public XsDeviceMode(XsDeviceMode other) : this(xsensdeviceapiPINVOKE.new_XsDeviceMode__SWIG_3(XsDeviceMode.getCPtr(other)), true)
{
if (xsensdeviceapiPINVOKE.SWIGPendingException.Pending)
{
throw xsensdeviceapiPINVOKE.SWIGPendingException.Retrieve();
}
}
public bool setDeviceMode(XsDeviceMode mode)
{
bool ret = xsensdeviceapiPINVOKE.XsDevice_setDeviceMode(swigCPtr, XsDeviceMode.getCPtr(mode));
if (xsensdeviceapiPINVOKE.SWIGPendingException.Pending)
{
throw xsensdeviceapiPINVOKE.SWIGPendingException.Retrieve();
}
return(ret);
}
public XsDeviceMode deviceMode()
{
XsDeviceMode ret = new XsDeviceMode(xsensdeviceapiPINVOKE.XsDevice_deviceMode(swigCPtr), true);
return(ret);
}
internal static global::System.Runtime.InteropServices.HandleRef getCPtr(XsDeviceMode obj)
{
return((obj == null) ? new global::System.Runtime.InteropServices.HandleRef(null, global::System.IntPtr.Zero) : obj.swigCPtr);
}
private void btnScan_Click(object sender, EventArgs e)
{
rtbSteps.Text = "Scanning for devices...";
btnScan.Enabled = false;
Update();
GT_Senxda.m_object.reset();
GT_Senxda.m_object.scanPorts();
if (GT_Senxda.m_object._DetectedDevices.Count > 0)
{
rtbSteps.Text = string.Format("Found {0} device(s)\n", GT_Senxda.m_object._DetectedDevices.Count);
XsPortInfo portInfo = GT_Senxda.m_object._DetectedDevices[0];
if (portInfo.deviceId().isMtMk4() || portInfo.deviceId().isFmt_X000() || portInfo.deviceId().isMt9c() || portInfo.deviceId().isLegacyMtig())
{
rtbSteps.Text += "Opening port...\n";
GT_Senxda.m_object.openPort(portInfo);
MasterInfo ai = new MasterInfo(portInfo.deviceId());
ai.ComPort = portInfo.portName();
ai.BaudRate = portInfo.baudrate();
_measuringDevice = GT_Senxda.m_object.getDevice(ai.DeviceId);
ai.ProductCode = new XsString(_measuringDevice.productCode());
// Print information about detected MTi / MTx / MTmk4 device
rtbSteps.Text += string.Format("Found a device with id: {0} @ port: {1}, baudrate: {2}\n", _measuringDevice.deviceId().toXsString().toString(), ai.ComPort.toString(), ai.BaudRate);
// Create and attach callback handler to device
_myMtCallback = new MyMtCallback();
_measuringDevice.addCallbackHandler(_myMtCallback);
ConnectedMtData mtwData = new ConnectedMtData();
// connect signals
_myMtCallback.DataAvailable += new EventHandler <DataAvailableArgs>(_callbackHandler_DataAvailable);
// Put the device in configuration mode
rtbSteps.Text += "Putting device into configuration mode...\n";
if (!_measuringDevice.gotoConfig()) // Put the device into configuration mode before configuring the device
{
rtbSteps.Text = "Could not put device into configuration mode. Aborting.";
return;
}
// Configure the device. Note the differences between MTix and MTmk4
rtbSteps.Text += "Configuring the device...\n";
if (_measuringDevice.deviceId().isMt9c() || _measuringDevice.deviceId().isLegacyMtig())
{
XsOutputMode outputMode = XsOutputMode.XOM_Orientation; // output orientation data
XsOutputSettings outputSettings = XsOutputSettings.XOS_OrientationMode_Quaternion; // output orientation data as quaternion
XsDeviceMode deviceMode = new XsDeviceMode(100); // make a device mode with update rate: 100 Hz
deviceMode.setModeFlag(outputMode);
deviceMode.setSettingsFlag(outputSettings);
// set the device configuration
if (!_measuringDevice.setDeviceMode(deviceMode))
{
rtbSteps.Text = "Could not configure MTix device. Aborting.";
return;
}
}
else if (_measuringDevice.deviceId().isMtMk4() || _measuringDevice.deviceId().isFmt_X000())
{
XsOutputConfigurationArray configArray = new XsOutputConfigurationArray();
if (_measuringDevice.deviceId().isMtMk4_1() || _measuringDevice.deviceId().isMtMk4_10() || _measuringDevice.deviceId().isMtMk4_100() || _measuringDevice.deviceId().isFmt1010())
{
configArray.push_back(new XsOutputConfiguration(XsDataIdentifier.XDI_PacketCounter, 0));
configArray.push_back(new XsOutputConfiguration(XsDataIdentifier.XDI_SampleTimeFine, 0));
