ardupilot/libraries/AP_HAL/examples/DSP_test/DSP_test.cpp

#include <AP_BoardConfig/AP_BoardConfig.h>
#include <AP_HAL/AP_HAL.h>
#include <AP_HAL_Empty/AP_HAL_Empty.h>
#include <GCS_MAVLink/GCS_Dummy.h>
#include <AP_SerialManager/AP_SerialManager.h>
#include <AP_Logger/AP_Logger.h>
#include "GyroFrame.h"

#if HAL_WITH_DSP
const AP_HAL::HAL &hal = AP_HAL::get_HAL();

static const uint16_t WINDOW_SIZE = 128;
static const uint16_t FRAME_SIZE = 1024;
static const float max_hz = 350;
static const float attenuation_power_db = 15;
static const float frequency1 = 120;
static const float frequency2 = 50;
static const float frequency3 = 350;
static float attenuation_cutoff;
static FloatBuffer fft_window {WINDOW_SIZE};

static const uint16_t last_bin = MIN(ceilf(max_hz / ((float)SAMPLE_RATE/ WINDOW_SIZE)), WINDOW_SIZE/2);

static AP_HAL::DSP::FFTWindowState* fft;

void setup();
void loop();
void update();
void do_fft(const float* data);

static AP_SerialManager serial_manager;
static AP_BoardConfig board_config;
static AP_InertialSensor ins;
AP_Int32 logger_bitmask;
static AP_Logger logger{logger_bitmask};

class DummyVehicle {
public:
};

class DSPTest : public AP_HAL::DSP {
public:
    virtual FFTWindowState* fft_init(uint16_t w, uint16_t sample_rate, uint8_t sliding_window_size) override { return nullptr; }
    virtual void fft_start(FFTWindowState* state, FloatBuffer& samples, uint16_t advance) override {}
    virtual uint16_t fft_analyse(FFTWindowState* state, uint16_t start_bin, uint16_t end_bin, float noise_att_cutoff) override { return 0; }
protected:
    virtual void vector_max_float(const float* vin, uint16_t len, float* maxValue, uint16_t* maxIndex) const override {}
    virtual void vector_scale_float(const float* vin, float scale, float* vout, uint16_t len) const override {}
    virtual float vector_mean_float(const float* vin, uint16_t len) const override { return 0.0f; };
    virtual void vector_add_float(const float* vin1, const float* vin2, float* vout, uint16_t len) const override {}
public:
    void run_tests();
} dsptest;

//static DummyVehicle vehicle;
// create fake gcs object
GCS_Dummy _gcs;

const AP_Param::GroupInfo GCS_MAVLINK_Parameters::var_info[] = {
        AP_GROUPEND
};

uint32_t frame_num = 0;

void setup()
{
    hal.console->printf("DSP test\n");
    board_config.init();   
    serial_manager.init();
    fft = hal.dsp->fft_init(WINDOW_SIZE, SAMPLE_RATE);
    attenuation_cutoff = powf(10.0f, -attenuation_power_db / 10.0f);

    for(uint16_t i = 0; i < WINDOW_SIZE; i++) {
        float sample = sinf(2.0f * M_PI * frequency1 * i / SAMPLE_RATE) * ToRad(20) * 2000;
        sample += sinf(2.0f * M_PI * frequency2 * i / SAMPLE_RATE) * ToRad(10) * 2000;
        sample += sinf(2.0f * M_PI * frequency3 * i / SAMPLE_RATE) * ToRad(10) * 2000;
        fft_window.push(sample);
    }

    dsptest.run_tests();

}

void DSPTest::run_tests() {
    float vals[] = {1, 1, 1, 10, 10, 10, 1, 1, 1, 1};
    fastsmooth(vals, 10, 3); 
    for (int i=0; i < 10; i++) {
        hal.console->printf("%.f ", vals[i]);
    }
    hal.console->printf("\n");
    // fastsmooth([1 1 1 10 10 10 1 1 1 1],3) => [0 1 4 7 10 7 4 1 1 0]
}


void do_fft(const float* data)
{
    fft_window.push(data, WINDOW_SIZE);
    hal.dsp->fft_start(fft, fft_window, WINDOW_SIZE);
    uint16_t max_bin = hal.dsp->fft_analyse(fft, 1, last_bin, attenuation_cutoff);

    if (max_bin <= 0) {
        hal.console->printf("FFT: could not detect frequency %.1f\n", frequency1);
    }

    const float max_energy = fft->_freq_bins[fft->_peak_data[AP_HAL::DSP::CENTER]._bin];

