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// int32_t *mem2 = (int32_t *)&vect.value[0];
// // uint32_t *mem3 = (uint32_t *)&vect.value[0]; causes overload problem
// float *mem4 = (float *)&vect.value[0];
// if ( vect.ver == 0) vect.type = 0, vect.ver = 1; else ;
// if ( vect.ver == 1)
// {
// switch (vect.type) {
// default:
// case 0:
// for (int i = 0; i < 16; i++)
// // FIXME REMOVE LATER emit valueChanged(uasId, str.arg(vect.address+(i*2)), "i16", mem0[i], time);
// break;
// case 1:
// for (int i = 0; i < 16; i++)
// // FIXME REMOVE LATER emit valueChanged(uasId, str.arg(vect.address+(i*2)), "ui16", mem1[i], time);
// break;
// case 2:
// for (int i = 0; i < 16; i++)
// // FIXME REMOVE LATER emit valueChanged(uasId, str.arg(vect.address+(i*2)), "Q15", (float)mem0[i]/32767.0, time);
// break;
// case 3:
// for (int i = 0; i < 16; i++)
// // FIXME REMOVE LATER emit valueChanged(uasId, str.arg(vect.address+(i*2)), "1Q14", (float)mem0[i]/16383.0, time);
// break;
// case 4:
// for (int i = 0; i < 8; i++)
// // FIXME REMOVE LATER emit valueChanged(uasId, str.arg(vect.address+(i*4)), "i32", mem2[i], time);
// break;
// case 5:
// for (int i = 0; i < 8; i++)
// // FIXME REMOVE LATER emit valueChanged(uasId, str.arg(vect.address+(i*4)), "i32", mem2[i], time);
// break;
// case 6:
// for (int i = 0; i < 8; i++)
// // FIXME REMOVE LATER emit valueChanged(uasId, str.arg(vect.address+(i*4)), "float", mem4[i], time);
// break;
// }
// }
// }
// break;
case MAVLINK_MSG_ID_NAV_FILTER_BIAS:
{
mavlink_nav_filter_bias_t bias;
mavlink_msg_nav_filter_bias_decode(&message, &bias);
quint64 time = getUnixTime();
// FIXME REMOVE LATER emit valueChanged(uasId, "b_f[0]", "raw", bias.accel_0, time);
// FIXME REMOVE LATER emit valueChanged(uasId, "b_f[1]", "raw", bias.accel_1, time);
// FIXME REMOVE LATER emit valueChanged(uasId, "b_f[2]", "raw", bias.accel_2, time);
// FIXME REMOVE LATER emit valueChanged(uasId, "b_w[0]", "raw", bias.gyro_0, time);
// FIXME REMOVE LATER emit valueChanged(uasId, "b_w[1]", "raw", bias.gyro_1, time);
// FIXME REMOVE LATER emit valueChanged(uasId, "b_w[2]", "raw", bias.gyro_2, time);
case MAVLINK_MSG_ID_RADIO_CALIBRATION:
{
mavlink_radio_calibration_t radioMsg;
mavlink_msg_radio_calibration_decode(&message, &radioMsg);
QVector<uint16_t> aileron;
QVector<uint16_t> elevator;
QVector<uint16_t> rudder;
QVector<uint16_t> gyro;
QVector<uint16_t> pitch;
QVector<uint16_t> throttle;
for (int i=0; i<MAVLINK_MSG_RADIO_CALIBRATION_FIELD_AILERON_LEN; ++i)
aileron << radioMsg.aileron[i];
for (int i=0; i<MAVLINK_MSG_RADIO_CALIBRATION_FIELD_ELEVATOR_LEN; ++i)
elevator << radioMsg.elevator[i];
for (int i=0; i<MAVLINK_MSG_RADIO_CALIBRATION_FIELD_RUDDER_LEN; ++i)
rudder << radioMsg.rudder[i];
for (int i=0; i<MAVLINK_MSG_RADIO_CALIBRATION_FIELD_GYRO_LEN; ++i)
gyro << radioMsg.gyro[i];
for (int i=0; i<MAVLINK_MSG_RADIO_CALIBRATION_FIELD_PITCH_LEN; ++i)
pitch << radioMsg.pitch[i];
for (int i=0; i<MAVLINK_MSG_RADIO_CALIBRATION_FIELD_THROTTLE_LEN; ++i)
throttle << radioMsg.throttle[i];
QPointer<RadioCalibrationData> radioData = new RadioCalibrationData(aileron, elevator, rudder, gyro, pitch, throttle);
emit radioCalibrationReceived(radioData);
delete radioData;
}
break;
case MAVLINK_MSG_ID_SET_LOCAL_POSITION_SETPOINT:
default:
{
if (!unknownPackets.contains(message.msgid))
{
unknownPackets.append(message.msgid);