configArray.push_back(new XsOutputConfiguration(XsDataIdentifier.XDI_DeltaV, 100));
configArray.push_back(new XsOutputConfiguration(XsDataIdentifier.XDI_DeltaQ, 100));
configArray.push_back(new XsOutputConfiguration(XsDataIdentifier.XDI_MagneticField, 100));
}
else
{
configArray.push_back(new XsOutputConfiguration(XsDataIdentifier.XDI_PacketCounter, 0));
configArray.push_back(new XsOutputConfiguration(XsDataIdentifier.XDI_SampleTimeFine, 0));
configArray.push_back(new XsOutputConfiguration(XsDataIdentifier.XDI_Quaternion, 100));
configArray.push_back(new XsOutputConfiguration(XsDataIdentifier.XDI_DeltaV, 100));
configArray.push_back(new XsOutputConfiguration(XsDataIdentifier.XDI_DeltaQ, 100));
configArray.push_back(new XsOutputConfiguration(XsDataIdentifier.XDI_MagneticField, 100));
configArray.push_back(new XsOutputConfiguration(XsDataIdentifier.XDI_StatusWord, 0));
}
if (!_measuringDevice.setOutputConfiguration(configArray))
{
rtbSteps.Text = "Could not configure MTmk4 device. Aborting.";
return;
}
}
else
{
rtbSteps.Text = "Unknown device while configuring. Aborting.";
return;
}
// Put the device in measurement mode
rtbSteps.Text += "Putting device into measurement mode...\n";
if (!_measuringDevice.gotoMeasurement())
{
rtbSteps.Text = "Could not put device into measurement mode. Aborting.";
return;
}
btnRecord.Enabled = true;
}
timer1.Interval = 20;
timer1.Enabled = true;
}
else
{
rtbSteps.Text = "No devices detected. Press 'Scan' to retry.";
btnScan.Enabled = true;
}
}
public void Start()
{
if (state != XSensState.NotStarted)
{
Debug.Log("[XSensGyroscope] Cannot call Start twice! Ignoring...\n");
return;
}
this.UpdateState(XSensState.Starting);
_xda.scanPorts();
Debug.LogFormat("[XSensGyroscope] Found {0} device(s)\n", _xda._DetectedDevices.Count);
if (_xda._DetectedDevices.Count > 0)
{
XsPortInfo portInfo = _xda._DetectedDevices[0];
if (portInfo.deviceId().isMtMk4())
{
_xda.openPort(portInfo);
MasterInfo ai = new MasterInfo(portInfo.deviceId());
ai.ComPort = portInfo.portName();
ai.BaudRate = portInfo.baudrate();
_measuringDevice = _xda.getDevice(ai.DeviceId);
ai.ProductCode = new XsString(_measuringDevice.productCode());
// Print information about detected MTi / MTx / MTmk4 device
Debug.LogFormat("[XSensGyroscope] Found a device with id: {0} @ port: {1}, baudrate: {2}\n",
_measuringDevice.deviceId().toXsString().toString(), ai.ComPort.toString(), ai.BaudRate);
// Create and attach callback handler to device
_myMtCallback = new MyMtCallback();
_measuringDevice.addCallbackHandler(_myMtCallback);
ConnectedMtData mtwData = new ConnectedMtData();
// connect signals
_myMtCallback.DataAvailable += new EventHandler<DataAvailableArgs>(DataAvailable);
// Put the device in configuration mode
Debug.Log("[XSensGyroscope] Putting device into configuration mode...\n");
if (!_measuringDevice.gotoConfig()) // Put the device into configuration mode before configuring the device
{
Debug.Log("[XSensGyroscope] Could not put device into configuration mode. Aborting.");
this.UpdateState(XSensState.Failed);
return;
}
// Configure the device. Note the differences between MTix and MTmk4
Debug.Log("[XSensGyroscope] Configuring the device...\n");
if (_measuringDevice.deviceId().isMt9c())
{
XsOutputMode outputMode = XsOutputMode.XOM_Orientation; // output orientation data
XsOutputSettings outputSettings = XsOutputSettings.XOS_OrientationMode_Quaternion; // output orientation data as quaternion
XsDeviceMode deviceMode = new XsDeviceMode(100); // make a device mode with update rate: 100 Hz
deviceMode.setModeFlag(outputMode);
deviceMode.setSettingsFlag(outputSettings);
// set the device configuration
if (!_measuringDevice.setDeviceMode(deviceMode))
{
Debug.Log("[XSensGyroscope] Could not configure MTix device. Aborting.");
this.UpdateState(XSensState.Failed);
return;
}
}
else if (_measuringDevice.deviceId().isMtMk4())
{
XsOutputConfiguration quat = new XsOutputConfiguration(XsDataIdentifier.XDI_Quaternion, 0);
