User Guide

RN-BT-DATA-UG
Bluetooth Data Module Command
Reference & Advanced Information
User’s Guide
MODULES:
RN24
RN25
RN41
RN42
RN41XV
RN42XV
SERIAL ADAPTERS:
RN220XP
RN240
RN270
RN274
© 2013 Roving Networks. All rights reserved.
RN-BT-DATA-UG Version 1.0r 3/26/13
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and other changes to its products, documentation and services at any
time. Customers should obtain the latest relevant information before placing orders and should verify that such information is current and complete.
Roving Networks assumes no liability for applications assistance or customer’s product design. Customers are responsible for their products and
applications that use Roving Networks components. To minimize customer product risks, customers should provide adequate design and operating safeguards.
Roving Networks, Inc.
102 Cooper Court
Los Gatos, CA 95032
+1 (408) 395-5300
www.rovingnetworks.com
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Roving Networks products are not authorized for use in safety-critical
applications (such as life support) where a failure of the Roving Networks
product would reasonably be expected to cause severe personal injury or
death, unless officers of the parties have executed an agreement specifically governing such use.
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Table of Contents
Chapter 1. Introduction
1.1 Overview ........................................................................................................ 5
1.2 Evaluation Boards & Reference Designs ....................................................... 5
1.3 Command Mode vs. Data Mode ..................................................................... 6
1.4 Operating Modes .......................................................................................... 10
1.5 Using Dipswitches & GPIO Pins for Configuration ....................................... 11
1.6 Making a Bluetooth Connection ................................................................... 12
Chapter 2. Command Reference
2.1 Command Syntax ......................................................................................... 19
2.2 SET Commands ........................................................................................... 19
2.3 GET Commands ........................................................................................... 31
2.4 Change & Action Commands ....................................................................... 32
2.5 GPIO Commands ......................................................................................... 37
Chapter 3. Advanced Topics
3.1 Power Management ..................................................................................... 41
3.2 Configuration Timer Settings ........................................................................ 44
3.3 Interfacing to a Microprocessor .................................................................... 45
3.4 HCI Mode ..................................................................................................... 45
3.5 Profile Settings & Features ........................................................................... 46
3.6 Using GPIO Pins as Modem Control Signals ............................................... 47
3.7 Design Concerns .......................................................................................... 47
3.8 Serial Adapter Configuration ........................................................................ 52
3.9 Null Modem & Flow Control Jumpers ........................................................... 53
3.10 Dipswitch Settings ...................................................................................... 54
Chapter 4. Applications
4.1 Instant Cable Replacement .......................................................................... 57
Chapter 5. HID Profile
5.1 Overview ...................................................................................................... 59
5.2 HID Firmware Overview ............................................................................... 60
5.3 HID Reports .................................................................................................. 62
5.4 HID References ............................................................................................ 68
Appendix A. Factory Defaults
Appendix B. Command Quick Reference Guide
Appendix C. Firmware Revision History
C.1 Version 6.15 (3/26/2013) ............................................................................. 75
C.2 Version 6.12 (Limited Release) ................................................................... 75
C.3 Version 6.11 ................................................................................................. 75
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C.4 Version 6.10 ................................................................................................. 75
C.5 Version 4.77 (8/10/2009) ............................................................................. 76
C.6 Version 4.74 (3/7/2009) ............................................................................... 76
Appendix D. Document Information
RN-BT-DATA-UG
Chapter 1. Introduction
1.1
OVERVIEW
This document contains the software command reference and advanced configuration
settings for Roving Networks Bluetooth data modules. The document is applicable to
all Bluetooth data modules modules (such as the RN41 and RN42), and USB dongles.
Commands and settings that are specific to a single product or product family are identified as such in the document.
You configure Roving Networks Bluetooth devices over the Bluetooth link or over the
module’s UART using a simple ASCII command language. Set commands configure
the module and get commands echo the current configuration. Configuration settings
modified with set commands do not take effect until the module has been rebooted,
even though the get command may show otherwise.
This document assumes that you have a working knowledge of Bluetooth operation
and communications. To configure the Roving Networks modules you need a Bluetooth-enabled PC (either built-in or using a USB Bluetooth dongle). You can only configure one module at a time. Once configured, module settings are saved (independent
of power down) until they are explicitly changed or the factory defaults are restored.
NOTICE TO CUSTOMERS
The commands and applications described in this document apply to Roving Networks
Bluetooth data modules, e.g., RN41 and RN42. For Bluetooth audio module configuration
information (e.g., RN52), refer to the Bluetooth Audio Module Command Reference User’s
Guide.
1.2
EVALUATION BOARDS & REFERENCE DESIGNS
Roving Networks provides a variety of boards, kits, and reference designs that you can
use for evaluation and prototyping.
The RN-41-EK and RN-42-EK evaluation boards are field-ready, Bluetooth SIG qualified prototyping platforms for the RN41 and RN42 modules, respectively. The boards
have the flexibility to connect directly to PCs via a standard USB interface (via the FTDI
chipset) or to embedded processors through the TTL UART interface. The status LEDs,
dipswitches, and signal headers enable demonstrations and proofs of concept.
The Bluetooth HID reference design is implemented in the RN42HID-I/RM module. The
Bluetooth HID profile is typically used in applications such as keyboards, mice, and
game controllers. To demonstrate the basic capability of the Bluetooth HID profile, Roving Networks has developed a Bluetooth reference design implemented in the
RN42HID-I/RM module. The reference design operates in three modes:
• Presenter mode—Used for presentation software such as Microsoft Powerpoint
• Music mode—Music controller for products such as the iPod, iPhone, and iPad
• Custom mode—You can configure each button to send a sequence of up to 4
keys
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For more information on available evaluation boards and reference designs, refer to the
Roving Networks web site.
1.3
COMMAND MODE VS. DATA MODE
The Bluetooth module operates in two modes: data mode (default) and command
mode. While in data mode, the module operates as a data pipe. When the module
receives data, it strips the Bluetooth headers and trailers and passes the user data to
the UART port. When data is written to the UART port, the module constructs the Bluetooth packet and sends it out over the Bluetooth wireless connection. Thus, the entire
process of sending/receiving data to the host is transparent to the end microprocessor.
See Figure 1-1.
FIGURE 1-1:
DATA & COMMAND MODES
Host
Bluetooth
User Data
A
B
Bluetooth
Module
UART
$$$
Bluetooth Interface
A
B
$$$
Command
Mode
The default configuration for the Bluetooth module is:
•
•
•
•
•
Bluetooth slave mode
Bluetooth pin code 1234
Serial port 115,200 Kbps baud rate, 8 bits, no parity, 1 stop bit
Serial port flow control disabled
Low power mode off
You configure the module by putting it into command mode (see “Enter Command
Mode” on page 8) and sending ASCII commands over the UART port or the Bluetooth
link. You reboot the module so that the settings take effect. Once you change the configuration parameters, they persist until you change them or you perform a factory
reset.
There are two ways to configure the Bluetooth module:
• Local configuration using your computer’s serial port
• Via Bluetooth
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You need a terminal emulator to complete the setup.
Note:
1.3.1
Use either the TeraTerm (Windows OS) or CoolTerm (Mac OS-X) terminal
emulator program.
Configuring the Module over the UART Port
Connect the module to your computer. You can connect using the RS-232 DB9 port or
via a USB cable. For example, if you are using the RN-41-EK evaluation board, connect it to your computer using a USB cable.
With the Bluetooth module connected and powered on, run a terminal emulator and
open the COM port to which the cable is connected. The terminal emulator’s communication settings should be the default serial port settings:
•
•
•
•
•
Baud rate 115,200 kbps
8 bits
No parity
1 stop bit
Hardware flow control enabled
Note:
You can use local configuration at any time when the module does NOT
have a Bluetooth connection, as well as under certain conditions. If the
module is in configuration mode and a connection occurs, the module exits
configuration mode and data passes back and forth from the remote module.
Once a connection is made, you can only enter command mode if the boot-up configuration timer has not expired (60 seconds). To remain in configuration mode, set the
configuration timer to 255. See “Configuration Timer Settings” on page 44 for more
information.
Note:
If the module is in Auto-Connect Master Mode, you cannot enter command
mode when connected over Bluetooth. See “Operating Modes” on page 10
for more information on the various operating modes.
Refer to “Enter Command Mode” on page 8” for information on entering command
mode from a terminal emulator.
1.3.2
Remote Configuration Using Bluetooth
It is often useful to configure the module remotely over a Bluetooth connection. Before
performing remote configuration using Bluetooth, first pair the Bluetooth module with
your computer. For PCs with Bluetooth capability and running Windows, click Bluetooth devices in the system tray at the bottom right of your computer screen. Select
Add a Bluetooth device and follow the on-screen instructions. For Mac OS-X, click
the Bluetooth icon, select Set up Bluetooth device, and follow the on-screen instructions.
Once a connection is made, you can only enter command mode if the boot-up configuration timer has not expired (60 seconds). To remain in configuration mode, set the
configuration timer to 255. See “Configuration Timer Settings” on page 44 for more
information.
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When you are finished configuring, reset the module or send the --- command, which
causes the module to exit configuration mode and allows data to pass normally.
Note:
1.3.3
Configuration mode (local or remote) is NEVER enabled when the module
is in auto-mode and is connected over Bluetooth.
Enter Command Mode
To enter command mode, launch a terminal emulator and specify the module’s default
settings. Table 1-1 shows the serial port settings.
TABLE 1-1:
SERIAL PORT SETTINGS
Setting
Value
Port
COM port to which you attached the module
Baud rate
115200
Data rate
8 bits
Patiry
None
Stop bits
1
Flow control
None
Type $$$ into the terminal emulator to enter command mode.
The module returns the string CMD, which indicates that your connection and terminal
settings are correct. While in command mode, the module accepts ASCII bytes as commands. When you enter a valid command, the module returns AOK. It returns ERR for an
invalid command and ? for unrecognized commands. Type h <cr> to see a list of commands.
A quick check to confirm that you are in command mode is to type the X <cr> command
after entering command mode. This command shows the a summary of the module’s
current settings, such as the Bluetooth name, device class, and serial port settings.
See Figure 1-2.
To return to data mode, type --- <cr> or reset the module and re-connect.
Note:
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The module supports a fast data mode. In this mode, the module does not
go into command mode even if it receives $$$. If you do not enter command
mode within the configuration window (60 seconds), the module enters fast
data mode. See “ST,<value>” on page 26 and “Configuration Timer Settings” on page 44 for more information on setting the configuration window.
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FIGURE 1-2:
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VIEW CURRENT SETTINGS
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1.4
OPERATING MODES
The Bluetooth module has several operating modes, which you set using the SM command in command mode.
Note:
In all master modes, the module cannot be discovered or configured
remotely over Bluetooth.
• Slave Mode (SM,0)—Default mode, in which other Bluetooth devices can discover
and connect to the module. You can also make outbound connections in this
mode.
• Master Mode (SM,1)—In this low-speed connection mode, the module makes
connections when a connect command (C) is received. This command can also
contain the Bluetooth address of the remote device. If a device is not specified,
the module uses the stored remote address. The connection can be broken if the
special break character or string is sent (use the SO command to set the break
character). This mode is useful when you want the module to initiate connections
(not receive them). In this mode, the module is NOT discoverable or connectable.
• Trigger Mode (SM,2)—In this low-speed connection mode, the module makes
connections automatically when a character is received on the serial port (UART).
The connection continues as long as characters are received on either end. The
module has a configurable timeout (which you set using the ST command) that
disconnects the module after the specified number of seconds of inactivity (1 to
255) or a configurable break character is received.
• Auto-Connect Master Mode (SM,3)—In this mode, the module makes connections automatically on power-up and re-connects when the connection is lost. This
mode can be set by command, or by setting the external dipswitch 3 during power
up (evaluation kits) or by driving GPIO6 high (Bluetooth modules). If an address is
not stored, the module performs an inquiry process and the first device found that
matches the COD is stored. In this mode, high-speed data is passed without being
interpreted; therefore, the connection cannot be broken via commands or software break characters. If a disconnect occurs, the module attempts to re-connect
until successful.
• Auto-Connect DTR Mode (SM,4)—This mode must be set by command. It operates like Auto-Connect Master Mode, except that you control connection and disconnection with dipswitch 3 (evaluation kits) and GPIO6 (Bluetooth modules).
Turning the dipswitch on or driving GPIO6 high initiates the auto-connect process;
turning the dipswitch off or driving GPIO6 low causes a disconnect.
• Auto-Connect ANY Mode (SM,5)—This mode must be set by command. This
mode operates like Auto-Connect DTR Mode, except that each time the dipswitch
or GPIO is set, an inquiry is performed and the first device found is connected.
The stored address is NOT used, and the address found is never stored.
• Pairing Mode (SM,6)—In this mode, the module attempts to connect with the
remote device matching the store remote address. You set the remote address
using the SR command.
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1.5
USING DIPSWITCHES & GPIO PINS FOR CONFIGURATION
The Bluetooth modules have dipswitches (for evaluation kits) or GPIO pins (for modules) that you can use to configure the module. See Table 1-2.
TABLE 1-2:
Function
DIPSWITCH & GPIO SETTINGS
Dipswitch
(Adpaters & GPIO Pin
Evaluation (Modules)
Boards)
Factory Reset
1
GPIO4
Settings (OFF = 0 VDC/ON = 3 VDC)
Off = disabled, on = armed.
Set this dipswitch/GPIO pin on power up to arm the reset function. Then
toggle the module off and on three times to reset all settings to the factory defaults (other than the Bluetooth name).
Auto Discovery/
Pairing
2
GPIO3
Off = disabled, on = enabled.
You use these settings in conjunction with dipswitch 3/GPIO6. If
dipswitch 3/GPIO6 are also set, the module performs a device inquiry
scan, searching for a partner device with a special matching class
(0x55AA). Once it finds this device, it stores the address into the remote
address field and auto-connects to the remote device.
If dipswitch 3/GPIO6 are NOT set, the module enters slave mode with
the special matching class and waits for the master to find it. This mode
is usually set once on both ends of a module pair (for instant cable
replacement) and then removed.
Auto-Connect
3
GPIO6
Off = disabled, on = enabled.
This setting is equivalent to Auto-Connect Master Mode in software. The
module connects to the stored address. If dipswitch 2/GPIO3 is also set,
a new discovery/pairing can be made.
If connected via the CFR command, toggling the dipswitch off-on-off terminates the current connection.
Baud Rate
4
GPIO7
Off = stored setting (115 K), on = 9,600.
This setting is used to configure 9,600 or a software selected (default =
115 K) baud rate. If the dipswitch is off, the module uses the stored
baud rate setting. When the dipswitch is on, the baud rate is set to 9,600
regardless of the software setting.
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Table 1-3 describes the GPIO pin assignments for Roving Networks Bluetooth hardware. Refer to “GPIO Commands” on page 37 for more information on the commands
you use to configure the GPIO pins.
TABLE 1-3:
GPIO ASSIGNMENTS
RN4x, RN4xXV,
RN220, RN270,
RN-XV-EK,
RN-XV-RD1/2
GPIO
RN-4X-EK
RN-BT-HID-RD1
Firmware
4.77
6.xx
6.11-HID DEMO
GPIO2
–
–
IN: (B7) power on/off, left arrow, iOS
keyboard toggle
GPIO3
IN: (dipswitch 2), discovery/auto-pair
read at power up, DCD in DUN and
MDM profile
–
IN: (B3) Custom, down arrow
GPIO4
IN: (dipswitch 1), factory default
IN: (dipswitch 1), factory default
IN: presentation (B1)
GPIO5
OUT: system status (green LED)
OUT: system status (green LED)
OUT: system status (green LED)
GPIO6
IN: (dipswitch 3), auto connect read
at power up, DSR in DUN and MDM
profile
–
IN: factory reset (B4)
GPIO7
IN: (dipswitch 4), baud rate select on
power up, CTS in DUN and MDM
profile
–
IN: (B3), music
OUT: over the air TX activity (blue
LED)
–
GPIO8
GPIO9
OUT: fire relay A on RD1
–
–
GPIO10
–
–
IN: pull high connect to stored Bluetooth address; pull low disconnect if
connected
OUT: (B6), SPP, FAST-FWD
GPIO11
–
–
IN: on power up if high, HID profile is
selected AND if bit 9 in HID flag is set
(SH,<value>)
1.6
MAKING A BLUETOOTH CONNECTION
By default, the Bluetooth module acts as a slave and the PC or smartphone is the master. You connect to the Bluetooth module using the Bluetooth device manager, which
varies depending on your smartphone or computer’s operating system. In all cases, the
process is the same:
• Discovery—In the discovery phase, the Bluetooth module broadcasts its name,
profile support, and MAC address. It is ready for other devices to pair with it. Discovery is only availoable in slave mode.
