/** * Helper routine to get last received message for a given ID. */ private long checkMessage(int fullId, int deviceId) { try { targetId.clear(); targetId.order(ByteOrder.LITTLE_ENDIAN); targetId.asIntBuffer().put(0, fullId | deviceId); timestamp.clear(); timestamp.order(ByteOrder.LITTLE_ENDIAN); timestamp.asIntBuffer().put(0, 0x00000000); CANJNI.FRCNetCommCANSessionMuxReceiveMessage(targetId.asIntBuffer(), 0x1fffffff, timestamp); long retval = timestamp.getInt(); retval &= 0xFFFFFFFF; /* undo sign-extension */ return retval; } catch (Exception ex) { return -1; } }
/** helper routine to get last received message for a given ID */ private long checkMessage(int fullId, int deviceID) { try { targetID.clear(); targetID.order(ByteOrder.LITTLE_ENDIAN); targetID.asIntBuffer().put(0,fullId|deviceID); timeStamp.clear(); timeStamp.order(ByteOrder.LITTLE_ENDIAN); timeStamp.asIntBuffer().put(0,0x00000000); CANJNI.FRCNetworkCommunicationCANSessionMuxReceiveMessage(targetID.asIntBuffer(), 0x1fffffff, timeStamp); long retval = timeStamp.getInt(); retval &= 0xFFFFFFFF; /* undo sign-extension */ return retval; } catch (Exception e) { return -1; } }
/** * Set the P constant for the closed loop modes. * * @param p The proportional gain of the Jaguar's PID controller. */ public void setP(double p) { byte[] data = new byte[8]; byte dataSize = packFXP16_16(data, p); switch (m_controlMode) { case Speed: sendMessage(CANJNI.LM_API_SPD_PC, data, dataSize); break; case Position: sendMessage(CANJNI.LM_API_POS_PC, data, dataSize); break; case Current: sendMessage(CANJNI.LM_API_ICTRL_PC, data, dataSize); break; default: throw new IllegalStateException( "PID constants only apply in Speed, Position, and Current mode"); } m_p = p; m_pVerified = false; }
/** * Set the I constant for the closed loop modes. * * @param i The integral gain of the Jaguar's PID controller. */ public void setI(double i) { byte[] data = new byte[8]; byte dataSize = packFXP16_16(data, i); switch (m_controlMode) { case Speed: sendMessage(CANJNI.LM_API_SPD_IC, data, dataSize); break; case Position: sendMessage(CANJNI.LM_API_POS_IC, data, dataSize); break; case Current: sendMessage(CANJNI.LM_API_ICTRL_IC, data, dataSize); break; default: throw new IllegalStateException( "PID constants only apply in Speed, Position, and Current mode"); } m_i = i; m_iVerified = false; }
/** * Set the D constant for the closed loop modes. * * @param d The derivative gain of the Jaguar's PID controller. */ public void setD(double d) { byte[] data = new byte[8]; byte dataSize = packFXP16_16(data, d); switch (m_controlMode) { case Speed: sendMessage(CANJNI.LM_API_SPD_DC, data, dataSize); break; case Position: sendMessage(CANJNI.LM_API_POS_DC, data, dataSize); break; case Current: sendMessage(CANJNI.LM_API_ICTRL_DC, data, dataSize); break; default: throw new IllegalStateException( "PID constants only apply in Speed, Position, and Current mode"); } m_d = d; m_dVerified = false; }
/** * Disable the closed loop controller. * * Stop driving the output based on the feedback. */ public void disableControl() { // Disable all control modes. sendMessage(CANJNI.LM_API_VOLT_DIS, new byte[0], 0); sendMessage(CANJNI.LM_API_SPD_DIS, new byte[0], 0); sendMessage(CANJNI.LM_API_POS_DIS, new byte[0], 0); sendMessage(CANJNI.LM_API_ICTRL_DIS, new byte[0], 0); sendMessage(CANJNI.LM_API_VCOMP_DIS, new byte[0], 0); // Stop all periodic setpoints sendMessage(CANJNI.LM_API_VOLT_T_SET, new byte[0], 0, CANJNI.CAN_SEND_PERIOD_STOP_REPEATING); sendMessage(CANJNI.LM_API_SPD_T_SET, new byte[0], 0, CANJNI.CAN_SEND_PERIOD_STOP_REPEATING); sendMessage(CANJNI.LM_API_POS_T_SET, new byte[0], 0, CANJNI.CAN_SEND_PERIOD_STOP_REPEATING); sendMessage(CANJNI.LM_API_ICTRL_T_SET, new byte[0], 0, CANJNI.CAN_SEND_PERIOD_STOP_REPEATING); sendMessage(CANJNI.LM_API_VCOMP_T_SET, new byte[0], 0, CANJNI.CAN_SEND_PERIOD_STOP_REPEATING); m_controlEnabled = false; }
