示例#1
0
int main(void)
	{
	//*******************************************************************
	Init();
	TMRInit(2);			// Initialize Timer interface with Priority=2
	BLIInit();			// Initialize Signal interface
	ADCInit(3);			// Initialize ADC
	UARTInitTX(6, 350);	// Initialize UART1 for TX
	// This initialization routine accepts BaudRate in multiples
	// of 2400 bps; Thus:
	// BaudRate =   1	=>   2400 bps
	// BaudRate =   2	=>   4800 bps
	// ...
	// BaudRate =  48	=> 115200 bps
	//------------------------------------------------------------
	// High speed
	//------------------------------------------------------------
	// BaudRate =  100	=>   250,000 bps
	// BaudRate =  200	=>   500,000 bps
	// BaudRate =  250	=>   625,000 bps
	// BaudRate =  350	=>   833,333 bps
	// BaudRate =  500	=> 1,250,000 bps
	// BaudRate = 1000	=> 2,500,000 bps
	//*******************************************************************
	struct 
		{
		float			V;
		uint			Raw;
		uint			Stat;
		} UData;

	int i = 0;
	int j = 0;
	BLISignalON();
	while(j < 10)
		{
		TMRDelay(10);
		//--------------------------
		UData.V		= ADCGetBatteryVoltage();
		UData.Raw 	= ADCGetRawSample();
		UData.Stat	= ADCGetBatteryStatus();
		//--------------------------
		UARTPostWhenReady((uchar*)&UData, sizeof(UData));
		i++;
		//--------------------------
		if (i >= 100)
			{
			UARTPostWhenReady(NULL, 0);
			BLISignalFlip();
			//------------------------
			i = 0;
			j++;
			}
		TMRDelay(10);
		}


	return 1;
	}
示例#2
0
int main(void)
	{
	//*******************************************************************
	Init();
	TMRInit(2);		// Initialize Timer interface with Priority=2
	BLIInit();		// Initialize Signal interface
	//*******************************************************************
	//_T1IE 	= 0; 	// Temporarily disable Timer1 interrupt
	//*******************************************************************
	LogInit();			// Initialize Data Logger	
	//*******************************************************************
	// Initialize UART for RX on IPL=6 at
	//-------------------------------------------------------------------
	// BaudRate =   48	=>   115,200 bps
	//--------------------------------------
	// BaudRate =  100	=>   250,000 bps
	// BaudRate =  200	=>   500,000 bps
	// BaudRate =  250	=>   625,000 bps
	// BaudRate =  350	=>   833,333 bps
	// BaudRate =  500	=> 1,250,000 bps
	// BaudRate = 1000	=> 2,500,000 bps
	//-------------------------------------------------------------------
	// Switch 1 controls UART speed - if the switch is in the "On"
	// position, UART initialized for high speed (833,333 bps), otherwise
	// UART is initialized at low speed (115,200 bps) compatible with
	// XBee.
	//-------------------------------------------------------------------
	if (_SW1)
		UARTInitRX(6, 350);		// High speed:	833,333 bps
	else
		UARTInitRX(6, 48);		// Low speed:	115,200 bps
	//*******************************************************************
	UARTDataBlock*	DataBlock = NULL;
	UARTRXStat		Stats;
	WORD			RC = 0;
	int				i;
	//-----------------------------------
	// Start Async read on UART in BLOCK mode
	while ( !(RC = UARTRXStartAsyncRead(64, TRUE, TRUE)) ); 		
	for (i = 0; i < 10; i++)
		{
		DataBlock = UARTReadBlock();
		
		BLISignalON();
		TMRDelay(50);
		UARTFreeBlock(DataBlock);		
		BLISignalOFF();
		}
	UARTRXStopAsyncRead();

	UARTRXGetStat(&Stats);
	
	//------------------------------
	i = sizeof(byte*);
	//------------------------------
	while(1);
	
	return 0;
	}
示例#3
0
int main(void)
{

    //*******************************************************************
    DBGInit();		// Initialize Debug interface

    DBG_1_ON();
    Init();
    DBG_1_Flip();

    TMRInit(2);		// Initialize Timer interface with Priority=2
    BLIInit();		// Initialize Signal interface
    //*******************************************************************
    ulong	i;

    DBG_1_ON();
    BLIAsyncMorse("SSS", 3);
    while(1)
    {
        TMRDelay(50);		// Delay 50 msec
        DBG_1_Flip();
        DBG_2_Flip();
    }


    /*
    	BLIAsyncStart(30, 30);
    	while(1)
    		{TMRDelay(30);}
    */
    BLISignalON();
    while (1)
    {
//		TMRDelay(50);
        for (i=0; i < 1000001; i++);
        BLISignalFlip();
    }

    while(1);
    {
        for (i=0; i < 1000001; i++);
        BLISignalFlip();
    }


    while(1)
    {
        BLIAsyncStart(500, 1000);
        TMRDelay(5000);		// Delay 5 sec
        //--------------------------------
        BLIAsyncMorse("SOS", 3);
        TMRDelay(5000);		// Delay 5 sec
    }
    //*******************************************************************

    return 1;
}
示例#4
0
int main(void)
	{
	//*******************************************************************
	Init();
	TMRInit(2);		// Initialize Timer interface with Priority=2
	BLIInit();		// Initialize Signal interface
	//*******************************************************************
	//_T1IE 	= 0; 	// Temporarily disable Timer1 interrupt
	//*******************************************************************
	LogInit();			// Initialize Data Logger	
	UARTInitRX(6, 48);	// Initialize UART RX at 115,200 baud
	//*******************************************************************
	UARTDataBlock*	DataBlock = NULL;
	UARTRXStat		Stats;
	WORD			RC = 0;
	int				i;
	//-----------------------------------
	// Start Async read on UART in BLOCK mode
	while ( !(RC = UARTRXStartAsyncRead(64, TRUE, TRUE)) ); 		
	for (i = 0; i < 10; i++)
		{
		DataBlock = UARTReadBlock();
		
		BLISignalON();
		TMRDelay(50);
		UARTFreeBlock(DataBlock);		
		BLISignalOFF();
		}
	UARTRXStopAsyncRead();

	UARTRXGetStat(&Stats);
	
	//------------------------------
	i = sizeof(byte*);
	//------------------------------
	while(1);
	
	return 0;
	}
示例#5
0
int main(void)
	{
	//*******************************************************************
	Init();
	TMRInit(2);		// Initialize Timer interface with Priority=2
	BLIInit();		// Initialize Signal interface
	//*******************************************************************
	//_T1IE 	= 0; 	// Temporarily disable Timer1 interrupt
	//*******************************************************************
	LogInit();	// Initialize Data Logger	
	//*******************************************************************
	//-------------------------------------------------------------------
	#define		MaxRec		60
	//-------------------------------------------------------------------
	struct
		{
		DWORD	TS;
		WORD	Index;
		char	filler[506];
		}	Data;
	//-------------------------------------------------------------------
	uint	i;
	for (i = 0; i < sizeof(Data.filler); i++)
		{
		Data.filler[i] = 0;
		}
	//-------------------------------------------------------------------
	DWORD	TimeStart;
	float	TimePoints[MaxRec];
//	WORD	TimeIndex[MaxRec];
	//-------------------------------------------------------------------
	char		pFN[15];

	
	WORD			RC;
	
	uint			ReadCnt;
	FSFILE			File;
	//*******************************************************************
	BLISignalON();
	//------------------------------
	// Create (Open) Log file for Writing and Reading 
	//------------------------------
	RC = LogNewFile(&File);
	while ( RC != LE_GOOD );
	//------------------------------
	// Retrieve and save for future new log file name 
	//------------------------------
	RC = FS_GetName(pFN, 15, &File);
	while ( RC != LE_GOOD );
	//------------------------------
	// Write sample data to file
	//------------------------------
	for (i=0; i < MaxRec; i++)
		{
		Data.Index 	= i;
		Data.TS		= TMRGetTS();
	   	RC = FS_WriteSector(&File, &Data);
		while (CE_GOOD != RC);
		}
	//------------------------------
	// Check position in the file
	//------------------------------
   	i = FS_GetPosition (&File);
	while (i != 512*MaxRec);
	//------------------------------
	// Close the file - save changes
	//------------------------------
	RC = FS_Flush(&File);
   	while ( RC != CE_GOOD );
	//------------------------------

	//------------------------------
	// Open file for Reading 
	//------------------------------
	RC = FS_CreateFile(pFN, FS_READ_ONLY, &File);
	while ( RC != CE_GOOD );
	//------------------------------
	// Reed records
	//------------------------------
	for (i=0; i < MaxRec; i++)
		{
	   	RC = FS_Read (&File, &Data, sizeof(Data), &ReadCnt);
		while (CE_GOOD != RC);
		//--------------------------
//		TimeIndex[i] = Data.Index;
		//--------------------------
		if (0 == i)
			TimeStart = Data.TS;
		//--------------------------
		TimePoints[i] = (Data.TS - TimeStart) * TMRGetTSRate() * 1000.0;	// in msec
		//--------------------------
		TimeStart = Data.TS;
		}
	//------------------------------
	// Close the file - save changes
	//------------------------------
	RC = FS_Flush(&File);
   	while ( RC != CE_GOOD );
	//*******************************************************************
	BLISignalOFF();
	//------------------------------
	i = 1 + i;
	//------------------------------
	while(1);
	return 0;
	}
示例#6
0
int main(void)
	{
	// <editor-fold defaultstate="collapsed" desc="Initialization of HW components/modules">
	//*******************************************************************
	// Initialization of HW components/modules
	//===================================================================
	Init();
	TMRInit(2);			// Initialize Timer interface with Priority=2
	BLIInit();			// Initialize Signal interface
	//--------------------------
	BLIAsyncMorse("S", 1);	// dit-dit-dit
	MCMInitT(2.5, 2500);	// Initialize Motor Control for PPM with setting
							// Throttle to HIGH for delay interval to let ESC
							// capture Throttle range
	BLIAsyncMorse("O", 1);	// dah-dah-dah
	//--------------------------
	ADCInit(3);			// Initialize ADC to control battery
	//--------------------------
	RCInit(4);			// Initialize Receiver interface with Priority=4
	//--------------------------
	I2CInit(5, 1);		// Initialize I2C1 module with IPL=5 and Fscl=400 KHz
	//--------------------------
	UARTInitTX(6, 350);	// Initialize UART1 for TX on IPL=6 at 
	// BaudRate =   48	=>   115,200 bps	- ZigBEE
	//--------------------------------------
	// BaudRate =  100	=>   250,000 bps
	// BaudRate =  200	=>   500,000 bps
	// BaudRate =  250	=>   625,000 bps
	// BaudRate =  350	=>   833,333 bps	- SD Logger
	// BaudRate =  500	=> 1,250,000 bps
	// BaudRate = 1000	=> 2,500,000 bps
	//*******************************************************************
	// <editor-fold defaultstate="collapsed" desc="Initializing IMU">
	//==================================================================
	#ifdef __MAG_Use__
	//--------------------------------------------------------------
	// Initialize Magnetometer
	//--------------------------------------------------------------
	if (HMCInit(6, 1, 0))	// Initialize magnetic Sensor
							// ODR  = 6 (max, 75 Hz),
							// Gain = 2 (1.3 Gs)
							// DLPF = 0 (no averaging)
		BLIDeadStop("EM", 2);
	#endif
	//*******************************************************************
	BLIAsyncMorse(	"I", 1);	// dit - dit
	//==================================================================
	#ifdef __MXB_Use__
	//--------------------------------------------------------------
	// Initialize MaxBotix range finder
	//--------------------------------------------------------------
	if ( 0 == MXBInit(3, &TM.MXB) )
		BLIDeadStop("ES", 2);
	#endif
	//==================================================================
	// Initialize motion sensor - rotation rate baseline established at
	// this time - QUAD should be motionless!!!
	//------------------------------------------------------------------
	if ( MPUInit(0, 3 ) )	// Initialize motion Sensor
		// 1 kHz/(0+1) = 1000 Hz (1ms)
		// DLPF=3 => Bandwidth 44 Hz (delay: 4.9 msec)
		BLIDeadStop("EA", 2);
	//------------------------------------------------------------------
	BLIAsyncStop();
	//==================================================================
	// </editor-fold>

