LG Electronics USA LGAJ10N GSM/WCDMA/LTE Telematics NAD module User Manual TM01LA N Rev04

Download:
Mirror Download [FCC.gov]
Document ID	3198185
Application ID	zboHXyDWeTYcWhGf4NPPuw==
Document Description	Users Manual
Short Term Confidential	No
Permanent Confidential	No
Supercede	No
Document Type	User Manual
Display Format	Adobe Acrobat PDF - pdf
Filesize	38.94kB (486812 bits)
Date Submitted	2016-11-16 00:00:00
Date Available	2017-01-14 00:00:00
Creation Date	2016-11-10 16:21:39
Producing Software	nPDF, http://iblogbox.com/npdf
Document Lastmod	2016-11-11 23:39:48
Document Title	Microsoft Word - TM01LA-N_User Manual_Rev04
Document Creator	nPDF, http://iblogbox.com/npdf

Technical Specification (TM01LA-N)
History
Ver.
Date
Contents
Written
Checked
Approved
by
by
by
２/30
Note
Contents
1. Product Introduction..................................................................................................... 4
1.1 Block Diagram .................................................................................................... 4
1.2 Environmental Specifications.............................................................................. 6
1.3 Electrical Specifications ...................................................................................... 6
1.3.1 Absolute Maximum and ESD Ratings........................................................... 6
1.3.2 Current Consumption ................................................................................... 7
1.4 Mechanical Specifications ................................................................................. 8
1.4.1 Physical Dimensions and Connection Interface ........................................... 8
1.4.2 Mechanical Drawing ..................................................................................... 9
1.4.3 Footprint ...................................................................................................... 9
1.5 PCB information ............................................................................................ 10
1.5.1 PCB Stack up ............................................................................................ 10
2. Pin Definitions............................................................................................................ 10
2.1 VCOIN.............................................................................................................. 13
2.2 ON/OFF Control ............................................................................................... 14
2.2.1 ON/OFF Timing .......................................................................................... 14
2.2.2 Deep Sleep ................................................................................................ 14
2.2.3 Sequence to Enter Deep Sleep Mode ........................................................ 15
2.3 USB.................................................................................................................. 16
2.4 UART ............................................................................................................... 16
2.5 UIM Interface .................................................................................................... 16
2.6 General Purpose IO ......................................................................................... 17
2.7 Secure Digital IO .............................................................................................. 17
2.8 I2C Interface ................................................................................................... 17
2.9 RESET ............................................................................................................. 18
2.10 ADC................................................................................................................ 19
2.11 LED driver ..................................................................................................... 19
2.13 SPI Interface ................................................................................................. 20
2.14 HSIC Interface .............................................................................................. 20
2.15 JTAG Interface .............................................................................................. 21
3 RF Specification ....................................................................................................... 21
3.1. WCDMA Specification ..................................................................................... 22
3.1. LTE Specification ............................................................................................. 23
3.3. GSM Specification ........................................................................................... 26
3.3. TD-SCDMA Specification................................................................................. 27
３/30
4. GNSS ...................................................................................................................... 28
4.1 GNSS Characteristics....................................................................................... 28
4.2 GNSS Antenna Interface .................................................................................. 29