• Pairing—During pairing, the Bluetooth module and the Bluetooth master validate
the pin code. If the pin code validates successfully, they exchange security keys
and a channel hopping pseudo-random sequence. Successful pairing results in
the module and master establishing link keys.
• Connecting—Before connecting, the Bluetooth devices must have paired successfully. The master initiates a connection, the master and slave validate the link
keys, and a Bluetooth link is established.
The following sections describe these processes in detail.
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1.6.1
Discovery
When you turn on the Bluetooth module, it is discoverable. For evaluation kits, the
green LED blinks, indicating that it is discoverable. Open your PC’s Bluetooth device
manager and choose to add a new device. The Bluetooth device manager’s icon is
located in the bottom right corner of your screen in the taskbar for Windows and in the
upper right corner for Mac OS-X. The Bluetooth device manager displays a list of discoverable Bluetooth devices (see Figure 1-3). The Bluetooth module displays as Serial
Port Profile (SPP) Service FireFly-ABCD, where FireFly is the type of Roving Networks module and ABCD is the last four nibbles of the Bluetooth MAC address. (You
can change the local device name).
FIGURE 1-3:
1.6.2
DISCOVER THE BLUETOOTH MODULE
Pairing
To pair with the module, double-click the module’s name (i.e., FireFly-XXXX) in the list.
The firmware automatically stores up to 8 pairings from remote hosts in a first in, first
out fashion.
Choose to enter the module’s pairing code (see Figure 1-4) and enter the default pin
code, 1234. When the Bluetooth device manager completes pairing, it issues a message that the Bluetooth device is installed on COMX where COMX is unique to your
computer. In some cases, the Bluetooth device manager creates two COM ports; in this
situation, only use the COM port labeled “outgoing.”
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FIGURE 1-4:
Note:
PAIR WITH THE BLUETOOTH MODULE
You only need to pair with the module once.
Figure 1-5 shows example COM port settings.
FIGURE 1-5:
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BLUETOOTH COM PORT SETTINGS
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If the remote Bluetooth device does not require authentication, a connection can occur
without the pairing process. However the Bluetooth specification requires that if either
device involved in the pairing process requires authentication, the other device must
participate to ensure a secure link. Roving Networks modules default to an open mode,
such that the module does NOT require authentication. However, most PCs require
authentication. See “Security Modes” on page 17 for more information on using pass
keys.
Once connected, the module is in data mode allowing data to flow in both directions as
if the serial port were locally attached to the PC. For configuration, the module must be
in command mode. See “Enter Command Mode” on page 8 for more information.
Note:
1.6.2.1
Only one client can connect to a slave module at a time. As a master, the
module can make multiple connections, but only in a point-to-point, serialized fashion. Roving Networks modules do not currently support multi-point
master mode.
PAIRING WITH A COMPUTER OR SMART PHONE
The module may use simple secure pairing (SSP) if it is attempting to pair with devices
that support the Bluetooth specification version 2.1 + EDR. SSP does not require the
user to remember the pin code, but it asks to confirm the 6-digit number if the device
has a display capability.
1.6.3
Connecting
In most cases, you connect from another device to the module as an outgoing Bluetooth connection. You can also make an incoming connection in which the evaluation
board initiates the connection to the remote device.
1.0.0.1
Outgoing Connections
To establish an outgoing Bluetooth connection from a PC to the module, open the module’s outgoing COM port from your application or a terminal emulator. The module
remains connected until you close the COM port or remove power from the board.
Once connected, the module is in data mode allowing data to flow in both directions.
For configuration, the module must be in command mode. See “Enter Command
Mode” on page 8 for more information.
Note:
1.0.0.2
Only one client can connect to a slave module at a time. As a master, the
module can make multiple connections, but only in a point-to-point, serialized fashion. Roving Networks modules do not currently support multi-point
master mode.
Incoming Connections
For an incoming connection you use the port specified in your Bluetooth settings as
incoming (refer back to Figure 1-3). In incoming connections, the PC or host listens for
an incoming connection from the remote Bluetooth device, in this case the module.
Perform the following steps to make in incoming connection.
1. You need the MAC address of the PC’s Bluetooth radio to connect from the module to the host PC. Open the PC’s Bluetooth advanced settings to find the MAC
address. See Figure 1-6.
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FIGURE 1-6:
PC’S BLUETOOTH RADIO MAC ADDRESS
2. Pair your module with the PC as described in “Pairing” on page 13.
3. Open a terminal (called terminal A in this example) and connect it to the module.
You can run this terminal on the host PC or another computer.
4. Open a second terminal (called terminal B in this example) on the host PC to listen for the incoming Bluetooth connection using the incoming COM port number.
5. Type C,<MAC address> <cr> in terminal A to establish an SPP connection to the
host PC. See Figure 1-7 for an example connection.
6. Try the following commands:
• $$$ to enter command mode
• SO,% to enable status message to see connect/disconnect conditions
• R,1 to reboot
• $$$ to re-enter command mode
• + to enable local echo
• C,<MAC address> to attempt a connection with remote device
Characters you type in terminal B are sent over Bluetooth to the host PC and
appear in terminal A. Any characters entered in terminal A are transmitted to terminal B.
7. To kill the connection, type the k,1 <cr> command in terminal B.
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FIGURE 1-7:
1.6.4
TERMINALS A & B
Security Modes
The Bluetooth module supports authentication. If the local or remote Bluetooth device
has authentication enabled, a pin code is required the first time a connection is
attempted. The pin code is a series of numbers or characters from 1 to 16 characters
in length.
Note:
The default pin code for Roving Networks Bluetooth modules is 1234. The
RN-41-EK and RN-42-EK evaluation boards do not require a pin code.
After you enter the pin code, the Bluetooth devices compare them. If they match, a link
key is generated and stored. Usually, but not always, the remote device stores the link
key. For subsequent connections, the devices compare link keys. If they are correct,
you do not need to re-enter the pin code.
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If the remote device is a PC or PDA, the user generally is prompted to enter this pin
code. To remove the stored link key on the remote device, you typically “unpair” or
remove the device from the Bluetooth manager. You can change the pin code to
remove the link key on the Bluetooth module, forcing a new pin code exchange to occur
upon subsequent connection attempts.
Note:
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Only one master can connect to the Bluetooth module at a time.
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Chapter 2. Command Reference
Roving Networks Bluetooth modules support a variety of commands for configuration.
This section describes these commands in detail and provides examples.
2.1
COMMAND SYNTAX
To issue commands to the module, you send a keyword followed by optional parameters.
•
•
•
•
•
All commands are one or two characters and can be upper or lower case.
Delimit command arguments with a comma.
Commands use decimal input, except where noted.
Text data, such as the Bluetooth name and pin code, is case sensitive.
All commands only take effect AFTER reboot, except where noted.
There are five general command categories, as shown in Table 2-1.
TABLE 2-1:
COMMAND TYPES
Command Type
Description
Set commands
Store information to flash memory. Changes take effect after a power cycle or reboot.
Get commands
Retrieve and display the stored information.
Change commands
Temporarily change the value of various settings such as serial baud rate, parity, etc.
Action commands
Perform actions such as inquiries, connecting, etc.
GPIO commands
Configure and manipulate the GPIO signals.
2.2
SET COMMANDS
The set commands specify configuration settings and take effect after power cycling or
rebooting.
2.2.1
S7,<flag>
This command enables/disables 7-bit data mode, where <flag> is shown in Table 2-2.
TABLE 2-2:
7-BIT DATA MODE VALUES
Flag
Default:
Description
0
Disable.
1
Enable.
0
// Enable 7-bit data mode
Example: S7,1
2.2.2
SA,<value>
The set authentication command forces authentication when a remote device attempts
to connect, where <value> is one of the values shown in Table 2-3. Regardless of this
setting, if a remote device forces authentication, this device responds with the stored
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pin code. Once a remote device has exchanged pin codes with this device, a link key
is stored for future use. The device stores up to 8 keys automatically and permanently
in flash memory, in a first in, first out fashion.
TABLE 2-3:
SET AUTHENTICATION VALUES
Value
Description
0
Open mode. With this mode, the module uses Bluetooth version 2.0 with NO encryption (open mode). This
mode is useful for legacy devices that do not need security. This mode is the same as in firmware version 4.77.
1
SSP keyboard I/O mode (default). If this option is set, the remote host receives a prompt; reply yes to pair.
For Android devices, the user is prompted with a 6-digit code and is asked to verify that the code matches
on the module. The module always responds yes. Because the module cannot display a code, simply
press OK or Yes on the remote device to authenticate.
2
SSP “just works” mode. This mode works with iOS device and newer PCs. You can use this mode with
Droid devices if the application connects using unsecure mode (which was the default on Droid version
3.3). This mode also works with new PC stacks.
4
Pin code. Forces pin code mode authentication (Bluetooth version 2.0), which requires the host device to
enter a pin code that matches the stored pin code. The functionality is similar to firmware version 4.77.
Note:
Default:
Modes 0 and 4 are legacy modes that do not support SSP (Bluetooth version 2.0).
1
Example: SA,1
2.2.3
// Enable authentication
SB,<value>
When you issue the set break command, the device sends a break signal immediately
where <value> is the length of the break signal in milliseconds as shown in Table 2-4.
The break signal on the UART TX pulls the line low.
TABLE 2-4:
SET BREAK VALUES
Default:
Value
Break Length (ms)
1
37
2
18.5
3
12
4
9
5
7
6
6
N/A
Example: SB,1
2.2.4
// Send a break signal of 37 ms
SC,<value>
This command sets the service class field in the class of device (COD). The service
class consists of the most significant 11 bits in the COD. This command sets the MSW
to create the 24-bit device class number. The inquiring device interprets the service
class to determine the service. A complete listing of available Bluetooth service classes
is referenced on the Bluetooth SIG web site.
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Default:
0000
Example: SC,0002
2.2.5
// Set service class to 0002
SD,<value>
This command sets the class of device (COD) LSW. The COD is a 24-bit number that
is made up of the device class with major 8 bit and minor in a 16-bit word. This command is used with the service class command.
Default:
1F00
Example: SD,8040
To set the COD to 0x1F0123, use the following commands:
SC,001F
SD,0123
2.2.6
SE,<value>
In firmware versions 5.40, 6.10, and above, this command sets the UUID for outbound
connections. Roving Networks bluetooth modules use the standard SPP UUID of
0x1101. Encryption is always enabled in firmware versions 5.40 and higher.
2.2.6.1
FIRMWARE VERSION 5.40 & HIGHER
The UUID setting is useful for Android-based applications so that the application can
uniquely determine the remote device. Android applications require a 128-bit UUID.
00001101-0000-1000-8000-00805F9B34FB is the 16-bit UMUID for the serial port profile (0x1101) when promoted to a 128-bit UUID. Android application developers are
expected to use this 128-bit UUID for SPP.
This feature applies to SPP connect back only, which is used primarily for Android
devices. With this feature, you can set a custom UUID for connecting back. Android
phones run an audio gateway that always attempts to grab a connection when it comes
in from a remote Bluetooth device such as the Roving Networks module. With the SE
command, you can register a custom UUID, which ensures that ONLY your application
obtains the connection when it comes in.
The default SSP UUID is 35111C0000110100001000800000805F9B34FB.
You can modify a subset of the UUID; the bytes are changed from left to right. For
example, if the UUID is:
35111C0000110100001000800000805F9B34FB
Typing the command SE,ABCD<cr> changes the first 2 bytes resulting in:
ABCD1C0000110100001000800000805F9B34FB
The command has three short forms:
SE,S
// Loads the default SPP UUID
SE,I
// Loads the iPhone UUID
SE,C
// Loads the custom UUID (appropriate for testing or custom use)
spp_uuid[19] =
{0x35,0x11,0x1C,0x00,0x00,0x11,0x01,0x00,0x00,0x10,0x00,0x80,0x00,0x00,0x80,0
x5F,0x9B,0x34,0xFB };
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iphone_uuid[19] =
{0x35,0x11,0x1C,0x00,0x00,0x00,0x00,0xDE,0xCA,0xFA,0xDE,0xDE,0xCA,0xDE,0x
AF,0xDE,0xCA,0xCA,0xFE };
Where FE is the iPhone UUID and FF is a local UUID.
droid_uuid[19] =
{0x35,0x11,0x1C,0xEE,0x28,0x6E,0xA0,0x00,0x01,0x11,0xE1,0xBE,0x50,0x08,0x00,
0x20,0x0C,0x9A,0x66 };
Default:
0x1101
Example: SE,0000110100001000800000805F9B34FB // Set the UUID for Droid
2.2.6.2
FIRMWARE PRIOR TO VERSION 5.40
For firmware prior to version 5.40, the SE command enables and disables encryption.The <flag> value determines whether or not encryption is enabled as shown in
Table 2-4.
TABLE 2-5:
SET ENCRYPTION ENABLE
Flag
2.2.7
Description
0
Disable.
1
Enable.
SF,1
This command restores the device to the factory defaults.
Example: SF,1
2.2.8
// Restore factory defaults
SH,<value>
The HID flag register is a bit-mapped register that is configured while in command
mode. To set the register, use the SH, <value> command, where <value> is a 4-character hex word. The GH command returns the current value of the register. The default
factory setting is 0000, which corresponds to a keyboard.
Note:
This command is only available for use in the HID profile. Refer to Chapter
5. “HID Profile” for more information on using the HID profile.
Table 2-6 shows the HID flag register bits; currently only the lower 9 bits are defined.
See “HID Flag Register” on page 61 for more information on setting these bits.
TABLE 2-6:
HID FLAG REGISTER BITS
9
8
Force HID mode if
GPIO11 is high on
power-up.
Toggle virtual keyboard on iOS when
first connected.
Default:
7..4
Descriptor type:
0000 = Keyboard
0001 = Game Pad
0010 = Mouse
0011 = COMBO
0100 = JOYSTICK
1XXX = Reserved
Send output reports
over UART.
2..0
Indicates number of
paired devices to which
the module can reconnect.
0200
Example: SH,0220
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3
// Set the device as a mouse
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2.2.9
SI,<hex value>
The inquiry scan window command sets the length of time the device spends enabling
an inquiry scan (discoverability). The minimum value is 0x0012, corresponding to about
a 1% duty cycle.
The page scan interval is fixed at 0x1000. The default window is 0x0100. The maximum
value is 0x800. Set this parameter to 0x0000 to disable inquiry scanning and render the
device undiscoverable. If the host has already paired, the inquiry scan is not used.
Note:
Default:
When pairing with Android devices, increasing this value makes pairing
more reliable.
0100
Example: SI,0200
2.2.10
// Set inquiry scan window to 0x0200
SJ,<hex value>
The page scan window command sets the amount of time the device spends enabling
page scanning (connectability). The minimum value is 0x0012, which corresponds to
about a 1% duty cycle. The page scan interval is fixed at 0x1000. The default window
is 0x0100. The maximum value is 0x800. Set this option to 0x0000 to disable page
scanning and render the device non-connectable.
Note:
Default:
When pairing with Android devices, increasing this value makes pairing
more reliable.
