ardupilot/libraries/AP_Hott_Telem/AP_Hott_Telem.cpp

445 lines
15 KiB
C++

/*
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 <http://www.gnu.org/licenses/>.
*/
/*
Graupner Hott Telemetry library
Hott telemetry runs at 19200 8N1 on a non-inverted half-duplex UART
With thanks to Graupner and betaflight
*/
#include "AP_Hott_Telem.h"
#if HAL_HOTT_TELEM_ENABLED
#include <AP_AHRS/AP_AHRS.h>
#include <AP_BattMonitor/AP_BattMonitor.h>
#include <AP_Baro/AP_Baro.h>
#include <AP_RPM/AP_RPM.h>
#include <AP_Airspeed/AP_Airspeed.h>
#include <AP_Stats/AP_Stats.h>
#include <AP_GPS/AP_GPS.h>
#include <AP_RTC/AP_RTC.h>
#include <AP_Notify/AP_Notify.h>
#include <AP_Mission/AP_Mission.h>
#include <AP_InertialSensor/AP_InertialSensor.h>
#include <stdio.h>
#define PROT_BINARY 0x80
#define PROT_ID_GAM 0x8D
#define PROT_ID_EAM 0x8E
#define PROT_ID_GPS 0x8A
#define PROT_ID_VARIO 0x89
#define BYTE_DELAY_FIRST_US 4000
#define BYTE_DELAY_US 1200
extern const AP_HAL::HAL& hal;
AP_Hott_Telem *AP_Hott_Telem::singleton;
AP_Hott_Telem::AP_Hott_Telem(void)
{
#if CONFIG_HAL_BOARD == HAL_BOARD_SITL
if (singleton != nullptr) {
AP_HAL::panic("AP_Hott_Telem must be singleton");
}
#endif
singleton = this;
}
/*
* initialise uart
*/
void AP_Hott_Telem::init()
{
const AP_SerialManager &serial_manager = AP::serialmanager();
uart = serial_manager.find_serial(AP_SerialManager::SerialProtocol_Hott, 0);
if (uart) {
// register thread
if (!hal.scheduler->thread_create(FUNCTOR_BIND_MEMBER(&AP_Hott_Telem::loop, void),
"Hott",
1024, AP_HAL::Scheduler::PRIORITY_BOOST, 1)) {
hal.console->printf("Failed to create Hott thread\n");
}
}
}
/*
send EAM (Electric Air Model)
*/
void AP_Hott_Telem::send_EAM(void)
{
// EAM message
struct PACKED {
uint8_t start_byte = 0x7C; //#01 start uint8_t
uint8_t eam_sensor_id = 0x8E;//#02 EAM sensort id. constat value 0x8e
uint8_t warning_beeps;
uint8_t sensor_id = 0xE0;
uint16_t alarms; //#05 alarm bitmask. Value is displayed inverted
uint8_t cell_low[7]; //#07 cell voltage lower value. 0.02V steps, 124=2.48V
uint8_t cell_high[7]; //#14 cell voltage high value. 0.02V steps, 124=2.48V
uint16_t batt1_voltage; //#21 battery 1 voltage in 100mv steps
uint16_t batt2_voltage; //#23 battery 2 voltage in 100mv steps
uint8_t temp1; //#25 Temperature sensor 1. 20=0C, 46=26C - offset of 20.