QString errString = tr("UNABLE TO DECODE MESSAGE NUMBER %1").arg(message.msgid);
GAudioOutput::instance()->say(errString+tr(", please check console for details."));
emit textMessageReceived(uasId, message.compid, 255, errString);
std::cout << "Unable to decode message from system " << std::dec << static_cast<int>(message.sysid) << " with message id:" << static_cast<int>(message.msgid) << std::endl;
//qDebug() << std::cerr << "Unable to decode message from system " << std::dec << static_cast<int>(message.acid) << " with message id:" << static_cast<int>(message.msgid) << std::endl;
}
void UAS::setHomePosition(double lat, double lon, double alt)
{
// Send new home position to UAS
mavlink_set_gps_global_origin_t home;
home.target_system = uasId;
home.latitude = lat*1E7;
home.longitude = lon*1E7;
home.altitude = alt*1000;
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qDebug() << "lat:" << home.latitude << " lon:" << home.longitude;
mavlink_msg_set_gps_global_origin_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &home);
void UAS::setLocalOriginAtCurrentGPSPosition()
{
bool result = false;
QMessageBox msgBox;
msgBox.setIcon(QMessageBox::Warning);
msgBox.setText("Setting new World Coordinate Frame Origin");
msgBox.setInformativeText("Do you want to set a new origin? Waypoints defined in the local frame will be shifted in their physical location");
msgBox.setStandardButtons(QMessageBox::Yes | QMessageBox::Cancel);
msgBox.setDefaultButton(QMessageBox::Cancel);
int ret = msgBox.exec();
// Close the message box shortly after the click to prevent accidental clicks
QTimer::singleShot(5000, &msgBox, SLOT(reject()));
if (ret == QMessageBox::Yes)
{
// FIXME MAVLINKV10PORTINGNEEDED
// mavlink_message_t msg;
// mavlink_msg_action_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, this->getUASID(), 0, MAV_ACTION_SET_ORIGIN);
// // Send message twice to increase chance that it reaches its goal
// sendMessage(msg);
// // Wait 5 ms
// MG::SLEEP::usleep(5000);
// // Send again
// sendMessage(msg);
result = true;
}
}
void UAS::setLocalPositionSetpoint(float x, float y, float z, float yaw)
{
#ifdef MAVLINK_ENABLED_PIXHAWK
mavlink_msg_position_control_setpoint_set_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, 0, 0, x, y, z, yaw);
sendMessage(msg);
#else
Q_UNUSED(x);
Q_UNUSED(y);
Q_UNUSED(z);
Q_UNUSED(yaw);
#endif
void UAS::setLocalPositionOffset(float x, float y, float z, float yaw)
{
mavlink_message_t msg;
mavlink_msg_position_control_offset_set_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, 0, x, y, z, yaw);
sendMessage(msg);
Q_UNUSED(x);
Q_UNUSED(y);
Q_UNUSED(z);
Q_UNUSED(yaw);
#endif
}
void UAS::startRadioControlCalibration()
mavlink_message_t msg;
// Param 1: gyro cal, param 2: mag cal, param 3: pressure cal, Param 4: radio
mavlink_msg_command_short_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, MAV_COMP_ID_IMU, MAV_CMD_PREFLIGHT_CALIBRATION, 1, 0, 0, 0, 1);
mavlink_msg_command_short_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, 0, MAV_CMD_DO_CONTROL_VIDEO, 1, -1, -1, -1, 2);
mavlink_msg_command_short_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, 0, MAV_CMD_DO_CONTROL_VIDEO, 1, -1, -1, -1, 0);
void UAS::startMagnetometerCalibration()
{
mavlink_message_t msg;
// Param 1: gyro cal, param 2: mag cal, param 3: pressure cal, Param 4: radio