0100
Example: SJ,0200
2.2.11
// Set the page scan window to 0x0200
SL,<char>
This command sets the UART parity, where <char> is a character shown in Table 2-7.
TABLE 2-7:
UART PARITY VALUES
Value
Default:
E
Even.
O
Odd.
N
None.
N
// Set parity to even
Example: SL,E
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Description
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2.2.12
SM,<value>
This command sets the mode, where <value> is a decimal number as shown in
Table 2-8.
TABLE 2-8:
MODE VALUES
Value
Default:
Description
0
Slave Mode.
1
Master Mode.
2
Trigger Mode.
3
Auto-Connect Master Mode.
4
Auto-Connect DTR Mode.
5
Auto-Connect Any Mode.
6
Pairing Mode.
04
Example: SM,0
2.2.13
// Set the mode to slave
SN,<string>
This command sets the device name, where <string> is up to 20 alphanumeric characters.
Default:
N/A
Example: SN,MyDevice
2.2.14
// Set the device name to “MyDevice”
SO,<string>
This command sets the extended status string, where <string> is up to 8 alphanumeric
characters. Setting this string to from 1 to 8 characters permits status messages to be
sent to the local serial port. When you set this parameter, two status messages are
sent:
• When a Bluetooth connection is established, the device sends the string
<string>CONNECT.
• When disconnecting, the device sends the string <string>DISCONNECT.
This parameter is useful when connecting to equipment or hardware. For example,
when the device is connected to a printer, the printer can examine an escape
sequence. If <string> is set to ESC%, the printer can parse ESC%CONNECT and ESC%DISCONNECT messages without interfering with normal print jobs. In trigger or master
modes, the first character of this string is used as the break connection character.
Default:
Disabled
Example: SO,ESC%
SO,<space>
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// Set escape sequence
// Disables the extended status string
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2.2.15
SP,<string>
This command sets the security pin code, where <string> is up to 20 alphanumeric
characters. Each time the device pairs successfully, it saves the Bluetooth address.
The device can store up to eight addresses on a first in first out basis. Using this command also erases all stored pairings. You can use the same value that is already set.
You cannot erase the pin code, however, you can overwrite the default pin code.
Default:
1234
Example: SP,0123
2.2.16
// Set pin code to “0123”
SQ,<mask>
This command is for special configuration settings, where <mask> is a decimal number
as shown in Table 2-9.
TABLE 2-9:
SPECIAL CONFIGURATION SETTINGS VALUES
Mask
Description
0
Default. The device does not use any special configuration.
4
With this option set, the device does not read the GPIO3 and GPIO6 pin values on
power-up. This command is used when configuring GPIO3 and GPIO6 for a function
other than the default configuration. See “GPIO Commands” on page 37.
8
Disables discoverability at power up. Clear this setting with SQ,0. Use the W or Q,1
commands to enable discovery at runtime.
16
This option configures the firmware to optimize for low latency data transfers rather
than throughput.
128
This option causes the device to reboot after disconnect.
256
This option sets 2 stop bit mode on the UART.
Note:
Default:
If the module is unable to connect to the Bluetooth device for 15 to 30 seconds after disconnecting, try clearing the SQ, bit (i.e., use SQ,0).
0
// Do not use special configuration
Example: SQ,128
2.2.17
// Reboot after disconnect
SR,<hex value>
This command stores the remote address, where <hex value> is 12 hexadecimal digits
(6 bytes) with no spaces or characters between digits. Additionally, this command takes
two special characters for the address parameter:
• SR,Z erases any stored addresses.
• SR,I writes the last address observed using the inquiry command. This command
can be helpful when you only have one other device in range.
Note:
Default:
In firmware version 6.12, you must type the SR,Z command in uppercase
characters. If you type the command in lowercase characters, the module
returns ERR.
N/A
Example: SR,00A053112233
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// Set the remote Bluetooth address to
// 00A053112233
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RN-BT-DATA-UG
2.2.18
SS,<string>
This command sets the service name, where <string> is from 1 to 20 alphanumeric
characters. This command is not supported in firmware version 6.x.
Default:
SPP
Example: SS,SerialPort
2.2.19
// Service name set to “SerialPort”
ST,<value>
This command sets the remote configuration timer, where <value> is a decimal number
from 0 to 255 representing the time window (in seconds) to allow remote configuration
over Bluetooth after power up in Slave Mode. In all Master modes, the remote configuration timer is set to 0 (no remote configuration). In Trigger Master Mode, the configuration timer is used as an idle timer to break the connection after time expires with no
characters received.
The module supports a fast data mode. In this mode, the module does not go into command mode even if it receives $$$. If you do not enter command mode within the configuration window set by the configuration timer, the module enters fast data mode.
This command has the special modes shown in Table 2-10.
TABLE 2-10: CONFIGURAION TIMER SETTINGS
Value (Decimal)
0
1 - 252
Default:
Description
No remote configuration. No local configuration when connected.
Time in seconds from power up to allow configuration.
253
Continous configuration, local only.
254
Continous configuration, remote only.
255
Continous configuration, local and remote.
60
Example: ST,0
// Disable remote configuration
// Enable remote configuration forever
ST,255
2.2.20
SU,<value>
The set UART baud rate command sets the baud rate where <value> is 1200, 2400,
4800, 9600, 19.2, 28.8, 38.4, 57.6, 115K, 230K, 460K, or 921K. You only need to specify the first 2 characters of the desired baud rate.
Note:
Default:
After a factory reset, the device returns 0 when you issue the GU command,
however, the module communicates at 115K.
115,200
Example: SU,57
2.2.21
// Set the baud rate to 57,600
SW,<value>
This command enables low-power Sniff mode, which allows extremely low-power operation. In the mode, the device goes into a deep sleep and wakes up every 625 μs x
<value> to send/receive data. For example, the SW,0050 setting (0x50 = 80, 80 x
625 μs = 50 ms) causes the module to enter low-power sleep and wake once every 50
ms to check for RF activity.
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This setting is useful for applications in which the device is connected and sending
data. Data is not lost; however, it may have a delay. See “Sniff Mode” on page 42 for
more details on this mode and managing power.
Default:
0000
// Disable Sniff mode
Example: SW,0050
2.2.22
// Enable Sniff mode with interval time of
// 50 ms
SX,<flag>
The bonding command determines which connections the device accepts, where
<flag> is a value shown in Table 2-11. If bonding is enabled, the device only accepts
connections from the device that matches the stored Bluetooth address register. You
can set the stored address register with the SR command or it can be set upon the first
device pairing.
TABLE 2-11: BONDING VALUES
Flag
Default:
Description
0
Disable.
1
Enable.
0
Example: SX,1
2.2.23
// Enable bonding
SY,<hex value>
This command sets the module’s transmit power, where <hex value> represents the
desired power setting.
In August 2012, Roving Networks changed the power setting hex values. The new
power setting:
• Uses the desired power value instead of an arbitrary value
• Shifts the power range up to use the highest transmit power
• Provides more evenly spaced linear power values.
Table 2-12 describes the SY, power settings for August 2012 and later.
TABLE 2-12: POWER SETTINGS (AUGUST 2012 AND LATER)
Hex
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Power (dBM)
0010
16
000C
12
0008
8
0004
4
0000
0
FFFC
-4
FFF8
-8
FFF4
-12
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Table 2-13 describes the power settings for the SY, command prior to August 2012.
TABLE 2-13: POWER TABLE (BEFORE AUGUST 2012)
Default:
Hex
Power (dBM)
0004
12
0000
6
FFFC
2
FFF8
0
FFF4
-5
FFF0
-10
FFE8
-20
16
// Set the power to 12 dBM
Example: SY,000C
To determine which power settings your module uses, you restore your module to the
factory defaults and then view the power setting. The factory default is for the module
to use maximum power. Therefore, if the power setting displays as 10 hex (16 decimal),
the module uses the new power settings. If the power displays as 4 hex (12 decimal),
the module uses the old power settings.
To find the power setting:
1.
2.
3.
4.
5.
Type $$$ in a console to put the module into command mode.
Type SF,1 <cr> to restore the factory defaults.
Type R,1 <cr> to reboot the module.
Type $$$ to go into command mode.
Type GY <cr> to view the power setting.
2.2.24
SZ,<value>
You use this command to specify non-standard raw baud rates, where <value> is a
decimal number based on the formula <value> = baud rate x 0.004096. This setting
takes effect after rebooting.
Default:
N/A
Example: SZ,39
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// Set the baud rate to 9,521.48
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2.2.25
S~,<value>
This command sets the profile, where <value> is shown in Table 2-14. See “Profile Settings & Features” on page 46 for more details on profiles.
TABLE 2-14: PROFILE VALUES
Value
Profile
Comments
0
SPP
Default, no modem control.
1
DUN-DCE
Slave or gateway. Note 1
2
DUN-DTE
Master or client. Note 1
3
MDM SPP
With modem control signals. Note 1, Note 2
4
SPP and DUN-DCE Multi-profile. Note 1
5
APL
Apple (iAP) profile. Refer to the iAP Bluetooth Evaluation Kit for
Developing Accessories Compatible with iOS Devices User
Manual for more information on using this profile.
6
HID
HID profile. To use the Bluetooth HID profile, the device must
be running a special firmware version. See Chapter 5. “HID
Profile” for more information.
Refer to “Profile Settings & Features” on page 46 for information on
modem control signals and GPIO assignments.
Note 1:
In this mode, GPIO11 is reserved for RTS.
2:
Default:
0
Example: S~,0
2.2.26
// Set profile to SPP
S-,<string>
This command sets the serialized friendly name of the device, where <string> is up to
15 alphanumeric characters. This command automatically appends the last 2 bytes of
the Bluetooth MAC address to the name, which is useful for generating a custom name
with unique numbering.
Default:
N/A
Example: S-,MyDevice
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// Set name to “MyDevice-ABCD”
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2.2.27
S?,<flag>
The role switch command enables and disables the role switch, where <flag> is shown
in Table 2-15. If the switch is set, when a slave mode device receives an incoming connection, the device tries to force a role switch, allowing the slave to become the master.
This option is useful in situations where the local device sends high-speed data up to
the remote host, and can result in better performance. However, this setting may create
a situation in which the connecting host cannot make additional outbound connections
(multi-point) while connected to this device.
TABLE 2-15: ROLE SWITCH VALUES
Flag
Default:
Description
0
Disable.
1
Enable.
0
Example: S?,1
2.2.28
// Enable role switch
S$,<char>
This command sets the configuration detect character string, where <char> is a single
character. This setting allows you to change the default string to go into command
mode ($$$) to some other character string. Restoring the factory defaults returns the
device to using $$$.
Default:
$
Example S$,#
2.2.29
// Set ### as string to go into command
// mode
S|,<value>
The low-power connect mode command disables the Bluetooth radio and LED timers
while not connected, where <value> is a 4-digit number made up of two 1-byte intervals. The first interval is the off period and the second the on period. Both are in hex
seconds (not decimal). The maximum value for either interval is 20 seconds. The
default is 0000, which indicates always actively waiting for a connection.
When this option is set, the module cycles between active (discoverable and connectable) and low-power deep sleep. This setting can save considerable power when the
module is waiting for a long time without a connection. The trade off is additional
latency when connecting or pairing.
Default:
0000
Example: S|,2001
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// Cycle on for 1 s and OFF for 32 s
// (hex 20 = decimal 32)
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2.3
GET COMMANDS
The get commands retrieve and display the device’s stored information. These commands do not have a keyword or character and do not take any parameters, except as
noted.
2.3.1
D
This command displays basic settings such as the address, name, UART settings,
security, pin code, bonding, and remote address.
Example: D
2.3.2
// Display basic settings
E
This command displays the device’s extended settings such as the service name, service class, device class, and configuration timer.
Example: E
2.3.3
// Display extended settings
GB
This command returns the device’s Bluetooth address.
Example: GB
2.3.4
// Display the device’s Bluetooth address
GF
This command returns the Bluetooth address of the currently connected device. This
command can give a different result than the GR command, which is the stored remote
address for re-connecting.
Example: GF
2.3.5
// Show Bluetooth address of currently
// connected device
GK
This command returns the device’s current connection status. 1,0,0 indicates the
device is connected; 0,0,0 indicates that it is not connected.
Note:
If diagnostic messages are enabled (using the SO,% command) and the
device is not connected, NO_AUTH_CHIP is displayed on the UART and the
module returns the error code 8 when you issue the GK command.
Example: GK
2.3.6
// Show the current connection status
GR
This command shows the remote address.
Example: GR
2.3.7
// Display remote address
G&
This command returns a hex byte containing the value of the GPIO pins.
Example: G&
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// Show the GPIO pin values.
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2.3.8
G<char>
This command displays the stored settings for a set command, where <char> is a set
command name.
Example: GS
2.4
// Return 1 or 0 depending on the security
// value
CHANGE & ACTION COMMANDS
Change commands temporarily change the value of various settings such as serial
baud rate, parity, etc. Action commands perform actions such as inquiries, connecting,
and entering/exiting command mode.
2.4.1
$$$
This command causes the device to enter command mode, displaying CMD. The device
passes characters as data until it sees this exact sequence. If the device sees any
bytes before or after the $$$ characters in a 1 second window, the device does not
enter command mode and these bytes are passed through.
You can change the character string used to enter command mode with the S$ command.
Example: $$$
2.4.2
// Enter command mode
---
This command causes the device to exit command mode, displaying END.
Example: ---
2.4.3
// Exit command mode
+
This command toggles the local echo on and off. If you send the + command in command mode, all typed characters are echoed to the output. Typing + a second time
turns local echo off.
Default:
Off
Example: +
2.4.4
// Turn local echo on
&
This command returns the evaluation kit’s dipswitch values or GPIO3, 4, 6, 7 values on
other modules.
Example: &
2.4.5
// Display dipswitch or GPIO values
C
This command causes the device to attempt to connect to the stored remote address.
Example: C
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// Connect to stored remote address
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2.4.6
C,<address>
This command causes the device to connect to a remote address, where <address> is
specified in hex format. The address is also stored as the remote address.
Example: C,00A053112233
2.4.7
// Connect to the Bluetooth address
// 00A053112233
CF,<address>
This command causes the device to connect to <address> and immediately go into fast
data mode.
Note:
You cannot enter command mode while connected using this command.
However, GPIO6 can still be used to disconnect. Therefore, you should
hold GPIO6 high before sending this command because if GPIO6 goes low,
the device disconnects.
Example: CF,00A053112233
2.4.8
// Connect to 00A053112233 in fast data
// mode
CFI
This command causes the device to connect and immediately go into fast data mode
using the last address found with the inquiry command.
Note:
You cannot enter command mode while connected using this command.
However, GPIO6 can still be used to disconnect. Therefore, you should
hold GPIO6 high before sending this command because if GPIO6 goes low,
the device disconnects.
Example: CFI
2.4.9
// Connect to last found address in fast
// data mode
CFR
This command causes the device to connect and immediately go into fast data mode
using the stored remote address. This command is similar to the C command, except it
bypasses the configuration timer.
Note:
2.4.10
You cannot enter command mode while connected using this command.
However, GPIO6 can still be used to disconnect. Therefore, you should
hold GPIO6 high before sending this command because if GPIO6 goes low,
the device disconnects.
CT,<address>,<value>
This command uses a timer to control the connection duration, where <address> is the
connection address (required) and <value> is the length of the timer in ¼ seconds up
to 255 (optional). For example, a <value> of 255 is 64 seconds.
The device does not use or store a remote address. The device automatically disconnects after 7 seconds if no data is seen from the UART or over Bluetooth. You can use
the optional timer <value> to change the timer length.
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Example: CT,00A053112233
CT,00A053112233,120
2.4.11
// Connect to 00A053112233 and
// disconnect after 7 seconds if
// no data is seen from UART or Bluetooth
// Connect to 00A053112233 and
// disconnect after 30 seconds if
// no data is seen from UART or Bluetooth
F,1
This command ends configuration immediately and puts the device into fast data mode.
