ETC F2M03GLA

Rev: b
Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
Features
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Fully qualified end product with
Bluetooth™ v2.0+EDR, CE and FCC
Low power consumption
Integrated high output antenna
Transmit power up to +8dBm
Range up to 350m (line of sight)
Piconet and Scatternet capability,
support for up to 7 slaves
Require only few external components
Industrial temperature range -40°C to +85°C
USB v2.0 compliant
Extensive digital and analog I/O interface
PCM interface for up to 3 simultaneous voice channels
Large external memory for custom applications
Support for 802.11b/g Co-Existence
RoHS compliant
Applications
General Description
•
Industrial and domestic appliances
•
Cable replacement
•
Medical systems
•
Automotive applications
•
Stand-alone sensors
•
Embedded systems
•
Cordless headsets
•
Computer peripherals
F2M03GLA is a Low power embedded
Bluetooth™ v2.0+EDR module with built-in high
output antenna. The module is a fully
Bluetooth™ compliant device for data and voice
communication. With a transmit power of up to
+8dBm and receiver sensibility of down to
–83dBm combined with low power consumption
the F2M03GLA is suitable for the most
demanding applications. Developers can easily
implement a wireless solution into their product
even with limited knowledge in Bluetooth™ and
RF. The module is fully Bluetooth™ v2.0+EDR
qualified and it is certified according to CE and
FCC, which give fast and easy Plug-and-Go
implementation and short time to market.
(Mice, Keyboard, USB dongles, etc.)
•
Handheld, laptop and desktop computers
•
Mobile phones
RoHS
COMPLIANT
2002/96/EC
The F2M03GLA comes with an on board highly
efficient omni-directional antenna that simplifies
the integration for a developers Bluetooth™
solution. The high output power combined with
the low power consumption makes this module
ideal for handheld applications and other battery
powered devices.
F2M03GLA can be delivered with the
exceedingly reliable and powerful easy-to-use
Wireless UART firmware implementing the
Bluetooth™
Serial
Port
Profile
(SPP).
BLUETOOTH is a trademark owned by
Bluetooth SIG, Inc., U.S.A. and licensed to Free2move
www.free2move.net
Rev: b
Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
Table of contents
1
Device pinout .........................................................................................................................3
2
Device terminal functions .....................................................................................................4
3
Electrical Characteristics ......................................................................................................5
4
Radio Characteristics ............................................................................................................7
5
Firmware versions .................................................................................................................8
5.1
5.2
6
Wireless UART ............................................................................................................................. 10
HCI ................................................................................................................................................ 15
Device terminal description ................................................................................................18
6.1
6.2
6.3
6.4
6.5
6.6
6.7
7
UART Interface ............................................................................................................................. 18
USB Interface................................................................................................................................ 20
Serial Peripheral Interface ............................................................................................................ 24
I2C Interface .................................................................................................................................. 24
PCM .............................................................................................................................................. 25
PIOs .............................................................................................................................................. 32
Power supply ................................................................................................................................ 33
Application information.......................................................................................................34
7.1
7.2
7.3
Recommended land pattern.......................................................................................................... 34
Layout guidelines .......................................................................................................................... 35
Typical application schematic ....................................................................................................... 36
8
Package information............................................................................................................37
9
Certifications ........................................................................................................................38
9.1
9.2
9.3
Bluetooth ....................................................................................................................................... 38
CE ................................................................................................................................................. 38
FCC............................................................................................................................................... 38
10
RoHS Statement...................................................................................................................39
11
Tape and Reel information ..................................................................................................40
11.1
11.2
Package Tape dimensions............................................................................................................ 40
Reel dimensions ........................................................................................................................... 40
12
Ordering information ...........................................................................................................41
13
Document history ................................................................................................................42
Acronyms and definitions...........................................................................................................43
© 2006 Free2move AB
Page 2(44)
Rev: b
Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
1 Device pinout
Pinout for F2M03GLA [TOP VIEW]
© 2006 Free2move AB
Page 3(44)
Rev: b
Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
2 Device terminal functions
Ground
GND
Pin
1,16,17,32
Power supplies
+VCC
Pin type
Positive voltage supply (3.0-3.6)
Pin
Pin type
18
Bi-directional
AIO(1)
19
Bi-directional
Reset
Pin
30
Test and debug
3
SPI CSB
5
SPI CLK
SPI MOSI
2
4
UART
UART CTS
UART TX
UART RTS
UART RX
PCM
Pin type
Pin type
Pin type
Description
CMOS input with weak internal pull-down
CMOS output
CMOS output, tristatable with internal pull-up
CMOS input with weak internal pull-down
Pin type
PCM_SYNC
PCM_IN
PCM_CLK
8
9
6
CMOS output, tristatable with internal weak
pull down
Bi-directional with weak internal pull-down
CMOS input, with weak internal pull-down
Bi-directional with weak internal pull-down
PIO
Pin
Pin type
Bi-directional
Bi-directional
Pin
Pin type
15
PIO(10)
14
PIO(9)
13
PIO(8)
12
PIO(7)
11
PIO(6)/WLAN_Active/
Ch_Data
10
PIO(5)/BT_Active
23
Bi-directional with
