Users Manual Rev 2
Integrated Transceiver Modules for WLAN 802.11 b/g/n
FEATURES
IEEE 802.11b,g,n,d,e,i compliant
Typical WLAN Transmit Power:
o 20.0dBm, 11 Mbps,CCK (b)
o 14.5dBm, 54 Mbps,OFDM (g)
o 12.5dBm, 65 Mbps,OFDM (n)
Typical WLAN Sensitivity:
o -89dBm, 8% PER, 11 Mbps
o -76dBm, 10% PER, 54 Mbps
o -73dBm, 10% PER, 65 Mbps
Miniature footprint: 18 mm x 13 mm
Low height profile: 1.9 mm
U.FL connector for external antenna
Terminal for PCB/Chip antenna feeds
Integrated band-pass filter
Compact design based on Texas
Instruments WL1271L Transceiver
Seamless integration with TI OMAP™
application processors
SDIO Host data path interfaces
Bluetooth Advanced Audio Interfaces
Low power operation mode
RoHS compliant
APPLICATIONS
Security
HVAC Control, Smart Energy
Sensor Networks
Medical
DESCRIPTION
The TiWi-BLE module is a high performance
2.4 GHz IEEE 802.11 b/g/n radio in a cost
effective, pre-certified footprint.
The module realizes the necessary PHY/MAC
layers to support WLAN applications in
conjunction with a host processor over a SDIO
interface.
ELECTRICAL SPECIFICATIONS
The majority of these characteristics are based on controlling and conditioning the tests using the TiWi-
BLE control software application. Other control conditions may require these values to be re-
characterized by the customer.
Absolute Maximum Ratings
Parameter Min Max Unit
Power supply voltage (VBAT)(4)(5) -0.5 +5.5 V
Digital supply voltage (VIO) -0.5 2.1 V
Voltage on any GPIO -0.5 VIO + 0.5 V
Voltage on any Analog Pins(3) -0.5 2.1 V
RF input power, antenna port +10 dBm
Operating temperature(6) -40 +85 ºC
Storage temperature -55 +125 ºC
1. Stresses beyond those listed under “absolute maximum ratings” may cause permanent damage to the device and are not
covered by the warranty. These are stress ratings only and functional operation of the device at these or any other
conditions beyond those indicated under “recommended operating conditions” is not implied. Exposure to absolute-
maximum-rated conditions for extended periods may affect device reliability.
2. All parameters are measured as follows unless stated otherwise: VDD_IN=1.8V, VDDIO_1.8V=1.8V,
VDD_LDO_CLASS1P5=3.6V
3. Analog pins: XTALP, XTALM, RFIOBT, DRPWRXBM, DRPWRXBP, DRPWTXB, and also FMRFINP, FMRFINM,
FMRFINM, FMAUDLIN, FMAUDRIN, FMAUDLOUT, FMAUDROUT
4. The following signals are from the VBAT group, PMS_VBAT and VDD_LDO_CLASS1P5 (if BT class 1.5 direct VBAT is
used).
