sensor No. 226 (0xE2) Fan Tray 7 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117
Table 2-122 Sensor No. 227 (0xE3) Fan Tray 8 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 118
Table 2-123 Sensor No. 228 (0xE4) Fan Tray 9, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 118
Table 2-124 Sensor No. 230 (0xE6) FT 1 -48 V Fuse . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119
Table 2-125 Sensor No. 231 (0xE7) FT 2 -48 V Fuse . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120
Table 2-126 Sensor No. 233 (0xE9) FT 4 -48 V Fuse . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120
Table 2-127 Sensor No. 232 (0xE8) FT 3 -48 V Fuse . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 121
Table 2-128 Sensor No. 234 (0xEA) FT 5 -48 V Fuse . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 121
Table 2-129 Sensor No. 235 (0xEB) FT 6 -48 V Fuse . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 122
Table 2-130 Sensor No. 236 (0xEC) FT 7 -48 V Fuse . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 122
Table 2-131 Sensor No. 237 (0xED) FT 8 -48 V Fuse . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123
Table 2-132 Sensor No. 238 (0xEE) FT9 -48 V Fuse, AXP1600 . . . . . . . . . . . . . . . . . . . . . . . . . . 123
Table 2-133 Power Configuration for PEMs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125
Table 2-134 IPMI Sensors on the PEM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126
Table 2-135 Sensor No. 2 +3.3 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 127
Table 2-136 Sensor No. 3 +8 V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 127
Table 2-137 Sensor No. 4 +12 V Backplane . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 128
Table 2-138 Sensor No. 11 +48.0 V Feed . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 128
Table 2-139 Sensor No. 12 +7.5 V PEM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 129
Table 2-140 Sensor No. 13 +8 V PEM Feed 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 130
Table 2-141 Sensor No. 15 +8 V PEM Feed 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 130
Table 2-142 Sensor No. 14 +12 V Current . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 131
Table 2-143 Sensor No. 10 DS75 Temp . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 132
Table 2-144 Sensor #0, Hot Swap . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 132
Table 2-145 Sensor #1, IPMB Physical . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 133
Table 2-146 Sensor #5, CB 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 134
Table 2-147 Sensor #6 CB 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 134
Table 2-148 Sensor No. 7 CB 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 135
Table 2-149 Sensor No. 8 CB 4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 135
Table 2-150 Sensor No. 9 CB 5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 136
Table 3-1 Shm Fault Classes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 140
Table A-1 FRU State Table for Nonrecoverable Threshold Events from Temperature Sensors . 144
Table B-1 Emerson Newtork Power - Embedded Computing Documents . . . . . . . . . . . . . . . . . 147
Table B-2 Manufacturers Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 148
Table B-3 Related Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 148
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 11
About this Manual
Overview of Contents
The information in this reference guide support both Centellis 3406 and Centellis 3600
platforms. The differences between the two platforms are:
zThe AXP1406 is a 14-slot shelf with 2 PEMs, 2 SAMs, and 8 FTMs.
zThe AXP1600 is a 16-slot shelf with 2 PEMs, 2 SAMs, and 9 FTMs.
This guide provides FRU data and SDR for each AXP shelf. On the AXP1600 platform,
additional sensors are described for FTM FRU 9. All AXP1600 FRU data and sensor
information is clearly identified throughout this guide.
The AXP1406 and AXP1600 both have an Intelligent Peripheral Management Controller
(IPMC) which is fully compliant to the IPMI V1.5 specification. The IPMC provides access to on-
board Sensor Data Records (SDRs), Field Replaceable Unit (FRU) data, and furthermore
contains an event generator. Within this document you find a description of:
zSupported IPMI commands
zFRU States
zSDRs
zFRU data
For the last two items in the list, the default values are given for reference purposes if you want
to restore the factory values.
This manual is divided into the following chapters and appendices.
Chapter 1, Supported IPMI Commands, lists IPMI commands supported by the IPMC.
Chapter 2, FRU Information and Sensor Data Records, lists the PEM, FTM, and SAM1000
Shelf Manager FRU information, as well as sensors that are accessible via IPMI for both the
AXP1406 and AXP1600 shelves.
Chapter 3, OEM Sensors, lists the additional OEM sensors that are accessible via IPMI for both
the AXP1406 and AXP1600 shelves.
Appendix A, System Behavior in Response to Sensor Events, describes the shelf manager’s
cooling management and FRU state management for nonrecoverable threshold events.
Appendix B, Related Documentation, lists publications for blade and software products used
with the Centellis 3406 and 3600 platforms.
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
About this Manual
12
Abbreviations
This document uses the following terms and abbreviations:
Conventions
The following table describes the conventions used throughout this manual.
Term Definition
FRU Field Replaceable Unit. A module or component which will typically be replaced in its
entirety as part of a field service repair operation.
FTM Fan Tray Module. An FRU that provides cooling to the shelf.
IPMB Intelligent Platform Management Bus. Name for the architecture, protocol, and
implementation of a special bus that interconnects the baseboard and chassis
electronics and provides a communications media for system platform management
information. The bus is built on I2C and provides a communications path between
“management controllers” such as the BMC, FPC, and HSC.
LPMI Local Peripheral Manager Interface.
LUN Logical Unit Number. In the context of the Intelligent Platform Management Bus
protocol, this is a subaddress that allows messages to be routed to different ‘logical
units’ that reside behind the same I2C slave address.
PEM Power Entry Module. An FRU that introduces power to the shelf.
SAM Shelf Manager. An FRU that provides system management functions for shelf
components.
SDR Sensor Data Record. A data record that provides platform management sensor type,
locations, event generation, and access information.
SEL System Event Log. A non-volatile storage area and associated interfaces for storing
system platform event information for later retrieval.
Notation Description
0x00000000 Typical notation for hexadecimal numbers (digits
are 0 through F), for example used for addresses
and offsets
0b0000 Same for binary numbers (digits are 0 and 1)
bold Used to emphasize a word
Screen Used for on-screen output and code related
elements or commands in body text
Courier + Bold Used to characterize user input and to separate it
from system output
Reference Used for references and for table and figure
descriptions
File > Exit Notation for selecting a submenu
<text> Notation for variables and keys
[text] Notation for software buttons to click on the screen
and parameter description
About this Manual
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 13
Summary of Changes
The next table provides information on the changes since the first release of this manual. This
edition supersedes all other releases.
... Repeated item for example node 1, node 2, ...,
node 12
.
.
.
Omission of information from example/command
that is not necessary at the time being
.. Ranges, for example: 0..4 means one of the
integers 0,1,2,3, and 4 (used in registers)
| Logical OR
Indicates a hazardous situation which, if not
avoided, could result in death or serious injury
Indicates a hazardous situation which, if not
avoided, may result in minor or moderate injury
Indicates a property damage message
No danger encountered. Pay attention to important
information
Notation Description
Date Description of Change Replaces
April 2008 Updated to Emerson style. 6806800B66B
April 2007 Shm Fault Event OEM Sensor added. 6806800B66A
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
About this Manual
14
Comments and Suggestions
We welcome and appreciate your comments on our documentation. We want to know what you
think about our manuals and how we can make them better.
Mail comments to us by filling out the following online form:
http://www.emersonnetworkpowerembeddedcomputing.com/ > Contact Us > Online Form
In “Area of Interest” select “Technical Documentation”. Be sure to include the title, part number,
and revision of the manual and tell us how you used it.
1
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 15
Supported IPMI Commands
1.1 Introduction
This chapter describes the different commands supported by the Centellis 3000 series
platforms. Command categories are as follows:
zStandard IPMI Commands
zPICMG 3.0 Commands
zEmerson and Pigeon Point OEM Commands
1.2 Standard IPMI Commands
The IPMC is fully compliant to the Intelligent Platform Management Interface v.1.5. This section
provides information on which IPMI commands are supported. Table entries marked with an “x”
indicate which FRU or ATCA blade supports a listed command.
1.2.1 Global IPMI Commands
The IPMC supports the following global IPMI commands.
Table 1-1 Supported Global IPMI Commands
NetFn Rq/Rs Command CMD
Active
ShelfMgr
Physical
ShelfMgr PEMs FTMs
ATCA
Blades
Get Device ID 0x06/0x07 0x01 X X X X X
Cold Reset 0x06/0x07 0x02 X X X X
Warm Reset 0x06/0x07 0x03 X X X
Get Self Test Result 0x06/0x07 0x04 X X X X X
Set ACPI Power State 0x06/0x07 0x06 X X *
Get ACPI Power State 0x06/0x07 0x07 X X *
Get Device GUID 0x06/0x07 0x08 X X X X X
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
Supported IPMI Commands BMC WatchDog Timer Commands
16
1.2.2 BMC WatchDog Timer Commands
The IPMC supports the following BMC WatchDog Timer commands.
1.2.3 BMC Device and Messaging Commands
The IPMC supports the following BMC device and messaging commands.
Table 1-2 Supported BMC WatchDog Timer Commands
Command
NetFn
R1/Rs CMD
Active
ShelfMgr
Physical
ShelfMgr PEMs FTMs
ATCA
Blades
Reset Watchdog Timer 0x06/0x07 0x22 X X X
Set Watchdog Timer 0x06/0x07 0x24 X X X
Get Watchdog Timer 0x06/0x07 0x25 X X X
Table 1-3 Supported BMC Device and Messaging Commands
Command
NetFn
Rq/Rs CMD
Active
ShelfMgr
Physical
ShelfMgr PEMs FTMs
ATCA
Blades
Set BMC Global Enables 0x06/0x07 0x2E X X X X X
Get BMC Global Enables 0x06/0x07 0x2F X X X X X
Clear Message Flags 0x06/0x07 0x30 X X X X X
Get Message Flags 0x06/0x07 0x31 X X X X X
Send Message 0x06/0x07 0x34 X X X X X
Get System GUID 0x06/0x07 0x37 X X X X X
Get Channel Authentication
Capabilities
0x06/0x07 0x38 X X X X X
Get Session Challenge 0x06/0x07 0x39 X X X X X
Activate Session 0x06/0x07 0x3A X X X X X
Set Session Privilege Level 0x06/0x07 0x3B X X X X X
Close Session 0x06/0x07 0x3C X X X X X
Get Session Info 0x06/0x07 0x3D X X X X X
Get AuthCode 0x06/0x07 0x3F X X X X X
Set Channel Access 0x06/0x07 0x40 X X X X X
Get Channel Access 0x06/0x07 0x41 X X X X X
Get Channel Info Command 0x06/0x07 0x42 X X X X X
Set User Access Command 0x06/0x07 0x43 X X X X X
Get User Access Command 0x06/0x07 0x44 X X X X X
Set User Name 0x06/0x07 0x45 X X X X X
Get User Name Command 0x06/0x07 0x46 X X X X X
Set User Password Command 0x06/0x07 0x47 X X X X X
Chassis Device Commands Supported IPMI Commands
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 17
1.2.4 Chassis Device Commands
The IPMC supports the following chassis device commands.
1.2.5 Event Commands
The IPMC supports the following event commands.
1.2.6 PEF and Alerting Commands
The IPMC supports the following PEF and alerting commands.
Table 1-4 Supported Chassis Device Commands
Command
NetFn
Rq/Rs CMD
Active
ShelfMgr
Physical
ShelfMgr PEMs FTMs
ATCA
Blades
Get Chassis Capabilities 0x00/0x01 0x00 X X
Get Chassis Status 0x00/0x01 0x01 X X
Chassis Control 0x00/0x01 0x02 X X
Set Chassis Capabilities 0x00/0x01 0x05 X X
Set System Boot Options* 0x00/0x01 0x08 X
Get System Boot Options* 0x00/0x01 0x09 X
*The data portion of these commands are blade-specific. Refer to the respective blade specification.
Table 1-5 Supported Event Commands
Command NetFn Rq/Rs CMD
Active
ShelfMgr
Physical
ShelfMgr PEMs FTMs
ATCA
Blades
Set Event Receiver 0x04/0x05 0x00 X X X X X
Get Event Receiver 0x04/0x05 0x01 X X X X X
Platform Event (a.k.a. “Event
Message”)
0x04/0x05 0x02 X X *
*ATCA-F101 supports this command.
Table 1-6 Supported PEF and Alerting Commands
Command
NetFn
Rq/Rs CMD
Active
ShelfMgr
Physical
ShelfMgr PEMs FTMs
ATCA
Blades
Get PEF Capabilities 0x04/0x05 0x10 X X
Arm PEF Postpone Timer 0x04/0x05 0x11 X X
Set PEF Configuration Parameters 0x04/0x05 0x12 X X
Get PEF Configuration Parameters 0x04/0x05 0x13 X X
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
Supported IPMI Commands Sensor Device Commands
18
1.2.7 Sensor Device Commands
The IPMC supports the following sensor device commands.
Set Last Processed Event ID 0x04/0x05 0x14 X X
Get Last Processed Event ID 0x04/0x05 0x15 X X
Alert Immediate 0x04/0x05 0x16 X X
PET Acknowledge 0x04/0x05 0x17 X X
Table 1-6 Supported PEF and Alerting Commands (continued)
Command
NetFn
Rq/Rs CMD
Active
ShelfMgr
Physical
ShelfMgr PEMs FTMs
ATCA
Blades
Table 1-7 Supported Sensor Device Commands
Command
NetFn
Rq/Rs CMD
Active
ShelfMgr
Physical
ShelfMgr PEMs FTMs
ATCA
Blades
Get Device SDR Info 0x04/0x05 0x20 X X X X X
Get Device SDR 0x04/0x05 0x21 X X X X X
Reserve Device SDR Repository 0x04/0x05 0x22 X X X X X
Get Sensor Reading Factors 0x04/0x05 0x23 X X X X X
Set Sensor Hysteresis 0x04/0x05 0x24 X X X X X
Get Sensor Hysteresis 0x04/0x05 0x25 X X X X X
Set Sensor Threshold 0x04/0x05 0x26 X X X X X
Get Sensor Threshold 0x04/0x05 0x27 X X X X X
Set Sensor Event Enable 0x04/0x05 0x28 X X X X X
Get Sensor Event Enable 0x04/0x05 0x29 X X X X X
Re-arm Sensor Events 0x04/0x05 0x2a X X *
Get Sensor Event Status 0x04/0x05 0x2b X X X X X
Get Sensor Reading 0x04/0x05 0x2d X X X X X
Set Sensor Type 0x04/0x05 0x2e X X *
Get Sensor Type 0x04/0x05 0x2f X X X X X
*ATCA-F101 Supports this command.
FRU Device Commands Supported IPMI Commands
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 19
1.2.8 FRU Device Commands
The IPMC supports the following FRU device commands.
1.2.9 SDR Device Commands
The IPMC supports the following SDR device commands.
1.2.10 SEL Device Commands
The IPMC supports the following SEL device commands.
Table 1-8 Supported FRU Commands
Command NetFn Rq/Rs CMD
Active
ShelfMgr
Physical
ShelfMgr PEMs FTMs
ATCA
Blades
Get FRU Inventory Area Info 0x0A/0x0B 0x10 X X X X X
Read FRU Data 0x0A/0x0B 0x11 X X X X X
Write FRU Data 0x0A/0x0B 0x12 X X X X X
Table 1-9 Supported SDR Device Commands
Command
NetFn
Rq/Rs CMD
Active
ShelfMgr
Physical
ShelfMgr PEMs FTMs
ATCA
Blades
Get SDR Repository Info 0x0A/0x0B 0x20 X
Get SDR Repository
Allocation Info
0x0A/0x0B 0x21
Reserve SDR Repository 0x0A/0x0B 0x22 X
Get SDR 0x0A/0x0B 0x23 X
Add SDR 0x0A/0x0B 0x24 X
Partial Add SDR 0x0A/0x0B 0x25 X
Delete SDR 0x0A/0x0B 0x26 X
Clear SDR Repository 0x0A/0x0B 0x27 X
Get SDR Repository Time 0x0A/0x0B 0x28 X
Set SDR Repository Time 0x0A/0x0B 0x29 X
Table 1-10 Supported SEL Commands
Command
NetFn
Rq/Rs CMD
Active
ShelfMgr
Physical
ShelfMgr PEMs FTMs
ATCA
Blades
Get SEL Info 0x0A/0x0B 0x40 X
Get SEL Allocation Info 0x0A/0x0B 0x41 X
Reserve SEL 0x0A/0x0B 0x42 X
Get SEL Entry 0x0A/0x0B 0x43 X X
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
Supported IPMI Commands LAN Device Commands
20
1.2.11 LAN Device Commands
The IPMC supports the following LAN device commands.
1.2.12 Serial/Modem Device Commands
The IPMC supports the following serial/modem device commands.