uint8_t temp2; //#26 temperature sensor 2
uint16_t altitude; //#27 Attitude unit: meters. Value of 500 = 0m
uint16_t current; //#29 Current in 0.1A steps
uint16_t main_voltage; //#31 Main power voltage (drive) in 0.1V steps
uint16_t batt_used; //#33 used battery capacity in 10mAh steps
uint16_t climbrate; //#35 climb rate in 0.01m/s. Value of 30000 = 0.00 m/s
uint8_t climbrate3s; //#37 climbrate in m/3sec. Value of 120 = 0m/3sec
uint16_t rpm; //#38 RPM. Steps: 10 rev/min
uint8_t electric_min; //#40 Electric minutes. Time starts when motor current is > 3 A
uint8_t electric_sec; //#41
uint16_t speed; //#42 speed in km/h. Steps 1km/h
uint8_t stop_byte = 0x7D; //#44 stop
} msg {};
const AP_BattMonitor &battery = AP::battery();
if (battery.num_instances() > 0) {
msg.batt1_voltage = uint16_t(battery.voltage(0) * 10);
}
if (battery.num_instances() > 1) {
msg.batt2_voltage = uint16_t(battery.voltage(1) * 10);
}
float current;
if (battery.current_amps(current)) {
msg.current = uint16_t(current * 10);
}
msg.main_voltage = uint16_t(battery.voltage() * 10);
float used_mah;
if (battery.consumed_mah(used_mah)) {
msg.batt_used = used_mah * 0.1;
}
const AP_Baro &baro = AP::baro();
msg.temp1 = uint8_t(baro.get_temperature(0) + 20.5);
#if BARO_MAX_INSTANCES > 1
if (baro.healthy(1)) {
msg.temp2 = uint8_t(baro.get_temperature(1) + 20.5);
}
#endif
AP_AHRS &ahrs = AP::ahrs();
float alt = 0;
Vector3f vel;
{
WITH_SEMAPHORE(ahrs.get_semaphore());
ahrs.get_relative_position_D_home(alt);
alt = -alt;
IGNORE_RETURN(ahrs.get_velocity_NED(vel));
}
msg.altitude = uint16_t(500.5 + alt);
msg.climbrate = uint16_t(30000.5 + vel.z * -100);
msg.climbrate3s = 120 + vel.z * -3;
const AP_RPM *rpm = AP::rpm();
float rpm_value;
if (rpm && rpm->get_rpm(0, rpm_value)) {
msg.rpm = rpm_value * 0.1;
}
AP_Stats *stats = AP::stats();
if (stats) {
uint32_t t = stats->get_flight_time_s();
msg.electric_min = t / 60U;
msg.electric_sec = t % 60U;
}
AP_Airspeed *airspeed = AP_Airspeed::get_singleton();
if (airspeed && airspeed->healthy()) {
msg.speed = uint16_t(airspeed->get_airspeed() * 3.6 + 0.5);
} else {
WITH_SEMAPHORE(ahrs.get_semaphore());
msg.speed = uint16_t(ahrs.groundspeed() * 3.6 + 0.5);
}
send_packet((const uint8_t *)&msg, sizeof(msg));
}
/*
convert from a GPS lat/lon in decimal degrees to degrees plus decimal minutes
*/
void AP_Hott_Telem::GPS_to_DDM(float decimal, uint8_t &sign, uint16_t &dm, uint16_t &sec) const
{
sign = decimal>=0?0:1;
decimal = fabsf(decimal);
uint8_t deg = uint16_t(decimal);
uint8_t min = uint16_t((decimal - deg) * 60);
dm = deg*100 + min;
sec = (decimal - (deg + min/60.0)) * 60 * 10000 + 0.5;
}
/*
send GPS packet
*/
void AP_Hott_Telem::send_GPS(void)
{
// GPS message
struct PACKED {
uint8_t start_byte = 0x7c; //#01 constant value 0x7c
uint8_t gps_sensor_id = 0x8a; //#02 constant value 0x8a
uint8_t warning_beeps; //#03
uint8_t sensor_id = 0xA0; //#04 constant (?) value 0xa0
uint16_t alarm; //#05
uint8_t flight_direction; //#07 flight direction in 2 degreees/step (1 = 2degrees);
uint16_t gps_speed_kmh; //#08 km/h
uint8_t pos_NS; //#10 north = 0, south = 1
uint16_t pos_NS_dm; //#11 degree minutes
uint16_t pos_NS_sec; //#13 position seconds
