AzureWave Technologies AM691NF IEEE 802.11 a/b/g/n Wireless LAN and Bluetooth Combo LGA Module User Manual AW AM691NF manual For FCC rev2

AzureWave Technologies, Inc. IEEE 802.11 a/b/g/n Wireless LAN and Bluetooth Combo LGA Module AW AM691NF manual For FCC rev2

User Manual.pdf

Download: AzureWave Technologies AM691NF IEEE 802.11 a/b/g/n Wireless LAN and Bluetooth Combo LGA Module User Manual AW AM691NF  manual For FCC rev2
Mirror Download [FCC.gov]AzureWave Technologies AM691NF IEEE 802.11 a/b/g/n Wireless LAN and Bluetooth Combo LGA Module User Manual AW AM691NF  manual For FCC rev2
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AW-AM691NF
IEEE 802.11
a/b/g/n
Wireless
LAN
and
IEEE
82.11 a/b/g/n
Wireless
LAN,
Bluetooth,
Bluetooth
Module
FMCombo
ComboLGA
Module
Demo Board User Guide
Document
release
Date
Version 0.1
2013/07/26
Modification
Initial Version
-1-
Initials
Approved
N.C. Chen
Chihhao Liao
Contents
1. Activate AW-AM634NF
1-1. What you need
1-2. Power-Up AW-AM634NF
1-3. Test Software Version
2. WLAN Basic Test
2-1. Driver Installation
2-2. Throughput Test
2-3. RF Tx/Rx Performance Test
3. Bluetooth Basic Test
3-1. Download Mini-driver
3-2. Throughput Test
3-3. RF Performance Test
4. Known Limitation/Issues
5. Demo board schematic
-2-
1. Activate AW-AM634NF
1-1. what you need
Hardware:
AW-AM691NF Demo Board V.01
SDIO to PCI Host Controller
USB-B type to A type Cable
Software (Windows XP):
Ubuntu 12.04 LTS
WLAN: firmware, nvram file, dhd.ko, wl.exe
Bluetooth: Bluetool V1.1.9.3, HCD HCI download file, ActivePerl 5.8 and driver for Prolific USB to
UART Bridge.
FIG. 1.1
-3-
1-2. Power UP AW-AM634NF
RF ANT port
SDIO
J4: VBAT In
VDDIO power select
UART to USB Bridge
B type USB Connector
FIG. 1.2
1-3. Test Software Version
Test Station
Item
Version
Remarks
WLAN
firmware
sdio-ag-mfgtest-seqcmds-autoabn.bin
6.10.185
nvram
AH691.NVRAM_20130605.txt
HCD File
BCM4324B3_002.004.006.0076.0081_RC.hcd
BT
BCM4324B3_002.004.006.0076.0082_RC.hcd
-4-
2. WLAN Basic Test
J5/J1 setting as below
Must connect USB to PC
2-1. Driver Installation
COMPONENTS
dhd.ko
dhd.ko is an utility application that one can use to control the software running in the dongle host for test and
debug purposes.
wl.exe
wl is an utility application that one can use to control the software running in the SDIO dongle, e.g. initiate an
association and modify WLAN parameters.
-5-
DRIVER INSTALLATION (IN LINUX)
•First prepare the Broadcom’s Linux package, and put it in the “home” folder.
•Open the Terminal, enter the command: sudo su and password.
•Enter cd /home/username/5.90.195.26.3/open-src/src/dhd/linux
•Enter make dhd-cdc-sdmmc-gpl to generate the dhd.ko file in
/home/username/5.90.195.26.3/open-src/src/dhd/linux/dhd-cdc-sdmmc-gpl-2.6.32-21-generic
•Enter
Insmod /(path of dhd.ko file)
firmware_path=/(path of firmware file) nvram_path=/(path of nvram file) to enable.
•Enter rmmod dhd to disable
•
2-2. Throughput Test
CONNECTING TO WIRELESS NETWORKS
The examples in the following sections illustrate how to connect to both infrastructure and ad hoc networks,
including Infrastructure networks that use no security, WEP security, and WPA/PSK and WPS2/PSK security.
SCANNING FOR WIRELESS NETWORKS
To force the dongle to scan
• Run wl scan.
To force the dongle to return the results of the scan
• Run wl scanresults.
Example results returned when an AP is found:
• SSID: “Eval4325”
• Mode: Managed: RSSI: -48 dBm noise: -105 dBm Channel: 1
• BSSID: 00:10:18:90:2E:C1 Capability: ESS ShortSlot
• Supported Rates: [ 1(b) 2(b) 5.5(b) 11(b) 18 24 36 54 6 9 12 48 ]
Example results returned when an ad hoc network is found:
• SSID: “ADHOC#1”
• Mode: Ad Hoc RSSI: -41 dBm noise: -105 dBm Channel: 1
• BSSID: B2:51:28:6B:3C:A1 Capability: IBSS
• Supported Rates: [ 1(b) 2(b) 5.5(b) 11(b) ]
CONNECTING TO AN INFRASTRUCTURE NETWORK WITH NO SECURITY (AP CONNECTION)
To connect to the network through an AP with SSID = Eval4325
Run wl join Eval4325.
-6-
CONNECTING TO AN INFRASTRUCTURE NETWORK WITH WEP SECURITY
To connect to the network that uses 12345 as the network key
• Run wl join Eval4325 key 12345.
CONNECTING TO AN INFRASTRUCTURE NETWORK WITH WPA-PSK/WPA2-PSK SECURITY
To specify TKIP or AES as the data encryption method
• Run wl wsec 3/7.
To enable the supplicant
• Run wl sup_wpa 1.
To specify the PSK passphrase (network key) to use
• Run wl set_psk $passphrase.
To connect to a network that uses WPA-PSK security
• Run wl join Eval4325 imode bss amode wpapsk.
To connect to a network that uses WPA2-PSK security
• Run wl join Eval4325 imode bss amode wpa2psk.
CONNECTING TO AN AD HOC NETWORK USING CHANNEL 1
To set the channel to channel 1
• Run wl channel 1.
To connect to the ad hoc network with SSID = 4325-ADHOC
• Run wl join 4325-ADHOC imode ibss.
MANAGING POWER CONSUMPTION
To disable Power Save (PS) mode (default)
• Run wl PM 0.