Example: F,1
2.4.12
// Leave command mode and enter fast
// data mode
H
The help command displays a list of commands and their basic syntax.
Example: H
2.4.13
// Display help
I,<value 1>,<value 2>
This command performs an inquiry scan, where <value 1> is the scan time in seconds
and <value 2> is the optional COD of the device class for which you are scanning. The
default time is 10 seconds, and the maximum is 48. If <value 2> is unused or set to 0,
the device looks for all device classes. When entering a COD, you must provide all six
characters, e.g., you would enter 0040F0 for COD 0x40F0. The scan returns a maximum of 9 devices. As devices are found, they are displayed in the format:
<Bluetooth address>,< Bluetooth name>,<COD>00A053000123,MySerialPort,72010C
Default:
10 seconds, no COD
Example: I,20,0040F0
2.4.14
// Scan for 20 seconds using the COD
// 0x40F0
IN<value 1>,< value 2>
This command is similar to the I command, but it does not return the Bluetooth name,
where <value 1> is the scan time in seconds and <value 2> is the optional COD of the
device class for which you are scanning. Therefore, the device returns the scan result
much faster because the device does not have to perform a remote lookup for each
device found.
Example: IN10,001F00
2.4.15
// Scan for 10 seconds using the COD
// 0x1F00
IQ
This command scans for Bluetooth devices in pairing mode and returns the RSSI,
which is an indicator of the signal quality for remote devices. Inquiry scaning with RSSI
is part of the Bluetooth specification where the Tx power is held a constant level (no
power control) while sampling the RSSI. A useful application for RSSI scanning is proximity based pairing.
Example: IQ
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// Scan for devices and return their RSSI
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2.4.16
IS<value>
This command performs an inquiry scan with a COD of 0x001F00, which is the default
COD for Roving Networks modules, where <value> is the scan time in seconds.
Example: IS10
2.4.17
// Scan for Roving Networks devices for
// 10 seconds
IR<value>
This command performs an inquiry scan with a COD of 0x0055AA, where <value> is
the scan time in seconds. Roving Networks modules use this COD for instant cable
replacement.
Example: IR10
2.4.18
// Scan for instant cable replacement
// devices for 10 seconds
J
This command hides the current 4-digit pin code (or pairing code) used for legacy pairing mode or default mode. When the pin code is hidden, the GP, D, and X commands
do NOT display the currently assigned pin code.
To disable the pin code hiding:
• Use the SP, command to set a new pin code
or
• Restore the factory defaults using the commands
SF,1
R,1
Example: J
2.4.19
// Hide the pin code
K,
The kill command disconnects the device the current connection. The characters
KILL<cr><lf> are echoed to the local UART once the connection is broken.
Example: K,
2.4.20
// Disconnect the current connection.
L
The link quality command returns the real-time streaming link quality values at 5 Hz.
The returned value is two bytes separated by a comma, where ff is the highest value.
The first byte is the current reading and the second byte is the low water mark. Example
output for RSSI is ff,e6.
If the module is not connected, the module responds with NOT Connected! when you
issue the L command.
Example: L
2.4.21
// Display the real-time streaming link
// quality value
M
This command displays the remote side modem signal status.
Example: M
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// Show the remote side modem signal
// status
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2.4.22
O
This command displays other settings, such as the configuration character, I/O port values, and debug mode.
Example: O
2.4.23
// Show the other settings
P,<char>
This command passes through any <char> up to a carriage return or line feed while in
command mode.
2.4.24
Q
This command puts the device into quiet mode, which means it is temporarily not discoverable or connectable. When you issue this command, the device responds Quiet.
This command does not survive a power cycle or reset.
You use this command with the Z command. For the lowest power mode, issue Q and
then Z. Use the Sniff settings for the lowest power while connected. See “Power Management” on page 41 for more details on low-power mode.
In firmware version 6.15 and higher, the Q command has the following settings that
have different responses as follows:
• Q—The module is undiscoverable (firmware version 4.77 and 6.15 and higher).
• Q,0—The module is discoverable and able to connect. Response is AOK. (firmware 6.11 and higher)
• Q,1—The module is not discoverable and not able to connect. (firmware version
6.11 and higher)
• Q,2—The module is able to connect but is not discoverable. (firmware version
6.11 and higher)
• Q,?—Displays the current quiet mode where ? is 0, 1, or 2 as defined above (firmware version 6.15 and higher).
Note:
2.4.25
In firmware version 6.11 and 6.12, the Q command displays the quiet mode.
R,1
This command forces a complete device reboot (similar to a power cycle).
Note:
2.4.26
Any changes to the device configuration using the set commands will not
take effect until you reboot the device.
T,<flag>
This command passes received data (from the UART or Bluetooth) while in command
mode according to the <flag> value shown in Table 2-16.
TABLE 2-16: T COMMAND VALUES
Flag
Description
0
Disable.
1
Enable.
Example: T,1
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// Pass received data while in command
// mode
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2.4.27
U,<value 1>,<value 2>
This command causes a temporary UART change, where <value 1> is the baud rate
and <value 2> is the parity. This command changes the serial parameters immediately,
but does not store them to flash memory. The device returns AOK at the current settings,
then automatically exits command mode and switches to the new baud rate.
The baud rate, <value 1>, must be EXACTLY 4 characters: 1200, 2400, 4800, 9600,
19.2K, 38.4K, 57.6K, 115K, 230K, 460K, or 921K. The parity, <value 2>, is E, O, or N
(must be capital letters).
Default:
60
Example: U,9600,E
2.4.28
// Set the baud rate to 9,600 with even
// parity
V
This command displays the firmware version.
Example: V
2.4.29
// Show the firmware version
W
This command enables discovery and connection after it has been disabled with the Q
command. It reloads the stored value of the inquiry and page window to re-enable. The
device returns Wake as a response.
Note:
For backwards compatibility with firmware version 4.77, this command is
available in firmware version 6.15 and higher.
In firmware version 6.11, the W command is deprecated. Instead, use Q,1.
Example: SI,0000
// Turn off discovery but still allow
// connections
// Turn on discovery and connections
W
2.4.30
Z
When you use this command, the device enters low-power, deep sleep mode (<2 mA)
when NOT connected. To exit this mode, power cycle the device or toggle the module’s
reset pin (causing a hard reset). For more information on managing power, see “Power
Management” on page 41.
2.5
GPIO COMMANDS
GPIO commands configure and manipulate the module’s GPIO signals. Each GPIO
command takes a 16-bit parameter made up of 2 bytes. The first byte is a mask to specify the GPIO number and the second byte is the command’s value:
PARAMETER[15:0] =
2.5.1
MASK[7...0]<<8 ||
VALUE[7..0]
S@,<hex value>
This command sets the GPIO pin’s direction (input or output). This setting is lost when
power is cycled.
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2.5.2
S&,<hex value>
This command sets the GPIO pin’s value. This setting is lost when power is cycled.
2.5.3
S%,<hex value>
This command stores the GPIO pin’s direction for use on power up.
2.5.4
S^,<hex value>
This command stores the GPIO pin’s powerup value.
2.5.5
S*,<hex value>
This command sets values for GPIO8, GPIO9, GPIO10, and GPIO11.
2.5.6
Controlling the GPIO Pins
Two registers control the GPIO pins:
• The direction register controls whether the GPIO is an input or an output.
• The second register is the value to apply to the GPIO if it is an output, or it is the
value of the built-in, weak pull-up resistor if the GPIO is an input.
These settings are immediate and do not survive a power cycle.
Example: S@,8080
2.5.7
// Set GPIO7 as an output
S&,8080
// Drives GPIO7 high
S&,8000
// Drives GPIO7 low
Setting GPIO Pin Power-Up Values
There are two additional registers that control the GPIO pin direction and value on
power up. You set these registers with the S% and S^ commands.
Example: S%,0101
// Set GPIO0 as an output on power-up
// Drive GPIO0 high and pull up GPIO1
S^,0303
You can set multiple bits can be set with a single command. Any bits with a mask of 0
are unaffected.
Some GPIO pins are read at power-up to perform certain functions; therefore, you must
be careful when manipulating them. For example, you can use GPIO3 and GPIO6 to
set master mode and auto discovery automatically. If you want to use these GPIO pins
for other purposes at power-up, you must disable the module from sensing these GPIO
pins upon power-up by using the SQ,4 command. This command sets a flag in a stored
register that is read at power-up. View the GPIO pin’s power-up settings using the O
(other settings) command.
WARNING
GPIO4 is used by the system to reset stored parameters to factory defaults. If GPIO4
is pulled high on power-up and then toggled 3 times, all user settings returns to the
factory default values. Therefore, you should not use this pin as an output and your
system should not drive it high at power-up (first 1 second of operation).
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GPIO2 and GPIO5 are driven by the embedded software as outputs. You can disable
them using the direction command (for example to save power) and them use them as
inputs. If these pins are set as outputs the software overrides any user values.
2.5.8
Setting GPIO8, GPIO9, GPIO10 & GPIO11
You use the S*, command to set these GPIO pins:
S*,<hex value> = MASK[11..8] VALUE[11..8]
For the upper 4 GPIO pins, a single word controls the mask and values,. Only the lower
4 bits of each byte are used. The first time you use this command, all 4 GPIO pins are
driven as outputs and remain as outputs until a power cycle. These bits cannot be set
to be read on powerup. Some modules do not offer these GPIO pins.
Example: S*,0101
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// Drive GPIO8 high
S*,0100
// Drive GPIO8 low
S*,0202
// Drive GPIO9 high
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NOTES:
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Chapter 3. Advanced Topics
This section provides information on advanced topics such as power management,
profile settings, design concerns, etc.
3.1
POWER MANAGEMENT
There are five different methods to lower Bluetooth device power consumption. Some
methods only have an effect when the device is in certain Bluetooth states (i.e., when
connected or disconnected). Additionally, each method has advantages, disadvantages, and requirements. Table 3-1 summarizes these methods.
TABLE 3-1:
POWER MANAGEMENT METHODS
Method
Bluetooth State
Advantages
Disadvantages
Optimize Inquiry
(Discovery) and
Page (Connection)
Window
Idle (Not Connected) or Active
Connection
The current can be reduced from more
Causes additional latency
than 20 mA to less than 5 mA (combining when pairing or connecting.
this method with Sniff mode uses less
than 3 mA).
Sniff Mode
Transmit
Active Connection
This mode can be combined with the
Optimize Inquiry (Discovery) and Page
(Connection) Window or Enable Deep
Sleep methods for lower power consumption.
-
Enable Deep Sleep
Idle (Not Connected)
With this method, current is reduced to
about 300 μA.
This method can cause
latency issues and may drop
the first byte if the device
wakes on RX data. It also
causes a loss of performance/power when the
device wakes frequently.
Disable Output Driv- Idle (Not Coners
nected) or Active
Connection
This method is simple to use. However, it External components driven
depends on the load: if the device is not by GPIO pins may not work
connected there are no power savings.
properly.
This method is required for Roving Networks evaluation boards to measure
power accurately.
Lower Transmit
Power
This method lowers power consumption The device has a shorter
during Txmt and active mode by reducing effective range.
radio output power.
Idle (Not Connected) or Active
Connection
3.1.1
Optimizing Inquiry (Discovery) & Page (Connection) Windows
In slave mode, there are two timers that can be used to lower radio power radio while
idle. When not connected, the Bluetooth radio is active when listening for other devices.
Other devices can discover (inquire) or connect (page) to the device. The amount of
time the radio listens is called the window, and the interval at which the process repeats
is called the interval.
For Roving Networks devices, the inquiry and page window is fixed at is 0x1000
(2.56 seconds). The default window is 0x0100 (160 ms) or a 6.25% duty cycle. By lowering the window values, you can save power at the expense of possibly missing an
inquiry or page request. Because the host usually retries many times automatically, the
only downside is a delay in discovery or connection time.
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You adjust the inquiry scan window using the SI command. The minimum window for
inquiry or page is 0x0012 (11.25 ms), which corresponds to about a 0.5% duty cycle.
Example: SI,0200
// Set the inquiry scan window to 0x0200
You adjust the page scan window using the SJ command. The minimum window for
inquiry or page is 0x0012 (11.25 ms), which corresponds to about a 0.5% duty cycle.
Example: SJ,0200
// Set the page scan window to 0x0200
Thus, you can reduce the average power from more than 20 mA to less than 5 mA in
standard mode and less than 3 mA in Sniff mode.
It is also possible (and desirable for security reasons) to completely disable inquiry.
Once a host has found and installed a device, inquiry is not required, only page is used
to make a connection. To disable inquiry while still allowing connections, set the inquiry
timer to 0 with the SI,0000 command.
3.1.2
Sniff Mode
Sniff mode, a Bluetooth power conservation method, only pertains to an active connection. In Roving Networks devices, Sniff mode is disabled by default and the radio is
active continuously when connected (about 25 to 30 mA). In Sniff mode, the radio
wakes up at specific intervals and sleeps in very low power mode (around 2 mA) the
rest of the time. With Sniff mode, the power savings can be quite dramatic.
To enable Sniff mode, use the SW,<hex value> command. Example interval timers:
0x0020 = 20 ms (32 decimal * .625 = 20)
0x0050 = 50 ms
0x00A0 = 100 ms
0x0190 = 250 ms
0x0320 = 500 ms
0x0640 = 1 second
When a connection is made, both master and slave must support Sniff mode and agree
to the Sniff window, otherwise, the radio remains in full active mode.
Note:
3.1.3
The maximum allowed Sniff interval is about 20 seconds, which is 0x7FFF.
Enabling Deep Sleep
You can use deep sleep mode to obtain extremely low power operation. In this mode,
the device shuts down completely and only draws about 300 μA of current. To enable
deep sleep, set the high-order bit of the Sniff word to 0x8000. This bit is NOT used to
determine the sleep interval, it is only used as a flag to enable deep sleep.
Example: SW,8320
// ½ second sleep (0x0320), with deep
// sleep enabled
In normal low-power sleep (not deep sleep) the firmware is still running in idle mode,
and wakes up about 20 times per second to check ports, update LEDs, etc. During
deep sleep, the firmware actually stops running some tasks. For example, the LEDs
only update about once per second. There are 3 ways to wake the radio from sleep
mode:
• Send a character to the UART.
• Transition the RX pin. The worst-case wake time is 5 ms. Therefore, the radio
generally loses the first character sent. A better way to wake the radio is to toggle
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the CTS line from low to high, wait 5 ms, and then send data.
• The radio can wake automatically every <hex value> slot times (1 slot time is
625 μs) as defined previously. The radio wakes and listens to see if the other side
of the connection has anything to send. This wake time is typically about 5 ms (8
slots) even if no data is to be transferred.
Once the radio is awake it stays active for exactly 1 second of inactivity, and then sleeps
again.
Note:
Setting this mode can cause latency issues and dropped bytes/loss of performance in cases where large amounts of data are being transferred. The
nuances of Bluetooth Sniff can be complex. If necessary, contact Roving
Networks for more details on how to use Sniff mode.
To enable even lower power utilization, use the S|,<hex value> command to set an
on/off duty cycle.
3.1.4
Disabling Output Drivers
Use the S%,1000 command to set all GPIO pins (0 to 11) to inputs. This command also
turns off the FireFly adapter LED (GPIO5). Refer to “GPIO Commands” on page 37 for
more information on using commands to control the GPIO pins.
3.1.5
Lowering Transmit Power
All Roving Networks Bluetooth modules adhere to the Bluetooth (version 1.1, 1.2, and
2.0/2.1) specifications for power control. The RN-21 and RN-41 radios are Class 1
capable.
The radio power output is automatically controlled by the baseband. Depending on the
mode (inquiry scan, page scan, connected) the power is adjusted. Once a connection
is made, the radios on both sides negotiate a power setting based on the perceived signal strength (RSSI).
The transmit power can be controlled to:
• Reduce effective range for security reasons.
• Lower radio emissions for agency compliancy concerns.
• Reduce total power consumption.
