azaleasource/WPILibCProgramming/trunk/WPILib/Ultrasonic.cpp - RealtimeRoboticsGroup/test - Gitiles

 /*----------------------------------------------------------------------------*/
 /* Copyright (c) FIRST 2008. All Rights Reserved.							  */
 /* Open Source Software - may be modified and shared by FRC teams. The code   */
 /* must be accompanied by the FIRST BSD license file in $(WIND_BASE)/WPILib.  */
 /*----------------------------------------------------------------------------*/

 #include "Ultrasonic.h"

 #include "Counter.h"
 #include "DigitalInput.h"
 #include "DigitalOutput.h"
 #include "NetworkCommunication/UsageReporting.h"
 #include "Timer.h"
 #include "Utility.h"
 #include "WPIErrors.h"
 #include "LiveWindow/LiveWindow.h"

 const double Ultrasonic::kPingTime;	///< Time (sec) for the ping trigger pulse.
 const UINT32 Ultrasonic::kPriority;	///< Priority that the ultrasonic round robin task runs.
 const double Ultrasonic::kMaxUltrasonicTime;	///< Max time (ms) between readings.
 const double Ultrasonic::kSpeedOfSoundInchesPerSec;
 Task Ultrasonic::m_task("UltrasonicChecker", (FUNCPTR)UltrasonicChecker); // task doing the round-robin automatic sensing
 Ultrasonic *Ultrasonic::m_firstSensor = NULL; // head of the ultrasonic sensor list
 bool Ultrasonic::m_automaticEnabled = false; // automatic round robin mode
 SEM_ID Ultrasonic::m_semaphore = 0;

 /**
  * Background task that goes through the list of ultrasonic sensors and pings each one in turn. The counter
  * is configured to read the timing of the returned echo pulse.
  *
  * DANGER WILL ROBINSON, DANGER WILL ROBINSON:
  * This code runs as a task and assumes that none of the ultrasonic sensors will change while it's
  * running. If one does, then this will certainly break. Make sure to disable automatic mode before changing
  * anything with the sensors!!
  */
 void Ultrasonic::UltrasonicChecker()
 {
 	Ultrasonic *u = NULL;
 	while (m_automaticEnabled)
 	{
 		if (u == NULL) u = m_firstSensor;
 		if (u == NULL) return;
 		if (u->IsEnabled())
 			u->m_pingChannel->Pulse(kPingTime);	// do the ping
 		u = u->m_nextSensor;
 		Wait(0.1);							// wait for ping to return
 	}
 }

 /**
  * Initialize the Ultrasonic Sensor.
  * This is the common code that initializes the ultrasonic sensor given that there
  * are two digital I/O channels allocated. If the system was running in automatic mode (round robin)
  * when the new sensor is added, it is stopped, the sensor is added, then automatic mode is
  * restored.
  */
 void Ultrasonic::Initialize()
 {
 	m_table = NULL;
 	bool originalMode = m_automaticEnabled;
 	if (m_semaphore == 0) m_semaphore = semBCreate(SEM_Q_PRIORITY, SEM_FULL);
 	SetAutomaticMode(false); // kill task when adding a new sensor
 	semTake(m_semaphore, WAIT_FOREVER); // link this instance on the list
 	{
 		m_nextSensor = m_firstSensor;
 		m_firstSensor = this;
 	}
 	semGive(m_semaphore);

 	m_counter = new Counter(m_echoChannel); // set up counter for this sensor
 	m_counter->SetMaxPeriod(1.0);
 	m_counter->SetSemiPeriodMode(true);
 	m_counter->Reset();
 	m_counter->Start();
 	m_enabled = true; // make it available for round robin scheduling
 	SetAutomaticMode(originalMode);

 	static int instances = 0;
 	instances++;
 	nUsageReporting::report(nUsageReporting::kResourceType_Ultrasonic, instances);
 	LiveWindow::GetInstance()->AddSensor("Ultrasonic", m_echoChannel->GetModuleForRouting(), m_echoChannel->GetChannel(), this);
 }

