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imu/invensense/icm20608g: minor improvements and potential fixes 

- perform full sensor signal path reset and wait for max time (100 ms)
 - issue full sensor reset on any error
 - always read FIFO count before transfersj
 - only allocate drdy perf counter if GPIO is available
This commit is contained in:
Daniel Agar 2020-05-31 16:46:37 -04:00
parent 626895eadc
commit ff3b040d3c
4 changed files with 182 additions and 209 deletions
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4
platforms/common/include/px4_platform_common/atomic.h
View File

@ -166,9 +166,9 @@ public:
* contents of _value are written into *expected.
* @return If desired is written into _value then true is returned
*/
inline bool compare_exchange(T *expected, T num)
inline bool compare_exchange(T *expected, T desired)
{
return __atomic_compare_exchange(&_value, expected, num, false, __ATOMIC_SEQ_CST, __ATOMIC_SEQ_CST);
return __atomic_compare_exchange(&_value, expected, &desired, false, __ATOMIC_SEQ_CST, __ATOMIC_SEQ_CST);
}
private:

297
src/drivers/imu/invensense/icm20608g/ICM20608G.cpp
View File

@ -48,6 +48,10 @@ ICM20608G::ICM20608G(I2CSPIBusOption bus_option, int bus, uint32_t device, enum
_px4_accel(get_device_id(), ORB_PRIO_HIGH, rotation),
_px4_gyro(get_device_id(), ORB_PRIO_HIGH, rotation)
{
if (drdy_gpio != 0) {
_drdy_interval_perf = perf_alloc(PC_INTERVAL, MODULE_NAME": DRDY interval");
}
ConfigureSampleRate(_px4_gyro.get_max_rate_hz());
}
@ -77,6 +81,7 @@ int ICM20608G::init()
bool ICM20608G::Reset()
{
_state = STATE::RESET;
DataReadyInterruptDisable();
ScheduleClear();
ScheduleNow();
return true;
@ -91,8 +96,8 @@ void ICM20608G::exit_and_cleanup()
void ICM20608G::print_status()
{
I2CSPIDriverBase::print_status();
PX4_INFO("FIFO empty interval: %d us (%.3f Hz)", _fifo_empty_interval_us,
static_cast<double>(1000000 / _fifo_empty_interval_us));
PX4_INFO("FIFO empty interval: %d us (%.3f Hz)", _fifo_empty_interval_us, 1e6 / _fifo_empty_interval_us);
perf_print_counter(_transfer_perf);
perf_print_counter(_bad_register_perf);
@ -120,13 +125,17 @@ int ICM20608G::probe()
void ICM20608G::RunImpl()
{
const hrt_abstime now = hrt_absolute_time();
switch (_state) {
case STATE::RESET:
// PWR_MGMT_1: Device Reset
RegisterWrite(Register::PWR_MGMT_1, PWR_MGMT_1_BIT::DEVICE_RESET);
_reset_timestamp = hrt_absolute_time();
_reset_timestamp = now;
_consecutive_failures = 0;
_total_failures = 0;
_state = STATE::WAIT_FOR_RESET;
ScheduleDelayed(1_ms);
ScheduleDelayed(100_ms);
break;
case STATE::WAIT_FOR_RESET:
@ -136,13 +145,18 @@ void ICM20608G::RunImpl()
if ((RegisterRead(Register::WHO_AM_I) == WHOAMI)
&& (RegisterRead(Register::PWR_MGMT_1) == 0x40)) {
// Wakeup and reset digital signal path
RegisterWrite(Register::PWR_MGMT_1, 0);
RegisterWrite(Register::SIGNAL_PATH_RESET, SIGNAL_PATH_RESET_BIT::ACCEL_RST | SIGNAL_PATH_RESET_BIT::TEMP_RST);
RegisterSetAndClearBits(Register::USER_CTRL, USER_CTRL_BIT::SIG_COND_RST, USER_CTRL_BIT::I2C_IF_DIS);
