ardupilot/libraries/AP_SurfaceDistance/AP_SurfaceDistance.cpp

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#include "AP_SurfaceDistance.h"
#include <AP_RangeFinder/AP_RangeFinder.h>
#ifndef RANGEFINDER_TIMEOUT_MS
# define RANGEFINDER_TIMEOUT_MS 1000 // rangefinder filter reset if no updates from sensor in 1 second
#endif
#if AP_RANGEFINDER_ENABLED
#include <AP_AHRS/AP_AHRS.h>
#include <AP_Logger/AP_Logger.h>
#ifndef RANGEFINDER_TILT_CORRECTION // by disable tilt correction for use of range finder data by EKF
# define RANGEFINDER_TILT_CORRECTION 1
#endif
#ifndef RANGEFINDER_GLITCH_NUM_SAMPLES
# define RANGEFINDER_GLITCH_NUM_SAMPLES 3 // number of rangefinder glitches in a row to take new reading
#endif
#ifndef RANGEFINDER_GLITCH_ALT_CM
# define RANGEFINDER_GLITCH_ALT_CM 200 // amount of rangefinder change to be considered a glitch
#endif
#ifndef RANGEFINDER_HEALTH_MIN
# define RANGEFINDER_HEALTH_MIN 3 // number of good reads that indicates a healthy rangefinder
#endif
void AP_SurfaceDistance::update()
{
WITH_SEMAPHORE(sem);
const RangeFinder *rangefinder = RangeFinder::get_singleton();
if (rangefinder == nullptr) {
alt_healthy = false;
return;
}
#if RANGEFINDER_TILT_CORRECTION == 1
const float tilt_correction = MAX(0.707f, AP::ahrs().get_rotation_body_to_ned().c.z);
#else
const float tilt_correction = 1.0f;
#endif
const uint32_t now = AP_HAL::millis();
// assemble bitmask assistance, definition is used to generate log documentation
enum class Surface_Distance_Status : uint8_t {
Enabled = 1U<<0, // true if rangefinder has been set to enable by vehicle
Unhealthy = 1U<<1, // true if rangefinder is considered unhealthy
Stale_Data = 1U<<2, // true if the last healthy rangefinder reading is no longer valid
Glitch_Detected = 1U<<3, // true if a measurement glitch detected
};
// reset status and add to the bitmask as we progress through the update
status = 0;
// update enabled status
if (enabled) {
status |= (uint8_t)Surface_Distance_Status::Enabled;
}
// update health
alt_healthy = (rangefinder->status_orient(rotation) == RangeFinder::Status::Good) &&
(rangefinder->range_valid_count_orient(rotation) >= RANGEFINDER_HEALTH_MIN);
if (!alt_healthy) {
status |= (uint8_t)Surface_Distance_Status::Unhealthy;
}
// tilt corrected but unfiltered, not glitch protected alt
alt_cm = tilt_correction * rangefinder->distance_cm_orient(rotation);
// remember inertial alt to allow us to interpolate rangefinder
inertial_alt_cm = inertial_nav.get_position_z_up_cm();
// glitch handling. rangefinder readings more than RANGEFINDER_GLITCH_ALT_CM from the last good reading
// are considered a glitch and glitch_count becomes non-zero
// glitches clear after RANGEFINDER_GLITCH_NUM_SAMPLES samples in a row.
// glitch_cleared_ms is set so surface tracking (or other consumers) can trigger a target reset
const int32_t glitch_cm = alt_cm - alt_cm_glitch_protected;
bool reset_terrain_offset = false;
if (glitch_cm >= RANGEFINDER_GLITCH_ALT_CM) {
glitch_count = MAX(glitch_count+1, 1);
status |= (uint8_t)Surface_Distance_Status::Glitch_Detected;
} else if (glitch_cm <= -RANGEFINDER_GLITCH_ALT_CM) {
glitch_count = MIN(glitch_count-1, -1);
status |= (uint8_t)Surface_Distance_Status::Glitch_Detected;
} else {
glitch_count = 0;
alt_cm_glitch_protected = alt_cm;
}
if (abs(glitch_count) >= RANGEFINDER_GLITCH_NUM_SAMPLES) {
// clear glitch and record time so consumers (i.e. surface tracking) can reset their target altitudes
glitch_count = 0;
alt_cm_glitch_protected = alt_cm;
glitch_cleared_ms = now;
reset_terrain_offset = true;
}
// filter rangefinder altitude
const bool timed_out = now - last_healthy_ms > RANGEFINDER_TIMEOUT_MS;
if (alt_healthy) {
if (timed_out) {
// reset filter if we haven't used it within the last second
alt_cm_filt.reset(alt_cm);
reset_terrain_offset = true;
status |= (uint8_t)Surface_Distance_Status::Stale_Data;
} else {
// TODO: When we apply this library in plane we will need to be able to set the filter freq
alt_cm_filt.apply(alt_cm, 0.05);
}
last_healthy_ms = now;
}
// handle reset of terrain offset
if (reset_terrain_offset) {
if (rotation == ROTATION_PITCH_90) {
// upward facing
terrain_offset_cm = inertial_alt_cm + alt_cm;
} else {
// assume downward facing
terrain_offset_cm = inertial_alt_cm - alt_cm;
}
}
#if HAL_LOGGING_ENABLED
Log_Write();
#endif
}
/*
get inertially interpolated rangefinder height. Inertial height is
recorded whenever we update the rangefinder height, then we use the
difference between the inertial height at that time and the current
inertial height to give us interpolation of height from rangefinder
*/
bool AP_SurfaceDistance::get_rangefinder_height_interpolated_cm(int32_t& ret) const
{
if (!enabled_and_healthy()) {
return false;
}
ret = alt_cm_filt.get();
ret += inertial_nav.get_position_z_up_cm() - inertial_alt_cm;
return true;
}
#if HAL_LOGGING_ENABLED
void AP_SurfaceDistance::Log_Write(void) const
{
// @LoggerMessage: SURF
// @Vehicles: Copter
// @Description: Surface distance measurement
// @Field: TimeUS: Time since system startup
// @Field: I: Instance
// @FieldBitmaskEnum: St: Surface_Distance_Status
// @Field: D: Raw Distance
// @Field: FD: Filtered Distance
// @Field: TO: Terrain Offset
//Write to data flash log
AP::logger().WriteStreaming("SURF",
"TimeUS,I,St,D,FD,TO",
"s#-mmm",
"F--000",
"QBBfff",
AP_HAL::micros64(),
instance,
status,
(float)alt_cm * 0.01,
(float)alt_cm_filt.get() * 0.01,
(float)terrain_offset_cm * 0.01
);
}
#endif // HAL_LOGGING_ENABLED
#endif // AP_RANGEFINDER_ENABLED
bool AP_SurfaceDistance::data_stale(void)
{
WITH_SEMAPHORE(sem);
return (AP_HAL::millis() - last_healthy_ms) > RANGEFINDER_TIMEOUT_MS;
}
bool AP_SurfaceDistance::enabled_and_healthy(void) const
{
return enabled && alt_healthy;
}