mavlink_msg_command_short_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, MAV_COMP_ID_IMU, MAV_CMD_PREFLIGHT_CALIBRATION, 1, 0, 1, 0, 0);
}
void UAS::startGyroscopeCalibration()
{
mavlink_message_t msg;
// Param 1: gyro cal, param 2: mag cal, param 3: pressure cal, Param 4: radio
mavlink_msg_command_short_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, MAV_COMP_ID_IMU, MAV_CMD_PREFLIGHT_CALIBRATION, 1, 1, 0, 0, 0);
}
void UAS::startPressureCalibration()
{
mavlink_message_t msg;
// Param 1: gyro cal, param 2: mag cal, param 3: pressure cal, Param 4: radio
mavlink_msg_command_short_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, MAV_COMP_ID_IMU, MAV_CMD_PREFLIGHT_CALIBRATION, 1, 0, 0, 1, 0);
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quint64 UAS::getUnixReferenceTime(quint64 time)
{
// Same as getUnixTime, but does not react to attitudeStamped mode
if (time == 0)
{
// qDebug() << "XNEW time:" <<QGC::groundTimeMilliseconds();
return QGC::groundTimeMilliseconds();
}
// Check if time is smaller than 40 years,
// assuming no system without Unix timestamp
// runs longer than 40 years continuously without
// reboot. In worst case this will add/subtract the
// communication delay between GCS and MAV,
// it will never alter the timestamp in a safety
// critical way.
//
// Calculation:
// 40 years
// 365 days
// 24 hours
// 60 minutes
// 60 seconds
// 1000 milliseconds
// 1000 microseconds
#ifndef _MSC_VER
else if (time < 1261440000000000LLU)
#else
else if (time < 1261440000000000)
#endif
{
// qDebug() << "GEN time:" << time/1000 + onboardTimeOffset;
if (onboardTimeOffset == 0)
{
onboardTimeOffset = QGC::groundTimeMilliseconds() - time/1000;
}
return time/1000 + onboardTimeOffset;
}
else
{
// Time is not zero and larger than 40 years -> has to be
// a Unix epoch timestamp. Do nothing.
return time/1000;
}
}
/**
* @warning If attitudeStamped is enabled, this function will not actually return the precise time stamp
* of this measurement augmented to UNIX time, but will MOVE the timestamp IN TIME to match
* the last measured attitude. There is no reason why one would want this, except for
* system setups where the onboard clock is not present or broken and datasets should
* be collected that are still roughly synchronized. PLEASE NOTE THAT ENABLING ATTITUDE STAMPED
* RUINS THE SCIENTIFIC NATURE OF THE CORRECT LOGGING FUNCTIONS OF QGROUNDCONTROL!
*/
quint64 UAS::getUnixTimeFromMs(quint64 time)
{
return getUnixTime(time*1000);
}
/**
* @warning If attitudeStamped is enabled, this function will not actually return the precise time stamp
* of this measurement augmented to UNIX time, but will MOVE the timestamp IN TIME to match
* the last measured attitude. There is no reason why one would want this, except for
* system setups where the onboard clock is not present or broken and datasets should
* be collected that are still roughly synchronized. PLEASE NOTE THAT ENABLING ATTITUDE STAMPED
* RUINS THE SCIENTIFIC NATURE OF THE CORRECT LOGGING FUNCTIONS OF QGROUNDCONTROL!
*/
quint64 UAS::getUnixTime(quint64 time)
{
if (time == 0)
{
}
// Check if time is smaller than 40 years,
// assuming no system without Unix timestamp
// runs longer than 40 years continuously without
// reboot. In worst case this will add/subtract the
// communication delay between GCS and MAV,
// it will never alter the timestamp in a safety
// critical way.