To enable legacy IEEE 802.11 Power Save (PS) mode
• Run wl PM 1.
To enable Fast IEEE 802.11 Power Save mode
• Run wl PM 2.
Note:
• The STA automatically transitions to Legacy PS mode when no data is being sent or received.
• The STA automatically disables PS mode when data is being sent or received.
-7-
MEASURING WLAN THROUGHPUT
The throughput measurement shows the performance of the TCP/IP layer over the wireless link. To achieve
the best results,
run the measurement test in a clean environment with as little interference as possible . The test can be run
with the adapter
connected to either an Infrastructure network (see Fig. 2.2) or an ad hoc network (see Fig. 2.3). An AP that is
known to be
in good working order should be used for the infrastructure mode test.
LAN
HOST
COMPUTER.
Reference
Computer
AW-AM691NF
Chariot
EndPoint
Console
FIG. 2.2
HOST
Reference
COMPUTER.
Computer
AW-AM691NF
Chariot
EndPoint
Console
FIG. 2.3
MEASURING THROUGHPUT USING NETIQ CHARIOT
Test Procedure
1. Bring up the AW-AM691NF demo boar with the IP address set as 192.168.1.110.
2. Connect the reference computer with Chariot Console, which is assigned an IP address of 192.168.1.100,
to the LAN
port of the AP
3. Verify that communication exists between the reference computer and the AW-AM691NF demo board by
pinging 192.168.1.100
from the AW-AM691NF host console.
-8-
4. Set up Chariot.
a. On the host computer, activate EndPoint:
b. Using Chariot Console on the reference computer, create two pair groups (192.168.1.100 and
192.168.1.110) using the Chariot Throughput.scr script. Run the throughput test for a specified period of time
and observe the results.
2-3. RF Tx/Rx Performance Test
CREATING A Tx TEST
1. From the Start menu, select Run.
2. Type cmd, then click OK.
3. Navigate to the directory that contains wl.exe
4. Enter the wl ver command to check the current WL driver version.
5. Run the following command set (delay at least 700ms between each command):
11b mode:
./wl ver
./wl mpc 0
./wl country US
ALL
./wl up
./wl phy_forcecal 1
./wl interference 0
./wl phy_watchdog 0
./wl scansuppress 1
./wl phy_oclscdenable 0
./wl isup
./wl down
./wl band b
./wl phymsglevel +cal
./wl interference 0
./wl interference_override 0
./wl mimo_preamble
./wl mimo_bw_cap 0
./wl mimo_txbw -1
./wl chanspec -c 7 -b 2 -w 20
Åset Tx channel
-9-
./wl up
./wl phy_forcecal 1
./wl isup
./wl bi 10000
./wl join dummy imode adhoc
./wl assoc
./wl glacial_timer 30000
./wl phy_watchdog 0
./wl phy_percal 0
./wl phy_forcecal 1
./wl disassoc
./wl mimo_preamble
./wl chanspec
./wl sgi_tx 0
./wl nrate -r 11
Åset Tx data rate
./wl nrate
./wl sgi_tx
./wl down
./wl up
./wl txant 0
./wl antdiv 0
./wl txpwr1 -o -d 15
./wl phy_forcecal 1
Åset Tx path 0: port 0, 1:port 1,
Åset Tx path 0: port 0, 1:port 1,
Åset Tx power
./wl pkteng_start 10:20:30:40:50:60 tx 100 1500 0
This will send continuous Tx Packets with 100 us packet interval,1500 byte packet length. Data rate
=11Mbps, Channel=7 and output power =15dBm.
11g mode:
./wl ver
./wl mpc 0
./wl country US
ALL
./wl up
./wl phy_forcecal 1
./wl interference 0
- 10 -
./wl phy_watchdog 0
./wl scansuppress 1
./wl phy_oclscdenable 0
./wl isup
./wl down
./wl band b
./wl phymsglevel +cal
./wl interference 0
./wl interference_override 0
./wl mimo_preamble
./wl mimo_bw_cap 0
./wl mimo_txbw -1
./wl chanspec -c 7 -b 2 -w 20
Åset Tx channel
./wl up
./wl phy_forcecal 1
./wl isup
./wl bi 10000
./wl join dummy imode adhoc
./wl assoc
./wl glacial_timer 30000
./wl phy_watchdog 0
./wl phy_percal 0
./wl phy_forcecal 1
./wl disassoc
./wl mimo_preamble
./wl chanspec
./wl sgi_tx 0
./wl nrate -r 54
./wl nrate
./wl sgi_tx
./wl down
./wl up
./wl txant 0
./wl antdiv 0
./wl txpwr1 -o -d 14
./wl phy_forcecal 1
Åset Tx data rate
Åset Tx path 0: port 0, 1:port 1,
Åset Tx path 0: port 0, 1:port 1,
Åset Tx power
- 11 -
./wl pkteng_start 10:20:30:40:50:60 tx 100 1500 0
This will send continuous Tx Packets with 100 us packet interval,1500 byte packet length. Data rate
=54Mbps ,Channel=7 and output power =14dBm.
2.4G 11n HT20 SISO mode:
./wl
ver
./wl
./wl
mpc 0
country ALL
US
./wl
./wl
up
phy_forcecal 1
./wl interference 0
./wl phy_watchdog 0
./wl
scansuppress 1
./wl phy_oclscdenable 0
./wl isup
./wl
down
./wl band b
./wl phymsglevel +cal
./wl interference 0
./wl interference_override 0
./wl mimo_preamble 0
./wl mimo_bw_cap 0
./wl mimo_txbw -1
./wl chanspec -c 7 -b 2 -w 20
./wl up
./wl phy_forcecal 1
./wl isup
./wl bi 10000
./wl join dummy imode adhoc
./wl assoc
./wl glacial_timer 30000
./wl phy_watchdog 0
./wl phy_percal 0
./wl phy_forcecal 1
Åset Tx channel
- 12 -
./wl
./wl
./wl
./wl
./wl
disassoc
mimo_preamble
chanspec
sgi_tx 0
nrate -m 7 -s 0
Åset Tx data rate
./wl nrate
./wl sgi_tx
./wl down
./wl up
./wl
./wl
txant 0
antdiv 0
./wl txpwr1 -o -d 13
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx power
./wl phy_forcecal 1
./wl pkteng_start 10:20:30:40:50:60 tx 100 1500 0
This will send continuous Tx Packets with 100 us packet interval,1500 byte packet length. Data rate =MCS7,
Bandwidth=20 MHz, Channel=7 and output power =13dBm.