internal pull-up/down
programmable
PIO(4)/ BT_Priority/Ch_Clk
22
Bi-directional with
internal pull-up/down
programmable
PIO(3)
21
PIO(2)
20
Bi-directional with
internal pull-up/down
Bi-directional with
internal pull-up/down
Not connected
Bi-directional with
internal pull-up/down
Bi-directional with
internal pull-up/down
Bi-directional with
internal pull-up/down
Bi-directional with
internal pull-up/down
Bi-directional with
internal pull-up/down
Bi-directional with
internal pull-up/down
Pin
UART clear to send active low
UART data output active high
UART request to send active low
UART data input active high
Description
Synchronous data output
Synchronous data SYNC
Synchronous data input
Synchronous data clock
Description
USB data plus
USB data minus
PIO(11)
NC
also
Description
7
24
25
line
Description
Pin
USB
also
Reset if low. Input debounced so must be
low for >5ms to cause a reset
PCM_OUT
USB +
USB -
line
CMOS output, tristatable with weak internal Serial Peripheral Interface data output
pull-down
CMOS input with weak internal pull-up
Chip select for Synchronous Serial
Interface, active low
CMOS input with weak internal pull-down
Serial Peripheral Interface clock
CMOS input with weak internal pull-down
Serial Peripheral Interface data input
Pin
27
29
26
28
Description
Programmable input/output
possible to use as digital I/O
Programmable input/output
possible to use as digital I/O
CMOS input with internal pull-up (10kΩ)
Pin
SPI MISO
Description
VDD
AIO(0)
RESET
Description
Ground connections
Pin
31
Analog I/O
Pin type
VSS
Description
programmable
weak Programmable input/output line
programmable
weak Programmable input/output line
programmable
weak Programmable input/output line
programmable
weak Programmable input/output line
programmable
weak Programmable input/output line
programmable
programmable
weak Programmable input/output line or
Optionally WLAN_Active/Ch_Data input for
co-existence signalling
weak Programmable input/output line or
Optionally BT_Active output for coexistence signalling
weak Programmable input/output line or
Optionally BT_Priority/Ch_Clk output for
co-existence signalling
weak Programmable input/output line
programmable
weak Programmable input/output line
Pin type
Not connected
Description
Soldering pads for stability
© 2006 Free2move AB
Page 4(44)
Rev: b
Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
3 Electrical Characteristics
Absolute Maximum Ratings
Rating
Min
Max
Storage Temperature
Breakdown supply voltage
-40°C
-0.4V
+150°C
5.60V
Recommended Operating Conditions
Rating
Min
Max
Operating temperature range
Supply voltage
+85°C
3.6V
-40°C
3.1V
Input/Output Terminal Characteristics
Digital Terminals
Min
Typ
Max
Unit
-0.4
0.7VDD
-
+0.8
VDD+0.4
V
V
VDD-0.2
-
0.2
-
V
V
-100
+10
-5.0
+0.2
-1
1.0
-40
+40
-1.0
+1.0
0
-
-10
+100
-0.2
+5.0
+1
5.0
µA
µA
µA
µA
µA
pF
Min
Typ
Max
Unit
3.1
-
3.6
V
0.7VDD
-
0.3VDD
-
V
V
2.5
-
10.0
pF
0
2.8
-
0.2
VDD
V
V
Input Voltage
VIL input logic level low, 2.7V ≤ VDD ≤ 3.0V
VIH input logic level high
Output Voltage
VOL output logic level low, (lO = 4.0mA), 2.7V ≤ VDD ≤ 3.0V
VOH output logic level high, (lO = 4.0mA), 2.7V ≤ VDD ≤ 3.0V
Input and tristate current
Strong pull-up
Strong pull-down
Weak pull-up
Weak pull-down
I/O pad leakage current
CI Input Capacitance
USB Terminals
USB Terminals
VDD for correct USB operation
Input threshold
VIL input logic level low
VIH input logic level high
Input leakage current
CI Input capacitance
Output levels to correctly terminated USB Cable
VOL output logic level low
VOH output logic level high
Notes:
Current drawn into a pin is defined as positive; current supplied out of a pin is defined as negative.
© 2006 Free2move AB
Page 5(44)
Rev: b
Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
Input/Output Terminal Characteristics (Continued)
Auxiliary ADC, 8-bit resolution
Min
Resolution
Input voltage range
(LSB size = 1.8/255= 7.1mV)
Accuracy
(Guaranteed monotonic)
Offset
Gain Error
Input Bandwidth
Conversion time
Sample rate*
INL
DNL
Typ
Max
Unit
0
-
8
1.8
Bits
V
-1
0
-1
-0.8
-
100
2.5
-
1
1
1
0.8
700
LSB
LSB
LSB
%
KHz
µS
Sample/s
*The ADC is accessed through the VM function. The sample rate given is achieved as a part of this function
Average current consumption
VDD = 3.3V Temperature = 20 oC
Measured using Wireless UART firmware v4.
Slave:
Mode
Average (mA)
No connection (default settings)
No connection (inquiry scan disabled)
Connected (Short range), no data transfer
Connected (Short range), no data transfer
Sniff mode 200 ms interval
Connected (Short range), no data transfer
Park mode 200 ms interval
Connected, (Short range) 115.2 kbit/s master to slave
Connected, (Short range) 115.2 kbit/s slave to master
Connected, (Short range) 115.2 kbit/s full duplex
Connected, (Short range) 115.2 kbit/s slave to master
Sniff mode 125 ms interval
TBD
-
Master:
Mode
Average (mA)
No connection (default settings)
Connected (Short range), no data transfer
Connected (Short range), no data transfer
Sniff mode 200 ms interval
Connected (Short range), no data transfer
Park mode 200 ms interval
Connected, (Short range) 115.2 kbit/s master to slave
Connected, (Short range) 115.2 kbit/s full duplex
Connected, (Long range) 115.2 kbit/s full duplex
Connected, (Short range) 115.2 kbit/s slave to master
Sniff mode 125 ms interval
Connected, (Short range) 115.2 kbit/s slave to master
Sniff mode 125 ms interval
Connected, (Short range) 115.2 kbit/s full duplex
Sniff mode 125 ms interval
TBD
-
Peak current consumption
VDD = 3.3V Temperature = 20 oC
Mode
Typ
Unit
75
mA
Deep sleep leakage current
VDD = 3.3V Temperature = 20 oC
Mode
Typ
Unit
Deep sleep
275
µA
Peak consumption during RF peaks
© 2006 Free2move AB
Page 6(44)
Rev: b
Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
4 Radio Characteristics
VDD = 3.3V Temperature = 25 oC Frequency = 2.441GHz
All measurements are based on the Bluetooth test specification.
Device Under Test (Radio characteristics will be presented here)
© 2006 Free2move AB
Page 7(44)
Rev: b
Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
5 Firmware versions
F2M03 is supplied with Bluetooth stack firmware, which runs on the internal RISC micro controller of the
Bluetooth module. This chapter includes an overview of the different options for more in depth information
please use separate firmware datasheets provided by Free2move.
All firmware versions are compliant with the Bluetooth specification v2.0. The F2M03 software architecture
allows Bluetooth processing to be shared between the internal micro controller and a host processor.
Depending on application the upper layers of the Bluetooth stack (above HCI) can execute on-chip or on
the host processor.
Running the upper stack on F2M03 module reduces (or eliminates, in the case of a on module application)
the need for host-side software and processing time.
The integration approach depends on the type of product being developed. For example, performance will
depend on the integration approach adopted. In general Free2move offers four categories of Bluetooth
stack firmware:
•
•
•
•
Wireless UART; offers a transparent interface to the Bluetooth channel. There is no need for
additional drivers or Bluetooth software on the host.
Embedded module solutions offer an application to run on the module. There is no need for an
external host (E.g. a Bluetooth headset).
Two-processor solution involving a host and host controller, where the higher layers of the
Bluetooth stack has to be implemented on the host.
Two-processor embedded solution offers a host with limited resources to gain access to a
Bluetooth stack, with the higher layers on-chip, via a special API.
The protocol layer models for the different Bluetooth stack firmware categories can be represented as
shown in the figures below.