5. Maximum allowed depends on accumulated time at that voltage; 4.8V for 7 years lifetime, 5.5V for 6 hours cumulative.
6. The device can be reliably operated for 5,000 active-WLAN cumulative hours at TA of 85oC.
Table 1 Absolute Maximum Ratings
Recommended Operating Conditions
Parameter Min Typ Max Unit
VBAT 3.0 3.6 4.8 V
VIO 1.62 1.8 1.92 V
VIH 0.65 x VIO - VIO V
VIL 0 - 0.35 x VIO V
VOH @ 4, 8 mA VIO - 0.45 - VIO V
VOL @ 4, 8 mA 0 - 0.45 V
Ambient temperature range -40 25 85 ºC
Table 2 Recommended Operating Conditions
General Characteristics
Parameter Min Typ Max Unit
WLAN RF frequency range 2412 2472 MHz
WLAN RF data rate 1
802.11 b/g/n
rates
supported
65 Mbps
Table 3 General Characteristics
Power Consumption - WLAN
Parameter Test Conditions Min Typ Max Unit
CCK (802.11b)
TX Current
2437 MHz, VBAT =3.6V, Tamb=+25°C
Po=20dBm, 11 Mbps CCK
L=1200 bytes, tdelay (idle)=4 S
- 280 - mA
OFDM (802.11g)
TX Current
2437 MHz, VBAT =3.6V, Tamb=+25°C
Po=14.5 dBm, 54 Mbps OFDM
L=1200 bytes, tdelay (idle)=4S
- 185 - mA
OFDM (802.11n)
TX Current
2437 MHz, VBAT =3.6V, Tamb=+25°C
Po=12.5dBm, 65 Mbps OFDM
L=1200 bytes, tdelay (idle)=4S
- 165 - mA
CCK (802.11b)
RX Current - 100 - mA
OFDM (802.11g)
RX Current - 100 - mA
OFDM (802.11n)
RX Current - 100 - mA
Dynamic Mode [1] - <1.2 - mA
[1] Total Current from VBAT for reception of Beacons with DTIM=1 TBTT=100 mS, Beacon duration 1.6ms, 1 Mbps beacon
reception in Listen Mode.
Table 4 WLAN Power Consumption
DC Characteristics – General Purpose I/O
Parameter Test Conditions Min Typ Max Unit
VIO Current - 16 mA
Logic input low, VIL 0 - 0.35 x VIO V
Logic input high, VIH 0.65 x VIO - VIO V
Logic output low, VOL
(Full Drive)
Iout = 8 mA 0 - 0.45 V
Iout = 4 mA 0 - 0.45 V
Logic output low, VOL
(Reduced Drive)
Iout = 1 mA 0 - 0.112 V
Iout = 0.09 mA 0 - 0.01 V
Logic output high, VOH
(Full Drive)
Iout = -8 mA VIO - 0.45 - VIO V
Iout = -4 mA VIO - 0.45 - VIO V
Logic output high, VOH
(Reduced Drive)
Iout = -1 mA VIO - 0.112 - VIO V
Iout = -0.3 mA VIO - 0.033 - VIO V
Table 5 DC Characteristics General Purpose I/O
WLAN RF Characteristics
WLAN Transmitter Characteristics
(TA=25°C, VBAT=3.6 V)
Parameter Test Conditions Min Typ Max Unit
11 Mbps CCK (802.11b)
TX Output Power
11 Mbps CCK , 802.11(b) Mask
Compliance, 35% EVM
RMS power over TX packet
- 20 - dBm
9 Mbps OFDM (802.11g)
TX Output Power
9 Mbps OFDM , 802.11(g) Mask
Compliance, -8 dB EVM
RMS power over TX packet
- 19 - dBm
54 Mbps OFDM (802.11g)
TX Output Power
54 Mbps OFDM, 802.11(g) Mask
Compliance, -25 dB EVM
RMS power over TX packet
- 14.5 - dBm
6.5 Mbps OFDM (802.11n)
TX Output Power
6.5 Mbps OFDM, 802.11(n) Mask
Compliance, -5 dB EVM
RMS power over TX packet
- 19 - dBm
65 Mbps OFDM (802.11n)
TX Output Power
65 Mbps OFDM, 802.11(n) Mask
Compliance, -28 dB EVM
RMS power over TX packet
- 12.5 - dBm
Table 6 WLAN Transmitter RF Characteristics
WLAN Receiver Characteristics
(TA=25°C, VBAT=3.6 V) [1]
Parameter Test Conditions Min Typ Max Unit
1 Mbps CCK (802.11b)
RX Sensitivity 8% PER - -97 - dBm
11 Mbps CCK (802.11b)
RX Sensitivity 8% PER - -89 - dBm
9 Mbps OFDM (802.11g)
RX Sensitivity 10% PER - -90 - dBm
54 Mbps OFDM (802.11g)
RX Sensitivity 10% PER - -76 - dBm
6.5 Mbps OFDM (802.11n)
RX Sensitivity 10% PER - -91 - dBm
65 Mbps OFDM (802.11n)
RX Sensitivity 10% PER - -73 -- dBm
11 Mbps CCK (802.11b)
RX Overload Level 8% PER - - -10 dBm
6 Mbps OFDM (802.11g)
RX Overload Level 10% PER - - -20 dBm
54 Mbps OFDM (802.11g)
RX Overload Level. 10% PER - - -20 dBm
65 Mbps OFDM (802.11n)
RX Overload Level 10% PER - - -20 dBm
[1] Up to 2 dB degradation at Channel 13 for 11g/n modes and up to 2 dB degradation at Channel 14 for 11b/g/n modes.