/** * set the maximum voltage change rate. * * When in PercentVbus or Voltage output mode, the rate at which the voltage * changes can be limited to reduce current spikes. set this to 0.0 to disable * rate limiting. * * @param rampRate The maximum rate of voltage change in Percent Voltage mode * in V/s. */ public void setVoltageRampRate(double rampRate) { byte[] data = new byte[8]; int dataSize; int message; switch (m_controlMode) { case PercentVbus: dataSize = packPercentage(data, rampRate / (m_maxOutputVoltage * kControllerRate)); message = CANJNI.LM_API_VOLT_SET_RAMP; break; case Voltage: dataSize = packFXP8_8(data, rampRate / kControllerRate); message = CANJNI.LM_API_VCOMP_COMP_RAMP; break; default: throw new IllegalStateException( "Voltage ramp rate only applies in Percentage and Voltage modes"); } sendMessage(message, data, dataSize); }
/** * Get a previously requested message. * * Jaguar always generates a message with the same message ID when replying. * * @param messageID The messageID to read from the CAN bus (device number is * added internally) * @param data The up to 8 bytes of data that was received with the message * * @throws CANMessageNotFoundException if there's not new message available */ protected void getMessage(int messageID, int messageMask, byte[] data) throws CANMessageNotFoundException { messageID |= m_deviceNumber; messageID &= CANJNI.CAN_MSGID_FULL_M; ByteBuffer targetedMessageID = ByteBuffer.allocateDirect(4); targetedMessageID.order(ByteOrder.LITTLE_ENDIAN); targetedMessageID.asIntBuffer().put(0, messageID); ByteBuffer timeStamp = ByteBuffer.allocateDirect(4); // Get the data. ByteBuffer dataBuffer = CANJNI.FRCNetworkCommunicationCANSessionMuxReceiveMessage(targetedMessageID.asIntBuffer(), messageMask, timeStamp); if (data != null) { for (int i = 0; i < dataBuffer.capacity(); i++) { data[i] = dataBuffer.get(i); } } }
/** * Cancel periodic messages to the Jaguar, effectively disabling it. No other * methods should be called after this is called. */ public void free() { allocated.free(m_deviceNumber - 1); m_safetyHelper = null; int messageID; // Disable periodic setpoints switch (m_controlMode) { case PercentVbus: messageID = m_deviceNumber | CANJNI.LM_API_VOLT_T_SET; break; case Speed: messageID = m_deviceNumber | CANJNI.LM_API_SPD_T_SET; break; case Position: messageID = m_deviceNumber | CANJNI.LM_API_POS_T_SET; break; case Current: messageID = m_deviceNumber | CANJNI.LM_API_ICTRL_T_SET; break; case Voltage: messageID = m_deviceNumber | CANJNI.LM_API_VCOMP_T_SET; break; default: return; } CANJNI.FRCNetworkCommunicationCANSessionMuxSendMessage(messageID, null, CANJNI.CAN_SEND_PERIOD_STOP_REPEATING); configMaxOutputVoltage(kApproxBusVoltage); }
/** * Enable the closed loop controller. * * Start actually controlling the output based on the feedback. If starting a * position controller with an encoder reference, use the * encoderInitialPosition parameter to initialize the encoder state. * * @param encoderInitialPosition Encoder position to set if position with * encoder reference. Ignored otherwise. */ public void enableControl(double encoderInitialPosition) { switch (m_controlMode) { case PercentVbus: sendMessage(CANJNI.LM_API_VOLT_T_EN, new byte[0], 0); break; case Speed: sendMessage(CANJNI.LM_API_SPD_T_EN, new byte[0], 0); break; case Position: byte[] data = new byte[8]; int dataSize = packFXP16_16(data, encoderInitialPosition); sendMessage(CANJNI.LM_API_POS_T_EN, data, dataSize); break; case Current: sendMessage(CANJNI.LM_API_ICTRL_T_EN, new byte[0], 0); break; case Voltage: sendMessage(CANJNI.LM_API_VCOMP_T_EN, new byte[0], 0); break; } m_controlEnabled = true; }