//
// Calculation:
// 40 years
// 365 days
// 24 hours
// 60 minutes
// 60 seconds
// 1000 milliseconds
// 1000 microseconds
#ifndef _MSC_VER
else if (time < 1261440000000000LLU)
{
// qDebug() << "GEN time:" << time/1000 + onboardTimeOffset;
if (onboardTimeOffset == 0)
{
}
}
else
{
// Time is not zero and larger than 40 years -> has to be
// a Unix epoch timestamp. Do nothing.
}
}
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QList<QString> UAS::getParameterNames(int component)
{
if (parameters.contains(component))
{
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return parameters.value(component)->keys();
}
else
{
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return QList<QString>();
}
}
QList<int> UAS::getComponentIds()
{
return parameters.keys();
}
if (mode >= (int)MAV_MODE_PREFLIGHT && mode < (int)MAV_MODE_ENUM_END)
{
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//this->mode = mode; //no call assignament, update receive message from UAS
mavlink_msg_set_mode_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, (uint8_t)uasId, (uint8_t)mode, (uint16_t)navMode);
qDebug() << "SENDING REQUEST TO SET MODE TO SYSTEM" << uasId << ", REQUEST TO SET MODE " << (uint8_t)mode;
}
else
{
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qDebug() << "uas Mode not assign: " << mode;
}
}
void UAS::sendMessage(mavlink_message_t message)
{
// Emit message on all links that are currently connected
foreach (LinkInterface* link, *links)
{
if (link)
{
sendMessage(link, message);
}
else
{
// Remove from list
links->removeAt(links->indexOf(link));
}
void UAS::forwardMessage(mavlink_message_t message)
{
// Emit message on all links that are currently connected
QList<LinkInterface*>link_list = LinkManager::instance()->getLinksForProtocol(mavlink);
foreach(LinkInterface* link, link_list)
{
if (link)
{
SerialLink* serial = dynamic_cast<SerialLink*>(link);
if(serial != 0)
{
for(int i=0; i<links->size(); i++)
{
if(serial != links->at(i))
{
qDebug()<<"Antenna tracking: Forwarding Over link: "<<serial->getName()<<" "<<serial;
sendMessage(serial, message);
}
}
}
}
}
}
void UAS::sendMessage(LinkInterface* link, mavlink_message_t message)
{
// Create buffer
uint8_t buffer[MAVLINK_MAX_PACKET_LEN];
// Write message into buffer, prepending start sign
int len = mavlink_msg_to_send_buffer(buffer, &message);
static uint8_t messageKeys[256] = MAVLINK_MESSAGE_CRCS;
mavlink_finalize_message_chan(&message, mavlink->getSystemId(), mavlink->getComponentId(), link->getId(), message.len, messageKeys[message.msgid]);
if (link->isConnected())
{
// Send the portion of the buffer now occupied by the message
link->writeBytes((const char*)buffer, len);
}
}
/**
* @param value battery voltage
*/
float UAS::filterVoltage(float value) const
return lpVoltage * 0.7f + value * 0.3f;
QString UAS::getNavModeText(int mode)
{
switch (mode)
{
break;
default:
return QString("UNKNOWN");
}
}
else if (autopilot == MAV_AUTOPILOT_ARDUPILOTMEGA)
{
return QString("UNKNOWN");
}
else if (autopilot == MAV_AUTOPILOT_OPENPILOT)
{
return QString("UNKNOWN");
}
void UAS::getStatusForCode(int statusCode, QString& uasState, QString& stateDescription)
{
switch (statusCode)
{
stateDescription = tr("Unitialized, booting up.");
stateDescription = tr("Booting system, please wait.");
stateDescription = tr("Calibrating sensors, please wait.");