// if reset succeeded then configure
_state = STATE::CONFIGURE;
ScheduleNow();
ScheduleDelayed(100_ms);
} else {
// RESET not complete
if (hrt_elapsed_time(&_reset_timestamp) > 100_ms) {
if (hrt_elapsed_time(&_reset_timestamp) > 1000_ms) {
PX4_DEBUG("Reset failed, retrying");
_state = STATE::RESET;
ScheduleDelayed(100_ms);
@ -164,7 +178,7 @@ void ICM20608G::RunImpl()
_data_ready_interrupt_enabled = true;
// backup schedule as a watchdog timeout
ScheduleDelayed(10_ms);
ScheduleDelayed(100_ms);
} else {
_data_ready_interrupt_enabled = false;
@ -174,82 +188,88 @@ void ICM20608G::RunImpl()
FIFOReset();
} else {
PX4_DEBUG("Configure failed, retrying");
// try again in 10 ms
// CONFIGURE not complete
if (hrt_elapsed_time(&_reset_timestamp) > 1000_ms) {
PX4_DEBUG("Configure failed, resetting");
_state = STATE::RESET;
} else {
PX4_DEBUG("Configure failed, retrying");
}
ScheduleDelayed(10_ms);
}
break;
case STATE::FIFO_READ: {
hrt_abstime timestamp_sample = 0;
uint8_t samples = 0;
if (_data_ready_interrupt_enabled) {
// re-schedule as watchdog timeout
ScheduleDelayed(10_ms);
// timestamp set in data ready interrupt
if (!_force_fifo_count_check) {
samples = _fifo_read_samples.load();
} else {
const uint16_t fifo_count = FIFOReadCount();
samples = (fifo_count / sizeof(FIFO::DATA) / SAMPLES_PER_TRANSFER) * SAMPLES_PER_TRANSFER; // round down to nearest
// scheduled from interrupt if _drdy_fifo_read_samples was set
if (_drdy_fifo_read_samples.fetch_and(0) == _fifo_gyro_samples) {
perf_count_interval(_drdy_interval_perf, now);
}
timestamp_sample = _fifo_watermark_interrupt_timestamp;
// push backup schedule back
ScheduleDelayed(_fifo_empty_interval_us * 2);
}
bool failure = false;
// always check current FIFO count
bool success = false;
const uint16_t fifo_count = FIFOReadCount();
// manually check FIFO count if no samples from DRDY or timestamp looks bogus
if (!_data_ready_interrupt_enabled || (samples == 0)
|| (hrt_elapsed_time(&timestamp_sample) > (_fifo_empty_interval_us / 2))) {
// use the time now roughly corresponding with the last sample we'll pull from the FIFO
timestamp_sample = hrt_absolute_time();
const uint16_t fifo_count = FIFOReadCount();
samples = (fifo_count / sizeof(FIFO::DATA) / SAMPLES_PER_TRANSFER) * SAMPLES_PER_TRANSFER; // round down to nearest
}
if (samples > FIFO_MAX_SAMPLES) {
// not technically an overflow, but more samples than we expected or can publish
perf_count(_fifo_overflow_perf);
failure = true;
if (fifo_count >= FIFO::SIZE) {
FIFOReset();
perf_count(_fifo_overflow_perf);
} else if (samples >= SAMPLES_PER_TRANSFER) {
// require at least SAMPLES_PER_TRANSFER (we want at least 1 new accel sample per transfer)
if (!FIFORead(timestamp_sample, samples)) {
failure = true;
_px4_accel.increase_error_count();
_px4_gyro.increase_error_count();
}
} else if (samples == 0) {
failure = true;
} else if (fifo_count == 0) {
perf_count(_fifo_empty_perf);
} else {
// FIFO count (size in bytes) should be a multiple of the FIFO::DATA structure