 /**
  * Create an instance of the Ultrasonic Sensor using the default module.
  * This is designed to supchannel the Daventech SRF04 and Vex ultrasonic sensors. This
  * constructor assumes that both digital I/O channels are in the default digital module.
  * @param pingChannel The digital output channel that sends the pulse to initiate the sensor sending
  * the ping.
  * @param echoChannel The digital input channel that receives the echo. The length of time that the
  * echo is high represents the round trip time of the ping, and the distance.
  * @param units The units returned in either kInches or kMilliMeters
  */
 Ultrasonic::Ultrasonic(UINT32 pingChannel, UINT32 echoChannel, DistanceUnit units)
 {
 	m_pingChannel = new DigitalOutput(pingChannel);
 	m_echoChannel = new DigitalInput(echoChannel);
 	m_allocatedChannels = true;
 	m_units = units;
 	Initialize();
 }

 /**
  * Create an instance of an Ultrasonic Sensor from a DigitalInput for the echo channel and a DigitalOutput
  * for the ping channel.
  * @param pingChannel The digital output object that starts the sensor doing a ping. Requires a 10uS pulse to start.
  * @param echoChannel The digital input object that times the return pulse to determine the range.
  * @param units The units returned in either kInches or kMilliMeters
  */
 Ultrasonic::Ultrasonic(DigitalOutput *pingChannel, DigitalInput *echoChannel, DistanceUnit units)
 {
 	if (pingChannel == NULL || echoChannel == NULL)
 	{
 		wpi_setWPIError(NullParameter);
 		return;
 	}
 	m_allocatedChannels = false;
 	m_pingChannel = pingChannel;
 	m_echoChannel = echoChannel;
 	m_units = units;
 	Initialize();
 }

 /**
  * Create an instance of an Ultrasonic Sensor from a DigitalInput for the echo channel and a DigitalOutput
  * for the ping channel.
  * @param pingChannel The digital output object that starts the sensor doing a ping. Requires a 10uS pulse to start.
  * @param echoChannel The digital input object that times the return pulse to determine the range.
  * @param units The units returned in either kInches or kMilliMeters
  */
 Ultrasonic::Ultrasonic(DigitalOutput &pingChannel, DigitalInput &echoChannel, DistanceUnit units)
 {
 	m_allocatedChannels = false;
 	m_pingChannel = &pingChannel;
 	m_echoChannel = &echoChannel;
 	m_units = units;
 	Initialize();
 }

 /**
  * Create an instance of the Ultrasonic sensor using specified modules.
  * This is designed to supchannel the Daventech SRF04 and Vex ultrasonic sensors. This
  * constructors takes the channel and module slot for each of the required digital I/O channels.
  * @param pingModuleNumber The digital module that the pingChannel is on.
  * @param pingChannel The digital output channel that sends the pulse to initiate the sensor
  * sending the ping.
  * @param echoModuleNumber The digital module that the echoChannel is on.
  * @param echoChannel The digital input channel that receives the echo. The length of time
  * that the echo is high represents the round trip time of the ping, and the distance.
  * @param units The units returned in either kInches or kMilliMeters
  */
 Ultrasonic::Ultrasonic(UINT8 pingModuleNumber, UINT32 pingChannel,
 		UINT8 echoModuleNumber, UINT32 echoChannel, DistanceUnit units)
 {
 	m_pingChannel = new DigitalOutput(pingModuleNumber, pingChannel);
 	m_echoChannel = new DigitalInput(echoModuleNumber, echoChannel);
 	m_allocatedChannels = true;
 	m_units = units;
 	Initialize();
 }

