Merged master

This commit is contained in:
Lorenz Meier
2013-08-18 12:04:07 +02:00
28 changed files with 638 additions and 297 deletions
+10 -7
View File
@@ -23,10 +23,13 @@ Firmware.sublime-workspace
Images/*.bin
Images/*.px4
mavlink/include/mavlink/v0.9/
NuttX
nuttx-configs/px4io-v2/src/.depend
nuttx-configs/px4io-v2/src/Make.dep
nuttx-configs/px4io-v2/src/libboard.a
nuttx-configs/px4io-v1/src/.depend
nuttx-configs/px4io-v1/src/Make.dep
nuttx-configs/px4io-v1/src/libboard.a
/nuttx-configs/px4io-v2/src/.depend
/nuttx-configs/px4io-v2/src/Make.dep
/nuttx-configs/px4io-v2/src/libboard.a
/nuttx-configs/px4io-v1/src/.depend
/nuttx-configs/px4io-v1/src/Make.dep
/nuttx-configs/px4io-v1/src/libboard.a
/NuttX
/Documentation/doxy.log
/Documentation/html/
/Documentation/doxygen*objdb*tmp
+6 -7
View File
@@ -429,19 +429,19 @@ SORT_BY_SCOPE_NAME = NO
# disable (NO) the todo list. This list is created by putting \todo
# commands in the documentation.
GENERATE_TODOLIST = YES
GENERATE_TODOLIST = NO
# The GENERATE_TESTLIST tag can be used to enable (YES) or
# disable (NO) the test list. This list is created by putting \test
# commands in the documentation.
GENERATE_TESTLIST = YES
GENERATE_TESTLIST = NO
# The GENERATE_BUGLIST tag can be used to enable (YES) or
# disable (NO) the bug list. This list is created by putting \bug
# commands in the documentation.
GENERATE_BUGLIST = YES
GENERATE_BUGLIST = NO
# The GENERATE_DEPRECATEDLIST tag can be used to enable (YES) or
# disable (NO) the deprecated list. This list is created by putting
@@ -569,7 +569,7 @@ WARN_LOGFILE = doxy.log
# directories like "/usr/src/myproject". Separate the files or directories
# with spaces.
INPUT = ../apps
INPUT = ../src
# This tag can be used to specify the character encoding of the source files
# that doxygen parses. Internally doxygen uses the UTF-8 encoding, which is
@@ -599,9 +599,8 @@ RECURSIVE = YES
# excluded from the INPUT source files. This way you can easily exclude a
# subdirectory from a directory tree whose root is specified with the INPUT tag.
EXCLUDE = ../dist/ \
../docs/html/ \
html
EXCLUDE = ../src/modules/mathlib/CMSIS \
../src/modules/attitude_estimator_ekf/codegen
# The EXCLUDE_SYMLINKS tag can be used select whether or not files or
# directories that are symbolic links (a Unix filesystem feature) are excluded
+1 -1
View File
@@ -268,7 +268,7 @@ CONFIG_USART2_RXDMA=y
# CONFIG_USART3_RXDMA is not set
# CONFIG_UART4_RXDMA is not set
# CONFIG_UART5_RS485 is not set
CONFIG_UART5_RXDMA=y
CONFIG_UART5_RXDMA=n
# CONFIG_USART6_RS485 is not set
CONFIG_USART6_RXDMA=y
# CONFIG_USART7_RXDMA is not set
+51 -4
View File
@@ -71,6 +71,12 @@
#endif
static const int ERROR = -1;
/* Orientation on board */
#define SENSOR_BOARD_ROTATION_000_DEG 0
#define SENSOR_BOARD_ROTATION_090_DEG 1
#define SENSOR_BOARD_ROTATION_180_DEG 2
#define SENSOR_BOARD_ROTATION_270_DEG 3
/* SPI protocol address bits */
#define DIR_READ (1<<7)
#define DIR_WRITE (0<<7)
@@ -186,6 +192,7 @@ private:
unsigned _current_rate;
unsigned _current_range;
unsigned _orientation;
perf_counter_t _sample_perf;
@@ -283,6 +290,7 @@ L3GD20::L3GD20(int bus, const char* path, spi_dev_e device) :
_gyro_topic(-1),
_current_rate(0),
_current_range(0),
_orientation(SENSOR_BOARD_ROTATION_270_DEG),
_sample_perf(perf_alloc(PC_ELAPSED, "l3gd20_read")),
_gyro_filter_x(250, 30),
_gyro_filter_y(250, 30),
@@ -363,8 +371,23 @@ L3GD20::probe()
(void)read_reg(ADDR_WHO_AM_I);
/* verify that the device is attached and functioning, accept L3GD20 and L3GD20H */
if (read_reg(ADDR_WHO_AM_I) == WHO_I_AM || read_reg(ADDR_WHO_AM_I) == WHO_I_AM_H)
if (read_reg(ADDR_WHO_AM_I) == WHO_I_AM) {
#ifdef CONFIG_ARCH_BOARD_PX4FMU_V1
_orientation = SENSOR_BOARD_ROTATION_270_DEG;
#elif CONFIG_ARCH_BOARD_PX4FMU_V2
_orientation = SENSOR_BOARD_ROTATION_270_DEG;
#else
#error This driver needs a board selection, either CONFIG_ARCH_BOARD_PX4FMU_V1 or CONFIG_ARCH_BOARD_PX4FMU_V2
#endif
return OK;
}
if (read_reg(ADDR_WHO_AM_I) == WHO_I_AM_H) {
_orientation = SENSOR_BOARD_ROTATION_180_DEG;
return OK;
}
return -EIO;
}
@@ -717,9 +740,33 @@ L3GD20::measure()
*/
report->timestamp = hrt_absolute_time();
/* swap x and y and negate y */
report->x_raw = raw_report.y;
report->y_raw = ((raw_report.x == -32768) ? 32767 : -raw_report.x);
switch (_orientation) {
case SENSOR_BOARD_ROTATION_000_DEG:
/* keep axes in place */
report->x_raw = raw_report.x;
report->y_raw = raw_report.y;
break;
case SENSOR_BOARD_ROTATION_090_DEG:
/* swap x and y */
report->x_raw = raw_report.y;
report->y_raw = raw_report.x;
break;
case SENSOR_BOARD_ROTATION_180_DEG:
/* swap x and y and negate both */
report->x_raw = ((raw_report.x == -32768) ? 32767 : -raw_report.x);
report->y_raw = ((raw_report.y == -32768) ? 32767 : -raw_report.y);
break;
case SENSOR_BOARD_ROTATION_270_DEG:
/* swap x and y and negate y */
report->x_raw = raw_report.y;
report->y_raw = ((raw_report.x == -32768) ? 32767 : -raw_report.x);
break;
}
report->z_raw = raw_report.z;
report->x = ((report->x_raw * _gyro_range_scale) - _gyro_scale.x_offset) * _gyro_scale.x_scale;
+87 -48
View File
@@ -94,21 +94,62 @@ extern device::Device *PX4IO_serial_interface() weak_function;
#define PX4IO_SET_DEBUG _IOC(0xff00, 0)
#define PX4IO_INAIR_RESTART_ENABLE _IOC(0xff00, 1)
/**
* The PX4IO class.
