Power Consumption Analysis#

This section provides a comprehensive analysis of power consumption for the Amazon Sidewalk protocol, encompassing the three physical layers: BLE, FSK, and CSS. This section details the testing procedures and methodologies applied to each radio layer. Every step of the process is thoroughly explained to ensure the ability to replicate the measurements. Finally, this section culminates in presenting the results for each radio layer, highlighting the average power consumption for fundamental events such as transmission (TX), reception (RX), registration, time synchronization, and idle power, among others.

For more information on Energy modes for Silicon Labs platforms, see the dedicated documentation on Power Manager.

Testing Scenario#

In this section are example use cases for each physical layer: BLE (Bluetooth Low Energy), FSK (Frequency-Shift Keying), and CSS (Chirp Spread Spectrum). In each scenario, for each uplink with payload of 19 bytes sent to the cloud, the cloud answered with an ACK message (0 bytes payload). Default parameters for each radio layer are provided. Tests were run on those default configurations to extract Amazon Sidewalk performance out of the box.

Hardware#

To perform the necessary tests, various platforms were selected for each physical layer (PHY).

Reference platforms include:

Creating a Power Optimized Application#

This study requires a fundamental application that is optimized for power efficiency while still running the Amazon Sidewalk stack. This application was derived from the Hello Neighbor sample application, with only minor modifications implemented. By default, the Hello Neighbor application operates in EM2 energy mode when idle. The initial modification involved switching the log output from RTT to UART.

Create a Hello Neighbor Application#

Follow public documentation to create the Hello Neighbor application here.

Switch Log Output and CLI to UART#

The initial step was to verify that VCOM is active. This was confirmed by ensuring that SL_BOARD_ENABLE_VCOM is set to 1 in the config/sl_board_control_config.h file. If it is not, you should adjust it accordingly.

To configure the log output from RTT to UART, follow these steps:

  1. Navigate to Software Components and search for iostream.

  2. Install the IO Stream: USART component (or IO Stream: EUSART for xG28 and xG24).

  3. Access the configuration settings of the newly created VCOM instance.

  4. Deactivate Enable High frequency mode and Restrict the energy mode to allow the reception options. Then, modify the Baud rate to 9600.

  5. In config/sl_cli_config_inst.h, change the value of SL_CLI_INST_IOSTREAM_HANDLE to sl_iostream_vcom_handle.

  6. Navigate back to Software Components and search for sidewalk.

  7. Uninstall the Sidewalk Log: App RTT component and install Sidewalk Log: App VCOM component in its place.

⚠ WARNING ⚠: Regarding the log output alteration from RTT to UART when using xG24 with the Semtech module, it is necessary to employ a UART bridge. This requires remapping the UART pins to available GPIOs where the UART bridge is connected. Since the Semtech connection occupies the UART pins, the WSTK’s VCOM support cannot be utilized in this setup.

Ⓘ INFO Ⓘ: For the xG24 configuration, it is preset to accommodate the Semtech module. However, if your usage is limited to BLE, you can omit the Semtech-specific parameters, thus leveraging the VCOM capability of the mainboard.

Power Consumption Setup#

For each of the three physical layers, the Simplicity Studio Energy Profiler was used to assess power consumption. The power usage of the Semtech SX1262 was evaluated independently with a DC/DC power Analyzer from Keysight. To conduct the power analysis on the Semtech radio module, a minor hardware alteration was required to facilitate an external power source, as the module derives power from the DC/DC power Analyzer's supply.

Semtech SX1262 Radio Module Modification

A 0 ohm resistor needed to be removed and another shifted to redirect power supply from the mainboard to the DC/DC Power Analyzer, as shown in the following picture.

Semtech Modification Close-upSemtech Modification Close-up

The final setup with the DC/DC Power Analyzer looks like the picture below.

Semtech Power Consumption MeasurementSemtech Power Consumption Measurement

Once all the necessary tools are in place, review each physical layer power consumption.

BLE#

Per Amazon’s guidelines, the process begins with a Fast Advertising phase that lasts for 30 seconds, emitting an advertising beacon every 160 milliseconds. This phase is succeeded by Slow Advertising, during which the beacon is broadcasted every second. Subsequently, the BLE endpoint and the gateway can establish a connection to exchange messages. This connected state is maintained for a minimum of 30 seconds, with a default connection interval of 30 milliseconds.

The following picture shows the endpoint power consumption graph during fast advertising.

BLE Power Consumption Fast AdvertisingBLE Power Consumption Fast Advertising

The following picture shows the endpoint power consumption graph during slow advertising.

BLE Power Consumption Slow AdvertisingBLE Power Consumption Slow Advertising

The following picture shows the endpoint power consumption graph while connected to the GW.

BLE Power Consumption Connected StateBLE Power Consumption Connected State

FSK#

As per Amazon’s standards for FSK, the connection with the gateway is sustained by sending beacons at 10-second intervals. The default configuration permits three opportunities for listening in the time between each beacon. Transmissions may occur at any point between beacons when the device is not in a listening window.

The following picture shows the endpoint power consumption graph between 2 beacons.

FSK Power Consumption BeaconingFSK Power Consumption Beaconing

The following picture shows the endpoint power consumption graph between 2 beacons with a transmission and a reception.