const uint8_t samples = (fifo_count / sizeof(FIFO::DATA) / SAMPLES_PER_TRANSFER) *
SAMPLES_PER_TRANSFER; // round down to nearest
if (samples > FIFO_MAX_SAMPLES) {
// not technically an overflow, but more samples than we expected or can publish
FIFOReset();
perf_count(_fifo_overflow_perf);
} else if (samples >= 1) {
if (FIFORead(now, samples)) {
success = true;
_consecutive_failures = 0;
}
}
}
if (failure || hrt_elapsed_time(&_last_config_check_timestamp) > 10_ms) {
// check registers incrementally
if (RegisterCheck(_register_cfg[_checked_register], true)) {
_last_config_check_timestamp = timestamp_sample;
if (!success) {
_consecutive_failures++;
_total_failures++;
// full reset if things are failing consistently
if (_consecutive_failures > 100 || _total_failures > 1000) {
Reset();
return;
}
}
if (!success || hrt_elapsed_time(&_last_config_check_timestamp) > 10_ms) {
// check configuration registers periodically or immediately following any failure
if (RegisterCheck(_register_cfg[_checked_register])) {
_last_config_check_timestamp = now;
_checked_register = (_checked_register + 1) % size_register_cfg;
} else {
// register check failed, force reconfigure
PX4_DEBUG("Health check failed, reconfiguring");
_state = STATE::CONFIGURE;
ScheduleNow();
// register check failed, force reset
perf_count(_bad_register_perf);
Reset();
}
} else {
// periodically update temperature (1 Hz)
if (hrt_elapsed_time(&_temperature_update_timestamp) > 1_s) {
// periodically update temperature (~1 Hz)
if (hrt_elapsed_time(&_temperature_update_timestamp) >= 1_s) {
UpdateTemperature();
_temperature_update_timestamp = timestamp_sample;
_temperature_update_timestamp = now;
}
}
}
@ -319,23 +339,27 @@ void ICM20608G::ConfigureSampleRate(int sample_rate)
}
// round down to nearest FIFO sample dt * SAMPLES_PER_TRANSFER
const float min_interval = SAMPLES_PER_TRANSFER * FIFO_SAMPLE_DT;
const float min_interval = FIFO_SAMPLE_DT * SAMPLES_PER_TRANSFER;
_fifo_empty_interval_us = math::max(roundf((1e6f / (float)sample_rate) / min_interval) * min_interval, min_interval);
_fifo_gyro_samples = math::min((float)_fifo_empty_interval_us / (1e6f / GYRO_RATE), (float)FIFO_MAX_SAMPLES);
_fifo_gyro_samples = roundf(math::min((float)_fifo_empty_interval_us / (1e6f / GYRO_RATE), (float)FIFO_MAX_SAMPLES));
// recompute FIFO empty interval (us) with actual gyro sample limit
_fifo_empty_interval_us = _fifo_gyro_samples * (1e6f / GYRO_RATE);
_fifo_accel_samples = math::min(_fifo_empty_interval_us / (1e6f / ACCEL_RATE), (float)FIFO_MAX_SAMPLES);
}
bool ICM20608G::Configure()
{
// first set and clear all configured register bits
for (const auto &reg_cfg : _register_cfg) {
RegisterSetAndClearBits(reg_cfg.reg, reg_cfg.set_bits, reg_cfg.clear_bits);
}
// now check that all are configured
bool success = true;
for (const auto &reg : _register_cfg) {
if (!RegisterCheck(reg)) {
for (const auto &reg_cfg : _register_cfg) {
if (!RegisterCheck(reg_cfg)) {
success = false;
}
}
@ -354,12 +378,13 @@ int ICM20608G::DataReadyInterruptCallback(int irq, void *context, void *arg)