Application
Host
Host
F2M03
F2M03
Wireless UART application (SPP)
APPLICATION INTERFACE
RFCOMM
APPLICATION INTERFACE
SDP
RFCOMM
Device
Manager
L2CAP
Hardware
Application
SDP
Device
Manager
L2CAP
HCI
HCI
LINK MANAGER
LINK MANAGER
BASEBAND and RF
Hardware
Wireless UART
BASEBAND and RF
Embedded singleprocessor architecture
© 2006 Free2move AB
Page 8(44)
Rev: b
Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
Application
Port Entity
Application
Host
Bluetooth stack
Host
F2M03
HCI
RFCOMM
SDP
Device
Manager
L2CAP
F2M03
HCI
HCI
LINK MANAGER
LINK MANAGER
BASEBAND and RF
BASEBAND and RF
HCI, (Two-Processor
Architecture)
RFCOMM, (Embedded
Two-Processor Architecture)
Wireless UART
Free2move’s Wireless UART (WU) firmware is intended to replace the serial cable(s) connecting portable
and/or fixed electronic devices. Key features are robustness, high configurability, high security, low
complexity and low power. The WU firmware is compliant with the Bluetooth Serial Port Profile (SPP) for
setting up emulated serial cable connections between connected devices. There is no additional need for
drivers or an external host with Bluetooth software when using the WU firmware. When a successful
Bluetooth connection is established the data channel and the voice channel can be used simultaneously or
separately. All information sent/received at the data/voice interface of the WU unit is exchanged
transparently via Bluetooth with the connected remote device.
HCI (Standard Two-Processor Solution)
For the standard two-processor solution, where the split between higher and lower layers of the stack takes
place at the HCI, a complete Bluetooth stack is needed in the external host. It is often preferable to use this
solution when the host is a personal computer of some description. However, in general this category can
include any computing platform with communications capability that is not resource limited.
Free2move can offer a host stack solution on request.
Embedded Solution
This version of the stack firmware requires no host processor. All software layers, including application
software, run on the internal RISC processor in a protected user software execution environment.
The embedded solution can be used for a single chip Bluetooth product. One example is a cordless
headset. However this solution is equally applicable to any small wireless device that would benefit from a
single processor solution.
Free2move can offers among others the following single chip solutions upon a custom request*:
• Headset / Hands Free
• Human Interface Device; Mouse, keyboard etc (HID)
• Dial Up Network (DUN)
• Audio Gateway Profile (AGP)
• OBEX
• Onboard application (development of customer specific applications)
*Please consult your reseller for more information about custom firmwares.
© 2006 Free2move AB
Page 9(44)
Rev: b
Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
5.1
Wireless UART
Free2move’s Wireless UART (WU) firmware is intended to replace the serial cable(s) connecting portable
and/or fixed electronic devices. Key features are robustness, high configurability, high security, low
complexity and low power.
The WU firmware is compliant with the Bluetooth Serial Port Profile (SPP) for setting up emulated serial
cable connections between connected devices. There is no additional need for drivers or an external host
with Bluetooth software when using the WU firmware.
Application
Host
F2M03
Wireless UART application (SPP)
APPLICATION INTERFACE
RFCOMM
SDP
Device
Manager
L2CAP
HCI
LINK MANAGER
Hardware
BASEBAND and RF
Wireless UART architecture
The WU application runs on top of an embedded Bluetooth v2.0 + EDR compliant stack, including protocols
up to the RFCOMM layer. Point-to-point connections are supported. This means that a unit running WU can
be either a master or slave unit.
The WU firmware offers one asynchronous data channel and one synchronous voice channel, both
channels capable of full duplex transmissions.
When a successful Bluetooth connection is established the data channel and the voice channel can be
used simultaneously or separately. All information sent/received at the data/voice interface of the WU unit is
exchanged transparently via Bluetooth with the connected remote device.
The WU unit is set to operate in a default mode that allows the user to communicate via the asynchronous
data channel over Bluetooth, as soon as a successful connection has been established. This can be
achieved without sending any configuration commands to the WU firmware. However, as long as there is
no Bluetooth connection established, it is possible to configure the WU firmware via hex commands
(described in the document Wireless_UART_protocol) or using a Windows configuration software.
© 2006 Free2move AB
Page 10(44)
Rev: b
Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
5.1.1 General I/O
General I/O interfaces are used for different purposes between the WU firmware and the Host:
• Asynchronous data interface – configuration of the WU firmware or exchange transparent digital
information between the connected Bluetooth devices.
• Synchronous voice interface – exchange transparent voice information between the connected
Bluetooth devices.
• Bluetooth connectivity PIO interfaces – indication and disconnection of the established Bluetooth
connection.
• Emulate serial handshaking PIO lines interface – DTE or DCE serial handshake emulation between
the connected Bluetooth devices.
UART interface (Asynchronous data and configuration):
Signal
Direction
Output
Input
Output
Input
UART
TX
RX
RTS
CTS
Active (TTL)
High
High
Low
Low
Description
UART transmit data
UART receive data
UART request to send
UART clear to send
Voice interface:
CODEC I/O
MIC_P
MIC_N
AUX_DAC
SPKR_P
SPKR_N
Signal Direction
Input (analogue)
Input (analogue)
Output (analogue)
Output (analogue)
Output (analogue)
Description
Microphone input positive
Microphone input negative
Microphone input bias
Speaker output positive
Speaker output negative
PIOs are used to control/monitor the Bluetooth connectivity of the WU firmware.
PIO
Signal
Direction
Active (TTL)
2
Input
High
3
Output
High
Description
Request to close the current Bluetooth connection to the remote
device.
Indicates that a successful Bluetooth connection is established with a
remote device.
To prevent connections or to close the current Bluetooth connection PIO[2] can be set high.
PIO[3] is held low as long as there is no Bluetooth connection. As soon as a successful Bluetooth
connection has been established with a remote device, PIO[3] goes high.
PIOs can also be used to emulate serial handshaking lines between the connected Bluetooth devices.
Emulation can either be DTE or DCE.
Emulated Signal
PIO
RI
DTR
DCD
DSR
4
5
6
7
Signal Direction
Emulate DTE
Input
Output
Input
Input
Signal Direction
Emulate DCE
Output
Input
Output
Output
Active (TTL)
High
High
High
High
While the handshaking lines are transparent to the data channel these I/O may also be used to transfer
digital signals between two Free2move devices running WU
© 2006 Free2move AB
Page 11(44)
Rev: b
Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
5.1.2 Settings
The default settings allow the user to communicate via Bluetooth, without sending any configuration
commands, as soon as a successful connection has been established. Information sent and received on
the serial interface of the WU unit at 38400 bps is transmitted transparently between the two connected
devices. The default settings are valid as long as the user has made no configuration.
When there is no Bluetooth connection established it is possible to configure the WU firmware via
commands sent on the serial interface. All settings changed by the user are stored in persistent memory.
The following serial settings are used for configuration mode and are not configurable:
Parameter
Baud rate
Data bits
Parity
Stop bits
Hardware flow control
Default Value
38400
8
None
1
On
To be able to send commands to the Wireless UART firmware, it must be set in Host Controlled Mode
(HCM). As previously described the Wireless UART firmware can only enter HCM when no Bluetooth
connection is established.
Once entered HCM there are several commands that can be issued:
• Configuration commands
• Software / Hardware reboot
• Inquiry (search for Bluetooth devices in the neighborhood)
• Pairing (device security - authentication and encryption)
• Advanced configuration commands
• SCO commands
• Information commands
• Control commands
Configuration Commands
There are several settings stored in the Wireless UART firmware that can be read and modified by using
the configuration commands.