	//==================================================================
	BLISignalON();
	TMRDelay(2000); 	// Wait for extra 2 sec - to let ESC arm...
	// (finish the song :) )
	BLISignalOFF();
	//===================================================================
	// </editor-fold>

	//*******************************************************************
	// Quadrocopter control variables
	//-------------------------------------------------------------------
	ulong		StartTS		= 0;
	ulong		StepTS;

	RCData		RCNative;		// Control input from Receiver
	RCData		RC;				// Smoothed control input used in all
								// control calculations
	
	DCMData		IMU;			// Orientation data from DCM
	
	MCMData		MC;				// Motor control Variables

	float		BatNomV		= ADCGetBatteryNomVoltage();

	ulong		Alarm		= 0;
	
	#ifdef __CB_To_Model_Front__
		// RC native input rotated to adjust CB orientation to model front
		RCData	RC_CB_To_Model_Front;
		// Control board front does not coincide with the model front
		Matrix	CB_To_Model;
		// Build rotation matrix to adjust for orientation discrepancy
		MatrixYawRotation(__CB_To_Model_Front__, &CB_To_Model);
	#else
		// If CB orientation coincides with the fron of the model
		// we will use Native RC input as base for RC input to
		// Quadrocopter control module
		#define RC_CB_To_Model_Front  RCNative
	#endif


Re_Start:
	//==================================================================
	// Wait for the Receiver ARMing: Control should go Down and then Up
	//------------------------------------------------------------------
	BLIAsyncMorse(	"O", 1);	// doh - doh - doh
	RCSymArm();

	//==================================================================
	BLIAsyncMorse("T", 1);			// doh
	MPUAsyncStop();
	if (MPUCalibrate() != MPU_OK)	
		// Gyro Calibration filed
		BLIDeadStop("EA", 2);
	BLIAsyncStop();
	//==================================================================
	// Start IMU and wait until orientation estimate stabilizes
	//------------------------------------------------------------------
	BLIAsyncMorse(	"E", 1);		// dit
	IMUInit();
	//------------------------------------------------------------------
	QCMReset();			// Initialize (reset) QCM variables
	//------------------------------------------------------------------
	BLIAsyncStop();
	//==================================================================

	//******************************************************************
	// Control variables used to smooth RC receiver data
	//------------------------------------------------------------------
	// Reset Smothed RC data 
	//-------------------------------------------------------------------
	RC.Roll		= 0.0;
	RC.Pitch	= 0.0;
	RC.Yaw		= 0.0;
	//------------------------
	RC.Throttle	= 0.0;
	//------------------------
	RC.Control	= 1;
	//-------------------------------------------------------------------
	
	//*******************************************************************
	// Quadrocopter Control Loop
	//-------------------------------------------------------------------
	BLISignalON();
	while (1)
		{
		// Sets the "frquency" of Control Loop
		Alarm = TMRSetAlarm(10);	// Set Alarm 10 msec in the future
		//============================================================
		// Read commands from receiver - non-blocking call!
		// (we will get out of this call even if connection to the
		// receiver is lost!)
		//============================================================
		// <editor-fold defaultstate="collapsed" desc="Process Receiver feed">
		if ( RCSymRead(&RCNative) )
			{
			//------------------------------------------------------------
			// Normalize Roll and Pitch control input from RC Receiver to
			// +/- 0.35 rad (~20 degrees) and Yaw control input to
			// +/- 3.00 rad (~172 degrees)
			//------------------------------------------------------------
			RCNative.Roll 	= 0.35 * RCNative.Roll;
			RCNative.Pitch	= 0.35 * RCNative.Pitch;
			RCNative.Yaw	= 3.00 * RCNative.Yaw;
			#ifdef __CB_To_Model_Front__
				{
				// Control board front does not coincide with the model front
				Vector	RCInput;
				Vector	RCRotated;
				VectorSet(RCNative.Roll, RCNative.Pitch, RCNative.Yaw, &RCInput);
				MatrixTimesVector(&CB_To_Model, &RCInput, &RCRotated);
				RC_CB_To_Model_Front.Roll		= RCRotated.X;
				RC_CB_To_Model_Front.Pitch		= RCRotated.Y;
				RC_CB_To_Model_Front.Yaw		= RCRotated.Z;
				}
			#endif
			}
		//============================================================
		// Smooth RC data 
		//------------------------------------------------------------
		// Roll, Pitch, and Yaw are smoothed with the IIR(8)
		//------------------------------------------------------------
		RC.Roll		= (RC.Roll	* 7.0	+ RC_CB_To_Model_Front.Roll	) * 0.125;	// 1/8 = 0.125
		RC.Pitch	= (RC.Pitch	* 7.0 	+ RC_CB_To_Model_Front.Pitch) * 0.125;
		RC.Yaw		= (RC.Yaw	* 7.0	+ RC_CB_To_Model_Front.Yaw	) * 0.125;
		//------------------------------------------------------------
		// Throttle is smoothed with the IIR(4) and adjusted to
		// account for actual battery voltage. This is done to
		// improve "hovering" when throttle stick is not moving.
		//------------------------------------------------------------
		// Adjust Native (from RC) throttle to a value corresponding
		float BatAdjTh	= RCNative.Throttle	* BatNomV / ADCGetBatteryVoltage();
		//-----------------------------------------
		RC.Throttle	= (RC.Throttle * 3	+ BatAdjTh) * 0.25;		// 1/4 = 0.25
		//-----------------------------------------
		RC.Control	= RCNative.Control;
		// </editor-fold>
		//============================================================

		//============================================================
		// Implement Motor Cut-Off if RC Control is LOW
		//============================================================
		// <editor-fold defaultstate="collapsed" desc="Process RC Control">
		if ( 0 == RC.Control )
			{
			// Yes, Control is reliably low!
			//--------------------------------------------
			// Override motor control
			//--------------------------------------------
			MC.F = MC.B = MC.L = MC.R = 0;
			MCMSet(&MC);
			//--------------------------------------------
			// Reset Timing series
			StartTS = 0;
			//--------------------------------------------
			// Flight terminated, post EOF to Data Logger
			//--------------------------------------------
			TMRDelay(10);	// Wait for pipe to clear
			UARTPostIfReady( NULL, 0);
			// ... and again - to be sure!
			TMRDelay(10);	// Wait for pipe to clear
			UARTPostIfReady( NULL, 0);
			//----------------------------------
			goto Re_Start;
			}
		// </editor-fold>
		//============================================================

		//============================================================
		// Obtain and process battery charge status
		//============================================================
		// <editor-fold defaultstate="collapsed" desc="Process Battery level">
		float BatteryCharge	= QCMBatteryMgmt();	
		if (BatteryCharge < 0.35)	// BC < 35%
			{
			float MaxLevel = 2.0 * BatteryCharge;
			if (RC.Throttle > MaxLevel)
				RC.Throttle = MaxLevel;
			}
		// </editor-fold>
		//============================================================

		//============================================================
		// Read current orientation and sensor data from the IMU
		// (non-blocking call)
		//============================================================
		if (IMU_OK == IMUGetUpdate(&IMU))
			{
			// Calculate motor control based
			// upon IMU data
			QCMPerformStep(&RC, &IMU, &MC);
			}
		else
			{
			// IMU Failed to provide update -
			// set Motor Control to native throttle
			MC.F = MC.B = MC.L = MC.R = RC.Throttle;
			}
		//============================================================

		//*****************************************
		// Implement Motor Cut-Off if model is
		// dangerously tilted (> 60 degrees) while
		// RC Throttle is low - to protect props 
		//----------------------------------------
		if (IMU.Incl <= 0.5 && RC.Throttle <= 0.40)
			{
			// Override motor control
			MC.F = MC.B = MC.L = MC.R = 0;
			}
		//----------------------------------------

		//*****************************************
		// Update motor control
		//*****************************************
		MCMSet(&MC);
		//-----------------------------------------
		