void ICM20608G::DataReady()
{
perf_count(_drdy_interval_perf);
const uint8_t count = _drdy_count.fetch_add(1) + 1;
if (_data_ready_count.fetch_add(1) >= (_fifo_gyro_samples - 1)) {
_data_ready_count.store(0);
_fifo_watermark_interrupt_timestamp = hrt_absolute_time();
_fifo_read_samples.store(_fifo_gyro_samples);
uint8_t expected = 0;
// at least the required number of samples in the FIFO
if ((count >= _fifo_gyro_samples) && _drdy_fifo_read_samples.compare_exchange(&expected, _fifo_gyro_samples)) {
_drdy_count.store(0);
ScheduleNow();
}
}
@ -383,7 +408,7 @@ bool ICM20608G::DataReadyInterruptDisable()
return px4_arch_gpiosetevent(_drdy_gpio, false, false, false, nullptr, nullptr) == 0;
}
bool ICM20608G::RegisterCheck(const register_config_t &reg_cfg, bool notify)
bool ICM20608G::RegisterCheck(const register_config_t &reg_cfg)
{
bool success = true;
@ -399,16 +424,6 @@ bool ICM20608G::RegisterCheck(const register_config_t &reg_cfg, bool notify)
success = false;
}
if (!success) {
RegisterSetAndClearBits(reg_cfg.reg, reg_cfg.set_bits, reg_cfg.clear_bits);
if (notify) {
perf_count(_bad_register_perf);
_px4_accel.increase_error_count();
_px4_gyro.increase_error_count();
}
}
return success;
}
@ -429,17 +444,12 @@ void ICM20608G::RegisterWrite(Register reg, uint8_t value)
void ICM20608G::RegisterSetAndClearBits(Register reg, uint8_t setbits, uint8_t clearbits)
{
const uint8_t orig_val = RegisterRead(reg);
uint8_t val = orig_val;
if (setbits) {
val |= setbits;
uint8_t val = (orig_val & ~clearbits) | setbits;
if (orig_val != val) {
RegisterWrite(reg, val);
}
if (clearbits) {
val &= ~clearbits;
}
RegisterWrite(reg, val);
}
uint16_t ICM20608G::FIFOReadCount()
@ -456,11 +466,11 @@ uint16_t ICM20608G::FIFOReadCount()
return combine(fifo_count_buf[1], fifo_count_buf[2]);
}
bool ICM20608G::FIFORead(const hrt_abstime &timestamp_sample, uint16_t samples)
bool ICM20608G::FIFORead(const hrt_abstime &timestamp_sample, uint8_t samples)
{
perf_begin(_transfer_perf);
FIFOTransferBuffer buffer{};
const size_t transfer_size = math::min(samples * sizeof(FIFO::DATA) + 3, FIFO::SIZE);
const size_t transfer_size = math::min(samples * sizeof(FIFO::DATA) + 1, FIFO::SIZE);
if (transfer((uint8_t *)&buffer, (uint8_t *)&buffer, transfer_size) != PX4_OK) {
perf_end(_transfer_perf);
@ -470,47 +480,8 @@ bool ICM20608G::FIFORead(const hrt_abstime &timestamp_sample, uint16_t samples)
perf_end(_transfer_perf);
const uint16_t fifo_count_bytes = combine(buffer.FIFO_COUNTH, buffer.FIFO_COUNTL);
const uint16_t fifo_count_samples = fifo_count_bytes / sizeof(FIFO::DATA);
if (fifo_count_samples == 0) {
perf_count(_fifo_empty_perf);
return false;
}
if (fifo_count_bytes >= FIFO::SIZE) {
perf_count(_fifo_overflow_perf);
FIFOReset();
return false;
}
const uint16_t valid_samples = math::min(samples, fifo_count_samples);
if (fifo_count_samples < samples) {
// force check if there is somehow fewer samples actually in the FIFO (potentially a serious error)
_force_fifo_count_check = true;
} else if (fifo_count_samples >= samples + 2) {