Examples of these settings are:
• Local Bluetooth name
• Local SDP-service name
• Operating mode
• Serial port settings
• Bluetooth security settings (authentication, encryption)
There are two normal operating modes:
• Connecting mode – Bluetooth master
• Endpoint mode – Bluetooth slave
In Connecting mode the Wireless UART firmware will continuously try to establish a Bluetooth connection to
a specified remote Bluetooth device in the neighborhood (Bluetooth master).
In Endpoint mode the Wireless UART firmware may accept connections from remote Bluetooth devices. A
connection request will be accepted when the specified rules are fulfilled (Bluetooth slave).
© 2006 Free2move AB
Page 12(44)
Rev: b
Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
Software / Hardware Reboot
This option gives the ability to be able to reboot the module via software commands.
Inquiry
Search for other Bluetooth devices in the neighborhood.
There are three configuration parameters:
• How many seconds the search should be active
• A filter, used when searching for devices of as certain class
• The possibility to include the Bluetooth name of the discovered devices
Pairing
When authentication is enabled, the devices must be paired before a successful connection can be
established.
The Wireless UART firmware can either initiate pairing with a remote device or accept pairing requests.
During a pairing PIN codes are exchanged between the local and remote device. A successful pairing
requires identical PIN codes. The result of the pairing attempt will be returned to the Host. If pairing was
successful, a unique link key has been generated and saved in non-volatile memory. The link key is used in
the connection establishment procedure for secure verification of the relationship between the paired
devices.
The Wireless UART firmware allows the user to be paired with one device at a time. The last pin code
entered and link key generated are saved.
Advanced configuration
Includes among others commands for enabling power save modes, fine tune performance, enabling
modem emulation and changing transmit power.
SCO commands
Makes it possible to establish full duplex audio connections between two WU units.
© 2006 Free2move AB
Page 13(44)
Rev: b
Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
5.1.3 Performance
The WU firmware is a complete on-chip application; limited resources restrict the maximum throughput. The
table below shows the maximum achieved throughput when streaming data between two connected WU
v4.00 devices at close range.
57600
57600
57600
Maximum
Throughput (kbit/s
(throughput mode))
~57.6
~57.6
~57.6
Maximum
Throughput (kbit/s)
(latency mode)
~57.6
~57.6
~50.5
Master to Slave
Slave to Master
Full duplex
115200
115200
115200
~115.1
~115.1
~114.5
~93.9
~79.6
~42.0
Master to Slave
Slave to Master
Full duplex
230400
230400
230400
~223.1
~221.4
~172.7
~158.0
~117.7
~86.2
Master to Slave
Slave to Master
Full duplex
460800
460800
460800
~228.6
~222.7
~173.3
~206.7
~154.1
~109.8
Master to Slave
Slave to Master
Full duplex
921600
921600
921600
~240.1
~235.4
~174.7
~235.7
~186.0
~150.5
Direction
Baud Rate
Master to Slave
Slave to Master
Full duplex
5.1.4 Configuration
The F2M03 can either be configured using hex commands described in the document
“Wireless_UART_protocol.pdf” or using the Windows configuration software. The configuration software
can be downloaded from www.free2move.net
© 2006 Free2move AB
Page 14(44)
Rev: b
Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
5.2
HCI
In this implementation the internal processor of the module runs the Bluetooth stack up to the Host
Controller Interface (HCI) as specified in the Bluetooth specification V1.1. The external host processor must
provide all upper Bluetooth stack layers.
Application
Bluetooth stack
HCI
Host
HCI
F2M03
LINK MANAGER
BASEBAND and RF
Standard Two-Processor
Architecture
5.2.1 Standard Bluetooth Functionality
Bluetooth v2.0 + EDR mandatory functionality:
• Adaptive frequency hopping (AFH), including classifier
• Faster connection - enhanced inquiry scan (immediate FHS response)
• LMP improvements
• Parameter ranges
Optional Bluetooth v2.0 + EDR functionality supported:
• Adaptive Frequency Hopping (AFH) as Master and Automatic Channel Classification
• Fast Connect - Interlaced Inquiry and Page Scan plus RSSI during Inquiry
• Extended SCO (eSCO), eV3 +CRC, eV4, eV5
• SCO handle
• Synchronisation
The firmware has been written against the Bluetooth v2.0 + EDR specification.
• Bluetooth components: Baseband (including LC), LM and HCI
• Standard USB (v1.1) and UART (H4) HCI Transport Layers
• All standard radio packet types
• Full Bluetooth data rate, enhanced data rates of 2 and 3Mbps(1)
• Operation with up to seven active slaves(1)
• Operation with up to three SCO links, routed to one or more slaves
• Scatternet v2.5 operation
• Maximum number of simultaneous active ACL connections: 7(2)
• Maximum number of simultaneous active SCO connections: 3(2)
• Role switch: can reverse Master/Slave relationship
• All standard SCO voice coding, plus “transparent SCO”
• Standard operating modes: Page, Inquiry, Page-Scan and Inquiry-Scan
• All standard pairing, authentication, link key and encryption operations
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Datasheet
•
•
•
•
•
•
•
Standard Bluetooth power saving mechanisms: Hold, Sniff and Park modes, including “Forced
Hold”
Dynamic control of peers’ transmit power via LMP
Master/Slave switch
Broadcast
Channel quality driven data rate (CQDDR)
All standard Bluetooth Test Modes
Standard firmware upgrade via USB (DFU)
Note:
(1)
Maximum allowed by Bluetooth v2.0 + EDR specification.
F2M03 supports all combinations of active ACL and SCO channels for both Master and Slave operation, as specified
by the Bluetooth v2.0 + EDR specification.
(2)
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5.2.2 Extra Functionality
The firmware extends the standard Bluetooth functionality with the following features:
• Supports BlueCore Serial Protocol (BCSP) - a proprietary, reliable alternative to the standard
Bluetooth (H4) UART Host Transport.
• Provides a set of approximately 50 manufacturer-specific HCI extension commands. This command
set (called BCCMD – “BlueCore Command”) provides:
o Access to the module’s general-purpose PIO port
o The negotiated effective encryption key length on established Bluetooth links
o Access to the firmware’s random number generator
o Controls to set the default and maximum transmit powers - these can help to reduce
interference between overlapping, fixed-location piconets
o Dynamic UART configuration
o Radio transmitter enable/disable - a simple command connects to a dedicated hardware
switch that determines whether the radio can transmit.
• The firmware can read the voltage on a pair of the module’s external pins (normally used to build a
battery monitor, using either VM or host code).
• A block of BCCMD commands provides access to the module’s Persistent Store (PS) configuration
database. The database sets the device’s Bluetooth address, Class of Device, radio (transmit
class) configuration, SCO routing, LM, USB and DFU constants, etc.
• A UART “break” condition can be used in three ways:
o Presenting a UART break condition to the module can force the module to perform a
hardware reboot.
o Presenting a break condition at boot time can hold the module in a low power state,
preventing normal initialisation while the condition exists.
o With BCSP, the firmware can be configured to send a break to the host before sending
data - normally used to wake the host from a Deep Sleep state.