Add SEL Entry 0x0A/0x0B 0x44 X X
Partial Add SEL Entry 0x0A/0x0B 0x45 X X
Delete SEL Entry 0x0A/0x0B 0x46 X X
Clear SEL 0x0A/0x0B 0x47 X X
Get SEL Time 0x0A/0x0B 0x48 X
Set SEL Time 0x0A/0x0B 0x49 X X
Table 1-10 Supported SEL Commands (continued)
Command
NetFn
Rq/Rs CMD
Active
ShelfMgr
Physical
ShelfMgr PEMs FTMs
ATCA
Blades
Table 1-11 Supported LAN Device Commands
Command
NetFn
Rq/Rs CMD
Active
ShelfMgr
Physical
ShelfMgr PEMs FTMs
ATCA
Blades
Set LAN Configuration Parameters 0x0C/0x0D 0x01 X
Get LAN Configuration Parameters 0x0C/0x0D 0x02 X
Suspend BMC ARPs 0x0C/0x0D 0x03 X
Table 1-12 Supported Serial/Modem Device Commands
Command NetFn Rq/Rs CMD
Active
ShelfMgr
Physical
ShelfMgr PEMs FTMs
ATCA
Blades
Set User Callback Options 0x0C/0x0D 0x1A X
Get User Callback Options 0x0C/0x0D 0x1B X
PICMG 3.0 Commands Supported IPMI Commands
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 21
1.3 PICMG 3.0 Commands
The Emerson IPMC is a fully compliant AdvancedTCA Intelligent Platform Management
Controller. For example, it supports all required and mandatory AdvancedTCA commands as
defined in the PICMG 3.0 specification.
Table 1-13 Supported PICMG 3.0 Commands
Command NetFn Rq/Rs CMD
Active
ShelfMgr
Physical
ShelfMgr PEMs FTMs
ATCA
Blades
Get PICMG Properties 0x2C/0x2D 0x00 X X X X X
Get Address Info 0x2C/0x2D 0x01 X X X X X
Get Shelf Address Info 0x2C/0x2D 0x02 X X
Set Shelf Address Info 0x2C/0x2D 0x03 X X
FRU Control 0x2C/0x2D 0x04 X X X X X
Get FRU LED Properties 0x2C/0x2D 0x05 X X X
Get LED Color Capabilities 0x2C/0x2D 0x06 X X X
Set FRU LED State 0x2C/0x2D 0x07 X X X
Get FRU LED State 0x2C/0x2D 0x08 X X X
Set IPMB State 0x2C/0x2D 0x09 X X X X X
Set FRU Activation Policy 0x2C/0x2D 0x0A X X X X X
Get FRU Activation Policy 0x2C/0x2D 0x0B X X X X X
Set FRU Activation 0x2C/0x2D 0x0C X X X X X
Get Device Locator Record
ID
0x2C/0x2D 0x0D X X X X X
Set Port State 0x2C/0x2D 0x0E X X X
Get Port State 0x2C/0x2D 0x0F X X X
Compute Power Properties 0x2C/0x2D 0x10 X X X X X
Set Power Level 0x2C/0x2D 0x11 X X X X X
Get Power Level 0x2C/0x2D 0x12 X X X X X
Renegotiate Power 0x2C/0x2D 0x13 X
Get Fan Speed Properties 0x2C/0x2D 0x14 X
Set Fan Level 0x2C/0x2D 0x15 X
Get Fan Level 0x2C/0x2D 0x16 X
Bused Resource 0x2C/0x2D 0x17 X X
Get IPMB Link Info 0x2C/0x2D 0x18 X X
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
Supported IPMI Commands Emerson and Pigeon Point OEM Commands
22
1.4 Emerson and Pigeon Point OEM Commands
These commands can only be sent to the Emerson AXP1406 and AXP1600 Shelf Managers,
sending these commands to other shelf managers or IPMCs will result in error responses or
undefined behavior.
The SAM supports these OEM IPMI commands that are not defined in the IPMI 1.5 or PICMG
3.0 specifications.
This command gets the shelf configuration for the AXP1600.
Table 1-14 OEM Command Summary
IPMI NetFn (Request/Response) Emerson OEM Command IPMI Cmd
Get Shelf Configuration Record 0x2E / 0x2F 0x01
Shelf Manager Switchover 0x2E / 0x2F 0x02
Set FRU Extracted 0x2E / 0x2F 0x03
Table 1-15 Get Shelf Configuration Record (Cmd = 0x01)
Byte Data field
Request data 1 Pigeon Point Systems IANA Enterprise number, LSB first
2 0x0A
3 0x40
0x00
4 IANA enterprise number for the desired record, LSB first
5
6
7 Record Type
8 Record Number
9 Offset within record
10 Count of bytes to retrieve
Response
data
1 Completion Code
2 Pigeon Point Systems IANA Enterprise number, LSB first
0x0A
0x40
3
4
5 Requested bytes from the specified Shelf FRU record
n
Emerson and Pigeon Point OEM Commands Supported IPMI Commands
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 23
This command requests a SAM switchover.
This command instructs the SAM to transition a FRU to the M0 (not installed) state.
Table 1-16 Shelf Manager Switchover (Cmd = 0x02)
Byte Data field
Request data 1 Pigeon Point Systems IANA Enterprise number, LSB first
2 0x0A
3 0x40
0x00
4 Flags
0x00 Switchover, but do not reboot the active Shelf Manager
0x01 Switchover, and reboot the active Shelf Manager
Response data 1 Completion Code
2 0x0A
3 0x40
4 0x00
Table 1-17 Set FRU Extracted (Cmd = 0x03)
Byte Data field
Request data 1 Pigeon Point Systems IANA Enterprise number, LSB first
2 0x0A
3 0x40
0x00
4 IPMB address
5FRU Id
6 Force option
0x00 Only extract specified FRU if it is in M7 state
0x01 Extract the specified FRU regardless of its current state
Response data 1 Completion Code
2 Pigeon Point Systems IANA Enterprise number, LSB first
3 0x0A
4 0x40
0x00
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
Supported IPMI Commands Emerson and Pigeon Point OEM Commands
24
2
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 25
FRU Information and Sensor Data
Records
2.1 Introduction
This chapter introduces FRU information, e-keying, sensor overviews, and power configuration
data for each subcomponent of the AXP1406 and AXP1600 shelf. Information in this chapter
also includes:
zTotal Power Consumption
zSAM1000 Physical Shelf Manager
zSAM1000 Active (Virtual) Shelf Manager
zPower Entry Module Sensor Data Records
Subcomponents include the Power Entry Modules (PEMs), upper and lower Fan Tray Modules
(FTMs), and the SAM1000 Shelf Management Alarm Module (SAMs), both physical and active.
2.2 Total Power Consumption
The following table shows the total power requirements for the shelf. Power consumption
breakdown is shown in the next table.
All fan tray sensors are exposed by the Active SAM.
Table 2-1 Total Power Consumption for AXP 1406 and AXP1600 Shelves
Amps per Fan Maximum Total Watts
AXP1406 Shelf
8 FTMs without AdvancedTCA Blades
400 Watts
AXP1600 Shelf
9 FTMs without AdvancedTCA Blades
400 Watts
Assumes the shelf is configured with 2 SAMs, 2 PEMs, and all FTMs running at full
speed.
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records SAM1000 Physical Shelf Manager
26
2.3 SAM1000 Physical Shelf Manager
This section describes in detail the physical SAM Shelf Manager, FRU data, power
configuration and sensors at IPMB addresses 0xFC and 0xFE. The information in this section
supports the SAM on both the AXP1406 and AXP1600 shelves. The AXP1600 FRU and sensor
data is highlighted and marked for ease of use.
2.3.1 SAM Physical FRU Information
The following tables provides the FRU information for the physical SAM on the AXP1406 and
AXP1600 shelves.
2.3.1.1 Physical Shelf Manager FRU Data, AXP1406
Common Header: Format Version = 1
Internal Use Area:
Version = 1
Board Info Area:
Version = 1
Language Code = 25
Mfg Date/Time = Mar 30 23:00:00 2005 (4862820 minutes since 1996)
Board Manufacturer = Pigeon Point Systems
Board Product Name = IPM Sentry ShMM-500
Board Serial Number = PPS0000000
Board Part Number = A
FRU Programmer File ID =
Product Info Area:
Version = 1
Language Code = 25
Manufacturer Name = Pigeon Point Systems
Product Name = IPM Sentry Shelf Manager
Product Part / Model# = 000000
Product Version = Rev 1.00
Product Serial Number = PPS0000000
Asset Tag =
SAM Physical FRU Information FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 27
FRU Programmer File ID =
Multi Record Area:
PICMG Board Point-to-Point Connectivity Record (ID=0x14)
Version = 0
2.3.1.2 Physical Shelf Manager FRU Data, AXP1600
Common Header: Version = 1
Language Code = 25
Mfg Date/Time = Jan 1 00:00:00 2006 (5260320 minutes since 1996)
Board Manufacturer = Pigeon Point Systems
Board Product Name = IPM Sentry ShMM-500
Board Serial Number = 08000000
Board Part Number = 01-W3911F11B
FRU Programmer File ID = SAM1000R.inf
Product Info Area:
Version = 1
Language Code = 25
Manufacturer Name = Motorola
Product Name = SAM1000
Product Part / Model# = 01-W2313F11A
Product Version = Rev 1.00
Product Serial Number = 12345678901
Asset Tag =
FRU Programmer File ID = SAM1000R.inf
Multi Record Area:
PICMG Board Point-to-Point Connectivity Record (ID=0x14)
Version = 0
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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28
2.3.2 E-Keying
The physical SAMs (IPMB 0xfc and 0xfe) each contain the following Point-to-Point
Connectivity Record:
PICMG Board Point-to-Point Connectivity Record (ID=0x14)
Version = 0
OEM GUID Count = 0
Link Descriptor:
Link Grouping ID = 0x00
Link Type = 0x01 PICMG®3.0 Base 10/100/1000 Base-T
Link Type Extension = 0x0 10/100/1000BASE-T Link (four-pair)
Link Designator = 0x101 Channel1/BaseInterface/Ports0
Link Descriptor:
Link Grouping ID = 0x00
Link Type = 0x01 PICMG®3.0 Base 10/100/1000 Base-T
Link Type Extension = 0x0 10/100/1000BASE-T Link (four-pair)
Link Designator = 0x102 Channel2/BaseInterface/Ports0
2.3.3 Power Configuration
The following table describes the power configuration for the Physical SAM.
Table 2-2 SAM Physical Power Configuration
Item Value Meaning
Dynamic power reconfiguration
support
No Possibility to change FRU power consumption without
switching it off, according to ATCA
Dynamic power configuration No Are the Power Draw levels fixed or these may vary if
additional components are hot inserted or onboard
components power consumption is changing
dynamically
Number of Power Draw Levels 1 The amount of possible power levels, normally 1
Early Power Draw Levels, Watt 20 Complete early power consumption including IPMC
Steady state Power Draw Levels,
Watt
20 Complete steady power consumption including IPMC
Transition from Early to Steady
levels, sec
0 How long does board consumes early power. Early
power is normally bigger than steady
Sensor Overview FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 29
2.3.4 Sensor Overview
The following table lists all IPMI sensors available on the physical SAM at IPMB addresses
0xFC and 0xFE. The information in this section supports the SAM on both the AXP1406 and
AXP1600 shelves. The AXP1600 FRU and sensor data is highlighted and marked for ease of
use.
Table 2-3 Sensor Overview
Sensor
No. Sensor Name
Type of
Measurement
What does it
measure?
Sensor
Type Availability
0 FRU 0 HOT_SWAP Status State of FRU Discrete Always
1 IPMB LINK Status State of IPMB link Discrete Always
2 Vbat Voltage Analog Always
3 Vcc 3.3 V voltage Voltage Analog Always
4 +12 V voltage Voltage Analog Always
5 +1.8 V Voltage Analog Always
6 MAX6656 INT @1A Temperature Analog Always
7 MAX6656 EXT1 @1A Temperature Analog Always
8 MAX6656 EXT2 @1A Temperature Analog Always
9 PEM A Status PEM A Presence Discrete Always
10 PEM B Status PEM B Presence Discrete Always
11 NSC A1
1. These are additional sensors on the SAM1000 for the AXP1600.
Status NSC Board
Presence
Discrete Always
12 NSC B1Status NSC Board
Presence
Discrete Always
13 AXP Backplane ID OEM Backplane Bus
Type
Discrete Always
14 12 V In B Valid Status Power Unit Discrete Always
15 12 V In A Valid Status Power Unit Discrete Always
16 Fault Event OEM Shelf Manager
Rebooting Notifier
Discrete Always
17 POST Results Status Management
Subsystem Health
Discrete Always
18 Shelf FRU Info OEM Shelf Fru Info
Validity
Discrete Always
128 CPLD State OEM Master and
Backup Shelf
Manager State
Discrete Always
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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30
2.3.5 SAM Physical Shelf Manager Analog Sensors
The physical shelf managers at IPMB addresses 0xFC and 0xFE present the following analog
sensors:
zVoltage Sensors
zTemperature Sensors
The following tables describe the analog sensors available on the physical SAM. The
information in this section supports the SAM on both the AXP1406 and AXP1600 shelves. The
AXP1600 FRU and sensor data is highlighted and marked for ease of use.
2.3.5.1 Voltage Sensors
The following table describes the analog voltage sensors on the physical SAM.
Table 2-4 Sensor No. 2 Vbat
Feature Raw Value/Description Interpreted Value
Sensor Name Vbat
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x60
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable threshold mask,
Settable threshold mask (bytes
19, 20)
0x12, 0x12 Upper and Lower Critical
Thresholds are Readable and
Settable
Reading Type Unsigned
Lower critical threshold 0x00 0 Volts
Upper critical threshold 0xFF 3.315 Volts
SAM Physical Shelf Manager Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 31
Table 2-5 Sensor No. 3 3.3 V Voltage
Feature Raw Value/Description Interpreted Value
Sensor Name Vcc 3.3 V voltage
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x60
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable threshold mask,
Settable threshold mask (bytes
19, 20)
0x12, 0x12 Upper and Lower Critical
Thresholds are Readable and
Settable
Reading Type Unsigned
Lower critical threshold 0x73 3.0245 Volts
Upper critical threshold 0x88 3.5768 Volts
Table 2-6 Sensor No. 4 +12 V Voltage
Feature Raw Value/Description Interpreted Value
Sensor Name +12 V voltage
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x60
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable threshold mask,
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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32
2.3.5.2 Temperature Sensors
The following tables describe the analog temperature sensors available on the physical SAM.
Settable threshold mask (bytes
19, 20)
0x12, 0x12 Upper and Lower Critical
Thresholds are Readable and
Settable
Reading Type Unsigned
Lower critical threshold 0x00 0 Volts
Upper critical threshold 0xFF 15.81 Volts
Table 2-7 Sensor No. 5 +1.8 V
Feature Raw Value/Description Interpreted Value
Sensor Name +1.8 V
Type of measurement Voltage
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x60
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable threshold mask,
Settable threshold mask (bytes
19, 20)
0x10, 0x10 Upper Critical Threshold is
Readable and Settable
Reading Type Unsigned
Upper critical threshold 0xFF 2.499 Volts
Table 2-6 Sensor No. 4 +12 V Voltage (continued)
Feature Raw Value/Description Interpreted Value
Table 2-8 Sensor No. 6 MAX6656 INT@1A
Feature Raw Value/Description Interpreted Value
Sensor Name MAX6656 INT @1A
Device
Sensor Type 0x01 Temperature
Class 0x01 Threshold
SAM Physical Shelf Manager Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 33
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x60
Rearm mode Auto
Hysteresis support Readable and Settable
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable threshold mask,
Settable threshold mask (bytes
19, 20)
0x38, 0x38 Upper Non-Critical, Critical and
Non-Recoverable Thresholds
are Readable and Settable
Reading Type 2's Complement
Upper Non-Critical, Critical and
Non-Recoverable threshold
0x50, 0x5A, 0x64 (80, 90, 100) Centigrade
Table 2-9 Sensor No. 7 MAX6656 EXT1@1A
Feature Raw Value/Description Interpreted Value
Sensor Name MAX6656 EXT1 @1A
Device
Sensor Type 0x01 Temperature
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x60
Rearm mode Auto
Hysteresis support Readable and Settable
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable threshold mask,
Settable threshold mask (bytes
19, 20)
0x38, 0x38 Upper Non-Critical, Critical and
Non-Recoverable Thresholds
are Readable and Settable
Reading Type 2's Complement
Upper Non-Critical, Critical and
Non-Recoverable threshold
0x50, 0x5A, 0x64 (80, 90, 100) Centigrade
Table 2-8 Sensor No. 6 MAX6656 INT@1A (continued)
Feature Raw Value/Description Interpreted Value
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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34
2.3.6 SAM Module Discrete Sensors
The physical shelf managers at IPMB addresses 0xFC and 0xFE present the following discrete
sensors:
zHot Swap Sensor
zIPMB Link Sensor
zPEM A Sensor
zPEM B Sensor
zAXP Backplane ID Sensor
z+12 V B Valid Sensor
z+12 V A Valid Sensor
zFault Event Sensor
zPOST Results Sensor
zShelf FRU Info Sensor
zCPLD State Sensor
Table 2-10 Sensor No. 8 MAX6656 EXT2@1A
Feature Raw Value/Description Interpreted Value
Sensor Name MAX6656 EXT2 @1A
Device
Sensor Type 0x01 Temperature
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x60
Rearm mode Auto
Hysteresis support Readable and Settable
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable threshold mask,
Settable threshold mask (bytes
19, 20)
0x38, 0x38 Upper Non-Critical, Critical and
Non-Recoverable Thresholds
are Readable and Settable
Reading Type 2's Complement
Upper Non-Critical, Critical and
Non-Recoverable threshold
0x50, 0x5A, 0x64 (80, 90, 100) Centigrade
SAM Module Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 35
2.3.6.1 Hot Swap Sensor
The following table describes the discrete hot swap sensor available on the physical SAM.