2.4G 11n HT20 MIMO mode:
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
ver
mpc 0
country US
ALL
up
phy_forcecal 1
interference 0
phy_watchdog 0
scansuppress 1
phy_oclscdenable 0
isup
down
band b
phymsglevel +cal
interference 0
interference_override 0
mimo_preamble 0
mimo_bw_cap 0
- 13 -
./wl
./wl
./wl
./wl
./wl
./wl
./wl
mimo_txbw -1
chanspec -c 13 -b 2 -w 20
up
phy_forcecal 1
isup
bi 10000
join dummy imode adhoc
./wl
assoc
./wl
glacial_timer 30000
./wl
phy_watchdog 0
./wl phy_percal 0
./wl
phy_forcecal 1
./wl
disassoc
./wl mimo_preamble
./wl
chanspec
./wl
sgi_tx 0
./wl nrate -m 15 -s 3
./wl
Åset Tx data rate
nrate
./wl sgi_tx
./wl down
./wl up
./wl
./wl
txant 3
antdiv 3
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx path 0: port 0, 1:port 1, 3: dual port
./wl txpwr1 -o -d 14
Åset Tx power
./wl phy_forcecal 1
./wl pkteng_start 10:20:30:40:50:60 tx 100 1500 0
2.4G 11n HT40 SISO mode:
./wl
./wl
./wl
./wl
./wl
./wl
./wl
ver
mpc 0
country US
ALL
up
phy_forcecal 1
interference 0
phy_watchdog 0
- 14 -
./wl
./wl
./wl
./wl
./wl
./wl
./wl
scansuppress 1
phy_oclscdenable 0
isup
down
band b
phymsglevel +cal
interference 0
./wl interference_override 0
./wl mimo_preamble 0
./wl mimo_bw_cap 1
./wl
mimo_txbw 4
./wl
chanspec -c 7 -b 2 -w 40 -s 1
./wl
up
Åset Tx channel
./wl phy_forcecal 1
./wl isup
./wl bi 10000
./wl join dummy imode adhoc
./wl assoc
./wl glacial_timer 30000
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
phy_watchdog 0
phy_percal 0
phy_forcecal 1
disassoc
mimo_preamble
chanspec
sgi_tx 0
nrate -m 7 -s 0
Åset Tx data rate
nrate
sgi_tx
down
up
txant 0
Åset Tx path 0: port 0, 1:port 1, 3: dual port
antdiv 0
Åset Tx path 0: port 0, 1:port 1, 3: dual port
txpwr1 -o -d 11
Åset Tx power
phy_forcecal 1
pkteng_start 10:20:30:40:50:60 tx 100 1500 0
- 15 -
This will send continuous Tx Packets with 100 us packet interval, 1500 byte packet length. Data rate = MCS7,
Bandwidth=40 MHz, Channel=6 and output power =11dBm.
2.4G 11n HT40 MIMO mode:
./wl
./wl
ver
mpc 0
./wl
./wl
./wl
country US
ALL
up
phy_forcecal 1
./wl interference 0
./wl phy_watchdog 0
./wl
scansuppress 1
./wl phy_oclscdenable 0
./wl isup
./wl
down
./wl band b
./wl phymsglevel +cal
./wl interference 0
./wl interference_override 0
./wl mimo_preamble 0
./wl mimo_bw_cap 1
./wl mimo_txbw 4
./wl chanspec -c 7 -b 2 -w 40 -s 1
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
Åset Tx channel
up
phy_forcecal 1
isup
bi 10000
join dummy imode adhoc
assoc
glacial_timer 30000
phy_watchdog 0
phy_percal 0
phy_forcecal 1
disassoc
mimo_preamble
- 16 -
./wl chanspec
./wl sgi_tx 0
./wl nrate -m 15 -s 3
./wl nrate
./wl sgi_tx
./wl
./wl
./wl
./wl
down
up
txant 3
antdiv 3
./wl txpwr1 -o -d 12
./wl phy_forcecal 1
Åset Tx data rate
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx power
./wl pkteng_start 10:20:30:40:50:60 tx 100 1500 0
11a mode:
./wl
ver
./wl
./wl
mpc 0
country US
ALL
./wl up
./wl phy_forcecal 1
./wl interference 0
./wl
phy_watchdog 0
./wl
./wl
./wl
./wl
scansuppress 1
phy_oclscdenable 0
isup
down
./wl band a
./wl phymsglevel +cal
./wl interference 0
./wl interference_override 0
./wl mimo_preamble
./wl mimo_bw_cap 0
./wl
./wl
./wl
mimo_txbw -1
chanspec -c 100 -b 5 -w 20
up
Åset Tx channel
- 17 -
./wl
./wl
./wl
./wl
./wl
./wl
./wl
phy_forcecal 1
isup
bi 10000
join dummy imode adhoc
assoc
glacial_timer 30000
phy_watchdog 0
./wl phy_percal 0
./wl
phy_forcecal 1
./wl
disassoc
./wl mimo_preamble
./wl
chanspec
./wl
sgi_tx 0
./wl nrate -r 54
./wl
Åset Tx data rate
nrate
./wl sgi_tx
./wl down
./wl
up
./wl
txant 0
./wl
antdiv 0
./wl txpwr1 -o -d 10
./wl phy_forcecal 1
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx power
./wl pkteng_start 10:20:30:40:50:60 tx 100 1500 0
This will send continuous Tx Packets with 100 us packet interval, 1500 byte packet length. Data rate
=54Mbps, Channel=36 and output power =10dBm.