FSK Power Consumption RX and TXFSK Power Consumption RX and TX

CSS#

CSS operates on an asynchronous protocol, aligning its timing with the gateway as needed and executing transmissions when necessary. Listening windows are set to activate every 5 seconds consistently, or they can be triggered after a transmission, depending on the selected power profile. The default power profile utilized in the subsequent graphs is profile B.

The following picture shows the endpoint power consumption of the EFR32xG24 radio board during a transmission and a reception.

CSS Power Consumption EFRxG24CSS Power Consumption EFRxG24

The following picture shows the endpoint power consumption of the SX1262 radio module during a transmission and a reception.

CSS Power Consumption SX1262CSS Power Consumption SX1262

Power Consumption Results#

The results of the average power consumption study on fundamental events are provided in the following tables. These include:

  • Registration

  • Time Synchronization

  • BLE Advertising

  • BLE Connected State

  • TX

  • RX

  • Idle State

BLE#

BLE Physical Layer

Details

Radio Board

xG24

Physical Layer

BLE

Output Power

20 dBm

TX Payload Size

19 bytes

RX Payload Size

0 byte

Fast Advertising Interval

160 ms

Slow Advertising Interval

1000 ms

Connected State Minimal Duration

30 s

Fundamental Events Average Power Consumption

Results

Registration

2.75 mA

Time Synchronization

1.9 mA

Fast Advertisement

464.67 µA

Slow Advertisement

98.31 µA

Connected State with 1 TX Event

743.11 µA

TX 19 bytes

3.51 mA

RX 0 byte

3.39 mA

30 seconds Connected State without TX

713.79 µA

Idle State

4.82 µA

FSK#

FSK Physical Layer

Details

Radio Board

xG28

Radio Layer

FSK

Output Power

20 dBm

TX Payload Size

19 bytes

RX Payload Size

0 byte

Number of RX Window in-between Beacons

3

Fundamental Events Average Power Consumption

Results

Registration

2.66 mA

Time Synchronization

1.03 mA

Beacon Reception

2.44 mA

Idle State

6.12 µA

TX 19 bytes including CCA and ACK

14.21 mA

RX Window

534.11 µA

RX 0 byte

3.84 mA

10 Seconds Loop Average

43.23 µA

CSS#

CSS Physical Layer

Details

Radio Board

xG24 + SX1262

Radio Layer

CSS

Output Power

20 dBm

TX Payload Size

19 bytes

RX Payload Size

0 byte

Fundamental Events Average Power Consumption

EFR32

SX1262

Global Power Consumption

Time Synchronization

400.88 µA

10.11 mA

10.51 mA

Idle State

13.7 µA

547 nA

14.25 µA

TX 19 bytes

1.67 mA

107.94 mA

109.61 mA

RX Window

55.07 µA

1.94 mA

1.99 mA

RX 0 bytes

733.47 µA

3.9 mA

4.63 mA

20 RX windows after TX

15.52 µA

35.686 µA

51.2 µA

Going Further#

For each physical layer, several parameters can be tweaked to influence the protocol behavior, thus impacting average power consumption. Below are the most commonly thought after parameters and where to change them.

BLE#

The BLE configuration can be seen in the file sidewalk_<version>/component/ble_subghz/radio/ble/app_ble_config.c of your sample application. Most enumeration related to Sidewalk BLE are defined in sidewalk_<version>\component\includes\projects\sid\sal\common\public\sid_ifc\sid_ble_cfg\sid_ble_config_ifc.h. The default device BLE name is "SL_SIDEWALK", MTU size is 247 bytes, and MAC address type is random private resolvable. BLE connection parameters are chosen by the gateway and the connection timeout is 30 seconds.

Advertising is divided into two behaviors:

  • Fast advertising: transmit beacons every 160 ms for 30 seconds after boot

  • Slow advertising: transmit beacons every 1 s after fast advertising

You can check the following structures in the API Reference:

  • sid_ble_cfg_adv_param_t: for advertising parameters

  • sid_ble_cfg_conn_param_t: for the connection parameters

  • sid_ble_cfg_gatt_profile_t: for the GATT profile parameters

  • sid_ble_config_t: for more generic configuration parameters

For more information on Silicon Labs BLE stack and power consumption, see the following pages:

FSK#

The FSK radio configuration can be seen in the file sidewalk_<version>/component/ble_subghz/radio/subghz/rail/app_subghz_config.c of your sample application for Silicon Labs hardware and sidewalk_<version>/component/ble_subghz/radio/subghz/semtech/app_subghz_config.c for Semtech hardware. Most Sidewalk FSK enumeration are defined in sidewalk_<version>\component\includes\projects\sid\sal\common\public\sid_ifc\sid_900_cfg\sid_900_cfg.h. While running with FSK, your EFR32 will be either in EM2 or EM0 energy modes depending on radio events. During radio events like beacons, RX, or TX, your EFR32 will run in EM0 energy mode and in EM2 outside of those events.

For more power optimization, check Amazon Sidewalk power profiles for FSK.

CSS#

The CSS radio configuration can be seen in the file sidewalk_<version>/component/ble_subghz/radio/subghz/rail/app_subghz_config.c of your sample application for Silicon Labs hardware and sidewalk_<version>/component/ble_subghz/radio/subghz/semtech/app_subghz_config.c for Semtech hardware. While running with CSS, your EFR32 will be either in EM2 or EM0 energy modes depending on radio events. During radio events like RX or TX your EFR32 will run in EM0 energy mode and in EM2 outside of those events.

For more power optimization, check Amazon Sidewalk power profiles for CSS.