To configure the transmit power, use the SY,<hex value> command, where <hex
value> is an unsigned hex representation of the setting command. See Table 3-2. The
radio can use a value that is lower than the default.
TABLE 3-2:
POWER SETTINGS
Hex
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Power (dBM)
0010
16 (default)
000c
12
0008
8
0004
4
0000
0
FFFC
-4
FFF8
-8
FFF4
-12
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If a non-zero value is stored in the variable, upon power up the radio uses the highest
value that is less than or equal to the stored variable.
Example: SY,FFF8
// -8 dBM
// 0 dBm
SY,0000
The power setting takes effect after a power cycle, reboot, or reset pin toggle. To check
the stored power setting, use the O command; the device returns TX Power=1 (or other
setting equal to the value you entered). To view the current power setting, use the GY
command. The device returns only the actual value with no leading zeroes. The GY
value may not match the value in the shown with the O command due to how the value
is used as described previously.
Note:
3.2
Prior to August 2012, the SY, command used different power settings.
Refer to “SY,<hex value>” on page 27 for more information on the old
power settings and to determine which power settings your module uses.
CONFIGURATION TIMER SETTINGS
The module has a remote configuration timer to allow remote configuration over Bluetooth after power up in Slave Mode. In all Master modes, the remote configuration timer
is set to 0 (no remote configuration). In Trigger Master Mode, the configuration timer is
used as an idle timer to break the connection after time expires with no characters
received.
You can only configure remotely if the boot-up configuration timer (default 60 seconds)
has not expired. This timer is set to 0 (remote configuration disabled) for Master Mode
and Auto-Connect Slave Mode so that data can immediately flow between 2 modules
for cable replacement applications. Once the timer has expired, any data sent to the
module passes through unmodified and unrecognized by the command interpreter. The
timer can be set to any value from 0 (disable remote configuration) to 255 decimal,
which allows continuous (no timeout) configuration.
Table 3-3 shows the configuration timer settings.
TABLE 3-3:
CONFIGURATION TIMER SETTINGS
Value
(Decimal)
0
Description
No remote configuration. No local configuration when connected.
1 - 252
Time in seconds from power up to allow configuration.
253
Continous configuration, local only.
254
Continous configuration, remote only.
255
Continous configuration, local and remote.
You use the ST,<value> command to change the configuration timer settings. For
example:
ST,0
ST,255
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// Disable remote configuration
// Enable remote configuration forever
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3.3
INTERFACING TO A MICROPROCESSOR
Roving Networks Bluetooth devices can connect to 3.3-V (only) microprocessors using
the UART interface. When interfacing with a microprocessor, use the following guidelines:
• The Bluetooth device power, ground, RX, and TX signals must be connected and
CTS should be held low or tied to RTS.
• The Bluetooth device can go into command mode 500 ms after booting.
• The microprocessor should send $$$ with no carriage return or line feed to enter
command mode.
3.3.0.1
HOW DO I KNOW THE MODULE IS READY FOR COMMAND MODE?
500 ms after rebooting, the module is ready for command mode. You send $$$with no
carriage return.
3.3.0.2
WHICH HARD SIGNALS SHOULD I CONNECT?
You should connect power, ground, RX, and TX. CTS should be low or you can connect
or tie it to RTS.
3.4
HCI MODE
Roving Networks offers the Host Controller Interface (HCI) mode in addition to the standard operational mode of its Bluetooth modules (standard mode refers to the on-board
stack running on the module).
In HCI mode, the on-board stack is bypassed and the module is put in a state that runs
the Bluetooth baseband. The HCI provides a command reference interface to the baseband controller and the link manager, and provides access to the hardware status and
control registers. This interface provides a uniform method for accessing the Bluetooth
baseband capabilities.
In this mode, the Bluetooth stack is no longer on-board the module. It is offloaded to
the interfacing host processor. The Bluetooth module is used as a radio, performing the
lower level MAC functionalities, while the application stack runs on the host processor.
Using the module in HCI mode allows designers to implement profiles that are not
natively supported on the Bluetooth module.
Note:
HCI mode requires a separate firmware build that must be loaded into the
module’s flash at the factory. It cannot be updated in the field or by the user.
Roving Networks offers HCI mode in two hardware interfaces:
• HCI over UART
• HCI over USB
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3.4.1
HCI over UART
In this mode, the hardware interface between the host processor and the Bluetooth
module is the UART. You must interface the flow control signals between the host processor and the Bluetooth module for the HCI interface to work. Failure to do so can
cause the host processor and the Bluetooth module to become out of sync and break
the Bluetooth link.
3.4.2
HCI over USB
In this mode, the hardware interface between the host processor and the Bluetooth
module is the USB. In this architecture, the Bluetooth module is the USB slave and the
host processor is the USB host.
Using the USB interface offers the advantage of a faster data link between the Bluetooth module and the host processor. With this architecture, it is possible to achieve
Bluetooth’s theoretical maximum throughput of 3 Mpbs.
3.5
PROFILE SETTINGS & FEATURES
The default profile for Roving Networks Bluetooth device is the Serial Port Profile
(SPP). However, the firmware also supports the DUN profile in both master and slave
modes. To change the profile, use the S~,<value> command, where <value> is shown
in Table 3-4. Refer to “HID Profile” on page 59 for more information on using HID.
TABLE 3-4:
PROFILE CHANGE VALUES
Value
Profile
Comments
0
SPP
Default, no modem control
1
DUN-DCE
Slave or gateway
2
DUN-DTE
Master or client
3
MDM SPP
With modem control signals
4
SPP and DUN-DCE
Multi-profile
5
APL
iAP data connection to iOS device
6
HID
Human interface device (keyboard, mouse, etc.)
The most common use of DUN profile is to allow a Bluetooth client to connect to a
dialup modem. For this mode, use profile 1 (DUN-DCE) or S~,1. You may also want to
set the COD so that clients can recognize the device as a Bluetooth modem (COD
0x040210) using the following commands:
SC,0004
SD,0210
With firmware version 4.74 and higher, the device can connect to either SPP or DUN
(but not both at the same time). When a host discovers the device, the device displays
both services. The host can connect to either one. The device can also connect using
the SPP profile, disconnect, and then connect using the DUN profile.
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3.6
USING GPIO PINS AS MODEM CONTROL SIGNALS
RNXX modules can replicate the required modem control hardware signals automatically once a connection is made. These signals are transferred outside the data channel (using RFCOMM control channels) and are automatically updated. The default SPP
profile (profile = 0) does not drive these signals or report back inputs. If DUN or MDM
profiles are enabled (profile = 1, 2, or 3), the following signals are automatically driven
and received:
• Inputs, active low. These signals are read and sent back over Bluetooth to the
remote host.
- GPIO3 = DCD (dipswitch 2)
- GPIO6 = DSR (dipswitch 3)
- GPIO7 = CTS (dipswitch 4)
• Outputs. The remote host sends these signals and drives them out.
- GPIO10 = DTR (active high)
- GPIO11 = RTS (active low)
On the Firefly module, you can also use the dipswitches to set/clear the DCD, CTS, and
DSR signals. The DTR and RTS signals are available on the 9-pin header as well.
3.7
DESIGN CONCERNS
This section provides information on design concerns, such as hardware signals, hardware connections and power, LED status, optimizing for latency and throughput, common problems, etc.
3.7.1
Hardware Signals
The following sections provide information on the reset circuit, factory reset, connection
status, SPI bus, and other hardware connections.
3.7.1.1
RESET CIRCUIT
The RN41/RN42 modules contain a 1k pull-up to VCC, and the reset polarity is active
low. RN21/RN22 modules contain a 1k pull-down, and the reset polarity is active high.
The module’s reset pin has an optional power-on-reset circuit with a delay, which
should only be required if the input power supply has a very slow ramp or tends to
bounce or have instability on power up. Often a microcontroller or embedded CPU I/O
is available to generate the reset once power is stable. If not, designers can use one of
the many low-cost power supervisor chips currently available, such as the MCP809,
MCP102/121, and Torex XC61F.
3.7.1.2
FACTORY RESET GPIO4
Roving Networks recommends that designers connect the GPIO4 pin to a dipswitch,
jumper, or resistor so that it can be accessed. This pin can be used to reset the module
to its factory default settings, which is critical in situations where the module has been
misconfigured. To reset the module to the factory defaults, GPIO4 should be high on
power-up and then toggle low, high, low, high with a 1 second wait between the transitions.
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3.7.1.3
CONNECTION STATUS
GPIO5 is available to drive an LED, and it blinks at various speeds to indicate status
(see Table 3-5). GPIO2 is an output that directly reflects the connection state as shown
in Table 3-6.
TABLE 3-5:
GPIO5 STATUS
GPIO5 Status
Description
Toggle at 1 Hz
The module is discoverable and waiting for a connection.
Toggle at 10 Hz
The module is in command mode.
Low
The module is connected to another device over Bluetooth.
TABLE 3-6:
GPIO2 STATUS
GPIO2 Status
Description
High
The module is connected to another device over Bluetooth.
Low
The module is not connected over Bluetooth.
3.7.1.4
USING THE SPI BUS FOR FLASH UPGRADES
While not required, this bus is very useful for configuring the Bluetooth modules’
advanced parameters. The bus is required when upgrading the module’s firmware. In
a typical application, a 6-pin header can be implemented to gain access to this bus. A
minimum-mode version might simply use the SPI signals (4 pins) and obtain ground
and VCC from elsewhere in the design.
3.7.1.5
HARDWARE CONNECTIONS & POWER
When designing with Roving Networks Bluetooth devices, follow these guidelines:
• Placing 3.3-V DC power into the GPIO pins while they are set up as outputs will
permanently damage the radio modules. The failure mode is short across GND
and VCC. Use a 10-KΩ resistor in series or a 10-KΩ pull-up resistor for input and
output GPIO pins, respectively.
• Do not leave any GPIO pins floating (or have LEDs that might drift up to a voltage
such as 1.8 V) because it causes leakage in low-power mode.
• By default, you drive CTS high to enable deep sleep and then wake the device by
pulling CTS low. However, in some cases, you may need to tie the CTS pin high
(3.3-V inactive) for the module to go into deep sleep. This change must be performed at the factory; contact Roving Networks for more information.
• Connect a common ground when using the external TX/RX inputs 0 – 3.3 V DC.
• For a 3-wire DB-9 interface (TX, RX, and GND only), connect/short CTS to RTS.
The factory default is hardware flow control enabled, and CTS and RTS connected.
• When using a 5.0-V DC input, GPIO pins require a voltage divider. A good choice
is a 10 KΩ series with 20 K to ground. The GPIO pins are 0 - 3.3 V DC, not 5-V tolerant.
• To obtain the lowest power, the device should be passive (in slave mode and not
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trying to make any connections). When sleeping, the device uses 26 μA.
Note:
To connect with Android phones, the module must wake up once in a while
and be connectable (in this mode, the radio draws about 25 mA). The minimum wakeup time is 11 ms every 2.5 seconds, which gives an average
power of about 200 μA to be able to connect. You can fine-tune the power
usage by and turning the radio off for a number of seconds, e.g., 20 seconds, which draws 26 μA.
• Hardware communications connections for modules and evaluation board
- Radio TX Æ RX of the application microcontroller unit (MCU)
- Radio RX Å TX of the application MCU
- Radio RTS Æ CTS of the application MCU
- Radio CTS Å RTS of the application MCU
3.7.2
LED Status
Table 3-7 describes the green LED status. If installed on the evaluation board or module, the yellow LED blinks when data is transferred on the DB9 serial port’s RX or TX
pins. This LED is a physical monitor of the actual voltage, and is not driven by software
in the module. If installed, the blue LED indicates the transmit activity on the Bluetooth
link over the air interface.
TABLE 3-7:
GREEN LED STATUS
Mode
Green LED Blink Rate
Configuring
10 times per second
Startup/Configuration Timer
2 times per second
Discoverable/Inquiring/Idle
Once per second
Connected
Solid On
3.7.3
Optimizing for Latency or Throughput
The firmware must make decisions automatically on when to forward received data
coming into the UART RX input out the RF link. By default, the firmware is optimized
for throughput. In some cases, especially with smaller, close-spaced incoming data
packets, the data can get split, with a partial packet forwarded and other data coming
later. Unfortunately, Bluetooth has algorithms that can cause significant latency
between packets (> 10 ms) at certain times. If the host protocol expects data to come
as contiguous bursts and has short timeouts, this latency can cause errors.
Another optimization method forces the radio to attempt to keep small bursts of data
together. In this mode, the firmware is optimized for latency. To enable this mode, use
the special debug command SQ,16, which sets the latency bit in the firmware. To disable this mode, use the SQ,0 command. You can read the register’s value with the GQ
command.
Note:
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This command gives a result in hex even though the command is set in decimal.
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3.7.4
Limitations of 7-Bit Data Mode
Roving Networks firmware supports a selectable 7-bit data mode using the S7,1 command. The Bluetooth hardware, however, does not support 7-bit data, so this function
is accomplished in firmware. While completely functional, the 7-bit performance is
affected because it works through software emulation. Therefore, this mode has a
noticeable latency and character per second processing limit. Roving Networks does
not recommend using this mode if the desired serial baud rate is greater than 9,600.
3.7.5
Common Issues
The following sections provide some solutions to common issues.
3.7.5.1
MY BLUETOOTH CLIENT CAN SEE THE FIREFLY MODULE AND ITS
SERIAL SERVICE, BUT I CAN’T CONNECT
This issue is most likely caused by a security setting on your client. The FireFly module
supports authentication by default if the client requires it (with the default pin code of
1234), but for ease of use, you may want to turn security off on your client. Some clients
have these settings turned off by default, others have them turned on. To check and
disable security, perform the following steps from a Windows PC:
1. Click My Bluetooth Places.
2. Click the Client Applications tab under Bluetooth Device Configuration (or
Advanced Configuration).
3. Click the Bluetooth serial port application name.
4. Click the Properties button.
5. If Secure connection, Authentication, or Encryption is turned on, turn it off.
6. Click OK.
3.7.5.2
HOW DO I CHANGE THE CLIENT’S COM PORT?
The Widcomm stack, the most commonly used stack, allows you to connect to the FireFly module using a virtual COM port mapper. The software installs with a default COM
port, usually COM3, COM4, or COM5. To change this setting, perform the following
steps on a Windows PC:
1. Click My Bluetooth Places.
2. Click the Client Applications tab under Bluetooth Device Configuration (or
Advanced Configuration).
3. Click the Bluetooth serial port application name.
4. Click the Properties button.
5. Change the COM port setting.
6. Click OK.
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3.7.5.3
HOW DO I CONNECT TO MORE THAN ONE FIREFLY MODULE FROM
THE SAME CLIENT AT THE SAME TIME?
Bluetooth allows 7 devices to connect at a time in a piconet. The Widcomm stack allows
you to create multiple instances of the serial port profile and connect to multiple FireFly
modules at the same time. To connect to multiple modules, perform the following steps
on a Windows PC:
1. Click My Bluetooth Places.
2. Click the Client Applications tab under Bluetooth Device Configuration (or
Advanced Configuration).
3. Click the Bluetooth serial port application name.
4. Click the Add COM Port button.
5. Add another Bluetooth serial port and assign it to another virtual COM port (such
as COM9).
6. Click OK.
3.7.6
Discovery & Connection Example Sequence
The following example goes through a master discovery/connection sequence from
power up and no connection.
1. Perform an inquiry to obtain the Bluetooth address (unless it is already known).
Send: $$$
// Places radio in command mode
Reply: CMD<cr>
Send: I,30<cr>
// Look for Bluetooth devices
Reply: 00A096112233,1F00<cr>Inquiry Done<cr>
2. Store the remote address that you just found.
Send: SR,00A096112233<cr>
// or type SR,I if this was the only device
// found
Reply: AOK<cr>
3. Connect.
Send: C<cr>
Reply: AOK<cr>
// Places the radio in connect mode
The device attempts to connect to the remote slave. The terminal displays TRYING
while the device attempts to connect.