*
* Encapsulates PX4FMU to PX4IO communications modeled as file operations.
*/
class PX4IO : public device::CDev
{
public:
/**
* Constructor.
*
* Initialize all class variables.
*/
PX4IO(device::Device *interface);
/**
* Destructor.
*
* Wait for worker thread to terminate.
*/
virtual ~PX4IO();
/**
* Initialize the PX4IO class.
*
* Initialize the physical I2C interface to PX4IO. Retrieve relevant initial system parameters. Initialize PX4IO registers.
*/
virtual int init();
/**
* IO Control handler.
*
* Handle all IOCTL calls to the PX4IO file descriptor.
*
* @param[in] filp file handle (not used). This function is always called directly through object reference
* @param[in] cmd the IOCTL command
* @param[in] the IOCTL command parameter (optional)
*/
virtual int ioctl(file *filp, int cmd, unsigned long arg);
/**
* write handler.
*
* Handle writes to the PX4IO file descriptor.
*
* @param[in] filp file handle (not used). This function is always called directly through object reference
* @param[in] buffer pointer to the data buffer to be written
* @param[in] len size in bytes to be written
* @return number of bytes written
*/
virtual ssize_t write(file *filp, const char *buffer, size_t len);
/**
* Set the update rate for actuator outputs from FMU to IO.
*
* @param rate The rate in Hz actuator outpus are sent to IO.
* @param[in] rate The rate in Hz actuator outpus are sent to IO.
* Min 10 Hz, max 400 Hz
*/
int set_update_rate(int rate);
@@ -116,16 +157,16 @@ public:
/**
* Set the battery current scaling and bias
*
* @param amp_per_volt
* @param amp_bias
* @param[in] amp_per_volt
* @param[in] amp_bias
*/
void set_battery_current_scaling(float amp_per_volt, float amp_bias);
/**
* Push failsafe values to IO.
*
* @param vals Failsafe control inputs: in us PPM (900 for zero, 1500 for centered, 2100 for full)
* @param len Number of channels, could up to 8
* @param[in] vals Failsafe control inputs: in us PPM (900 for zero, 1500 for centered, 2100 for full)
* @param[in] len Number of channels, could up to 8
*/
int set_failsafe_values(const uint16_t *vals, unsigned len);
@@ -149,11 +190,21 @@ public:
*/
void print_status();
/**
* Set the DSM VCC is controlled by relay one flag
*
* @param[in] enable true=DSM satellite VCC is controlled by relay1, false=DSM satellite VCC not controlled
*/
inline void set_dsm_vcc_ctl(bool enable)
{
_dsm_vcc_ctl = enable;
};
/**
* Get the DSM VCC is controlled by relay one flag
*
* @return true=DSM satellite VCC is controlled by relay1, false=DSM satellite VCC not controlled
*/
inline bool get_dsm_vcc_ctl()
{
return _dsm_vcc_ctl;
@@ -163,60 +214,50 @@ private:
device::Device *_interface;
// XXX
unsigned _hardware;
unsigned _max_actuators;
unsigned _max_controls;
unsigned _max_rc_input;
unsigned _max_relays;
unsigned _max_transfer;
unsigned _hardware; ///< Hardware revision
unsigned _max_actuators; ///<Maximum # of actuators supported by PX4IO
unsigned _max_controls; ///<Maximum # of controls supported by PX4IO
unsigned _max_rc_input; ///<Maximum receiver channels supported by PX4IO
unsigned _max_relays; ///<Maximum relays supported by PX4IO
unsigned _max_transfer; ///<Maximum number of I2C transfers supported by PX4IO
unsigned _update_interval; ///< subscription interval limiting send rate
unsigned _update_interval; ///<Subscription interval limiting send rate
volatile int _task; ///< worker task
volatile bool _task_should_exit;
volatile int _task; ///<worker task id
volatile bool _task_should_exit; ///<worker terminate flag
int _mavlink_fd;
int _mavlink_fd; ///<mavlink file descriptor
perf_counter_t _perf_update;
perf_counter_t _perf_update; ///<local performance counter
/* cached IO state */
uint16_t _status;
uint16_t _alarms;
uint16_t _status; ///<Various IO status flags
uint16_t _alarms; ///<Various IO alarms
/* subscribed topics */
int _t_actuators; ///< actuator controls topic
int _t_actuator_armed; ///< system armed control topic
int _t_vehicle_control_mode; ///< vehicle control mode topic
int _t_param; ///< parameter update topic
int _t_param; ///<parameter update topic
/* advertised topics */
orb_advert_t _to_input_rc; ///< rc inputs from io
orb_advert_t _to_actuators_effective; ///< effective actuator controls topic
orb_advert_t _to_outputs; ///< mixed servo outputs topic
orb_advert_t _to_battery; ///< battery status / voltage
orb_advert_t _to_safety; ///< status of safety
orb_advert_t _to_input_rc; ///<rc inputs from IO topic
orb_advert_t _to_actuators_effective; ///<effective actuator controls topic
orb_advert_t _to_outputs; ///<mixed servo outputs topic
orb_advert_t _to_battery; ///<battery status / voltage topic
orb_advert_t _to_safety; ///< status of safety
actuator_outputs_s _outputs; ///< mixed outputs
actuator_controls_effective_s _controls_effective; ///< effective controls
actuator_outputs_s _outputs; ///<mixed outputs
actuator_controls_effective_s _controls_effective; ///<effective controls
bool _primary_pwm_device; ///< true if we are the default PWM output