		//===========================================================
		// Load and post telemetry data (non-blocking call)
		//-----------------------------------------------------------
		// <editor-fold defaultstate="collapsed" desc="Populating Telemetry">
		StepTS =  TMRGetTS(); 
		//-----------------------------------------
		if ( 0 == StartTS )
			// Time stamp of cycle start!
			StartTS =  StepTS;
		//-----------------------------------------
		TM.TS			= StepTS - StartTS;
		//----------------------
		TM.Roll			= IMU.Roll;
		TM.Pitch		= IMU.Pitch;
		TM.Yaw			= IMU.Yaw;
		TM.Inclination	= IMU.Incl;
		TM.Azimuth		= IMU.Azimuth;
		//----------------------
		#ifdef  _TMReport_GYRO_
			#ifdef	_TMReport_GYRO_Rotated
			//------------------------------------------------------
			// We rotate Gyro vector using "partial" DCM built using
			// only Roll and Pitch angles as the actual Yaw does not
			// affect Angualr Velocity by axis
			//------------------------------------------------------
			Matrix		NoYawDCM;
			// Generate partial rotation matrix
			MatrixEulerRotation(IMU.Roll, IMU.Pitch, 0.0, &NoYawDCM);
			// Rotate Gyro vector
			MatrixTimesVector(&NoYawDCM, &IMU.GyroRate, &TM.Gyro);
			#else
			// Just report native Gyro data
			VectorCopy(&IMU.GyroRate, &TM.Gyro);
			#endif
		#endif
		//----------------------
		#ifdef  _TMReport_ACC_
		// Just report native Gyro data
		VectorCopy(&IMU.Gravity, &TM.Acc);
		#endif
		//----------------------
		TM.RollDer		= QSD.RollDer;
		TM.PitchDer		= QSD.PitchDer;
		TM.YawDer		= QSD.YawDer;
		//----------------------
		TM.RC_Throttle	= RC.Throttle;
		TM.RC_Roll		= RC.Roll;
		TM.RC_Pitch		= RC.Pitch;
		TM.RC_Yaw		= RC.Yaw;
		//----------------------
		#ifdef _TMReport_NativeRC_
		TM.RCN_Throttle	= RCNative.Throttle;
		TM.RCN_Roll		= RCNative.Roll;
		TM.RCN_Pitch	= RCNative.Pitch;
		TM.RCN_Yaw		= RCNative.Yaw;
		#endif
		//----------------------
		#ifdef __MXB_Use__
		MXBRead(&TM.MXB);
		#endif
		//----------------------
		#ifdef _TMReport_PID_
		#ifdef _TMReport_PID_Details
		TM.DRProp		= QSD.DeltaRollProp;
		TM.DRDiff		= QSD.DeltaRollDiff;
		TM.DRInt		= QSD.DeltaRollInt;
		#endif
		TM.DRTot		= QSD.DeltaRoll;
		//-------------
		#ifdef _TMReport_PID_Details
		TM.DPProp		= QSD.DeltaPitchProp;
		TM.DPDiff		= QSD.DeltaPitchDiff;
		TM.DPInt		= QSD.DeltaPitchInt;
		#endif
		TM.DPTot		= QSD.DeltaPitch;
		//-------------
		#ifdef _TMReport_PID_Details
		TM.DYProp		= QSD.DeltaYawProp;
		TM.DYDiff		= QSD.DeltaYawDiff;
		TM.DYInt		= QSD.DeltaYawInt;
		#endif
		TM.DYTot		= QSD.DeltaYaw;
		#endif
		//----------------------
		TM.Throttle		= QSD.Throttle;				// Real Throttle
		//----------------------
		TM.Voltage 		= QSD.Voltage;
		// </editor-fold>
		//===========================================================
		UARTPostIfReady( (unsigned char *) &TM, sizeof(TM)	);
		//===========================================================
		// Insert controlled "delay" to slow down the Control Loop
		TMRWaitAlarm(Alarm);
		}
	//*******************************************************************
	return 1;
	}
示例#7
0
int main(void)
	{
	//*******************************************************************
	Init();
	TMRInit(2);		// Initialize Timer interface with Priority=2
	BLIInit();		// Initialize Signal interface
	//*******************************************************************
	//_T1IE 	= 0; 	// Temporarily disable Timer1 interrupt
	//*******************************************************************
	LogInit();			// Initialize Data Logger
	//*******************************************************************
	uint	i;
	char		RData[30];
	char		CData[30];

	for (i = 0; i < 30; i++)
		{
		RData[i] = CData[i] = 0;
		}

	char*		pFN		= "log1.txt";
	void*		pWData	= &"01 02 03 04 05 06 07 08 09";
	//-------------------------------------------------------------------
	
	CETYPE			RC;
	uint			ReadCnt;
	
	FSFILE			File;
	//*******************************************************************
	BLISignalON();
	//------------------------------
	// Create (Open) file for Writing and Reading 
	//------------------------------
	RC = FS_CreateFile(pFN, FS_CREATE_NEW, &File);
	while ( RC != CE_GOOD );
	//------------------------------
	// Write sample string to file
	//------------------------------
   	RC = FS_Write (&File, pWData, 26 );
	while (CE_GOOD != RC);
	//------------------------------
	// Check position in the file
	//------------------------------
   	i = FS_GetPosition (&File);
	while (i != 26);
	//------------------------------
	// Seek to start
	//------------------------------
   	FS_SeekStart(&File);
	//------------------------------
	// Reed from start
	//------------------------------
   	RC = FS_Read (&File, RData, 26, &ReadCnt);
	while (CE_GOOD != RC);
	//------------------------------
	// Close the file - save changes
	//------------------------------
	RC = FS_Flush(&File);
   	while ( RC != CE_GOOD );
	//------------------------------

	//------------------------------
	// Open file for Reading 
	//------------------------------
	RC = FS_CreateFile(pFN, FS_READ_ONLY, &File);
	while ( RC != CE_GOOD );
	//------------------------------
	// Reed from start
	//------------------------------
   	RC = FS_Read (&File, CData, 26, &ReadCnt);
	while (CE_GOOD != RC);
	//------------------------------
	// Close the file - save changes
	//------------------------------
	RC = FS_Flush(&File);
   	while ( RC != CE_GOOD );
	//------------------------------
	i = 1 + i;
	//*******************************************************************
	BLISignalOFF();
	//------------------------------
	while(1);
	return 0;
	}
示例#8
0
int main(void)
	{
	//*******************************************************************
	// Initialization of HW components/modules
	//===================================================================
	Init();
	TMRInit(2);			// Initialize Timer interface with Priority=2
	BLIInit();			// Initialize Signal interface
	//--------------------------
	BLIAsyncMorse("S", 1);	// dot-dot-dot
	UARTInitTX(6, 48);	// Initialize UART1 for TX on IPL=6 at
						// BaudRate =   48	=>   115,200 bps	- ZigBEE
						//--------------------------------------
						// BaudRate =  100	=>   250,000 bps
						// BaudRate =  200	=>   500,000 bps
						// BaudRate =  250	=>   625,000 bps
						// BaudRate =  350	=>   833,333 bps	- SD Logger
						// BaudRate =  500	=> 1,250,000 bps
						// BaudRate = 1000	=> 2,500,000 bps
	//===================================================================

	//*******************************************************************
	// Quadrocopter control variables
	//-------------------------------------------------------------------
	ulong		StartTS		= 0;
	ulong		StepTS;

	//==================================================================
	// Initialize sensors...
	//------------------------------------------------------------------
	BLIAsyncMorse(	"I", 1);
	//============================================================
	// Let MaxBotix initialize HW
	//============================================================
	TMRDelay(1000);
	//==================================================================
	// Initialize MaxBotix range finder
	//--------------------------------------------------------------
	if (0 == MXBInit(4, &TM.MXBDLPF))
		BLIDeadStop("ES", 2);
	//--------------------------------------------------------------
	BLIAsyncStop();
	
	//*******************************************************************
	// Control Loop
	//-------------------------------------------------------------------
	BLISignalON();
	while (1)
		{
		//============================================================
		// Simulate control loop duration
		//============================================================
		TMRDelay(10);
		//-----------------------------------------
		
		//===========================================================
		// Load and post telemetry data (non-blocking call)
		//-----------------------------------------------------------
		StepTS =  TMRGetTS();
		//-----------------------------------------
		if (0 == StartTS)
			// Time stamp of cycle start!
			StartTS =  StepTS;
		//-----------------------------------------
		TM.TS			= StepTS - StartTS;
		//----------------------
		TM.BaseOffset	= _MXBOffset;
		MXBReadDLPF(8, &TM.MXBDLPF);
		memcpy(&TM.MXBNative, &_NewMXBReading, sizeof(TM.MXBNative));
		//===========================================================
		UARTPostIfReady( (unsigned char *) &TM, sizeof(TM)	);
		//===========================================================

		}
	//*******************************************************************
	return 1;
	}
示例#9
0
int main(void)
	{
	//*******************************************************************
	Init();
	TMRInit(2);			// Initialize Timer interface with Priority=2
	BLIInit();			// Initialize Signal interface
	ADCInit(3);			// Initialize ADC to control battery
	I2CInit(5, 0);		// Initialize I2C1 module with IPL=5 and Fscl=400 KHz
	//--------------------------
	BLISignalON();
	//--------------------------
	if (MPUInit(3, 1))	// Initialize motion Sensor - 1 kHz/4 (250 Hz)
		DeadStop("A", 1);
	//--------------------------
	BLISignalOFF();
	//--------------------------
	UARTInitTX(6, 48);	// Initialize UART1 for TX on IPL=6 at 115200 bps
	// This initialization routine accepts BaudRate in multiples
	// of 2400 bps; Thus:
	// BaudRate =   1	=>   2400 bps
	// BaudRate =   2	=>   4800 bps
	// ...
	// BaudRate =  48	=> 115200 bps
	//------------------------------------------------------------
	// High speed
	//------------------------------------------------------------
	// BaudRate =  100	=>   250,000 bps
	// BaudRate =  200	=>   500,000 bps
	// BaudRate =  250	=>   625,000 bps
	// BaudRate =  350	=>   833,333 bps
	// BaudRate =  500	=> 1,250,000 bps
	// BaudRate = 1000	=> 2,500,000 bps
	//*******************************************************************
	uint			RC			= 0;
	//--------------------------
	_MPURawData	RawData;
	//--------------------------
	struct 
		{
		ulong	TS;		// Timestamp of the cycle
		//-----------------------------------------------
		// Temperature
		//-----------------------------------------------
		float			Temp;
		//-----------------------------------------------
		// Accelerometer
		//-----------------------------------------------
		float			AX;
		float			AY;
		float			AZ;
		//-----------------------------------------------
		// Gyroscopes
		//-----------------------------------------------
		float			GX;
		float			GY;
		float			GZ;
		//-----------------------------------------------
		} UData;
	//*******************************************************************
	long	AX, AY, AZ, GX, GY, GZ, Temp;
	//*******************************************************************
	while(1)
		{
		//------------------------	
		if (ADCGetBatteryStatus() < 30)
			DeadStop("SOS", 3);
		//------------------------
		AX= AY= AZ= GX= GY= GZ= Temp = 0;
		//------------------------
		int i;
		for (i=0; i<128; i++)	
			{
			RC 	= _MPUReadRawData(&RawData);
			if (RC) DeadStop("A", 1);
			//-----------------------------
			AX	+=	RawData.AX;
			AY	+=	RawData.AY;
			AZ	+=	RawData.AZ;
			//-----------------
			GX	+=	RawData.GX;
			GY	+=	RawData.GY;
			GZ	+=	RawData.GZ;
			//-----------------
			Temp+=	RawData.Temp;
			//-----------------------------
			}
		//---------------------------------------------	
		UData.TS	= 	TMRGetTS();
		//------------------------
		UData.Temp	=	((float)Temp/128.0 - _MPU_Temp_OffsetTo0) * _MPU_Temp_Sensitivity - 25.0;
		//------------------------
		UData.AX	= 	(float)AX/128.0;
		UData.AY	=	(float)AY/128.0;
		UData.AZ	=	(float)AZ/128.0;
		//------------------------
		UData.GX	= 	(float)GX/128.0;
		UData.GY	=	(float)GY/128.0;
		UData.GZ	=	(float)GZ/128.0;
		//---------------------------------------------	
		UARTPostWhenReady((uchar*)&UData, sizeof(UData));
		//---------------------------------------------	
		}
	return 1;
	}
示例#10
0
int main(void)
	{