Table 7 WLAN Receiver RF Characteristics
WLAN POWER-UP SEQUENCE
The following sequence describes device power-up from shutdown. Only the WLAN Core is enabled; the
Bluetooth and FM cores are disabled.
Figure 1 TiWi-BLE Power-up Sequence Requirements
1. No signals are allowed on the IO pins if no IO power is supplied, because the IOs are not 'failsafe’.
Exceptions are CLK_REQ_OUT, SLOWCLK, XTALP, and AUD_xxx, which are failsafe and can
tolerate external voltages with no VDDS and DC2DC".
2. VBAT, VIO, and SLOWCLK must be available before WL_EN.
3. Twakeup = T1 + T2
The duration of T1 is defined as the time from WL_EN=high until Fref is valid for the SoC. T1=~55ms
The duration of T2 depends on:
Operating system
– Host enumeration for the SDIO/WSPI
– PLL configuration
– Firmware download
– Releasing the core from reset
– Firmware initialization
WLAN POWER-DOWN SEQUENCE
Notes:
1. The DC2DC(1.8V) signal can be monitored on BT_FUNC2 Module Pin (#41)
2. DC_REQ and CLK_REQ are internal signals shown for reference only
Figure 2 TiWi-BLE Module Power-down Sequence Requirements
1. DC_REQ will go low only if WLAN is the only core working. Otherwise if another core is working (e.g
BT) it will stay high.
2. CLK_REQ will go low only if WLAN is the only core working. Otherwise if another core is working and
using the FREF (e.g BT) it will stay high.
3. If WLAN is the only core that is operating, WL_EN must remain de-asserted for at least 64sec
before it is re-asserted.
IRQ OPERATION
1. The default state of the WLAN_IRQ prior to firmware initialization is 0.
2. During firmware initialization, the WLAN_IRQ is configured by the SDIO module; a WLAN_IRQ changes
its state to 1.
3. A WLAN firmware interrupt is handled as follows:
a. The WLAN firmware creates an Interrupt-to-Host, indicated by a 1-to-0 transition on the
WLAN_IRQ line (host must be configured as active-low or falling-edge detect).
b. After the host is available, depending on the interrupt priority and other host tasks, it masks the
firmware interrupt. The WLAN_IRQ line returns to 1 (0-to-1 transition on the WLAN_IRQ line).
c. The host reads the internal register status to determine the interrupt sources - the register is
cleared after the read.
d. The host processes in sequence all the interrupts read from this register
e. The host unmasks the firmware interrupts.
4. The host is ready to receive another interrupt from the WLAN device.
SLOW (32 KHZ) CLOCK SOURCE REQUIREMENTS
The slow clock is always supplied from an external source. It is input on the SLOW_CLK pin, and can be a digital
signal in the range of VIO only. For slow clock frequency and accuracy refer to Table 8. The external slow clock
must be stable before the system exits from shut down mode.
Parameter [1] Condition Symbol Min Typ Max Unit
Input slow clock frequency 32768 Hz
Input slow clock accuracy WLAN, BT +/-250 ppm
Input transition time Tr/Tf – 10% to 90% Tr/Tf 100 ns
Frequency input duty cycle 30 50 70 %
Input voltage limits Square wave,
DC coupled
VIH 0.65 x VDDS VDDS Vpeak
VIL 0 0.35 x VDDS
Input impedance 1 MW
Input capacitance 5 pF
Rise and fall time 100 ns
Phase noise 1 kHz -125 dBc/Hz
[1] Slow clock is a fail safe input
Table 8 Slow Clock Source Requirements
SDIO INTERFACE TIMING
Table 9 SDIO Interface Read (see Figure 3)
Figure 3 SDIO Single Block Read
Table 10 SDIO Interface Write (see Figure 4)
Figure 4 SDIO Single Block Write
SDIO CLOCK TIMING
Table 11 SDIO Clock Timing
Figure 5 SDIO Clock Timing
SOLDERING RECOMMENDATIONS
Recommended Reflow Profile for Lead Free Solder
Note: The quality of solder joints on the castellations (‘half vias’) where they contact the
host board should meet the appropriate IPC Specification. See IPC-A-610-D Acceptability
of Electronic Assemblies, section 8.2.4 Castellated Terminations.”
