Bluetooth: Direction finding connectionless beacon
The direction finding connectionless beacon sample demonstrates Bluetooth® LE direction finding transmission.
Requirements
The sample supports the following development kits:
Hardware platforms |
PCA |
Board name |
Board target |
---|---|---|---|
PCA10095 |
|
||
PCA10100 |
|
||
PCA10100 |
|
The sample also requires an antenna matrix when operating in angle of departure mode. It can be a Nordic Semiconductor design 12 patch antenna matrix, or any other antenna matrix.
Overview
The direction finding connectionless beacon sample application uses Constant Tone Extension (CTE) that is transmitted with periodic advertising PDUs.
The sample supports two direction finding modes:
Angle of Arrival (AoA)
Angle of Departure (AoD)
By default, both modes are available in the sample.
Configuration
See Configuring and building an application for information about how to permanently or temporarily change the configuration.
This sample configuration is split into the following two files:
Generic configuration available in the
prj.conf
fileBoard-specific configuration available in the
boards/<BOARD>.conf
file
nRF5340 configuration files
The following additional configuration files are available for the nRF5340 DK:
The Bluetooth LE controller is part of a child image meant to run on the network core. The configuration for the child image is stored in the
child_image/
subdirectory.The DTS overlay file
boards/nrf5340dk_nrf5340_cpuapp.overlay
is available for the application core. This file forwards the control over GPIOs to network core, which provides control over GPIOs to the radio peripheral in order to execute antenna switching.
Angle of arrival mode
To build this sample with AoA mode only, set EXTRA_CONF_FILE
to the overlay-aoa.conf
file.
See Providing CMake options for instructions on how to add this option. For more information about using configuration overlay files, see Important Build System Variables in the Zephyr documentation.
To build this sample for nRF5340 DK, with AoA mode only, add content of overlay-aoa.conf
file to child_image/hci_ipc.conf
file.
Antenna matrix configuration for angle of departure mode
To use this sample when AoD mode is enabled, additional configuration of GPIOs is required to control the antenna array.
An example of such configuration is provided in a devicetree overlay file nrf52833dk_nrf52833.overlay
.
The overlay file provides the information of which GPIOs should be used by the Radio peripheral to switch between antenna patches during the CTE transmission in the AoD mode. At least two GPIOs must be provided to enable antenna switching.
The GPIOs are used by the Radio peripheral in the order provided by the dfegpio#-gpios
properties.
The order is important because it has an impact on the mapping of the antenna switching patterns to GPIOs (see Antenna patterns).
To successfully use the direction finding beacon when the AoD mode is enabled, provide the following data related to antenna matrix design:
The GPIO pins to
dfegpio#-gpios
properties in thenrf52833dk_nrf52833.overlay
file.The default antenna that will be used to receive a PDU
dfe-pdu-antenna
property in thenrf52833dk_nrf52833.overlay
file.Update the antenna switching patterns of the
ant_patterns
array in themain.c
file.
Antenna patterns
The antenna switching pattern is a binary number where each bit is applied to a particular antenna GPIO pin.
For example, the pattern 0x3
means that antenna GPIOs at index 0,1
will be set, while the following are left unset.
This also means that, for example, when using four GPIOs, the pattern count cannot be greater than 16 and the maximum allowed value is 15.
If the number of switch-sample periods is greater than the number of stored switching patterns, the radio loops back to the first pattern.
The length of the antenna switching pattern is limited by the CONFIG_BT_CTLR_DF_MAX_ANT_SW_PATTERN_LEN
Kconfig option.
If the required length of the antenna switching pattern is greater than the default value of that option, set it to the required value in the board configuration file.
For example, for the nRF52833 DK, set the option value to the required antenna switching pattern length in the nrf52833dk_nrf52833.conf
file.
The following table presents the patterns that you can use to switch antennas on the Nordic-designed antenna matrix:
Antenna |
PATTERN[3:0] |
---|---|
ANT_12 |
0 (0b0000) |
ANT_10 |
1 (0b0001) |
ANT_11 |
2 (0b0010) |
RFU |
3 (0b0011) |
ANT_3 |
4 (0b0100) |
ANT_1 |
5 (0b0101) |
ANT_2 |
6 (0b0110) |
RFU |
7 (0b0111) |
ANT_6 |
8 (0b1000) |
ANT_4 |
9 (0b1001) |
ANT_5 |
10 (0b1010) |
RFU |
11 (0b1011) |
ANT_9 |
12 (0b1100) |
ANT_7 |
13 (0b1101) |
ANT_8 |
14 (0b1110) |
RFU |
15 (0b1111) |
Building and Running
This sample can be found under samples/bluetooth/direction_finding_connectionless_tx
in the nRF Connect SDK folder structure.
To build the sample, follow the instructions in Configuring and building an application for your preferred building environment. See also Programming an application for programming steps and Testing and optimization for general information about testing and debugging in the nRF Connect SDK.
Note
When building repository applications in the SDK repositories, building with sysbuild is enabled by default.
If you work with out-of-tree freestanding applications, you need to manually pass the --sysbuild
parameter to every build command or configure west to always use it.
Testing
After programming the sample to your development kit, complete the following steps to test it:
Connect to the kit that runs this sample with a terminal emulator (for example, nRF Connect Serial Terminal). See Testing and optimization for the required settings and steps.
In the terminal window, check for information similar to the following:
Starting Connectionless Beacon Demo Bluetooth initialization...success Advertising set create...success Update CTE params...success Periodic advertising params set...success Enable CTE...success Periodic advertising enable...success Extended advertising enable...success Started extended advertising as XX:XX:XX:XX:XX:XX (random)
Dependencies
This sample uses the following Zephyr libraries:
include/zephyr/types.h
lib/libc/minimal/include/errno.h
include/sys/printk.h
include/sys/byteorder.h
include/sys/util.h
API:
include/bluetooth/bluetooth.h
include/bluetooth/hci.h
include/bluetooth/direction.h
include/bluetooth/gatt.h