bool _primary_pwm_device; ///<true if we are the default PWM output
float _battery_amp_per_volt;
float _battery_amp_bias;
float _battery_mamphour_total;
uint64_t _battery_last_timestamp;
float _battery_amp_per_volt; ///<current sensor amps/volt
float _battery_amp_bias; ///<current sensor bias
float _battery_mamphour_total;///<amp hours consumed so far
uint64_t _battery_last_timestamp;///<last amp hour calculation timestamp
/**
* Relay1 is dedicated to controlling DSM receiver power
*/
bool _dsm_vcc_ctl;
/**
* System armed
*/
bool _system_armed;
bool _dsm_vcc_ctl; ///<true if relay 1 controls DSM satellite RX power
/**
* Trampoline to the worker task
@@ -388,8 +429,7 @@ PX4IO::PX4IO(device::Device *interface) :
_battery_amp_bias(0),
_battery_mamphour_total(0),
_battery_last_timestamp(0),
_dsm_vcc_ctl(false),
_system_armed(false)
_dsm_vcc_ctl(false)
{
/* we need this potentially before it could be set in task_main */
g_dev = this;
@@ -732,7 +772,7 @@ PX4IO::task_main()
// See if bind parameter has been set, and reset it to 0
param_get(dsm_bind_param = param_find("RC_DSM_BIND"), &dsm_bind_val);
if (dsm_bind_val) {
if (!_system_armed) {
if (!(_status & PX4IO_P_STATUS_FLAGS_OUTPUTS_ARMED)) {
if ((dsm_bind_val == 1) || (dsm_bind_val == 2)) {
mavlink_log_info(mavlink_fd, "[IO] binding dsm%c rx", dsm_bind_val == 1 ? '2' : 'x');
ioctl(nullptr, DSM_BIND_START, dsm_bind_val == 1 ? 3 : 7);
@@ -853,8 +893,6 @@ PX4IO::io_set_arming_state()
uint16_t set = 0;
uint16_t clear = 0;
_system_armed = armed.armed;
if (armed.armed && !armed.lockdown) {
set |= PX4IO_P_SETUP_ARMING_FMU_ARMED;
} else {
@@ -1731,7 +1769,8 @@ PX4IO::ioctl(file * /*filep*/, int cmd, unsigned long arg)
}
ssize_t
PX4IO::write(file *filp, const char *buffer, size_t len)
PX4IO::write(file * /*filp*/, const char *buffer, size_t len)
/* Make it obvious that file * isn't used here */
{
unsigned count = len / 2;
+5 -5
View File
@@ -456,7 +456,8 @@ rgbled_main(int argc, char *argv[])
int rgbledadr = ADDR; /* 7bit */
int ch;
while ((ch = getopt(argc, argv, "a:b:")) != EOF) {
/* jump over start/off/etc and look at options first */
while ((ch = getopt(argc-1, &argv[1], "a:b:")) != EOF) {
switch (ch) {
case 'a':
rgbledadr = strtol(optarg, NULL, 0);
@@ -468,9 +469,8 @@ rgbled_main(int argc, char *argv[])
rgbled_usage();
}
}
argc -= optind;
argv += optind;
const char *verb = argv[0];
const char *verb = argv[1];
int fd;
int ret;
@@ -549,7 +549,7 @@ rgbled_main(int argc, char *argv[])
if (fd == -1) {
errx(1, "Unable to open " RGBLED_DEVICE_PATH);
}
if (argc < 4) {
if (argc < 5) {
errx(1, "Usage: rgbled rgb <red> <green> <blue>");
}
rgbled_rgbset_t v;
+236 -172
View File
@@ -48,161 +48,44 @@
#include <drivers/drv_hrt.h>
#define DEBUG
#include "px4io.h"
#define DSM_FRAME_SIZE 16
#define DSM_FRAME_CHANNELS 7
#define DSM_FRAME_SIZE 16 /**<DSM frame size in bytes*/
#define DSM_FRAME_CHANNELS 7 /**<Max supported DSM channels*/
static int dsm_fd = -1;
static hrt_abstime last_rx_time;
static hrt_abstime last_frame_time;
static uint8_t frame[DSM_FRAME_SIZE];
static unsigned partial_frame_count;
static unsigned channel_shift;
unsigned dsm_frame_drops;
static bool dsm_decode_channel(uint16_t raw, unsigned shift, unsigned *channel, unsigned *value);
static void dsm_guess_format(bool reset);
static bool dsm_decode(hrt_abstime now, uint16_t *values, uint16_t *num_values);
int
dsm_init(const char *device)
{
if (dsm_fd < 0)
dsm_fd = open(device, O_RDONLY | O_NONBLOCK);
if (dsm_fd >= 0) {
struct termios t;
/* 115200bps, no parity, one stop bit */
tcgetattr(dsm_fd, &t);
cfsetspeed(&t, 115200);
t.c_cflag &= ~(CSTOPB | PARENB);
tcsetattr(dsm_fd, TCSANOW, &t);
/* initialise the decoder */
partial_frame_count = 0;
last_rx_time = hrt_absolute_time();
/* reset the format detector */
dsm_guess_format(true);
debug("DSM: ready");
} else {
debug("DSM: open failed");
}
return dsm_fd;
}
void
dsm_bind(uint16_t cmd, int pulses)
{
const uint32_t usart1RxAsOutp = GPIO_OUTPUT|GPIO_CNF_OUTPP|GPIO_MODE_50MHz|GPIO_OUTPUT_SET|GPIO_PORTA|GPIO_PIN10;
if (dsm_fd < 0)
return;
#ifdef CONFIG_ARCH_BOARD_PX4IO_V2
// XXX implement
#warning DSM BIND NOT IMPLEMENTED ON PX4IO V2
#else
switch (cmd) {
case dsm_bind_power_down:
// power down DSM satellite
POWER_RELAY1(0);
break;
case dsm_bind_power_up:
POWER_RELAY1(1);
dsm_guess_format(true);
break;
case dsm_bind_set_rx_out:
stm32_configgpio(usart1RxAsOutp);
break;
case dsm_bind_send_pulses:
for (int i = 0; i < pulses; i++) {
stm32_gpiowrite(usart1RxAsOutp, false);
up_udelay(25);
stm32_gpiowrite(usart1RxAsOutp, true);
up_udelay(25);
}
break;
case dsm_bind_reinit_uart:
// Restore USART rx pin
stm32_configgpio(GPIO_USART1_RX);
break;
}
#endif
}
bool
dsm_input(uint16_t *values, uint16_t *num_values)
{
ssize_t ret;
hrt_abstime now;
/*
* The DSM* protocol doesn't provide any explicit framing,
* so we detect frame boundaries by the inter-frame delay.
*
* The minimum frame spacing is 11ms; with 16 bytes at 115200bps
* frame transmission time is ~1.4ms.