Figure 6 Reflow Profile
Repeating Reflow Soldering
Only a single reflow soldering process is encouraged for host boards.
CLEANING
In general, cleaning the populated modules is
strongly discouraged. Residuals under the
module cannot be easily removed with any
cleaning process.
Cleaning with water can lead to capillary
effects where water is absorbed into the gap
between the host board and the module.
The combination of soldering flux residuals
and encapsulated water could lead to short
circuits between neighboring pads. Water
could also damage any stickers or labels.
Cleaning with alcohol or a similar organic
solvent will likely flood soldering flux
residuals into the RF shield, which is not
accessible for post-washing inspection. The
solvent could also damage any stickers or
labels.
Ultrasonic cleaning could damage the
module permanently.
OPTICAL INSPECTION
After soldering the Module to the host board,
consider optical inspection to check the
following:
Proper alignment and centering of the
module over the pads.
Proper solder joints on all pads.
Excessive solder or contacts to neighboring
pads, or vias.
REWORK
The module can be unsoldered from the host
board if the Moisture Sensitivity Level (MSL)
requirements are met as described in this
datasheet.
Never attempt a rework on the module
itself, e.g. replacing individual
components. Such actions will
terminate warranty coverage.
HANDLING AND STORAGE
Handling
The modules contain a highly sensitive
electronic circuitry. Handling without proper
ESD protection may destroy or damage the
module permanently. ESD protection may
destroy or damage the module permanently.
Moisture Sensitivity Level (MSL)
Per J-STD-020, devices rated as MSL 4 and
not stored in a sealed bag with desiccant pack
should be baked prior to use.
After opening packaging, devices that will be
subjected to reflow must be mounted within 72
hours of factory conditions (<30°C and 60%
RH) or stored at <10% RH.
Bake devices for 48 hours at 125°C.
Storage
Please use this product within 6 months after
receipt. Any product used after 6 months of
receipt needs to have solderability confirmed
before use.
The product shall be stored without opening the
packing under the ambient temperature from 5 to
35deg.C and humidity from 20 to 70%RH.
(Packing materials, in particular, may be
deformed at the temperatures above this range.)
Do not store in salty air or in an environment
with a high concentration of corrosive gas, such
as Cl2, H2S, NH3, SO2, or NOX.
Do not store in direct sunlight.
The product should not be subject to excessive
mechanical shock.
AGENCY CERTIFICATIONS
FCC ID: H5P-TIWIBLE
IC: 6050A-TIWIBLE
Model: TiWi-BLE
AGENCY STATEMENTS
Federal Communication Commission Interference Statement
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.
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 CAUTION: Any changes or modifications not expressly approved by the party
responsible for compliance could void the user's authority to operate this equipment.
To comply with FCC and Industry Canada RF exposure limits for general population / uncontrolled
exposure, the antenna(s) used for this transmitter must be installed to provide a separation distance of
at least 35 mm from all persons and must not be operating in conjunction with any other antenna or
transmitter.
If the module is used in a multi-transmitter or simultaneous transmission host then the module must be
evaluated and approved to one of the host platform exposure conditions. (Mobile exposure, Portable
exposure or Mixed Mobile and Portable exposure).
Industry Canada Statements
This Device complies with Industry Canada License-exempt RSS standard(s). Operation is subject to
the following two conditions: 1) this device may not cause interference, and 2) this device must accept
any interference, including interference that may cause undesired operation of the device.