// if we're more than a couple samples behind force FIFO_COUNT check
_force_fifo_count_check = true;
} else {
// skip earlier FIFO_COUNT and trust DRDY count if we're in sync
_force_fifo_count_check = false;
}
if (valid_samples > 0) {
ProcessGyro(timestamp_sample, buffer, valid_samples);
if (ProcessAccel(timestamp_sample, buffer, valid_samples)) {
return true;
}
}
// force FIFO count check if there was any other error
_force_fifo_count_check = true;
return false;
ProcessGyro(timestamp_sample, buffer.f, samples);
return ProcessAccel(timestamp_sample, buffer.f, samples);
}
void ICM20608G::FIFOReset()
@ -524,9 +495,8 @@ void ICM20608G::FIFOReset()
RegisterSetAndClearBits(Register::USER_CTRL, USER_CTRL_BIT::FIFO_RST, USER_CTRL_BIT::FIFO_EN);
// reset while FIFO is disabled
_data_ready_count.store(0);
_fifo_watermark_interrupt_timestamp = 0;
_fifo_read_samples.store(0);
_drdy_count.store(0);
_drdy_fifo_read_samples.store(0);
// FIFO_EN: enable both gyro and accel
// USER_CTRL: re-enable FIFO
@ -542,12 +512,12 @@ static bool fifo_accel_equal(const FIFO::DATA &f0, const FIFO::DATA &f1)
return (memcmp(&f0.ACCEL_XOUT_H, &f1.ACCEL_XOUT_H, 6) == 0);
}
bool ICM20608G::ProcessAccel(const hrt_abstime &timestamp_sample, const FIFOTransferBuffer &buffer,
const uint8_t samples)
bool ICM20608G::ProcessAccel(const hrt_abstime &timestamp_sample, const FIFO::DATA fifo[], const uint8_t samples)
{
PX4Accelerometer::FIFOSample accel;
accel.timestamp_sample = timestamp_sample;
accel.dt = _fifo_empty_interval_us / _fifo_accel_samples;
accel.samples = 0;
accel.dt = FIFO_SAMPLE_DT * SAMPLES_PER_TRANSFER;
bool bad_data = false;
@ -555,59 +525,57 @@ bool ICM20608G::ProcessAccel(const hrt_abstime &timestamp_sample, const FIFOTran
int accel_first_sample = 1;
if (samples >= 4) {
if (fifo_accel_equal(buffer.f[0], buffer.f[1]) && fifo_accel_equal(buffer.f[2], buffer.f[3])) {
if (fifo_accel_equal(fifo[0], fifo[1]) && fifo_accel_equal(fifo[2], fifo[3])) {
// [A0, A1, A2, A3]
// A0==A1, A2==A3
accel_first_sample = 1;
} else if (fifo_accel_equal(buffer.f[1], buffer.f[2])) {
} else if (fifo_accel_equal(fifo[1], fifo[2])) {
// [A0, A1, A2, A3]
// A0, A1==A2, A3
accel_first_sample = 0;
} else {
perf_count(_bad_transfer_perf);
// no matching accel samples is an error
bad_data = true;
perf_count(_bad_transfer_perf);
}
}
int accel_samples = 0;
for (int i = accel_first_sample; i < samples; i = i + 2) {
const FIFO::DATA &fifo_sample = buffer.f[i];
int16_t accel_x = combine(fifo_sample.ACCEL_XOUT_H, fifo_sample.ACCEL_XOUT_L);
int16_t accel_y = combine(fifo_sample.ACCEL_YOUT_H, fifo_sample.ACCEL_YOUT_L);
int16_t accel_z = combine(fifo_sample.ACCEL_ZOUT_H, fifo_sample.ACCEL_ZOUT_L);
for (int i = accel_first_sample; i < samples; i = i + SAMPLES_PER_TRANSFER) {
int16_t accel_x = combine(fifo[i].ACCEL_XOUT_H, fifo[i].ACCEL_XOUT_L);
int16_t accel_y = combine(fifo[i].ACCEL_YOUT_H, fifo[i].ACCEL_YOUT_L);
int16_t accel_z = combine(fifo[i].ACCEL_ZOUT_H, fifo[i].ACCEL_ZOUT_L);
// sensor's frame is +x forward, +y left, +z up