	//*******************************************************************
	Init();
	TMRInit(2);		// Initialize Timer interface with Priority=2
	BLIInit();		// Initialize Signal interface
	//*******************************************************************
	// Switch 1 controls the Serial Data Logger (SDL) communication speed
	//-------------------------------------------------------------------
	if (_SW1)
		// Switch 1 is ON - Configuring SDL for PIC-to-PIC
		// high-speed communication at 1 MBaud
		SDLInit(3, BAUD_1M);
	else
		// Switch 1 is OFF - Configuring SDL for ZigBEE
		// wireless communication at 115.2 KBaud
		SDLInit(3, BAUD_115200);
	//*******************************************************************
	I2CInit(5, 2);	// First param: IL = 5 (interrupt request priority
					// Second param: I2C speed
					// 0 - lowest (123 kHz at Fcy = 64MHz)
					// 1 - 200 kHz - MPU-6050 stable
					// 2 - 400 kHz
					// 3 - 1 MHz
	//-------------------------------------------------------------------
	uint			RC			= 0;
	ulong			Alarm		= 0;
	//==================================================================
	BLIAsyncStart(50,50);
	TMRDelay(5000);
	BLIAsyncStop();
	//==================================================================
	if (_SW2)
		// Switch 2 is ON - Configuring MPU fo Alt. sensitivity
		RC = MPUInit(0, 1, MPU_GYRO_1000ds, MPU_ACC_4g);
							// Initialize motion Sensor
							// 1 kHz/(0+1) = 1000 Hz (1ms)
							// DLPF = 3 => Bandwidth 44 Hz (delay: 4.9 msec)
	else
		// Switch 2 is OFF - Configuring MPU fo normal sensitivity
		RC = MPUInit(0, 1, MPU_GYRO_2000ds, MPU_ACC_2g);
							// Initialize motion Sensor
							// 1 kHz/(0+1) = 1000 Hz (1ms)
							// DLPF = 1 => Bandwidth 184 Hz (delay: 2.0 msec)
	if (RC)	BLIDeadStop("EG", 2);
	//*******************************************************************
	struct
		{
		MPUData	Sample1;
		MPUData	Sample2;
		} MPU;
	//=====================================================
	// Initialize Asynchronous mode
	//-----------------------------------------------------
	if ( (RC = MPUAsyncStart(2)) )
		BLIDeadStop("S2", 2);
	//------------------------------
	if ( (RC = MPUAsyncStart(1)) )
		BLIDeadStop("S1", 2);
	//=====================================================
	// Calibrate Gyros
	//-----------------------------------------------------
//	BLIAsyncStart(100,100);
//	//------------------------------
//	if ( (RC = MPUCalibrate(1)) )
//		BLIDeadStop("C1", 2);
//	//------------------------------
//	if ( (RC = MPUCalibrate(2)) )
//		BLIDeadStop("C2", 2);
//	//------------------------------
//	BLIAsyncStop();
	//=====================================================
	// Main Loop
	//-----------------------------------------------------
	BLISignalOFF();
	while (TRUE)
		{
		Alarm = TMRSetAlarm(1000);
		//------------------------------------
		if ( (RC = MPUAsyncReadWhenReady(1, &MPU.Sample1)) )
			BLIDeadStop("SOS", 3);
		//--------------------------
		if ( (RC = MPUAsyncReadWhenReady(2, &MPU.Sample2)) )
			BLIDeadStop("SOS", 3);
		//------------------------
		BLISignalFlip();
		//-------------------------
		SDLPostIfReady((byte*)&MPU, sizeof(MPU));
		//-------------------------
		TMRWaitAlarm(Alarm);
		}

	//*******************************************************************
	return 0;
	}
示例#11
0
//*************************************************************
void	TMRInitDefault()
	{TMRInit(_TMRIL);}
示例#12
0
int main(void)
    {

    //*******************************************************************
    Init();         // Initialize microprocessor
    TMRInit(2);     // Initialize Timer interface with Priority=2
    BLIInit();      // Initialize Signal interface
    //*******************************************************************
    // Switch 1 controls the Serial Data Logger (SDL) communication speed
    //-------------------------------------------------------------------
    if (_SW1)
        // Switch 1 is ON - Configuring SDL for PIC-to-PIC
        // high-speed communication at 1 MBaud
        SDLInit(3, BAUD_1M);
    else
        // Switch 1 is OFF - Configuring SDL for ZigBEE
        // wireless communication at 115.2 KBaud
        SDLInit(3, BAUD_115200);
    //*******************************************************************
    // Initialize I2C Library
    //-------------------------------------------------------------------
    I2CInit(5, 2);  // First param: IL = 5 (interrupt request priority
                    // Second param: I2C speed
                    // 0 - lowest (123 kHz at Fcy = 64MHz)
                    // 1 - 200 kHz
                    // 2 - 400 kHz
                    // 3 - 1 MHz
    //*******************************************************************
    uint    RC      = 0;
    ulong   Alarm   = 0;
    //==================================================================
    // Initialize MPUs
    //------------------------------------------------------------------
    RC = MPUInit(0, 3, MPU_GYRO_2000ds, MPU_ACC_2g);
                        // Initialize motion Sensor
                        // 1 kHz/(0+1) = 1000 Hz (1msec)
                        // DLPF = 3 => Bandwidth 44 Hz (delay: 4.9 msec)
    if (RC)    BLIDeadStop("EG", 2);
    //==================================================================
    // Initialize MPL3115 Altimeter
    //------------------------------------------------------------------
    // OSR = 0 => No averaging ( 2^0= 1),   update rate about 166.6 Hz
    // OSR = 1 => Average 2^1=   2 samples, update rate about 111.1 Hz
    // OSR = 2 => Average 2^2=   4 samples, update rate about  67.8 Hz
    // OSR = 3 => Average 2^3=   8 samples, update rate about  37.7 Hz
    // OSR = 4 => Average 2^4=  16 samples, update rate about  20.1 Hz
    // OSR = 5 => Average 2^5=  32 samples, update rate about  10.4 Hz
    // OSR = 6 => Average 2^6=  64 samples, update rate about   5.3 Hz
    // OSR = 7 => Average 2^7= 128 samples, update rate about   2.7 Hz
    //------------------------------------------------------------------
    byte    OSR    = 3;
    //------------------------------------------------------------------
    if ( MPL_OK != MPLInit (OSR) )
        BLIDeadStop ("EB", 2);
    //==================================================================
    // Initialize Asynchronous mode
    //-----------------------------------------------------
    if ( (RC = MPUAsyncStart(1)) )
        BLIDeadStop("S1", 2);
    //------------------------------
    if ( (RC = MPUAsyncStart(2)) )
        BLIDeadStop("S2", 2);
    //-----------------------------------------------------
    if ( (RC = MPLAsyncStart()) )
        BLIDeadStop("S3", 2);
    //==================================================================
    // Provide a few second delay prior to calibrating Gyros to make
    // sure that the board is stable after the "turn-on" shake
    //------------------------------------------------------------------
    BLIAsyncStart(50,50);
    TMRDelay(5000);
    BLIAsyncStop();
    //==================================================================
    // Calibrate Gyros
    //------------------------------------------------------------------
    BLIAsyncStart(100,100);
    //------------------------------
    if ( (RC = MPUCalibrateGyro(1)) )
        BLIDeadStop("C1", 2);
    //------------------------------
    if ( (RC = MPUCalibrateGyro(2)) )
        BLIDeadStop("C2", 2);
    //------------------------------
    BLIAsyncStop();
    //==================================================================
    
    //==================================================================
    struct
        {
        MPUData        MPUSample1;
        MPUData        MPUSample2;
        MPLData        MPLSample;
        } SensorData;
    //==================================================================
    // Main Loop
    //------------------------------------------------------------------
    BLISignalOFF();
    while (TRUE)
        {
        Alarm = TMRSetAlarm(1000);
        //-----------------------------------------------------
        if ( (RC = MPUAsyncReadWhenReady(1, &SensorData.MPUSample1)) )
            BLIDeadStop("SOS", 3);
        //--------------------------
        if ( (RC = MPUAsyncReadWhenReady(2, &SensorData.MPUSample2)) )
            BLIDeadStop("SOS", 3);
        if (MPL_OK != MPLAsyncReadWhenReady(&SensorData.MPLSample))
            BLIDeadStop("SOS", 3);
        //-----------------------------------------------------
        BLISignalFlip();
        //-------------------------
        SDLPostIfReady((byte*)&SensorData, sizeof(SensorData));
        //-------------------------
        TMRWaitAlarm(Alarm);
        }

    //*******************************************************************
    return 0;
    }
示例#13
0
int main(void)
	{
	//*******************************************************************
	Init();
	TMRInit(2);		// Initialize Timer interface with Priority=2
	BLIInit();		// Initialize Signal interface
	//*******************************************************************
	//_T1IE 	= 0; 	// Temporarily disable Timer1 interrupt
	//*******************************************************************
	LogInit();			// Initialize Data Logger
	//*******************************************************************
	uint	i;
	char		RData[30];
	char		CData[30];

	for (i = 0; i < 30; i++)
		{
		RData[i] = CData[i] = 0;
		}

	char*		pFN		= "log1.txt";
	void*		pWData	= &"01 02 03 04 05 06 07 08 09";
	//-------------------------------------------------------------------
	
	CETYPE			RC;
	uint			ReadCnt;
	
	FSFILE			File;
	SEARCH_STATE	Search;
	//*******************************************************************
	BLISignalON();
	//*******************************************************************
	
	// Search for every entry in the Root
	RC = FS_FindFirst(	"*", ATTR_NONE,  ATTR_NONE, &Search, &File);	
	while (CE_GOOD == RC)
		{
		RC = FS_FindNext(&Search, &File);
		}

	// Search only for files
	RC = FS_FindFirst(	"*", ATTR_NONE,  ATTR_DIRECTORY, &Search, &File);	
	while (CE_GOOD == RC)
		{
		RC = FS_FindNext(&Search, &File);
		}

	// Search only for directories
Deeper:
	RC = FS_FindFirst(	"*", ATTR_DIRECTORY,  ATTR_NONE, &Search, &File);	
	if (CE_GOOD == RC)
		{
		RC = FS_chDir(&File);
		if (CE_GOOD == RC)
			goto Deeper;
		}
		