Under Industry Canada regulations, this radio transmitter may only operate using an antenna of a type
and maximum (or lesser) gain approved for the transmitter by Industry Canada. To reduce potential
radio interference to other users, the antenna type and its gain should be so chosen that the equivalent
isotropically radiated power (e.i.r.p.) is not more than that necessary for successful communication.
This device has been designed to operate with the antenna(s) listed below, and having a maximum
gain of 2.15 dBi. Antennas not included in this list or having a gain greater than 2.15 dBi are strictly
prohibited for use with this device. The required antenna impedance is 50 ohms.
List of all Antennas Acceptable for use with the Transmitter
1) Mitsubishi materials AM03DP-ST01 with a peak gain of 2.15dBi (0 dBd)
2) HOKO Electronics 1029-C17586 with a peak gain of 1.9dBi
3) LSR 2.4GHz dipole antenna with a peak gain of 2.0dBi
4) Ethertronics Prestta 1000423 2.4GHz antenna with a peak gain of -0.6dBi (at 2.4GHz)
5) LSR 2.4GHz waterproof Dipole Antenna, part 001-0010, with a peak gain of 2.0dBi.
Cet appareil est conforme avec Industrie Canada, exempts de licence standard RSS (s). Son
fonctionnement est soumis aux deux conditions suivantes: 1) ce dispositif ne peut pas causer
d'interférences, et 2) ce dispositif doit accepter toute interférence, y compris les interférences qui
peuvent causer un mauvais fonctionnement de l'appareil.
En vertu des règlements d'Industrie Canada, cet émetteur de radio ne peut fonctionner en utilisant une
antenne d'un type et maximale (ou moins) Gain approuvé pour l'émetteur par Industrie Canada. Pour
réduire les interférences radio potentielles pour les autres utilisateurs, le type d'antenne et son gain
doivent être choisis afin que la puissance isotrope rayonnée équivalente (PIRE) ne dépasse pas ce qui
est nécessaire pour une communication réussie.
Cet appareil a été conçu pour fonctionner avec l'antenne mentionnés ci-dessous et avoir un maximum
de gain de 2,15 dBi. Antennes non inclus dans cette liste ou avoir un gain supérieur à 2,15 dBi sont
strictement interdits pour une utilisation avec cet appareil. L'impédance d'antenne requis est de 50
ohms.
Liste des antennes autant Acceptable pour une utilisation avec l'émetteur
1) Mitsubishi matériaux AM03DP-ST01 avec un gain de pic de 2.15dBi (0 dBd)
2) HOKO HOKO Electronics 1029-C17586 avec un pic de 1.9dBi
3) LSR 2.4GHz 2.4 GHz antenne dipôle avec un gain maximum de 2.0dBi
4) Ethertronics Prestta 1000423 2,4 GHz antenne avec un gain maximum de - 0.6dBi (à 2, 4GHz)
5) LSR 2.4 GHz antenne dipôle imperméable à l'eau , partie 001-0010, avec un gain maximum de
2.0dBi.
OEM RESPONSIBILITIES TO COMPLY WITH FCC AND INDUSTRY CANADA
REGULATIONS
The TiWi-BLE Module has been certified for integration into products only by OEM integrators under
the following condition:
To comply with FCC and Industry Canada RF exposure limits for general population / uncontrolled
exposure, the antenna(s) used for this transmitter must be installed to provide a separation distance of
at least 35mm from all persons and operating in conjunction with any other antenna or transmitter.
If the module is used in a multi-transmitter or simultaneous transmission host then the module must be
evaluated and approved to one of the host platform exposure conditions. (Mobile exposure, Portable
exposure or Mixed Mobile and Portable exposure).
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 cannot be met (for certain
configurations or co-location with another transmitter), then the FCC and Industry Canada
authorizations are no longer considered valid and the FCC ID and IC Certification Number
cannot 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 and Industry Canada authorization.
Le module de TiWi-BLE a été certifié pour l'intégration dans des produits uniquement par des
intégrateurs OEM dans les conditions suivante:
Pour se conformer aux limites d'exposition aux RF de la FCC et d'Industrie Canada pour la population
générale / exposition non contrôlée, l'antenne (s) utilisé pour cet émetteur doit être installé pour fournir
une distance de séparation d'au moins 35mm de toutes les personnes et opérant en conjonction avec
une autre antenne ou émetteur.