// flip y & z to publish right handed with z down (x forward, y right, z down)
accel.x[accel_samples] = accel_x;
accel.y[accel_samples] = (accel_y == INT16_MIN) ? INT16_MAX : -accel_y;
accel.z[accel_samples] = (accel_z == INT16_MIN) ? INT16_MAX : -accel_z;
accel_samples++;
accel.x[accel.samples] = accel_x;
accel.y[accel.samples] = (accel_y == INT16_MIN) ? INT16_MAX : -accel_y;
accel.z[accel.samples] = (accel_z == INT16_MIN) ? INT16_MAX : -accel_z;
accel.samples++;
}
accel.samples = accel_samples;
_px4_accel.set_error_count(perf_event_count(_bad_register_perf) + perf_event_count(_bad_transfer_perf) +
perf_event_count(_fifo_empty_perf) + perf_event_count(_fifo_overflow_perf));
_px4_accel.updateFIFO(accel);
if (accel.samples > 0) {
_px4_accel.updateFIFO(accel);
}
return !bad_data;
}
void ICM20608G::ProcessGyro(const hrt_abstime &timestamp_sample, const FIFOTransferBuffer &buffer,
const uint8_t samples)
void ICM20608G::ProcessGyro(const hrt_abstime &timestamp_sample, const FIFO::DATA fifo[], const uint8_t samples)
{
PX4Gyroscope::FIFOSample gyro;
gyro.timestamp_sample = timestamp_sample;
gyro.samples = samples;
gyro.dt = _fifo_empty_interval_us / _fifo_gyro_samples;
gyro.dt = FIFO_SAMPLE_DT;
for (int i = 0; i < samples; i++) {
const FIFO::DATA &fifo_sample = buffer.f[i];
const int16_t gyro_x = combine(fifo_sample.GYRO_XOUT_H, fifo_sample.GYRO_XOUT_L);
const int16_t gyro_y = combine(fifo_sample.GYRO_YOUT_H, fifo_sample.GYRO_YOUT_L);
const int16_t gyro_z = combine(fifo_sample.GYRO_ZOUT_H, fifo_sample.GYRO_ZOUT_L);
const int16_t gyro_x = combine(fifo[i].GYRO_XOUT_H, fifo[i].GYRO_XOUT_L);
const int16_t gyro_y = combine(fifo[i].GYRO_YOUT_H, fifo[i].GYRO_YOUT_L);
const int16_t gyro_z = combine(fifo[i].GYRO_ZOUT_H, fifo[i].GYRO_ZOUT_L);
// sensor's frame is +x forward, +y left, +z up
// flip y & z to publish right handed with z down (x forward, y right, z down)
@ -616,6 +584,9 @@ void ICM20608G::ProcessGyro(const hrt_abstime &timestamp_sample, const FIFOTrans
gyro.z[i] = (gyro_z == INT16_MIN) ? INT16_MAX : -gyro_z;
}
_px4_gyro.set_error_count(perf_event_count(_bad_register_perf) + perf_event_count(_bad_transfer_perf) +
perf_event_count(_fifo_empty_perf) + perf_event_count(_fifo_overflow_perf));
_px4_gyro.updateFIFO(gyro);
}

45
src/drivers/imu/invensense/icm20608g/ICM20608G.hpp
View File

@ -73,22 +73,20 @@ private:
void exit_and_cleanup() override;
// Sensor Configuration
static constexpr float FIFO_SAMPLE_DT{125.f};
static constexpr uint32_t SAMPLES_PER_TRANSFER{2}; // ensure at least 1 new accel sample per transfer
static constexpr float GYRO_RATE{1e6f / FIFO_SAMPLE_DT}; // 8 kHz gyro
static constexpr float ACCEL_RATE{GYRO_RATE / 2.f}; // 4 kHz accel
static constexpr float FIFO_SAMPLE_DT{1e6f / 8000.f};
static constexpr uint32_t SAMPLES_PER_TRANSFER{2}; // ensure at least 1 new accel sample per transfer
static constexpr float GYRO_RATE{1e6f / FIFO_SAMPLE_DT}; // 8000 Hz gyro
static constexpr float ACCEL_RATE{GYRO_RATE / SAMPLES_PER_TRANSFER}; // 4000 Hz accel