Higher:
	RC = FS_GetCWD(&File);
	RC = CE_GOOD;
	RC = FS_chDirUp();
	if (CE_GOOD == RC)
		goto Higher;
		
	//*******************************************************************


	//------------------------------
	// Create (Open) file for Writing and Reading 
	//------------------------------
	RC = FS_CreateFile(pFN, FS_CREATE_NEW, &File);
	while ( RC != CE_GOOD );
	//------------------------------
	// Write sample string to file
	//------------------------------
   	RC = FS_Write (&File, pWData, 26 );
	while (CE_GOOD != RC);
	//------------------------------
	// Check position in the file
	//------------------------------
   	i = FS_GetPosition (&File);
	while (i != 26);
	//------------------------------
	// Seek to start
	//------------------------------
   	FS_SeekStart(&File);
	//------------------------------
	// Reed from start
	//------------------------------
   	RC = FS_Read (&File, RData, 26, &ReadCnt);
	while (CE_GOOD != RC);
	//------------------------------
	// Close the file - save changes
	//------------------------------
	RC = FS_Flush(&File);
   	while ( RC != CE_GOOD );
	//------------------------------

	//------------------------------
	// Open file for Reading 
	//------------------------------
	RC = FS_CreateFile(pFN, FS_READ_ONLY, &File);
	while ( RC != CE_GOOD );
	//------------------------------
	// Reed from start
	//------------------------------
   	RC = FS_Read (&File, CData, 26, &ReadCnt);
	while (CE_GOOD != RC);
	//------------------------------
	// Close the file - save changes
	//------------------------------
	RC = FS_Flush(&File);
   	while ( RC != CE_GOOD );
	//------------------------------
	i = 1 + i;

	//*******************************************************************
	BLISignalOFF();
	//------------------------------
	while(1);
	return 0;
	}
示例#14
0
int main(void)
    {

    //*******************************************************************
    Init();
    TMRInit(2);        // Initialize Timer interface with Priority=2
    BLIInit();        // Initialize Signal interface
    //==================================================================
    // Provide a 5 second delay prior to initialization of I2C interface
    // to avoid false-start during programming by PIC Kit 3
    //------------------------------------------------------------------
    BLIAsyncStart(50,200);
    TMRDelay(5000);
    BLIAsyncStop();
    //*******************************************************************
    // Switch 1 controls the Serial Data Logger (SDL) communication speed
    //-------------------------------------------------------------------
    if (_SW1)
        // Switch 1 is ON - Configuring SDL for PIC-to-PIC
        // high-speed communication at 1 MBaud
        SDLInit(3, BAUD_1M);
    else
        // Switch 1 is OFF - Configuring SDL for ZigBEE
        // wireless communication at 115.2 KBaud
        SDLInit(3, BAUD_115200);
    //*******************************************************************
    // Initialize I2C Library
    //-------------------------------------------------------------------
    I2CInit(5, 2);  // First param: IL = 5 (interrupt request priority
                    // Second param: I2C speed
                    // 0 - lowest (123 kHz at Fcy = 64MHz)
                    // 1 - 200 kHz
                    // 2 - 400 kHz
                    // 3 - 1 MHz
    //-------------------------------------------------------------------
    uint    RC      = 0;
    ulong   Alarm   = 0;
    //==================================================================
    // Initialize MPUs
    //------------------------------------------------------------------
    RC = MPUInit(0, 3, MPU_GYRO_2000ds, MPU_ACC_2g);
                        // Initialize motion Sensor
                        // 1 kHz/(0+1) = 1000 Hz (1msec)
                        // DLPF = 3 => Bandwidth 44 Hz (delay: 4.9 msec)
    if (RC)    BLIDeadStop("EG", 2);
    //=====================================================
    // Initialize Asynchronous mode
    //-----------------------------------------------------
    if ( (RC = MPUAsyncStart(2)) )
        BLIDeadStop("S2", 2);
    //------------------------------
    if ( (RC = MPUAsyncStart(1)) )
        BLIDeadStop("S1", 2);
    //==================================================================
    // Provide a few second delay prior to calibrating Gyros to make
    // sure that the board is stable after the "turn-on" shake
    //------------------------------------------------------------------
    BLIAsyncStart(50,50);
    TMRDelay(1000);
    BLIAsyncStop();
    //*******************************************************************
    // Calibrate Gyros
    //-----------------------------------------------------
    //  MPUSetOptions(Rotate, TempComp, CrossAxis)
    MPUSetOptions(TRUE, TRUE, TRUE);
    //-----------------------------------------------------
    BLIAsyncStart(100,100);
    //------------------------------
    if ( (RC = MPUCalibrateGyro(1)) )
        BLIDeadStop("C1", 2);
    //------------------------------
    if ( (RC = MPUCalibrateGyro(2)) )
        BLIDeadStop("C2", 2);
    //------------------------------
    BLIAsyncStop();
    //=====================================================
    struct
        {
        MPUData    Sample1;
        MPUData    Sample2;
        } MPU;
    //=====================================================
    // Main Loop
    //-----------------------------------------------------
    BLISignalOFF();
    while (TRUE)
        {
        Alarm = TMRSetAlarm(20);
        //------------------------------------
        if ( (RC = MPUAsyncReadWhenReady(1, &MPU.Sample1)) )
            BLIDeadStop("SM1", 3);
        //--------------------------
        if ( (RC = MPUAsyncReadWhenReady(2, &MPU.Sample2)) )
            BLIDeadStop("SM2", 3);
        //------------------------
        BLISignalFlip();
        //-------------------------
        SDLPostIfReady((byte*)&MPU, sizeof(MPU));
        //-------------------------
        TMRWaitAlarm(Alarm);
        }

    //*******************************************************************
    return 0;
    }
示例#15
0
int main(void)
	{
	//*******************************************************************
	Init();
	TMRInit(2);			// Initialize Timer interface with Priority=2
	BLIInit();			// Initialize Signal interface
	I2CInit(5, 0);		// Initialize I2C1 module with IPL=5 and Fscl=400 KHz
	//--------------------------
	TMRDelay(1000);		// Wait for 1 sec so that the shake from turning on
						// power switch dissipates...
	//--------------------------
	if (MPUInit(3, 1))	// Initialize motion Sensor - 1 kHz/4 (250 Hz)
		BLIDeadStop("EA", 2);
	//--------------------------
	#ifdef __MAG_Use__
	if (HMCInit(6, 1, 0))	// Initialize magnetic Sensor
							// ODR  = 6 (max, 75 Hz),
							// Gain = 2 (1.3 Gs)
							// DLPF = 0 (no averaging)
		BLIDeadStop("EM", 2);
	#endif
	//--------------------------
	UARTInitTX(6, 48);	// Initialize UART1 for TX on IPL=6 at 115200 bps
	// This initialization routine accepts BaudRate in multiples
	// of 2400 bps; Thus:
	// BaudRate =   1	=>   2400 bps
	// BaudRate =   2	=>   4800 bps
	// ...
	// BaudRate =  48	=> 115200 bps
	//------------------------------------------------------------
	// High speed
	//------------------------------------------------------------
	// BaudRate =  100	=>   250,000 bps
	// BaudRate =  200	=>   500,000 bps
	// BaudRate =  250	=>   625,000 bps
	// BaudRate =  350	=>   833,333 bps
	// BaudRate =  500	=> 1,250,000 bps
	// BaudRate = 1000	=> 2,500,000 bps
	//*******************************************************************
	uint			RC			= 0;
	//--------------------------
	MPUSample		AGSample;
	#ifdef __MAG_Use__
	HMCSample		MSample;
	#endif
	//--------------------------
	if (MPUAsyncStart())
		BLIDeadStop("A", 1);
	//--------------------------
	#ifdef __MAG_Use__
	if (HMCAsyncStart())
		BLIDeadStop("M", 1);
	#endif
	//--------------------------
	struct 
		{
		ulong	TS;		// Timestamp of the cycle
		//-----------------------------------------------
		ulong	MPUCount;	// Sequential number of MPU sample
		#ifdef __MAG_Use__
		ulong	MAGCount;	// Sequential number of MAG sample
		#endif
		//-----------------------------------------------
		// Accelerometer (in units of G)
		//-----------------------------------------------
		Vector	A;
		//-----------------------------------------------
		// Gyroscopes	(in Rad/sec)
		//-----------------------------------------------
		Vector	G;
		#ifdef __MAG_Use__
		//-----------------------------------------------
		// Magnetometer (in mGs)
		//-----------------------------------------------
		Vector	M;
		#endif
		} UData;
	//*******************************************************************
	BLISignalON();
	while(1)
		{
		TMRDelay(100);
		//------------------------	
		#ifdef __MAG_Use__
		RC 	= HMCAsyncReadWhenReady(&MSample);
		if (RC) BLIDeadStop("M", 1);
		#endif
		//------------------------	
		RC 	= MPUAsyncReadWhenReady(&AGSample);
		if (RC) BLIDeadStop("A", 1);
		//---------------------------------------------	
		UData.MPUCount	= AGSample.Count;
		#ifdef __MAG_Use__
		UData.MAGCount	= MSample.Count;
		#endif
		//------------------------
		VectorCopy(&AGSample.A, &UData.A);
		VectorCopy(&AGSample.G, &UData.G);
		#ifdef __MAG_Use__
		VectorCopy(&MSample.M,  &UData.M);
		#endif
		//------------------------
		UData.TS	= AGSample.TS;
		//---------------------------------------------	
		UARTPostWhenReady((uchar*)&UData, sizeof(UData));
		//---------------------------------------------	
		BLISignalFlip();
		}
	return 1;
	}
示例#16
0
int main(void)
	{
	//*******************************************************************
	Init();
	TMRInit(2);			// Initialize Timer interface with Priority=2
	BLIInit();			// Initialize Signal interface
	//--------------------------
	BLIAsyncMorse("S", 1);	// dot-dot-dot
	MCMInitF(50, 2500);	// Initialize Motor Control at 50 Hz with setting
						// Throttle to HIGH for delay interval to let ESC
						// capture Throttle range
	BLIAsyncStop();
	//--------------------------
	RCInit(4);			// Initialize Receiver interface with Priority=4
	//--------------------------
	UARTInitTX(6, 48);	// Initialize UART1 for TX on IPL=6 at 115200 bps
	// This initialization routine accepts BaudRate in multiples
	// of 2400 bps; Thus:
	// BaudRate =   1	=>   2400 bps
	// BaudRate =   2	=>   4800 bps
	// ...
	// BaudRate =  48	=> 115200 bps
	//------------------------------------------------------------
	// High speed
	//------------------------------------------------------------
	// BaudRate =  100	=>   250,000 bps
	// BaudRate =  200	=>   500,000 bps
	// BaudRate =  250	=>   625,000 bps
	// BaudRate =  350	=>   833,333 bps
	// BaudRate =  500	=> 1,250,000 bps
	// BaudRate = 1000	=> 2,500,000 bps
	//*******************************************************************
	BLISignalON();
	TMRDelay(2000); 	// Wait for extra 2 sec - to let ESC arm...
						// (finish the song :) )
	BLISignalOFF();
	//==================================================================
	MCMData		MC;
	RCData		RC;
	//-------------------------------------------------
	BLIAsyncMorse("R", 1);	// dot-doh-dot
	RCArm();
	BLIAsyncStop();
	//-------------------------------------------------
	BLISignalON();
	while(1)
		{
		RCReadWhenReady(&RC);
		//---------------------------------------------	
		if (0 == RC.Control)
			MC.F = MC.B	= MC.L = MC.R	= 0.0;
		else
			{	
			MC.F	= RC.Throttle;
			MC.B	= RC.Throttle;
			//--------------
			MC.L	= RC.Throttle;
			MC.R	= RC.Throttle;
			//--------------
			}
		//---------------------------------------------	
		MCMSet(&MC);
		//---------------------------------------------	
		UARTPostWhenReady((uchar*)&RC, sizeof(RC));
		//---------------------------------------------	
		BLISignalFlip();
		}
	return 1;
	}
示例#17
0
int main(void)
{