2.3.6.2 IPMB Link Sensor
The following table describes the discrete IPMB link sensor available on the physical SAM.
Table 2-11 Sensor No. 0 FRU 0 HOT_SWAP
Feature Raw Value/Description Interpreted Value
Sensor Name FRU 0 HOT_SWAP
Type of Measurement Hot Swap State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF0 Hot Swap
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x60
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes 15,
16)
0xFF, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0xFF, 0x00 Supports 8 Successive States
Reading Definition According to PICMG 3.0
Table 2-12 Sensor No. 1 IPMB Link
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK
Type of Measurement IPMB Link State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x60
Rearm mode Auto
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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36
2.3.6.3 PEM A Sensor
The following table describes the discrete PEM A sensor available on the physical SAM.
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-12 Sensor No. 1 IPMB Link (continued)
Feature Raw Value/Description Interpreted Value
Table 2-13 Sensor No. 9 PEM A
Feature Raw Value/Description Interpreted Value
Sensor Name PEM A
Type of Measurement Presence
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0x25 Entity Presence
Sensor Owner LUN 0x00
Entity ID 0x0A Power Supply
Entity Instance 0x00
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x03, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
SAM Module Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 37
2.3.6.4 PEM B Sensor
The following table describes the discrete PEM B sensor available on the physical SAM.
Table 2-14 Sensor No. 10 PEM B
Feature Raw Value/Description Interpreted Value
Sensor Name PEM B
Type of Measurement Presence
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0x25 Entity Presence
Sensor Owner LUN 0x00
Entity ID 0x0A Power Supply
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x03, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
Two additional NSC Presence sensor support the SAM used in the AXP1600 shelf.
Table 2-15 Sensor No. 11 NSC A (AXP1600 Only)
Feature Raw Value/Description Interpreted Value
Sensor Name NSC A
Type of Measurement Presence
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0x25 Entity Presence
Sensor Owner LUN 0x00
Entity ID 0x0B (add-in card) Power Supply
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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38
Entity Instance 0x00
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x03, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
Table 2-16 Sensor No. 12 NSC B (AXP1600 Only)
Feature Raw Value/Description Interpreted Value
Sensor Name NSC B
Type of Measurement Presence
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0x25 Entity Presence
Sensor Owner LUN 0x00
Entity ID 0x0B (add-in card Power Supply
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x03, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
Table 2-15 Sensor No. 11 NSC A (AXP1600 Only) (continued)
Feature Raw Value/Description Interpreted Value
SAM Module Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 39
2.3.6.5 AXP Backplane ID Sensor
The following table describes the discrete AXP backplane ID sensor available on the physical
SAM. For more detail on this sensor, refer to AXP Backplane ID (Emerson OEM) on page 138.
2.3.6.6 +12 V B Valid Sensor
The following table describes the discrete +12 V B valid sensor available on the physical SAM.
Table 2-17 Sensor No. 13 AXP Backplane ID
Feature Raw Value/Description Interpreted Value
Sensor Name AXP Backplane ID
Type of Measurement Specifies Bus Type of the
Backplane
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xDB OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x60
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x01, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x01 0x00 Supports 1 Successive State
Reading Definition According to Motorola XXXX
Table 2-18 Sensor No. 14 12 V B Valid
Feature Raw Value/Description Interpreted Value
Sensor Name 12 V In B Valid
Type of Measurement State of Power Unit B
Class Discrete
Event/Reading Type 0x03 'digital' Discrete
Sensor Type 0x09 Power Unit
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x60
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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40
2.3.6.7 +12 V A Valid Sensor
The following table describes the discrete +12V A valid sensor available on the physical SAM.
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x03, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
Table 2-18 Sensor No. 14 12 V B Valid (continued)
Feature Raw Value/Description Interpreted Value
Table 2-19 Sensor No. 15 12 V A Valid
Feature Raw Value/Description Interpreted Value
Sensor Name 12 V In A Valid
Type of Measurement State of Power Unit A
Class Discrete
Event/Reading Type 0x03 'digital' Discrete
Sensor Type 0x09 Power Unit
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x60
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x03, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
SAM Module Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 41
2.3.6.8 Fault Event Sensor
The following table describes the discrete fault event sensor available on the physical SAM.
2.3.6.9 POST Results Sensor
The following table describes the discrete POST results sensor available on the physical SAM.
For more information on this sensor, refer to POST Results (Emerson OEM) on page 138.
Table 2-20 Sensor No. 16 Fault Event
Feature Raw Value/Description Interpreted Value
Sensor Name Fault Event
Type of Measurement Reports that the Shelf Manager
has Rebooted.
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xDC OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x60
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x01, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x01, 0x00 Supports 1 State
Reading Definition According to Motorola XXX
Table 2-21 Sensor No. 17 POST Results
Feature Raw Value/Description Interpreted Value
Sensor Name POST Results
Type of Measurement POST Results
Class Discrete
Event/Reading Type 0x06 'digital' Discrete
Sensor Type 0x28 Management Subsystem Health
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x60
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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42
2.3.6.10 Shelf FRU Info Sensor
The following table describes the discrete shelf FRU info sensor available on the physical SAM.
For more information on this sensor, refer to Shelf FRU Info (Emerson OEM) on page 139.
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x02, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
Table 2-21 Sensor No. 17 POST Results (continued)
Feature Raw Value/Description Interpreted Value
Table 2-22 Sensor No. 18 Shelf FRU Info
Feature Raw Value/Description Interpreted Value
Sensor Name Shelf FRU Info
Type of Measurement Basic validation of the Shelf
FRU Info
Class Discrete
Event/Reading Type 0x09 'digital' Discrete
Sensor Type 0xDD OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x60
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x03, 0x00
Deassertion Event Mask(bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to Motorola XXX
SAM1000 Active (Virtual) Shelf Manager FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 43
2.3.6.11 CPLD State Sensor
The following table describes the discrete CPLD state sensor available on the physical SAM.
2.4 SAM1000 Active (Virtual) Shelf Manager
This section describes in detail all available IPMI sensors of the Active SAM1000 at IPMB
address 0x20. The information in this section supports the SAM on both the AXP1406 and
AXP1600 shelves. The AXP1600 FRU and sensor data is highlighted and/or marked for ease
of use.
2.4.1 FRU Information
FRU 0 of address 0x20 corresponds to the main FRU information of the respective Physical
SAM that is running as the Active SAM; it could be either FRU 0 of IPMB address 0xFC or FRU
0 of IPMB address 0xFE.
Active Shelf Manager FRU Data, AXP1406
There are an additional eight managed FRUs (FRUs 1 to 8) that correspond to each of the eight
fan trays that cool the chassis. The Active SAM FRU information is addressed as FRU 254
which is cached information from data stored as a FRU 1 in each of the PEMs (IPMB addresses
0x66 and 0x68).
Table 2-23 Sensor No. 128 CPLD State
Feature Raw Value/Description Interpreted Value
Sensor Name CPLD State
Type of Measurement States of the Master and Backup
Shelf Managers
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xDE OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x60
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0xF7, 0x07
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0xF7, 0x07 Supports 10 States
Reading Definition According to Motorola XXX
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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44
Active Shelf Manager FRU Data, AXP1600
There are an additional nine managed FRUs (FRUs 1 to 9) that correspond to each of the nine
fan trays that cool the chassis. The Active SAM FRU information is addressed as FRU 254
which is cached information from data stored as a FRU 1 in each of the PEMs (IPMB addresses
0x66 and 0x68).
The following tables show an example of the output obtained when retrieving FRU information
using the CLIA tool of the Active SAM.
2.4.1.1 Active Shelf Manager FRU Data, AXP1406
# clia fruinfo 20 254
Pigeon Point Shelf Manager Command Line Interpreter
66: FRU # 1, FRU Info
Common Header: Format Version = 1
Chassis Info Area:
Version = 1
Chassis Type = (2)
Chassis Part Number = CHS1406
Chassis Serial Number = 0000001
Board Info Area:
Version = 1
Language Code = 25
Mfg Date/Time = Mar 29 00:00:00 2006 (5385600 minutes since 1996)
Board Manufacturer = Motorola
Board Product Name = CHS1406
Board Serial Number = 0000001
Board Part Number = CHS1406
FRU Programmer File ID = CHS1406.inf
Product Info Area:
Version = 1
FRU Information FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 45
Language Code = 25
Manufacturer Name = Motorola
Product Name = CHS1406
Product Part / Model# = CHS1406
Product Version = Rev. 1
Product Serial Number = 0000001
Asset Tag =
FRU Programmer File ID = CHS1406.inf
Multi Record Area:
PICMG Shelf Manager IP Connection Record (ID=0x13)
Version = 1
Record Type = Management Access Record
Version = 2
Sub-Record Type: Component Name (0x05)
PICMG Address Table Record (ID=0x10)
Version = 0
PICMG Backplane Point-to-Point Connectivity Record (ID=0x04)
Version = 0
PICMG Backplane Point-to-Point Connectivity Record (ID=0x04)
Version = 0
PICMG Shelf Power Distribution Record (ID=0x11)
Version = 0
PICMG Radial IPMB-0 Link Mapping Record (ID=0x15)
Version = 0
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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46
PICMG Shelf Activation And Power Management Record (ID=0x12)
Version = 0
Record Type = 0xc0 OEM Record
Version = 2
Manufacturer ID = 0x0000A1 MOTOROLA
Record ID = 0x02
2.4.1.2 Active Shelf Manager FRU Data, AXP1600
Pigeon Point Shelf Manager Command Line Interpreter
20: FRU # 254, FRU Info
Common Header: Format Version = 1
Chassis Info Area:
Version = 1
Chassis Type = (1)
Chassis Part Number = 01-W1055C12B
Chassis Serial Number = 00001
Board Info Area:
Version = 1
Language Code = 25
Mfg Date/Time = Jan 1 00:00:00 2006 (5260320 minutes since 1
996)
Board Manufacturer = Motorola
Board Product Name = CHS1600
Board Serial Number = 1234567890
Board Part Number = CHS1600
FRU Programmer File ID = CHS1600R_ShelfFru.inf
FRU Information FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 47
Product Info Area:
Version = 1
Language Code = 25
Manufacturer Name = Motorola
Product Name = CHS1600
Product Part / Model# = CHS1600
Product Version = Rev. 1
Product Serial Number = 00001
Asset Tag =
FRU Programmer File ID = CHS1600R_ShelfFru.inf
Multi Record Area:
PICMG Shelf Manager IP Connection Record (ID=0x13)
Version = 1
Record Type = Management Access Record
Version = 2
Sub-Record Type: Component Name (0x05)
PICMG Address Table Record (ID=0x10)
Version = 0
PICMG Backplane Point-to-Point Connectivity Record (ID=0x04)
Version = 0
PICMG Backplane Point-to-Point Connectivity Record (ID=0x04)
Version = 0
PICMG Backplane Point-to-Point Connectivity Record (ID=0x04)
Version = 0
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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48
PICMG Shelf Power Distribution Record (ID=0x11)
Version = 0
PICMG Radial IPMB-0 Link Mapping Record (ID=0x15)
Version = 0
PICMG Shelf Activation And Power Management Record (ID=0x12)
Version = 1
Record Type = 0xc0 OEM Record
Version = 2
Manufacturer ID = 0x0000A1 MOTOROLA
Record ID = 0x02
2.4.1.3 SAM1000 Shelf Manager FRU Data
Pigeon Point Shelf Manager Command Line Interpreter
fc: FRU # 0, FRU Info
Common Header: Format Version = 1
Internal Use Area:
Version = 1
Board Info Area:
Version = 1
Language Code = 25
Mfg Date/Time = Jan 1 00:00:00 2006 (5260320 minutes since 1996)
Board Manufacturer = Pigeon Point Systems
Board Product Name = IPM Sentry ShMM-500
Board Serial Number = 08000000
Board Part Number = 01-W3911F11B
FRU Programmer File ID = SAM1000R.inf
Product Info Area:
Version = 1
FRU Information FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 49
Language Code = 25
Manufacturer Name = Motorola
Product Name = SAM1000
Product Part / Model# = 01-W2313F11A
Product Version = Rev 1.00
Product Serial Number = 12345678901
Asset Tag =
FRU Programmer File ID = SAM1000R.inf
Multi Record Area:
PICMG Board Point-to-Point Connectivity Record (ID=0x14)
Version = 0
2.4.1.4 Fan Tray FRU Data, AXP1406
There are eight fan trays in the AXP1406 shelf, six of them are located at the top of the shelf
and two are located in the bottom. Looking at the shelf from the top; the location of the fan tray
FRUs 1 through 6 looks like this:
The bottom fan tray are FRU 7 (left side) and FRU 8 (right side) looking at the shelf from the
front.
Figure 2-1 Upper Fan Tray Locations, AXP1406
Figure 2-2 Lower Fan Tray Locations, AXP1406
654
123
Top Rear
Top Front
78
Bottom Front
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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50
The FRU information for fan trays 1, 2 and 3 is the same (except serial numbers); similarly for
fan trays 4, 5 and 6; and for fan trays 7 and 8. This information follows:
2.4.1.5 Fan Tray FRUs 1,2, and 3 Data
Pigeon Point Shelf Manager Command Line Interpreter
20: FRU # 1, FRU Info
Common Header: Format Version = 1
Board Info Area:
Version = 1
Language Code = 25
Mfg Date/Time = Jan 10 00:00:00 2006 (5273280 minutes since 1996)
Board Manufacturer = Motorola
Board Product Name = CHS1406 Fan Tray
Board Serial Number = AA123456
Board Part Number = 0106876A01B
FRU Programmer File ID = CHS1406R_FT_UpperFront.inf
Product Info Area:
Version = 1
Language Code = 25
Manufacturer Name = Motorola
Product Name = CHS1406 Fan Tray
Product Part / Model# = TFT-F-1406
Product Version = Rev. 1.00
Product Serial Number = AA123456
Asset Tag =
FRU Programmer File ID = CHS1406R_FT_UpperFront.inf
FRU Information FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 51
2.4.1.6 Fan Tray FRUs 4, 5, and 6 Data
Pigeon Point Shelf Manager Command Line Interpreter
20: FRU # 4, FRU Info
Common Header: Format Version = 1
Board Info Area:
Version = 1
Language Code = 25
Mfg Date/Time = Jan 1 00:00:00 2006 (5260320 minutes since 1996)
Board Manufacturer = Motorola
Board Product Name = CHS1406 Fan Tray
Board Serial Number = AA123456
Board Part Number = 0106877A01B
FRU Programmer File ID = CHS1406R_FT_UpperRear.inf
Product Info Area:
Version = 1
Language Code = 25
Manufacturer Name = Motorola
Product Name = CHS1406 Fan Tray
Product Part / Model# = TFT-R-1406
Product Version = Rev. 1.00
Product Serial Number = AA123456
Asset Tag =
FRU Programmer File ID = CHS1406R_FT_UpperRear.inf
2.4.1.7 Fan Tray FRUs 7 and 8 Data
Pigeon Point Shelf Manager Command Line Interpreter
20: FRU # 7, FRU Info
Common Header: Format Version = 1
Board Info Area:
Version = 1
Language Code = 25
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52
Mfg Date/Time = Jan 10 00:00:00 2006 (5273280 minutes since 1996)
Board Manufacturer = Motorola
Board Product Name = CHS1406 Fan Tray
Board Serial Number = AA123456
Board Part Number = 0106878A01B
FRU Programmer File ID = CHS1406R_FT_LowerFront.inf
Product Info Area:
Version = 1
Language Code = 25
Manufacturer Name = Motorola
Product Name = CHS1406 Fan Tray
Product Part / Model# = BFT-F-1406
Product Version = Rev. 1.00
Product Serial Number = AA123456
Asset Tag =
FRU Programmer File ID = CHS1406R_FT_LowerFront.inf
2.4.1.8 Fan Tray FRU Data, AXP1600
There are nine fan trays in the AXP1600 shelf, six of them are located at the top of the shelf
and three are located in the bottom. Looking at the shelf from the top; the location of the fan
tray FRUs 1 through 6 looks like this:
Figure 2-3 Upper Fan Tray Locations, AXP1600
654
123
Top Rear
Top Front
FRU Information FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 53
The bottom three fan trays are FTM 7 (left side) and FTM 8 (center), and FTM 9 (right side)
looking at the shelf from the front.