    for (uint16_t i = 0; i < 32; i++) {
        const uint16_t height = uint16_t(roundf(80.0f * fft->_freq_bins[i] / max_energy));
        hal.console->printf("[%3.f]", i * fft->_bin_resolution);
        for (uint16_t j = 0; j < height; j++) {
            hal.console->printf("\u2588");
        }
        hal.console->printf("\n");
    }

    hal.console->printf("FFT: detected frequencies %.1f/%d/[%.1f-%.1f] %.1f/%d/[%.1f-%.1f] %.1f/%d/[%.1f-%.1f]\n",
        fft->_peak_data[AP_HAL::DSP::CENTER]._freq_hz,
        fft->_peak_data[AP_HAL::DSP::CENTER]._bin,
        (fft->_peak_data[AP_HAL::DSP::CENTER]._bin - 0.5) * fft->_bin_resolution,
        (fft->_peak_data[AP_HAL::DSP::CENTER]._bin + 0.5) * fft->_bin_resolution,
        fft->_peak_data[AP_HAL::DSP::LOWER_SHOULDER]._freq_hz,
        fft->_peak_data[AP_HAL::DSP::LOWER_SHOULDER]._bin,
        (fft->_peak_data[AP_HAL::DSP::LOWER_SHOULDER]._bin - 0.5) * fft->_bin_resolution,
        (fft->_peak_data[AP_HAL::DSP::LOWER_SHOULDER]._bin + 0.5) * fft->_bin_resolution,
        fft->_peak_data[AP_HAL::DSP::UPPER_SHOULDER]._freq_hz,
        fft->_peak_data[AP_HAL::DSP::UPPER_SHOULDER]._bin,
        (fft->_peak_data[AP_HAL::DSP::UPPER_SHOULDER]._bin - 0.5) * fft->_bin_resolution,
        (fft->_peak_data[AP_HAL::DSP::UPPER_SHOULDER]._bin + 0.5) * fft->_bin_resolution);
}

void update()
{
    for (uint16_t i = 0; i < FRAME_SIZE / WINDOW_SIZE; i++) {
        do_fft(&gyro_frames[frame_num].x[i * WINDOW_SIZE]);
    }
    if (++frame_num > NUM_FRAMES) {
        exit(0);
    };
}

void loop()
{
    if (!hal.console->is_initialized()) {
        return;
    }
    uint32_t reference_time, run_time;

    hal.console->printf("--------------------\n");

    reference_time = AP_HAL::micros();
    update();
    run_time = AP_HAL::micros() - reference_time;
    if (run_time > 1000) {
        hal.console->printf("ran for %d\n", unsigned(run_time));
    }

    // delay before next display
    hal.scheduler->delay(1e3); // 1 second
}

AP_HAL_MAIN();

#else

#include <stdio.h>

const AP_HAL::HAL& hal = AP_HAL::get_HAL();

static void loop() { }
static void setup()
{
    printf("Board not currently supported\n");
}

AP_HAL_MAIN();

#endif
AP_HAL: change namespace of MultiCopter and FixedWing params this stops the libraries knowing anything about AP_Vehicle 2022-09-29 20:10:40 -03:00			`#include <AP_BoardConfig/AP_BoardConfig.h>`
AP_HAL: collect data for three largest peaks new dsp peak detection algorithm add DSP sketch with frequency ascii art tool to generate gyro data frames from batch sampled DF logs add generated data from real Y6B flight allow fft_start() to use ObjectBuffer<float> for lock-free access allow ObjectBuffer to be resized 2020-03-05 10:59:25 -04:00			`#include <AP_HAL/AP_HAL.h>`
			`#include <AP_HAL_Empty/AP_HAL_Empty.h>`
			`#include <GCS_MAVLink/GCS_Dummy.h>`
			`#include <AP_SerialManager/AP_SerialManager.h>`
AP_HAL: stop libraries including AP_Logger.h in .h files AP_Logger.h is a nexus of includes; while this is being improved over time, there's no reason for the library headers to include AP_Logger.h as the logger itself is access by singleton and the structures are in LogStructure.h This necessitated moving The PID_Info structure out of AP_Logger's namespace. This cleans up a pretty nasty bit - that structure is definitely not simply used for logging, but also used to pass pid information around to controllers! There are a lot of patches in here because AP_Logger.h, acting as a nexus, was providing transitive header file inclusion in many (some unlikely!) places. 2022-03-04 02:14:40 -04:00			`#include <AP_Logger/AP_Logger.h>`
AP_HAL: collect data for three largest peaks new dsp peak detection algorithm add DSP sketch with frequency ascii art tool to generate gyro data frames from batch sampled DF logs add generated data from real Y6B flight allow fft_start() to use ObjectBuffer<float> for lock-free access allow ObjectBuffer to be resized 2020-03-05 10:59:25 -04:00			`#include "GyroFrame.h"`