4.3 Active antenna Powering the External LNA ...................................................... 29
４/30
1. Product Introuction
The TM01LA-N are designed for the automotive industry. They support LTE, WCDMA and
GSM air Interface standards. They also have Global Navigation satellite system (GNSS)
capabilities including GPS and GLONASS.
The TM01LA\-N are based on the Qualcomm MDM9215 wireless chipsets and support the
following bands.
Table 1.
Supported Band
Region
LTE
Band
NA
B2/B4/B5/B7/B17
WCDMA
B2/B4/B5
GSM
GSM850/PCS1900
GNSS
Voice
TML1-E
1.1 Block Diagram
Figure 1.1. TM01LA-N Block diagram
5/30
TML1-C
1.2 Environmental Specifications
The environmental specification for operating and storage of the TM01LA-N are defined in the
the table below.
LGE guarantee the automotive operation by internal reliability verification
Table 2.
Environmental Specifications
Parameter
Temperature Range
Operating Temperature
1)
Storage Temperature
2)
Humidity
-40℃ to 85℃
-40℃ to +105℃
95% or less
1) At
90℃operating, there is some deviation, but a module can meet 3GPP RF HW Spec
2) A module can accept over 105 ℃ storage temperature without packing
A module was guaranteed 34.2 MTTF in worst case at least
1.3 Electrical Specifications
This section provides details for some of the key electrical specifications of the TM01LA-N
embedded modules.
1.3.1 Absolute Maximum Rating and ESD Ratings
This section defines the Absolute Maximum and Electrostatic Discharge (ESD) Ratings of the
TM01LA-N embedded modules.
Warning: If these parameters are exceeded, even momentarily, damage may occur to the
device.
Table 3. Absolute Maximum Ratings
Parameter
+3.7V_VPWR
VIN
Min
Max
Units
tbd
VREG_MDME+0.5
tbd
tbd
tbd
Power Supply Input
Voltage on any digital input or output pin
Maximum Voltage applied to antenna interface pins
VANT
Primary Antenna
Diversity Antenna
GNSS Antenna
ESD Ratings
ESD1
Primary, Diversity and GNSS antenna
pads - Contact
All other signal pads - Contact
tbd
tbd
kV
kV
1 The ESD Simulator configured with 330pF, 1000Ω.
Caution: The TM01LA-N embedded modules are sensitive to Electrostatic Discharge. ESD
countermeasures and handling methods must be used when handling the TM01LA-N devices.
6/30
1.3.2 Current Consumption
Table 4. TM01LA-N Current Consumption (TBD)
Mode
Parameter
Typical
Max
Units
Band 2, Max TX Output Power
WCDMA
Band 4, Max TX Output Power
mA
Band 5, Max TX Output Power
Band2, Max TX Output /Full RB
Band4, Max TX Output /Full RB
LTE
Band5, Max TX Output /Full RB
mA
Band7, Max TX Output /Full RB
Band17, Max TX Output /Full RB
GSM
850/900MHz PCL5
mA
1800/1900MHz PCL0
WCDMA
Idle, Registered
mA
LTE
Idle, Registered
mA
GSM
Idle, Registered
mA
WCDMA
Sleep Mode, Average Current
mA
LTE
Sleep Mode, Average Current
mA
GSM
Sleep Mode, Average Current
mA
1.4 Mechanical Specifications
1.4.1 Physical Dimensions and Connection Interface
The TM01LA-N embedded modules are a Land Grid Array (LGA) form factor device. The
device does not have a System or RF connectors. All electrical and mechanical connections
are made via the 206 pad TM01LA-N on the underside of the PCB.
Table5. TM01LA-N Embedded Module Dimensions
Parameter
Nominal
Max
Overall Dimension
Overall Module Height
PCB Thickness
Flatness Specification
Weight
35 x 35
3.5
1.0
35.35 x 35.35
3.85
1.1
0.1
tbd
7/30
Units
mm
mm
mm
mm
1.4.2 Mechanical Drawing
[Top view]
[Right view]
[Bottom view]
1.4.3 Footprint
8/30
[LGA PAD View]
1.5 PCB information
1.5.1 PCB Stack up
9/30
1.5.2 PCB via structure
2. Pin Definitions
Pin No.
Name
Direction
12
ANT_MAIN
Input/Output
15
ANT_DIVERSITY
Input
ANT_GNSS
Input
Description
RF Antenna Pads
GNSS Antenna Pad
126
Power Supply Pads
81,82,91,92
+3.7V_VPWR
Input
Power Supply Input
114
VREG_MDME
Output
Voltage Reference Output (1.8V)
84
VDD_AUDIO_3.3V
Input
Audio codec power supply (typ 3.3V)
135
VCOIN_3.3V
Input
Coin Battery Input
USB Pads
10/30
185
USB_VBUS
Input
USB Power Supply
198
USB_D+
Input/Output
Differential data interface positive
183
USB_D-
Input/Output
Differential data interface negative
199
USB_ID
Input
USB ID
153
UART_RXD
Output
Receive Data (UART1)
169
UART_TXD
Input
Transmit Data (UART1)
154
UART2_RXD
Output
UART2 Receive Data
170
UART2_TXD
Input
UART2 Transmit Data
146
VREG_USIM
Output
Supply output for an UIM card
177
UIM_DET
Input
Detection of an external UIM card
162
UIM_RESET
Output
Reset output to an external UIM card
161
UIM_DATA
Input/Output
Data connection with an external UIM card
163
UIM_CLK
Output
Clock output to an external UIM card
172
GPIO1
Pull-Down
Available-GPIO
128
GPIO2
Pull-Down
Available-GPIO
150
GPIO3
Pull-Down
Available-GPIO
164
GPIO4
Pull-Down
Available-GPIO
139
GPIO5
Pull-Down
Available-GPIO
189
GPIO6
Pull-Down
Available-GPIO
137
GPIO7
Pull-Down
Available-GPIO
138
GPIO8
Pull-Down
Available-GPIO
148
GPIO9
Pull-Down
Available-GPIO
130
GPIO10
Pull-Down
Available-GPIO
AUDIO_INP1
Input
Microphone 1 input positive
AUDIO_INN1
Input
Microphone 1 input negative
17
AUDIO_INP2
Input
Microphone 2 input positive
18
AUDIO_INN2
Input
Microphone 2 input negative
19
AUDIO_LINE_IN
Input
Audio LINE_IN input
48
SPK_OUT3
Output
Speaker 3 output
64
SPK_OUT1
Output
Speaker 1 output
73
SPK_OUT2
Output
Speaker 2 output
195
HSIC_STB
Input/Output
HSIC Strobe signal
194
HSIC_DATA
Input/Output
HSIC data signal
196
HSIC_CAL