stateDescription = tr("Active, normal operation.");
stateDescription = tr("Standby mode, ready for liftoff.");
stateDescription = tr("FAILURE: Continuing operation.");
stateDescription = tr("EMERGENCY: Land Immediately!");
//uasState = tr("HIL SIM");
//stateDescription = tr("HIL Simulation, Sensors read from SIM");
//break;
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stateDescription = tr("Powering off system.");
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stateDescription = tr("Unknown system state");
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#ifdef MAVLINK_ENABLED_PIXHAWK
qDebug() << "IMAGE TYPE:" << imageType;
// RAW greyscale
if (imageType == MAVLINK_DATA_STREAM_IMG_RAW8U)
{
// TODO FIXME Fabian
// RAW hardcoded to 22x22
int imgWidth = 22;
int imgHeight = 22;
int imgColors = 255;
//const int headerSize = 15;
// Construct PGM header
QString header("P5\n%1 %2\n%3\n");
header = header.arg(imgWidth).arg(imgHeight).arg(imgColors);
QByteArray tmpImage(header.toStdString().c_str(), header.toStdString().size());
tmpImage.append(imageRecBuffer);
//qDebug() << "IMAGE SIZE:" << tmpImage.size() << "HEADER SIZE: (15):" << header.size() << "HEADER: " << header;
if (imageRecBuffer.isNull())
{
qDebug()<< "could not convertToPGM()";
return QImage();
}
if (!image.loadFromData(tmpImage, "PGM"))
{
qDebug()<< "could not create extracted image";
return QImage();
}
}
// BMP with header
else if (imageType == MAVLINK_DATA_STREAM_IMG_BMP ||
imageType == MAVLINK_DATA_STREAM_IMG_JPEG ||
imageType == MAVLINK_DATA_STREAM_IMG_PGM ||
imageType == MAVLINK_DATA_STREAM_IMG_PNG)
{
if (!image.loadFromData(imageRecBuffer))
{
qDebug() << "Loading data from image buffer failed!";
}
}
// Restart statemachine
imagePacketsArrived = 0;
#else
return QImage();
}
void UAS::requestImage()
{
qDebug() << "trying to get an image from the uas...";
// check if there is already an image transmission going on
if (imagePacketsArrived == 0)
{
mavlink_message_t msg;
mavlink_msg_data_transmission_handshake_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, DATA_TYPE_JPEG_IMAGE, 0, 0, 0, 50);
sendMessage(msg);
}
#endif
/* MANAGEMENT */
/*
*
* @return The uptime in milliseconds
*
**/
quint64 UAS::getUptime() const
if(startTime == 0)
{
}
else
{
return MG::TIME::getGroundTimeNow() - startTime;
}
}
int UAS::getCommunicationStatus() const
void UAS::requestParameters()
{
mavlink_message_t msg;
mavlink_msg_param_request_list_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, this->getUASID(), 25);
}
{
mavlink_msg_command_short_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, 0, MAV_CMD_PREFLIGHT_STORAGE, 1, 1, -1, -1, -1);
}
void UAS::readParametersFromStorage()
{
mavlink_msg_command_short_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, 0, MAV_CMD_PREFLIGHT_STORAGE, 1, 0, -1, -1, -1);
void UAS::enableAllDataTransmission(int rate)
mavlink_message_t msg;
mavlink_request_data_stream_t stream;
// Select the message to request from now on
// 0 is a magic ID and will enable/disable the standard message set except for heartbeat
stream.req_stream_id = MAV_DATA_STREAM_ALL;
// Select the update rate in Hz the message should be send
// All messages will be send with their default rate
// TODO: use 0 to turn off and get rid of enable/disable? will require
// a different magic flag for turning on defaults, possibly something really high like 1111 ?