 /**
  * Destructor for the ultrasonic sensor.
  * Delete the instance of the ultrasonic sensor by freeing the allocated digital channels.
  * If the system was in automatic mode (round robin), then it is stopped, then started again
  * after this sensor is removed (provided this wasn't the last sensor).
  */
 Ultrasonic::~Ultrasonic()
 {
 	bool wasAutomaticMode = m_automaticEnabled;
 	SetAutomaticMode(false);
 	if (m_allocatedChannels)
 	{
 		delete m_pingChannel;
 		delete m_echoChannel;
 	}
 	wpi_assert(m_firstSensor != NULL);

 	semTake(m_semaphore, WAIT_FOREVER);
 	{
 		if (this == m_firstSensor)
 		{
 			m_firstSensor = m_nextSensor;
 			if (m_firstSensor == NULL)
 			{
 				SetAutomaticMode(false);
 			}
 		}
 		else
 		{
 			wpi_assert(m_firstSensor->m_nextSensor != NULL);
 			for (Ultrasonic *s = m_firstSensor; s != NULL; s = s->m_nextSensor)
 			{
 				if (this == s->m_nextSensor)
 				{
 					s->m_nextSensor = s->m_nextSensor->m_nextSensor;
 					break;
 				}
 			}
 		}
 	}
 	semGive(m_semaphore);
 	if (m_firstSensor != NULL && wasAutomaticMode)
 		SetAutomaticMode(true);
 }

 /**
  * Turn Automatic mode on/off.
  * When in Automatic mode, all sensors will fire in round robin, waiting a set
  * time between each sensor.
  * @param enabling Set to true if round robin scheduling should start for all the ultrasonic sensors. This
  * scheduling method assures that the sensors are non-interfering because no two sensors fire at the same time.
  * If another scheduling algorithm is preffered, it can be implemented by pinging the sensors manually and waiting
  * for the results to come back.
  */
 void Ultrasonic::SetAutomaticMode(bool enabling)
 {
 	if (enabling == m_automaticEnabled)
 		return; // ignore the case of no change

 	m_automaticEnabled = enabling;
 	if (enabling)
 	{
 		// enabling automatic mode.
 		// Clear all the counters so no data is valid
 		for (Ultrasonic *u = m_firstSensor; u != NULL; u = u->m_nextSensor)
 		{
 			u->m_counter->Reset();
 		}
 		// Start round robin task
 		wpi_assert(m_task.Verify() == false);	// should be false since was previously disabled
 		m_task.Start();
 	}
 	else
 	{
 		// disabling automatic mode. Wait for background task to stop running.
 		while (m_task.Verify())
 			Wait(0.15);	// just a little longer than the ping time for round-robin to stop

 		// clear all the counters (data now invalid) since automatic mode is stopped
 		for (Ultrasonic *u = m_firstSensor; u != NULL; u = u->m_nextSensor)
 		{
 			u->m_counter->Reset();
 		}
 		m_task.Stop();
 	}
 }

 /**
  * Single ping to ultrasonic sensor.
  * Send out a single ping to the ultrasonic sensor. This only works if automatic (round robin)
  * mode is disabled. A single ping is sent out, and the counter should count the semi-period
  * when it comes in. The counter is reset to make the current value invalid.
  */
 void Ultrasonic::Ping()
 {
 	// TODO: Either assert or disable, not both.
 	wpi_assert(!m_automaticEnabled);
 	SetAutomaticMode(false); // turn off automatic round robin if pinging single sensor
 	m_counter->Reset(); // reset the counter to zero (invalid data now)
 	m_pingChannel->Pulse(kPingTime); // do the ping to start getting a single range
 }

 /**
  * Check if there is a valid range measurement.
  * The ranges are accumulated in a counter that will increment on each edge of the echo (return)
  * signal. If the count is not at least 2, then the range has not yet been measured, and is invalid.
  */
 bool Ultrasonic::IsRangeValid()
 {
 	return m_counter->Get() > 1;
 }