/** * Enable controlling the motor voltage with position feedback from a * potentiometer and no speed feedback. * * @param tag The constant {@link CANJaguar#kPotentiometer} */ public void setVoltageMode(PotentiometerTag tag) { changeControlMode(JaguarControlMode.Voltage); setPositionReference(CANJNI.LM_REF_POT); setSpeedReference(CANJNI.LM_REF_NONE); configPotentiometerTurns(1); }
/** * Configure how many codes per revolution are generated by your encoder. * * @param codesPerRev The number of counts per revolution in 1X mode. */ public void configEncoderCodesPerRev(int codesPerRev) { byte[] data = new byte[8]; int dataSize = packINT16(data, (short) codesPerRev); sendMessage(CANJNI.LM_API_CFG_ENC_LINES, data, dataSize); m_encoderCodesPerRev = (short) codesPerRev; m_encoderCodesPerRevVerified = false; }
/** * Configure the number of turns on the potentiometer. * * There is no special support for continuous turn potentiometers. Only * integer numbers of turns are supported. * * @param turns The number of turns of the potentiometer */ public void configPotentiometerTurns(int turns) { byte[] data = new byte[8]; int dataSize = packINT16(data, (short) turns); sendMessage(CANJNI.LM_API_CFG_POT_TURNS, data, dataSize); m_potentiometerTurns = (short) turns; m_potentiometerTurnsVerified = false; }
/** * Set the position that, if exceeded, will disable the forward direction. * * Use {@link #configSoftPositionLimits(double, double)} to set this and the * {@link LimitMode} automatically. *$ * @param forwardLimitPosition The position that, if exceeded, will disable * the forward direction. */ public void configForwardLimit(double forwardLimitPosition) { byte[] data = new byte[8]; int dataSize = packFXP16_16(data, forwardLimitPosition); data[dataSize++] = 1; sendMessage(CANJNI.LM_API_CFG_LIMIT_FWD, data, dataSize); m_forwardLimit = forwardLimitPosition; m_forwardLimitVerified = false; }
/** * Set the position that, if exceeded, will disable the reverse direction. * * Use {@link #configSoftPositionLimits(double, double)} to set this and the * {@link LimitMode} automatically. *$ * @param reverseLimitPosition The position that, if exceeded, will disable * the reverse direction. */ public void configReverseLimit(double reverseLimitPosition) { byte[] data = new byte[8]; int dataSize = packFXP16_16(data, reverseLimitPosition); data[dataSize++] = 1; sendMessage(CANJNI.LM_API_CFG_LIMIT_REV, data, dataSize); m_reverseLimit = reverseLimitPosition; m_reverseLimitVerified = false; }
/** * Configure the maximum voltage that the Jaguar will ever output. * * This can be used to limit the maximum output voltage in all modes so that * motors which cannot withstand full bus voltage can be used safely. * * @param voltage The maximum voltage output by the Jaguar. */ public void configMaxOutputVoltage(double voltage) { byte[] data = new byte[8]; int dataSize = packFXP8_8(data, voltage); sendMessage(CANJNI.LM_API_CFG_MAX_VOUT, data, dataSize); m_maxOutputVoltage = voltage; m_maxOutputVoltageVerified = false; }
