/*
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see .
*/
/*
support for MicroStrain MIP parsing
*/
#define ALLOW_DOUBLE_MATH_FUNCTIONS
#include "AP_ExternalAHRS_config.h"
#if AP_MICROSTRAIN_ENABLED
#include "MicroStrain_common.h"
#include
// https://s3.amazonaws.com/files.microstrain.com/GQ7+User+Manual/external_content/dcp/Data/sensor_data/sensor_data_links.htm
enum class INSPacketField {
ACCEL = 0x04,
GYRO = 0x05,
QUAT = 0x0A,
MAG = 0x06,
PRESSURE = 0x17,
};
// https://s3.amazonaws.com/files.microstrain.com/GQ7+User+Manual/external_content/dcp/Data/gnss_recv_1/gnss_recv_1_links.htm
enum class GNSSPacketField {
LLH_POSITION = 0x03,
NED_VELOCITY = 0x05,
DOP_DATA = 0x07,
FIX_INFO = 0x0B,
// https://s3.amazonaws.com/files.microstrain.com/GQ7+User+Manual/external_content/dcp/Data/shared_data/data/mip_field_shared_gps_timestamp.htm
GPS_TIMESTAMP = 0xD3,
};
// https://s3.amazonaws.com/files.microstrain.com/GQ7+User+Manual/external_content/dcp/Data/gnss_recv_1/data/mip_field_gnss_fix_info.htm
enum class GNSSFixType {
FIX_3D = 0x00,
FIX_2D = 0x01,
TIME_ONLY = 0x02,
NONE = 0x03,
INVALID = 0x04,
FIX_RTK_FLOAT = 0x05,
FIX_RTK_FIXED = 0x06,
};
// https://s3.amazonaws.com/files.microstrain.com/GQ7+User+Manual/external_content/dcp/Data/filter_data/filter_data_links.htm
enum class FilterPacketField {
FILTER_STATUS = 0x10,
LLH_POSITION = 0x01,
NED_VELOCITY = 0x02,
// https://s3.amazonaws.com/files.microstrain.com/GQ7+User+Manual/external_content/dcp/Data/shared_data/data/mip_field_shared_gps_timestamp.htm
GPS_TIMESTAMP = 0xD3,
};
bool AP_MicroStrain::handle_byte(const uint8_t b, DescriptorSet& descriptor)
{
switch (message_in.state) {
case ParseState::WaitingFor_SyncOne:
if (b == SYNC_ONE) {
message_in.packet.header[0] = b;
message_in.state = ParseState::WaitingFor_SyncTwo;
}
break;
case ParseState::WaitingFor_SyncTwo:
if (b == SYNC_TWO) {
message_in.packet.header[1] = b;
message_in.state = ParseState::WaitingFor_Descriptor;
} else {
message_in.state = ParseState::WaitingFor_SyncOne;
}
break;
case ParseState::WaitingFor_Descriptor:
message_in.packet.descriptor_set(b);
message_in.state = ParseState::WaitingFor_PayloadLength;
break;
case ParseState::WaitingFor_PayloadLength:
message_in.packet.payload_length(b);
message_in.state = ParseState::WaitingFor_Data;
message_in.index = 0;
break;
case ParseState::WaitingFor_Data:
message_in.packet.payload[message_in.index++] = b;
if (message_in.index >= message_in.packet.payload_length()) {
message_in.state = ParseState::WaitingFor_Checksum;
message_in.index = 0;
}
break;
case ParseState::WaitingFor_Checksum:
message_in.packet.checksum[message_in.index++] = b;
if (message_in.index >= 2) {
message_in.state = ParseState::WaitingFor_SyncOne;
message_in.index = 0;
if (valid_packet(message_in.packet)) {
descriptor = handle_packet(message_in.packet);
return true;
}
}
break;
}
return false;
}
bool AP_MicroStrain::valid_packet(const MicroStrain_Packet & packet)
{
uint8_t checksum_one = 0;
uint8_t checksum_two = 0;
for (int i = 0; i < 4; i++) {
checksum_one += packet.header[i];
checksum_two += checksum_one;
}
for (int i = 0; i < packet.payload_length(); i++) {
checksum_one += packet.payload[i];