    //*******************************************************************
    Init();
    TMRInit(2);        // Initialize Timer interface with Priority=2
    BLIInit();        // Initialize Signal interface
    //*******************************************************************
    // Switch 1 controls the Serial Data Logger (SDL) communication speed
    //-------------------------------------------------------------------
    if (_SW1)
        // Switch 1 is ON - Configuring SDL for PIC-to-PIC
        // high-speed communication at 1 MBaud
        SDLInit(3, BAUD_1M);
    else
        // Switch 1 is OFF - Configuring SDL for ZigBEE
        // wireless communication at 115.2 KBaud
        SDLInit(3, BAUD_115200);
    //*******************************************************************
    I2CInit(5, 1);    // First param: IL = 5 (interrupt request priority
    // Second param: I2C speed
    // 0 - lowest (123 kHz at Fcy = 64MHz)
    // 1 - 200 kHz
    // 2 - 400 kHz
    // 3 - 1 MHz
    //-------------------------------------------------------------------
    uint            RC            = 0;
    ulong            Alarm        = 0;
    //==================================================================
    BLIAsyncStart(100,100);
    TMRDelay(2000);
    BLIAsyncStop();
    //==================================================================
    BLIAsyncStart(50,50);
    if (_SW2)
        // Switch 2 is ON - Configuring MPU fo Alt. sensitivity
        RC = MPUInit(0, 3, MPU_GYRO_1000ds, MPU_ACC_4g);
    // Initialize motion Sensor
    // 1 kHz/(0+1) = 1000 Hz (1ms)
    // DLPF=3 => Bandwidth 44 Hz (delay: 4.9 msec)
    else
        // Switch 2 is OFF - Configuring MPU fo normal sensitivity
        RC = MPUInit(0, 3, MPU_GYRO_2000ds, MPU_ACC_2g);
    // Initialize motion Sensor
    // 1 kHz/(0+1) = 1000 Hz (1ms)
    if (RC)    BLIDeadStop("EG", 2);
    BLIAsyncStop();
    //*******************************************************************
    BLISignalOFF();

    //====================================================
//    byte            mpuID;
//    byte            mpuDLPF;
//    byte            mpuINT;
//    byte            mpuPWRM1;
//    //---------------------------
//    RC = MPUReadID(2, &mpuID);
//    RC = MPUGetPWRM1(2, &mpuPWRM1);
//    RC = MPUGetDLPF(2, &mpuDLPF);
//    RC = MPUGetINT(2, &mpuINT);
    //-----------------------------------------------------

    //====================================================
    // Synchronous interface
    //-----------------------------------------------------
    struct
    {
        MPUData    Sample1;
        MPUData    Sample2;
    } MPU;
    //-----------------------------------------------------
    while (TRUE)
    {
        Alarm = TMRSetAlarm(500);
        //------------------------------------
        if ( (RC = MPUReadSample(1, &MPU.Sample1)) )
            BLIDeadStop("SOS", 3);
        //------------------------
        if ( (RC = MPUReadSample(2, &MPU.Sample2)) )
            BLIDeadStop("SOS", 3);
        //------------------------------------
        BLISignalFlip();
        //-------------------------
        SDLPostIfReady((byte*)&MPU, sizeof(MPU));
        //-------------------------
        TMRWaitAlarm(Alarm);
    }

    //*******************************************************************
    return 0;
}
示例#18
0
int main(void)
	{
	//*******************************************************************
	Init();
	TMRInit(2);			// Initialize Timer interface with Priority=2
	//--------------------------
	BLIInit();			// Initialize Signal interface
	I2CInit(5, 1);		// Initialize I2C1 module with IPL=5 and Fscl=400 KHz
	//--------------------------
	UARTInitTX(6, 350);	// Initialize UART1 for TX on IPL=6 at 
	// BaudRate =   48	=>   115,200 bps	- ZigBEE
	//--------------------------------------
	// BaudRate =  100	=>   250,000 bps
	// BaudRate =  200	=>   500,000 bps
	// BaudRate =  250	=>   625,000 bps
	// BaudRate =  350	=>   833,333 bps	- SD Logger, FTDI cable
	// BaudRate =  500	=> 1,250,000 bps
	// BaudRate = 1000	=> 2,500,000 bps
	//*******************************************************************
	if ( MPUInit(0, 3) )	// Initialize motion Sensor
							// 1 kHz/(0+1) = 1000 Hz (1ms)
							// DLPF=3 => Bandwidth 44 Hz (delay: 4.9 msec)
		BLIDeadStop("EG", 2);
	//--------------------------
	if (HMCInit(6, 1, 0))	// Initialize magnetic Sensor
							// ODR  = 6 (max, 75 Hz),
							// Gain = 1 (1.3 Gs)
							// DLPF = 0 (no averaging)
		BLIDeadStop("EM", 2);
	//--------------------------
	if ( MPLInit(5) )		// Average over 32 samples providing
							// update rate about 10 Hz
		BLIDeadStop("EA", 2);
	//*******************************************************************
	uint			RC			= 0;
	ulong			Alarm		= 0;
	ulong			TS			= 0;
	//-------------------------------
	struct
		{
		ulong			TS;
		MPUSample		IMUData;
		HMCSample		MagData;
		MPLSample		AltData;	
		}	UData;
	//*******************************************************************
	BLIAsyncStart(100, 50);
	RC = MPLSetGround();
	if (RC) BLIDeadStop("SOS", 3);	// Failure...
	BLIAsyncStop();
	//====================================================
	
	BLISignalOFF();
	//====================================================
	// Testing MPU, HMC, and MPL together in a real-life
	// scenario
	//====================================================
	if(MPUAsyncStart()) 	BLIDeadStop("SG", 2);
	//------------------------
	if(HMCAsyncStart())		BLIDeadStop("SM", 2);
	//------------------------
	if(MPLAsyncStart())		BLIDeadStop("SA", 2);
	RC = MPLAsyncReadWhenReady(&UData.AltData);
	if (RC) BLIDeadStop("SAS", 3);	// Failure...
	//====================================================
	while (TRUE)
		{
		Alarm = TMRSetAlarm(500);
		//------------------------------------
		RC 	= MPUAsyncReadIfReady(&UData.IMUData);
		if (MPU_OK != RC && MPU_NRDY != RC)
			BLIDeadStop("G", 1);
		//------------------------
		RC 	= HMCAsyncReadIfReady(&UData.MagData);
		if (HMC_OK != RC && HMC_NRDY != RC)
			BLIDeadStop("M", 1);
		//------------------------
		RC = MPLAsyncReadIfReady(&UData.AltData);
		if (MPL_OK != RC && MPL_NRDY != RC)
			BLIDeadStop("A", 3);	// Failure...
		//-------------------------
		UData.TS	= TMRGetTS();
		//-------------------------
		if (0 == TS)	TS = UData.TS;
		UData.TS -= TS;
		BLISignalFlip();
		//-------------------------
		UARTPostIfReady((byte*)&UData, sizeof(UData));
		//-------------------------
		TMRWaitAlarm(Alarm);
		}
	//====================================================
	
	

	return 1;
	}
示例#19
0
int main(void)
	{

	//*******************************************************************
	Init();
	TMRInit(2);		// Initialize Timer interface with Priority=2
	BLIInit();		// Initialize Signal interface
	//-------------------------------------------------------------------
	BLIAsyncStart(100, 100);
	TMRDelay(5000);			// To avoid false-start at Reset
	BLIAsyncStop();
	BLISignalOFF();
	//*******************************************************************
	// Switch 1 controls the Serial Data Logger (SDL) communication speed
	//-------------------------------------------------------------------
	if (_SW1)
		// Switch 1 is ON - Configuring SDL for PIC-to-PIC
		// high-speed communication at 1 MBaud
		SDLInit(3, BAUD_1M);
	else
		// Switch 1 is OFF - Configuring SDL for ZigBEE
		// wireless communication at 115.2 KBaud
		SDLInit(3, BAUD_115200);
	//*******************************************************************
	// HMC5983 Magnetometer initialization
	//-------------------------------------------------------------------
	byte IL		= 5;	// Interrupt level
	//------------------------------------------------------
	// <editor-fold defaultstate="collapsed" desc="Output Data Rate (ODR">
	//------------------------------------------------------
	// Typical Data Output Rate (Hz) for various ODR values
	//------------------------------------------------------
	//		ODR =	0:		  0.75
	//		ODR =	2:		  1.5
	//		ODR =	2:		  3
	//		ODR =	3:		  7.5
	//		ODR =	4:		 15		(Default)
	//		ODR =	5:		 30
	//		ODR =	6:		 75
	//		ODR =	7:		220		(fastest)
	// </editor-fold>
 	byte ODR	= 7;	// Rate (fastest):	220 Hz
	// <editor-fold defaultstate="collapsed" desc="Low-pass filtering (DLPF)">
	//------------------------------------------------------
	// Low-pass filtering achieved through sample averaging.
	// Averaging does not affect effective ODR, so I assume
	// that wit averaging enabled each successive reported
	// sample is an average of the new measurement with "n"
	// previous measurements - something like a FIR filter.
	//------------------------------------------------------
	// DLPF = 0 => 1-average	
	// DLPF = 1 => 2-average
	// DLPF = 2 => 4-average
	// DLPF = 3 => 8-average
	//------------------------------------------------------
	// </editor-fold>
 	byte DLPF	= 0;
	// <editor-fold defaultstate="collapsed" desc="Sensor Field Range (Gain)">
	//------------------------------------------------------
	// Recommended sensor field range (Ga) for various Gains
	//------------------------------------------------------
	//		Gain =	0:		0.9
	//		Gain =	1:		1.3
	//		Gain =	2:		1.9
	//		Gain =	3:		2.5
	//		Gain =	4:		4.0
	//		Gain =	5:		4.7
	//		Gain =	6:		5.6
	//		Gain =	7:		8.1
	//------------------------------------------------------
	// The magnitude of Earth magnetic field varies over the
	// surface of the Earth in the range 0.3 to 0.6 Gauss.
	//------------------------------------------------------
	// </editor-fold>
 	byte Gain	= 1;	// +/- 1.3 Ga
	//------------------------------------------------------
	HMC_Init(IL, ODR, Gain, DLPF);
	//*******************************************************************
	HMC_RC		RC;
	//----------------------
	ulong		i = 0;
	//-----------------------------------------
	byte		RegA;
	byte		RegB;
	//-------------------------------
	RC = HMC_ReadA(&RegA);
	i++;
	//-------------------------------
	RC = HMC_ReadB(&RegB);
	i++;
	//-------------------------------