*
* We expect to only be called when bytes arrive for processing,
* and if an interval of more than 5ms passes between calls,
* the first byte we read will be the first byte of a frame.
*
* In the case where byte(s) are dropped from a frame, this also
* provides a degree of protection. Of course, it would be better
* if we didn't drop bytes...
*/
now = hrt_absolute_time();
if ((now - last_rx_time) > 5000) {
if (partial_frame_count > 0) {
dsm_frame_drops++;
partial_frame_count = 0;
}
}
/*
* Fetch bytes, but no more than we would need to complete
* the current frame.
*/
ret = read(dsm_fd, &frame[partial_frame_count], DSM_FRAME_SIZE - partial_frame_count);
/* if the read failed for any reason, just give up here */
if (ret < 1)
return false;
last_rx_time = now;
/*
* Add bytes to the current frame
*/
partial_frame_count += ret;
/*
* If we don't have a full frame, return
*/
if (partial_frame_count < DSM_FRAME_SIZE)
return false;
/*
* Great, it looks like we might have a frame. Go ahead and
* decode it.
*/
partial_frame_count = 0;
return dsm_decode(now, values, num_values);
}
static int dsm_fd = -1; /**< File handle to the DSM UART */
static hrt_abstime dsm_last_rx_time; /**< Timestamp when we last received */
static hrt_abstime dsm_last_frame_time; /**< Timestamp for start of last dsm frame */
static uint8_t dsm_frame[DSM_FRAME_SIZE]; /**< DSM dsm frame receive buffer */
static unsigned dsm_partial_frame_count; /**< Count of bytes received for current dsm frame */
static unsigned dsm_channel_shift; /**< Channel resolution, 0=unknown, 1=10 bit, 2=11 bit */
static unsigned dsm_frame_drops; /**< Count of incomplete DSM frames */
/**
* Attempt to decode a single channel raw channel datum
*
* The DSM* protocol doesn't provide any explicit framing,
* so we detect dsm frame boundaries by the inter-dsm frame delay.
*
* The minimum dsm frame spacing is 11ms; with 16 bytes at 115200bps
* dsm frame transmission time is ~1.4ms.
*
* We expect to only be called when bytes arrive for processing,
* and if an interval of more than 5ms passes between calls,
* the first byte we read will be the first byte of a dsm frame.
*
* In the case where byte(s) are dropped from a dsm frame, this also
* provides a degree of protection. Of course, it would be better
* if we didn't drop bytes...
*
* Upon receiving a full dsm frame we attempt to decode it
*
* @param[in] raw 16 bit raw channel value from dsm frame
* @param[in] shift position of channel number in raw data
* @param[out] channel pointer to returned channel number
* @param[out] value pointer to returned channel value
* @return true=raw value successfully decoded
*/
static bool
dsm_decode_channel(uint16_t raw, unsigned shift, unsigned *channel, unsigned *value)
{
@@ -220,6 +103,11 @@ dsm_decode_channel(uint16_t raw, unsigned shift, unsigned *channel, unsigned *va
return true;
}
/**
* Attempt to guess if receiving 10 or 11 bit channel values
*
* @param[in] reset true=reset the 10/11 bit state to unknown
*/
static void
dsm_guess_format(bool reset)
{
@@ -232,14 +120,14 @@ dsm_guess_format(bool reset)
cs10 = 0;
cs11 = 0;
samples = 0;
channel_shift = 0;
dsm_channel_shift = 0;
return;
}
/* scan the channels in the current frame in both 10- and 11-bit mode */
/* scan the channels in the current dsm_frame in both 10- and 11-bit mode */
for (unsigned i = 0; i < DSM_FRAME_CHANNELS; i++) {
uint8_t *dp = &frame[2 + (2 * i)];
uint8_t *dp = &dsm_frame[2 + (2 * i)];
uint16_t raw = (dp[0] << 8) | dp[1];
unsigned channel, value;
@@ -250,10 +138,10 @@ dsm_guess_format(bool reset)
if (dsm_decode_channel(raw, 11, &channel, &value) && (channel < 31))
cs11 |= (1 << channel);
/* XXX if we cared, we could look for the phase bit here to decide 1 vs. 2-frame format */
/* XXX if we cared, we could look for the phase bit here to decide 1 vs. 2-dsm_frame format */
}
/* wait until we have seen plenty of frames - 2 should normally be enough */
/* wait until we have seen plenty of frames - 5 should normally be enough */
if (samples++ < 5)
return;
@@ -289,13 +177,13 @@ dsm_guess_format(bool reset)
}
if ((votes11 == 1) && (votes10 == 0)) {
channel_shift = 11;
dsm_channel_shift = 11;
debug("DSM: 11-bit format");
return;
}
if ((votes10 == 1) && (votes11 == 0)) {
channel_shift = 10;
dsm_channel_shift = 10;
debug("DSM: 10-bit format");
return;
}
@@ -305,27 +193,136 @@ dsm_guess_format(bool reset)
dsm_guess_format(true);
}
/**
* Initialize the DSM receive functionality
*
* Open the UART for receiving DSM frames and configure it appropriately
*
* @param[in] device Device name of DSM UART
*/
int
dsm_init(const char *device)
{
if (dsm_fd < 0)
dsm_fd = open(device, O_RDONLY | O_NONBLOCK);
if (dsm_fd >= 0) {
struct termios t;
/* 115200bps, no parity, one stop bit */
tcgetattr(dsm_fd, &t);
cfsetspeed(&t, 115200);
t.c_cflag &= ~(CSTOPB | PARENB);
tcsetattr(dsm_fd, TCSANOW, &t);
/* initialise the decoder */
dsm_partial_frame_count = 0;
dsm_last_rx_time = hrt_absolute_time();
/* reset the format detector */
dsm_guess_format(true);
debug("DSM: ready");
} else {
debug("DSM: open failed");
}
return dsm_fd;
}
/**
* Handle DSM satellite receiver bind mode handler
*
* @param[in] cmd commands - dsm_bind_power_down, dsm_bind_power_up, dsm_bind_set_rx_out, dsm_bind_send_pulses, dsm_bind_reinit_uart
* @param[in] pulses Number of pulses for dsm_bind_send_pulses command
*/
void
dsm_bind(uint16_t cmd, int pulses)
{
const uint32_t usart1RxAsOutp =
GPIO_OUTPUT | GPIO_CNF_OUTPP | GPIO_MODE_50MHz | GPIO_OUTPUT_SET | GPIO_PORTA | GPIO_PIN10;
if (dsm_fd < 0)
return;
#ifdef CONFIG_ARCH_BOARD_PX4IO_V2
// XXX implement
#warning DSM BIND NOT IMPLEMENTED ON PX4IO V2
#else
switch (cmd) {
case dsm_bind_power_down:
/*power down DSM satellite*/
POWER_RELAY1(0);
break;
case dsm_bind_power_up:
/*power up DSM satellite*/
POWER_RELAY1(1);
dsm_guess_format(true);
break;
case dsm_bind_set_rx_out:
/*Set UART RX pin to active output mode*/
stm32_configgpio(usart1RxAsOutp);
break;
case dsm_bind_send_pulses:
/*Pulse RX pin a number of times*/
for (int i = 0; i < pulses; i++) {
stm32_gpiowrite(usart1RxAsOutp, false);
up_udelay(25);
stm32_gpiowrite(usart1RxAsOutp, true);
up_udelay(25);
}
break;
case dsm_bind_reinit_uart:
/*Restore USART RX pin to RS232 receive mode*/
stm32_configgpio(GPIO_USART1_RX);
break;
}
#endif
}
/**
* Decode the entire dsm frame (all contained channels)
*
* @param[in] frame_time timestamp when this dsm frame was received. Used to detect RX loss in order to reset 10/11 bit guess.