// The system which should take this command
stream.target_system = uasId;
// The component / subsystem which should take this command
stream.target_component = 0;
// Encode and send the message
mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
// Send message twice to increase chance of reception
sendMessage(msg);
void UAS::enableRawSensorDataTransmission(int rate)
mavlink_request_data_stream_t stream;
stream.req_stream_id = MAV_DATA_STREAM_RAW_SENSORS;
// The system which should take this command
stream.target_system = uasId;
// The component / subsystem which should take this command
stream.target_component = 0;
// Encode and send the message
mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
// Send message twice to increase chance of reception
sendMessage(msg);
void UAS::enableExtendedSystemStatusTransmission(int rate)
// Buffers to write data to
mavlink_message_t msg;
mavlink_request_data_stream_t stream;
// Select the message to request from now on
stream.req_stream_id = MAV_DATA_STREAM_EXTENDED_STATUS;
// Select the update rate in Hz the message should be send
// Start / stop the message
// The system which should take this command
stream.target_system = uasId;
// The component / subsystem which should take this command
stream.target_component = 0;
// Encode and send the message
mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
// Send message twice to increase chance of reception
sendMessage(msg);
sendMessage(msg);
void UAS::enableRCChannelDataTransmission(int rate)
#if defined(MAVLINK_ENABLED_UALBERTA_MESSAGES)
mavlink_message_t msg;
mavlink_msg_request_rc_channels_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, enabled);
sendMessage(msg);
#else
mavlink_message_t msg;
mavlink_request_data_stream_t stream;
// Select the message to request from now on
stream.req_stream_id = MAV_DATA_STREAM_RC_CHANNELS;
// Select the update rate in Hz the message should be send
// Start / stop the message
// The system which should take this command
stream.target_system = uasId;
// The component / subsystem which should take this command
stream.target_component = 0;
// Encode and send the message
mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
// Send message twice to increase chance of reception
sendMessage(msg);
sendMessage(msg);
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#endif
void UAS::enableRawControllerDataTransmission(int rate)
// Buffers to write data to
mavlink_message_t msg;
mavlink_request_data_stream_t stream;
// Select the message to request from now on
stream.req_stream_id = MAV_DATA_STREAM_RAW_CONTROLLER;
// Select the update rate in Hz the message should be send
// Start / stop the message
// The system which should take this command
stream.target_system = uasId;
// The component / subsystem which should take this command
stream.target_component = 0;
// Encode and send the message
mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
// Send message twice to increase chance of reception
sendMessage(msg);
sendMessage(msg);
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//void UAS::enableRawSensorFusionTransmission(int rate)
//{
// // Buffers to write data to
// mavlink_message_t msg;
// mavlink_request_data_stream_t stream;
// // Select the message to request from now on
// stream.req_stream_id = MAV_DATA_STREAM_RAW_SENSOR_FUSION;
// // Select the update rate in Hz the message should be send
// stream.req_message_rate = rate;
// // Start / stop the message
// stream.start_stop = (rate) ? 1 : 0;
// // The system which should take this command
// stream.target_system = uasId;
// // The component / subsystem which should take this command
// stream.target_component = 0;
// // Encode and send the message
// mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
// // Send message twice to increase chance of reception
// sendMessage(msg);
// sendMessage(msg);
//}
void UAS::enablePositionTransmission(int rate)
{
// Buffers to write data to
mavlink_message_t msg;
mavlink_request_data_stream_t stream;
// Select the message to request from now on
stream.req_stream_id = MAV_DATA_STREAM_POSITION;
// Select the update rate in Hz the message should be send
// The system which should take this command
stream.target_system = uasId;
// The component / subsystem which should take this command
stream.target_component = 0;
// Encode and send the message
mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
// Send message twice to increase chance of reception
sendMessage(msg);
sendMessage(msg);
}
{
// Buffers to write data to
mavlink_message_t msg;
mavlink_request_data_stream_t stream;
// Select the message to request from now on
stream.req_stream_id = MAV_DATA_STREAM_EXTRA1;
// Select the update rate in Hz the message should be send
// The system which should take this command
stream.target_system = uasId;