	//----------------------
	struct
		{
		HMCData		Sample;
		ulong		Count;
		} SDLData;
		SDLData.Count	= 0;
    //----------------------
	while (1)
		{
		//-------------------------------
		if ( HMC_OK != (RC = HMC_ReadSample(&SDLData.Sample)) )
			BLIDeadStop("SOS", 3);
		SDLData.Count++;
		//-------------------------------
		BLISignalFlip();
		//-------------------------------
		SDLPostIfReady((byte*)&SDLData, sizeof(SDLData));
		//-------------------------------
		}

	//*******************************************************************
	return 0;
	}
示例#20
0
int main(void)
	{
	// <editor-fold defaultstate="collapsed" desc="Initialization of HW components/modules">
	//*******************************************************************
	// Initialization of HW components/modules
	//===================================================================
	Init();
	TMRInit(2);			// Initialize Timer interface with Priority=2
	BLIInit();			// Initialize Signal interface
	//===================================================================
	BLIAsyncStart(50, 50);	// Fast blinking - initialization
	//===================================================================
	MCMInitT(2.5, 2500);	// Initialize Motor Control for PPM with setting
							// Throttle to HIGH for delay interval to let ESC
							// capture Throttle range
	//--------------------------
	ADCInit(3);			// Initialize ADC to control battery
	//--------------------------
	RCInit(4);			// Initialize Receiver interface with Priority=4
	//--------------------------
	I2CInit(5, 1);		// Initialize I2C1 module with IPL=5 and Fscl=400 KHz
	//--------------------------
	UARTInitTX(6, 350);	// Initialize UART1 for TX on IPL=6 at 
	// BaudRate =   48	=>   115,200 bps	- ZigBEE
	//--------------------------------------
	// BaudRate =  100	=>   250,000 bps
	// BaudRate =  200	=>   500,000 bps
	// BaudRate =  250	=>   625,000 bps
	// BaudRate =  350	=>   833,333 bps	- SD Logger, FTDI
	// BaudRate =  500	=> 1,250,000 bps
	// BaudRate = 1000	=> 2,500,000 bps
	//*******************************************************************
	// Initialize Magnetometer
	//--------------------------------------------------------------
	if (HMCInit(6, 1, 0))	// Initialize magnetic Sensor
							// ODR  = 6 (max, 75 Hz),
							// Gain = 1 (1.3 Gs)
							// DLPF = 0 (no averaging)
		BLIDeadStop("EM", 2);
	//==================================================================
	// Initialize motion sensor - No calibration at this time!!!
	//------------------------------------------------------------------
	if ( MPUInit(0, 3) )	// Initialize motion Sensor
		// 1 kHz/(0+1) = 1000 Hz (1ms)
		// DLPF=3 => Bandwidth 44 Hz (delay: 4.9 msec)
		BLIDeadStop("EA", 2);
	//------------------------------------------------------------------
	//==================================================================
	AltimeterInit(4);	// Initialize Altimeter with IPL=4 (if needed)
	// NOTE: All sensors areinitialized, so no more synchronous I2C
	//		 operations are needed. Thus we may start Altimeter to give
	//		 it more time to "warm-up"
	AltimeterReset();	// NOTE: will be reset again later
	//==================================================================
	BLIAsyncStop();		// Initialization complete
	//===================================================================
	// </editor-fold>

	//*******************************************************************
	// Quadrocopter control variables
	//-------------------------------------------------------------------
	// <editor-fold defaultstate="collapsed" desc="Timing control variables">
	ulong		StartTS		= 0;	// Flight start time
	ulong		StepTS;				// Control Loop step start time
	ulong		Alarm		= 0;	// "alarm" variable used to set
									// the duration of the Control Loop
	// </editor-fold>

	// <editor-fold defaultstate="collapsed" desc="Variable required to process RC Feed ">
	//-------------------------------------------------------------------
	RCData		RCFeed;			// Control input from Receiver adjusted
								// by control rates. It may also be
								// corrected (if necessary) to account
								// for "+" or "X" configuration as
								// specified by MODE_CB_to_MF flag
	//---------------------------------------
	RCData		RCSmthd;		// Smoothed control input used in all
								// subsequent control calculations
								//---------------------------------------
	RCData		RCFinal;		// Smoothed RC input adjusted for the
								// Yaw angle to provide "Course Lock" (if
								// required). Final RC input provided to
								// Quarocopter Control Module
	//-------------------------------------------------------------------
	// We need battery Nominal voltage to adjust RC Throttle as battery
	// charge depletes.
	float		BatNomV		= ADCGetBatteryNomVoltage ();
	//-------------------------------------------------------------------
	Matrix		Mtr_CB_To_MF;	// Rotation matrix used to adjust Control
								// Board orientation to Model front
								//---------------------------------------
	Matrix		Mtr_CrsLck;		// Rotation matrix used to adjust RC input
								// to account for current Yaw to implement
								// "Course Lock"
								//---------------------------------------
	if (MODE_CB_to_MF)
		// Initialize Rotation Matrix for pre-set angle
		MatrixYawRotation(__CB_To_MF_Angle__, &Mtr_CB_To_MF);
	else
		// Reset Rotation matrix to Identity
		MatrixSetIdentity(&Mtr_CB_To_MF);
	//-------------------------------------------------------------------
	// </editor-fold>
	
	DCMData		IMU;				// Orientation data from DCM
	MCMData		MC;					// Motor control Variables
	//-------------------------------------------------------------------


	// <editor-fold defaultstate="collapsed" desc="ARMing RC and initializing IMU">
	//==================================================================
	// Wait for the Receiver ARMing: Throttle should go up and then down
	//------------------------------------------------------------------
	BLIAsyncStart(200, 200);		// Really slow
	RCArm();
	BLIAsyncStop();
	//==================================================================
	// </editor-fold>

Re_Start:
	//==================================================================
	// <editor-fold defaultstate="collapsed" desc="Intialize Re-Start">
	//------------------------------------------------------------------
	StartTS		= 0;					// Reset timing of control Loop
	//------------------------------------------------------------------
	BLIAsyncMorse(	"I", 1);			// dit - dit
	RCReadWhenReady (&RCFeed);			// Get reading from receiver
	//------------------------------------------------------------------
	// Safety check:  CONTROL should be UP and THROTTLE - LOW
	//------------------------------------------------------------------
	while 	(
			0 == RCFeed.Control
			||
			RCFeed.Throttle > 0.1
			)
		{
		RCReadWhenReady (&RCFeed);		// Get next reading from receiver
		}
	//------------------------------------------------------------------
	BLIAsyncStop ();
	//==================================================================

	//==================================================================
	// Normalize last read RC values as they will represent the first
	// input into the control algorithm, so should be adjusted accordingly
	//------------------------------------------------------------------
	NormalizeRCFeed(&RCFeed);
	//------------------------------------------------------------------
	// Reset Smothed RC data (initialize filter)
	//------------------------------------------------------------------
	RCDataReset(&RCSmthd);
	//==================================================================
	// Initialize sensors... Performed after ARMing to ensure that model
	// is stable
	//--------------------------------------------------------------
	BLIAsyncStart(100, 50);
	//------------------------------------------------------------------
	// Start IMU and wait until orientation estimate stabilizes
	//------------------------------------------------------------------
	IMUReset();
	//--------------------------------------------------------------
	BLIAsyncStart(50, 100);
	//------------------------------------------------------------------
	// Reset Altimeter
	//------------------------------------------------------------------
	AltimeterReset();
	//------------------------------------------------------------------
	QCMReset ();			// Initialize (reset) QCM variables
	//------------------------------------------------------------------
	// Force update of DCMData as inside the control Loop this
	// call is non-blocking!
	//------------------------------------------------------------------
	if (IMU_OK != IMUGetUpdateWhenReady (&IMU))
		// Failure...
		BLIDeadStop ("A", 1);
	//--------------------------------------------------------------
	BLIAsyncStop();
	//--------------------------------------------------------------
	// </editor-fold>
	//==================================================================

	//*******************************************************************
	// Quadrocopter Control Loop
	//-------------------------------------------------------------------
	BLISignalON();
	while (1)
		{
		//============================================================
		// Timing of control Loop
		//============================================================
		// <editor-fold defaultstate="collapsed" desc="Control Loop timing management">
		// Sets the "frquency" of Control Loop
		Alarm = TMRSetAlarm (10);	// Set Alarm 10 msec in the future
		//------------------------------------------------------------
		StepTS =  TMRGetTS ();		// Capture TS of this step
		if ( 0 == StartTS )			// First iteration of Control?
		  StartTS =  StepTS;		// Yes, capture timestamp
		// </editor-fold>
		//============================================================

