#include #include #include #include #include #include #include #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; 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 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