Reply:<string>CONNECT<cr>
// Where <string> is an alphanumeric
// string defined in the stored parameters
4. Send/receive data.
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3.7.7
Auto-Pairing/Auto-Connection
You can use the GPIO pins/dipswitches for auto-pairing and auto-connection. Table 3-8
shows the function for various settings of the GPIO pins/dipswitches.
TABLE 3-8:
GPIO PIN/DIPSWITCH SETTINGS FOR AUTO-PAIRING/CONNECTION
GPIO3/Dipswitch 2 GPIO6/Dipswitch 3
Low
Function
Low
Default slave, no special function.
High
Low
Slave, changes COD to 0x0055aa for auto pairing.
Low
High
Auto master, the module uses the stored address and does not try auto
pairing.
High
High
Auto master, auto pairing, the module looks for the first device with
0x55aa, stores it, and connects to it.
To enable cable replacement, set GPIO3 high on the slave device and GPIO3 and
GPIO6 high on the master. Once paired, GPIO3 is low on both devices (so re-pairing
with another Roving Networks device does not occur).
3.8
SERIAL ADAPTER CONFIGURATION
The Bluetooth serial adapters have male or female DB9 connectors. Refer to
Figure 3-1 and Table 3-9 for the pin-out.
FIGURE 3-1:
DB9 CONNECTOR PINS
1
5
6
TABLE 3-9:
Pin
DB9 CONNECTOR PIN-OUT
RN220XP& RN270M
Male DB9
RN240F & RN270F
Female DB9
RN422M & RN274M
Male DB9
1
NC
NC
NC
2
RXD
TXD
NC
3
TXD
RXD
RXD-
4
NC
NC
TXD+
5
GND
GND
GND
6
NC
NC
+5 VDC (Input)
7
RTS
CTS
RXD+
8
CTS
RTS
TXD-
9
4 – 12 VDC
4 – 12 VDC
NC
Note:
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9
The RS-232 interface uses the SIPEX SP3232ECA chip with capacitor
switch to generate the + and – signals; therefore, it is not driving the full
RS-232 voltages. Devices stealing power from the RS-232 pins may not
have enough voltage.
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3.9
NULL MODEM & FLOW CONTROL JUMPERS
You can configure the adapter’s serial interface to enable flow control and null modem
signaling. You access the jumper block by removing the cover from the Bluetooth serial
adapter. Figure 3-2 and Figure 3-3 show the jumper settings.
FIGURE 3-2:
RN422, RN240, RN270 & RN274 JUMPERS
Male DB9 (Default Configuration)
DTE 3 Wire - Flow Control Disabled
Jumper 1 < > 2, 3 < > 4, 9 < > 10
1
3
5
7
9
2
4
6
8
10
Male DB9
DTE - Flow Control Enabled
Jumper 1 < > 2, 3 < > 4, 5 < > 6, 7 < > 8
1
3
5
7
9
2
4
6
8
10
Male DB9
DCE - Flow Control Enabled, Null Modem
Jumper 1 < > 3, 2 < > 4, 5 < > 6, 7 < > 8
1
3
5
7
9
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2
4
6
8
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Female DB9 (Default Configuration)
DTE 3 Wire - Flow Control Disabled
Jumper 1 < > 3, 2 < > 4, 9 < > 10
1
3
5
7
9
2
4
6
8
10
Female DB9
DTE - Flow Control Disabled
Jumper 1 < > 3, 2 < > 4, 5 < > 6, 7 < > 8
1
3
5
7
9
2
4
6
8
10
Female DB9
DTE - Flow Control Enabled
Jumper 1 < > 2, 3 < > 4, 5 < > 7, 6 < > 8
1
3
5
7
9
2
4
6
8
10
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FIGURE 3-3:
RN220XP JUMPERS
Male DB9 (Default Configuration)
DTE 3 Wire
Jumper 1 < > 2, 7 < > 8, 9 < > 10
1
3
5
7
9
Male DB9
DCE - Flow Control Disabled
Jumper 1 < > 2, 7 < > 9, 8 < > 10
2
4
6
8
10
1
3
5
7
9
2
4
6
8
10
Male DB9
DCE - Flow Control Enabled
Jumper 3 < > 4, 5 < > 6, 7 < > 8, 9 < > 10
1
3
5
7
9
3.10
2
4
6
8
10
DIPSWITCH SETTINGS
The adapters have small configuration dipswitches on the top. You need a paper clip
or small screwdriver to flip them. Holding the adapter with the DB9 connector facing to
the right, refer to Figure 3-4 for the dipswitch numbering and on/off positions.
FIGURE 3-4:
DIPSWITCHES
RN240, RN422 & RN220XP
On
Off
4
3
2
1
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RN270 & RN274
On
Off
4
3
2
1
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Table 3-10 describes the functions controlled by the dipswitches.
TABLE 3-10:
Dipswitch
SWITCH FUNCTIONS
Function
Description
1
Restore factory defaults Turn on the switch, power up the adapter, and toggle the switch
ON-OFF-ON-OFF-ON to return the adapter to its factory settings. The green
LED blinks quickly for a moment and then continues to blink about once per
second.
2
Automatic discovery
In slave mode, this dipswitch sets a special class of device that is used by the
master to auto connect. If dipswitch 3 also turned on, the adapter performs a
search, stores, and connects to a remote Roving Networks Bluetooth device
that has dipswitch 2 turned on.
3
Automatic master
With this dipswitch turned on, the adapter acts as Bluetooth master and
auto-connects to a stored remote address. You must first set the Bluetooth
address of the slave device using the SR command or using instant cable
replacement settings.
4
Default baud rate
With this dipswitch turned off, the default 115 K baud rate is overridden by software baud rate configuration commands. If this dipswitch is turned on, the
baud rate is 9600 and the adapter ignores the software configuration.
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NOTES:
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Chapter 4. Applications
The following sections describe how to use Roving Networks Bluetooth devices for
instant cable replacement.
4.1
INSTANT CABLE REPLACEMENT
You can configure a pair of Roving Networks serial adapters (with or without the FirePlug USB dongle, RN-USB-X) to provide an instant serial cable replacement. The two
adpaters are paired using either:
• Hardware pairing via dipswitches
• Configured using software commands
4.1.1
Hardware Pairing Using Dipswitches
To pair using hardware, perform the following steps:
1. Turn off the adapters and set the dipswitches as shown in Figure 4-1.
FIGURE 4-1:
CABLE REPLACEMENT DIPSWITCH SETTINGS FOR
Master Mode
Auto Discovery &
Auto Master Turned On
On
Slave Mode
Auto Discovery Turned On
Off
4
3
2
1
On
Off
4
3
2
1
PAIRING
2. Power up both devices. The master discovers the slave device, stores its Bluetooth address, and connects. The devices are now paired and each device’s
green LED should be on solid.
3. The devices are now paired. Set dipswitch 2 on both devices to off so that they
do not try to re-pair each time power is cycled. See Figure 4-2.
FIGURE 4-2:
SETTING DIPSWITCH 2 FOR DEPLOYMENT
Master Mode
On
Slave Mode
Off
4
3
2
1
On
Off
4
3
2
1
Once paired, when the devices are in range of each other, they connect and the master
will not attempt to connect to any other Bluetooth device. To break the pairing, restore
the factory defaults using dipswitch 1.
4.1.2
Software Pairing Using Commands
To configure the master and slave devices for instant cable replacement, connect your
terminal emulator on the host to the devices via the COM port using the settings
115,200 baud, no parity, 8 bits, 1 stop bit, and no flow control.
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On the slave device, issue the following commands:
1. Put the device in command mode by sending the $$$ command. The device
returns CMD to indicate it is in command mode.
2. Send SM,0<cr> to put the device into slave mode.
3. Verify that the device is in slave mode by issuing the D action command. Look
for the MODE =Slav message.
4. Reboot the device using the R,1<cr> command. The changes do not take effect
until the device is rebooted.
On the master device, issue the following commands:
1. Put the device in command mode by sending the $$$ command. The device
returns CMD to indicate it is in command mode.
2. Send SM,1<cr> to put the device into slave mode.
3. Verify that the device is in slave mode by issuing the D action command. Look
for the MODE =Mstr message.
4. Ensure that the slave device is turned on, and send the I<cr> inquire command.
5. Locate the slave’s (remote side) Bluetooth address (BTA) in the results of the
inquiry command. The BTA is a 6-byte (12 hex-characters) value.
6. Store the remote BTA using the SR,<address><cr> command. For example, if
the remote BTA is 000666037083, enter the command SR, 000666037083<cr>
to store the remote address.
7. Reboot the device using the R,1<cr> command. The changes do not take effect
until the device is rebooted. The master device restarts and connects with the
remote slave device. A solid green LED indicates that the devices are connected.
For more information on instant cable replacement, refer to the Bluetooth Cable
Replacement Application Note on the Roving Networks website at http://www.rovingnetworks.com/Support_Overview.
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Chapter 5. HID Profile
5.1
OVERVIEW
Roving Networks Bluetooth modules support a variety of Bluetooth profiles, including
human interface device (HID), serial port profile (SPP), DUN, HCI, and iAP for use with
iPad, iPod and iPhone devices. The Bluetooth HID profile enables customers to
develop wireless products such as computer keyboards and keypads, trackballs, mice,
and other pointing devices, and game controllers (gamepads, joysticks, steering
wheels, etc.). Additionally, Roving Networks has extended the basic HID capability to
allow programmability and control of devices such as the iPad.
The HID profile defines the protocol between:
• Device (HID)—Services human data input and output to and from the host.
• Host—Uses or requests the services of a human interface device.
The Bluetooth HID profile allows users to control the HID descriptor, which defines the
device’s feature set, and the HID report, which host uses to interpret the data as ASCII
values, movement, etc. The HID report format follows the standard universal serial bus
(USB) HID protocol as to leverage existing host drivers.
In a typical usage scenario such as a keyboard, a device using the Roving Networks
Bluetooth HID profile replaces the USB cable. In this case, the ASCII value of a key
press is converted to a scan code in a raw HID report that the Bluetooth module sends
over the Bluetooth link to the host. The host driver software decodes the raw HID report
and passes the key values to the application running on the PC. Figure 5-1 shows
some typical HID environments.
FIGURE 5-1:
TYPICAL HID ENVIRONMENTS
The type of HID device, such as a keyboard, mouse, or joystick, is defined by the HID
descriptor in the raw HID report.
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5.2
HID FIRMWARE OVERVIEW
To use Roving Networks’ Bluetooth HID profile, you must use a special build of firmware, version 6.03 or later.
Note:
5.2.1
Roving Networks modules shipped with firmware version 6.11 and higher
support the HID profile. You do not need special firmware if your module is
running firmware 6.11 or higher.
Operational Modes
Roving Networks Bluetooth modules operate in two modes: data mode (default) and
command mode. While in data mode, the module is essentially a data pipe. When the
module receives data, it strips the Bluetooth headers and trailers and passes the user
data to the UART. When data is written to the UART, the module constructs the Bluetooth packet and sends it out over the Bluetooth connection. Thus, the entire process
of sending/receiving data to the host is transparent to the end microprocessor.
You configure the module by putting it into command mode and sending ASCII commands over a serial port or the Bluetooth link. Once you change the configuration
parameters, they persist until changed or you perform a factory reset. You enter command mode by opening a terminal emulator and sending the string $$$ to the module.
You can connect to the module remotely over Bluetooth or via a computer. When you
send $$$ the module returns CMD, indicating that it is in command mode.
Once the module is in command mode, you can send configuration commands to it via
the terminal. When you enter a valid command, the module returns AOK. It returns ERR
for an invalid command and ? for unrecognized commands. Type H<cr> to see a list of
commands, and D<cr> to view a summary of the module’s current settings. To return to
data mode, type ---<cr> or reset the device and re-connect.
5.2.2
Profile Configuration
The HID firmware supports Bluetooth HID and SPP. You switch between these profiles
using ASCII commands. In firmware version 6.10 and higher, the SPP profile is enabled
by default. To switch between HID and SPP, use the following commands:
S~,0
// Enables SPP protocol
R,1
// Reboot to use SPP
To switch back to HID, use the following command:
S~,6
// Enables HID profile
R,1
// Reboot to use HID profile
5.2.3
Device Discovery & Pairing
During pairing, the module determines the HID device type. As part of the Bluetooth
protocol, the HID device sends the type. By default, the Roving Networks’ modules running the HID profile are discoverable as a keyboard. You can change the device type
by setting the descriptor type using the HID flags register.
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After first pairing the host to a device with the Bluetooth HID module, the host initiates
a connection. However, if the initial connection is broken, as the case when the power
is cycled, the device must re-connect to the host. (The host will not initiate a connection.)
Using DTR mode 4 (default) or pairing mode 6 allows the module to auto-connect back
to the last paired host. Alternatively, you can reconnect by sending the C command
from command mode. See the following examples:
SM,4
// Use GPIO6 to make and break
// connections
SM,6
// Automatically make connections
// without using GPIO6
5.2.4
HID Flag Register
The HID flag register is a bit-mapped register that is configured while in command
mode. To set the register, use the SH,<value> command, where <value> is a 4-character hex word. The GH command returns the current value of the register. The default
factory setting is 0000, which corresponds to a keyboard. Table 5-1 shows the HID flag
register bits; currently only the lower 9 bits are defined.
TABLE 5-1:
HID FLAG REGISTER BITS
9
Force HID mode if
GPIO11 is high on
power-up.
8
7..4
Toggle virtual key- Descriptor type:
board on iOS when
first connected.
0000 = Keyboard
0001 = Game Pad
0010 = Mouse
0011 = COMBO
0100 = JOYSTICK
1XXX = Reserved
5.2.4.1
3
Send output reports
over UART.
2..0
Indicates number of paired
devices to which the module
can reconnect.
BIT 9
Bit 9 is an enable bit that overrides the profile selection mode. When this bit is set, the
firmware checks the level of GPIO11 on power up; if it is high, the module switches to
HID mode. With this bit, you can set the module’s default profile to SPP mode, allowing
SPP and remote configuration (for example from Bluetooth clients with SPP). Then,
you can use GPIO11 to override SPP mode and enable HID mode.
Note:
5.2.4.2
GPIO11 HID profile switching is disabled when the module is configured for
the MDM SPP profile (S~,3). GPIO11 is reserved for RTS in MDM SPP
mode.
BIT 8
Bit 8 enables the toggling of the virtual keyboard on iOS devices.
5.2.4.3
BITS 7-4
Bits 7 through 4 control the following settings:
• The COD that is advertised by the module.
• The HID report descriptor and the available reports.
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5.2.4.4
BIT 3
Bit 3 enables output reports, which are sent by the host to the device over Bluetooth to
the UART. These reports are a feedback mechanism to the embedded microcontroller.
The output record is formatted as:
<start> <number of bytes>
0xFE
1–8
<report>
data
For example, the HID keyboard output reports the keyboard LED status as:
0xFE
0x2
5.2.4.5
0x1 <LED status byte>
BITS 2-0
Bits 2 through 0 define the number of paired hosts to which the module attempts to
reconnect after power up. After each successful pairing, the link key is stored in the Bluetooth module. Up to eight paired link keys are stored in FIFO fashion. Upon power
up, the module tries to connect to the most recently paired device. If it is not found, the
module attempts to connect to the next N hosts depending upon the settings of bits 2-0
in the HID register.
For example:
• To set the device as a mouse, use SH,0220.
• To set the device as a combo mouse, use SH,0230.
5.3
HID REPORTS
The module interprets input on the UART and generates an HID report that is sent over
the Bluetooth link to the host. Input to the module is interpreted as shown in Table 5-2
TABLE 5-2:
DATA INTERPRETATION
Binary Input
Function
0
Disconnect if connected from the host.
0x1 - 0xF
Converted to special keys like home, page up, backspace, etc.
0x10 - 0x7E
Translation mode: printable ASCII characters.
0x7F
Toggle virtual keyboard on iPhone.