 /**
  * Get the range in inches from the ultrasonic sensor.
  * @return double Range in inches of the target returned from the ultrasonic sensor. If there is
  * no valid value yet, i.e. at least one measurement hasn't completed, then return 0.
  */
 double Ultrasonic::GetRangeInches()
 {
 	if (IsRangeValid())
 		return m_counter->GetPeriod() * kSpeedOfSoundInchesPerSec / 2.0;
 	else
 		return 0;
 }

 /**
  * Get the range in millimeters from the ultrasonic sensor.
  * @return double Range in millimeters of the target returned by the ultrasonic sensor.
  * If there is no valid value yet, i.e. at least one measurement hasn't complted, then return 0.
  */
 double Ultrasonic::GetRangeMM()
 {
 	return GetRangeInches() * 25.4;
 }

 /**
  * Get the range in the current DistanceUnit for the PIDSource base object.
  *
  * @return The range in DistanceUnit
  */
 double Ultrasonic::PIDGet()
 {
 	switch(m_units)
 	{
 	case Ultrasonic::kInches:
 		return GetRangeInches();
 	case Ultrasonic::kMilliMeters:
 		return GetRangeMM();
 	default:
 		return 0.0;
 	}
 }

 /**
  * Set the current DistanceUnit that should be used for the PIDSource base object.
  *
  * @param units The DistanceUnit that should be used.
  */
 void Ultrasonic::SetDistanceUnits(DistanceUnit units)
 {
 	m_units = units;
 }

 /**
  * Get the current DistanceUnit that is used for the PIDSource base object.
  *
  * @return The type of DistanceUnit that is being used.
  */
 Ultrasonic::DistanceUnit Ultrasonic::GetDistanceUnits()
 {
 	return m_units;
 }

 void Ultrasonic::UpdateTable() {
 	if (m_table != NULL) {
 		m_table->PutNumber("Value", GetRangeInches());
 	}
 }

 void Ultrasonic::StartLiveWindowMode() {

 }

 void Ultrasonic::StopLiveWindowMode() {

 }

 std::string Ultrasonic::GetSmartDashboardType() {
 	return "Ultrasonic";
 }

 void Ultrasonic::InitTable(ITable *subTable) {
 	m_table = subTable;
 	UpdateTable();
 }

 ITable * Ultrasonic::GetTable() {
 	return m_table;
 }
	/----------------------------------------------------------------------------/
	/* Copyright (c) FIRST 2008. All Rights Reserved. */
	/* Open Source Software - may be modified and shared by FRC teams. The code */
	/* must be accompanied by the FIRST BSD license file in $(WIND_BASE)/WPILib. */
	/----------------------------------------------------------------------------/

	#include "Ultrasonic.h"

	#include "Counter.h"
	#include "DigitalInput.h"
	#include "DigitalOutput.h"
	#include "NetworkCommunication/UsageReporting.h"
	#include "Timer.h"
	#include "Utility.h"
	#include "WPIErrors.h"
	#include "LiveWindow/LiveWindow.h"

	const double Ultrasonic::kPingTime; ///< Time (sec) for the ping trigger pulse.
	const UINT32 Ultrasonic::kPriority; ///< Priority that the ultrasonic round robin task runs.
	const double Ultrasonic::kMaxUltrasonicTime; ///< Max time (ms) between readings.
	const double Ultrasonic::kSpeedOfSoundInchesPerSec;
	Task Ultrasonic::m_task("UltrasonicChecker", (FUNCPTR)UltrasonicChecker); // task doing the round-robin automatic sensing
	Ultrasonic *Ultrasonic::m_firstSensor = NULL; // head of the ultrasonic sensor list
	bool Ultrasonic::m_automaticEnabled = false; // automatic round robin mode
	SEM_ID Ultrasonic::m_semaphore = 0;