			`#if HAL_WITH_DSP`
			`const AP_HAL::HAL &hal = AP_HAL::get_HAL();`

			`static const uint16_t WINDOW_SIZE = 128;`
			`static const uint16_t FRAME_SIZE = 1024;`
			`static const float max_hz = 350;`
			`static const float attenuation_power_db = 15;`
			`static const float frequency1 = 120;`
			`static const float frequency2 = 50;`
			`static const float frequency3 = 350;`
			`static float attenuation_cutoff;`
			`static FloatBuffer fft_window {WINDOW_SIZE};`

			`static const uint16_t last_bin = MIN(ceilf(max_hz / ((float)SAMPLE_RATE/ WINDOW_SIZE)), WINDOW_SIZE/2);`

			`static AP_HAL::DSP::FFTWindowState* fft;`

			`void setup();`
			`void loop();`
			`void update();`
			`void do_fft(const float* data);`

			`static AP_SerialManager serial_manager;`
			`static AP_BoardConfig board_config;`
			`static AP_InertialSensor ins;`
			`AP_Int32 logger_bitmask;`
			`static AP_Logger logger{logger_bitmask};`

			`class DummyVehicle {`
			`public:`
			`};`

			`class DSPTest : public AP_HAL::DSP {`
			`public:`
AP_HAL: save a sliding window array of frequency bins calculate frequency average from sliding window 2022-03-12 10:45:41 -04:00			`virtual FFTWindowState* fft_init(uint16_t w, uint16_t sample_rate, uint8_t sliding_window_size) override { return nullptr; }`
AP_HAL: collect data for three largest peaks new dsp peak detection algorithm add DSP sketch with frequency ascii art tool to generate gyro data frames from batch sampled DF logs add generated data from real Y6B flight allow fft_start() to use ObjectBuffer<float> for lock-free access allow ObjectBuffer to be resized 2020-03-05 10:59:25 -04:00			`virtual void fft_start(FFTWindowState* state, FloatBuffer& samples, uint16_t advance) override {}`
			`virtual uint16_t fft_analyse(FFTWindowState* state, uint16_t start_bin, uint16_t end_bin, float noise_att_cutoff) override { return 0; }`
			`protected:`
			`virtual void vector_max_float(const float* vin, uint16_t len, float* maxValue, uint16_t* maxIndex) const override {}`
			`virtual void vector_scale_float(const float* vin, float scale, float* vout, uint16_t len) const override {}`
			`virtual float vector_mean_float(const float* vin, uint16_t len) const override { return 0.0f; };`
AP_HAL: add Jain's estimator notch tuning using FFT averaging allocate scratch space for peak finding return all detected peaks to caller 2022-03-05 16:00:11 -04:00			`virtual void vector_add_float(const float* vin1, const float* vin2, float* vout, uint16_t len) const override {}`
AP_HAL: collect data for three largest peaks new dsp peak detection algorithm add DSP sketch with frequency ascii art tool to generate gyro data frames from batch sampled DF logs add generated data from real Y6B flight allow fft_start() to use ObjectBuffer<float> for lock-free access allow ObjectBuffer to be resized 2020-03-05 10:59:25 -04:00			`public:`
			`void run_tests();`
			`} dsptest;`

			`//static DummyVehicle vehicle;`
			`// create fake gcs object`
			`GCS_Dummy _gcs;`

			`const AP_Param::GroupInfo GCS_MAVLINK_Parameters::var_info[] = {`
			`AP_GROUPEND`
			`};`

			`uint32_t frame_num = 0;`

			`void setup()`
			`{`
			`hal.console->printf("DSP test\n");`
			`board_config.init();`
			`serial_manager.init();`
AP_HAL: allow configuration of maximum number of notches based on MCU type increase notch filters in SITL remove redundant harmonics from DSP 2021-11-13 18:40:24 -04:00			`fft = hal.dsp->fft_init(WINDOW_SIZE, SAMPLE_RATE);`
AP_HAL: collect data for three largest peaks new dsp peak detection algorithm add DSP sketch with frequency ascii art tool to generate gyro data frames from batch sampled DF logs add generated data from real Y6B flight allow fft_start() to use ObjectBuffer<float> for lock-free access allow ObjectBuffer to be resized 2020-03-05 10:59:25 -04:00			`attenuation_cutoff = powf(10.0f, -attenuation_power_db / 10.0f);`

			`for(uint16_t i = 0; i < WINDOW_SIZE; i++) {`
			`float sample = sinf(2.0f * M_PI * frequency1 * i / SAMPLE_RATE) * ToRad(20) * 2000;`
			`sample += sinf(2.0f * M_PI * frequency2 * i / SAMPLE_RATE) * ToRad(10) * 2000;`
			`sample += sinf(2.0f * M_PI * frequency3 * i / SAMPLE_RATE) * ToRad(10) * 2000;`
			`fft_window.push(sample);`
			`}`