Input/Output
HSIC calibration pad
147
RESET_N
Input
External H/W Reset Input
133
RESOUT_N
Output
MDM Reset Output
UART Pads
UIM Pads
GPIO I/F Pads
Analog Audio I/F Pads
HSIC I/F Pads
Reset Pads
ADC I/F Pads
11/30
129
ADC2
Input
Analog to Digital Converter Input
204
ADC1
Input
Analog to Digital Converter Input
LED
Output
LED Driver control
171
SPI_CLK
Output
SPI Serial Clock
186
SPI_MISO
Input
SPI Serial input
201
SPI_MOSI
Output
SPI Serial output
202
SPI_CS_N
Output
SPI Chip Select
ON/OFF
Input
ON/OFF Control
140
SDIO_DATA0
Input/Output
SDIO Data bit 0
122
SDIO_DATA1
Input/Output
SDIO Data bit 1
141
SDIO_DATA2
Input/Output
SDIO Data bit 2
142
SDIO_DATA3
Input/Output
SDIO Data bit 3
131
SDIO_CMD
Output
SDIO Command
132
SDIO_CLK
Output
SDIO Clock
117
I2C_SCL
Output
I2C Clock output
109
I2C_SDA
Input/Output
I2C Data
159
TRST/
Input
Debugging
124
TDI
Input
Debugging
190
TMS
Input
Debugging
175
TCK
Input
Debugging
143
RTCK
Output
Debugging
174
TDO
Output
Debugging
206
JTAG_PS_HOLD
Input
Debugging
166
JTAG_RESIN_NN
Input
Debugging
113
VREG_MDME
Output
Power Supply JTAG (1.8V)
LED I/F Pad
188
SPI I/F Pads
ON/OFF Pad
173
SDIO I/F Pads
I2C I/F Pads
JTAG I/F Pads
Reserved
203
ADC5
Reserved (PMIC MPP_05)
74
AUDIO_RST/
Reserved
75
DEBUG_AUDIO_RST/
Reserved
93
DEBUG_SDOUT3
Reserved
94
I2S_DOUT
Reserved
99
DEBUG_I2C_SCL
Reserved
100
DEBUG_I2C_SDA
Reserved
101
DEBUG_SDOUT2
Reserved
102
I2S_CLK
Reserved
103
I2S_WS
Reserved
110
I2S_DIN
Reserved
111
WIFI_PM_EN
Reserved
112
WIFI_CLK_REQ
Reserved
12/30
120
WIFI_RESET_N
Reserved
180
GPIO68
Reserved
181
GPIO65
Reserved
182
GPIO66
Reserved
197
GPIO67
Reserved
158
PBL_STATUS/HSIC_RST_N
145
XO_OUT
Reserved
155
UART_RTS/
Reserved
156
UART_CTS/
Reserved
160
TCU_PCM_RXD
Reserved
165
WAKE_N
Reserved
176
TCU_PCM_CLK
Reserved
191
TCU_PCM_FRAME
Reserved
192
TCU_PCM_TXD
Reserved
200
I2S_MCLK
Reserved
205
NDR_PULSE
Reserved
149
GPIO_49
Reserved
Clock
Reserved
Ground
1,4,5,6,7,8,9,10,11,13,
14,16,20,21,22,23,24,
25,26,27,28,29,30,31,
32,33,34,35,36,37,38,39
,40,41,42,43,44,45,46,4
7,49,50,51,52,53,54,55,
56,57,58,
59,60,61,62,63,
65,66,67,68,69,
70,71,72,76,77,
78,79,80,83,85,
86,87,88,89,90,
95,96,97,98,104,
105,106,107,108,115,
116,118,119,121,123,
125,127,134,136,144,
151,152,157,167,168,
178,179,184,187,193,20
7,208,209,210,211,212,
213,214,215,216,217,21
GND
Ground
GND
2.1 VCOIN
The TM01LA-N provides an interface for a coin cell to maintain the internal RTC when
+3.7V_VPWR is removed from the TM01LA-N device. Whenever +3.7V_VPWR is applied the
RTC is powered from the +3.7V_VPWR supply.
Table7. VCOIN Interface Specification
VCOIN
Min
DC Power Input Range
Current Draw
Typ
1.1
2.2 ON/OFF Control
13/30
Max
3.2
2.0
Units
µA
The ON/OFF signal is internally pulled up to an internal 1.8V reference voltage. An open drain
transistor should be connected to this pin to generate a low pulse. This pin should not be driven
high external to the TM01LA-N embedded module.
2.2.1 ON/OFF Timing (TBD)
The ON/OFF pin is a low pulse toggle control. The first pulse powers the TM01LA-N ON, a
second pulse instructs the TM01LA-N to begin the Shutdown process.
The diagram below illustrates the recommended application implementation for ON/OFF
control.
The diagram below illustrates an alternate application implementation that holds ON/OFF low
during operation.
14/30
Table8. Power-ON Sequence Symbol Definitions (TBD)
Symbol
Parameter
Min
t ON
Turn ON Pulse duration
TBD
t OFF
Turn OFF Pulse duration
TBD
t pwroff
Time to Power OFF
t pwrrmv
Time +3.7V_VPWR must be
TBD
maintained after
VREG_MDME
goes inactive
t HI
Time required for ON/OFF to
TBD
be
TBD
high prior to OFF pulse.
Typ
TBD
TBD
TBD
Max
TBD
T pwroff is the time between when a power OFF pulse is complete and when shutdown is
completed by the TM01LA-N devices. This duration is network and device dependent, i.e. in a
CDMA network a power down registration is initiated by the TM01LA-N device, when the
acknowledgement is received from the network power OFF completes.
Detection of power down can be accomplished by monitoring for one of the following:
● +WIND: 10 output on the AT Command interface
● USB ports are de-enumerated
The application must wait for a power down to be detected prior to removing power from the
TM01LA-N device. If a timeout is required, it is recommended to be in excess of 30s prior to
removing power from the TM01LA-N device.
2.2.2 Deep Sleep
The TM01LA-N embedded modules support a low power mode in which the device is
registered on the LTE/GSM/WCDMA network and sleeps in between wake intervals where it
listens for pages.
The following table lists the parameter that defines the wake interval period for the various
devices.
Table9. Period of Wake Intervals
15/30
Device
Network Standard
Parameter
TM01LA-N
GSM
DRX
WCDMA
DRX
LTE
DRX
The DRX cycle index values are broadcast by the wireless network on which the TM01LA-N
embedded module is registered.
While in Deep Sleep mode the functions of the TM01LA-N are limited as defined in the
following table.
Table10. Deep Sleep Function Availability
Function
Availability
Paging
Conditions
√
GNSS
Time measurement
GNSS is powered down
√
USB
UART
Digital IO
USB_VBUS is not applied
Digital IO pins maintained last state
Events that cause the TM01LA-N to wake-up from Deep Sleep mode include:

 Incoming call

 Expiration of an internal timer in the TM01LA-N

 USB_VBUS is applied to the TM01LA-N

 WAKE_N is asserted (low)

 UART1 DTR is asserted (high) if UART1 DTR has been enabled as a sleep control
(AT+W32K=1,1) and AT Command Service is mapped to UART1

 GNSS location fix request is initiated from an Embedded Application
2.2.3 Sequence to Enter Deep Sleep Mode
The following list defines the sequence needed by the application to allow the TM01LA-N to
enter Deep Sleep mode:
1. TM01LA-N has registered on the WWAN network (or callbox), and is not in a call.
2. End GNSS Tracking session.
3. Turn off GNSS Antenna bias.
4. Confirm WAKE_N is not held low (pulled-up in TML1-X).
5. Ensure UARTs are in the inactive state.
6. Remove VBUS from being applied to the AR device.
7. Ensure UARTs are in the inactive state.
8. Remove VBUS from being applied to the AR device.
2.3 USB
16/30
The TM01LA-N has a High Speed USB2.0 compliant, peripheral only interface. The TM01LA-N
don’t support OTG.
The TM01LA-N will not be damaged if a valid USB_VBUS is supplied while the main DC power
is not supplied.
Table10. USB Characteristics
USB
USB_VBUS
Voltage range
Maximum Current draw 1
Maximum Input Capacitance
(Min ESR = 50 mΩ)
Value
Units
2.0 – 5.25
10
mA
µF
With the TM01LA-N device powered ON.
2.4 UART
The TM01LA-N has two UART interfaces. The primary UART is an 4-wire electrical interface
and the secondary UART is a 2-wire electrical interface.
Table11. UART Interface PADs
Pin No.
Name
Direction
Description
153
UART_RXD
Output
Receive Data (UART1)
169
UART_TXD
Input
Transmit Data (UART1)
154
UART2_RXD
Output
Receive Data (UART2)
170
UART2_TXD
Input
Transmit Data (UART2)
155
UART_RTS/
Output
Request To Send(UART1)
156
UART_CTS/
Input
Clear To Send(UART1)
2.5 UIM Interface
The UIM interface of the TM01LA-N supports a USIM for LTE, WCDMA and GSM.
Table13. UIM Interface PADs
Pin No.
Name
Direction
Description
146
VREG_USIM
Output
Supply output for an UIM card
177
UIM_DET
Input
Detection of an external UIM card
162
UIM_RESET
Output
Reset output to an external UIM card
161
UIM_DATA
Input/Output
Data connection with an external UIM card
163
UIM_CLK
Output
Clock output to an external UIM card
2.6 General Purpose IO
17/30
The TM01LA-N defines 10 GPIOs for customer use.
Table14. GPIO Inferface PADs
Pin No.
Name
Direction
Description
172
GPIO1
Pull-Down
Available-GPIO
128
GPIO2
Pull-Down
Available-GPIO
150
GPIO3
Pull-Down
Available-GPIO
164
GPIO4
Pull-Down
Available-GPIO
139
GPIO5
Pull-Down
Available-GPIO
189
GPIO6
Pull-Down
Available-GPIO
137
GPIO7
Pull-Down
Available-GPIO
138
GPIO8
Pull-Down
Available-GPIO
148
GPIO9
Pull-Down
Available-GPIO
130
GPIO10
Pull-Down
Available-GPIO
2.7 Secure Digital IO
The TM01LA-N defines a 1.8V SDIO interface for future use.
Table15. SDIO Inferface PADs
Pin No.
Name
Direction
Description
140
SDIO_DATA0
Input/Output
SDIO Data bit 0
122
SDIO_DATA1
Input/Output
SDIO Data bit 1
141
SDIO_DATA2
Input/Output
SDIO Data bit 2
142
SDIO_DATA3
Input/Output
SDIO Data bit 3
131
SDIO_CMD
Output
SDIO Command
132
SDIO_CLK
Output
SDIO Clock
2.8 I2C Interface
The TM01LA-N provides an I2C interface.
The I2C signals are open drain outputs with 2.2 kΩ pull-up resistors toVREG_MDME (1.8V)
internal to the TML1-X.
Table16. I2C Inferface PADs
Pin No.
Name
Direction
Description
117
I2C_SCL
Output
I2C Clock output
109
I2C_SDA
Input/Output
I2C Data
2.9 RESET
18/30
The TM01LA-N provides an interface to allow an external application to RESET the module as
well as an output to indicate the current RESET state or control an external device.
The RESIN_N signal is pulled-up internal to the TML1-X. An open collector transistor or
equivalent should be used to Ground the signal when necessary to RESET the module.
Note: Use of the RESIN_N signal to RESET the TM01LA-N could result in memory
corruption if used inappropriately. This signal should only be used if the TM01LA-N has
become unresponsive and it is not possible to perform a power cycle.
Table17. Reset Timing
Symbol
Parameter
Trdet
Duration of RESIN_N signal before firmware
detects it
(debounce timer)
Trlen
Duration reset asserted
Trdel
Delay between minimum Reset duration and
Internal Reset generated
Min
tbd
Figure . Illustration of Reset Timing When RESIN_N < Trdel
Figure. Illustration of Reset Timing When RESIN_N Held Low > Trdet+Trdel
2.10 ADC
19/30
Typ
tbd
tbd
Max
The TM01LA-N provides two ADC inputs. The interface information is provided in the tables
below.
Table18. ADC Interface Characteristics
ADC
ADCx
Full-Scale Voltage Level
Resolution
Sample rate
Input Impedance
Value
0.05 ~ 1.75
15
1.15(tbd)
>4
Units
bit
KHz
MΩ
2.11 LED driver
The TM01LA-N provides an LED driver. The LED driver is a programmable current sink.
Table19. LED Inferface PAD
Pin No.
Name
Direction
Description
188
LED
Output
LED Driver control
2.12 Audio
The TM01LA-N supports Analog audio interfaces.
The ADC blocks supports Stereo 24-bit Inputs (Differential, Single-ended) and Mono 24-bit
(Line-In).
The DAC blocks supports Stereo 24-bit output (Stereo) and Line output (Single-ended).
Table20. Audio Inferface PADs
Pin No.
Name
Direction
Description
AUDIO_INP1
Input
Microphone 1 input positive
AUDIO_INN1
Input
Microphone 1 input negative
17
AUDIO_INP2
Input
Microphone 2 input positive
18
AUDIO_INN2
Input
Microphone 2 input negative
19
AUDIO_LINE_IN
Input
Audio LINE_IN input
48
SPK_OUT3
Output
Speaker 3 output
64
SPK_OUT1
Output
Speaker 1 output
73
SPK_OUT2
Output
Speaker 2 output
2.13 SPI Interface
The TM01LA-N embedded module provides one SPI bus (4-wire interface).
SPI bus interface includes:
20/30