* @param[out] values pointer to per channel array of decoded values
* @param[out] num_values pointer to number of raw channel values returned
* @return true=DSM frame successfully decoded, false=no update
*/
static bool
dsm_decode(hrt_abstime frame_time, uint16_t *values, uint16_t *num_values)
{
/*
debug("DSM frame %02x%02x %02x%02x %02x%02x %02x%02x %02x%02x %02x%02x %02x%02x %02x%02x",
frame[0], frame[1], frame[2], frame[3], frame[4], frame[5], frame[6], frame[7],
frame[8], frame[9], frame[10], frame[11], frame[12], frame[13], frame[14], frame[15]);
debug("DSM dsm_frame %02x%02x %02x%02x %02x%02x %02x%02x %02x%02x %02x%02x %02x%02x %02x%02x",
dsm_frame[0], dsm_frame[1], dsm_frame[2], dsm_frame[3], dsm_frame[4], dsm_frame[5], dsm_frame[6], dsm_frame[7],
dsm_frame[8], dsm_frame[9], dsm_frame[10], dsm_frame[11], dsm_frame[12], dsm_frame[13], dsm_frame[14], dsm_frame[15]);
*/
/*
* If we have lost signal for at least a second, reset the
* format guessing heuristic.
*/
if (((frame_time - last_frame_time) > 1000000) && (channel_shift != 0))
if (((frame_time - dsm_last_frame_time) > 1000000) && (dsm_channel_shift != 0))
dsm_guess_format(true);
/* we have received something we think is a frame */
last_frame_time = frame_time;
/* we have received something we think is a dsm_frame */
dsm_last_frame_time = frame_time;
/* if we don't know the frame format, update the guessing state machine */
if (channel_shift == 0) {
/* if we don't know the dsm_frame format, update the guessing state machine */
if (dsm_channel_shift == 0) {
dsm_guess_format(false);
return false;
}
@@ -337,17 +334,17 @@ dsm_decode(hrt_abstime frame_time, uint16_t *values, uint16_t *num_values)
* Each channel is a 16-bit unsigned value containing either a 10-
* or 11-bit channel value and a 4-bit channel number, shifted
* either 10 or 11 bits. The MSB may also be set to indicate the
* second frame in variants of the protocol where more than
* second dsm_frame in variants of the protocol where more than
* seven channels are being transmitted.
*/
for (unsigned i = 0; i < DSM_FRAME_CHANNELS; i++) {
uint8_t *dp = &frame[2 + (2 * i)];
uint8_t *dp = &dsm_frame[2 + (2 * i)];
uint16_t raw = (dp[0] << 8) | dp[1];
unsigned channel, value;
if (!dsm_decode_channel(raw, channel_shift, &channel, &value))
if (!dsm_decode_channel(raw, dsm_channel_shift, &channel, &value))
continue;
/* ignore channels out of range */
@@ -359,7 +356,7 @@ dsm_decode(hrt_abstime frame_time, uint16_t *values, uint16_t *num_values)
*num_values = channel + 1;
/* convert 0-1024 / 0-2048 values to 1000-2000 ppm encoding in a very sloppy fashion */
if (channel_shift == 11)
if (dsm_channel_shift == 11)
value /= 2;
value += 998;
@@ -390,7 +387,7 @@ dsm_decode(hrt_abstime frame_time, uint16_t *values, uint16_t *num_values)
values[channel] = value;
}
if (channel_shift == 11)
if (dsm_channel_shift == 11)
*num_values |= 0x8000;
/*
@@ -398,3 +395,70 @@ dsm_decode(hrt_abstime frame_time, uint16_t *values, uint16_t *num_values)
*/
return true;
}
/**
* Called periodically to check for input data from the DSM UART
*
* The DSM* protocol doesn't provide any explicit framing,
* so we detect dsm frame boundaries by the inter-dsm frame delay.
* The minimum dsm frame spacing is 11ms; with 16 bytes at 115200bps
* dsm frame transmission time is ~1.4ms.
* We expect to only be called when bytes arrive for processing,
* and if an interval of more than 5ms passes between calls,
* the first byte we read will be the first byte of a dsm frame.
* In the case where byte(s) are dropped from a dsm frame, this also
* provides a degree of protection. Of course, it would be better
* if we didn't drop bytes...
* Upon receiving a full dsm frame we attempt to decode it.
*
* @param[out] values pointer to per channel array of decoded values
* @param[out] num_values pointer to number of raw channel values returned
* @return true=decoded raw channel values updated, false=no update
*/
bool
dsm_input(uint16_t *values, uint16_t *num_values)
{
ssize_t ret;
hrt_abstime now;
/*
*/
now = hrt_absolute_time();
if ((now - dsm_last_rx_time) > 5000) {
if (dsm_partial_frame_count > 0) {
dsm_frame_drops++;
dsm_partial_frame_count = 0;
}
}
/*
* Fetch bytes, but no more than we would need to complete
* the current dsm frame.
*/
ret = read(dsm_fd, &dsm_frame[dsm_partial_frame_count], DSM_FRAME_SIZE - dsm_partial_frame_count);
/* if the read failed for any reason, just give up here */
if (ret < 1)
return false;
dsm_last_rx_time = now;
/*
* Add bytes to the current dsm frame
*/
dsm_partial_frame_count += ret;
/*
* If we don't have a full dsm frame, return
*/
if (dsm_partial_frame_count < DSM_FRAME_SIZE)
return false;
/*
* Great, it looks like we might have a dsm frame. Go ahead and
* decode it.