0x80 - 0xDF
Interprets input as actual scan code.
0xE0 - 0xE7
Sends modifier keys Left Shift, Left Alt, Right Shift, etc.
0xE8 - 0xEF
Interprets input as actual scan code.
0xF0 - 0xFC
Reserved for custom reports.
0xFD
Raw mode: input is RAW report.
0xFE
Interpretive mode: input is shorthand report.
0xFF
Sends output report to UART.
See “Scan Code Tables: UART (ASCII) to HID Report” on page 67 for a complete table
of UART input to HID report.
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5.3.1
Translation Mode
Translation mode is the simplest way to send HID reports for printable ASCII characters. When the Bluetooth module’s UART receives a printable ASCII value, it is converted into a keyboard raw HID report. Two reports are sent for each character; the first
report indicates that the key is pressed and the second indicates that it is released. For
example:
a is translated into:
0xFD
0x9
0x1
0x0
0x04
0x0
0x0
0x0
0x0
0x0
0x0
0x0
0x0
Key Press
0xFD
0x9
0x1
0x0
0x00
0x0
0x0
0x0
0x0
0x0
0x0
0x0
0x0
Key Release
A is translated into:
0xFD
0x9
0x1
0x2
0x0
0x04
0xFD
0x9
0x1
0x0
0x00
0x00
0x0
0x0
0x0
0x0
0x0
0x0
0x0
0x0
Key Press
0x0
0x0
0x0
0x0
0x0
0x0
0x0
0x0
Key Release
Notice that the scan code for A is the same as the previous raw report except the modifier byte indicates the left Shift key is pressed. If multiple scan codes are sent, the modifier applies to all of them.
5.3.2
Keyboard Shorthand Mode
The Roving Networks HID profile supports shorthand for implementing keyboards. The
advantage of this mode is that multiple keyboard keys can be sent with minimal characters over the UART, which optimizes bandwidth because the module does not have
to send a keyboard report. Shorthand reports start with 0xFE and have variable length.
The shorthand format is:
0xFE
Length
Modifier
Scan
Code 1
Scan
Code 2
Scan
Code 3
Scan
Code 4
Scan
Code 5
Scan
Code 6
where Length = 0, 2, 3, 4, 5, 6, or 7, depending on how many keys are sent.
For example, shorthand for the a, b, and c keys is:
0xFE
0x3
0x0
0x4
0x05
0x06
The Bluetooth module converts this shorthand into the following raw HID reports that
are sent over the Bluetooth link:
0x9
0x1
0x0
0x04
0x5
0x6
0x0
0x0
0x0
0x0
0x0
0x0
Shorthand to release all three keys is:
0xFE
5.3.3
0x0
Raw Report Mode
The start byte 0xFD indicates a raw HID report. In the Bluetooth module, the start byte
is stripped and the following bytes are sent without interpretation. The Raw HID report
consists of a start byte, length, descriptor type (which defines the type of HID device),
and data specified in scan codes or encoded values. The format of the data depends
on the descriptor type. HID reports are sent one report at a time.
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The raw report format is:
Start
(1Byte)
Length
(1 Byte)
Descriptor
(1 Byte)
Data
Length – One Byte for the Descriptor
The keyboard report format is:
0xFD
9
1
Modifier
0x00
Scan
Code 1
Scan
Code 2
Scan
Code 3
Scan
Code 4
Scan
Code 5
Scan
Code 6
The modifier byte is a bit mask interpreted as shown below. For example, you can use
0x2 or 0x20 to turn a lower case a into an upper case A.
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Right
GUI
Right
Alt
Right
Shift
Right
Ctrl
Left
GUI
Left
Alt
Left
Shift
Left
Ctrl
The mouse raw report format is:
0xFD
5
2
Buttons
X-stop
Y-stop
Wheel
The consumer report format in keyboard or combo mode is:
0xFD
3
3
Data Byte
Data Byte
The joystick and gamepad format is:
0xFD
6
Buttons
0-7
Buttons
8 - 15
X1
Note 1
Y1
Note 1
X2
Note 1
Y2
Note 1
The range of X and Y is -127 to 127.
Note 1:
In combo mode, it is possible to send both for a keyboard and mouse HID reports. In
this case, if you wanted to enter an A and move the mouse you can use either of the
following methods:
A:
0XFD
0x5
0x2
0x0
0x1
0x20
0x20
0x20
or
0xFD
0x9
0x1
0x2
0x0
0x04
0x0
0XFD
0x5
0x2
0x0
0x1
0x20
0x20
5.3.4
0x0
0x0
0x0
0x0
0x0
0x0
0x0
0x20
Special Reports & Modes
This section describes special modes and reports, including output reports, virtual keyboards, a key-map register, etc.
5.3.4.1
OUTPUT REPORTS
Because the host controls the modifier keys’ state, the HID device must be able to
request the current status. The output report code 0xFF is reserved to return the current
status of the Caps Lock, Num Lock, and Scroll Lock keys over the UART. Because a
HID device can only toggle these keys, it tells the device the state of the keys. This
functionality is particularly useful when multiple HID devices are in the system and the
Bluetooth device needs to update the state of these keys. The format is sent as:
0xFF
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Status
Byte
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Table 5-3 shows the status byte definitions.
TABLE 5-3:
STATUS BYTE DEFINITIONS
5.3.4.2
Key
Status Bit
Num Lock
1
Caps Lock
2
Scroll Lock
4
APPLE VIRTUAL KEYBOARD
When the module is connected to an iOS device, the virtual keyboard is hidden. However, in some applications it is useful or required to display the keyboard for data entry
on the touch screen of the iOS device. Toggling GPIO9 displays or hides the virtual keyboard. GPIO9 must go from low to high for at least 200 ms for the toggle to occur.
Note:
5.3.4.3
The virtual keyboard toggle must be enabled in the HID flag register for this
feature to work.
KEY MAP REGISTER
This register allows you to replace any ASCII code with another ASCII code. It is useful
in cases where you want to toggle special keys that the device cannot generate. For
example, the touch keyboard on an iOS device is 0x7F, but the device cannot generate
0x7F.
If the register is non-zero, the upper byte is the key to replace, and the lower is the
replacement. The command to set the register is S=,< value>, where <value> is a
4-character hex word. To obtain the current value of the register, use the G= command.
(The value also shows up in the advanced settings using the E command.) The default
factory setting is 0000 (not enabled).
For example, to use the tilda (~), which is 0xfe, to toggle the keyboard, enter the command S=,7e7f.
5.3.4.4
DISCONNECT KEY
A special hex key value 0x00 (zero) causes a Bluetooth disconnect, which allows you
to control the connection by sending a single key. To disconnect, send 0x0.
Combining the disconnect feature with the key map register, any key can be used as a
disconnect key. For example to set the capital Z key (hex 5A) as the disconnect key,
use the following command:
// Map Z key as the disconnect key
S=,5A00
5.3.4.5
CONSUMER REPORT
You can use a HID raw report to send additional keys as a consumer report. The format
is:
0xFD
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3
3
Low Byte
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High Byte
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Table 5-4 shows the data byte format.
TABLE 5-4:
DATA BYTE FORMAT
Consumer Key Function
Report Bit
AC Home
0x1
AL Email Reader
0x2
AC Search
0x4
AL Keyboard Layout (Virtual Apple Keyboard Toggle)
0x8
Volume Up
0x10
Volume Down
0x20
Mute
0x40
Play/Pause
0x80
Scan Next Track
0x100
Scan Previous Track
0x200
Stop
0x400
Eject
0x800
Fast Forward
0x1000
Rewind
0x2000
Stop/Eject
0x4000
AL Internet Browser
0x8000
For example, to raise the volume, send:
0xFD
0x03
0x03
0x10
0x00
To release the key, send:
0xFD
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0x03
0x03
0x00
0x00
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5.3.4.6
SCAN CODE TABLES: UART (ASCII) TO HID REPORT
Table 5-5 shows the UART-to HID input conversion.
TABLE 5-5:
UART-TO-HID SCAN CODE
UART Input
HID Code
0
NA
1
0x49
Insert
2
0x4A
Home
3
0x4B
Page up
4
0x4C
delete
5
0x4D
end
6
0x4E
Page down
7
0x4F
Right arrow
8
0x2A
Backspace
9
0x2B
TAB
10
0x28
Enter
11
0x50
Left arrow
12
0x51
Down arrow
13
0x28
Enter
14
0x52
Up arrow
15-26
0x3A-45
F1 - F12
27
0x29
Escape
28
0x39
Caps lock
29
0x47
Scroll lock
30
0x48
Break-pause
31
0x53
Num lock
32-126
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HID Function
Disconnect if Connected
Printable ASCII characters
127
0x65
Toggle iPhone virtual keyboard
0x80-0xDF
0x80-0xDF
Sends actual scan code
0xE0
0xE0
Left Control
0xE1
0xE1
Left Shift
0xE2
0xE2
Left Alt
0xE3
0xE3
Left GUI
0xE4
0xE4
Right Control
0xE5
0xE5
Right Shift
0xE6
0xE6
Right Alt
0xE7
0xE7
Right GUI
0xE8-0xEF
0xE8-0xEF
Sends actual scan code
0xF0-0xFC
Reserved for future use
Custom reports
0xFD
Raw report
0xFE
Shorthand report
0xFF
Sends output report to UART
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Table 5-6 shows the ASCII to HID report scan codes.
TABLE 5-6:
ASCII
ASCII TO HID REPORT (TO HOST) SCAN CODES
Code
ASCII
Code
10
ASCII
System Power
81
mM
6^
System Sleep
82
nN
11
7&
System Wake
83
oO
12
8*
Code
23
ASCII
Code
.>
37
24
/?
38
25
Caps Lock
39
No Event
00
pP
13
9(
26
F1
3A
Overrun Error
01
qQ
14
0)
27
F2
3B
POST Fail
02
rR
15
Return
28
F3
3C
ErrorUndefined
03
sS
16
Escape
29
F4
3D
aA
04
tT
17
Backspace
2A
F5
3E
bB
05
uU
18
Tab
2B
F6
3F
cC
06
vV
19
Space
2C
F7
40
dD
07
wW
1A
-_
2D
F8
41
eE
08
xX
1B
=+
2E
F9
42
fF
09
yY
1C
[{
2F
F10
43
gG
0A
zZ
1D
]}
30
F11
44
hH
0B
1!
1E
\|
31
F12
45
iI
0C
2@
1F
Europe 1
32
Print Screen
46
jJ
0D
3#
20
;:
33
Scroll Lock
47
kK
0E
4$
21
‘“
34
Break (Ctrl-Pause)
48
lL
0F
5%
22
,<
36
Pause
48
5.4
HID REFERENCES
[1] Bluetooth SIG, Human Interface Profile Overview
URL: https://www.bluetooth.org/Building/HowTechnologyWorks/ProfilesAndProtocols/HID.htm
[2] USB.org, HID Usage Tables
URL: http://www.usb.org/developers/devclass_docs/Hut1_12v2.pdf
[3] USB.org, HID Technology
URL: http://www.usb.org/developers/hidpage/
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Appendix A. Factory Defaults
Table A-1 shows the factory default settings.
Note:
TABLE A-1:
Restoring the device to the factory default values resets all values to the
defaults shown in Table A-1.
FACTORY DEFAULT SETTINGS
Setting
Default Value
Bluetooth Service Profile
Serial Port Profile (SPP)
Device Mode
4 (DTR)
Baud Rate
115,200 bps
Parity
None
Data Bits
8 Bits
Stop Bits
1 Bit
Power Mode
Auto Low-Power Discoverable Mode
Device Name (Local Name)
FireFly-xxxx (last 2 bytes of the Bluetooth Address)
Service Class
SPP
Service Type
0000 (Undefined Service Type)
Class of Device (COD)
0x1F00 (Unknown Device Type)
Authentication
Keybboard I/O simple secure pairing (SPP)
Discovery Enabled
0x0100 Window, Fixed Interval of 0x1000
Connection Enabled
0x0100 window, Fixed Interval of 0x1000
Bonding
Disabled
Configuration Timer
60 seconds
Sniff Mode
Disabled
Default Pin
1234
Hide Pin Code
0, Disabled
Local Echo of RX Characters in Command Mode
OFF
Power
0010 (Maximum Power)
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NOTES:
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Appendix B. Command Quick Reference Guide
This section provides a quick reference of the firmware commands as well as the factory defaults. Table B-1 provides an overview of the set commands.
TABLE B-1:
SET COMMANDS
Command
Description
Factory Settings
S7,<1,0>
7-Bit Data Mode Enable/Disable.
0, Disabled
SA,<0,1,2,4>
Authentication Enable/Disable.
0, Disabled
SB,<value>
Send Break.
Not Applicable
SC,<value>
Service Class.
0x0000, Unknown
SD,<value>
Device Class.
0x1F00, Undefined
SE,<string>
Sets the UUID for SPP Data Connections.
0x1101
SF,1
Factory Defaults.
N/A
SH,<value>
Sets the HID flag register (HID firmware only).
0200
SI,<hex value>
Inquiry Scan Window.
0x0100
SJ,<hex value>
Page Scan Window.
0x0100
SL,<E,O,N>
Parity.
N, None
SM,<0,1,2,3,4,5>
Mode (0 = Slave, 1 = Master, 2 = Trigger, 3 = Auto, 4 = DTR, 5 =
Any).
4, DTR
SN,<string>
Name.
FireFly-xxxx
SO,<string>
Connect/Disconnect Status String.
NULL, No Status String
SP,<string>
Pin Code.
1234
SQ,<mask>
Special Configuration Settings.
0
SR,<hex value>
Remote Address (Use SR,Z to Remove).
None Set
SS,<string>
Service Name.
SPP
ST,<value>
Configuration Timer.
60 Seconds
SU,<value>
Baud Rate.
115 K
SW,<value>
Sniff Rate.
0x0000, Disabled
SX,<1,0>
Bonding.
0, Disabled
SY,<hex value>
Power Setting.
0010
SZ,<value>
Raw Baud Rate.
N/A
S|,<value>
Low-Power Connection Mode.
0000
S~,<0, 1, 2, 3, 4, 5, 6> Profile Setting (0 = SPP, 1 = DUN-DCE, 2 = DUN-DTE, 3 = MDM
SPP, 4 = DUN-DCE & SPP, 5 = APL, and 6 = HID).
0, SPP
S-,<string>
Sets the Serialized Friendly Name of the Device.
N/A
S?,<0,1>
Enable/Disable Role Switch.
0, Disabled
S$,<string>
Configuration Detection Character.
$$$
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Table B-2 describes the get (or display) commands.
TABLE B-2:
GET (DISPLAY) COMMANDS
Command
Description
D
Basic Settings.
E
Extended Settings.
G<string>
Displays Setting for a Set Command Indicated by <string>.
GB
Bluetooth Address.
GK
Connection Status.
GF
Bluetooth Address of Currently or Most Recently Connected Active Remote
Device.
GR
Remote Address.
G&
I/O Ports.
H
Help.
M
Remote Modem Signal Status.
O
Other Settings.
V
Firmware Version.
Table B-3 describes the action commands.
TABLE B-3:
ACTION COMMANDS (PART 1 OF 2)
Command
Description
$$$
Enter Command Mode.
---
Exit Command Mode.
+
Toggle the Local Echo of RX Characters in Command Mode.
&
Return the Dipswitch Values.
C
Connect Immediately to the Stored Remote Address.
C,<address>
Connect to Address.
CF<address>
Connect to Address in Fast Mode.
CFI
Connect and Immediately Go into Fast Data Mode Using Last Address Found.
CFR
Connect to Stored Remote Address in Fast Mode.
CT<address>,<value>
Connect, Address Required, Optional Disconnect Timer in ¼ Seconds.
F,1
Enter Fast Data Mode, End Configuration Immediately.
I,<value>,<COD>
Device Scan Inquiry, Time in Seconds, Optional COD Filter (0 = All).
IN<value>,<COD>
Device Scan Inquiry, Returns NAMEs.