 A CLK signal

 An O signal

 An I signal

 A CS (Chip Select) signal
The following features are available on the SPI bus :

 Master-only mode operation

 SPI speed is from 128 kbit/s to 26Mbit/s in master mode operation

 4-wire interface

 4 to 32 bits data length.
Table21. SPI Inferface PADs
Pin No.
Name
Direction
Description
171
SPI_CLK
Output
SPI Serial Clock
186
SPI_MISO
Input
SPI Serial input
201
SPI_MOSI
Output
SPI Serial output
202
SPI_CS_N
Output
SPI Chip Select
2.14 HSIC Interface
The TM01LA-N embedded module provides one HSIC bus (2-wire interface).
HSIC bus interface includes:

 HSIC strobe signal

 HSIC data signal

 Calibration pad for HSIC port signal
Table22. HSIC Inferface PADs
Pin No.
Name
Direction
Description
195
HSIC_STB
Input/Output
HSIC Strobe signal
194
HSIC_DATA
Input/Output
HSIC data signal
196
HSIC_CAL
Input/Output
HSIC calibration pad
2.15 JTAG Interface
JTAG test points on customer application are recommended for possible failure analysis if
necessary in the future.
Table23. JTAG Inferface PADs
Pin No.
Name
Direction
Description
159
TRST/
Input
Debugging
21/30
124
TDI
Input
Debugging
190
TMS
Input
Debugging
175
TCK
Input
Debugging
143
RTCK
Output
Debugging
174
TDO
Output
Debugging
206
JTAG_PS_HOLD
Input
Debugging
166
JTAG_RESIN_NN
Input
Debugging
113
VREG_MDME
Output
Power Supply JTAG (1.8V)
3. RF Specification
The specifications for the LTE, GSM and WCDMA interfaces are defined.
TM01LA-N is designed to be compliant with the standard shown in the table below.
Table24. Standards Compliance
Technology
Standards
• 3GPP Release 5
UMTS (WCDMA)
• 3GPP Release 6
• 3GPP Release 7
• 3GPP Release 8
LTE
• 3GPP Release 8
GSM/GPRS/EDGE
• 3GPP Release R99
3.1 WCDMA B1, B2, B4, B5 Specification
3.1.1 WCDMA TX Output Power
The Maximum / Minimum Transmitter Output Power of the TM01LA-N are specified in the
following table.
22/30
Table25.
Band
WCDMA Band 2
Power Level
WCDMA Band 4
Power Level
WCDMA Band 5
Power Level
Method (UL CH)
Specification
Measure Max and Min Transmit Power of Low
Channel (CH=9263) in WCDMA B2 Mode
Max Power : 20.2~24.2dBm
Min Power : ≤ -50dBm
Measure Max and Min Transmit Power of Middle
Channel (CH=9400) in WCDMA B2 Mode
Max Power : 20.2~24.2dBm
Min Power : ≤ -50dBm
Measure Max and Min Transmit Power of High
Channel (CH=9537) in WCDMA B2 Mode
Max Power : 20.2~24.2dBm
Min Power : ≤ -50dBm
Measure Max and Min Transmit Power of Low
Channel (CH=1313) in WCDMA B4 Mode
Max Power : 20.2~24.2dBm
Min Power : ≤ -50dBm
Measure Max and Min Transmit Power of Middle
Channel (CH=1413) in WCDMA B4 Mode
Max Power : 20.2~24.2dBm
Min Power : ≤ -50dBm
Measure Max and Min Transmit Power of High
Channel (CH=1513) in WCDMA B4 Mode
Max Power : 20.2~24.2dBm
Min Power : ≤ -50dBm
Measure Max and Min Transmit Power of Low
Channel (CH=4133) in WCDMA B5 Mode
Max Power : 20.2~24.2dBm
Min Power : ≤ -50dBm
Measure Max and Min Transmit Power of Middle
Channel (CH=4183) in WCDMA B5 Mode
Max Power : 20.2~24.2dBm
Min Power : ≤ -50dBm
Measure Max and Min Transmit Power of High
Channel (CH=4232) in WCDMA B5 Mode
Max Power : 20.2~24.2dBm
Min Power : ≤ -50dBm
3.1.2 WCDMA RX Sensitivity
The Receiver Sensitivity of the TM01LA-N are specified in the following table.
Table26. Conducted RX (Receive) Sensitivity – WCDMA Bands
Item
WCDMA Band 2
BER(Bit Error
Rate)
WCDMA Band 4
BER(Bit Error
Rate)
WCDMA Band 5
BER(Bit Error
Rate)
Method (DL CH)
Specification
Measure BER of Low Channel (CH=9663) in
WCDMA B2 Mode
Measure BER of Middle Channel (CH=9800) in
WCDMA B2 Mode
Measure BER of High Channel (CH=9937) in
WCDMA B2 Mode
Measure BER of Low Channel (CH=1538) in
WCDMA B4 Mode
Measure BER of Middle Channel (CH=1675) in
WCDMA B4 Mode
Measure BER of High Channel (CH=1737) in
WCDMA B4 Mode
Measure BER of Low Channel (CH=4358) in
WCDMA B5 Mode
Measure BER of Middle Channel (CH=4400) in
WCDMA B5 Mode
Measure BER of High Channel (CH=4457) in
WCDMA B5 Mode
3.2. LTE B2, B4, B5, B7, B17 Specification
3.2.1 LTE TX Output Power
23/30
0~0.1% @<-104.7dBm
0~0.1% @<-104.7dBm
0~0.1% @<-104.7dBm
0~0.1% @<-106.7dBm
0~0.1% @<-106.7dBm
0~0.1% @<-106.7dBm
0~0.1% @<-104.7dBm
0~0.1% @<-104.7dBm
0~0.1% @<-104.7dBm
The Maximum / Minimum Transmitter Output Power of the TM01LA-N are specified in the
following table.
Table27. Conducted TX (Transmit) Max output Power Tolerances – LTE Bands
BAND