/** * Configure how long the Jaguar waits in the case of a fault before resuming * operation. * * Faults include over temerature, over current, and bus under voltage. The * default is 3.0 seconds, but can be reduced to as low as 0.5 seconds. * * @param faultTime The time to wait before resuming operation, in seconds. */ public void configFaultTime(float faultTime) { byte[] data = new byte[8]; if (faultTime < 0.5f) faultTime = 0.5f; else if (faultTime > 3.0f) faultTime = 3.0f; int dataSize = packINT16(data, (short) (faultTime * 1000.0)); sendMessage(CANJNI.LM_API_CFG_FAULT_TIME, data, dataSize); m_faultTime = faultTime; m_faultTimeVerified = false; }
/** * Enables periodic status updates from the Jaguar */ protected void setupPeriodicStatus() { byte[] data = new byte[8]; int dataSize; // Message 0 returns bus voltage, output voltage, output current, and // temperature. final byte[] kMessage0Data = new byte[] {CANJNI.LM_PSTAT_VOLTBUS_B0, CANJNI.LM_PSTAT_VOLTBUS_B1, CANJNI.LM_PSTAT_VOLTOUT_B0, CANJNI.LM_PSTAT_VOLTOUT_B1, CANJNI.LM_PSTAT_CURRENT_B0, CANJNI.LM_PSTAT_CURRENT_B1, CANJNI.LM_PSTAT_TEMP_B0, CANJNI.LM_PSTAT_TEMP_B1}; // Message 1 returns position and speed final byte[] kMessage1Data = new byte[] {CANJNI.LM_PSTAT_POS_B0, CANJNI.LM_PSTAT_POS_B1, CANJNI.LM_PSTAT_POS_B2, CANJNI.LM_PSTAT_POS_B3, CANJNI.LM_PSTAT_SPD_B0, CANJNI.LM_PSTAT_SPD_B1, CANJNI.LM_PSTAT_SPD_B2, CANJNI.LM_PSTAT_SPD_B3}; // Message 2 returns limits and faults final byte[] kMessage2Data = new byte[] {CANJNI.LM_PSTAT_LIMIT_CLR, CANJNI.LM_PSTAT_FAULT, CANJNI.LM_PSTAT_END, (byte) 0, (byte) 0, (byte) 0, (byte) 0, (byte) 0,}; dataSize = packINT16(data, (short) (kSendMessagePeriod)); sendMessage(CANJNI.LM_API_PSTAT_PER_EN_S0, data, dataSize); sendMessage(CANJNI.LM_API_PSTAT_PER_EN_S1, data, dataSize); sendMessage(CANJNI.LM_API_PSTAT_PER_EN_S2, data, dataSize); dataSize = 8; sendMessage(CANJNI.LM_API_PSTAT_CFG_S0, kMessage0Data, dataSize); sendMessage(CANJNI.LM_API_PSTAT_CFG_S1, kMessage1Data, dataSize); sendMessage(CANJNI.LM_API_PSTAT_CFG_S2, kMessage2Data, dataSize); }
/** * Update all the motors that have pending sets in the syncGroup. * * @param syncGroup A bitmask of groups to generate synchronous output. */ public static void updateSyncGroup(byte syncGroup) { byte[] data = new byte[8]; data[0] = syncGroup; sendMessageHelper(CANJNI.CAN_MSGID_API_SYNC, data, 1, CANJNI.CAN_SEND_PERIOD_NO_REPEAT); }
void sendStateToLights(boolean isEnabled, boolean isAutonomous) { // final int MSGID_FOR_LIGHTS = CANJNI.LM_API_ICTRL_T_SET | 0x30; // ID=59 // LM_API_ICTRL_T_SET =((0x00020000 | 0x02000000 | 0x00001000) | (7 << 6)); // Final ID: 0x020211FB // (7 < 6) => 111000000 => 0x1C0 // Decoded on Ardinio as 0x1F02033B // Random: 0x2041441 // DO NOT CHANGE THIS NUMBER // Doug and Justin worked for a long while to find an ID that works. // We are using CAN ID 16 (0x10) Bigger IDs don't seem to work. final int MSGID_FOR_LIGHTS = 0x02021451; timer = System.currentTimeMillis(); if ( timer > lastRunTime + 100 ) // At least 100 ms difference. { lastRunTime = timer; CAN_data.put(0, (byte)(isAutonomous ? 0 : 1) ); CAN_data.put(1, (byte)(isBlue ? 0 : 1) ); CAN_data.put(2, (byte)(isEnabled ? 1 : 0) ); CAN_data.put(3, (byte)(isSpinning ? 1 : 0) ); //CAN_data.put(3, (byte)(rightTriggerPressed ? 1 : 0) ); CAN_data.put(4, (byte)(isShooting ? 1 : 0) ); CAN_data.put(5, (byte)(isExpelling ? 1 : 0) ); CAN_data.put(6, (byte)(leftTriggerPressed ? 1: 0) ); // CAN_data.put(6, (byte)(isIngesting ? 1 : 0) ); CAN_data.put(7, (byte)0); try { CANJNI.FRCNetworkCommunicationCANSessionMuxSendMessage(MSGID_FOR_LIGHTS, CAN_data, CANJNI.CAN_SEND_PERIOD_NO_REPEAT); } catch (Exception e) { // e.printStackTrace(); } } }