// The component / subsystem which should take this command
stream.target_component = 0;
// Encode and send the message
mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
// Send message twice to increase chance of reception
sendMessage(msg);
sendMessage(msg);
}
{
// Buffers to write data to
mavlink_message_t msg;
mavlink_request_data_stream_t stream;
// Select the message to request from now on
stream.req_stream_id = MAV_DATA_STREAM_EXTRA2;
// Select the update rate in Hz the message should be send
// The system which should take this command
stream.target_system = uasId;
// The component / subsystem which should take this command
stream.target_component = 0;
// Encode and send the message
mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
// Send message twice to increase chance of reception
sendMessage(msg);
sendMessage(msg);
}
{
// Buffers to write data to
mavlink_message_t msg;
mavlink_request_data_stream_t stream;
// Select the message to request from now on
stream.req_stream_id = MAV_DATA_STREAM_EXTRA3;
// Select the update rate in Hz the message should be send
// Start / stop the message
// The system which should take this command
stream.target_system = uasId;
// The component / subsystem which should take this command
stream.target_component = 0;
// Encode and send the message
mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
// Send message twice to increase chance of reception
sendMessage(msg);
sendMessage(msg);
}
/**
* Set a parameter value onboard
*
* @param component The component to set the parameter
* @param id Name of the parameter
* @param value Parameter value
*/
void UAS::setParameter(const int component, const QString& id, const QVariant& value)
if (!id.isNull())
{
mavlink_message_t msg;
mavlink_param_set_t p;
mavlink_param_union_t union_value;
// Assign correct value based on QVariant
switch (value.type())
{
case QVariant::Int:
union_value.param_int32 = value.toInt();
p.param_type = MAVLINK_TYPE_INT32_T;
break;
case QVariant::UInt:
union_value.param_uint32 = value.toUInt();
p.param_type = MAVLINK_TYPE_UINT32_T;
break;
case QMetaType::Float:
union_value.param_float = value.toFloat();
p.param_type = MAVLINK_TYPE_FLOAT;
break;
default:
qCritical() << "ABORTED PARAM SEND, NO VALID QVARIANT TYPE";
return;
}
p.param_value = union_value.param_float;
p.target_system = (uint8_t)uasId;
p.target_component = (uint8_t)component;
qDebug() << "SENT PARAM:" << value;
// Copy string into buffer, ensuring not to exceed the buffer size
for (unsigned int i = 0; i < sizeof(p.param_id); i++)
{
if ((int)i < id.length() && i < (sizeof(p.param_id) - 1))
{
p.param_id[i] = id.toAscii()[i];
}
// // Null termination at end of string or end of buffer
// else if ((int)i == id.length() || i == (sizeof(p.param_id) - 1))
// {
// p.param_id[i] = '\0';
// }
else
{
mavlink_msg_param_set_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &p);
sendMessage(msg);
void UAS::requestParameter(int component, int parameter)
{
mavlink_message_t msg;
mavlink_param_request_read_t read;
read.param_index = parameter;
read.target_system = uasId;
read.target_component = component;
mavlink_msg_param_request_read_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &read);
sendMessage(msg);
qDebug() << __FILE__ << __LINE__ << "REQUESTING PARAM RETRANSMISSION FROM COMPONENT" << component << "FOR PARAM ID" << parameter;
}
void UAS::setSystemType(int systemType)
{
type = systemType;
// If the airframe is still generic, change it to a close default type
if (airframe == 0)
{
switch (systemType)
{
airframe = QGC_AIRFRAME_EASYSTAR;
break;
airframe = QGC_AIRFRAME_MIKROKOPTER;
break;
}
}
emit systemSpecsChanged(uasId);
}
void UAS::setUASName(const QString& name)
{
this->name = name;
emit systemSpecsChanged(uasId);
void UAS::executeCommand(MAV_CMD command)
{
mavlink_message_t msg;
cmd.command = (uint8_t)command;
cmd.confirmation = 0;
cmd.param1 = 0.0f;
cmd.param2 = 0.0f;
cmd.param3 = 0.0f;
cmd.param4 = 0.0f;
cmd.target_system = uasId;
cmd.target_component = 0;
mavlink_msg_command_short_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &cmd);
sendMessage(msg);
}
void UAS::executeCommand(MAV_CMD command, int confirmation, float param1, float param2, float param3, float param4, int component)
{
mavlink_message_t msg;
cmd.command = (uint8_t)command;
cmd.confirmation = confirmation;
cmd.param1 = param1;
cmd.param2 = param2;
cmd.param3 = param3;
cmd.param4 = param4;
cmd.target_system = uasId;
cmd.target_component = component;
mavlink_msg_command_short_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &cmd);
sendMessage(msg);
}
void UAS::executeCommand(MAV_CMD command, int confirmation, float param1, float param2, float param3, float param4, float param5, float param6, float param7, int component)
{
mavlink_message_t msg;
mavlink_command_long_t cmd;