		//============================================================
		// Read commands from receiver - non-blocking call!
		// (we will get out of this call even if connection to the
		// receiver is lost!)
		// At the end processed Receiver data is stored in RCSmthd
		//============================================================
		// <editor-fold defaultstate="collapsed" desc="Process Receiver feed">
		if ( RCRead(&RCFeed) )
			{
			//------------------------------------------------------------
			// Every NEW sample need to be "normalized"
			//------------------------------------------------------------
			NormalizeRCFeed(&RCFeed);
			//------------------------------------------------------------
			// Adjust orientation from "+" to "X" if needed
			//------------------------------------------------------------
			if (MODE_CB_to_MF)
				{
				// Control board front does not coincide with the model front
				Vector	RCInput;
				Vector	RCRotated;
				VectorSet(RCFeed.Roll, RCFeed.Pitch, RCFeed.Yaw, &RCInput);
				MatrixTimesVector(&Mtr_CB_To_MF, &RCInput, &RCRotated);
				RCFeed.Roll		= RCRotated.X;
				RCFeed.Pitch	= RCRotated.Y;
				RCFeed.Yaw		= RCRotated.Z;	// NOTE: Yaw is not affected!
				}
			}
		//============================================================
		// Smooth RC data 
		//------------------------------------------------------------
		// Roll, Pitch, and Yaw are smoothed with the IIR(4)
		//------------------------------------------------------------
		RCSmthd.Roll	= (RCSmthd.Roll	* 3.0	+ RCFeed.Roll ) * 0.25;	// 1/4 = 0.25
		RCSmthd.Pitch	= (RCSmthd.Pitch* 3.0 	+ RCFeed.Pitch) * 0.25;
		if (MODE_Course_Lock)
			{
			// In this mode Yaw is integrated over the Control Loop
			// duration (0.01 sec) and normalized to +/-Pi range
			RCSmthd.Yaw = QCMRangeToPi(RCSmthd.Yaw + RCFeed.Yaw * 0.01);
			}
		else
			{
			// Without Course-Lock Yaw is treated as "direct input" and
			// just smothed similar to other control variables.
			RCSmthd.Yaw		= (RCSmthd.Yaw	* 3.0	+ RCFeed.Yaw  ) * 0.25;
			}
		//------------------------------------------------------------
		// Throttle is smoothed with the IIR(4) and adjusted to
		// account for actual battery voltage. This is done to
		// improve "hovering" when throttle stick is not moving.
		//------------------------------------------------------------
		// Adjust Native (from RC) throttle to a value corresponding
		float BatV		= ADCGetBatteryVoltage();
		float BatAdjTh	= RCFeed.Throttle;
		if (BatV > 2.0)		// Sanity check :)
			BatAdjTh	= BatAdjTh	* BatNomV / BatV;
		//-----------------------------------------
		RCSmthd.Throttle	= (RCSmthd.Throttle*3.0	+ BatAdjTh) * 0.25;	// 1/4 = 0.25
		//-----------------------------------------
		RCSmthd.Control		= RCFeed.Control;
		// </editor-fold>
		//============================================================

		//============================================================
		// Implement Motor Cut-Off if RC Control is LOW
		//============================================================
		// <editor-fold defaultstate="collapsed" desc="Process RC Control">
		if ( 0 == RCSmthd.Control )
			{
			// Yes, Control is reliably low!
			//--------------------------------------------
			// Override motor control
			//--------------------------------------------
			MC.F = MC.B = MC.L = MC.R = 0;
			MCMSet(&MC);
			//--------------------------------------------
			// Flight terminated, post EOF to Data Logger
			//--------------------------------------------
			TMRDelay(10);	// Wait for pipe to clear
			UARTPostIfReady( NULL, 0);
			// ... and again - to be sure!
			TMRDelay(10);	// Wait for pipe to clear
			UARTPostIfReady( NULL, 0);
			//----------------------------------
			goto Re_Start;
			}
		// </editor-fold>
		//============================================================

		//============================================================
		// Obtain and process battery charge status
		//============================================================
		// <editor-fold defaultstate="collapsed" desc="Process Battery level">
		float BatteryCharge	= QCMBatteryMgmt();	
		if (BatteryCharge < 0.35)	// BC < 35%
			{
			float MaxLevel = 2.0 * BatteryCharge;
			if (RCSmthd.Throttle > MaxLevel)
				RCSmthd.Throttle = MaxLevel;
			}
		// </editor-fold>
		//============================================================

		//============================================================
		// Read current orientation from the IMU  with sensors' raw
		// measurements (non-blocking call) and, if necessary, perform
		// adjustment to RCSmthd to obtain RCFinal
		//============================================================
		// <editor-fold defaultstate="collapsed" desc="Process IMU data and generate Motor Control">
		// First, unconditionally promote RCSmthd to RCFinal
		RCDataCopy(&RCSmthd, &RCFinal);
		//------------------------------------------------------------
		if (IMU_OK == IMUGetUpdate(&IMU))
			{
			if (MODE_Course_Lock)
				{
				// We need to rotate RC input to adjust for current Yaw
				// to implement "Course Lock" - RC Roll and Pitch commands
				// are interpreted as being applied to the original (pre-
				// takeoff) orientation of the model
				//-------------------------------------------------------
				Vector	RCInput;
				Vector	RCRotated;
				// Build rotation matrix to adjust for orientation discrepancy
				MatrixYawRotation(-IMU.Yaw, &Mtr_CrsLck);
				// Load RC input into RCInput vector
				VectorSet(RCSmthd.Roll, RCSmthd.Pitch, RCSmthd.Yaw, &RCInput);
				// Rotate RCInput vector
				MatrixTimesVector(&Mtr_CrsLck, &RCInput, &RCRotated);
				// Save rotated values
				RCFinal.Roll		= RCRotated.X;
				RCFinal.Pitch		= RCRotated.Y;
				RCFinal.Yaw			= RCRotated.Z;
				}
			// Calculate motor control based
			// upon IMU data
			QCMPerformStep(&RCFinal, &IMU, &MC);
			}
		else
			{
			// IMU Failed to provide update -
			// set Motor Control to RC throttle
			MC.F = MC.B = MC.L = MC.R = RCFinal.Throttle;
			}
		// </editor-fold>
		//============================================================

		//************************************************************
		// Implement Motor Cut-Off to protect props if model is
		// dangerously tilted (> 60 degrees) while RC Throttle is low
		//------------------------------------------------------------
		if (IMU.Incl <= 0.5 && RCFinal.Throttle <= 0.40)
			{
			// Override motor control
			MC.F = MC.B = MC.L = MC.R = 0.0;
			}
		//------------------------------------------------------------

		//************************************************************
		// Update motor control
		//************************************************************
		MCMSet(&MC);
		//------------------------------------------------------------
		
		//===========================================================
		// Load and post telemetry data (non-blocking call)
		//-----------------------------------------------------------
		// <editor-fold defaultstate="collapsed" desc="Populating Telemetry">
		//-----------------------------------------
		TM.TS			= StepTS - StartTS;
		//----------------------
		TM.Roll			= IMU.Roll;
		TM.Pitch		= IMU.Pitch;
		TM.Yaw			= IMU.Yaw;
		TM.Inclination	= IMU.Incl;
		TM.Azimuth		= IMU.Azimuth;
		//----------------------
		#ifdef  _TMReport_GYRO_
			#ifdef	_TMReport_GYRO_Rotated
			//------------------------------------------------------
			// We rotate Gyro vector using "partial" DCM built using
			// only Roll and Pitch angles as the actual Yaw does not
			// affect Angualr Velocity by axis
			//------------------------------------------------------
			Vector		Earth;	// One of the Earth axis in Body frame
			Vector		Cross;	// Temporary vector to hold the cross
								// product
			//------------------------------------------------------
			// Calculate Roll and Pitch rates
			//------------------------------------------------------
			// Retrieve Earth Z-axis and calculate cross-product of
			// Z-axis with Gyro vector
			VectorCrossProduct(DCMEarthZ(&Earth), &IMU.GyroRate, &Cross);
			TM.Gyro.X = Cross.X;
			TM.Gyro.Y = Cross.Y;
			//------------------------------------------------------
			// Calculate Yaw rate
			//------------------------------------------------------
			// Retrieve Earth X-axis and calculate cross-product of
			// X-axis with Gyro vector
			VectorCrossProduct(DCMEarthX(&Earth), &IMU.GyroRate, &Cross);
			TM.Gyro.Z = Cross.Z;
			#else
			// Just report native Gyro data
			VectorCopy(&IMU.GyroRate, &TM.Gyro);
			#endif
		#endif
		//----------------------
		#ifdef  _TMReport_ACC_
		// Just report native Gyro data
		VectorCopy(&IMU.Gravity, &TM.Acc);
		#endif
		//----------------------
		TM.RollDer		= QSD.RollDer;
		TM.PitchDer		= QSD.PitchDer;
		TM.YawDer		= QSD.YawDer;
		//----------------------
		TM.RC_Throttle	= RCFinal.Throttle;
		TM.RC_Roll		= RCFinal.Roll;
		TM.RC_Pitch		= RCFinal.Pitch;
		TM.RC_Yaw		= RCFinal.Yaw;
		//----------------------
		#ifdef _TMReport_RCSmthd_
		TM.RCS_Throttle	= RCSmthd.Throttle;
		TM.RCS_Roll		= RCSmthd.Roll;
		TM.RCS_Pitch	= RCSmthd.Pitch;
		TM.RCS_Yaw		= RCSmthd.Yaw;
		#endif
		//----------------------
		#ifdef _TMReport_RCFeed_
		TM.RCN_Throttle	= RCFeed.Throttle;
		TM.RCN_Roll		= RCFeed.Roll;
		TM.RCN_Pitch	= RCFeed.Pitch;
		TM.RCN_Yaw		= RCFeed.Yaw;
		#endif
		//----------------------
		#ifdef _TMReport_Altimetry_
		if ( 0 == AltimeterGetAltData(	IMU.TS,
								&IMU.Gravity,
								&TM.AltResult) )
			goto EndOfCycle;	// Skip reporting on this step
		#endif
		//----------------------
		#ifdef _TMReport_PID_
		#ifdef _TMReport_PID_Details
		TM.DRProp		= QSD.DeltaRollProp;
		TM.DRDiff		= QSD.DeltaRollDiff;
		TM.DRInt		= QSD.DeltaRollInt;
		#endif
		TM.DRTot		= QSD.DeltaRoll;
		//-------------
		#ifdef _TMReport_PID_Details
		TM.DPProp		= QSD.DeltaPitchProp;
		TM.DPDiff		= QSD.DeltaPitchDiff;
		TM.DPInt		= QSD.DeltaPitchInt;
		#endif
		TM.DPTot		= QSD.DeltaPitch;
		//-------------
		#ifdef _TMReport_PID_Details
		TM.DYProp		= QSD.DeltaYawProp;
		TM.DYDiff		= QSD.DeltaYawDiff;
		TM.DYInt		= QSD.DeltaYawInt;
		#endif
		TM.DYTot		= QSD.DeltaYaw;
		#endif
		//----------------------
		TM.Throttle		= QSD.Throttle;				// Real Throttle
		//----------------------
		TM.Voltage 		= ADCGetBatteryVoltage();
		// </editor-fold>
		//===========================================================
		UARTPostIfReady( (unsigned char *) &TM, sizeof(TM)	);
		//===========================================================
		// Insert controlled "delay" to slow down the Control Loop
		// to pre-set frequency
	EndOfCycle:
		TMRWaitAlarm(Alarm);
		//===========================================================
		}
	//*******************************************************************
	return 1;
	}