	/**
	* Background task that goes through the list of ultrasonic sensors and pings each one in turn. The counter
	* is configured to read the timing of the returned echo pulse.
	*
	* DANGER WILL ROBINSON, DANGER WILL ROBINSON:
	* This code runs as a task and assumes that none of the ultrasonic sensors will change while it's
	* running. If one does, then this will certainly break. Make sure to disable automatic mode before changing
	* anything with the sensors!!
	*/
	void Ultrasonic::UltrasonicChecker()
	{
	Ultrasonic *u = NULL;
	while (m_automaticEnabled)
	{
	if (u == NULL) u = m_firstSensor;
	if (u == NULL) return;
	if (u->IsEnabled())
	u->m_pingChannel->Pulse(kPingTime); // do the ping
	u = u->m_nextSensor;
	Wait(0.1); // wait for ping to return
	}
	}

	/**
	* Initialize the Ultrasonic Sensor.
	* This is the common code that initializes the ultrasonic sensor given that there
	* are two digital I/O channels allocated. If the system was running in automatic mode (round robin)
	* when the new sensor is added, it is stopped, the sensor is added, then automatic mode is
	* restored.
	*/
	void Ultrasonic::Initialize()
	{
	m_table = NULL;
	bool originalMode = m_automaticEnabled;
	if (m_semaphore == 0) m_semaphore = semBCreate(SEM_Q_PRIORITY, SEM_FULL);
	SetAutomaticMode(false); // kill task when adding a new sensor
	semTake(m_semaphore, WAIT_FOREVER); // link this instance on the list
	{
	m_nextSensor = m_firstSensor;
	m_firstSensor = this;
	}
	semGive(m_semaphore);

	m_counter = new Counter(m_echoChannel); // set up counter for this sensor
	m_counter->SetMaxPeriod(1.0);
	m_counter->SetSemiPeriodMode(true);
	m_counter->Reset();
	m_counter->Start();
	m_enabled = true; // make it available for round robin scheduling
	SetAutomaticMode(originalMode);

	static int instances = 0;
	instances++;
	nUsageReporting::report(nUsageReporting::kResourceType_Ultrasonic, instances);
	LiveWindow::GetInstance()->AddSensor("Ultrasonic", m_echoChannel->GetModuleForRouting(), m_echoChannel->GetChannel(), this);
	}

	/**
	* Create an instance of the Ultrasonic Sensor using the default module.
	* This is designed to supchannel the Daventech SRF04 and Vex ultrasonic sensors. This
	* constructor assumes that both digital I/O channels are in the default digital module.
	* @param pingChannel The digital output channel that sends the pulse to initiate the sensor sending
	* the ping.
	* @param echoChannel The digital input channel that receives the echo. The length of time that the
	* echo is high represents the round trip time of the ping, and the distance.
	* @param units The units returned in either kInches or kMilliMeters
	*/
	Ultrasonic::Ultrasonic(UINT32 pingChannel, UINT32 echoChannel, DistanceUnit units)
	{
	m_pingChannel = new DigitalOutput(pingChannel);
	m_echoChannel = new DigitalInput(echoChannel);
	m_allocatedChannels = true;
	m_units = units;
	Initialize();
	}

	/**
	* Create an instance of an Ultrasonic Sensor from a DigitalInput for the echo channel and a DigitalOutput
	* for the ping channel.
	* @param pingChannel The digital output object that starts the sensor doing a ping. Requires a 10uS pulse to start.
	* @param echoChannel The digital input object that times the return pulse to determine the range.
	* @param units The units returned in either kInches or kMilliMeters
	*/
	Ultrasonic::Ultrasonic(DigitalOutput pingChannel, DigitalInput echoChannel, DistanceUnit units)
	{
	if (pingChannel == NULL \|\| echoChannel == NULL)
	{
	wpi_setWPIError(NullParameter);
	return;
	}
	m_allocatedChannels = false;
	m_pingChannel = pingChannel;
	m_echoChannel = echoChannel;
	m_units = units;
	Initialize();
	}