checksum_two += checksum_one;
}
return packet.checksum[0] == checksum_one && packet.checksum[1] == checksum_two;
}
AP_MicroStrain::DescriptorSet AP_MicroStrain::handle_packet(const MicroStrain_Packet& packet)
{
const DescriptorSet descriptor = packet.descriptor_set();
switch (descriptor) {
case DescriptorSet::IMUData:
handle_imu(packet);
break;
case DescriptorSet::FilterData:
handle_filter(packet);
break;
case DescriptorSet::BaseCommand:
case DescriptorSet::DMCommand:
case DescriptorSet::SystemCommand:
break;
case DescriptorSet::GNSSData:
case DescriptorSet::GNSSRecv1:
case DescriptorSet::GNSSRecv2:
handle_gnss(packet);
break;
}
return descriptor;
}
void AP_MicroStrain::handle_imu(const MicroStrain_Packet& packet)
{
last_imu_pkt = AP_HAL::millis();
// Iterate through fields of varying lengths in INS packet
for (uint8_t i = 0; i < packet.payload_length(); i += packet.payload[i]) {
switch ((INSPacketField) packet.payload[i+1]) {
// Scaled Ambient Pressure
case INSPacketField::PRESSURE: {
imu_data.pressure = be32tofloat_ptr(packet.payload, i+2) * 100; // Convert millibar to pascals
break;
}
// Scaled Magnetometer Vector
case INSPacketField::MAG: {
imu_data.mag = populate_vector3f(packet.payload, i+2) * 1000; // Convert gauss to milligauss
break;
}
// Scaled Accelerometer Vector
case INSPacketField::ACCEL: {
imu_data.accel = populate_vector3f(packet.payload, i+2) * GRAVITY_MSS; // Convert g's to m/s^2
break;
}
// Scaled Gyro Vector
case INSPacketField::GYRO: {
imu_data.gyro = populate_vector3f(packet.payload, i+2);
break;
}
// Quaternion
case INSPacketField::QUAT: {
imu_data.quat = populate_quaternion(packet.payload, i+2);
break;
}
}
}
}
void AP_MicroStrain::handle_gnss(const MicroStrain_Packet &packet)
{
last_gps_pkt = AP_HAL::millis();
uint8_t gnss_instance;
const DescriptorSet descriptor = DescriptorSet(packet.descriptor_set());
if (!get_gnss_instance(descriptor, gnss_instance)) {
return;
}
// Iterate through fields of varying lengths in GNSS packet
for (uint8_t i = 0; i < packet.payload_length(); i += packet.payload[i]) {
switch ((GNSSPacketField) packet.payload[i+1]) {
case GNSSPacketField::GPS_TIMESTAMP: {
gnss_data[gnss_instance].tow_ms = double_to_uint32(be64todouble_ptr(packet.payload, i+2) * 1000); // Convert seconds to ms
gnss_data[gnss_instance].week = be16toh_ptr(&packet.payload[i+10]);
break;
}
case GNSSPacketField::FIX_INFO: {
switch ((GNSSFixType) packet.payload[i+2]) {
case (GNSSFixType::FIX_RTK_FLOAT): {
gnss_data[gnss_instance].fix_type = GPS_FIX_TYPE_RTK_FLOAT;
break;
}
case (GNSSFixType::FIX_RTK_FIXED): {
gnss_data[gnss_instance].fix_type = GPS_FIX_TYPE_RTK_FIXED;
break;
}
case (GNSSFixType::FIX_3D): {
gnss_data[gnss_instance].fix_type = GPS_FIX_TYPE_3D_FIX;
break;
}
case (GNSSFixType::FIX_2D): {
gnss_data[gnss_instance].fix_type = GPS_FIX_TYPE_2D_FIX;
break;
}
case (GNSSFixType::TIME_ONLY):
case (GNSSFixType::NONE): {
gnss_data[gnss_instance].fix_type = GPS_FIX_TYPE_NO_FIX;
break;
}
default:
case (GNSSFixType::INVALID): {
gnss_data[gnss_instance].fix_type = GPS_FIX_TYPE_NO_GPS;
break;
}
}
gnss_data[gnss_instance].satellites = packet.payload[i+3];
break;
}
case GNSSPacketField::LLH_POSITION: {