• The DFU standard has been extended with public/private key authentication, allowing
manufacturers to control the firmware that can be loaded onto their Bluetooth modules.
• A modified version of the DFU protocol allows firmware upgrade via the module’s UART.
• A block of “radio test” or Built-In Self-Test (BIST) commands allows direct control of the module’s
radio. This aids the development of modules’ radio designs and can be used to support Bluetooth
qualification.
• Virtual Machine (VM). The VM allow development of customer applications on the module.
Although the VM is mainly used with “RFCOMM builds” (alternative firmware builds providing
L2CAP, SDP and RFCOMM), the VM can be used with this build to perform simple tasks such as
flashing LEDs via the module’s PIO port.
• Hardware low power modes: Shallow Sleep and Deep Sleep. The module drops into modes that
significantly reduce power consumption when the software goes idle.
SCO channels are normally routed over HCI (over BCSP). However, up to three SCO channels can be
routed over the module’s single PCM port (at the same time as routing any other SCO channels over HCI).
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Datasheet
6 Device terminal description
6.1
UART Interface
The F2M03 Bluetooth module’s Universal Asynchronous Receiver Transmitter (UART) interface provides a
simple mechanism for communicating with other serial devices using the RS232 standard(1).
Universal Asynchronous Receiver
Four signals are used to implement the UART function, as shown in the figure above. When F2M03 is
connected to another digital device, UART_RX and UART_TX transfer data between the two devices. The
remaining two signals, UART_CTS and UART_RTS, can be used to implement RS232 hardware flow
control where both are active low indicators. All UART connections are implemented using CMOS
technology and have signalling levels of 0V and VDD. UART configuration parameters, such as Baud rate
and packet format, are set by Free2move firmware.
Note:
In order to communicate with the UART at its maximum data rate using a standard PC, an accelerated
serial port adapter card is required for the PC.
(1)
Uses RS232 protocol but voltage levels are 0V to VDD, (requires external RS232 transceiver IC)
Parameter
Baud Rate
Minimum
Maximum
Possible Values
1200 Baud (≤2%Error)
9600 Baud (≤1%Error)
3MBaud (≤1%Error)
Flow Control
RTS/CTS or None
Parity
None, Odd or Even
Number of Stop Bits
1 or 2
Bits per channel
8
Possible UART Settings
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Datasheet
The UART interface is capable of resetting the Free2move module upon reception of a break signal. A
Break is identified by a continuous logic low on the UART_RX terminal, as shown in figure below. If tBRK is
longer than a special value, defined by the Free2move firmware a reset will occur. This feature allows a
host to initialise the system to a known state. Also, the F2M03 can emit a Break character that may be used
to wake the Host. The above capabilities are not supported in the standard firmware, please contact
Free2move for more information.
Break signal
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Datasheet
6.2
USB Interface
F2M03 contain a full-speed (12Mbits/s) USB interface, capable of driving a USB cable directly. No external
USB transceiver is required. The device operates as a USB peripheral, responding to requests from a
master host controller such as a PC. Both the OHCI and the UHCI standards are supported. The set of
USB endpoints implemented behave as specified in the USB section of the Bluetooth specification
v2.0+EDR. As USB is a master-slave orientated system, F2M03 only supports USB slave operation.
Note: The USB interface can only be used with the HCI firmware
6.2.1 USB Data Connections
The USB data lines emerge as pins USB_DP (USB +) and USB_DN (USB -) on the package. These
terminals are connected to the internal USB I/O buffers of F2M03 and therefore have low output
impedance. To match the connection to the characteristic impedance of the USB cable, series resistors
must be connected to both USB + and USB -.
6.2.2 USB Pull-up Resistor
F2M03 features an internal USB pull-up resistor. This pulls the USB_DP pin weakly high when F2M03 is
ready to enumerate. It signals to the PC that it is a full-speed (12Mbit/s) USB device.
The USB internal pull-up is implemented as a current source, and is compliant with 7.1.5 of the USB
specification v1.1. The internal pull-up pulls USB DP high to at least 2.8V when loaded with a 15kΩ-5%
pull-down resistor (in the hub/host) (when VDD=3.1V). This presents a the venin resistance to the host of at
least 900Ω. Alternatively, an external 1.5kΩ pull-up resistor can be placed between a PIO line and D+ on
the USB cable. The firmware must be alerted to which mode is used (contact Free2move). The default
setting uses the internal pull-up resistor.
6.2.3 Power Supply
The minimum output high voltage for USB data lines is 2.8V. To safely meet the USB specification, the
voltage on terminals must be an absolute minimum of 3.1V. Free2move recommends 3.3V for optimal USB
signal quality.
6.2.4 Self-Powered Mode
In self-powered mode, the circuit is powered from its own power supply and not from the VBUS (5V) line of
the USB cable. It draws only a small leakage current (below 0.5mA) from VBUS on the USB cable. This is
the easier mode for which to design for, as the design is not limited by the power that can be drawn from
the USB hub or root port. However, it requires that VBUS be connected to F2M03 via a resistor network
(Rvb1 and Rvb2), so F2M03 can detect when VBUS is powered up. F2M03 will not pull USB + high when
VBUS is off.
PIO
USB +
USB –
USB ON
Connections to F2M03 for Self-Powered Mode
The terminal marked USB ON can be any free PIO pin. The PIO pin selected must be registered by settings in firmware (contact
Free2move) to the corresponding pin number
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Datasheet
6.2.5 Bus-Powered Mode
In bus-powered mode the application circuit draws its current from the 5V VBUS supply on the USB cable.
F2M03 negotiates with the PC during the USB enumeration stage about power consumption.
When selecting a regulator, be aware that VBUS may go as low as 4.4V. The inrush current (when charging
reservoir and supply decoupling capacitors) is limited by the USB specification (see USB 1.1 specification,
section 7.2.4.1). Some applications may require soft-start circuitry to limit inrush current if more than 10µF
is present between VBUS and GND.
The 5V VBUS line emerging from a PC is often electrically noisy. Regulation down to e.g. VDD=3.3V should
include careful filtering of the 5V line to attenuate noise that is above the voltage regulator’s bandwidth.
Excessive noise on the VDD supply pins of F2M03 may result in reduced receive sensitivity and a distorted
transmit signal. Recommended voltage regulator for the F2M03 is presented in section 6.7.
USB +
USB –
USB ON
Connections to F2M03 for Bus-Powered Mode
Identifier
Value
Function
Rs
27Ω nominal
Impedance matching to USB cable
Rvb1
22kΩ -5%
VBUS ON sense divider
Rvb2
47kΩ - 5%
VBUS ON sense divider
USB Interface Component Values
Note:
USB ON is shared with F2M03’s PIO terminals.
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Datasheet
6.2.6 Suspend Current
USB devices that run off VBUS must be able to enter a suspended state, whereby they consume less that
0.5mA from VBUS. The voltage regulator circuit itself should draw only a small quiescent current (typically
less than 100µA) to ensure adherence to the suspend-current requirement of the USB specification. This is
not normally a problem with modern regulators. The entire circuit must be able to enter the suspend mode.