/** * Sets the output set-point value. * * The scale and the units depend on the mode the Jaguar is in.<br> * In percentVbus Mode, the outputValue is from -1.0 to 1.0 (same as PWM * Jaguar).<br> * In voltage Mode, the outputValue is in volts. <br> * In current Mode, the outputValue is in amps.<br> * In speed mode, the outputValue is in rotations/minute.<br> * In position Mode, the outputValue is in rotations. * * @param outputValue The set-point to sent to the motor controller. * @param syncGroup The update group to add this set() to, pending * UpdateSyncGroup(). If 0, update immediately. */ @Override public void set(double outputValue, byte syncGroup) { int messageID; byte[] data = new byte[8]; byte dataSize; if (m_safetyHelper != null) m_safetyHelper.feed(); if (m_stopped) { enableControl(); m_stopped = false; } if (m_controlEnabled) { switch (m_controlMode) { case PercentVbus: messageID = CANJNI.LM_API_VOLT_T_SET; dataSize = packPercentage(data, isInverted ? -outputValue : outputValue); break; case Speed: messageID = CANJNI.LM_API_SPD_T_SET; dataSize = packFXP16_16(data, isInverted ? -outputValue : outputValue); break; case Position: messageID = CANJNI.LM_API_POS_T_SET; dataSize = packFXP16_16(data, outputValue); break; case Current: messageID = CANJNI.LM_API_ICTRL_T_SET; dataSize = packFXP8_8(data, outputValue); break; case Voltage: messageID = CANJNI.LM_API_VCOMP_T_SET; dataSize = packFXP8_8(data, isInverted ? -outputValue : outputValue); break; default: return; } if (syncGroup != 0) { data[dataSize++] = syncGroup; } sendMessage(messageID, data, dataSize, kSendMessagePeriod); } m_value = outputValue; verify(); }
static void sendMessageHelper(int messageID, byte[] data, int dataSize, int period) throws CANMessageNotFoundException { final int[] kTrustedMessages = {CANJNI.LM_API_VOLT_T_EN, CANJNI.LM_API_VOLT_T_SET, CANJNI.LM_API_SPD_T_EN, CANJNI.LM_API_SPD_T_SET, CANJNI.LM_API_VCOMP_T_EN, CANJNI.LM_API_VCOMP_T_SET, CANJNI.LM_API_POS_T_EN, CANJNI.LM_API_POS_T_SET, CANJNI.LM_API_ICTRL_T_EN, CANJNI.LM_API_ICTRL_T_SET}; for (byte i = 0; i < kTrustedMessages.length; i++) { if ((kFullMessageIDMask & messageID) == kTrustedMessages[i]) { // Make sure the data will still fit after adjusting for the token. if (dataSize > kMaxMessageDataSize - 2) { throw new RuntimeException("CAN message has too much data."); } ByteBuffer trustedBuffer = ByteBuffer.allocateDirect(dataSize + 2); trustedBuffer.put(0, (byte) 0); trustedBuffer.put(1, (byte) 0); for (byte j = 0; j < dataSize; j++) { trustedBuffer.put(j + 2, data[j]); } CANJNI.FRCNetworkCommunicationCANSessionMuxSendMessage(messageID, trustedBuffer, period); return; } } // Use a null pointer for the data buffer if the given array is null ByteBuffer buffer; if (data != null) { buffer = ByteBuffer.allocateDirect(dataSize); for (byte i = 0; i < dataSize; i++) { buffer.put(i, data[i]); } } else { buffer = null; } CANJNI.FRCNetworkCommunicationCANSessionMuxSendMessage(messageID, buffer, period); }
/** * Set the reference source device for speed controller mode. * * Choose encoder as the source of speed feedback when in speed control mode. * * @param reference Specify a speed reference. */ private void setSpeedReference(int reference) { sendMessage(CANJNI.LM_API_SPD_REF, new byte[] {(byte) reference}, 1); m_speedReference = reference; m_speedRefVerified = false; }