*/
dsm_partial_frame_count = 0;
return dsm_decode(now, values, num_values);
}
+1 -1
View File
@@ -198,7 +198,7 @@ extern void controls_init(void);
extern void controls_tick(void);
extern int dsm_init(const char *device);
extern bool dsm_input(uint16_t *values, uint16_t *num_values);
extern void dsm_bind(uint16_t cmd, int pulses);
extern void dsm_bind(uint16_t cmd, int pulses);
extern int sbus_init(const char *device);
extern bool sbus_input(uint16_t *values, uint16_t *num_values);
+3
View File
@@ -70,6 +70,9 @@ PARAM_DEFINE_FLOAT(SENS_ACC_ZSCALE, 1.0f);
PARAM_DEFINE_FLOAT(SENS_DPRES_OFF, 0);
PARAM_DEFINE_INT32(SENS_BOARD_ROT, 0);
PARAM_DEFINE_INT32(SENS_EXT_MAG_ROT, 0);
PARAM_DEFINE_FLOAT(RC1_MIN, 1000.0f);
PARAM_DEFINE_FLOAT(RC1_TRIM, 1500.0f);
PARAM_DEFINE_FLOAT(RC1_MAX, 2000.0f);
+144 -15
View File
@@ -50,6 +50,7 @@
#include <stdio.h>
#include <errno.h>
#include <math.h>
#include <mathlib/mathlib.h>
#include <nuttx/analog/adc.h>
@@ -137,6 +138,77 @@
#define limit_minus_one_to_one(arg) (arg < -1.0f) ? -1.0f : ((arg > 1.0f) ? 1.0f : arg)
/**
* Enum for board and external compass rotations.
* This enum maps from board attitude to airframe attitude.
*/
enum Rotation {
ROTATION_NONE = 0,
ROTATION_YAW_45 = 1,
ROTATION_YAW_90 = 2,
ROTATION_YAW_135 = 3,
ROTATION_YAW_180 = 4,
ROTATION_YAW_225 = 5,
ROTATION_YAW_270 = 6,
ROTATION_YAW_315 = 7,
ROTATION_ROLL_180 = 8,
ROTATION_ROLL_180_YAW_45 = 9,
ROTATION_ROLL_180_YAW_90 = 10,
ROTATION_ROLL_180_YAW_135 = 11,
ROTATION_PITCH_180 = 12,
ROTATION_ROLL_180_YAW_225 = 13,
ROTATION_ROLL_180_YAW_270 = 14,
ROTATION_ROLL_180_YAW_315 = 15,
ROTATION_ROLL_90 = 16,
ROTATION_ROLL_90_YAW_45 = 17,
ROTATION_ROLL_90_YAW_90 = 18,
ROTATION_ROLL_90_YAW_135 = 19,
ROTATION_ROLL_270 = 20,
ROTATION_ROLL_270_YAW_45 = 21,
ROTATION_ROLL_270_YAW_90 = 22,
ROTATION_ROLL_270_YAW_135 = 23,
ROTATION_PITCH_90 = 24,
ROTATION_PITCH_270 = 25,
ROTATION_MAX
};
typedef struct
{
uint16_t roll;
uint16_t pitch;
uint16_t yaw;
} rot_lookup_t;
const rot_lookup_t rot_lookup[] =
{
{ 0, 0, 0 },
{ 0, 0, 45 },
{ 0, 0, 90 },
{ 0, 0, 135 },
{ 0, 0, 180 },
{ 0, 0, 225 },
{ 0, 0, 270 },
{ 0, 0, 315 },
{180, 0, 0 },
{180, 0, 45 },
{180, 0, 90 },
{180, 0, 135 },
{ 0, 180, 0 },
{180, 0, 225 },
{180, 0, 270 },
{180, 0, 315 },
{ 90, 0, 0 },
{ 90, 0, 45 },
{ 90, 0, 90 },
{ 90, 0, 135 },
{270, 0, 0 },
{270, 0, 45 },
{270, 0, 90 },
{270, 0, 135 },
{ 0, 90, 0 },
{ 0, 270, 0 }
};
/**
* Sensor app start / stop handling function
*
@@ -189,8 +261,8 @@ private:
int _mag_sub; /**< raw mag data subscription */
int _rc_sub; /**< raw rc channels data subscription */
int _baro_sub; /**< raw baro data subscription */
int _airspeed_sub; /**< airspeed subscription */
int _diff_pres_sub; /**< raw differential pressure subscription */
int _airspeed_sub; /**< airspeed subscription */
int _diff_pres_sub; /**< raw differential pressure subscription */
int _vcontrol_mode_sub; /**< vehicle control mode subscription */
int _params_sub; /**< notification of parameter updates */
int _manual_control_sub; /**< notification of manual control updates */
@@ -210,13 +282,15 @@ private:
struct differential_pressure_s _diff_pres;
struct airspeed_s _airspeed;
math::Matrix _board_rotation; /**< rotation matrix for the orientation that the board is mounted */
math::Matrix _external_mag_rotation; /**< rotation matrix for the orientation that an external mag is mounted */
struct {
float min[_rc_max_chan_count];
float trim[_rc_max_chan_count];
float max[_rc_max_chan_count];
float rev[_rc_max_chan_count];
float dz[_rc_max_chan_count];
// float ex[_rc_max_chan_count];
float scaling_factor[_rc_max_chan_count];
float gyro_offset[3];
@@ -227,6 +301,9 @@ private:
float accel_scale[3];
float diff_pres_offset_pa;
int board_rotation;
int external_mag_rotation;
int rc_type;
int rc_map_roll;
@@ -264,7 +341,6 @@ private:
param_t max[_rc_max_chan_count];
param_t rev[_rc_max_chan_count];
param_t dz[_rc_max_chan_count];
// param_t ex[_rc_max_chan_count];
param_t rc_type;
param_t rc_demix;
@@ -304,6 +380,9 @@ private:
param_t battery_voltage_scaling;
param_t board_rotation;
param_t external_mag_rotation;
} _parameter_handles; /**< handles for interesting parameters */
@@ -312,6 +391,11 @@ private:
*/
int parameters_update();
/**
* Get the rotation matrices
*/
void get_rot_matrix(enum Rotation rot, math::Matrix *rot_matrix);
/**
* Do accel-related initialisation.