	/**
	* Create an instance of an Ultrasonic Sensor from a DigitalInput for the echo channel and a DigitalOutput
	* for the ping channel.
	* @param pingChannel The digital output object that starts the sensor doing a ping. Requires a 10uS pulse to start.
	* @param echoChannel The digital input object that times the return pulse to determine the range.
	* @param units The units returned in either kInches or kMilliMeters
	*/
	Ultrasonic::Ultrasonic(DigitalOutput &pingChannel, DigitalInput &echoChannel, DistanceUnit units)
	{
	m_allocatedChannels = false;
	m_pingChannel = &pingChannel;
	m_echoChannel = &echoChannel;
	m_units = units;
	Initialize();
	}

	/**
	* Create an instance of the Ultrasonic sensor using specified modules.
	* This is designed to supchannel the Daventech SRF04 and Vex ultrasonic sensors. This
	* constructors takes the channel and module slot for each of the required digital I/O channels.
	* @param pingModuleNumber The digital module that the pingChannel is on.
	* @param pingChannel The digital output channel that sends the pulse to initiate the sensor
	* sending the ping.
	* @param echoModuleNumber The digital module that the echoChannel is on.
	* @param echoChannel The digital input channel that receives the echo. The length of time
	* that the echo is high represents the round trip time of the ping, and the distance.
	* @param units The units returned in either kInches or kMilliMeters
	*/
	Ultrasonic::Ultrasonic(UINT8 pingModuleNumber, UINT32 pingChannel,
	UINT8 echoModuleNumber, UINT32 echoChannel, DistanceUnit units)
	{
	m_pingChannel = new DigitalOutput(pingModuleNumber, pingChannel);
	m_echoChannel = new DigitalInput(echoModuleNumber, echoChannel);
	m_allocatedChannels = true;
	m_units = units;
	Initialize();
	}

	/**
	* Destructor for the ultrasonic sensor.
	* Delete the instance of the ultrasonic sensor by freeing the allocated digital channels.
	* If the system was in automatic mode (round robin), then it is stopped, then started again
	* after this sensor is removed (provided this wasn't the last sensor).
	*/
	Ultrasonic::~Ultrasonic()
	{
	bool wasAutomaticMode = m_automaticEnabled;
	SetAutomaticMode(false);
	if (m_allocatedChannels)
	{
	delete m_pingChannel;
	delete m_echoChannel;
	}
	wpi_assert(m_firstSensor != NULL);

	semTake(m_semaphore, WAIT_FOREVER);
	{
	if (this == m_firstSensor)
	{
	m_firstSensor = m_nextSensor;
	if (m_firstSensor == NULL)
	{
	SetAutomaticMode(false);
	}
	}
	else
	{
	wpi_assert(m_firstSensor->m_nextSensor != NULL);
	for (Ultrasonic *s = m_firstSensor; s != NULL; s = s->m_nextSensor)
	{
	if (this == s->m_nextSensor)
	{
	s->m_nextSensor = s->m_nextSensor->m_nextSensor;
	break;
	}
	}
	}
	}
	semGive(m_semaphore);
	if (m_firstSensor != NULL && wasAutomaticMode)
	SetAutomaticMode(true);
	}

	/**
	* Turn Automatic mode on/off.
	* When in Automatic mode, all sensors will fire in round robin, waiting a set
	* time between each sensor.
	* @param enabling Set to true if round robin scheduling should start for all the ultrasonic sensors. This
	* scheduling method assures that the sensors are non-interfering because no two sensors fire at the same time.
	* If another scheduling algorithm is preffered, it can be implemented by pinging the sensors manually and waiting
	* for the results to come back.
	*/
	void Ultrasonic::SetAutomaticMode(bool enabling)
	{
	if (enabling == m_automaticEnabled)
	return; // ignore the case of no change

	m_automaticEnabled = enabling;
	if (enabling)
	{
	// enabling automatic mode.
	// Clear all the counters so no data is valid
	for (Ultrasonic *u = m_firstSensor; u != NULL; u = u->m_nextSensor)
	{
	u->m_counter->Reset();
	}
	// Start round robin task
	wpi_assert(m_task.Verify() == false); // should be false since was previously disabled
	m_task.Start();
	}
	else
	{
	// disabling automatic mode. Wait for background task to stop running.
	while (m_task.Verify())
	Wait(0.15); // just a little longer than the ping time for round-robin to stop