gnss_data[gnss_instance].lat = be64todouble_ptr(packet.payload, i+2) * 1.0e7; // Decimal degrees to degrees
gnss_data[gnss_instance].lon = be64todouble_ptr(packet.payload, i+10) * 1.0e7;
gnss_data[gnss_instance].msl_altitude = be64todouble_ptr(packet.payload, i+26) * 1.0e2; // Meters to cm
gnss_data[gnss_instance].horizontal_position_accuracy = be32tofloat_ptr(packet.payload, i+34);
gnss_data[gnss_instance].vertical_position_accuracy = be32tofloat_ptr(packet.payload, i+38);
break;
}
case GNSSPacketField::DOP_DATA: {
gnss_data[gnss_instance].hdop = be32tofloat_ptr(packet.payload, i+10);
gnss_data[gnss_instance].vdop = be32tofloat_ptr(packet.payload, i+14);
break;
}
case GNSSPacketField::NED_VELOCITY: {
gnss_data[gnss_instance].ned_velocity_north = be32tofloat_ptr(packet.payload, i+2);
gnss_data[gnss_instance].ned_velocity_east = be32tofloat_ptr(packet.payload, i+6);
gnss_data[gnss_instance].ned_velocity_down = be32tofloat_ptr(packet.payload, i+10);
gnss_data[gnss_instance].speed_accuracy = be32tofloat_ptr(packet.payload, i+26);
break;
}
}
}
}
void AP_MicroStrain::handle_filter(const MicroStrain_Packet &packet)
{
last_filter_pkt = AP_HAL::millis();
// Iterate through fields of varying lengths in filter packet
for (uint8_t i = 0; i < packet.payload_length(); i += packet.payload[i]) {
switch ((FilterPacketField) packet.payload[i+1]) {
case FilterPacketField::GPS_TIMESTAMP: {
filter_data.tow_ms = be64todouble_ptr(packet.payload, i+2) * 1000; // Convert seconds to ms
filter_data.week = be16toh_ptr(&packet.payload[i+10]);
break;
}
case FilterPacketField::LLH_POSITION: {
filter_data.lat = be64todouble_ptr(packet.payload, i+2) * 1.0e7; // Decimal degrees to degrees
filter_data.lon = be64todouble_ptr(packet.payload, i+10) * 1.0e7;
filter_data.hae_altitude = be64todouble_ptr(packet.payload, i+26) * 1.0e2; // Meters to cm
break;
}
case FilterPacketField::NED_VELOCITY: {
filter_data.ned_velocity_north = be32tofloat_ptr(packet.payload, i+2);
filter_data.ned_velocity_east = be32tofloat_ptr(packet.payload, i+6);
filter_data.ned_velocity_down = be32tofloat_ptr(packet.payload, i+10);
break;
}
case FilterPacketField::FILTER_STATUS: {
filter_status.state = be16toh_ptr(&packet.payload[i+2]);
filter_status.mode = be16toh_ptr(&packet.payload[i+4]);
filter_status.flags = be16toh_ptr(&packet.payload[i+6]);
break;
}
}
}
}
Vector3f AP_MicroStrain::populate_vector3f(const uint8_t *data, uint8_t offset)
{
return Vector3f {
be32tofloat_ptr(data, offset),
be32tofloat_ptr(data, offset+4),
be32tofloat_ptr(data, offset+8)
};
}
Quaternion AP_MicroStrain::populate_quaternion(const uint8_t *data, uint8_t offset)
{
return Quaternion {
be32tofloat_ptr(data, offset),
be32tofloat_ptr(data, offset+4),
be32tofloat_ptr(data, offset+8),
be32tofloat_ptr(data, offset+12)
};
}
bool AP_MicroStrain::get_gnss_instance(const DescriptorSet& descriptor, uint8_t& instance){
bool success = false;
switch(descriptor) {
case DescriptorSet::GNSSData:
case DescriptorSet::GNSSRecv1:
instance = 0;
success = true;
break;
case DescriptorSet::GNSSRecv2:
instance = 1;
success = true;
break;
default:
break;
}
return success;
}
#endif // AP_MICROSTRAIN_ENABLED