*/
@@ -448,7 +532,10 @@ Sensors::Sensors() :
_diff_pres_pub(-1),
/* performance counters */
_loop_perf(perf_alloc(PC_ELAPSED, "sensor task update"))
_loop_perf(perf_alloc(PC_ELAPSED, "sensor task update")),
_board_rotation(3,3),
_external_mag_rotation(3,3)
{
/* basic r/c parameters */
@@ -538,6 +625,10 @@ Sensors::Sensors() :
_parameter_handles.battery_voltage_scaling = param_find("BAT_V_SCALING");
/* rotations */
_parameter_handles.board_rotation = param_find("SENS_BOARD_ROT");
_parameter_handles.external_mag_rotation = param_find("SENS_EXT_MAG_ROT");
/* fetch initial parameter values */
parameters_update();
}
@@ -724,9 +815,33 @@ Sensors::parameters_update()
warnx("Failed updating voltage scaling param");
}
param_get(_parameter_handles.board_rotation, &(_parameters.board_rotation));
param_get(_parameter_handles.external_mag_rotation, &(_parameters.external_mag_rotation));
get_rot_matrix((enum Rotation)_parameters.board_rotation, &_board_rotation);
get_rot_matrix((enum Rotation)_parameters.external_mag_rotation, &_external_mag_rotation);
return OK;
}
void
Sensors::get_rot_matrix(enum Rotation rot, math::Matrix *rot_matrix)
{
/* first set to zero */
rot_matrix->Matrix::zero(3,3);
float roll = M_DEG_TO_RAD_F * (float)rot_lookup[rot].roll;
float pitch = M_DEG_TO_RAD_F * (float)rot_lookup[rot].pitch;
float yaw = M_DEG_TO_RAD_F * (float)rot_lookup[rot].yaw;
math::EulerAngles euler(roll, pitch, yaw);
math::Dcm R(euler);
for (int i = 0; i < 3; i++) for (int j = 0; j < 3; j++)
(*rot_matrix)(i,j) = R(i, j);
}
void
Sensors::accel_init()
{
@@ -750,7 +865,7 @@ Sensors::accel_init()
/* set the driver to poll at 1000Hz */
ioctl(fd, SENSORIOCSPOLLRATE, 1000);
#else
#elif CONFIG_ARCH_BOARD_PX4FMU_V2
/* set the accel internal sampling rate up to at leat 800Hz */
ioctl(fd, ACCELIOCSSAMPLERATE, 800);
@@ -758,6 +873,9 @@ Sensors::accel_init()
/* set the driver to poll at 800Hz */
ioctl(fd, SENSORIOCSPOLLRATE, 800);
#else
#error Need a board configuration, either CONFIG_ARCH_BOARD_PX4FMU_V1 or CONFIG_ARCH_BOARD_PX4FMU_V2
#endif
warnx("using system accel");
@@ -867,9 +985,12 @@ Sensors::accel_poll(struct sensor_combined_s &raw)
orb_copy(ORB_ID(sensor_accel), _accel_sub, &accel_report);
raw.accelerometer_m_s2[0] = accel_report.x;
raw.accelerometer_m_s2[1] = accel_report.y;
raw.accelerometer_m_s2[2] = accel_report.z;
math::Vector3 vect = {accel_report.x, accel_report.y, accel_report.z};
vect = _board_rotation*vect;
raw.accelerometer_m_s2[0] = vect(0);
raw.accelerometer_m_s2[1] = vect(1);
raw.accelerometer_m_s2[2] = vect(2);
raw.accelerometer_raw[0] = accel_report.x_raw;
raw.accelerometer_raw[1] = accel_report.y_raw;
@@ -890,9 +1011,12 @@ Sensors::gyro_poll(struct sensor_combined_s &raw)
orb_copy(ORB_ID(sensor_gyro), _gyro_sub, &gyro_report);
raw.gyro_rad_s[0] = gyro_report.x;
raw.gyro_rad_s[1] = gyro_report.y;
raw.gyro_rad_s[2] = gyro_report.z;
math::Vector3 vect = {gyro_report.x, gyro_report.y, gyro_report.z};
vect = _board_rotation*vect;
raw.gyro_rad_s[0] = vect(0);
raw.gyro_rad_s[1] = vect(1);
raw.gyro_rad_s[2] = vect(2);
raw.gyro_raw[0] = gyro_report.x_raw;
raw.gyro_raw[1] = gyro_report.y_raw;
@@ -913,9 +1037,14 @@ Sensors::mag_poll(struct sensor_combined_s &raw)
orb_copy(ORB_ID(sensor_mag), _mag_sub, &mag_report);
raw.magnetometer_ga[0] = mag_report.x;
raw.magnetometer_ga[1] = mag_report.y;
raw.magnetometer_ga[2] = mag_report.z;
// XXX TODO add support for external mag orientation
math::Vector3 vect = {mag_report.x, mag_report.y, mag_report.z};
vect = _board_rotation*vect;
raw.magnetometer_ga[0] = vect(0);
raw.magnetometer_ga[1] = vect(1);
raw.magnetometer_ga[2] = vect(2);
raw.magnetometer_raw[0] = mag_report.x_raw;
raw.magnetometer_raw[1] = mag_report.y_raw;
+4
View File
@@ -37,6 +37,10 @@
* Common object definitions without a better home.
*/
/**
* @defgroup topics List of all uORB topics.
*/
#include <nuttx/config.h>
#include <drivers/drv_orb_dev.h>
+11 -1
View File
@@ -55,15 +55,25 @@
/* control sets with pre-defined applications */
#define ORB_ID_VEHICLE_ATTITUDE_CONTROLS ORB_ID(actuator_controls_0)
/**
* @addtogroup topics
* @{
*/
struct actuator_controls_s {
uint64_t timestamp;
float control[NUM_ACTUATOR_CONTROLS];
};
/**
* @}
*/
/* actuator control sets; this list can be expanded as more controllers emerge */
ORB_DECLARE(actuator_controls_0);
ORB_DECLARE(actuator_controls_1);
ORB_DECLARE(actuator_controls_2);
ORB_DECLARE(actuator_controls_3);
#endif
#endif
@@ -53,11 +53,20 @@
#define NUM_ACTUATOR_CONTROLS_EFFECTIVE NUM_ACTUATOR_CONTROLS
#define NUM_ACTUATOR_CONTROL_GROUPS_EFFECTIVE NUM_ACTUATOR_CONTROL_GROUPS /**< for sanity checking */
/**
* @addtogroup topics
* @{
*/
struct actuator_controls_effective_s {
uint64_t timestamp;
float control_effective[NUM_ACTUATOR_CONTROLS_EFFECTIVE];
};
/**
* @}
*/
/* actuator control sets; this list can be expanded as more controllers emerge */
ORB_DECLARE(actuator_controls_effective_0);
ORB_DECLARE(actuator_controls_effective_1);
@@ -52,12 +52,21 @@
#define NUM_ACTUATOR_OUTPUTS 16
#define NUM_ACTUATOR_OUTPUT_GROUPS 4 /**< for sanity checking */
/**
* @addtogroup topics
* @{
*/
struct actuator_outputs_s {
uint64_t timestamp; /**< output timestamp in us since system boot */
float output[NUM_ACTUATOR_OUTPUTS]; /**< output data, in natural output units */
int noutputs; /**< valid outputs */
};
/**
* @}
*/
/* actuator output sets; this list can be expanded as more drivers emerge */
ORB_DECLARE(actuator_outputs_0);
ORB_DECLARE(actuator_outputs_1);
@@ -47,6 +47,7 @@
/**
* @addtogroup topics
* @{
*/
/**
+6 -5
View File
@@ -51,10 +51,6 @@
#include <stdbool.h>
#include "../uORB.h"
/**
* @addtogroup topics @{
*/
/**
* The number of ESCs supported.