	// clear all the counters (data now invalid) since automatic mode is stopped
	for (Ultrasonic *u = m_firstSensor; u != NULL; u = u->m_nextSensor)
	{
	u->m_counter->Reset();
	}
	m_task.Stop();
	}
	}

	/**
	* Single ping to ultrasonic sensor.
	* Send out a single ping to the ultrasonic sensor. This only works if automatic (round robin)
	* mode is disabled. A single ping is sent out, and the counter should count the semi-period
	* when it comes in. The counter is reset to make the current value invalid.
	*/
	void Ultrasonic::Ping()
	{
	// TODO: Either assert or disable, not both.
	wpi_assert(!m_automaticEnabled);
	SetAutomaticMode(false); // turn off automatic round robin if pinging single sensor
	m_counter->Reset(); // reset the counter to zero (invalid data now)
	m_pingChannel->Pulse(kPingTime); // do the ping to start getting a single range
	}

	/**
	* Check if there is a valid range measurement.
	* The ranges are accumulated in a counter that will increment on each edge of the echo (return)
	* signal. If the count is not at least 2, then the range has not yet been measured, and is invalid.
	*/
	bool Ultrasonic::IsRangeValid()
	{
	return m_counter->Get() > 1;
	}

	/**
	* Get the range in inches from the ultrasonic sensor.
	* @return double Range in inches of the target returned from the ultrasonic sensor. If there is
	* no valid value yet, i.e. at least one measurement hasn't completed, then return 0.
	*/
	double Ultrasonic::GetRangeInches()
	{
	if (IsRangeValid())
	return m_counter->GetPeriod() * kSpeedOfSoundInchesPerSec / 2.0;
	else
	return 0;
	}

	/**
	* Get the range in millimeters from the ultrasonic sensor.
	* @return double Range in millimeters of the target returned by the ultrasonic sensor.
	* If there is no valid value yet, i.e. at least one measurement hasn't complted, then return 0.
	*/
	double Ultrasonic::GetRangeMM()
	{
	return GetRangeInches() * 25.4;
	}

	/**
	* Get the range in the current DistanceUnit for the PIDSource base object.
	*
	* @return The range in DistanceUnit
	*/
	double Ultrasonic::PIDGet()
	{
	switch(m_units)
	{
	case Ultrasonic::kInches:
	return GetRangeInches();
	case Ultrasonic::kMilliMeters:
	return GetRangeMM();
	default:
	return 0.0;
	}
	}

	/**
	* Set the current DistanceUnit that should be used for the PIDSource base object.
	*
	* @param units The DistanceUnit that should be used.
	*/
	void Ultrasonic::SetDistanceUnits(DistanceUnit units)
	{
	m_units = units;
	}

	/**
	* Get the current DistanceUnit that is used for the PIDSource base object.
	*
	* @return The type of DistanceUnit that is being used.
	*/
	Ultrasonic::DistanceUnit Ultrasonic::GetDistanceUnits()
	{
	return m_units;
	}

	void Ultrasonic::UpdateTable() {
	if (m_table != NULL) {
	m_table->PutNumber("Value", GetRangeInches());
	}
	}

	void Ultrasonic::StartLiveWindowMode() {

	}

	void Ultrasonic::StopLiveWindowMode() {

	}

	std::string Ultrasonic::GetSmartDashboardType() {
	return "Ultrasonic";
	}

	void Ultrasonic::InitTable(ITable *subTable) {
	m_table = subTable;
	UpdateTable();
	}

	ITable * Ultrasonic::GetTable() {
	return m_table;
	}