XsOutputConfigurationArray configArray = new XsOutputConfigurationArray();
configArray.push_back(quat);
if (!_measuringDevice.setOutputConfiguration(configArray))
{
Debug.Log("[XSensGyroscope] Could not configure MTmk4 device. Aborting.");
this.UpdateState(XSensState.Failed);
return;
}
}
else
{
Debug.Log("[XSensGyroscope] Unknown device while configuring. Aborting.");
this.UpdateState(XSensState.Failed);
return;
}
// Put the device in measurement mode
Debug.Log("[XSensGyroscope] Putting device into measurement mode...\n");
if (!_measuringDevice.gotoMeasurement())
{
Debug.Log("[XSensGyroscope] Could not put device into measurement mode. Aborting.");
this.UpdateState(XSensState.Failed);
return;
}
this.UpdateState(XSensState.Started);
}
}
}
public void Start()
{
if (state != XSensState.NotStarted)
{
Debug.Log("[XSensGyroscope] Cannot call Start twice! Ignoring...\n");
return;
}
this.UpdateState(XSensState.Starting);
_xda.scanPorts();
Debug.LogFormat("[XSensGyroscope] Found {0} device(s)\n", _xda._DetectedDevices.Count);
if (_xda._DetectedDevices.Count > 0)
{
XsPortInfo portInfo = _xda._DetectedDevices[0];
if (portInfo.deviceId().isMtMk4())
{
_xda.openPort(portInfo);
MasterInfo ai = new MasterInfo(portInfo.deviceId());
ai.ComPort = portInfo.portName();
ai.BaudRate = portInfo.baudrate();
_measuringDevice = _xda.getDevice(ai.DeviceId);
ai.ProductCode = new XsString(_measuringDevice.productCode());
// Print information about detected MTi / MTx / MTmk4 device
Debug.LogFormat("[XSensGyroscope] Found a device with id: {0} @ port: {1}, baudrate: {2}\n",
_measuringDevice.deviceId().toXsString().toString(), ai.ComPort.toString(), ai.BaudRate);
// Create and attach callback handler to device
_myMtCallback = new MyMtCallback();
_measuringDevice.addCallbackHandler(_myMtCallback);
ConnectedMtData mtwData = new ConnectedMtData();
// connect signals
_myMtCallback.DataAvailable += new EventHandler <DataAvailableArgs>(DataAvailable);
// Put the device in configuration mode
Debug.Log("[XSensGyroscope] Putting device into configuration mode...\n");
if (!_measuringDevice.gotoConfig()) // Put the device into configuration mode before configuring the device
{
Debug.Log("[XSensGyroscope] Could not put device into configuration mode. Aborting.");
this.UpdateState(XSensState.Failed);
return;
}
// Configure the device. Note the differences between MTix and MTmk4
Debug.Log("[XSensGyroscope] Configuring the device...\n");
if (_measuringDevice.deviceId().isMt9c())
{
XsOutputMode outputMode = XsOutputMode.XOM_Orientation; // output orientation data
XsOutputSettings outputSettings = XsOutputSettings.XOS_OrientationMode_Quaternion; // output orientation data as quaternion
XsDeviceMode deviceMode = new XsDeviceMode(100); // make a device mode with update rate: 100 Hz
deviceMode.setModeFlag(outputMode);
deviceMode.setSettingsFlag(outputSettings);
// set the device configuration
if (!_measuringDevice.setDeviceMode(deviceMode))
{
Debug.Log("[XSensGyroscope] Could not configure MTix device. Aborting.");
this.UpdateState(XSensState.Failed);
return;
}
}
else if (_measuringDevice.deviceId().isMtMk4())
{
XsOutputConfiguration quat = new XsOutputConfiguration(XsDataIdentifier.XDI_Quaternion, 0);
XsOutputConfigurationArray configArray = new XsOutputConfigurationArray();
configArray.push_back(quat);
if (!_measuringDevice.setOutputConfiguration(configArray))
{
Debug.Log("[XSensGyroscope] Could not configure MTmk4 device. Aborting.");
this.UpdateState(XSensState.Failed);
return;
}
}
else
{
Debug.Log("[XSensGyroscope] Unknown device while configuring. Aborting.");
this.UpdateState(XSensState.Failed);
return;
}
// Put the device in measurement mode
Debug.Log("[XSensGyroscope] Putting device into measurement mode...\n");
if (!_measuringDevice.gotoMeasurement())
{
Debug.Log("[XSensGyroscope] Could not put device into measurement mode. Aborting.");
this.UpdateState(XSensState.Failed);
return;
}
this.UpdateState(XSensState.Started);
}
}
}