The FRU information for fan trays 1, 2 and 3 is the same (except serial numbers); similarly for
fan trays 4, 5 and 6; and for fan trays 7, 8 and 9. This information follows:
2.4.1.9 Fan Tray FRUs 1, 2, and 3 Data, AXP1600
Pigeon Point Shelf Manager Command Line Interpreter
20: FRU # 1, FRU Info
Common Header: Format Version = 1
Board Info Area:
Version = 1
Language Code = 25
Mfg Date/Time = Jan 1 00:00:00 2006 (5260320 minutes since 1996)
Board Manufacturer = Motorola
Board Product Name = CHS1600 Fan Tray
Board Serial Number = 1234567890
Board Part Number = 01-W2327F12A
FRU Programmer File ID = CHS1600R_FT_UpperFront.inf
Product Info Area:
Version = 1
Language Code = 25
Manufacturer Name = Motorola
Product Name = CHS1600 Fan Tray
Figure 2-4 Lower Fan Tray Locations, AXP1600
79
Bottom Front
8
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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54
Product Part / Model# = TFT-F-1600
Product Version = Rev. 1.00
Product Serial Number = 1234567890
Asset Tag =
FRU Programmer File ID = CHS1600R_FT_UpperFront.inf
2.4.1.10 Fan Tray FRUs 4, 5, and 6 Data, AXP1600
Pigeon Point Shelf Manager Command Line Interpreter
20: FRU # 4, FRU Info
Common Header: Format Version = 1
Board Info Area:
Version = 1
Language Code = 25
Mfg Date/Time = Jan 1 00:00:00 2006 (5260320 minutes since 1996)
Board Manufacturer = Motorola
Board Product Name = CHS1600 Fan Tray
Board Serial Number = 1234567890
Board Part Number = 01-W2328F12A
FRU Programmer File ID = CHS1600R_FT_UpperRear.inf
Product Info Area:
Version = 1
Language Code = 25
Manufacturer Name = Motorola
Product Name = CHS1600 Fan Tray
Product Part / Model# = TFT-R-1600
Product Version = Rev. 1.00
Product Serial Number = 1234567890
Asset Tag =
FRU Programmer File ID = CHS1600R_FT_UpperRear.inf
E-Keying FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 55
2.4.1.11 Fan Tray FRUs 7, 8 and 9 Data, AXP1600
Pigeon Point Shelf Manager Command Line Interpreter
20: FRU # 7, FRU Info
Common Header: Format Version = 1
Board Info Area:
Version = 1
Language Code = 25
Mfg Date/Time = Jan 1 00:00:00 2006 (5260320 minutes since 1996)
Board Manufacturer = Motorola
Board Product Name = CHS1600 Fan Tray
Board Serial Number = 1234567890
Board Part Number = 01-W2329F12A
FRU Programmer File ID = CHS1600R_FT_LowerFront.inf
Product Info Area:
Version = 1
Language Code = 25
Manufacturer Name = Motorola
Product Name = CHS1600 Fan Tray
Product Part / Model# = BFT-F-1600
Product Version = Rev. 1.00
Product Serial Number = 1234567890
Asset Tag =
FRU Programmer File ID = CHS1600R_FT_LowerFront.inf
2.4.2 E-Keying
The active (virtual) SAM does not have e-keyed backplane interfaces, and hence the FRU
information for it does not contain a PICMG Point-to-Point Connectivity Record.
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records Power Configuration
56
2.4.3 Power Configuration
The following table describes the power configuration for the Active SAM.
2.4.4 Active SAM1000 Sensor Overview
The following table lists the discrete and analog sensors that reside on the Active SAM. The
information in this section supports the SAM on both the AXP1406 and AXP1600 shelves. The
AXP1600 FRU and sensor data is highlighted and/or marked for ease of use.
Rows that are highlighted in blue provide information for the additional sensors on the
SAM1000 for the AXP1600.
Table 2-24 SAM1000 Active Power Configuration
Item Value Meaning
Dynamic power reconfiguration support No Possibility to change FRU power consumption
without switching it off, according to
AdvancedTCA
Dynamic power configuration No Are the power draw levels fixed or these may vary
if additional components are hot inserted or
onboard components’ power consumption is
changing dynamically
Number of power draw levels 1 The amount of possible power levels, normally 1
Early power draw levels, Watt 5 Complete early power consumption including
IPMC
Steady state power draw levels, Watt 5 Complete steady power consumption including
IPMC
Transition from Early to Steady levels,
sec
0 How long does board consumes early power.
Early power is normally bigger than steady
Table 2-25 Active SAM1000 Sensor Overview
Sensor
No. Sensor Name
Type of
Measurement
What does it
measure?
Sensor
Type Availability
0FRU 0
HOT_SWAP
Status State of FRU Discrete Always
2FRU 1
HOT_SWAP
Status State of FRU Discrete Always
3FRU 2
HOT_SWAP
Status State of FRU Discrete Always
4FRU 3
HOT_SWAP
Status State of FRU Discrete Always
5FRU 4
HOT_SWAP
Status State of FRU Discrete Always
6FRU 5
HOT_SWAP
Status State of FRU Discrete Always
Active SAM1000 Sensor Overview FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 57
7FRU 6
HOT_SWAP
Status State of FRU Discrete Always
8FRU 7
HOT_SWAP
Status State of FRU Discrete Always
9FRU 8
HOT_SWAP
Status State of FRU Discrete Always
10 FRU9 HOT_SWAP Status State of FRU Discrete Always
11 SHM FAULT
EVENT
Status State of SHM Discrete Always
12 IPMB LINK 1 Status State of IPMB
link
Discrete Always
13 IPMB LINK 2 Status State of IPMB
link
Discrete Always
14 IPMB LINK 3 Status State of IPMB
link
Discrete Always
15 IPMB LINK 4 Status State of IPMB
link
Discrete Always
16 IPMB LINK 5 Status State of IPMB
link
Discrete Always
17 IPMB LINK 6 Status State of IPMB
link
Discrete Always
18 IPMB LINK 7 Status State of IPMB
link
Discrete Always
19 IPMB LINK 8 Status State of IPMB
link
Discrete Always
20 IPMB LINK 9 Status State of IPMB
link
Discrete Always
21 IPMB LINK 10 Status State of IPMB
link
Discrete Always
22 IPMB LINK 11 Status State of IPMB
link
Discrete Always
23 IPMB LINK 12 Status State of IPMB
link
Discrete Always
24 IPMB LINK 13 Status State of IPMB
link
Discrete Always
25 IPMB LINK 14 Status State of IPMB
link
Discrete Always
26 IPMB LINK 15 Status State of IPMB
link
Discrete Always
27 IPMB LINK 16 Status State of IPMB
link
Discrete Always
Table 2-25 Active SAM1000 Sensor Overview (continued)
Sensor
No. Sensor Name
Type of
Measurement
What does it
measure?
Sensor
Type Availability
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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58
28 IPMB LINK 17 Status State of IPMB
link
Discrete Always
29 IPMB LINK 18 Status State of IPMB
link
Discrete Always
30 IPMB LINK 19 Status State of IPMB
link
Discrete Always
31 IPMB LINK 20 Status State of IPMB
link
Discrete Always
32 IPMB LINK 21 Status State of IPMB
link
Discrete Always
131 TELCO Alarms Status State of
TELCO Alarms
Discrete Always
132 BMC Watchdog Status State of BMC
Watchdog on
active SAM
Discrete Always
133 SYSTEM EVENT Status State of PEF
actions,
system
reconfigured
events, etc.
Discrete Always
141 FT 1 Fan 1 Fan Speed RPM of Fan 1 Analog Always
142 FT 1 Fan 2 Fan Speed RPM of Fan 2 Analog Always
143 FT 2 Fan 1 Fan Speed RPM of Fan 1 Analog Always
144 FT 2 Fan 2 Fan Speed RPM of Fan 2 Analog Always
145 FT 3 Fan 1 Fan Speed RPM of Fan 1 Analog Always
146 FT 3 Fan 2 Fan Speed RPM of Fan 2 Analog Always
147 FT 4 Fan 1 Fan Speed RPM of Fan 1 Analog Always
148 FT 4 Fan 2 Fan Speed RPM of Fan 2 Analog Always
149 FT 5 Fan 1 Fan Speed RPM of Fan 1 Analog Always
150 FT 5 Fan 2 Fan Speed RPM of Fan 2 Analog Always
151 FT 6 Fan 1 Fan Speed RPM of Fan 1 Analog Always
152 FT 6 Fan 2 Fan Speed RPM of Fan 2 Analog Always
153 FT 7 Fan 1 Fan Speed RPM of Fan 1 Analog Always
154 FT 7 Fan 2 Fan Speed RPM of Fan 2 Analog Always
155 FT 8 Fan 1 Fan Speed RPM of Fan 1 Analog Always
156 FT 8 Fan 2 Fan Speed RPM of Fan 2 Analog Always
157 FT 9 Fan 1 Fan Speed RPM of Fan 1 Analog Always
158 FT 9 Fan 2 Fan Speed RPM of Fan 2 Analog Always
171 FT 1 Fan 1 12 V Voltage Analog Always
Table 2-25 Active SAM1000 Sensor Overview (continued)
Sensor
No. Sensor Name
Type of
Measurement
What does it
measure?
Sensor
Type Availability
Active SAM1000 Sensor Overview FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 59
172 FT 1 Fan 1 VBias Voltage Analog Always
173 FT 1 Fan 2 12 V Voltage Analog Always
174 FT 1 Fan 2 VBias Voltage Analog Always
175 FT 2 Fan 1 12 V Voltage Analog Always
176 FT 2 Fan 1 VBias Voltage Analog Always
177 FT 2 Fan 2 12 V Voltage Analog Always
178 FT 2 Fan 2 VBias Voltage Analog Always
179 FT 3 Fan 1 12 V Voltage Analog Always
180 FT 3 Fan 1 VBias Voltage Analog Always
181 FT 3 Fan 2 12 V Voltage Analog Always
182 FT 3 Fan 2 VBias Voltage Analog Always
183 FT 4 Fan 1 12 V Voltage Analog Always
184 FT 4 Fan 1 VBias Voltage Analog Always
185 FT 4 Fan 2 12 V Voltage Analog Always
186 FT 4 Fan 2 VBias Voltage Analog Always
187 FT 5 Fan 1 12 V Voltage Analog Always
188 FT 5 Fan 1 VBias Voltage Analog Always
189 FT 5 Fan 2 12 V Voltage Analog Always
190 FT 5 Fan 2 VBias Voltage Analog Always
191 FT 6 Fan 1 12 V Voltage Analog Always
192 FT 6 Fan 1 VBias Voltage Analog Always
193 FT 6 Fan 2 12 V Voltage Analog Always
194 FT 6 Fan 2 VBias Voltage Analog Always
195 FT 7 Fan 1 12 V Voltage Analog Always
196 FT 7 Fan 1 VBias Voltage Analog Always
197 FT 7 Fan 2 12 V Voltage Analog Always
198 FT 7 Fan 2 VBias Voltage Analog Always
199 FT 8 Fan 1 12 V Voltage Analog Always
200 FT 8 Fan 1 VBias Voltage Analog Always
201 FT 8 Fan 2 12 V Voltage Analog Always
202 FT 8 Fan 2 VBias Voltage Analog Always
203 FT 9 Fan 1 12 V Voltage Analog Always
204 FT 9 Fan 1 VBias Voltage Analog Always
205 FT 9 Fan 2 12 V Voltage Analog Always
206 FT 9 Fan 2 VBias Voltage Analog Always
Table 2-25 Active SAM1000 Sensor Overview (continued)
Sensor
No. Sensor Name
Type of
Measurement
What does it
measure?
Sensor
Type Availability
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60
220 Fan Tray 1 Status Fan Tray 1
Presence
Discrete Always
221 Fan Tray 2 Status Fan Tray 2
Presence
Discrete Always
222 Fan Tray 3 Status Fan Tray 3
Presence
Discrete Always
223 Fan Tray 4 Status Fan Tray 4
Presence
Discrete Always
224 Fan Tray 5 Status Fan Tray 5
Presence
Discrete Always
225 Fan Tray 6 Status Fan Tray 6
Presence
Discrete Always
226 Fan Tray 7 Status Fan Tray 7
Presence
Discrete Always
227 Fan Tray 8 Status Fan Tray 8
Presence
Discrete Always
228 Fan Tray 9 Status Fan Tray 9
Presence
Discrete Always
230 FT 1 -48 V Fuse Status OEM-reserved Discrete Always
231 FT 2 -48 V Fuse Status OEM-reserved Discrete Always
232 FT 3 -48 V Fuse Status OEM-reserved Discrete Always
233 FT 4 -48 V Fuse Status OEM-reserved Discrete Always
234 FT 5 -48 V Fuse Status OEM-reserved Discrete Always
235 FT 6 -48 V Fuse Status OEM-reserved Discrete Always
236 FT 7 -48 V Fuse Status OEM-reserved Discrete Always
237 FT 8 -48 V Fuse Status OEM-reserved Discrete Always
238 FT 9 -48 V Fuse Status OEM-reserved Discrete Always
Table 2-25 Active SAM1000 Sensor Overview (continued)
Sensor
No. Sensor Name
Type of
Measurement
What does it
measure?
Sensor
Type Availability
Active SAM1000 Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 61
2.4.5 Active SAM1000 Analog Sensors
The Active SAM at IPMB address 0x20 presents the following analog sensors:
All fan sensors are exposed by the Active SAM.
zFan Speed Sensors
zFan Voltage Sensors
2.4.5.1 Fan Speed Sensors
The following tables describe the analog fan speed sensors available on the Active SAM.
Table 2-26 Sensor No. 141 (0x8D) FT 1 Fan 1
Feature Raw Value/Description Interpreted Value
Sensor Name FT 1 Fan 1
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x60
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x00 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x23 1190 RPM
Table 2-27 Sensor No. 142 (0x8E) FT 1 Fan 2
Feature Raw Value/Description Interpreted Value
Sensor Name FT 1 Fan 2
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
0x00 Sensor Owner LUN
Entity ID 0x1E Cooling Unit
Entity Instance 0x60
Rearm mode Auto
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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62
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x00 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x23 1190 RPM
Table 2-28 Sensor No. 143 (0x8F) FT 2 Fan 1
Feature Raw Value/Description Interpreted Value
Sensor Name FT 2 Fan 1
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x61
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x00 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x23 1190 RPM
Table 2-29 Sensor No. 144 (0x90) FT2 Fan 2
Feature Raw Value/Description Interpreted Value
Sensor Name FT 2 Fan 2
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x61
Rearm mode Auto
Table 2-27 Sensor No. 142 (0x8E) FT 1 Fan 2 (continued)
Feature Raw Value/Description Interpreted Value
Active SAM1000 Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 63
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x00 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x23 1190 RPM
Table 2-30 Sensor No. 145 (0x91) FT 3 Fan 1
Feature Raw Value/Description Interpreted Value
Sensor Name FT 3 Fan 1
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x62
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x00 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x23 1190 RPM
Table 2-31 Sensor No. 146 (0x92) FT 3 Fan 2
Raw Value/Description Feature Interpreted Value
Sensor Name FT 3 Fan 2
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x62
Rearm mode Auto
Table 2-29 Sensor No. 144 (0x90) FT2 Fan 2 (continued)
Feature Raw Value/Description Interpreted Value
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64
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x00 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x23 1190 RPM
Table 2-32 Sensor No. 147 (0x93) FT 4 Fan 1
Feature Raw Value/Description Interpreted Value
Sensor Name FT 4 Fan 1
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x63
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x00 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x23 1190 RPM
Table 2-33 Sensor No. 148 (0x94) FT 4 Fan 2
Feature Raw Value/Description Interpreted Value
Sensor Name FT 4 Fan 2
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x63
Rearm mode Auto
Table 2-31 Sensor No. 146 (0x92) FT 3 Fan 2 (continued)
Raw Value/Description Feature Interpreted Value
Active SAM1000 Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 65
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x00 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x23 1190 RPM
Table 2-34 Sensor No. 149 (0x95) FT 5 Fan 1
Feature Raw Value/Description Interpreted Value
Sensor Name FT 5 Fan 1
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x64
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x00 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x23 1190 RPM
Table 2-35 Sensor No. 150 (0x96) FT 5 Fan 2
Feature Raw Value/Description Interpreted Value
Sensor Name FT 5 Fan 2
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x64
Rearm mode Auto
Table 2-33 Sensor No. 148 (0x94) FT 4 Fan 2 (continued)
Feature Raw Value/Description Interpreted Value
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66
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x00 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x23 1190 RPM
Table 2-36 Sensor No. 151 (0x97) FT 6 Fan 1
Feature Raw Value/Description Interpreted Value
Sensor Name FT 6 Fan 1
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x65
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x0 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x23 1190 RPM
Table 2-37 Sensor No. 152 (0x98) FT 6 Fan 2
Raw Value/Description Feature Interpreted Value
Sensor Name FT 6 Fan 2
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x65
Rearm mode Auto
Table 2-35 Sensor No. 150 (0x96) FT 5 Fan 2 (continued)
Feature Raw Value/Description Interpreted Value
Active SAM1000 Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 67
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x0 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x23 1190 RPM
Table 2-38 Sensor No. 153 (0x99) FT 7 Fan 1
Feature Raw Value/Description Interpreted Value
Sensor Name FT 7 Fan 1
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x66
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x00 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x83 5895 RPM
Table 2-39 Sensor No. 154 (0x9A) FT 7 Fan 2
Feature Raw Value/Description Interpreted Value
Sensor Name FT 7 Fan 2
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x66
Rearm mode Auto
Table 2-37 Sensor No. 152 (0x98) FT 6 Fan 2 (continued)
Raw Value/Description Feature Interpreted Value
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records Active SAM1000 Analog Sensors
68
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x00 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x83 5895 RPM
Table 2-40 Sensor No. 155 (0x9B) FT 8 Fan 1
Feature Raw Value/Description Interpreted Value
Sensor Name FT 8 Fan 1
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x67
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x00 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x83 5895 RPM
Table 2-41 Sensor No. 156 (0x9C) FT 8 Fan 2
Feature Raw Value/Description Interpreted Value
Sensor Name FT 8 Fan 2
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x67
Rearm mode Auto
Table 2-39 Sensor No. 154 (0x9A) FT 7 Fan 2 (continued)
Feature Raw Value/Description Interpreted Value
Active SAM1000 Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 69
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x00 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x83 5895 RPM
Table 2-41 Sensor No. 156 (0x9C) FT 8 Fan 2 (continued)
Feature Raw Value/Description Interpreted Value
Two additional Fan Speed sensors support the SAM used in the AXP1600 shelf.