/** * Set the reference source device for position controller mode. * * Choose between using and encoder and using a potentiometer as the source of * position feedback when in position control mode. * * @param reference Specify a position reference. */ private void setPositionReference(int reference) { sendMessage(CANJNI.LM_API_POS_REF, new byte[] {(byte) reference}, 1); m_positionReference = reference; m_posRefVerified = false; }
/** * Enable controlling the motor voltage as a percentage of the bus voltage, * and enable speed sensing from a non-quadrature encoder.<br> * After calling this you must call {@link CANJaguar#enableControl()} or * {@link CANJaguar#enableControl(double)} to enable the device. * * @param tag The constant {@link CANJaguar#kEncoder} * @param codesPerRev The counts per revolution on the encoder */ public void setPercentMode(EncoderTag tag, int codesPerRev) { changeControlMode(JaguarControlMode.PercentVbus); setPositionReference(CANJNI.LM_REF_NONE); setSpeedReference(CANJNI.LM_REF_ENCODER); configEncoderCodesPerRev(codesPerRev); }
/** * Enable controlling the motor voltage as a percentage of the bus voltage, * and enable position and speed sensing from a quadrature encoder.<br> * After calling this you must call {@link CANJaguar#enableControl()} or * {@link CANJaguar#enableControl(double)} to enable the device. * * @param tag The constant {@link CANJaguar#kQuadEncoder} * @param codesPerRev The counts per revolution on the encoder */ public void setPercentMode(QuadEncoderTag tag, int codesPerRev) { changeControlMode(JaguarControlMode.PercentVbus); setPositionReference(CANJNI.LM_REF_ENCODER); setSpeedReference(CANJNI.LM_REF_QUAD_ENCODER); configEncoderCodesPerRev(codesPerRev); }
/** * Enable controlling the motor voltage as a percentage of the bus voltage, * and enable position sensing from a potentiometer and no speed feedback.<br> * After calling this you must call {@link CANJaguar#enableControl()} or * {@link CANJaguar#enableControl(double)} to enable the device. * * @param tag The constant {@link CANJaguar#kPotentiometer} */ public void setPercentMode(PotentiometerTag tag) { changeControlMode(JaguarControlMode.PercentVbus); setPositionReference(CANJNI.LM_REF_POT); setSpeedReference(CANJNI.LM_REF_NONE); configPotentiometerTurns(1); }
/** * Enable controlling the motor current with a PID loop.<br> * After calling this you must call {@link CANJaguar#enableControl()} or * {@link CANJaguar#enableControl(double)} to enable the device. * * @param p The proportional gain of the Jaguar's PID controller. * @param i The integral gain of the Jaguar's PID controller. * @param d The differential gain of the Jaguar's PID controller. */ public void setCurrentMode(double p, double i, double d) { changeControlMode(JaguarControlMode.Current); setPositionReference(CANJNI.LM_REF_NONE); setSpeedReference(CANJNI.LM_REF_NONE); setPID(p, i, d); }
/** * Enable controlling the motor current with a PID loop, and enable speed * sensing from a non-quadrature encoder.<br> * After calling this you must call {@link CANJaguar#enableControl()} or * {@link CANJaguar#enableControl(double)} to enable the device. * * @param tag The constant {@link CANJaguar#kEncoder} * @param p The proportional gain of the Jaguar's PID controller. * @param i The integral gain of the Jaguar's PID controller. * @param d The differential gain of the Jaguar's PID controller. */ public void setCurrentMode(EncoderTag tag, int codesPerRev, double p, double i, double d) { changeControlMode(JaguarControlMode.Current); setPositionReference(CANJNI.LM_REF_NONE); setSpeedReference(CANJNI.LM_REF_NONE); configEncoderCodesPerRev(codesPerRev); setPID(p, i, d); }