5G 11n HT20 SISO mode:
./wl
./wl
./wl
./wl
./wl
./wl
ver
mpc 0
country US
ALL
up
phy_forcecal 1
interference 0
- 18 -
./wl
./wl
./wl
./wl
./wl
./wl
./wl
phy_watchdog 0
scansuppress 1
phy_oclscdenable 0
isup
down
band a
phymsglevel +cal
./wl interference 0
./wl interference_override 0
./wl mimo_preamble 0
./wl mimo_bw_cap 0
./wl
mimo_txbw -1
./wl
chanspec -c 100 -b 5 -w 20
./wl
up
Åset Tx channel
./wl phy_forcecal 1
./wl isup
./wl bi 10000
./wl join dummy imode adhoc
./wl assoc
./wl glacial_timer 30000
./wl phy_watchdog 0
./wl phy_percal 0
./wl phy_forcecal 1
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
disassoc
mimo_preamble
chanspec
sgi_tx 0
nrate -m 7 -s 0
nrate
sgi_tx
down
up
txant 0
antdiv 0
txpwr1 -o -d 9
phy_forcecal 1
Åset Tx data rate
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx power
- 19 -
./wl pkteng_start 10:20:30:40:50:60 tx 100 1500 0
This will send continuous Tx Packets with 100 us packet interval, 1500 byte packet length. Data rate = MCS7,
Bandwidth=20 MHz, Channel=36 and output power =9dBm.
5G 11n HT20 MIMO mode:
./wl
ver
./wl mpc 0
./wl country US
ALL
./wl up
./wl phy_forcecal 1
./wl interference 0
./wl
phy_watchdog 0
./wl scansuppress 1
./wl phy_oclscdenable 0
./wl
isup
./wl down
./wl band a
./wl phymsglevel +cal
./wl interference 0
./wl interference_override 0
./wl mimo_preamble 0
./wl mimo_bw_cap 0
./wl
./wl
mimo_txbw -1
chanspec -c 64 -b 5 -w 20
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
up
phy_forcecal 1
isup
bi 10000
join dummy imode adhoc
assoc
glacial_timer 30000
phy_watchdog 0
phy_percal 0
phy_forcecal 1
Åset Tx channel
- 20 -
./wl
./wl
./wl
./wl
./wl
disassoc
mimo_preamble
chanspec
sgi_tx 0
nrate -m 15 -s 3
Åset Tx data rate
./wl nrate
./wl sgi_tx
./wl down
./wl up
./wl
./wl
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx path 0: port 0, 1:port 1, 3: dual port
txant 3
antdiv 3
Åset Tx power
./wl txpwr1 -o -d 8
./wl phy_forcecal 1
./wl pkteng_start 10:20:30:40:50:60 tx 100 1500 0
5G 11n HT40 SISO mode:
./wl
ver
./wl
./wl
mpc 0
country US
ALL
./wl
up
./wl
./wl
./wl
./wl
./wl
./wl
./wl
phy_forcecal 1
interference 0
phy_watchdog 0
scansuppress 1
phy_oclscdenable 0
isup
down
./wl band a
./wl phymsglevel +cal
./wl interference 0
./wl interference_override 0
./wl mimo_preamble 0
./wl mimo_bw_cap 1
./wl mimo_txbw 4
./wl chanspec -c 102 -b 5 -w 40 -s 1
./wl up
Åset Tx channel
- 21 -
./wl
./wl
./wl
./wl
./wl
./wl
./wl
phy_forcecal 1
isup
bi 10000
join dummy imode adhoc
assoc
glacial_timer 30000
phy_watchdog 0
./wl phy_percal 0
./wl
phy_forcecal 1
./wl
disassoc
./wl mimo_preamble
./wl
chanspec
./wl
sgi_tx 0
Åset Tx data rate
./wl nrate -m 7 -s 0
./wl
nrate
./wl sgi_tx
./wl down
./wl
up
./wl
txant 0
./wl
antdiv 0
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx power
./wl txpwr1 -o -d 9
./wl phy_forcecal 1
./wl pkteng_start 10:20:30:40:50:60 tx 100 1500 0
This will send continuous Tx Packets with 100 us packet interval, 1500 byte packet length. Data rate = MCS7,
Bandwidth=40 MHz, Channel=38 and output power =9dBm.
5G 11n HT40 MIMO mode:
./wl
./wl
./wl
./wl
./wl
./wl
ver
mpc 0
country ALL
US
up
phy_forcecal 1
interference 0
- 22 -
./wl
./wl
./wl
./wl
./wl
./wl
./wl
phy_watchdog 0
scansuppress 1
phy_oclscdenable 0
isup
down
band a
phymsglevel +cal
./wl interference 0
./wl interference_override 0
./wl mimo_preamble 0
./wl mimo_bw_cap 1
./wl
mimo_txbw 4
./wl
chanspec -c 102 -b 5 -w 40 -s 1
./wl
up
Åset Tx channel
./wl phy_forcecal 1
./wl isup
./wl bi 10000
./wl join dummy imode adhoc
./wl assoc
./wl glacial_timer 30000
./wl phy_watchdog 0
./wl phy_percal 0
./wl phy_forcecal 1
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
./wl
disassoc
mimo_preamble
chanspec
sgi_tx 0
nrate -m 15 -s 3
nrate
sgi_tx
down
up
txant 3
antdiv 3
txpwr1 -o -d 12
phy_forcecal 1
Åset Tx data rate
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx power
- 23 -
./wl pkteng_start 10:20:30:40:50:60 tx 100 1500 0
Carrier mode
./wl out
./wl fqacurcy 149
CREATING A Rx TEST
1. From the Start menu, select Run.
2. Type cmd, then click OK.
3. Navigate to the directory that contains wl.exe.
4. Run the following command set (delay at least 700ms between each command):
11b Rx mode:
./wl ver
./wl mpc 0
./wl country US
ALL
./wl up
./wl phy_forcecal 1
./wl interference 0
./wl phy_watchdog 0
./wl scansuppress 1
./wl phy_oclscdenable 0
./wl isup
./wl down
./wl mimo_preamble 0
./wl mimo_bw_cap 0
./wl mimo_txbw -1
./wl band b
./wl chanspec -c 7 -b 2 -w 20
Åset Tx channel
- 24 -
./wl up
./wl chanspec
./wl sgi_tx 0
./wl nrate -r 11
Åset Tx data rate
Åset Tx path 0: port 0, 1:port 1, 3: dual port
./wl txant 0
Åset Tx path 0: port 0, 1:port 1, 3: dual port
./wl antdiv 0
./wl cur_etheraddr 00:11:22:33:44:55
./wl pkteng_start 00:11:22:33:44:55 rx
This will enter 11Mbps, Channel 7 receive mode.