Table 2-42 Sensor No. 157 (0x9D) FT 9 Fan 1, AXP1600
Feature Raw Value/Description Interpreted Value
Sensor Name FT 9 Fan 1
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x68
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x00 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x83 5895 RPM
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records Active SAM1000 Analog Sensors
70
2.4.5.2 Fan Voltage Sensors
The following tables describe the analog fan voltage sensors available on the Active SAM.
Table 2-43 Sensor No. 158 (0x9E) FT 9 Fan 2, AXP1600
Feature Raw Value/Description Interpreted Value
Sensor Name FT 9 Fan 2
Device
Sensor Type 0x04 Fan Speed
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x68
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x02, 0x00 Lower Critical Threshold is
Readable
Reading Type Unsigned
Lower critical threshold 0x83 5895 RPM
Table 2-44 Sensor No. 171 (0xAB) FT 1 Fan 1 12 V
Feature Raw Value/Description Interpreted Value
Sensor Name FT 1 Fan 1 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x60
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Active SAM1000 Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 71
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-45 Sensor No. 172 (0xAC) FT 1 Fan 1 VBias
Feature Raw Value/Description Interpreted Value
Sensor Name FT 1 Fan 1 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x60
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-46 Sensor No. 173 (0xAD) FT 1 Fan 2 12 V
Feature Raw Value/Description Interpreted Value
Sensor Name FT 1 Fan 2 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Table 2-44 Sensor No. 171 (0xAB) FT 1 Fan 1 12 V (continued)
Feature Raw Value/Description Interpreted Value
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records Active SAM1000 Analog Sensors
72
Entity ID 0x1E Cooling Unit
Entity Instance 0x60
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-47 Sensor No. 174 (0xAE) FT 1 Fan 2 VBias
Feature Raw Value/Description Interpreted Value
Sensor Name FT 1 Fan 2 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x60
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-46 Sensor No. 173 (0xAD) FT 1 Fan 2 12 V (continued)
Feature Raw Value/Description Interpreted Value
Active SAM1000 Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 73
Table 2-48 Sensor No. 175 (0xAF) FT 2 Fan 1 12 V
Feature Raw Value/Description Interpreted Value
Sensor Name FT 2 Fan 1 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x61
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-49 Sensor No. 176 (0xB0) FT 2 Fan 1 VBias
Feature Raw Value/Description Interpreted Value
Sensor Name FT 2 Fan 1 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x61
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records Active SAM1000 Analog Sensors
74
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds are
Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-50 Sensor No. 177 (0xB1) FT 2 Fan 2 12 V
Feature Raw Value/Description Interpreted Value
Sensor Name FT 2 Fan 2 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x61
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds are
Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-51 Sensor No. 178 (0xB2) FT 2 Fan 2 VBias
Feature Raw Value/Description Interpreted Value
Sensor Name FT 2 Fan 2 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Table 2-49 Sensor No. 176 (0xB0) FT 2 Fan 1 VBias (continued)
Feature Raw Value/Description Interpreted Value
Active SAM1000 Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 75
Entity ID 0x1E Cooling Unit
Entity Instance 0x61
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-52 Sensor No. 179 (0xB3) FT 3 Fan 1 12 V
Feature Raw Value/Description Interpreted Value
Sensor Name FT 3 Fan 1 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x62
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-51 Sensor No. 178 (0xB2) FT 2 Fan 2 VBias (continued)
Feature Raw Value/Description Interpreted Value
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records Active SAM1000 Analog Sensors
76
Table 2-53 Sensor No. 180 (0xB4) FT 3 Fan 1 VBias
Feature Raw Value/Description Interpreted Value
Sensor Name FT 3 Fan 1 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x62
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-54 Sensor No. 181 (0xB5) FT 3 Fan 2 12 V
Feature Raw Value/Description Interpreted Value
Sensor Name FT 3 Fan 2 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x62
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Active SAM1000 Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 77
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-55 Sensor No. 182 (0xB6) FT 3 Fan 2 VBias
Feature Raw Value/Description Interpreted Value
Sensor Name FT 3 Fan 2 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x62
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-56 Sensor No. 183 (0xB7) FT 4 Fan 1 12 V
Feature Raw Value/Description Interpreted Value
Sensor Name FT 4 Fan 1 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Table 2-54 Sensor No. 181 (0xB5) FT 3 Fan 2 12 V (continued)
Feature Raw Value/Description Interpreted Value
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records Active SAM1000 Analog Sensors
78
Entity ID 0x1E Cooling Unit
Entity Instance 0x63
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-57 Sensor No. 184 (0xB8) FT 4 Fan 1 VBias
Feature Raw Value/Description Interpreted Value
Sensor Name FT 4 Fan 1 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x63
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-56 Sensor No. 183 (0xB7) FT 4 Fan 1 12 V (continued)
Feature Raw Value/Description Interpreted Value
Active SAM1000 Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 79
Table 2-58 Sensor No. 185 (0xB9) FT 4 Fan 2 12 V
Feature Raw Value/Description Interpreted Value
Sensor Name FT 4 Fan 2 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x63
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-59 Sensor No. 186 (0xBA) FT 4 Fan 2 VBias
Feature Raw Value/Description Interpreted Value
Sensor Name FT 4 Fan 2 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x63
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records Active SAM1000 Analog Sensors
80
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-60 Sensor No. 187 (0xBB) FT 5 Fan 1 12 V
Feature Raw Value/Description Interpreted Value
Sensor Name FT 5 Fan 1 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x64
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-61 Sensor No. 188 (0xBC) FT 5 Fan 1 VBias
Feature Raw Value/Description Interpreted Value
Sensor Name FT 5 Fan 1 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Table 2-59 Sensor No. 186 (0xBA) FT 4 Fan 2 VBias (continued)
Feature Raw Value/Description Interpreted Value
Active SAM1000 Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 81
Entity ID 0x1E Cooling Unit
Entity Instance 0x64
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-62 Sensor No. 189 (0xBD) FT 5 Fan 2 12 V
Feature Raw Value/Description Interpreted Value
Sensor Name FT 5 Fan 2 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x64
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-61 Sensor No. 188 (0xBC) FT 5 Fan 1 VBias (continued)
Feature Raw Value/Description Interpreted Value
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records Active SAM1000 Analog Sensors
82
Table 2-63 Sensor No. 190 (0xBE) FT 5 Fan 2 VBias
Feature Raw Value/Description Interpreted Value
Sensor Name FT 5 Fan 2 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x64
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-64 Sensor No. 191 (0xBF) FT 6 Fan 1 12 V
Feature Raw Value/Description Interpreted Value
Sensor Name FT 6 Fan 1 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x65
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Active SAM1000 Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 83
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-65 Sensor No. 192 (0xC0) FT 6 Fan 1 VBias
Feature Raw Value/Description Interpreted Value
Sensor Name FT 6 Fan 1 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x65
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds are
Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-66 Sensor No. 193 (0xC1) FT 6 Fan 2 12 V
Feature Raw Value/Description Interpreted Value
Sensor Name FT 6 Fan 2 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Table 2-64 Sensor No. 191 (0xBF) FT 6 Fan 1 12 V (continued)
Feature Raw Value/Description Interpreted Value
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records Active SAM1000 Analog Sensors
84
Entity ID 0x1E Cooling Unit
Entity Instance 0x65
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-67 Sensor No. 194 (0xC2) FT 6 Fan 2 VBias
Feature Raw Value/Description Interpreted Value
Sensor Name FT 6 Fan 2 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x65
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-66 Sensor No. 193 (0xC1) FT 6 Fan 2 12 V (continued)
Feature Raw Value/Description Interpreted Value
Active SAM1000 Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 85
Table 2-68 Sensor No. 195 (0xC3) FT 7 Fan 1 +12V
Feature Raw Value/Description Interpreted Value
Sensor Name FT 7 Fan 1 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x66
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds are
Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-69 Sensor No. 196 (0xC4) FT 7 Fan 1 VBias
Feature Raw Value/Description Interpreted Value
Sensor Name FT 7 Fan 1 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x66
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records Active SAM1000 Analog Sensors
86
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-70 Sensor No. 197 (0xC5) FT 7 Fan 2 12 V
Feature Raw Value/Description Interpreted Value
Sensor Name FT 7 Fan 2 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x66
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-71 Sensor No. 198 (0xC6) FT 7 Fan 2 VBias
Feature Raw Value/Description Interpreted Value
Sensor Name FT 7 Fan 2 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Table 2-69 Sensor No. 196 (0xC4) FT 7 Fan 1 VBias (continued)
Feature Raw Value/Description Interpreted Value
Active SAM1000 Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 87
Entity ID 0x1E Cooling Unit
Entity Instance 0x66
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-72 Sensor No. 199 (0xC7) FT 8 Fan 1 12 V
Feature Raw Value/Description Interpreted Value
Sensor Name FT 8 Fan 1 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x67
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds are
Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-71 Sensor No. 198 (0xC6) FT 7 Fan 2 VBias (continued)
Feature Raw Value/Description Interpreted Value
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records Active SAM1000 Analog Sensors
88
Table 2-73 Sensor No. 200 (0xC8) FT 8 Fan 1 VBias
Feature Raw Value/Description Interpreted Value
Sensor Name FT 8 Fan 1 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x67
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-74 Sensor No. 201 (0xC9) FT 8 Fan 2 12 V
Feature Raw Value/Description Interpreted Value
Sensor Name FT 8 Fan 2 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x67
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Active SAM1000 Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 89
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-75 Sensor No. 202 (0xCA) FT 8 Fan 2 VBias
Feature Raw Value/Description Interpreted Value
Sensor Name FT 8 Fan 2 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x67
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-74 Sensor No. 201 (0xC9) FT 8 Fan 2 12 V (continued)
Feature Raw Value/Description Interpreted Value
Additional Fan Voltage sensors support the SAM used in the AXP1600 shelf.
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records Active SAM1000 Analog Sensors
90
Table 2-76 Sensor No. 203 (0xCB) FT 9 Fan 1 12 V, AXP1600
Feature Raw Value/Description Interpreted Value
Sensor Name FT 9 Fan 1 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x68
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds are
Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-77 Sensor No. 204 (0xCC) FT 9 Fan 1 VBias, AXP1600
Feature Raw Value/Description Interpreted Value
Sensor Name FT 9 Fan 1 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x68
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Active SAM1000 Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 91
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-78 Sensor No. 205 (0xCD) FT 9 Fan 2 12 V, AXP1600
Feature Raw Value/Description Interpreted Value
Sensor Name FT 9 Fan 2 12 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x68
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x50, 0x4c (6.88, 6.536) Volts
Upper critical and non-
recoverable thresholds
0x9F, 0xA0 (13.674, 13.76) Volts
Table 2-79 Sensor No. 206 (0xCE) FT 9 Fan 2 VBias, AXP1600
Feature Raw Value/Description Interpreted Value
Sensor Name FT 9 Fan 2 VBias
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Table 2-77 Sensor No. 204 (0xCC) FT 9 Fan 1 VBias, AXP1600 (continued)
Feature Raw Value/Description Interpreted Value
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records SAM Active Shelf Manager Discrete Sensors
92
2.4.6 SAM Active Shelf Manager Discrete Sensors
The active shelf managers at IPMB address 0x20 present the following discrete sensors:
zHot Swap Sensors
zShm Fault Event Sensor
zIPMB Link Sensor
zTelco Alarm Sensor
zBMC Watchdog Sensor
zSystem Event
zFan Tray Presence Sensor
zFan Tray -48 V Fuse Sensor
The following tables describe the discrete sensors available on the active SAM.
Entity ID 0x1E Cooling Unit
Entity Instance 0x68
Rearm mode Auto
Hysteresis support No
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable and Settable
threshold mask (bytes 19, 20)
0x36, 0x00 Upper and Lower Critical and
Non-recoverable Thresholds
are Readable
Reading Type Unsigned
Lower critical and non-
recoverable thresholds
0x73, 0x71 (9.89, 9.718) Volts
Upper critical and non-
recoverable thresholds
0x87, 0xA5 (11.61, 14.19) Volts
Table 2-79 Sensor No. 206 (0xCE) FT 9 Fan 2 VBias, AXP1600 (continued)
Feature Raw Value/Description Interpreted Value
SAM Active Shelf Manager Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 93
2.4.6.1 Hot Swap Sensors
The following table describes the discrete hot swap sensors available on the Active SAM.
Table 2-80 Sensor No. 0 (0x00) FRU 0 HOT_SWAP
Feature Raw Value/Description Interpreted Value
Sensor Name FRU 0 HOT_SWAP
Type of Measurement Hot Swap State of Main FRU
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF0 Hot Swap
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0xFF, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0xFF, 0x00 Supports 8 Successive States
Reading Definition According to PICMG 3.0
Table 2-81 Sensor No. 2 (0x02) FRU 1 HOT_SWAP
Feature Raw Value/Description Interpreted Value
Sensor Name FRU 1 HOT_SWAP
Type of Measurement Hot Swap State of Fan Tray 1
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF0 Hot Swap
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x60
Rearm mode Auto
Event message control Entire Sensor only
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records SAM Active Shelf Manager Discrete Sensors
94
Assertion Event Mask (bytes
15,16)
0xFF, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0xFF, 0x00 Supports 8 Successive States
Reading Definition According to PICMG 3.0
Table 2-82 Sensor No. 3 (0x03) FRU 2 HOT_SWAP
Feature Raw Value/Description Interpreted Value
Sensor Name FRU 2 HOT_SWAP
Type of Measurement Hot Swap State of Fan Tray 2
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF0 Hot Swap
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x61
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0xFF, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0xFF, 0x00 Supports 8 Successive States
Reading Definition According to PICMG 3.0
Table 2-83 Sensor No. 4 (0x04) FRU 3 HOT_SWAP
Feature Raw Value/Description Interpreted Value
Sensor Name FRU 3 HOT_SWAP
Type of Measurement Hot Swap State of Fan Tray 3
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF0 Hot Swap
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Table 2-81 Sensor No. 2 (0x02) FRU 1 HOT_SWAP (continued)
Feature Raw Value/Description Interpreted Value
SAM Active Shelf Manager Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 95
Entity Instance 0x62
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0xFF, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes 19,
20)
0xFF, 0x00 Supports 8 Successive States
Reading Definition According to PICMG 3.0
Table 2-84 Sensor No. 5 (0x05) FRU 4 HOT_SWAP
Feature Raw Value/Description Interpreted Value
Sensor Name FRU 4 HOT_SWAP
Type of Measurement Hot Swap State of Fan Tray 4
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF0 Hot Swap
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x63
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0xFF, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0xFF, 0x00 Supports 8 Successive States
Reading Definition According to PICMG 3.0
Table 2-85 Sensor No. 6 (0x06) FRU 5 HOT_SWAP
Feature Raw Value/Description Interpreted Value
Sensor Name FRU 5 HOT_SWAP
Type of Measurement Hot Swap State of Fan Tray 5
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Table 2-83 Sensor No. 4 (0x04) FRU 3 HOT_SWAP (continued)
Feature Raw Value/Description Interpreted Value
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records SAM Active Shelf Manager Discrete Sensors
96
Sensor Type 0xF0 Hot Swap
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x64
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0xFF, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0xFF, 0x00 Supports 8 Successive States
Reading Definition According to PICMG 3.0
Table 2-86 Sensor No. 7 (0x07) FRU 6 HOT_SWAP
Feature Raw Value/Description Interpreted Value
Sensor Name FRU 6 HOT_SWAP
Type of Measurement Hot Swap State of Fan Tray 6
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF0 Hot Swap
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x65
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0xFF, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0xFF, 0x00 Supports 8 Successive States
Reading Definition According to PICMG 3.0
Table 2-85 Sensor No. 6 (0x06) FRU 5 HOT_SWAP (continued)
Feature Raw Value/Description Interpreted Value
SAM Active Shelf Manager Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 97
Table 2-87 Sensor No. 8 (0x08) FRU 7 HOT_SWAP
Feature Raw Value/Description Interpreted Value
Sensor Name FRU 7 HOT_SWAP
Type of Measurement Hot Swap State of Fan Tray 7
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF0 Hot Swap
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x66
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0xFF, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0xFF, 0x00 Supports 8 Successive States
Reading Definition According to PICMG 3.0
Table 2-88 Sensor No. 9 (0x09) FRU 8 HOT_SWAP
Feature Raw Value/Description Interpreted Value
Sensor Name FRU 8 HOT_SWAP
Type of Measurement Hot Swap State of Fan Tray 8
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF0 Hot Swap
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x67
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0xFF, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0xFF, 0x00 Supports 8 Successive States
Reading Definition According to PICMG 3.0
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records SAM Active Shelf Manager Discrete Sensors
98
2.4.6.2 Shm Fault Event Sensor
The following table describes the discrete Shm Fault Event sensor available on the Active SAM.
A FRU 9 Hot Swap sensor supports the SAM used in the AXP1600 shelf.