Si le module est utilisé dans un environnement multi-émetteur ou hôte de la transmission simultanée
alors le module doit être évaluée et a approuvé l'une quelconque des conditions d'exposition de la
plate-forme d'accueil. (Exposition mobile, l'exposition portable ou l'exposition mobile et portable mixte).
Toutefois, l'intégrateur OEM est toujours responsable de tester leur produit final pour toutes les
exigences de conformité supplémentaires requis avec ce module installé (par exemple, les émissions
appareil numérique, les exigences de périphériques PC, etc.)
NOTE IMPORTANTE: Dans le cas où ces conditions ne peuvent être satisfaites (pour
certaines configurations ou de co-implantation avec un autre émetteur), puis la FCC et
Industrie autorisations Canada ne sont plus considérés comme valides et l'ID de la FCC et
IC numéro de certification ne peut pas être utilisé sur la produit final. Dans ces
circonstances, l'intégrateur OEM sera chargé de réévaluer le produit final (y compris
l'émetteur) et l'obtention d'un distincte de la FCC et Industrie Canada l'autorisation.
OEM LABELING REQUIREMENTS FOR END-PRODUCT
The TiWi-BLE module is labeled with its own FCC ID and IC Certification Number. The FCC ID and IC
certification numbers are not visible when the module is installed inside another device, as such the
end device into which the module is installed must display a label referring to the enclosed module.
The final end product must be labeled in a visible area with the following:
“Contains Transmitter Module FCC ID: H5P-TIWIBLE”
“Contains Transmitter Module IC: 6050A-TIWIBLE”
or
“Contains FCC ID: H5P-TIWIBLE”
“Contains IC: 6050A-TIWIBLE”
The OEM of the TiWi-BLE Module must only use the approved antenna(s) listed above, which have
been certified with this module.
Le module de TiWi-BLE est étiqueté avec son propre ID de la FCC et IC numéro de
certification. L'ID de la FCC et IC numéros de certification ne sont pas visibles lorsque le module
est installé à l'intérieur d'un autre appareil, comme par exemple le terminal dans lequel le module est
installé doit afficher une etiquette faisant référence au module ci-joint. Le produit final doit être
étiqueté dans un endroit visible par le suivant:
“Contient Module émetteur FCC ID: H5P-TIWIBLE"
“Contient Module émetteur IC: 6050A-TIWIBLE"
ou
“Contient FCC ID: H5P-TIWIBLE"
“Contient IC: 6050A-TIWIBLE”
L’OEM du module TiWi-BLE ne doit utiliser l'antenne approuvée (s) ci-dessus, qui ont été certifiés avec
ce module.
OEM END PRODUCT USER MANUAL STATEMENTS
The OEM integrator should not 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.
The user manual for the end product must include the following information in a prominent
location:
This device is granted for configurations in which the antennas used for this transmitter must be
installed to provide a separation distance of at least 35mm from all person and not be co-located with
any other transmitters except in accordance with FCC and Industry Canada multi-transmitter product
procedures.
Other user manual statements may apply.
L'intégrateur OEM ne devrait pas fournir des informations à l'utilisateur final en ce qui concerne la façon
d'installer ou de retirer ce module RF ou modifier les paramètres RF connexes dans le manuel
utilisateur du produit final.
Le manuel d'utilisation pour le produit final doit comporter les informations suivantes dans
unendroit bien en vue:
Ce dispositif est accordée pour les configurations dans lesquelles les antennes utilisées pour cet
émetteur doit être installé pour fournir une distance de séparation d'au moins 35mm de toute personne
et ne pas être co-localisés avec d'autres émetteurs sauf en conformité avec la FCC et d'Industrie
Canada produit de l'émetteur multiples procédures.
Autres déclarations manuel de l'utilisateur peuvent s'appliquer.
MECHANICAL DATA
Figure 7 Module Mechanical Dimensions (Maximum Module Height = 1.9 mm)
Figure 8 TiWi-BLE Recommended PCB Footprint (Top View)