11g Rx mode:
./wl ver
./wl mpc 0
./wl country ALL
US
./wl up
./wl phy_forcecal 1
./wl interference 0
./wl phy_watchdog 0
./wl scansuppress 1
./wl phy_oclscdenable 0
./wl isup
./wl down
./wl mimo_preamble 0
./wl mimo_bw_cap 0
./wl mimo_txbw -1
./wl band b
./wl chanspec -c 7 -b 2 -w 20
./wl up
./wl chanspec
./wl sgi_tx 0
./wl nrate -r 54
./wl txant 0x0
./wl antdiv 0x0
./wl cur_etheraddr 00:11:22:33:44:55
Åset Tx channel
Åset Tx data rate
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx path 0: port 0, 1:port 1, 3: dual port
- 25 -
./wl pkteng_start 00:11:22:33:44:55 rx
11n HT20 Rx SISO mode:
./wl ver
./wl mpc 0
./wl country US
ALL
./wl up
./wl phy_forcecal 1
./wl interference 0
./wl phy_watchdog 0
./wl scansuppress 1
./wl phy_oclscdenable 0
./wl isup
./wl down
./wl mimo_preamble 0
./wl mimo_bw_cap 0
./wl mimo_txbw -1
./wl band b
Åset Tx channel
./wl chanspec -c 7 -b 2 -w 20
./wl up
./wl chanspec
./wl sgi_tx 0
./wl nrate -m 7 -s 0
Åset Tx data rate
./wl txant 0
./wl antdiv 0
./wl cur_etheraddr 00:11:22:33:44:55
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx path 0: port 0, 1:port 1, 3: dual port
./wl pkteng_start 00:11:22:33:44:55 rx
11n HT20 Rx MIMO mode:
./wl ver
./wl mpc 0
./wl country ALL
US
./wl up
./wl phy_forcecal 1
./wl interference 0
- 26 -
./wl phy_watchdog 0
./wl scansuppress 1
./wl phy_oclscdenable 0
./wl isup
./wl down
./wl mimo_preamble 0
./wl mimo_bw_cap 0
./wl mimo_txbw -1
./wl band b
Åset Tx channel
./wl chanspec -c 7 -b 2 -w 20
./wl up
./wl chanspec
./wl sgi_tx 0
./wl nrate -m 15 -s 3
./wl txant 3
Åset Tx data rate
Åset Tx path 0: port 0, 1:port 1, 3: dual port
./wl antdiv 3
Åset Tx path 0: port 0, 1:port 1, 3: dual port
./wl cur_etheraddr 00:11:22:33:44:55
./wl pkteng_start 00:11:22:33:44:55 rx
11n HT40 Rx SISO mode:
./wl ver
./wl mpc 0
./wl country ALL
US
./wl up
./wl phy_forcecal 1
./wl interference 0
./wl phy_watchdog 0
./wl scansuppress 1
./wl phy_oclscdenable 0
./wl isup
./wl down
./wl mimo_preamble 0
./wl mimo_bw_cap 1
./wl mimo_txbw 4
- 27 -
./wl band b
./wl chanspec -c 6 -b 2 -w 40 -s 1
Åset Tx channel
./wl up
./wl chanspec
./wl sgi_tx 0
./wl nrate -m 7 -s 0
./wl txant 0
Åset Tx data rate
Åset Tx path 0: port 0, 1:port 1, 3: dual port
./wl antdiv 0
./wl cur_etheraddr 00:11:22:33:44:55
./wl pkteng_start 00:11:22:33:44:55 rx
Åset Tx path 0: port 0, 1:port 1, 3: dual port
11n HT40 Rx MIMO mode:
./wl ver
./wl mpc 0
US
./wl country ALL
./wl up
./wl phy_forcecal 1
./wl interference 0
./wl phy_watchdog 0
./wl scansuppress 1
./wl phy_oclscdenable 0
./wl isup
./wl down
./wl mimo_preamble 0
./wl mimo_bw_cap 1
./wl mimo_txbw 4
./wl band b
./wl chanspec -c 6 -b 2 -w 40 -s 1
Åset Tx channel
./wl up
./wl chanspec
./wl sgi_tx 0
./wl nrate -m 15 -s 3
Åset Tx data rate
./wl txant 3
./wl antdiv 3
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx path 0: port 0, 1:port 1, 3: dual port
./wl cur_etheraddr 00:11:22:33:44:55
- 28 -
./wl pkteng_start 00:11:22:33:44:55 rx
11a Rx mode:
./wl ver
./wl mpc 0
./wl country ALL
US
./wl up
./wl phy_forcecal 1
./wl interference 0
./wl phy_watchdog 0
./wl scansuppress 1
./wl phy_oclscdenable 0
./wl isup
./wl down
./wl mimo_preamble 0
./wl mimo_bw_cap 0
./wl mimo_txbw -1
./wl band a
./wl chanspec -c 36 -b 5 -w 20
Åset Tx channel
./wl up
./wl chanspec
./wl sgi_tx 0
Åset Tx data rate
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx path 0: port 0, 1:port 1, 3: dual port
./wl nrate -r 54
./wl txant 0
./wl antdiv 0
./wl cur_etheraddr 00:11:22:33:44:55
./wl pkteng_start 00:11:22:33:44:55 rx
11a HT20 Rx SISO mode:
./wl ver
./wl mpc 0
./wl country US
ALL
./wl up
- 29 -
./wl phy_forcecal 1
./wl interference 0
./wl phy_watchdog 0
./wl scansuppress 1
./wl phy_oclscdenable 0
./wl isup
./wl down
./wl mimo_preamble 0
./wl mimo_bw_cap 0
./wl mimo_txbw -1
./wl band a
Åset Tx channel
./wl chanspec -c 36 -b 5 -w 20
./wl up
./wl chanspec
./wl sgi_tx 0
./wl nrate -m 7 -s 0
Åset Tx data rate
./wl txant 0
Åset Tx path 0: port 0, 1:port 1, 3: dual port
./wl antdiv 0
./wl cur_etheraddr 00:11:22:33:44:55
Åset Tx path 0: port 0, 1:port 1, 3: dual port
./wl pkteng_start 00:11:22:33:44:55 rx
11a HT20 Rx MIMO mode:
./wl ver
./wl mpc 0
./wl country ALL
US
./wl up
./wl phy_forcecal 1
./wl interference 0
./wl phy_watchdog 0
./wl scansuppress 1
./wl phy_oclscdenable 0
./wl isup
./wl down
./wl mimo_preamble 0
./wl mimo_bw_cap 0
- 30 -
./wl mimo_txbw -1
./wl band a
./wl chanspec -c 36 -b 5 -w 20
Åset Tx channel
./wl up
./wl chanspec
./wl sgi_tx 0
./wl nrate -m 15 -s 3
Åset Tx data rate
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx path 0: port 0, 1:port 1, 3: dual port
./wl txant 3
./wl antdiv 3
./wl cur_etheraddr 00:11:22:33:44:55
./wl pkteng_start 00:11:22:33:44:55 rx
11a HT40 Rx SISO mode:
./wl ver
./wl mpc 0
./wl country US
ALL
./wl up
./wl phy_forcecal 1
./wl interference 0
./wl phy_watchdog 0
./wl scansuppress 1
./wl phy_oclscdenable 0
./wl isup
./wl down
./wl mimo_preamble 0
./wl mimo_bw_cap 1
./wl mimo_txbw 4
./wl band a
./wl chanspec -c 38 -b 5 -w 40 -s 1
Åset Tx channel
./wl up
./wl chanspec
./wl sgi_tx 0
./wl nrate -m 7 -s 0
Åset Tx data rate
Åset Tx path 0: port 0, 1:port 1, 3: dual port
Åset Tx path 0: port 0, 1:port 1, 3: dual port
./wl txant 0
./wl antdiv 0
- 31 -
./wl cur_etheraddr 00:11:22:33:44:55
./wl pkteng_start 00:11:22:33:44:55 rx
This will enter MCS7 HT40, Channel 38 receive mode.