6.2.7 Detach and Wake_Up Signalling
F2M03 can provide out-of-band signalling to a host controller by using the dedicated control lines called
USB_DETACH and USB_WAKE_UP. These are outside the USB specification (no wires exist for them
inside the USB cable), but can be useful when embedding F2M03 into a circuit where no external USB is
visible to the user. Both control lines are shared with PIO pins and can be assigned to any PIO pin by
firmware settings (contact Free2move)
USB_DETACH, is an input which, when asserted high, causes F2M03 to put USB- and USB+ in a highimpedance state and turns off the pull-up resistor on USB+. This detaches the device from the bus and is
logically equivalent to unplugging the device. When USB_DETACH is taken low, F2M03 will connect back
to USB and await enumeration by the USB host.
USB_WAKE_UP, is an active high output (used only when USB_DETACH is active) to wake up the host
and allow USB communication to recommence. It replaces the function of the software USB WAKE_UP
message (which runs over the USB cable proper), and cannot be sent while F2M03 is effectively
disconnected from the bus.
USB_DETACH and USB_WAKE_UP Signal
6.2.8 USB Driver
A USB Bluetooth device driver is required to provide a software interface between F2M03 and Bluetooth
applications running on the host.
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Datasheet
6.2.9 USB 1.1 Compliance
The Bluetooth chip on the F2M03 is qualified to the USB specification v1.1, details of which are available
from http://www.usb.org. The specification contains valuable information on aspects such as PCB track
impedance, supply inrush current and product labeling.
Although F2M03’s Bluetooth module meets the USB specification, Free2move cannot guarantee that an
application circuit designed around the chip is USB compliant. The choice of application circuit, component
choice and PCB layout all affect USB signal quality and electrical characteristics. The information in this
document is intended as a guide and should be read in association with the USB specification. Independent
USB qualification must be sought before an application is deemed USB compliant and can bear the USB
logo. Such qualification can be obtained from a USB plugfest or from an independent USB test house.
Terminals USB+ and USB- adhere to the USB specification v2.0 (Chapter 7) electrical requirements.
For ac and dc specifications for terminals USB_DETACH, USB_WAKE_UP, USB_PULL_UP and USB_ON,
refer to section PIO specification.
6.2.10 2.0 Compatibility
F2M03 is compatible with USB specification v2.0 host controllers; under these circumstances the two ends
agree the mutually acceptable rate of 12Mbits/s according to the USB v2.0 specification.
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Datasheet
6.3
Serial Peripheral Interface
F2M03 is a slave device that uses terminals SPI_MOSI, SPI_MISO, SPI_CLK and SPI_CSB. This interface
is used for program emulation/debug and IC test. It is also the means by which the F2M03 flash may be
programmed, before any 'boot' program is loaded.
The SPI signals should be routed out from the module if you need to upgrade the firmware on the module in
the future when the module is already soldered (This is most applicable when using custom firmwares,
please consult Free2move)
Note:
The designer should be aware that no security protection is built into the hardware or firmware associated with this port,
so the terminals should not be permanently connected in a PC application. This interface is not a user interface and
only used for initial download and configuration of the firmware for the module.
6.4
I2C Interface
PIO[8:6] can be used to form a master I2C interface. The interface is formed using software to drive these
lines. Therefore, it is suited only to relatively slow functions such as driving a dot matrix liquid crystal display
(LCD), keyboard scanner or EEPROM.
Notes:
2
The I C interface is controlled by firmware specific settings. Please see specific firmware datasheet for information
PIO lines need to be pulled-up through 2.2k: resistors.
PIO[7:6] dual functions, UART bypass and EEPROM support, therefore, devices using an EEPROM cannot
support UART bypass mode.
For connection to EEPROMs, contact Free2move for information about devices that are currently supported.
Example EEPROM Connection
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Datasheet
6.5
PCM
Pulse Code Modulation (PCM) is the standard method used to digitise audio (particulary voice) for
transmission over digital communication channels. Through its PCM interface, F2M03 has hardware
support for continual transmission and reception of PCM data, thus reducing processor overhead for
wireless headset and other audio applications. F2M03 offers a bi-directional digital audio interface that
routes directly into the baseband layer of the on-chip firmware. It does not pass through the HCI protocol
layer.
Hardware on F2M03 allows the data to be sent to and received from a SCO connection. Up to three SCO
connections can be supported by the PCM interface at any one time(1)
F2M03 can operate as the PCM interface Master generating an output clock of 128, 256 or 512kHz. When
configured as PCM interface slave it can operate with an input clock up to 2048kHz. F2M03 is compatible
with a variety of clock formats, including Long Frame Sync, Short Frame Sync and GCI timing
environments.
It supports 13 or 16-bit linear, 8-bit µ-law or A-law companded sample formats at 8ksamples/s and can
receive and transmit on any selection of three of the first four slots following PCM_SYNC. The PCM
configuration options are enabled by firmware settings (contact Free2move).
F2M03 interfaces directly to PCM audio devices includes the following:
Qualcomm MSM 3000 series and MSM 5000 series CDMA baseband devices
• OKI MSM7705 four channel A-law and µ-law CODEC
• Motorola MC145481 8-bit A-law and µ-law CODEC
• Motorola MC145483 13-bit linear CODEC
• Winbond W681360R 13-bit linear CODEC
• STW 5093 and 5094 14-bit linear CODECs
• F2M03 is also compatible with the Motorola SSITM interface
Note:
(1)
Subject to firmware support, contact Free2move for current status.
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Datasheet
6.5.1 PCM Interface Master/Slave
When configured as the Master of the PCM interface, F2M03 generates PCM_CLK and PCM_SYNC.
F2M03 as PCM Interface Master
When configured as the Slave of the PCM interface, F2M03 accepts PCM_CLK rates up to 2048kHz
F2M03 as PCM Interface Master
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Datasheet
6.5.2 Long Frame Sync
Long Frame Sync is the name given to a clocking format that controls the transfer of PCM data words or
samples. In Long Frame Sync, the rising edge of PCM_SYNC indicates the start of the PCM word. When
F2M03 is configured as PCM Master, generating PCM_SYNC and PCM_CLK, then PCM_SYNC is 8-bits
long. When F2M03 is configured as PCM Slave, PCM_SYNC may be from two consecutive falling edges of
PCM_CLK to half the PCM_SYNC rate (i.e., 62.5µs) long.
Long Frame Sync (Shown with 8-bit Companded Sample)
F2M03 samples PCM_IN on the falling edge of PCM_CLK and transmits PCM_OUT on the rising edge.
PCM_OUT may be configured to be high impedance on the falling edge of PCM_CLK in the LSB position or
on the rising edge.
6.5.3 Short Frame Sync
In Short Frame Sync the falling edge of PCM_SYNC indicates the start of the PCM word. PCM_SYNC is
always one clock cycle long.
