When I was setting up a Machine Learning sketch for sound processing, I ran across a pretty steep learning curve to get reliable sampling, decibel measurement, signal analysis such as FFT, MFCC and Shazam-style fingerprint creation. So I decided: that can be made much more simple. I found after lots of trial and error some usable software, mostly in C, but no always very suitable for straightforward use in Arduino / Esp32 sketches. For example, many of these librariesextensively use dynamic memory- something that you want to avoid if possible in embedded environments.
In addition, setting up fast sound / signal sampling is, despite audiotools, still quite a bit of work. Because of the I2S, ADC and other parametrs and driver details. How to properly init de ESP32 ADC, which ADC to use, how to use ESP32 calibration, how to find and set the right parameters.
ESP32 Sampler is a wrapper around Phil Schatzman's awsome audiostream. I adapted that for pure mono-signal input,
and added esp32 ADC calibration to get accurate millivolts, which is needed for Decibel measurements.
I turned that into a class which properly inits the ADC, sets up the audiotools and collects buffers
Besides the simnple class-style interface that you find a lot in Arduinoe evnironments has a a lot of benefit and hides complexities.
The whole idea of sampling is to get a bunch of 16-bits ADC values in pretty accurate millivolts, with as little CPU overhead as possible. The beauty of the ADC-I2S approach is, besides cheap and easy hardware, that the ADC and I2S subsystems are ESP32 hardware-native and use no CPU. The only CPU cycles ar for copying the data.
ESP32Sampler is a singleton class, alread instantiated, ready to use. It works for high frequencies, 44100 is easy, but doc says it could work up to hundreds of Kb/sec
Extra note: With sampling, an important thing is to use RTOS, so that you can put a sampler task on a separate core. Believe me: RTOS is awesome, and very much needed in systems that process lots of data.
#include <Arduino.h>
#include "ESP32Sampler.h"
// Default values :
#define SMP_DEFAULT_VMAX 3.3
#define SMP_DEFAULT_FREQUENCY 44100
#define SMP_DEFAULT_SAMPLES 1024
#define SMP_DEFAULTPIN GPIO_NUM_34 // ADC1 channel 6
#define SMP_DEFAULT_MULTISAMPLE 2
#define SMP_DEFAULT_EXTRABUFFERS 0
#define SMP_DEFAULT_MODE SMODE_DC Config.vmax 1.1 - 3.3
Config.samplefrequency up to 500000 / multisample
Config.numsamples 16 -= 8192
Config.pin GPIO32 - 39
Config.mode AC or DC
Config.multisample 0-4 depending on buffers
Config.extrabuffers 0+, depending on needs- VMAX needs to be set for the max input voltage of the microphone, which is determined by the hardware setup.
- The Sample frequency. Speaks for itself
- Num of samples to collect in each run. best is a ^2 number, 64, 128, .. 1024, 2048, all fine. max is 8192 in one run.
- the Input pin, Supported are GPIO32 - 39
- Multisample: in noisy environments (e.g. Wifi introduces spikes) multi-sampling takes the average of multiple readings. Remember though, that 8192 samples is the max. So if you want the average of 4x samples for 1024 samples, the sampler creates 4 buffers that are always 1024, and sets the frequency to 4x your sample frequency.
- Extra buffers: when your processing task needs more time than the hardware need to collect data. If you don't have extra buffers there may be overrun. Example: at 8192 Hz sample frequency, a run of 1024 samples takes 125 msec. If your task needs less than that there is no problem becuase the collection takes no time (hardware, remember). But if once in a while you need 200 msec to process, an extra buffer is needed. Times multisample. Plus, extra buffers take up memory, so only do that when needed.
- Mode can be SMODE_AC, or SMODE_DC . Because when you analyze sound, it is easier to rule out DC and have signals centered around 0.
Samples are always 16 bits . Although it is possible to have less bits my sampler does not support that out of the box Sample data is signed with AC mode, true AC +- millivolts are returned. hence the in16_t.
typedef sample_t int16_t;
sample_t Samples[1024]; // the collect buffer
// connect analogue breakout e.g MAX 4466 to pin 34
const gpio_num_t micPin = GPIO_NUM_34;
// Optional, and for fun: connect pin 39 to 25
const gpio_num_t calibratePin = GPIO_NUM_39;
const gpio_num_t vrefPin = GPIO_NUM_25; // anaLog out for VREF routing
// Get the default config and set parameters
SamplerConfig Config = Sampler.defaultConfig();
// 8192 Hz at GPIO34, 1024 samples, AC mode, reduce noise
Config.pin = micPin;
Config.vmax = VCC;
Config.samplefrequency = 8192;
Config.numsamples = 1024;
Config.mode = SMODE_AC;
Config.multisample = 4;
// store the config in the sampler
Sampler.setConfig(Config);
Sampler.Begin();
Sampler.End();The collect call is blocking, it waits for the hardware to provide the number of samples requested
Sampler.Collect(Samples, 1024);A cute little feature is Sampler.Measure(pin,msecs) . Can be used for setup tasks. It measures during a number of msecs and returns the average in accurate mvolts. An better alternative for AnalogueRead It can not be used when the sampler is running, The example sketch outlines a use case
It is strongly recommended to use a dedicated RTOS task for sampling and signal analysis. Other task can then do Wifi and web things the Example sketch has that setup.
Have fun!