11a HT40 Rx MIMO mode:
./wl ver
./wl mpc 0
./wl country US
ALL
./wl up
./wl phy_forcecal 1
./wl interference 0
./wl phy_watchdog 0
./wl scansuppress 1
./wl phy_oclscdenable 0
./wl isup
./wl down
./wl mimo_preamble 0
./wl mimo_bw_cap 1
./wl mimo_txbw 4
./wl band a
Åset Tx channel
./wl chanspec -c 38 -b 5 -w 40 -s 1
./wl up
./wl chanspec
./wl sgi_tx 0
./wl txant 3
Åset Tx data rate
Åset Tx path 0: port 0, 1:port 1, 3: dual port
./wl antdiv 3
Åset Tx path 0: port 0, 1:port 1, 3: dual port
./wl nrate -m 15 -s 3
./wl cur_etheraddr 00:11:22:33:44:55
./wl pkteng_start 00:11:22:33:44:55 rx
The default MAC address is 001122334455. Packets sent from Signal Generator must have the same MAC
address as the DUT’s MAC address (Runtime mac address can be overrode by using wl cur_etheraddr
xx:xx:xx:xx:xx:xx .
4. Use “wl counters” and find the received frame numbers in “pktengrxducast”.
- 32 -
5. The RX PER = [ (Total lost packets at the receiver) / (Total sent packets from the Signal Generator) ] x
100%.
Thus, PER =100% - [(pktengrxducast numbers after sequence play) – (pktengrxducast numbers before
sequence play)] / (Total sent packets from the signal Generator) x 100%.
A simple PER calculation tool (fer.exe) can help you do the job:
NOTE: The fer.exe must be located with wl.exe in the same directory.
EUT plug-out
./wl down
rmmod dhd
3. Bluetooth Basic Test
- 33 -
* J5/J1 setting as below
*Must connect USB to PC
3-1. Download Mini-driver
1. Start Broadcom BlueTool.
2. On the View menu, click Log Windows Details.
3. On the Transport menu, click HCI Control.
- 34 -
4. in Select HCI Control Window Transport:
a. Select UART as the type of transport.
b. In the COM port list, select com6. (Check the port number in device manager)
- 35 -
c. In the Baud list, type 115200.
d. Select the CTS flow control check box.
e. Click OK.
5. In HCI Control, select the HCI protocol active check box
6. In the HCI Control commands list, select 0: Vendor-specific Commands (0 key), and then double-click
Download
Minidriver.
7. On the Transport menu, click Download Firmware/Config.
8. In Select Download Firmware/Config Transport:
- 36 -
a. Select UART as the type of transport.
b. In the COM port list, select com6.
c. In the Baud list box, type 115200.
d. Select the CTS flow control check box.
e. Click OK.
9. In Download, configure the settings to match those shown below
10. Click Execute.
11. Select the HCI protocol active check box
Throughput Test
Bluetool contains a throughput test feature that can be used with two or more AW-AM691NF devices.
Note that each device runs on a separate PC with BlueTool installed. This document will provide basic
directions for setting-up and running this test.
The next step in setting-up the test is establishing a connection between the devices.
ESTABLISH A BLUETOOTH CONNECTION BETWEEN TWO USB DEVICES
SET UP THE SLAVE DEVICE FIRST
1. On the Slave side, start Bluetool from the Start Menu.
2. If the Log Window is not already open, select “View” and then select “Log Window”.Select “Transport”
and then Select “HCI Control.” New window pop-up, select “UART” and enter com port number.
Click “OK”.
- 37 -
3. Download mini driver (see 3.1)
4. In the “HCI Control” window, select “7.3 Host Controller & Baseband Commands”
(Note: may be 4.3,
depending on version)
5. Double Click the “Write Scan Enable” entry
6. Select “Inquiry and Page Scan Enabled” and click “OK”
7. Double Click “Set Event Filter”
8. Select “Connection Setup”
9. Select “Allow Connections from all devices”
10. Select “Do Auto accept the connection with role switch disabled”
11. Click “OK”
12. In the “HCI Control” window, select “0 Vendor-specific commands”.
13. Double Click the “Write_BD_ADDR” command
14. Enter 001122334455
15. In the “HCI Control” window, select”0 Vendor-specific commands”. Double Click”Update UART Baud
Rate”. Select 3000000 then click OK.
SET UP THE MASTER DEVICE, AND CREATE THE CONNECTION
1. On the Master side, start Bluetool.
2. Open the log window, if not already open, and open the UART HCI Transport.
3. Download mini driver (see 3.1)
4. In the “HCI Control” window, select “7.1 Link Control Commands” (Note: may be 4.5 depending on
version)
5. Double Click “Create Connection” and put BD address of the slave device into the BDADDR box.
Click “OK”
6. In the “HCI Control” window,select”0 Vendor-specific commands”. Double Click ”Update UART Baud
Rate”. Select 3000000 then click OK.