Short Frame Sync (Shown with 16-bit Sample)
As with Long Frame Sync, F2M03 samples PCM_IN on the falling edge of PCM_CLK and transmits
PCM_OUT on the rising edge. PCM_OUT may be configured to be high impedance on the falling edge of
PCM_CLK in the LSB position or on the rising edge
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Datasheet
6.5.4 Multi-Slot Operation
More than one SCO connection over the PCM interface is supported using multiple slots. Up to three SCO
connections can be carried over any of the first four slots.
Multi-slot Operation with Two Slots and 8-bit Companded Samples
6.5.5 GCI Interface
F2M03 is compatible with the General Circuit Interface, a standard synchronous 2B+D ISDN timing
interface. The two 64Kbps B channels can be accessed when this mode is configured. In the GCI interface
two clock cycles are required for each bit of the voice sample. The voice sample format is 8-bit companded.
As for the standard PCM interface up to 3 SCO connections can be carried over the first four slots.
GCI Interface
The start of frame is indicated by PCM SYNC and runs at 8kHz. With F2M03 in Slave mode, the frequency
of PCMCLK can be up to PCM_SYNC In order to configure the PCM interface to work in GCI mode it is
necessary to have the correct firmware support (contact Free2move)
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Datasheet
6.5.6 Slots and Sample Formats
F2M03 can receive and transmit on any selection of the first four slots following each sync pulse. Slot
durations can be either 8 or 16 clock cycles. Durations of 8 clock cycles may only be used with 8-bit sample
formats. Durations of 16 clocks may be used with 8, 13 or 16-bit sample formats.
F2M03 supports 13-bit linear, 16-bit linear and 8-bit µ-law or A-law sample formats. The sample rate is
8ksamples/s. The bit order may be little or big endian. When 16-bit slots are used, the 3 or 8 unused bits in
each slot may be filled with sign extension, padded with zeros or a programmable 3-bit audio attenuation
compatible with some Motorola CODECs.
6.5.7 Additional Features
F2M03 has a mute facility that forces PCM_OUT to be 0. In Master mode, PCM_SYNC may also be forced
to 0 while keeping PCM_CLK running (which some CODECS use to control power-down)
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Datasheet
6.5.8 PCM Timing Information
PCM Master Timing
Symbol
fmclk
-
Parameter
PCMCLK frequency
Min(1)
Typ
M a x (2)
Unit
-
128
256
512
-
kHz
980
730
-
8
-
-
kHz
ns
ns
20
ns
-
-
20
ns
-
-
20
ns
-
-
20
ns
tdmclksynch
PCM_SYNC frequency
PCM_CLK high
PCM_CLK low
Delay time from PCM_CLK high to
PCM_SYNC high
tdmclkpout
Delay time from PCM_CLK high to valid
PCM_OUT
tdmclklsyncl
Delay time from PCM_CLK low to
PCM_SYNC low (Long Frame Sync
only)
tdmclkhsyncl
Delay time from PCM_CLK high to
PCM_SYNC low
tdmclklpoutz
Delay time from PCM_CLK low to
PCMOUT high impedance
-
-
20
ns
tdmclkhpoutz
Delay time from PCM_CLK high to
PCMOUT high impedance
-
-
20
ns
tsupinclkl
Set-up time for PCM_IN valid to
PCM_CLK low
30
-
-
ns
30
-
-
ns
-
-
15
15
ns
ns
(1)
tmclkh
(1)
tmclkl
thpinclkl
tr
tf
Hold time for PCM_CLK low to PCM_IN
invalid
Edge rise time (Cl = 50 pf, 10-90 %)
Edge fall time (Cl = 50 pf, 10-90 %)
Note:
(1)
Assumes normal system clock operation. Figures will vary during low power modes, when system clock speeds are reduced.
(2)
Valid for temperatures between -40°C and +85°C
PCM Master Timing
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Datasheet
PCM Slave Timing
Symbol
Parameter
Min
(1)
Typ
Max ( 1 )
Unit
fsclk
PCM clock frequency (Slave mode: input)
64
-
2048
kHz
fsclk
PCM clock frequency (GCI mode)
128
-
4096
kHz
tsclkl
PCM_CLK low time
200
-
-
ns
tsclkh
PCM_CLK high time
200
-
-
ns
thsclksynch
Hold time from PCM_CLK low to
PCM_SYNC high
30
-
-
ns
tsusclksynch
Set-up time for PCM_SYNC high to
PCM_CLK low
30
-
-
ns
tdpout
Delay time from PCM_SYNC or
PCM_CLK whichever is later, to valid
PCM_OUT data (Long Frame Sync only)
-
-
20
ns
tdsclkhpout
Delay time from CLK high to PCM_OUT
valid data
-
-
20
ns
tdpoutz
Delay time from PCM_SYNC or
PCM_CLK low, whichever is later, to
PCM_OUT data line high impedance
-
-
20
ns
tsupinsclkl
Set-up time for PCM_IN valid to CLK low
30
-
-
ns
thpinsclkl
Hold time for PCM_CLK low to PCM_IN
invalid
30
-
tr
Edge rise time (Cl = 50 pF, 10-90 %)
Tf
Edge fall time (Cl = 50 pF, 10-90 %)
-
-
ns
15
15
ns
ns
Note:
(1)
Valid for temperatures between -40°C and +105°C
PCM slave timing
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6.6
PIOs
The F2M03GLA have 10 programmable general-purpose I/O ports PIO[11:2] and two analog I/O ports
AIO[1:0]. PIO lines can be configured through software to have either weak or strong pull-ups or pulldowns.
All PIO lines are configured as inputs with weak pull-downs at reset.
AIO[1:0] functions available via these pins include an 8-bit ADC but can also be used as general-purpose
I/O lines. Typically the AIO[0] is used for battery voltage measurement. The voltage range for AIO[1:0] is
constrained by the internal analogue supply voltage which is 1.8V.
Note:
The PIO and AIO lines are controlled by firmware specific settings. Please see specific firmware datasheet for
information about the PIOs used!
6.6.1
General-purpose I/O lines
PIO[2]
Programmable I/O terminal.
PIO[3]
Programmable I/O terminal.
PIO[4]/ BT_Priority/Ch_Clk
Programmable input/output line or Optionally BT_Priority/Ch_Clk output for co-existence signaling
PIO[5]/BT_Active
Programmable input/output line or Optionally BT_Active output for co-existence signalling
PIO[6]/WLAN_Active/Ch_Data
Programmable input/output line or Optionally WLAN_Active/Ch_Data input for co-existence signalling
PIO[7]
Programmable I/O terminal.
PIO[8]
Programmable I/O terminal.
PIO[9]
Programmable I/O terminal.
PIO[10]
Programmable I/O terminal.
PIO[11]
Programmable I/O terminal.
6.6.2
Analog I/O lines
AIO[0]
Programmable input/output line also possible to use as digital I/O
AIO[1]
Programmable input/output line also possible to use as digital I/O
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Datasheet
6.7
Power supply
The power supply for the F2M03GLA should be chosen carefully. Bad power supply can reduce the
performance and may damage the module. Please use the recommended voltage regulator or consult
Free2move if using another regulator. It is also essential to use a proper reset circuit to the module for
correct operation.