* Current (Q2/2013) we support 8 ESCs,
@@ -76,7 +72,12 @@ enum ESC_CONNECTION_TYPE {
};
/**
*
* @addtogroup topics
* @{
*/
/**
* Electronic speed controller status.
*/
struct esc_status_s
{
+5 -5
View File
@@ -46,11 +46,6 @@
#include <stdbool.h>
#include "../uORB.h"
/**
* @addtogroup topics
* @{
*/
enum NAV_CMD {
NAV_CMD_WAYPOINT = 0,
NAV_CMD_LOITER_TURN_COUNT,
@@ -61,6 +56,11 @@ enum NAV_CMD {
NAV_CMD_TAKEOFF
};
/**
* @addtogroup topics
* @{
*/
/**
* Global position setpoint in WGS84 coordinates.
*
@@ -43,11 +43,6 @@
#include <stdint.h>
#include "../uORB.h"
/**
* @addtogroup topics
* @{
*/
/**
* Off-board control inputs.
*
@@ -66,6 +61,11 @@ enum OFFBOARD_CONTROL_MODE
OFFBOARD_CONTROL_MODE_MULTIROTOR_SIMPLE = 7, /**< roll / pitch rotated aligned to the takeoff orientation, throttle stabilized, yaw pos */
};
/**
* @addtogroup topics
* @{
*/
struct offboard_control_setpoint_s {
uint64_t timestamp;
@@ -46,6 +46,7 @@
/**
* @addtogroup topics
* @{
*/
/**
@@ -42,11 +42,20 @@
#include <stdint.h>
#include "../uORB.h"
/**
* @addtogroup topics
* @{
*/
struct parameter_update_s {
/** time at which the latest parameter was updated */
uint64_t timestamp;
};
/**
* @}
*/
ORB_DECLARE(parameter_update);
#endif
+5 -5
View File
@@ -45,11 +45,6 @@
#include <stdint.h>
#include "../uORB.h"
/**
* @addtogroup topics
* @{
*/
/**
* The number of RC channel inputs supported.
* Current (Q1/2013) radios support up to 18 channels,
@@ -85,6 +80,11 @@ enum RC_CHANNELS_FUNCTION
RC_CHANNELS_FUNCTION_MAX /**< indicates the number of functions. There can be more functions than RC channels. */
};
/**
* @addtogroup topics
* @{
*/
struct rc_channels_s {
uint64_t timestamp; /**< In microseconds since boot time. */
+5 -5
View File
@@ -46,17 +46,17 @@
#include <stdbool.h>
#include "../uORB.h"
/**
* @addtogroup topics
* @{
*/
enum MAGNETOMETER_MODE {
MAGNETOMETER_MODE_NORMAL = 0,
MAGNETOMETER_MODE_POSITIVE_BIAS,
MAGNETOMETER_MODE_NEGATIVE_BIAS
};
/**
* @addtogroup topics
* @{
*/
/**
* Sensor readings in raw and SI-unit form.
*
+4 -4
View File
@@ -50,10 +50,6 @@
#include <stdbool.h>
#include "../uORB.h"
/**
* @addtogroup topics
*/
enum SUBSYSTEM_TYPE
{
SUBSYSTEM_TYPE_GYRO = 1,
@@ -75,6 +71,10 @@ enum SUBSYSTEM_TYPE
SUBSYSTEM_TYPE_RANGEFINDER = 131072
};
/**
* @addtogroup topics
*/
/**
* State of individual sub systems
*/
@@ -50,6 +50,11 @@ enum TELEMETRY_STATUS_RADIO_TYPE {
TELEMETRY_STATUS_RADIO_TYPE_WIRE
};
/**
* @addtogroup topics
* @{
*/
struct telemetry_status_s {
uint64_t timestamp;
enum TELEMETRY_STATUS_RADIO_TYPE type; /**< type of the radio hardware */
@@ -62,6 +67,10 @@ struct telemetry_status_s {
uint8_t txbuf; /**< how full the tx buffer is as a percentage */
};
/**
* @}
*/
ORB_DECLARE(telemetry_status);
#endif /* TOPIC_TELEMETRY_STATUS_H */
@@ -48,6 +48,7 @@
/**
* @addtogroup topics
* @{
*/
/**
+4 -5
View File
@@ -45,11 +45,6 @@
#include <stdint.h>
#include "../uORB.h"
/**
* @addtogroup topics
* @{
*/
/**
* Commands for commander app.
*
@@ -110,6 +105,10 @@ enum VEHICLE_CMD_RESULT
VEHICLE_CMD_RESULT_ENUM_END=5, /* | */
};
/**
* @addtogroup topics
* @{
*/
struct vehicle_command_s
{
@@ -60,8 +60,8 @@
*/
struct vehicle_global_position_set_triplet_s
{
bool previous_valid;
bool next_valid;
bool previous_valid; /**< flag indicating previous position is valid */
bool next_valid; /**< flag indicating next position is valid */
struct vehicle_global_position_setpoint_s previous;
struct vehicle_global_position_setpoint_s current;
+4
View File
@@ -159,6 +159,10 @@ enum VEHICLE_BATTERY_WARNING {
VEHICLE_BATTERY_WARNING_ALERT /**< alerting of low voltage 2. stage */
};
/**
* @addtogroup topics
* @{
*/
/**
* state machine / state of vehicle.