Difference between revisions of "AudioMoth"

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(Suggested trigger extension)
(Hardware)
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The processor is EFM32WG380F256, [https://www.silabs.com/mcu/32-bit/efm32-wonder-gecko/device.efm32wg380f256-qfp100 link]
 
The processor is EFM32WG380F256, [https://www.silabs.com/mcu/32-bit/efm32-wonder-gecko/device.efm32wg380f256-qfp100 link]
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Where is the schematic?
  
 
== Software ==
 
== Software ==

Revision as of 11:26, 7 April 2021

Project AudioMoth
Audiomoth.png
Status In progress
Contact bertrik
Last Update 2021-04-07

What

I have an AudioMoth board, and plan to improve its software:

Ideas:

Hardware

Frequency response

See https://circuithub.com/projects/OpenAcoustics/AudioMoth

The microphone is a SPM0408LE5H. Can't find much about its ultrasonic performance. The official graph shows a hint of resonance above 10k so it does have ultrasonic sensitivity. For frequencies higher than the resonance peak the response of a typical microphone drops off steeply with 6 dB/octave. I have been able to record some pipistrelle bats with it (40 - 50 kHz).

The processor is EFM32WG380F256, link

Where is the schematic?

Software

My fork on github: https://github.com/bertrik/AudioMoth-Project

Suggested trigger extension

A bat specific trigger is desireable because this way we only get "interesting" files.

The idea is that bat signals are, in general:

  • ultrasonic, frequency above 10 kHz
  • organised in short pulses, e.g. 8 pulses per second of 5 ms each for a pipistrelle

Challenges:

  • crickets, sound is also at least partly ultrasonic, overlapping with the calls of some of the larger bats and with social bat calls in general

Proposed algorithm: 1) Apply a high-pass filter at about 10 kHz, this needs not be super-sharp filter. Perhaps just a simple 1-pole IIR (easy to calculate). 2) Calculate the energy in each millisecond by adding the squared amplitude of the high-pass filtered signal over this millisecond. Perhaps we can also just calculate variance here and forget about step 1). 3) Calculate a running average energy over several (say 500) of these milliseconds values. 4) If the millisecond energy exceeds the average energy by a factor X (the sensitivity of the trigger), consider the trigger to be active.

Running the tools

Running the AudioMoth tools (configuration tool, flash tool, etc) requires the --no-sandbox option (at least on my system), for example

 ./AudioMothConfigurationAppSetup1.2.5.AppImage --no-sandbox

IDE for development

A description of all steps to get the firmware compiled is written here: https://github.com/OpenAcousticDevices/AudioMoth-Project/wiki/AudioMoth

Compiling

platformio

It compiles and produces a firmware.bin file, but it's not recognized by the flashing tool as a valid file.

Use this platformio.ini file:

 [platformio]
 src_dir = src,fatfs_src
 include_dir = inc,fatfs_inc
 [env:default]
 framework = zephyr
 platform = siliconlabsefm32
 board = efm32wg_stk3800

Install platformio:

 sudo apt install python3-pip
 sudo pip3 install platformio
 sudo pip3 install -U PyYAML

Compile it:

 pio run