Table 2-89 Sensor No. 10 (0x0A) FRU 9 HOT_SWAP, AXP1600
Feature Raw Value/Description Interpreted Value
Sensor Name FRU 8 HOT_SWAP
Type of Measurement Hot Swap State of Fan Tray 8
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF0 Hot Swap
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x68
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0xFF, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0xFF, 0x00 Supports 8 Successive States
Reading Definition According to PICMG 3.0
Table 2-90 Sensor No. 11 (0x20) Fault Event Sensor
Feature Raw Value/Description Interpreted Value
Sensor Name Shm Fault Event
Type of Measurement Status of various classes of
software discovered faults in the
Shm
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xDE OEM-reserved
Sensor Owner LUN 0x00
SAM Active Shelf Manager Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 99
2.4.6.3 IPMB Link Sensor
The following table describes the discrete IPMB link sensors available on the Active SAM.
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0xFE 0x01
Deassertion Event Mask (bytes
17,18)
0xFE 0x01
Discrete Reading Mask (bytes
19, 20)
0xFE 0x01
Reading Definition According to Motorola XXX
Table 2-90 Sensor No. 11 (0x20) Fault Event Sensor (continued)
Feature Raw Value/Description Interpreted Value
Table 2-91 Sensor No. 12 (0x0B) IPMB LINK 1
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 1
Type of Measurement IPMB Link 1 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
FRU Information and Sensor Data Records SAM Active Shelf Manager Discrete Sensors
100
Table 2-92 Sensor No. 13 (0x0C) IPMB LINK 2
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 2
Type of Measurement IPMB Link 2 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-93 Sensor No. 14 (0x0D) IPMB LINK 3
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 3
Type of Measurement IPMB Link 3 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
SAM Active Shelf Manager Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 101
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-94 Sensor No. 15 (0x0E) IPMB LINK 4
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 4
Type of Measurement IPMB Link 4 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-95 Sensor No. 16 (0x0F) IPMB LINK 5
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 5
Type of Measurement IPMB Link 5 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Table 2-93 Sensor No. 14 (0x0D) IPMB LINK 3 (continued)
Feature Raw Value/Description Interpreted Value
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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102
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-96 Sensor No. 17 (0x10) IPMB LINK 6
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 6
Type of Measurement IPMB Link 6 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-95 Sensor No. 16 (0x0F) IPMB LINK 5 (continued)
Feature Raw Value/Description Interpreted Value
SAM Active Shelf Manager Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 103
Table 2-97 Sensor No. 18 (0x11) IPMB LINK 7
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 7
Type of Measurement IPMB Link 7 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-98 Sensor No. 19 (0x12) IPMB LINK 8
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 8
Type of Measurement IPMB Link 8 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-99 Sensor No. 20 (0x14) IPMB LINK 9
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 9
Type of Measurement IPMB Link 9 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-100 Sensor No. 21 (0x14) IPMB LINK 10
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 10
Type of Measurement IPMB Link 10 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Table 2-98 Sensor No. 19 (0x12) IPMB LINK 8 (continued)
Feature Raw Value/Description Interpreted Value
SAM Active Shelf Manager Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 105
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-101 Sensor No. 22 (0x15) IPMB LINK 11
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 11
Type of Measurement IPMB Link 11 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-100 Sensor No. 21 (0x14) IPMB LINK 10 (continued)
Feature Raw Value/Description Interpreted Value
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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106
Table 2-102 Sensor No. 23 (0x16) IPMB LINK 12
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 12
Type of Measurement IPMB Link 12 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-103 Sensor No. 24 (0x17) IPMB LINK 13
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 13
Type of Measurement IPMB Link 13 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
SAM Active Shelf Manager Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 107
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-104 Sensor No. 25 (0x18) IPMB LINK 14
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 14
Type of Measurement IPMB Link 14 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-103 Sensor No. 24 (0x17) IPMB LINK 13 (continued)
Feature Raw Value/Description Interpreted Value
Additional IPMB LINK sensors support the SAM used in the AXP1600 shelf.
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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108
Table 2-105 Sensor No. 26 (0x19) IPMB LINK 15, AXP1600
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 15
Type of Measurement IPMB Link 14 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-106 Sensor No. 27 (0x1A) IPMB LINK 16, AXP1600
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 16
Type of Measurement IPMB Link 14 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
SAM Active Shelf Manager Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 109
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-107 Sensor No. 28 (0x1B) IPMB LINK 17
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 17
Type of Measurement IPMB Link 17 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-108 Sensor No. 29 (0x1C) IPMB LINK 18, AXP1600
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 18
Type of Measurement IPMB Link 17 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Table 2-106 Sensor No. 27 (0x1A) IPMB LINK 16, AXP1600 (continued)
Feature Raw Value/Description Interpreted Value
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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110
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-109 Sensor No. 30 (0x1D) IPMB LINK 19, AXP1600
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 19
Type of Measurement IPMB Link 17 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-108 Sensor No. 29 (0x1C) IPMB LINK 18, AXP1600 (continued)
Feature Raw Value/Description Interpreted Value
SAM Active Shelf Manager Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 111
Table 2-110 Sensor No. 31 (0x1E) IPMB LINK 20, AXP1600
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 20
Type of Measurement IPMB Link 17 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-111 Sensor No. 32 (0x1F) IPMB LINK 21, AXP1600
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB LINK 21
Type of Measurement IPMB Link 17 State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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112
2.4.6.4 Telco Alarm Sensor
The following table describes the discrete Telco alarm sensor available on the Active SAM.
Further information on this sensor can be found at Telco Alarms (Pigeon Point OEM) on page
137.
Assertion Event Mask (bytes
15,16)
0x0F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
Table 2-111 Sensor No. 32 (0x1F) IPMB LINK 21, AXP1600 (continued)
Feature Raw Value/Description Interpreted Value
Table 2-112 Sensor No. 131 (0x83) TELCO Alarms
Feature Raw Value/Description Interpreted Value
Sensor Name TELCO Alarms
Type of Measurement State of the TELCO Alarms
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xDF OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x00, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x07, 0x00 OEM States
Reading Definition According to Pigeon Point
SAM Active Shelf Manager Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 113
2.4.6.5 BMC Watchdog Sensor
The following table describes the discrete BMC Watchdog sensor available on the Active SAM.
2.4.6.6 System Event
The following table describes the discrete system event sensor available on the Active SAM.
Table 2-113 Sensor No. 132 (0x84) BMC Watchdog
Feature Raw Value/Description Interpreted Value
Sensor Name BMC Watchdog
Type of Measurement State of the BMC Watchdog on
the Active SAM
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0x23 IPMI Watchdog 2
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x0F, 0x01
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x0F, 0x01 Supports 5 States
Reading Definition According to IPMI 1.5
Table 2-114 Sensor No. 133 (0x85) SYSTEM EVENT
Feature Raw Value/Description Interpreted Value
Sensor Name System Event
Type of Measurement Presence
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0x12 System Event
Sensor Owner LUN 0x00
Entity ID 0xF0 PICMG Shelf Management
Controller
Entity Instance 0x01
Rearm mode Auto
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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114
2.4.6.7 Fan Tray Presence Sensor
The following table describes the discrete fan tray presence sensor available on the Active
SAM.
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x1F, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x1F, 0x00 Supports 5 Successive States
Reading Definition According to IPMI 1.5
Table 2-114 Sensor No. 133 (0x85) SYSTEM EVENT (continued)
Feature Raw Value/Description Interpreted Value
Table 2-115 Sensor No. 220 (0xDC) Fan Tray 1
Feature Raw Value/Description Interpreted Value
Sensor Name Fan Tray 1
Type of Measurement Fan Tray 1 Presence
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0x25 Entity Presence
Sensor Owner LUN 0x00
Entity ID 0x1E 0x1E
Entity Instance 0x60
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask(bytes
15,16)
0x03, 0x00
Deassertion Event Mask(bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
SAM Active Shelf Manager Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 115
Table 2-116 Sensor No. 221 (0xDD) Fan Tray 2
Feature Raw Value/Description Interpreted Value
Sensor Name Fan Tray 2
Type of Measurement Fan Tray 2 Presence
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0x25 Entity Presence
Sensor Owner LUN 0x00
Entity ID 0x1E 0x1E
Entity Instance 0x61
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask(bytes
15,16)
0x03, 0x00
Deassertion Event Mask(bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
Table 2-117 Sensor No. 222 (0xDE) Fan Tray 3
Feature Raw Value/Description Interpreted Value
Sensor Name Fan Tray 3
Type of Measurement Fan Tray 3 Presence
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0x25 Entity Presence
Sensor Owner LUN 0x00
Entity ID 0x1E 0x1E
Entity Instance 0x62
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask(bytes
15,16)
0x03, 0x00
Deassertion Event Mask(bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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Table 2-118 Sensor No. 223 (0xDF) Fan Tray 4
Feature Raw Value/Description Interpreted Value
Sensor Name Fan Tray 4
Type of Measurement Fan Tray 4 Presence
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0x25 Entity Presence
Sensor Owner LUN 0x00
Entity ID 0x1E 0x1E
Entity Instance 0x63
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask(bytes
15,16)
0x03, 0x00
Deassertion Event Mask(bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
Table 2-119 Sensor No. 224 (0xE0) Fan Tray 5
Feature Raw Value/Description Interpreted Value
Sensor Name Fan Tray 5
Type of Measurement Fan Tray 5 Presence
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0x25 Entity Presence
Sensor Owner LUN 0x00
Entity ID 0x1E 0x1E
Entity Instance 0x64
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask(bytes
15,16)
0x03, 0x00
Deassertion Event Mask(bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
SAM Active Shelf Manager Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 117
Table 2-120 Sensor No. 225 (0xE1) Fan Tray 6
Feature Raw Value/Description Interpreted Value
Sensor Name Fan Tray 6
Type of Measurement Fan Tray 6 Presence
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0x25 Entity Presence
Sensor Owner LUN 0x00
Entity ID 0x1E 0x1E
Entity Instance 0x65
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask(bytes
15,16)
0x03, 0x00
Deassertion Event Mask(bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
Table 2-121 Sensor No. 226 (0xE2) Fan Tray 7
Feature Raw Value/Description Interpreted Value
Sensor Name Fan Tray 7
Type of Measurement Fan Tray 7 Presence
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0x25 Entity Presence
Sensor Owner LUN 0x00
Entity ID 0x1E 0x1E
Entity Instance 0x66
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask(bytes
15,16)
0x03, 0x00
Deassertion Event Mask(bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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Table 2-122 Sensor No. 227 (0xE3) Fan Tray 8
Feature Raw Value/Description Interpreted Value
Sensor Name Fan Tray 8
Type of Measurement Fan Tray 8 Presence
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0x25 Entity Presence
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x67
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x03, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
An additional Fan Tray Presence sensor supports the SAM used in the AXP1600 shelf.
Table 2-123 Sensor No. 228 (0xE4) Fan Tray 9, AXP1600
Feature Raw Value/Description Interpreted Value
Sensor Name Fan Tray 9
Type of Measurement Fan Tray 8 Presence
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0x25 Entity Presence
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x68
Rearm mode Auto
Event message control Entire Sensor only
SAM Active Shelf Manager Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 119
2.4.6.8 Fan Tray -48 V Fuse Sensor
The following tables describes the discrete fan tray -48 V fuse sensors available on the Active
SAM. For further information on these sensors, refer to FT -48 V Fuse (Emerson OEM) on page
139.
Assertion Event Mask (bytes
15,16)
0x03, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
Table 2-123 Sensor No. 228 (0xE4) Fan Tray 9, AXP1600 (continued)
Feature Raw Value/Description Interpreted Value
Table 2-124 Sensor No. 230 (0xE6) FT 1 -48 V Fuse
Feature Raw Value/Description Interpreted Value
Sensor Name FT 1 -48V Fuse
Type of Measurement State of Fuse
Class Discrete
Event/Reading Type 0x03 'digital' Discrete
Sensor Type 0xC0 OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x60
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x02, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to Pigeon Point
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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Table 2-125 Sensor No. 231 (0xE7) FT 2 -48 V Fuse
Feature Raw Value/Description Interpreted Value
Sensor Name FT 2 -48 V Fuse
Type of Measurement State of Fuse
Class Discrete
Event/Reading Type 0x03 'digital' Discrete
Sensor Type 0xC0 OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x61
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x02, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to Pigeon Point
Table 2-126 Sensor No. 233 (0xE9) FT 4 -48 V Fuse
Feature Raw Value/Description Interpreted Value
Sensor Name FT 4 -48 V Fuse
Type of Measurement State of Fuse
Class Discrete
Event/Reading Type 0x03 'digital' Discrete
Sensor Type 0xC0 OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x63
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x02, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to Pigeon Point
SAM Active Shelf Manager Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 121
Table 2-127 Sensor No. 232 (0xE8) FT 3 -48 V Fuse
Feature Raw Value/Description Interpreted Value
Sensor Name FT 3 -48 V Fuse
Type of Measurement State of Fuse
Class Discrete
Event/Reading Type 0x03 'digital' Discrete
Sensor Type 0xC0 OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x62
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x02, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to Pigeon Point
Table 2-128 Sensor No. 234 (0xEA) FT 5 -48 V Fuse
Feature Raw Value/Description Interpreted Value
Sensor Name FT 5 -48 V Fuse
Type of Measurement State of Fuse
Class Discrete
Event/Reading Type 0x03 'digital' Discrete
Sensor Type 0xC0 OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x64
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x02, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to Pigeon Point
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Table 2-129 Sensor No. 235 (0xEB) FT 6 -48 V Fuse
Feature Raw Value/Description Interpreted Value
Sensor Name FT 6 -48 V Fuse
Type of Measurement State of Fuse
Class Discrete
Event/Reading Type 0x03 'digital' Discrete
Sensor Type 0xC0 OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x65
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x02, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to Pigeon Point
Table 2-130 Sensor No. 236 (0xEC) FT 7 -48 V Fuse
Feature Raw Value/Description Interpreted Value
Sensor Name FT 7 -48 V Fuse
Type of Measurement State of Fuse
Class Discrete
Event/Reading Type 0x03 'digital' Discrete
Sensor Type 0xC0 OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x66
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x02, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to Pigeon Point
SAM Active Shelf Manager Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 123
Table 2-131 Sensor No. 237 (0xED) FT 8 -48 V Fuse
Feature Raw Value/Description Interpreted Value
Sensor Name FT 8 -48 V Fuse
Type of Measurement State of Fuse
Class Discrete
Event/Reading Type 0x03 'digital' Discrete
Sensor Type 0xC0 OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x67
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x02, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to Pigeon Point
An additional -48 V Fuse sensor supports the SAM used in the AXP1600 shelf.
Table 2-132 Sensor No. 238 (0xEE) FT9 -48 V Fuse, AXP1600
Feature Raw Value/Description Interpreted Value
Sensor Name FT 9 -48 V Fuse
Type of Measurement State of Fuse
Class Discrete
Event/Reading Type 0x03 'digital' Discrete
Sensor Type 0xC0 OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0x1E Cooling Unit
Entity Instance 0x68
Rearm mode Auto
Event message control Entire Sensor only
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124
2.5 Power Entry Module Sensor Data Records
This section describes in detail all available IPMI sensors of the Power Entry Module.
2.5.1 PEM FRU Information
There are two PEMs; one at IPMB address 0x66 and another at IPMB address 0x68. The main
FRU (FRU 0) contains the FRU information of the PEM and it is the same for both PEMs (except
for the serial number). FRU 1 contains the FRU information that the Active SAM caches as FRU
254 of IPMB address 0x20.
The FRU 0 information in a PEM1000 is represented in the next table.
Pigeon Point Shelf Manager Command Line Interpreter
66: FRU # 0, FRU Info
Common Header: Format Version = 1
Board Info Area:
Version = 1
Language Code = 25
Mfg Date/Time = Jan 1 00:00:00 2006 (5260320 minutes since 1996)
Board Manufacturer = Motorola
Board Product Name = PEM1000
Board Serial Number = 1234567890
Board Part Number = 01-W2330F11A
FRU Programmer File ID = PEM1000R.inf
Product Info Area:
Version = 1
Language Code = 25
Assertion Event Mask (bytes
15,16)
0x02, 0x00
Deassertion Event Mask (bytes
17,18)
0x00, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 Successive States
Reading Definition According to Pigeon Point
Table 2-132 Sensor No. 238 (0xEE) FT9 -48 V Fuse, AXP1600 (continued)
Feature Raw Value/Description Interpreted Value
E-Keying FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 125
Manufacturer Name = Motorola
Product Name = AXP Power Entry Module
Product Part / Model# = PEM1000
Product Version = Rev. 01
Product Serial Number = 1234567890
Asset Tag =
FRU Programmer File ID = PEM1000R.inf
2.5.2 E-Keying
The Power Entry Module does not have e-keyed backplane interfaces, and as a result the FRU
information for the PEM does not contain a PICMG Point-to-Point Connectivity Record.
2.5.3 Power Configuration
The next table describes the power configuration for the PEMs.