BAND2
UE Maximum
Output Power
BAND4
UE Maximum
Output Power
BAND5
UE Maximum
Output Power
BAND7
UE Maximum
Output Power
BAND17
UE Maximum
Output Power
Method (UL CH)
Specification
Measure Max and Min Transmit Power of Low
Channel (650)
Measure Max and Min Transmit Power of Mid
Channel (900)
Measure Max and Min Transmit Power of High
Channel (1150)
Measure Max and Min Transmit Power of Low
Channel (2000)
Measure Max and Min Transmit Power of Mid
Channel (2175)
Measure Max and Min Transmit Power of High
Channel (2350)
Measure Max and Min Transmit Power of Low
Channel (2450)
Measure Max and Min Transmit Power of Mid
Channel (2525)
Measure Max and Min Transmit Power of High
Channel (2600)
Measure Max and Min Transmit Power of Low
Channel (2800)
Measure Max and Min Transmit Power of Mid
Channel (3100)
Measure Max and Min Transmit Power of High
Channel (3400)
Measure Max and Min Transmit Power of Low
Channel (23735)
Measure Max and Min Transmit Power of Mid
Channel (23790)
Measure Max and Min Transmit Power of High
Channel (23845)
Max Power : 19.3~25.7dBm
Min Power : ≤ -39dBm
Max Power : 19.3~25.7dBm
Min Power : ≤ -39dBm
Max Power : 19.3~25.7dBm
Min Power : ≤ -39dBm
Max Power : 19.3~25.7dBm
Min Power : ≤ -39dBm
Max Power : 19.3~25.7dBm
Min Power : ≤ -39dBm
Max Power : 19.3~25.7dBm
Min Power : ≤ -39dBm
Max Power : 19.3~25.7dBm
Min Power : ≤ -39dBm
Max Power : 19.3~25.7dBm
Min Power : ≤ -39dBm
Max Power : 19.3~25.7dBm
Min Power : ≤ -39dBm
Max Power : 19.3~25.7dBm
Min Power : ≤ -39dBm
Max Power : 19.3~25.7dBm
Min Power : ≤ -39dBm
Max Power : 19.3~25.7dBm
Min Power : ≤ -39dBm
Max Power : 19.3~25.7dBm
Min Power : ≤ -39dBm
Max Power : 19.3~25.7dBm
Min Power : ≤ -39dBm
Max Power : 19.3~25.7dBm
Min Power : ≤ -39dBm
3.2.2 LTE RX Sensitivity
The Receiver Sensitivity of the TM01LA-N are specified in the following table.
Table28. Conducted RX (Receive) Sensitivity – LTE Bands
BAND
Method (DL CH)
Specification
Measure BLER of Low Channel (650) in Band2
BAND2
Reference
sensitivity
level(DUAL)
Measure BLER of Mid Channel (900) in Band2
BAND 4
Reference
Measure BLER of Low Channel (2000) in Band4
Measure BLER of High Channel (1150) in Band2
24/30
sensitivity : ≤-95
BLER : ≤ 5%
sensitivity : ≤-95
BLER : ≤ 5%
sensitivity : ≤-95
BLER : ≤ 5%
sensitivity : ≤-97
BLER : ≤ 5%
sensitivity
level(DUAL)
Measure BLER of Mid Channel (2175) in Band4
Measure BLER of High Channel (2350) in Band4
BAND 5
Reference
sensitivity
level(DUAL)
BAND 7
Reference
sensitivity
level(DUAL)
BAND 17
Reference
sensitivity
level(DUAL)
Measure BLER of Low Channel (2450) in Band5
Measure BLER of Mid Channel (2525) in Band5
Measure BLER of High Channel (2600) in Band5
Measure BLER of Low Channel (2800) in Band7
Measure BLER of Mid Channel (3100) in Band7
Measure BLER of High Channel (3400) in Band7
Measure BLER of Low Channel (5735) in Band12
Measure BLER of Mid Channel (5790) in Band12
Measure BLER of High Channel (5845) in Band12
sensitivity : ≤-97
BLER : ≤ 5%
sensitivity : ≤-97
BLER : ≤ 5%
sensitivity : ≤-95
BLER : ≤ 5%
sensitivity : ≤-95
BLER : ≤ 5%
sensitivity : ≤-95
BLER : ≤ 5%
sensitivity : ≤-95
BLER : ≤ 5%
sensitivity : ≤-95
BLER : ≤ 5%
sensitivity : ≤-95
BLER : ≤ 5%
sensitivity : ≤-94
BLER : ≤ 5%
sensitivity : ≤-94
BLER : ≤ 5%
sensitivity : ≤-94
BLER : ≤ 5%
3.3 GSM 850, 900,1800, 1900 Specification
3.3.1 GSM TX Output Power
The Maximum Transmitter Output Power of the TM01LA-N are specified in the following
table.
Table29. Conducted TX (Transmit) Max output Power Tolerances – GSM/EDGE Bands
Item
GSM850
Power Level
EGSM900
Power Level
DCS1800
Power Level
PCS1900
Power Level
Method (DL CH)
Specification
Measure Max Transmit Power of Low Channel
(CH=128) in GSM850 Mode
Measure Max Transmit Power of Middle Channel
(CH=189) in GSM850 Mode
Measure Max Transmit Power of High Channel
(CH=251) in GSM850 Mode
Measure Max Transmit Power of Low Channel
(CH=975) in EGSM Mode
Measure Max Transmit Power of Middle Channel
(CH=38) in EGSM Mode
Measure Max Transmit Power of High Channel
(CH=124) in EGSM Mode
Measure Max Transmit Power of Low Channel
(CH=512) in DCS1800 Mode
Measure Max Transmit Power of Middle Channel
(CH=660) in DCS1800 Mode
Measure Max Transmit Power of High Channel
(CH=885) in DCS1800 Mode
Measure Max Transmit Power of Low Channel
(CH=512) in DCS1900 Mode
Measure Max Transmit Power of Middle Channel