IQ
Scans for Devices and Returns their RSSI.
IS<value>
Device Scan Inquiry, Fixed COD (0x001F00) to Find Roving Networks Devices.
IR<value>
Device Scan Inquiry, Fixed COD (0x0055AA) to Find Instant Cable Pairs.
J
Hides the Device’s Pin Code.
K,
Kill (Disconnect) from Current Connection.
L
Toggle Link Quality Readings.
P,<char>
Pass through Any Character up to a Carriage Return or Line Feed.
Q
Quiet, Turn off Discovery and Connectability.
R,1
Reboot.
T,<0,1>
Pass Received Data (from UART or Bluetooth) while in Command Mode.
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TABLE B-3:
ACTION COMMANDS (PART 2 OF 2)
Command
Description
U,<value>,<E,O,N>
Temporary UART Change.
W
Re-Enable Discovery and Connectability.
Z
Enter Low-Power Sleep Mode.
Table B-4describes the GPIO commands.
TABLE B-4:
GPIO COMMANDS
Command
DESCRIPTION
S@,<hex value>
Set the GPIO pin’s direction (input or output). This setting is lost when power is cycled.
S&,<hex value>
Set the GPIO pin’s value. This setting is lost when power is cycled.
S%,<hex value>
Store the GPIO pin’s direction for use on power up.
S^,<hex value>
Store the GPIO pin’s powerup value.
S*,<hex value>
Set values for GPIO8, GPIO9, GPIO10, and GPIO11.
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NOTES:
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Appendix C. Firmware Revision History
The following sections provide the firmware revision history.
C.1
VERSION 6.15 (3/26/2013)
This firmware replaces version 4.77. Designers are encouraged to create all new
designs based on firmware version 6.15 and higher.
• The following commands that were changed or deprecated in version 6.11 have
been restored in 6.15 to maintain backwards compatibility (command level) with
firmware version 4.77.
- L—This command displays the minimun and maximium RSSI values.
- Q—Places the module in a non-discoverable mode (same as Q,1 in firmware
6.12)
- W—wakes up module (same as Q,0 in firmware 6.12)
• Changes to commands available in firmware 6.12:
- Q,? displays the current quiet mode (in firmware 6.12, you use the Q command to display the mode).
- SE,(0,1) are null commands in firmware 6.15 to maintain compatibility with
firmware 4.77 command syntax.
• Inquiry and Page scan defaults to 0x0100 for compatibility with firmware 4.77. In
firmware 6.11/6.12, the page interval was set to 0x0060.
C.2
VERSION 6.12 (LIMITED RELEASE)
• Incorporates the HID profile into the standard firmware.
• Added the J command to hide the device’s pin code. This command replaces the
SV,1 command (hide or show the pin code).
• Updated the IQ command to include RSSI inquiry scanning.
C.3
VERSION 6.11
No new features. Improved code to make it more maintainable.
Inquiry and page interval set to 0x0060.
C.4
VERSION 6.10
• Added additional functionality to the Q command to enable/disable device discovery and ability to connect.
• Added authentication modes: open mode, keyboard mode, SSP mode, and pin
code mode.
• Encryption is enabled by default and cannot be disabled.
• Added the ability to store a custom UUID in the device.
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C.4.1
HID Firmware Known Issues
• The HID firmware has difficulty maintaining a connection with the first generation
iPAD running iOS version 4.4; you must upgrade to iOS version 5 to use the iPad
with the HID firmware.
• The HID profile does not appear to work with BlueSoleil.
C.5
VERSION 4.77 (8/10/2009)
• Fixed issue where disconnect followed by a fast reconnect (< 100 ms) would cause the
module to go (deaf) making it undiscoverable or connectable, requiring a reset.
• Fixed issue where <cr><lf> characters often were sent out the UART when entering fast
data mode using the F,1 command remotely.
•
•
•
•
C.6
Added the S| command to reduce power while waiting for a connection.
Added CF, CFI, and CFR commands for fast data mode connections.
Added L command to display link quality.
Added + command to toggle local echo of characters in command mode.
VERSION 4.74 (3/7/2009)
• Added support for SPP and DUN simultaneous profile appearance.
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Appendix D. Document Information
CONVENTIONS USED IN THIS GUIDE
This manual uses the following documentation conventions:
DOCUMENTATION CONVENTIONS
Description
Arial font:
Italic characters
Represents
Referenced books
Emphasized text
A window
A dialog
A menu selection
A field name in a window or
dialog
A menu path
MPLAB® IDE User’s Guide
...is the only compiler...
the Output window
the Settings dialog
select Enable Programmer
“Save project before build”
A dialog button
A tab
A number in verilog format,
where N is the total number of
digits, R is the radix and n is a
digit.
A key on the keyboard
Click OK
Click the Power tab
4‘b0010, 2‘hF1
Italic Courier New
Sample source code
Filenames
File paths
Keywords
Command-line options
Bit values
Constants
A variable argument
Square brackets [ ]
Optional arguments
Curly braces and pipe
character: { | }
Ellipses...
Choice of mutually exclusive
arguments; an OR selection
Replaces repeated text
#define START
autoexec.bat
c:\mcc18\h
_asm, _endasm, static
-Opa+, -Opa0, 1
0xFF, ‘A’
file.o, where file can be
any valid filename
mcc18 [options] file
[options]
errorlevel {0|1}
Initial caps
Quotes
Underlined, italic text with
right angle bracket
Bold characters
N‘Rnnnn
Text in angle brackets < >
Courier New font:
Plain Courier New
Represents code supplied by
user
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Examples
Version 1.0r 3/26/13
Advanced Information
File>Save
Press <Enter>, <F1>
var_name [,
var_name...]
void main (void)
{ ...
}
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RN-BT-DATA-UG
RECOMMENDED READING
This user’s guide describes how to configure Roving Networks Bluetooth data modules.
The module-specific data sheets contain current information on the module hardware
specifications. Other useful documents are listed below. The following documents are
available and recommended as supplemental reference resources:
RN41/41N Class 1 Bluetooth Module Data Sheet
This data sheet provides detailed specifications for the RN41/41N module.
RN42/42N Class 2 Bluetooth Module Data Sheet
This data sheet provides detailed specifications for the RN42/42N module.
To obtain any of these documents, visit the Roving Networks web site at
www.rovingnetworks.com.
DOCUMENT REVISION HISTORY
Revision 1.0r (March 2012)
This is the initial released version of the document.
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Index
Numerics
C
7-bit data mode ........................................................ 50
C,.............................................................................. 33
cable replacement.................................................... 57
using hardware ................................................. 57
using software................................................... 57
CF, ........................................................................... 33
COM port, changing ................................................. 50
command
action ................................................................ 72
get ..................................................................... 72
quick reference ................................................. 71
set ..................................................................... 71
command mode ................................................... 6, 60
entering ............................................................... 8
command syntax ...................................................... 19
commands
action ................................................................ 32
change .............................................................. 32
get ..................................................................... 31
GPIO ........................................................... 32, 73
set ..................................................................... 19
common issues ........................................................ 50
computer
pairing ............................................................... 15
configuration............................................................. 11
local..................................................................... 7
over Bluetooth..................................................... 7
profile ................................................................ 60
remote................................................................. 7
serial adapter .................................................... 52
timer settings..................................................... 44
using GPIO ....................................................... 11
connecting................................................................ 15
connection
auto ................................................................... 52
changing COM port........................................... 50
example ............................................................ 51
issues connecting ............................................. 50
making .............................................................. 12
status ................................................................ 48
to multiple modules from 1 client ...................... 51
controlling modem.................................................... 47
CT,, .......................................................................... 33
Customer Support .................................................... 78
A
action command
--- ...................................................................... 32
& ....................................................................... 32
+........................................................................ 32
$$$ .................................................................... 32
C ....................................................................... 32
C, ...................................................................... 33
CF, .................................................................... 33
CFI .................................................................... 33
CFR .................................................................. 33
CT,, ................................................................... 33
F,1..................................................................... 34
H ....................................................................... 34
I,, ....................................................................... 34
IN, ..................................................................... 34
IR ...................................................................... 35
IS ...................................................................... 35
L ........................................................................ 35
M ....................................................................... 35
O ....................................................................... 36
P, ...................................................................... 36
Q ....................................................................... 36
R,1 .................................................................... 36
T,....................................................................... 36
U,, ..................................................................... 37
V ....................................................................... 37
W ...................................................................... 37
Z........................................................................ 37
action commands ..................................................... 72
Android phones ........................................................ 49
APL .......................................................................... 46
auto-connect ............................................................ 11
auto-connect ANY mode .......................................... 10
auto-connect DTR mode .......................................... 10
auto-connect master mode ...................................... 10
auto-connection ....................................................... 52
auto-discovery pairing .............................................. 11
auto-pairing .............................................................. 52
B
baud rate .................................................................. 11
Bluetooth
configuration ....................................................... 7
connection ...................................................12, 15
discovery........................................................... 13
pairing ............................................................... 13
profiles .............................................................. 60
boot-up, timing ......................................................... 69
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D
data mode ............................................................ 6, 60
DB9 pins................................................................... 52
deep sleep................................................................ 42
default
pin code ............................................................ 17
default configuration................................................... 6
defaults, factory........................................................ 69
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design concerns ....................................................... 47
device reboot ........................................................... 36
dipswitch .................................................................. 54
dipswitch settings ..................................................... 54
dipswitches .........................................................11, 55
disable output drivers ............................................... 41
disabling output drivers ............................................ 43
discovery .................................................................. 13
example ............................................................ 51
HID profile ......................................................... 60
DUN-DCE ................................................................ 46
DUN-DTE ................................................................. 46
E
enable deep sleep.................................................... 41
evaluation boards....................................................... 5
example
discovery and connection ................................. 51
F
factory defaults......................................................... 69
factory reset ........................................................11, 47
firmware ................................................................... 75
fixes .............................................................75, 77
HID profile ......................................................... 60
release notes ...............................................75, 77
firmware version....................................................... 37
flag register bits........................................................ 61
flow control ............................................................... 53
flow control jumpers ................................................. 53
GPIO4 ................................................................ 12, 47
GPIO5 ................................................................ 12, 48
GPIO6 ...................................................................... 12
GPIO7 ...................................................................... 12
GPIO8 ................................................................ 12, 39
GPIO9 ................................................................ 12, 39
green LED ................................................................ 49
H
hardware connections .............................................. 48
hardware pairing ...................................................... 57
hardware signals ...................................................... 47
HCI mode ................................................................. 45
HCI over UART ................................................. 46
HCI over USB ................................................... 46
HID ........................................................................... 46
HID profile
discovery and pairing ........................................ 60
fag register ........................................................ 61
firmware ............................................................ 60
reports............................................................... 62
translation ......................................................... 63
typical uses ....................................................... 59
I
I,, .............................................................................. 34
IN,............................................................................. 34
instant cable replacement ........................................ 57
IR.............................................................................. 35
IS.............................................................................. 35
G
J
get
jumpers .................................................................... 53
jumpers, flow control ................................................ 53
D ....................................................................... 31
E ....................................................................... 31
G ....................................................................... 32
G&..................................................................... 31
GB..................................................................... 31
GF ..................................................................... 31
GK..................................................................... 31
GR .................................................................... 31
get commands ......................................................... 72
GPIO assignments ................................................... 12
GPIO command
S^,..................................................................... 38
S@,................................................................... 37
S*, ..................................................................... 38
S&, .................................................................... 38
S%, ................................................................... 38
GPIO commands ..................................................... 37
GPIO pin power-up values ....................................... 38
GPIO pins ...........................................................11, 47
GPIO10 ...............................................................12, 39
GPIO11 ...............................................................12, 39
GPIO2 .................................................................12, 48
GPIO3 ...................................................................... 12
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K
K,.............................................................................. 35
kill command ............................................................ 35
L
latency, optimizing for .............................................. 49
LED
status ................................................................ 49
local configuration ...................................................... 7
lower transmit power ................................................ 41
lowering transmit power ........................................... 41
low-power mode....................................................... 41
M
managing power....................................................... 41
master mode ............................................................ 10
MDM SPP ................................................................ 46
microprocessor
interfacing with .................................................. 45
mode
7-bit data ........................................................... 50
auto-connect ANY............................................. 10
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RN-BT-DATA-UG
auto-connect DTR............................................. 10
auto-connect master ......................................... 10
command .......................................................6, 60
data ................................................................6, 60
HCI.................................................................... 45
master ............................................................... 10
security ............................................................. 17
slave ................................................................. 10
trigger................................................................ 10
modem control ......................................................... 47
modes ...................................................................... 60
N
null model jumpers ................................................... 53
null modem .............................................................. 53
O
operating modes
mode
operating.................................................... 10
operational modes ................................................... 60
optimizations ............................................................ 49
optimize inquiry and page window ........................... 41
P
pairing ...................................................................... 13
auto ................................................................... 52
hardware ........................................................... 57
HID profile ......................................................... 60
software ............................................................ 57
with computer ................................................... 15
with smartphone ............................................... 15
pairing mode
mode
pairing ........................................................ 10
pin code, default....................................................... 17
power ....................................................................... 48
power consumption, reducing .................................. 41
power management ................................................. 41
power setting............................................................ 43
power settings .......................................................... 27
profile
APL ................................................................... 46
configuration ..................................................... 60
DUN-DCE ......................................................... 46
DUN-DTE.......................................................... 46
MDM SPP ......................................................... 46
override ............................................................. 61
settings ............................................................. 46
SPP................................................................... 46
profile values ............................................................ 29
profiue
HID.................................................................... 46
Q
quick reference ........................................................ 71
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R
Reading, Recommended ......................................... 78
reference designs....................................................... 5
release notes...................................................... 75, 77
replacement, cable................................................... 57
reports ...................................................................... 62
reset circuit............................................................... 47
revision history ......................................................... 75
S
security modes ......................................................... 17
serial adapter configuration...................................... 52
serial cable
configuration ....................................................... 7
set
S-, ..................................................................... 29
S?,..................................................................... 30
S|,...................................................................... 30
S$,..................................................................... 30
S7,..................................................................... 19
SA, .................................................................... 19
SB, .................................................................... 20
SC, .................................................................... 20
SD, .................................................................... 21
SE, .................................................................... 21
SF,1 .................................................................. 22
SH, .................................................................... 22
SI,...................................................................... 23
SJ,..................................................................... 23
SL,..................................................................... 23
SM,.................................................................... 24
SN, .................................................................... 24
SO,.................................................................... 24
SP, .................................................................... 25
SQ,.................................................................... 25
SR, .................................................................... 25
SS, .................................................................... 26
ST, .................................................................... 26
SU, .................................................................... 26
SW, ................................................................... 26
SX, .................................................................... 27
SY, .................................................................... 27
SZ, .................................................................... 28
set commands.................................................... 19, 71
setitngs
dipswitch ........................................................... 54
setting
dipswitches ....................................................... 54
power ................................................................ 43
setting, switches....................................................... 57
slave mode............................................................... 10
smartphone
pairing ............................................................... 15
sniff mode........................................................... 41, 42
software pairing........................................................ 57
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RN-BT-DATA-UG
SPI bus .................................................................... 48
SPP .......................................................................... 46
switch settings.......................................................... 57
switches ..............................................................11, 54
SY, command .......................................................... 43
T
throughput, optimizing for ........................................ 49
timer
configuration settings ........................................ 44
used to lower power.......................................... 41
timing values ............................................................ 69
translate HID to ASCII.............................................. 63
transmit power
deep sleep ........................................................ 42
disabling output drivers ..................................... 43
lowering ............................................................ 43
reducing ............................................................ 41
sniff mode ......................................................... 42
trigger mode ............................................................. 10
U
upgrading
via SPI .............................................................. 48
USB cable
configuration ....................................................... 7
using switches.......................................................... 11
W
Warranty Registration .............................................. 78
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RN-BT-DATA-UG
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Version 0.02 3/26/13
Confidential - Preliminary Release
page 83