Table 2-133 Power Configuration for PEMs
Item Value Description
Dynamic power reconfiguration support No Possibility to change FRU power
consumption without switching it off,
according to AdvancedTCA
Dynamic power configuration No Are the power draw levels fixed or these
may vary if additional components are
hot inserted or onboard component
power consumption is changing
dynamically
Number of power draw levels 1 The amount of possible power levels,
normally 1
Early power draw levels, watt 0.1 Complete early power level including
IPMC
Steady state power draw levels, watt 0.1 Complete steady power consumption
including IPMC
Transition from early to steady levels in seconds 0 How long does board consume early
power. Early power is normally bigger
than steady power
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126
2.5.4 Power Entry Module Sensor Overview
The following table lists all IPMI sensors available on the Power Entry Module.
2.5.5 Power Entry Module Analog Sensors
The analog sensors available on the PEM can be divided into the following four categories:
zVoltage Sensors
zCurrent Sensor
zTemperature Sensor
Table 2-134 IPMI Sensors on the PEM
Sensor
No. Sensor Name
Type of
Measurement
What does it
measure?
Sensor
Type Availability
0 Hot Swap Status State of FRU Discrete Always
1 IPMB Physical Status State of IPMB link Discrete Always
2 +3.3 V Voltage Analog Always
3 +8 V Backup Out Voltage Analog Always
4 +12 V Backplane Voltage Analog Always
5 CB 1 Status Circuit Breaker fuse
state
OEM-
reserved
Always
6 CB 2 Status Circuit Breaker fuse
state
OEM-
reserved
Always
7 CB 3 Status Circuit Breaker fuse
state
OEM-
reserved
Always
8 CB 4 Status Circuit Breaker fuse
state
OEM-
reserved
Always
9 CB 5 Status Circuit Breaker fuse
state
OEM-
reserved
Always
10 DS75 Temp Temperature Analog Always
11 +48.0 V FEED Voltage Analog Always
12 +7.5 V PEM Voltage Analog Always
13 +8 V PEM Feed 2 Voltage Analog Always
14 +12 V Current Current Analog Always
15 +8 V PEM Feed 1 Voltage Analog Always
Power Entry Module Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 127
2.5.5.1 Voltage Sensors
The following sensors measure voltages of the PEM.
Table 2-135 Sensor No. 2 +3.3 V
Feature Raw Value/Description Interpreted Value
Sensor Name +3.3 V
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x0A Power Supply
Entity Instance 0x60
Rearm mode Auto
Hysteresis support Readable/Settable
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable threshold mask,
Settable threshold mask (bytes
19, 20)
0x3F, 0x3F Upper and Lower Non-Critical,
Critical and Non-Recoverable
Thresholds are Readable and
Settable
Reading Type Unsigned
Lower Non-Critical, Critical and
Non-Recoverable thresholds
0xD8, 0xD4, 0xD1 (3.1104, 2.0528, 3.0096) Volts
Upper Non-Critical, Critical and
Non-Recoverable thresholds
0xF4, 0xF7, 0xFA (3.5136, 3.5568, 3.6) Volts
Table 2-136 Sensor No. 3 +8 V
Feature Raw Value/Description Interpreted Value
Sensor Name +8 V Backup Out
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x0A Power Supply
Entity Instance 0x60
Rearm mode Auto
Hysteresis support Readable/Settable
Threshold access support Readable/Settable
Event message control Entire Sensor only
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128
Readable threshold mask,
Settable threshold mask (bytes
19, 20)
0x3F, 0x3F Upper and Lower Non-Critical,
Critical and Non-Recoverable
Thresholds are Readable and
Settable
Reading Type Unsigned
Lower Non-Critical, Critical and
Non-Recoverable thresholds
0x87, 0x7D, 0x74 (7.02, 6.5, 6.032) Volts
Upper Non-Critical, Critical and
Non-Recoverable thresholds
0xAE, 0xB7, 0xC1 (0.048, 9.516, 10.036) Volts
Table 2-137 Sensor No. 4 +12 V Backplane
Feature Raw Value/Description Interpreted Value
Sensor Name +12 V Backplane
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x0A Power Supply
Entity Instance 0x60
Rearm mode Auto
Hysteresis support Readable/Settable
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable threshold mask,
Settable threshold mask (bytes
19, 20)
0x3F, 0x3F Upper and Lower Non-Critical,
Critical and Non-Recoverable
Thresholds are Readable and
Settable
Reading Type Unsigned
Lower Non-Critical, Critical and
Non-Recoverable thresholds
0xD4, 0xCA, 0xC1 (11.024, 10.504, 10.036) Volts
Upper Non-Critical, Critical and
Non-Recoverable thresholds
0xFA, 0xFF, 0xFF (13, 13.26, 13.26) Volts
Table 2-138 Sensor No. 11 +48.0 V Feed
Feature Raw Value/Description Interpreted Value
Sensor Name +48.0 V FEED
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Table 2-136 Sensor No. 3 +8 V (continued)
Feature Raw Value/Description Interpreted Value
Power Entry Module Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 129
Sensor Owner LUN 0x00
Entity ID 0x0A Power Supply
Entity Instance 0x60
Rearm mode Auto
Hysteresis support Readable/Settable
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable threshold mask,
Settable threshold mask (bytes
19, 20)
0x3F, 0x3F Upper and Lower Non-Critical,
Critical and Non-Recoverable
Thresholds are Readable and
Settable
Reading Type Unsigned
Lower Non-Critical, Critical and
Non-Recoverable thresholds
0x86, 0x7A, 0x73 (42.076, 38.308, 36.11) Volts
Upper Non-Critical, Critical and
Non-Recoverable thresholds
0xE6, 0xEF, 0xF3 (72.22, 75.046, 76.302) Volts
Table 2-139 Sensor No. 12 +7.5 V PEM
Feature Raw Value/Description Interpreted Value
Sensor Name +7.5 V PEM
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x0A Power Supply
Entity Instance 0x60
Rearm mode Auto
Hysteresis support Readable/Settable
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable threshold mask,
Settable threshold mask (bytes
19, 20)
0x3F, 0x3F Upper and Lower Non-Critical,
Critical and Non-Recoverable
Thresholds are Readable and
Settable
Reading Type Unsigned
Lower Non-Critical, Critical and
Non-Recoverable thresholds
0x7D, 0x74, 0x6A (6.5, 6.032, 5.512) Volts
Upper Non-Critical, Critical and
Non-Recoverable thresholds
0xA4, 0xAE, 0xB7 (8.528, 9.048, 9.516) Volts
Table 2-138 Sensor No. 11 +48.0 V Feed (continued)
Feature Raw Value/Description Interpreted Value
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130
Table 2-140 Sensor No. 13 +8 V PEM Feed 2
Feature Raw Value/Description Interpreted Value
Sensor Name +8 V PEM Feed 2
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x0A Power Supply
Entity Instance 0x60
Rearm mode Auto
Hysteresis support Readable/Settable
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable threshold mask,
Settable threshold mask (bytes
19, 20)
0x3F, 0x3F Upper and Lower Non-Critical,
Critical and Non-Recoverable
Thresholds are Readable and
Settable
Reading Type Unsigned
Lower Non-Critical, Critical and
Non-Recoverable thresholds
0x87, 0x7D, 0x74 (7.02, 6.5, 6.032) Volts
Upper Non-Critical, Critical and
Non-Recoverable thresholds
0xAE, 0xB7, 0xC1 (9.048, 9.516, 10.036) Volts
Table 2-141 Sensor No. 15 +8 V PEM Feed 1
Feature Raw Value/Description Interpreted Value
Sensor Name +8 V PEM Feed 1
Device
Sensor Type 0x02 Voltage
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x0A Power Supply
Entity Instance 0x60
Rearm mode Auto
Hysteresis support Readable/Settable
Threshold access support Readable/Settable
Event message control Entire Sensor only
Power Entry Module Analog Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 131
2.5.5.2 Current Sensor
The following table describes the sensor that measures the +12V current on the PEM.
Readable threshold mask,
Settable threshold mask (bytes
19, 20)
0x3F, 0x3F Upper and Lower Non-Critical,
Critical and Non-Recoverable
Thresholds are Readable and
Settable
Reading Type Unsigned
Lower Non-Critical, Critical and
Non-Recoverable thresholds
0x87, 0x7D, 0x74 (7.02, 6.5, 6.032) Volts
Upper Non-Critical, Critical and
Non-Recoverable thresholds
0xAE, 0xB7, 0xC1 (9.048, 9.516, 10.036) Volts
Table 2-141 Sensor No. 15 +8 V PEM Feed 1 (continued)
Feature Raw Value/Description Interpreted Value
Table 2-142 Sensor No. 14 +12 V Current
Feature Raw Value/Description Interpreted Value
Sensor Name +12 V Current
Device
Sensor Type 0x03 Current
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x0A Power Supply
Entity Instance 0x60
Rearm mode Auto
Hysteresis support Readable/Settable
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable threshold mask,
Settable threshold mask (bytes
19, 20)
0x38, 0x38 Upper Non-Critical, Critical and
Non-Recoverable Thresholds
are Readable and Settable
Reading Type Unsigned
Upper Non-Critical, Critical and
Non-Recoverable thresholds
0x4A, 0x4E, 0x52 (9.028, 9.516, 10.004) Amps
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2.5.5.3 Temperature Sensor
The following tables describe the temperature sensors available on the PEMs.
2.5.6 Power Entry Module Discrete Sensors
The following tables describe these discrete sensors available on the PEM:
zHot Swap Sensor
zIPMB Link Sensor
zCircuit Breaker State Sensors
2.5.6.1 Hot Swap Sensor
The following table describes the discrete hot swap sensor available on the PEM.
Table 2-143 Sensor No. 10 DS75 Temp
Feature Raw Value/Description Interpreted Value
Sensor Name DS75 Temp
Device
Sensor Type 0x01 Temperature
Class 0x01 Threshold
Sensor Owner LUN 0x00
Entity ID 0x0A Power Supply
Entity Instance 0x60
Rearm mode Auto
Hysteresis support Readable/Settable
Threshold access support Readable/Settable
Event message control Entire Sensor only
Readable threshold mask,
Settable threshold mask (bytes
19, 20)
0x38, 0x38 Upper Non-Critical, Critical and
Non-Recoverable Thresholds
are Readable and Settable
Reading Type Unsigned
Upper Non-Critical, Critical and
Non-Recoverable thresholds
0x28, 0x3C, 0x50 (40, 60, 80) Centigrades
Table 2-144 Sensor #0, Hot Swap
Feature Raw Value/Description Interpreted Value
Sensor Name Hot Swap
Type of Measurement Hot Swap State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Power Entry Module Discrete Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 133
2.5.6.2 IPMB Link Sensor
The following table describes the IPMB link sensor on the PEMs.
Sensor Type 0xF0 Hot Swap
Sensor Owner LUN 0x00
Entity ID 0x0A Power Supply
Entity Instance 0x60
Rearm Mode Auto
Event Message Control Entire Sensor Only
Assertion Event Mask (byte 15, 16) 0xFF, 0x00
Deassertion Event Mask (byte 17, 18) 0x00, 0x00
Discrete Reading Mask (byte 19, 20) 0xFF, 0x00 Supports 8 Successive States
Reading Definition According to PICMG 3.0
Table 2-144 Sensor #0, Hot Swap (continued)
Feature Raw Value/Description Interpreted Value
Table 2-145 Sensor #1, IPMB Physical
Feature Raw Value/Description Interpreted Value
Sensor Name IPMB Physical
Type of Measurement IPMB Link State
Class Discrete
Event/Reading Type 0x6F Sensor-specific
Sensor Type 0xF1 IPMB Link
Sensor Owner LUN 0x00
Entity ID 0x0A
Entity Instance 0x60
Rearm Mode Auto
Event Message Control Entire Sensor Only
Assertion Event Mask (byte 15, 16) 0x0F, 0x00
Deassertion Event Mask (byte 17, 18) 0x00, 0x00
Discrete Reading Mask (byte 19, 20) 0x0F, 0x00 Supports 4 Successive States
Reading Definition According to PICMG 3.0
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134
2.5.7 Circuit Breaker State Sensors
The following tables describe the OEM circuit breaker state sensors available on the PEM.
Table 2-146 Sensor #5, CB 1
Feature Raw Value/Description Interpreted Value
Sensor Name CB 1
Type of Measurement Monitors if the circuit breaker
has been opened.l
Class Discrete
Event/Reading Type 0x03 Digital Discrete
Sensor Type 0xC0 OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0x0A Power Supply
Entity Instance 0x60
Rearm Mode Auto
Event Message Control Entire Sensor only
Assertion Event Mask (byte 15, 16) 0x02, 0x00
Deassertion Event Mask (byte 17, 18) 0x02, 0x00
Discrete Reading Mask (byte 19, 20) 0x03, 0x00 Supports 2 States
Reading Definition According to Pigeon Point
Table 2-147 Sensor #6 CB 2
Feature Raw Value/Description Interpreted Value
Sensor Name CB 2
Type of Measurement Monitors if the circuit breaker
has been opened.l
Class Discrete
Event/Reading Type 0x03 Digital Discrete
Sensor Type 0xC0 OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0x0A Power Supply
Entity Instance
Rearm Mode Auto
Event Message Control Discrete State Event
Enable/Disable
Circuit Breaker State Sensors FRU Information and Sensor Data Records
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 135
Assertion Event Mask (byte 15, 16) 0x02, 0x00 State Deasserted
State Asserted
Deassertion Event Mask (byte 17, 18) 0x02, 0x00 State Deasserted
State Asserted
Discrete Reading Mask (byte 19, 20) 0x03, 0x00 Supports 2 Successive States
Reading Definition According to IPMI 1.5
Table 2-148 Sensor No. 7 CB 3
Feature Raw Value/Description Interpreted Value
Sensor Name CB 3
Type of Measurement Monitors if the Circuit Breaker
has been opened.
Class Discrete
Event/Reading Type 0x03 'digital' Discrete
Sensor Type 0xC0 OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0x0A Power Supply
Entity Instance 0x60
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x02, 0x00
Deassertion Event Mask (bytes
17,18)
0x02, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 States
Reading Definition According to Pigeon Point
Table 2-149 Sensor No. 8 CB 4
Feature Raw Value/Description Interpreted Value
Sensor Name CB 4
Type of Measurement Monitors if the Circuit Breaker
has been opened.
Class Discrete
Event/Reading Type 0x03 'digital' Discrete
Sensor Type 0xC0 OEM-reserved
Sensor Owner LUN 0x00
Table 2-147 Sensor #6 CB 2 (continued)
Feature Raw Value/Description Interpreted Value
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136
Entity ID 0x0A Power Supply
Entity Instance 0x60
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x02, 0x00
Deassertion Event Mask (bytes
17,18)
0x02, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 States
Reading Definition According to Pigeon Point
Table 2-150 Sensor No. 9 CB 5
Feature Raw Value/Description Interpreted Value
Sensor Name CB 5
Type of Measurement Monitors if the Circuit Breaker
has been opened.
Class Discrete
Event/Reading Type 0x03 'digital' Discrete
Sensor Type 0xC0 OEM-reserved
Sensor Owner LUN 0x00
Entity ID 0x0A Power Supply
Entity Instance 0x60
Rearm mode Auto
Event message control Entire Sensor only
Assertion Event Mask (bytes
15,16)
0x02, 0x00
Deassertion Event Mask (bytes
17,18)
0x02, 0x00
Discrete Reading Mask (bytes
19, 20)
0x03, 0x00 Supports 2 States
Reading Definition According to Pigeon Point
Table 2-149 Sensor No. 8 CB 4 (continued)
Feature Raw Value/Description Interpreted Value
3
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 137
OEM Sensors
3.1 OEM Sensors
This section describes the various OEM sensors provided by Emerson and Pigeon Point
Systems that are located on the SAM.
zTelco Alarms (Pigeon Point OEM)
zAXP Backplane ID (Emerson OEM)
zPOST Results (Emerson OEM)
zShelf FRU Info (Emerson OEM)
zFT -48 V Fuse (Emerson OEM)
zShm Fault Event (Emerson OEM)
3.1.1 Telco Alarms (Pigeon Point OEM)
The ShM implements the alarm generation mechanism as part of the platform event filtering
(PEF) framework. An OEM action in PEF is implemented as alarm generation. The ShM
implements the alarm sensor in its own sensor space. The sensor type for this sensor is OEM
specific, currently chosen to be DFh. The sensor is a discrete sensor with three states:
zState 0 reflects the presence of the Critical alarm
zState 1 reflects the presence of the Major alarm
zState 2 reflects the presence of the Minor alarm
Changes in the states of this sensor may be mapped to events using regular IPMI mechanisms.
Subsequently, platform event filtering may be used to specify actions, such as chassis reset or
power cycle, that should be invoked for these events, or alerts to be sent to remote destinations
(including the System Manager).
The alarm sensor is recorded in the device SDR repository maintained by the ShM. The
command Re-Arm Sensor Events can be used by the ShM to clear active Major and Minor
alarms.
The ShM tracks the current state of alarms and the alarm cutoff input line and modifies the state
of alarm LEDs accordingly. When the alarm cutoff signal gets activated, the ShM stops
generating the alarms to the external output, but maintains the alarm state internally. The alarm
LED(s) is (are) left blinking during that time. When the alarm cutoff signal gets deactivated, the
state of external outputs and LEDs is restored according to the current state of the alarms
(Minor and Major alarms may still be cleared while alarm cutoff is active).
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
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138
Alarm cutoff is deactivated automatically after a timeout defined as a configuration parameter
(see PPS user guide for the Shmm 500 for more details about TELCO Alarms configuration
parameters).