			`dsptest.run_tests();`

			`}`

			`void DSPTest::run_tests() {`
			`float vals[] = {1, 1, 1, 10, 10, 10, 1, 1, 1, 1};`
			`fastsmooth(vals, 10, 3);`
			`for (int i=0; i < 10; i++) {`
			`hal.console->printf("%.f ", vals[i]);`
			`}`
			`hal.console->printf("\n");`
			`// fastsmooth([1 1 1 10 10 10 1 1 1 1],3) => [0 1 4 7 10 7 4 1 1 0]`
			`}`


			`void do_fft(const float* data)`
			`{`
			`fft_window.push(data, WINDOW_SIZE);`
			`hal.dsp->fft_start(fft, fft_window, WINDOW_SIZE);`
			`uint16_t max_bin = hal.dsp->fft_analyse(fft, 1, last_bin, attenuation_cutoff);`

			`if (max_bin <= 0) {`
			`hal.console->printf("FFT: could not detect frequency %.1f\n", frequency1);`
			`}`

			`const float max_energy = fft->_freq_bins[fft->_peak_data[AP_HAL::DSP::CENTER]._bin];`

			`for (uint16_t i = 0; i < 32; i++) {`
			`const uint16_t height = uint16_t(roundf(80.0f * fft->_freq_bins[i] / max_energy));`
			`hal.console->printf("[%3.f]", i * fft->_bin_resolution);`
			`for (uint16_t j = 0; j < height; j++) {`
			`hal.console->printf("\u2588");`
			`}`
			`hal.console->printf("\n");`
			`}`

			`hal.console->printf("FFT: detected frequencies %.1f/%d/[%.1f-%.1f] %.1f/%d/[%.1f-%.1f] %.1f/%d/[%.1f-%.1f]\n",`
			`fft->_peak_data[AP_HAL::DSP::CENTER]._freq_hz,`
			`fft->_peak_data[AP_HAL::DSP::CENTER]._bin,`
			`(fft->_peak_data[AP_HAL::DSP::CENTER]._bin - 0.5) * fft->_bin_resolution,`
			`(fft->_peak_data[AP_HAL::DSP::CENTER]._bin + 0.5) * fft->_bin_resolution,`
			`fft->_peak_data[AP_HAL::DSP::LOWER_SHOULDER]._freq_hz,`
			`fft->_peak_data[AP_HAL::DSP::LOWER_SHOULDER]._bin,`
			`(fft->_peak_data[AP_HAL::DSP::LOWER_SHOULDER]._bin - 0.5) * fft->_bin_resolution,`
			`(fft->_peak_data[AP_HAL::DSP::LOWER_SHOULDER]._bin + 0.5) * fft->_bin_resolution,`
			`fft->_peak_data[AP_HAL::DSP::UPPER_SHOULDER]._freq_hz,`
			`fft->_peak_data[AP_HAL::DSP::UPPER_SHOULDER]._bin,`
			`(fft->_peak_data[AP_HAL::DSP::UPPER_SHOULDER]._bin - 0.5) * fft->_bin_resolution,`
			`(fft->_peak_data[AP_HAL::DSP::UPPER_SHOULDER]._bin + 0.5) * fft->_bin_resolution);`
			`}`

			`void update()`
			`{`
			`for (uint16_t i = 0; i < FRAME_SIZE / WINDOW_SIZE; i++) {`
			`do_fft(&gyro_frames[frame_num].x[i * WINDOW_SIZE]);`
			`}`
			`if (++frame_num > NUM_FRAMES) {`
			`exit(0);`
			`};`
			`}`

			`void loop()`
			`{`
			`if (!hal.console->is_initialized()) {`
			`return;`
			`}`
			`uint32_t reference_time, run_time;`

			`hal.console->printf("--------------------\n");`

			`reference_time = AP_HAL::micros();`
			`update();`
			`run_time = AP_HAL::micros() - reference_time;`
			`if (run_time > 1000) {`
			`hal.console->printf("ran for %d\n", unsigned(run_time));`
			`}`

			`// delay before next display`
			`hal.scheduler->delay(1e3); // 1 second`
			`}`

			`AP_HAL_MAIN();`

			`#else`

			`#include <stdio.h>`

			`const AP_HAL::HAL& hal = AP_HAL::get_HAL();`

			`static void loop() { }`
			`static void setup()`
			`{`
			`printf("Board not currently supported\n");`
			`}`

			`AP_HAL_MAIN();`

			`#endif`