uint8_t pos_EW; //#15 east = 0, west = 1
uint16_t pos_EW_dm; //#16 degree minutes
uint16_t pos_EW_sec; //#18 position seconds
uint16_t home_distance; //#20 meters
uint16_t altitude; //#22 meters. Value of 500 = 0m
uint16_t climbrate; //#24 m/s 0.01m/s resolution. Value of 30000 = 0.00 m/s
uint8_t climbrate3s; //#26 climbrate in m/3s resolution, value of 120 = 0 m/3s
uint8_t gps_satelites; //#27 sat count
uint8_t gps_fix_char; //#28 GPS fix character. display, 'D' = DGPS, '2' = 2D, '3' = 3D, '-' = no fix
uint8_t home_direction; //#29 direction from starting point to Model position (2 degree steps)
int16_t vel_north; //#30 velocity north mm/s
uint8_t speed_acc; //#32 speed accuracy cm/s
uint8_t gps_time_h; //#33 UTC time hours
uint8_t gps_time_m; //#34 UTC time minutes
uint8_t gps_time_s; //#35 UTC time seconds
uint8_t gps_time_hs; //#36 UTC time 0.01s units
int16_t vel_east; //#37 velocity north mm/s
uint8_t horiz_acc; //#39 horizontal accuracy
uint8_t free_char1; //#40 displayed to right of home
uint8_t free_char2; //#41
uint8_t free_char3; //#42 GPS fix character. display, 'D' = DGPS, '2' = 2D, '3' = 3D, '-' = no fix
uint8_t version = 1; //#43 0: GPS Graupner #33600, 1: ArduPilot
uint8_t stop_byte = 0x7d; //#44
} msg {};
AP_GPS &gps = AP::gps();
Location loc;
{
WITH_SEMAPHORE(gps.get_semaphore());
loc = gps.location();
msg.flight_direction = uint16_t(gps.ground_course() * 0.5 + 0.5);
msg.gps_speed_kmh = uint16_t(gps.ground_speed() * 3.6 + 0.5);
float sacc, hacc;
if (gps.speed_accuracy(sacc)) {
msg.speed_acc = sacc * 100 + 0.5;
}
if (gps.horizontal_accuracy(hacc)) {
msg.horiz_acc = hacc * 100 + 0.5;
}
msg.gps_satelites = gps.num_sats();
}
float lat = loc.lat * 1.0e-7;
float lon = loc.lng * 1.0e-7;
uint16_t dm, sec;
GPS_to_DDM(lat, msg.pos_NS, dm, sec);
msg.pos_NS_dm = dm;
msg.pos_NS_sec = sec;
GPS_to_DDM(lon, msg.pos_EW, dm, sec);
msg.pos_EW_dm = dm;
msg.pos_EW_sec = sec;
AP_AHRS &ahrs = AP::ahrs();
Vector2f home_vec;
float alt = 0;
Vector3f vel;
{
WITH_SEMAPHORE(ahrs.get_semaphore());
if (ahrs.get_relative_position_NE_home(home_vec)) {
msg.home_distance = home_vec.length();
}
ahrs.get_relative_position_D_home(alt);
alt = -alt;
IGNORE_RETURN(ahrs.get_velocity_NED(vel));
}
msg.climbrate = uint16_t(30000.5 + vel.z * -100);
msg.climbrate3s = 120 + vel.z * -3;
msg.vel_north = vel.x * 1000 + 0.5;
msg.vel_east = vel.y * 1000 + 0.5;
msg.altitude = uint16_t(500.5 + alt);
msg.gps_fix_char = gps.status_onechar();
msg.free_char3 = msg.gps_fix_char;
msg.home_direction = degrees(atan2f(home_vec.y, home_vec.x)) * 0.5 + 0.5;
AP_RTC &rtc = AP::rtc();
{
WITH_SEMAPHORE(rtc.get_semaphore());
uint16_t ms;
rtc.get_system_clock_utc(msg.gps_time_h, msg.gps_time_m, msg.gps_time_s, ms);
}
send_packet((const uint8_t *)&msg, sizeof(msg));
}
/*
send Vario
*/
void AP_Hott_Telem::send_Vario(void)
{
// Vario message
struct PACKED {
uint8_t start_byte = 0x7C; //#01 start uint8_t
uint8_t vario_id = 0x89; //#02 ID
uint8_t warning_beeps; //#03 warnings
uint8_t sensor_id = 0x90; //#04 sensor ID
uint8_t inv_status; //#05 status
uint16_t altitude; //#06 Attitude meters. Value of 500 = 0m
uint16_t altitude_max; //#08 Attitude max meters. Value of 500 = 0m