static constexpr uint32_t FIFO_MAX_SAMPLES{math::min(FIFO::SIZE / sizeof(FIFO::DATA), sizeof(PX4Gyroscope::FIFOSample::x) / sizeof(PX4Gyroscope::FIFOSample::x[0]))};
// Transfer data
struct FIFOTransferBuffer {
uint8_t cmd{static_cast<uint8_t>(Register::FIFO_COUNTH) | DIR_READ};
uint8_t FIFO_COUNTH{0};
uint8_t FIFO_COUNTL{0};
uint8_t cmd{static_cast<uint8_t>(Register::FIFO_R_W) | DIR_READ};
FIFO::DATA f[FIFO_MAX_SAMPLES] {};
};
// ensure no struct padding
static_assert(sizeof(FIFOTransferBuffer) == (3 + FIFO_MAX_SAMPLES *sizeof(FIFO::DATA)));
static_assert(sizeof(FIFOTransferBuffer) == (1 + FIFO_MAX_SAMPLES *sizeof(FIFO::DATA)));
struct register_config_t {
Register reg;
@ -110,20 +108,18 @@ private:
bool DataReadyInterruptConfigure();
bool DataReadyInterruptDisable();
bool RegisterCheck(const register_config_t &reg_cfg, bool notify = false);
bool RegisterCheck(const register_config_t &reg_cfg);
uint8_t RegisterRead(Register reg);
void RegisterWrite(Register reg, uint8_t value);
void RegisterSetAndClearBits(Register reg, uint8_t setbits, uint8_t clearbits);
void RegisterSetBits(Register reg, uint8_t setbits) { RegisterSetAndClearBits(reg, setbits, 0); }
void RegisterClearBits(Register reg, uint8_t clearbits) { RegisterSetAndClearBits(reg, 0, clearbits); }
uint16_t FIFOReadCount();
bool FIFORead(const hrt_abstime &timestamp_sample, uint16_t samples);
bool FIFORead(const hrt_abstime &timestamp_sample, uint8_t samples);
void FIFOReset();
bool ProcessAccel(const hrt_abstime &timestamp_sample, const FIFOTransferBuffer &buffer, const uint8_t samples);
void ProcessGyro(const hrt_abstime &timestamp_sample, const FIFOTransferBuffer &buffer, const uint8_t samples);
bool ProcessAccel(const hrt_abstime &timestamp_sample, const FIFO::DATA fifo[], const uint8_t samples);
void ProcessGyro(const hrt_abstime &timestamp_sample, const FIFO::DATA fifo[], const uint8_t samples);
void UpdateTemperature();
const spi_drdy_gpio_t _drdy_gpio;
@ -137,17 +133,17 @@ private:
perf_counter_t _fifo_empty_perf{perf_alloc(PC_COUNT, MODULE_NAME": FIFO empty")};
perf_counter_t _fifo_overflow_perf{perf_alloc(PC_COUNT, MODULE_NAME": FIFO overflow")};
perf_counter_t _fifo_reset_perf{perf_alloc(PC_COUNT, MODULE_NAME": FIFO reset")};
perf_counter_t _drdy_interval_perf{perf_alloc(PC_INTERVAL, MODULE_NAME": DRDY interval")};
perf_counter_t _drdy_interval_perf{nullptr};
hrt_abstime _reset_timestamp{0};
hrt_abstime _last_config_check_timestamp{0};
hrt_abstime _fifo_watermark_interrupt_timestamp{0};
hrt_abstime _temperature_update_timestamp{0};
unsigned _consecutive_failures{0};
unsigned _total_failures{0};
px4::atomic<uint8_t> _data_ready_count{0};
px4::atomic<uint8_t> _fifo_read_samples{0};
px4::atomic<uint8_t> _drdy_fifo_read_samples{0};
px4::atomic<uint8_t> _drdy_count{0};
bool _data_ready_interrupt_enabled{false};
bool _force_fifo_count_check{true};
enum class STATE : uint8_t {
RESET,
@ -160,20 +156,19 @@ private:
uint16_t _fifo_empty_interval_us{1250}; // default 1250 us / 800 Hz transfer interval