A connection should establish now.
This can be verified by looking in the log windows for both devices,
which should now contain Connection Complete events with “Success” in the status field.
NOTE: once the connection has been established, Inquiry and Page Scan can be disabled.
Also, go to: “7.3
Host Controller !"$'*;<'>?"@QYY'>?*Z"\\"^`;{"|};>{"~€{;Z‚" " `;€;ƒ{"^@Q>>;ƒ{Q>"`;{„ Z†"`;€;ƒ{"^‡€€Qˆ"
- 38 -
Connections from all devices”; Select “Do NOT Auto accept the connection” and hit ‘OK’. This will make the
slave device non-discoverable and increase throughput by reducing overhead.
SET UP AND EXECUTE THE THROUGHPUT TEST
SET UP THE SLAVE AS THE RECEIVER
1. On the Slave side, select “Transport” and then select “Throughput Tests”. Select UART.
2. In the “Receive Test” (Bottom half of the window), fill in a data pattern such as “abcdef”, and fill in a count
such as “1000000”
3. Close the “Log Window.” If this window is left open or minimized, then the throughput test will not
achieve maximum throughput because of delay that is added by Windows every time the log window is
updated.
SET UP THE MASTER AS THE TRANSMITTER AND START THE TEST
1. On the Master side, select “Transport” and then select “Throughput Tests”.
Select UART.
2. In the “Transmit Test” window (top half of the window), fill in the same data pattern and count that was
filled in for the receive test on the Slave side.
3. Close the “Log Window.” If this window is left open or minimized, then the throughput test will not
achieve maximum throughput because of delay that is added by Windows every time the log window is
updated.
4. On the Slave side, click “Execute Test” in the “Receive Test” window.
5. On the Master side, click “Execute Test” in the “Transmit Test” window.
Bluetooth throughput test is now running.
To stop the test, click “Abort Test” on the Master side first, then on the slave side.
RF Performance Test
The following procedure explains how to configure the AW-AM691NF for RF testing using Broadcom
BlueTool. At the completion
of the procedure, connect the Bluetooth test instrument to the AW-AM691NF with RF cable and performs the
RF tests.
- 39 -
RESETTING THE USB DEVICE
To reset the USB device
•In HCI Control, in the HCI Control commands list, select 7.3: Host Controller & Baseband Commands (3
key), and then double-click Reset.
READING THE BLUETOOTH DEVICE ADDRESS
To read the Bluetooth Device Address
• In HCI Control, in the HCI Control commands list, select 7.4: Informational Parameters (4 key), and then
double-click
Read_BD_ADDR.
The Bluetooth Device Address (BD_ADDR) is displayed in the log window. The Bluetooth Device Address
might be needed
by the Bluetooth tester
SETTING THE EVENT FILTER TO AUTOMATICALLY ALLOW CONNECTION
To set the event filter to automatically allow connection
1. In HCI Control, in the HCI Control commands list, select 7.3: Host Controller & Baseband Commands (3
key), and
then double-click Set_Event_Filter.
2. In HCI Command: Set_Event_Filter:
a. In the Filter_Type list, select Connection Setup.
b. In the Connection_Setup_Filter_Condition_Type list, select Allow Connections from all devices.
c. In the Auto_Accept_Flag list, select Do Auto accept the connection with role switch disabled.
ENABLING WRITE SCAN
To enable Write Scan
1. In HCI Control, in the HCI Control commands list, select 7.3: Host Controller & Baseband Commands (3
key), and
then double-click Write_Scan_Enable.
2. In HCI Command: Write_Scan_Enable, in the Scan_Enable list, select Inquiry and Page Scan enabled.
ENABLING TEST MODE
To enable Test Mode
• In HCI Control, in the HCI Control commands list, select 7.6: Testing Commands (6 key), and then
double-click
Enable_Device_Under_Test_Mode.
- 40 -
The AW-AM691NF is now ready to receive a connection request from the Bluetooth tester and begin testing
specified RF parameters.
4. Known Limitations
*For PC test scenario. AW-AM691NF only support the following Host Controller IC:
PCI\VEN_1095&DEV_0670 ;Arasan SDIO HC
PCI\VEN_104C&DEV_803B ;TI Std SDIO HC
PCI\VEN_104C&DEV_803C ;TI Std SDIO HC
PCI\VEN_104C&DEV_8033 ;TI Std SDIO HC
PCI\VEN_104C&DEV_8034 ;TI Std SDIO HC
PCI\VEN_1180&DEV_0822 ;Ricoh Std SDIO HC
*WinXP,WIN7 WLAN drivers are not supported
- 41 -
Federal Communication Commission Interference Statement
5. Demo board schematic
This device complies with Part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device
may not cause harmful interference, and (2) this device must accept any interference received, including interference
that may cause undesired operation.
This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to Part 15 of
the FCC Rules. These limits are designed to provide reasonable protection against harmful interference in a residential
installation. This equipment generates, uses and can radiate radio frequency energy and, if not installed and used in
accordance with the instructions, may cause harmful interference to radio communications. However, there is no
guarantee that interference will not occur in a particular installation. If this equipment does cause harmful interference
to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to
try to correct the interference by one of the following measures:
- Reorient or relocate the receiving antenna.
- Increase the separation between the equipment and receiver.
- Connect the equipment into an outlet on a circuit different from that
to which the receiver is connected.
- Consult the dealer or an experienced radio/TV technician for help.
FCC Caution: Any changes or modifications not expressly approved by the party responsible for compliance could void
the user's authority to operate this equipment.
This transmitter must not be co-located or operating in conjunction with any other antenna or transmitter.
Operations in the 5.15-5.25GHz band are restricted to indoor usage only.
Radiation Exposure Statement:
This equipment complies with FCC radiation exposure limits set forth for an uncontrolled environment. This equipment
should be installed and operated with minimum distance 20cm between the radiator & your body.
This device is intended only for OEM integrators under the following conditions:
1) The antenna must be installed such that 20 cm is maintained between the antenna and users, and
2) The transmitter module may not be co-located with any other transmitter or antenna.