6.7.1
Voltage regulator
The F2M03GLA has one power supply, +VCC.
The voltage supplied should have low noise, less than 10mV rms between 0 and 10MHz. The transient
response of the regulator is also important. At the start of a Bluetooth packet, power consumption will jump
to high levels. The regulator should have a response time of 20µs or less; it is essential that the power rail
recovers quickly.
The recommended voltage regulator is:
TPS73633DBVTG4 from Texas Instrument
6.7.2
Reset
The F2M03GLA has an active low reset (pin nr: 30).The reset pin MUST be connected to either a resetcircuit such as the TC1270SERCTR, TCM811SERCTR, DS1818 or using an I/O from a microcontroller.
Reset cannot be done with a R-C network. It is recommended to used one of the reset circuits mentioned
above. Special considerations must be taken when using an I/O from a microcontroller; a pull-down resistor
(1.8kΩ) must be placed on the I/O-line.
It is recommended that RESET is applied for a period greater than 5ms.
At reset the digital I/O pins are set to inputs for bi-directional pins and outputs are tristated. The PIOs have
weak pull-downs.
© 2006 Free2move AB
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Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
7 Application information
Recommended land pattern
F2M03GLA
All dimensions are in [mm]
No ground planes, or placed
outside the PCB
16
17
0.8
1
32
1.37
1.27
20.42
28.5
[TOP VIEW]
0.8
7.1
1.2
15.2
Solder pad
Recommended extended pad for manual soldering
Restricted area for ground planes or other components
•
•
•
Pad size: 0.8x1.2mm,
Solder mask opening 0.9x1.3mm
Pitch: 1.27mm (50mil)
© 2006 Free2move AB
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Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
7.2
Layout guidelines
The module uses bottom pads for soldering optimized for an automatic solder line. It is also possible to
solder the module manually by using hot air soldering. For manual soldering solder pads may in some
situation be made slightly larger to allow easier heating process.
To achieve good RF performance it is recommended to place ground plane(s) beneath the module but not
under the antenna. The ground planes should be connected with vias surrounding the module. Except from
the ground plane it is preferable that there are as few components and other material as possible nearby
the antenna. Free air is the best surrounding for the antenna.
All GND pads must be connected directly to a flooded ground-plane. If more then one ground layer is used
then make a good connection between them using many via holes. +VCC should be connected to the
voltage regulator using a wide trace.
Antenna
Vias
Ground layers
F2M03GLA
© 2006 Free2move AB
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Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
7.3
Typical application schematic
Typical application schematic for F2M03GLA when using the Wireless UART firmware
© 2006 Free2move AB
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Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
8 Package information
F2M03GLA
Physical size [mm]:
Length: 28.5
Width: 15.2
Height: 2.1
Weight: 1.2g
© 2006 Free2move AB
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Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
9 Certifications
9.1
Bluetooth
Devise under test
9.2
CE
Device under test
9.3
FCC
Device under test
© 2006 Free2move AB
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Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
10 RoHS Statement
F2M03GLA meet the requirements of Directive 2002/95/EC of the European Parliament and of the Council
on the Restriction of Hazardous Substance (RoHS). The module is assembled solely using RoHS compliant
components.
© 2006 Free2move AB
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Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
11 Tape and Reel information
11.1
Package Tape dimensions
TBD
11.2
Reel dimensions
TBD
© 2006 Free2move AB
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Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
12 Ordering information
The F2M03GLA is available for delivery in volumes.
Part nr:
Description
F2M03GLA-S01
Low power Bluetooth module with antenna and Wireless UART firmware v4. (SPP)
F2M03GLA-S04
Low power Bluetooth module with antenna and HCI firmware (USB-interface)
Please use our website: www.free2move.net for more information about local distributors and dealers.
© 2006 Free2move AB
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Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
13 Document history
Date
Revision
Reason for Change
JAN 2007
b
Small technical changes of the document.
NOV 2006
a
Original Publication of this document.
F2M03GLA
Datasheet
Datasheet_F2M03GLA_rev_b.pdf
Last revision change
January 2007
© 2006 Free2move AB
Page 42(44)
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Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
Acronyms and definitions
Term:
Bluetooth
ACL
AC
A-law
API
BCSP
BER
C/I
CMOS
CODEC
CPU
CQDDR
CTS
CVSD
DAC
dBm
DC
DFU
GCI
HCI
Host
Host Controller
HV
ISDN
ISM
ksamples/s
L2CAP
LC
LSB
p-law
MISO
OHCI
PA
PCB
PCM
PIO
RAM
RF
RFCOMM
RISC
RSSI
RTS
RX
SCO
SDP
SIG
SPI
SPP
TBD
TX
UART
USB
VM
www
Definition:
A set of technologies providing audio and data transfer over short-range radio
Asynchronous Connection-Less. A Bluetooth data packet.
Alternating Current
Audio encoding standard
Application Programming Interface
BlueCore™ Serial Protocol
Bit Error Rate. Used to measure the quality of a link
Carrier Over Interferer
Complementary Metal Oxide Semiconductor
Coder Decoder
Central Processing Unit
Channel Quality Driven Data Rate
Clear to Send
Continuous Variable Slope Delta Modulation
Digital to Analogue Converter
Decibels relative to 1mW
Direct Current
Device Firmware Upgrade
General Circuit Interface. Standard synchronous 2B+D ISDN timing interface
Host Controller Interface
Application’s microcontroller
Bluetooth integrated chip
Header Value
Integrated Services Digital Network
Industrial, Scientific and Medical
kilosamples per second
Logical Link Control and Adaptation Protocol (protocol layer)
Link Controller
Least-Significant Bit
Encoding standard
Master In Serial Out
Open Host Controller Interface
Power Amplifier
Printed Circuit Board
Pulse Code Modulation. Refers to digital voice data
Parallel Input Output
Random Access Memory
Radio Frequency
Protocol layer providing serial port emulation over L2CAP
Reduced Instruction Set Computer
Receive Signal Strength Indication
Ready To Send
Receive or Receiver
Synchronous Connection-Oriented. Voice oriented Bluetooth packet
Service Discovery Protocol
Special Interest Group
Serial Peripheral Interface
Serial Port Profile
To Be Defined
Transmit or Transmitter
Universal Asynchronous Receiver Transmitter
Universal Serial Bus or Upper Side Band (depending on context)
Virtual Machine
world wide web
© 2006 Free2move AB
Page 43(44)
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Low power Bluetooth™ Module with antenna- F2M03GLA
Datasheet
Contact information
For support questions please contact your local dealer
For other purposes use: [email protected]
Website: www.free2move.net
Local dealer/distributor
The information given herein includes text, drawings, illustrations and schematics that are believed to be reliable. However,
Free2move makes no warranties as to its accuracy or completeness and disclaims any liability in connection with its use. Free2move
will in no case be liable for any incidental, indirect or consequential damages arising out of sale, resale, use or misuse of the product.
Users of Free2move products should make their own evaluation to determine the suitability of each such product for the specific
application.
© 2006 Free2move AB
Page 44(44)