uint8_t _fifo_gyro_samples{static_cast<uint8_t>(_fifo_empty_interval_us / (1000000 / GYRO_RATE))};
uint8_t _fifo_accel_samples{static_cast<uint8_t>(_fifo_empty_interval_us / (1000000 / ACCEL_RATE))};
uint8_t _checked_register{0};
static constexpr uint8_t size_register_cfg{9};
register_config_t _register_cfg[size_register_cfg] {
// Register | Set bits, Clear bits
{ Register::PWR_MGMT_1, PWR_MGMT_1_BIT::CLKSEL_0, PWR_MGMT_1_BIT::DEVICE_RESET | PWR_MGMT_1_BIT::SLEEP },
{ Register::CONFIG, CONFIG_BIT::FIFO_MODE | CONFIG_BIT::DLPF_CFG_BYPASS_DLPF_8KHZ, 0 },
{ Register::GYRO_CONFIG, GYRO_CONFIG_BIT::FS_SEL_2000_DPS, GYRO_CONFIG_BIT::FCHOICE_B_8KHZ_BYPASS_DLPF },
{ Register::ACCEL_CONFIG, ACCEL_CONFIG_BIT::ACCEL_FS_SEL_16G, 0 },
{ Register::ACCEL_CONFIG2, ACCEL_CONFIG2_BIT::ACCEL_FCHOICE_B_BYPASS_DLPF, 0 },
{ Register::GYRO_CONFIG, GYRO_CONFIG_BIT::FS_SEL_2000_DPS, GYRO_CONFIG_BIT::FCHOICE_B_8KHZ_BYPASS_DLPF },
{ Register::CONFIG, CONFIG_BIT::FIFO_MODE | CONFIG_BIT::DLPF_CFG_BYPASS_DLPF_8KHZ, 0 },
{ Register::USER_CTRL, USER_CTRL_BIT::FIFO_EN | USER_CTRL_BIT::I2C_IF_DIS, USER_CTRL_BIT::FIFO_RST | USER_CTRL_BIT::SIG_COND_RST },
{ Register::FIFO_EN, FIFO_EN_BIT::XG_FIFO_EN | FIFO_EN_BIT::YG_FIFO_EN | FIFO_EN_BIT::ZG_FIFO_EN | FIFO_EN_BIT::ACCEL_FIFO_EN, FIFO_EN_BIT::TEMP_FIFO_EN },
{ Register::INT_PIN_CFG, INT_PIN_CFG_BIT::INT_LEVEL, 0 },
{ Register::INT_ENABLE, INT_ENABLE_BIT::DATA_RDY_INT_EN, 0 }
{ Register::INT_ENABLE, INT_ENABLE_BIT::DATA_RDY_INT_EN, 0 },
{ Register::USER_CTRL, USER_CTRL_BIT::FIFO_EN | USER_CTRL_BIT::I2C_IF_DIS, 0 },
{ Register::PWR_MGMT_1, PWR_MGMT_1_BIT::CLKSEL_0, PWR_MGMT_1_BIT::DEVICE_RESET | PWR_MGMT_1_BIT::SLEEP },
};
};

45
src/drivers/imu/invensense/icm20608g/InvenSense_ICM20608G_registers.hpp
View File

@ -63,26 +63,28 @@ static constexpr float TEMPERATURE_SENSITIVITY = 326.8f; // LSB/C
static constexpr float TEMPERATURE_OFFSET = 25.f; // C
enum class Register : uint8_t {
CONFIG = 0x1A,
GYRO_CONFIG = 0x1B,
ACCEL_CONFIG = 0x1C,
ACCEL_CONFIG2 = 0x1D,
CONFIG = 0x1A,
GYRO_CONFIG = 0x1B,
ACCEL_CONFIG = 0x1C,
ACCEL_CONFIG2 = 0x1D,
FIFO_EN = 0x23,
FIFO_EN = 0x23,
INT_PIN_CFG = 0x37,
INT_ENABLE = 0x38,
INT_PIN_CFG = 0x37,
INT_ENABLE = 0x38,
TEMP_OUT_H = 0x41,
TEMP_OUT_L = 0x42,
TEMP_OUT_H = 0x41,
TEMP_OUT_L = 0x42,
USER_CTRL = 0x6A,
PWR_MGMT_1 = 0x6B,
SIGNAL_PATH_RESET = 0x68,
FIFO_COUNTH = 0x72,
FIFO_COUNTL = 0x73,
FIFO_R_W = 0x74,
WHO_AM_I = 0x75,
USER_CTRL = 0x6A,
PWR_MGMT_1 = 0x6B,
FIFO_COUNTH = 0x72,
FIFO_COUNTL = 0x73,
FIFO_R_W = 0x74,
WHO_AM_I = 0x75,
};
// CONFIG
@ -134,7 +136,13 @@ enum INT_PIN_CFG_BIT : uint8_t {
// INT_ENABLE
enum INT_ENABLE_BIT : uint8_t {
DATA_RDY_INT_EN = Bit0
DATA_RDY_INT_EN = Bit0,
};
// SIGNAL_PATH_RESET
enum SIGNAL_PATH_RESET_BIT : uint8_t {
ACCEL_RST = Bit1,
TEMP_RST = Bit0,
};
// USER_CTRL
@ -150,9 +158,8 @@ enum PWR_MGMT_1_BIT : uint8_t {
DEVICE_RESET = Bit7,
SLEEP = Bit6,
CLKSEL_2 = Bit2,
CLKSEL_1 = Bit1,
CLKSEL_0 = Bit0,
// CLKSEL[2:0]
CLKSEL_0 = Bit0, // It is required that CLKSEL[2:0] be set to 001 to achieve full gyroscope performance.
};
namespace FIFO