(CH=660) in DCS1900 Mode
Measure Max Transmit Power of High Channel
(CH=810) in DCS1900 Mode
25/30
Max Power : 31.0~33.5dBm
Max Power : 31.0~33.5dBm
Max Power : 31.0~33.5dBm
Max Power : 31.0~33.5dBm
Max Power : 31.0~33.5dBm
Max Power : 31.0~33.5dBm
Max Power : 28.0~30.5dBm
Max Power : 28.0~30.5dBm
Max Power : 28.0~30.5dBm
Max Power : 28.0~30.5dBm
Max Power : 28.0~30.5dBm
Max Power : 28.0~30.5dBm
3.3.2 GSM RX Sensitivity
The Receiver Sensitivity of the TM01LA-N are specified in the following table.
Table30. Conducted RX (Receive) Sensitivity – GSM/EDGE Bands
Item
Method (DL CH)
GSM850
BER(Bit Error
Rate)
EGSM900
BER(Bit Error
Rate)
DCS1800
BER(Bit Error
Rate)
PCS1900
BER(Bit Error
Rate)
Specification
Measure BER of Low Channel (CH=128)
in GSM850 Mode
Measure BER of Middle Channel (CH=189)
in GSM850 Mode
Measure BER of High Channel (CH=251)
in GSM850 Mode
Measure BER of Low Channel (CH=975)
in EGSM Mode
Measure BER of Middle Channel (CH=38)
in EGSM Mode
Measure BER of High Channel (CH=124)
in EGSM Mode
Measure BER of Low Channel (CH=512)
in DCS1800 Mode
Measure BER of Middle Channel (CH=660)
in DCS1800 Mode
Measure BER of High Channel (CH=885)
in DCS1800 Mode
Measure BER of Low Channel (CH=512)
in PCS1900 Mode
Measure BER of Middle Channel (CH=660)
in PCS1900 Mode
Measure BER of High Channel (CH=810)
in PCS1900 Mode
0~2.439% @<-102dBm
0~2.439% @<-102dBm
0~2.439% @<-102dBm
0~2.439% @<-102dBm
0~2.439% @<-102dBm
0~2.439% @<-102dBm
0~2.439% @<-102dBm
0~2.439% @<-102dBm
0~2.439% @<-102dBm
0~2.439% @<-102dBm
0~2.439% @<-102dBm
0~2.439% @<-102dBm
4. GNSS
The TM01LA-N includes optional Global Navigation Satellite System(GNSS) capabilities via
the Qualcomm gpsOne Gen8A Engine, capable of operation in assisted and stand-alone GPS
modes as well as GPS+GLONASS mode.
Table33. Position location and navigation summary(gpsOne™)
Standard
Feature descriptions
gpsOne with global navigation satellite system (GNSS) support
■ Global positioning system (GPS)
¨ □ Next-generation gpsOne™ solution with enhanced GNSS engine and low power tracking
¨ □ Enhanced navigation 3.0, dynamic power optimization, and on-demand positioning
Gen8A
¨ □ Support for Wi-Fi positioning
¨ □ MS/UE-based, MS/UE-assisted, hybrid modes with AFLT (CDMA), NMR (GSM), and
MRL(UMTS, WCDMA, LTE), standalone and network-aware modes
¨ □ gpsOneXTRA Assistance for enhanced standalone GNSS performance
¨ □ Control plane: IS-801, IS-881, and UMTS CP assisted-GNSS protocols
26/30
¨ □ User plane: v1/v2 trusted mode and OMA SUPL 2.0 assisted-GPS protocols
¨ □ Wideband processing of GPS signals helps resolve multipath interference, promoting improved
measurement accuracy
■ Support for GLONASS standalone mode
¨ □ GLONASS capability increases the number of satellites available to the positioning engine,
resulting in an expanded area of coverage over traditional GPS receivers
4.1 GNSS Characteristics
The GNSS implementation supports GPS L1 operation and GLONASS L1 FDMA operation.
Table34. GNSS Characteristics
Parameter
*Sensitivity
Value
Standalone or MS Based Tracking Sensitivity
TBD
Cold Start Sensitivity
TBD
MS Assisted Synchronous A-GNSS Acquisition Sensitivity
TBD
Accuracy in Open Sky (1 Hz tracking)
<2m CEP-50
Total number of SV available
~30 SVs
Support for Predicted Orbits
Yes
Predicted Orbit CEP-50 Accuracy
5m
Standalone Time To First Fix (TTFF)
Super Hot
1s
Warm
29 s
Cold
32 s
GNSS Message Protocols
NMEA
Note: Acquisition/Tracking Sensitivity performance figures assume open sky w/ active patch
GNSS antenna and a 2.5 dB Noise Figure.
4.2 GNSS Antenna Interface
Table35. GNSS Antenna Interface Characteristics
Characteristics
GNSS
GPS L1 (Wideband)
1575.42 ± 20 MHz
Frequency
Glonass L1 FDMA
1597.5 – 1605.8 MHz
RF Impedance
50 Ω
VSWR max
RX
2:1
4.3 Active antenna Powering the External LNA
The external LNA needs a source of power. Many of the active antennas accept a 3 volt or 5
volt DC voltage that is impressed upon the RF signal line. This voltage is not supplied by the
TML1-X, but can be easily supplied by the host design.
4.3.1 External LNA Enable
27/30
The electrical characteristics of the GNSS_LNA_EN signal are:
Table36. GNSS_LNA EN Table
Parameter
GNSS_LNA_EN
Output high level
Output low level
Min
1.6
Typ
Max
1.9
0.2
An example of GPS Antenna Supply circuit is shown in the following image:
28/30
Units
29/30