3.1.2 AXP Backplane ID (Emerson OEM)
This sensor reports the ID number of the IPMB backplane type. The 1406 and 1600 contain a
readable value which reports a unique identifier of the backplane type. While the main purpose
of this sensor is to report the unique ID of the backplane, it can also be used to determine if a
SAM has connectivity problems to the backplane. This sensor is available on each physical
ShMM controller.
zSensor Reading - Unique identification number of the backplane
zCurrent State Mask - 0x00 = No failure reading ID
0x01 = ECC check failed on read value
zEvents - No events are generated by this sensor.
3.1.3 POST Results (Emerson OEM)
This sensor reports the results of the U-Boot POST tests. This sensor is available on each
physical ShMM controller. POST results are reported in an 8-bit bit-field. Any bit that is set (set
to 1) indicates that the respective POST failure occurred.
zSensor Reading - POST State in a 8-bit value according to the following mask definition:
Bit 7 - RTC
Bit 6 - Watchdog
Bit 5 - CRC
Bit 4 - Ethernet
Bit 3 - UART
Bit 2 - I2C
Bit 1 - Memory
Bit 0 - IPMB
zCurrent State Mask - 0x01 = POST Passed
0x02 = POST Failed
zEvents - Events are generated at shelf manager start up that will report failure events for
each individual test that fails as follows:
Event Data Byte 1 = 0x61
Event Data Byte 2 = 0x3F
POST Sensor Reading = Bit 0 (IPMB)
Bit 1 (Memory)
Bit 2 (I2C)
Bit 3 (UART)
Bit 4 (Ethernet)
Shelf FRU Info (Emerson OEM) OEM Sensors
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 139
Bit 5 (CRC)
Bit 6 (Watchdog)
Bit 7 (RTC)
3.1.4 Shelf FRU Info (Emerson OEM)
This sensor reports the validity of the Shelf FRU Information. This sensor is available on each
physical ShMM controller. The check it performs is basic checksum and length checks based
on information of previous sections of the FRU area; and key bytes that are expected to have
certain values.
zSensor Reading - 0x00 (meaningless since discrete sensor reading)
zCurrent State Mask - 0x01 Shelf FRU Info not found (Disabled)
0x02 Shelf FRU Info found (Enabled)
zEvents - Events are generated when the state of the FRU Info found state changes.
Event Data Byte 1 = 0x01 Shelf FRU Info not found (Disabled)
0x02 Shelf FRU Info found (Enabled)
Event Data Byte 2 = 0xFF (Unspecified)
Event Data Byte 3 = 0xFF (Unspecified)
3.1.5 FT -48 V Fuse (Emerson OEM)
This sensor reads the System Status Register of the respective Fan Tray and verifies if the bit
for 48 V input power OK is set. The 48 V input power ok bit is set if all input fuses are intact.
zSensor Reading - 0x00 (NULL Discrete sensor reading)
zCurrent State Mask - 0x01 (State Deasserted, all input fuses are intact)
0x02 (State Asserted, not all input fuses are intact)
zEvents - No events are generated by this sensor.
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
OEM Sensors Shm Fault Event (Emerson OEM)
140
3.1.6 Shm Fault Event (Emerson OEM)
This sensor reports the status of Fault Classes on the Active shelf. When the value is read it
indicates the presence or absence of each fault class. Currently defined fault classes relate to
the health of the FTMs in the shelf.
zSensor Reading - This is a 2-byte bit mask of active fault conditions detected by the sensor.
A '1' in any bit indicates the specified fault is active. Refer to the following table for fault
classes.
zCurrent State Mask - 0x1FE - mask of possible fault event bits
zEvents - For FTM-related faults, an event is generated when any FTM transitions into or
out of a fault condition. An event is flagged as an assertion event when at least one FTM
exhibits the fault class. It is flagged as a deassertion event when no FTMs remain with the
fault class.
Table 3-1 Shm Fault Classes
Fault
Class Meaning
0 Not used.
1 One or more fan trays are missing.
2 One or more fan trays' speed sensors are below critical threshold.
By default, all of a FTM's speed sensors must be below critical speed in order to declare a
fault at that FTM; however through a new configuration option in shelfman.conf, the
administrator can change the behavior to declare a fault if any speed sensor is critical.
3 One or more fan trays' speed sensors do not show significant increase when the active shelf
manager asserts FULL_SPEED signal as part of the Fan Tray Latent Fault Check algorithm.
(Active FULL_SPEED test)
4 One or more fan trays' speed sensors do not return to a normal speed following the release
of FULL_SPEED signal by the active shelf manager, as part of the Fan Tray Latent Fault
Check algorithm. (Active FULL_SPEED test)
5 One or more fan trays' speed sensors do not show significant increase when the redundant
shelf manager asserts FULL_SPEED signal as part of the Fan Tray Latent Fault Check
algorithm. (Redundant FULL_SPEED test)
6 One or more fan trays' speed sensors do not return to a normal speed following the release
of FULL_SPEED signal by the active shelf manager, as part of the Fan Tray Latent Fault
Check algorithm. (Redundant FULL_SPEED test)
7 One or more fan trays' speed sensors do not show significant increase when the active shelf
manager increases the speed level to its maximum value as part of the Fan Tray Latent
Fault Check algorithm. (PSOC LFC test)
8 One or more fan trays' speed sensors do not return to a normal speed following the lowering
of the speed level by the active shelf manager, as part of the Fan Tray Latent Fault Check
algorithm. (PSOC test)
A
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 141
ASystem Behavior in Response to
Sensor Events
A.1 Introduction
This chapter introduces important information for those who are developing their own
applications code, based on how the Centellis 3406 and 3600 system behaves to different
events.
A.2 Cooling Management in Normal Operation Mode
The Shelf Manager operates in normal mode with respect to cooling if no temperature sensor
in the shelf reports crossing of one of the upper thresholds (noncritical, critical or
nonrecoverable). In that case, there is no need to accelerate the fan speed.
On the contrary, the Shelf Manager in normal mode periodically reduces the fan speed by
FAN_LEVEL_STEP_DOWN* levels (once per COOLING_FAN_DECREASE_TIMEOUT*
seconds) until the fan speed reaches the minimum fan level or the shelf goes to abnormal mode
(with at least one of the temperature sensors reporting one of its upper thresholds crossed).
The minimum fan level is initially specified as a configuration parameter, but its value is
adjusted if the transition to the abnormal mode happens, in order to prevent subsequent
recurrence of the thermal alert.
A.3 Cooling Management in Abnormal Operation
Mode
The Shelf Manager operates in abnormal mode with respect to cooling if at least one
temperature sensor in the shelf reports crossing of one of the upper thresholds (noncritical,
critical or nonrecoverable). In that case, the Shelf Manager takes over the control of all fan
trays, including those that support local control mode, but excluding any fans for which the Get
Fan Level command reports that the fan is in 'Emergency Shut Down' mode. The Shelf
Manager raises the fan speed by FAN_LEVEL_STEP_UP* levels for every fan tray every
COOLING_FAN_INCREASE_TIMEOUT* seconds until the temperature reported by all
temperature sensors falls below the thresholds.
Additionally, when at least one critical temperature threshold has been exceeded, the Shelf
Manager starts reducing the power level of FRUs one level each COOLING_POLL_TIMEOUT*
seconds, if possible. FRUs are not powered down in that case, for example, SetPowerLevel(0)
is not issued. In that state, the Shelf Manager also immediately raises the level of all fans to the
maximum level and keeps it at maximum.
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
System Behavior in Response to Sensor Events Adaptive Adjustment of the Minimum Fan Level
142
When at least one nonrecoverable temperature threshold has been exceeded on a FRU, the
Shelf Manager powers down the FRU (sending them the SetPowerLevel(0) command) and
refuses to power the FRU back up for COOLING_POLL_TIMEOUT* seconds. In that state, the
Shelf Manager also immediately raises the level of all fans to the maximum level and keeps it
at maximum.
A.4 Adaptive Adjustment of the Minimum Fan Level
The Shelf Manager changes the minimum fan level over time to prevent oscillations of the shelf
between normal and abnormal cooling mode. When the shelf transitions from normal to
abnormal cooling mode, this means that the current fan level is insufficient for effective cooling
of the shelf. In that case, the Shelf Manager dynamically changes the minimum fan level to the
current level + 1, so that next time in normal mode the Shelf Manager will not try to decrease
the fan level so low. (In the case of multiple fans and different fan levels, the Shelf Manager
chooses the maximum current fan level.) This makes the algorithm to converge to a certain fan
level after several oscillations; at that level, the shelf operates in normal cooling mode and this
is the minimum possible fan level at which the shelf can operate in normal cooling mode.
To accommodate for possible changes in the thermal load in the shelf in a long run, an
additional enhancement is implemented. After the shelf stays in normal cooling mode at a
stable fan level for a substantial period of time (specified as a configuration parameter
NORMAL_STABLE_TIME*, with a default of 1 hour), the minimum fan level is decreased by
one and the current fan level is allowed to drop to the new minimum. If the thermal load in the
shelf has decreased, the shelf will continue to operate at the reduced fan level. Otherwise, the
shelf will transition to the abnormal cooling state and the fan level will converge to a new stable
value after several oscillations.
Adaptive Adjustment of the Minimum Fan Level System Behavior in Response to Sensor Events
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 143
The following graph illustrates the behavior of the above cooling algorithm in finding a stable
fan level in real shelf, in the presence of a substantial thermal load in the shelf. The
configuration parameter NORMAL_STABLE_TIME* is set to 30 minutes. The graph presents
the fan speed changes over a period of 70 minutes. The horizontal axis has time scaled from 0
to 70 minutes.
The fan speed is initially lowered to 3. This causes a thermal alert and after a single increase
in fan speed, during the subsequent fan speed reduction, the level stabilizes at 4. After the
expiration of a period defined by the parameter NORMAL_STABLE_TIME* (which is equal to
30 minutes) the level is lowered to 3 which again causes a thermal alert, an increase in fan
speed with subsequent reductions, and the fan level again stabilizes at 4.
* These are configurable options in /etc/shelfman.conf. If these values are not defined in
shelfman.conf, default levels are used.
Figure A-1 Cooling Algorithm
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
System Behavior in Response to Sensor Events FRU State Management
144
A.5 FRU State Management
The following table provides the SAM action, FRU status, hot swap state for each FRU
temperature sensor in the shelf.
Table A-1 FRU State Table for Nonrecoverable Threshold Events from Temperature Sensors
FRU Temperature Sensor SAM Action FRU Status
Step-1 Step-2 Operation
Hot Swap
State H/S LED
Active
SAM
Sensor # 6("MAX6656 INT
@1A")
Sensor # 7("MAX6656 EXT1
@1A")
Sensor # 8("MAX6656 EXT2
@1A")
Set all FAN-
module speed
MAX
H/S LED
ON. Still
working as
Active.
M6->M1
(Logical
SAM
(0x20) will
show M4
state)
Tur n O N
Standby
SAM
Sensor # 6("MAX6656 INT
@1A")
Sensor # 7("MAX6656 EXT1
@1A")
Sensor # 8("MAX6656 EXT2
@1A")
Set all FAN-
module speed
MAX
H/S LED
ON.
M6->M1 Turn ON
PEM Sensor # 12 ("DS75 Temp") Set all FAN-
module speed
MAX
Issue
"deactivate"
command to
PEM
Still working. M6 > M1 Turn ON
ATC A -
F101
Sensor # 8 ("Inlet Temp") Set all FAN-
module speed
MAX
Issue
"deactivate"
command to
F101
Payload
powered
down by the
SAM.
M6 > M1 Turn ON
Sensor # 9 ("Outlet Temp") Set all FAN-
module speed
MAX
Issue
"deactivate"
command to
F101
Payload
powered
down by the
SAM.
M6 > M1 Turn ON
Sensor # 10 ("PMC Temp") Set all FAN-
module speed
MAX
Issue
"deactivate"
command to
F101
Payload
powered
down by the
SAM.
M6 > M1 Turn ON
Sensor # 20 ("Artesyn Temp") Set all FAN-
module speed
MAX
Issue
"deactivate"
command to
F101
Payload
powered
down by the
SAM.
M6 > M1 Turn ON
FRU State Management System Behavior in Response to Sensor Events
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 145
ATC A -
7221
Sensor # 0
("BrdTempNearPMC")
Set all FAN-
module speed
MAX
Issue
"deactivate"
command to
7221
Payload
powered
down by the
SAM.
M6 > M1 Turn ON
Sensor # 1 ("Temp Near Mem ") Set all FAN-
module speed
MAX
Issue
"deactivate"
command to
7221
Payload
powered
down by the
SAM.
M6 > M1 Turn ON
Sensor # 2 ("Temp CPU 0") Set all FAN-
module speed
MAX
Issue
"deactivate"
command to
7221
Payload
powered
down by the
SAM.
M6 > M1 Turn ON
Sensor # 3 ("Temp CPU 1") Set all FAN-
module speed
MAX
Issue
"deactivate"
command to
7221
Payload
powered
down by the
SAM.
M6 > M1 Turn ON
Sensor # 6 ("Die Temp CPU 0") Set all FAN-
module speed
MAX
Issue
"deactivate"
command to
7221
Payload
powered
down by the
SAM.
M6 > M1 Turn ON
Sensor # 7 ("Die Temp CPU 1") Set all FAN-
module speed
MAX
Issu e
"deactivate"
command to
7221
Payload
powered
down by the
SAM.
M6 > M1 Turn ON
Sensor # 10 ("12V DCDC
Te m p. " )
Set all FAN-
module speed
MAX
Issue
"deactivate"
command to
7221
Payload
powered
down by the
SAM.
M6 > M1 Turn ON
Table A-1 FRU State Table for Nonrecoverable Threshold Events from Temperature Sensors (continued)
FRU Temperature Sensor SAM Action FRU Status
Step-1 Step-2 Operation
Hot Swap
State H/S LED
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
System Behavior in Response to Sensor Events FRU State Management
146
B
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C) 147
BRelated Documentation
B.1 Emerson Network Power - Embedded Computing
Documents
The Emerson Network Power - Embedded Computing publications listed below are referenced
in this manual. You can obtain electronic copies of Emerson Network Power - Embedded
Computing publications by contacting your local Emerson sales office. For documentation of
final released (GA) products, you can also visit the following website:
http://www.emersonnetworkpowerembeddedcomputing.com > Solution Services> Technical
Documentation Search. This site provides the most up-to-date copies of Emerson Network
Power - Embedded Computing product documentation.
Table B-1 Emerson Newtork Power - Embedded Computing Documents
Document Title Publication Number
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference 6806800B66
Centellis R2 (AXP1405) to R3 (AXP1406/AXP1600) Porting Reference 6806800C31
ATCA-F101-5E System Controller and Switching Blade Installation and
Use
6806800C15
ATCA-7221 Reference Guide 6806800A50
ATCA-7107 Reference Guide 6806800A48
ATCA-S100 Reference Guide 6806800A36
ATCA-F101 Basic Blade Service Software Release 3 6806800C12
ATCA-7221 Basic Blade Service Software Release 3 6806800C14
ATCA-F101 Basic Blade Service Software Release 3 6806800C13
Centellis 3406/3600 Release 3.0 Document Collection 6806800C29
Pigeon Point Shelf Manager External Interface Reference, Release 2.1.1 DOCSHMEXTINT
Pigeon Point IPM Sentry Shelf Manager User Guide, 2.1.1 DOCSHMUG
AXP1406/AXP1600 Subsystem IPMI Programmer’s Reference (6806800B66C)
Related Documentation Manufacturers’ Documents
148
B.2 Manufacturers’ Documents
For additional information, refer to the following table for manufacturers’ data sheets or user’s
manuals. As an additional help, a source for the listed document is provided. Please note that,
while these sources have been verified, the information is subject to change without notice.
B.3 Related Specifications
For additional information, refer to the following table for related specifications. As an additional
help, a source for the listed document is provided. Please note that, while these sources have
been verified, the information is subject to change without notice.
Table B-2 Manufacturers Documents
Document Title Web Site Source
IPM Sentry Shelf Manager User Guide http://www.emersonnetworkpowerembeddedcompu
ting.com
P/N DOCShMUG
IPM Sentry Shelf - External Interface
Reference, Release
http://www.emersonnetworkpowerembeddedcompu
ting.com
P/N DOCShMEXTINT
Table B-3 Related Specifications
Document Title Source
IPMI Specifications, http://www.intel.com/design/servers/ipmi
IPMI Spec v1.5, Document Revision 1.1, February 20, 2002 Intel Corporation, Hewlett-
Packard, DEC, NEC
IPMI v1.5 Addenda, Errata, and Clarifications, Addendum
Document Revision 5, January 29, 2004
Intel Corporation, Hewlett-
Packard, DEC, NEC
Intelligent Platform Management Interface Specification v1.0,
Document Revision 1.1, November 15 1999
Intel Corporation, Hewlett-
Packard, NEC, Dell
IPMI Implementer's Guide, Draft Version 0.7, September 16, 1998 Intel Corporation
IPMI Platform Management FRU Information Storage Definition
V1.0, September 27, 1999
Intel Corporation
PCI Industrial Manufacturers Group (PICMG) http://www.picmg.com/
AdvancedTCA Base 3.0 Specification, Revision 2.0 PICMG 3.0 R 2.0,Dated
03/18/05

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