As long as 2 conditions above are met, further transmitter test will not be required. However, the OEM integrator is still
responsible for testing their end-product for any additional compliance requirements required with this module installed
IMPORTANT NOTE: In the event that these conditions can not be met (for example certain laptop configurations or colocation with another transmitter), then the FCC authorization is no longer considered valid and the FCC ID can not be
used on the final product. In these circumstances, the OEM integrator will be responsible for re-evaluating the end
product (including the transmitter) and obtaining a separate FCC authorization.
End Product Labeling
This transmitter module is authorized only for use in device where the antenna may be installed such that 20 cm may
be maintained between the antenna and users. The final end product must be labeled in a visible area with the
following: “Contains FCC ID: TLZ-AM691NF”. The grantee's FCC ID can be used only when all FCC compliance
requirements are met.
Manual Information To the End User
The OEM integrator has to be aware not to provide information to the end user regarding how to install or remove this
RF module in the user's manual of the end product which integrates this module.
The end user manual shall include all required regulatory information/warning as show in this manual.
- 42 -
Industry Canada statement:
This device complies with RSS-210 of the Industry Canada Rules. Operation is subject to the following two conditions:
(1) This device may not cause harmful interference, and (2) this device must accept any interference received,
including interference that may cause undesired operation.
Ce dispositif est conforme à la norme CNR-210 d'Industrie Canada applicable aux appareils radio exempts de licence.
Son fonctionnement est sujet aux deux conditions suivantes: (1) le dispositif ne doit pas produire de brouillage
préjudiciable, et (2) ce dispositif doit accepter tout brouillage reçu, y compris un brouillage susceptible de provoquer
un fonctionnement indésirable.
Radiation Exposure Statement:
This equipment complies with IC radiation exposure limits set forth for an uncontrolled environment. This equipment
should be installed and operated with minimum distance 20cm between the radiator & your body.
Déclaration d'exposition aux radiations:
Cet équipement est conforme aux limites d'exposition aux rayonnements IC établies pour un environnement non
contrôlé. Cet équipement doit être installé et utilisé avec un minimum de 20 cm de distance entre la source de
rayonnement et votre corps.
This device is intended only for OEM integrators under the following conditions: (For module device use)
1) The antenna must be installed such that 20 cm is maintained between the antenna and users, and
2) The transmitter module may not be co-located with any other transmitter or antenna.
As long as 2 conditions above are met, further transmitter test will not be required. However, the OEM integrator is still
responsible for testing their end-product for any additional compliance requirements required with this module
installed.
Cet appareil est conçu uniquement pour les intégrateurs OEM dans les conditions suivantes: (Pour utilisation
de dispositif module)
1) L'antenne doit être installée de telle sorte qu'une distance de 20 cm est respectée entre l'antenne et les utilisateurs,
et
2) Le module émetteur peut ne pas être coïmplanté avec un autre émetteur ou antenne.
Tant que les 2 conditions ci-dessus sont remplies, des essais supplémentaires sur l'émetteur ne seront pas
nécessaires. Toutefois, l'intégrateur OEM est toujours responsable des essais sur son produit final pour toutes
exigences de conformité supplémentaires requis pour ce module installé.
IMPORTANT NOTE:
In the event that these conditions can not be met (for example certain laptop configurations or co-location with another
transmitter), then the Canada authorization is no longer considered valid and the IC ID can not be used on the final
product. In these circumstances, the OEM integrator will be responsible for re-evaluating the end product (including
the transmitter) and obtaining a separate Canada authorization.
NOTE IMPORTANTE:
Dans le cas où ces conditions ne peuvent être satisfaites (par exemple pour certaines configurations d'ordinateur
portable ou de certaines co-localisation avec un autre émetteur), l'autorisation du Canada n'est plus considéré comme
valide et l'ID IC ne peut pas être utilisé sur le produit final. Dans ces circonstances, l'intégrateur OEM sera chargé de
réévaluer le produit final (y compris l'émetteur) et l'obtention d'une autorisation distincte au Canada.
- 43 -
End Product Labeling
This transmitter module is authorized only for use in device where the antenna may be installed such that 20 cm may be
maintained between the antenna and users. The final end product must be labeled in a visible area with the following:
“Contains IC: 6100A-AM691NF”.
Plaque signalétique du produit final
Ce module émetteur est autorisé uniquement pour une utilisation dans un dispositif où l'antenne peut être installée de
telle sorte qu'une distance de 20cm peut être maintenue entre l'antenne et les utilisateurs. Le produit final doit être
étiqueté dans un endroit visible avec l'inscription suivante: "Contient des IC: 6100A-AM691NF".
Manual Information To the End User
The OEM integrator has to be aware not to provide information to the end user regarding how to install or remove this RF
module in the user's manual of the end product which integrates this module.
The end user manual shall include all required regulatory information/warning as show in this manual.
Manuel d'information à l'utilisateur final
L'intégrateur OEM doit être conscient de ne pas fournir des informations à l'utilisateur final quant à la façon d'installer ou
de supprimer ce module RF dans le manuel de l'utilisateur du produit final qui intègre ce module.
Le manuel de l'utilisateur final doit inclure toutes les informations réglementaires requises et avertissements comme
indiqué dans ce manuel.
- 44 -
- 45 -

Source Exif Data:
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File Type Extension             : pdf
MIME Type                       : application/pdf
PDF Version                     : 1.6
Linearized                      : Yes
Encryption                      : Standard V2.3 (128-bit)
User Access                     : Print, Extract
XMP Toolkit                     : Adobe XMP Core 4.0-c316 44.253921, Sun Oct 01 2006 17:14:39
Create Date                     : 2013:09:17 10:13:12+08:00
Creator Tool                    : PDFCreator Version 1.2.3
Modify Date                     : 2013:09:17 10:15:23+08:00
Metadata Date                   : 2013:09:17 10:15:23+08:00
Format                          : application/pdf
Description                     : 
Creator                         : amawu
Title                           : AW-AM691NF- manual-For FCC rev2.pdf
Keywords                        : 
Producer                        : GPL Ghostscript 9.04
Document ID                     : uuid:3e7912f8-eefd-481d-a3f8-fc37889fd967
Instance ID                     : uuid:23433510-368f-4410-a2df-9ef69b1c8c04
Page Count                      : 45
Subject                         : 
Author                          : amawu
EXIF Metadata provided by EXIF.tools
FCC ID Filing: TLZ-AM691NF

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