FCC Part 15.19 Statements:
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.
FCC Part 15.21 statement
Any changes or modifications not expressly approved by the party responsible for
compliance could void the user's authority to operate this equipment.
RF Exposure Statement
The antenna(s) must be installed such that a minimum separation distance of at least 20 cm
is maintained between the radiator (antenna) and all persons at all times. This device must
not be co-located or operating in conjunction with any other antenna or transmitter.
The highest permitted antenna gains including cable loss for use with this device are: GSM850 /
WCDMA850 : -3.25 dBi, GSM1900 / WCDMA1900 : 1.26 dBi, WCDMA1700 : -0.13 dBi, LTE Band 2:
1.26 dBi, LTE Band 5: -3.25 dBi, LTE Band 17: -3.03 dBi, LTE Band 4: -0.13 dBi, LTE Band 7: -0.22
dBi, LTE Band 12: -3.03 dBi..
End Product Labeling
The module is labeled with its own FCC ID. If the FCC ID is not visible when the module is
installed inside another device, then the outside of the device into which the module is
installed must also display a label referring to the enclosed module. In that case, the final
end product must be labeled in a visible area with the following:
“Contains FCC ID: BEJLGAJ10N
" Contains IC: 2703H-LGAJ10N
OEM Responsibilities to comply with FCC Regulations
The module has been certified for integration into products only by OEM integrators under
the following condition:
- The antenna(s) must be installed such that a minimum separation distance of at least 20
cm is maintained between the radiator (antenna) and all persons at all times.
- The transmitter module must not be co-located or operating in conjunction with any other
antenna or transmitter except in accordance with FCC multi-transmitter product procedures.
As long as the two condition above is met, further transmitter testing 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 (for example, digital
device emissions, PC peripheral requirements, etc.).
IMPORTANT NOTE: In the event that these conditions can ’ t be met (for certain
configurations or co-location with another transmitter), then the FCC authorization is no
longer considered valid and the FCC ID can’t 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.
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 or change RF related parameters in the user
manual of the end product.
30/30
l'exposition aux RF
L’antenne (ou les antennes) doit être installée de façon à maintenir à tout instant une distance
minimum de au moins 20 cm entre la source de radiation (l’antenne) et toute personne physique.
Étiquetage du produit final
Le module BT111 est étiqueté avec sa propre identification FCC et son propre numéro de
certification IC. Si l’identification FCC et le numéro de certification IC ne sont pas visibles lorsque
le module est installé à l’intérieur d’un autre dispositif, la partie externe du dispositif dans lequel
le module est installé devra également présenter une étiquette faisant référence au module inclus.
Dans ce cas, le produit final devra être étiqueté sur une zone visible avec les informations
suivantes :
« Contient module émetteur identification FCC ID : BEJLGAJ10N
« Contient module émetteur IC : 2703H-LGAJ10N
RSS-GEN, Sec. 8.3
This radio transmitter (identify the device by certification number, or model number if Category II)
has been approved by Industry Canada to operate with the antenna types listed below with the
maximum permissible gain and required antenna impedance for each antenna type indicated.
Antenna types not included in this list, having a gain greater than the maximum gain indicated for
that type, are strictly prohibited for use with this device.
Le présent émetteur radio (identifier le dispositif par son numéro de certification ou son numéro
de modèle s’il fait partie du matériel de catégorie I) a été approuvé par Industrie Canada pour
fonctionner avec les types d’antenne énumérés ci-dessous et ayant un gain admissible maximal et
l’impédance requise pour chaque type d’antenne. Les types d’antenne non inclus dans cette liste,
ou dont le gain est supérieur au gain maximal indiqué, sont strictement interdits pour l’exploitation
de l’émetteur.

---

Source Exif Data:

File Type                       : PDF
File Type Extension             : pdf
MIME Type                       : application/pdf
PDF Version                     : 1.6
Linearized                      : No
Has XFA                         : No
XMP Toolkit                     : Adobe XMP Core 5.4-c005 78.147326, 2012/08/23-13:03:03
Format                          : application/pdf
Creator                         : 
Description                     : Microsoft Word - TM01LA-N_User Manual_Rev04
Title                           : Microsoft Word - TM01LA-N_User Manual_Rev04
Create Date                     : 2016:11:10 16:21:39
Creator Tool                    : nPDF, http://iblogbox.com/npdf
Modify Date                     : 2016:11:11 23:39:48+09:00
Metadata Date                   : 2016:11:11 23:39:48+09:00
Keywords                        : 
Producer                        : nPDF, http://iblogbox.com/npdf
Document ID                     : uuid:a2fcbcd2-a01c-48e8-8d78-d413418b664f
Instance ID                     : uuid:fa40a753-9203-49ce-840c-d07b6ea54202
Page Count                      : 31
Author                          : 
Subject                         : Microsoft Word - TM01LA-N_User Manual_Rev04

EXIF Metadata provided by EXIF.tools