uint16_t altitude_min; //#10 Attitude min meters. Value of 500 = 0m
uint16_t climbrate; //#12 climb rate in 0.01m/s. Value of 30000 = 0.00 m/s
uint16_t climbrate3s; //#14 climb rate in meters per 3s Value of 30000 = 0.00 m/s
uint16_t climbrate10s; //#16 climb rate in meters per 10s. Value of 30000 = 0.00 m/s
char text[3][7]; //#18 #Text display
char ascii3[3]; //#39 3 extra characters
uint8_t yaw; //#42 yaw in 2 degree units, 0 = north
uint8_t version = 1; //#43 protocol version
uint8_t stop_byte = 0x7D; //#44 stop
} msg {};
AP_AHRS &ahrs = AP::ahrs();
Vector3f vel;
float alt = 0;
{
WITH_SEMAPHORE(ahrs.get_semaphore());
ahrs.get_relative_position_D_home(alt);
alt = -alt;
IGNORE_RETURN(ahrs.get_velocity_NED(vel));
msg.yaw = wrap_360_cd(ahrs.yaw_sensor) * 0.005;
}
min_alt = MIN(alt, min_alt);
max_alt = MAX(alt, max_alt);
msg.altitude = uint16_t(500.5 + alt);
msg.altitude_max = uint16_t(500.5 + max_alt);
msg.altitude_min = uint16_t(500.5 + min_alt);
msg.climbrate = 30000.5 + vel.z * -100;
msg.climbrate3s = 30000.5 + vel.z * -100*3;
msg.climbrate10s = 30000.5 + vel.z * -100*10;
AP_Notify *notify = AP_Notify::get_singleton();
char fltmode[5] {};
if (notify) {
strncpy(fltmode, notify->get_flight_mode_str(), sizeof(fltmode));
strncpy(msg.text[0], fltmode, sizeof(msg.text[0]));
}
if (hal.util->get_soft_armed()) {
strncpy(msg.text[1], "ARMED", sizeof(msg.text[1]));
if (strncmp(fltmode, "AUTO", sizeof(fltmode)) == 0) {
const AP_Mission *mission = AP::mission();
if (mission) {
char wp[10] {};
snprintf(wp, sizeof(wp), "WP %3u", mission->get_current_nav_index());
memcpy(msg.text[2], wp, sizeof(msg.text[2]));
}
}
} else {
strncpy(msg.text[1], "DISARM", sizeof(msg.text[1]));
const char *ck = AP_Notify::flags.pre_arm_check ? "CK:PASS" : "CK:FAIL";
memcpy(msg.text[2], ck, MIN(strlen(ck), sizeof(msg.text[2])));
}
send_packet((const uint8_t *)&msg, sizeof(msg));
}
/*
send a packet out
*/
void AP_Hott_Telem::send_packet(const uint8_t *b, uint8_t len)
{
// initial delay
hal.scheduler->delay_microseconds(BYTE_DELAY_FIRST_US);
uint8_t crc = 0;
while (len) {
uint8_t ob = *b;
if (uart->write(ob) == 1) {
len--;
crc += ob;
b++;
hal.scheduler->delay_microseconds(BYTE_DELAY_US);
} else {
hal.scheduler->delay_microseconds(100);
}
}
uart->write(crc);
// discard any bytes received during the send
hal.scheduler->delay_microseconds(BYTE_DELAY_US*2);
while (uart->available() != 0) {
uart->read();
hal.scheduler->delay_microseconds(100);
}
}
/*
thread to process requests
*/
void AP_Hott_Telem::loop(void)
{
uart->begin(19200, 10, 10);
uart->set_unbuffered_writes(true);
uart->set_blocking_writes(true);
while (true) {
hal.scheduler->delay_microseconds(1500);
uint32_t n = uart->available();
if (n < 2) {
// wait for 2 bytes
continue;
}
if (n > 2) {
uart->discard_input();
continue;
}
const uint8_t prot_type = uart->read();
const uint8_t sensor_id = uart->read();
if (prot_type != PROT_BINARY) {
// only do binary protocol for now
continue;
}
switch (sensor_id) {
case PROT_ID_EAM:
send_EAM();
break;
case PROT_ID_GPS:
send_GPS();
break;
case PROT_ID_VARIO:
send_Vario();
break;
}
}
}
namespace AP {
AP_Hott_Telem *hott_telem() {
return AP_Hott_Telem::get_singleton();
}
};
#endif // HAL_HOTT_TELEM_ENABLED