/** * Enable controlling the motor current with a PID loop, and enable speed and * position sensing from a quadrature encoder.<br> * After calling this you must call {@link CANJaguar#enableControl()} or * {@link CANJaguar#enableControl(double)} to enable the device. * * @param tag The constant {@link CANJaguar#kQuadEncoder} * @param p The proportional gain of the Jaguar's PID controller. * @param i The integral gain of the Jaguar's PID controller. * @param d The differential gain of the Jaguar's PID controller. */ public void setCurrentMode(QuadEncoderTag tag, int codesPerRev, double p, double i, double d) { changeControlMode(JaguarControlMode.Current); setPositionReference(CANJNI.LM_REF_ENCODER); setSpeedReference(CANJNI.LM_REF_QUAD_ENCODER); configEncoderCodesPerRev(codesPerRev); setPID(p, i, d); }
/** * Enable controlling the motor current with a PID loop, and enable position * sensing from a potentiometer.<br> * After calling this you must call {@link CANJaguar#enableControl()} or * {@link CANJaguar#enableControl(double)} to enable the device. * * @param tag The constant {@link CANJaguar#kPotentiometer} * @param p The proportional gain of the Jaguar's PID controller. * @param i The integral gain of the Jaguar's PID controller. * @param d The differential gain of the Jaguar's PID controller. */ public void setCurrentMode(PotentiometerTag tag, double p, double i, double d) { changeControlMode(JaguarControlMode.Current); setPositionReference(CANJNI.LM_REF_POT); setSpeedReference(CANJNI.LM_REF_NONE); configPotentiometerTurns(1); setPID(p, i, d); }
/** * Enable controlling the speed with a feedback loop from a non-quadrature * encoder.<br> * After calling this you must call {@link CANJaguar#enableControl()} or * {@link CANJaguar#enableControl(double)} to enable the device. * * @param tag The constant {@link CANJaguar#kEncoder} * @param codesPerRev The counts per revolution on the encoder * @param p The proportional gain of the Jaguar's PID controller. * @param i The integral gain of the Jaguar's PID controller. * @param d The differential gain of the Jaguar's PID controller. */ public void setSpeedMode(EncoderTag tag, int codesPerRev, double p, double i, double d) { changeControlMode(JaguarControlMode.Speed); setPositionReference(CANJNI.LM_REF_NONE); setSpeedReference(CANJNI.LM_REF_ENCODER); configEncoderCodesPerRev(codesPerRev); setPID(p, i, d); }
/** * Enable controlling the speed with a feedback loop from a quadrature * encoder.<br> * After calling this you must call {@link CANJaguar#enableControl()} or * {@link CANJaguar#enableControl(double)} to enable the device. * * @param tag The constant {@link CANJaguar#kQuadEncoder} * @param codesPerRev The counts per revolution on the encoder * @param p The proportional gain of the Jaguar's PID controller. * @param i The integral gain of the Jaguar's PID controller. * @param d The differential gain of the Jaguar's PID controller. */ public void setSpeedMode(QuadEncoderTag tag, int codesPerRev, double p, double i, double d) { changeControlMode(JaguarControlMode.Speed); setPositionReference(CANJNI.LM_REF_ENCODER); setSpeedReference(CANJNI.LM_REF_QUAD_ENCODER); configEncoderCodesPerRev(codesPerRev); setPID(p, i, d); }
/** * Enable controlling the position with a feedback loop using an encoder.<br> * After calling this you must call {@link CANJaguar#enableControl()} or * {@link CANJaguar#enableControl(double)} to enable the device. * * @param tag The constant {@link CANJaguar#kQuadEncoder} * @param codesPerRev The counts per revolution on the encoder * @param p The proportional gain of the Jaguar's PID controller. * @param i The integral gain of the Jaguar's PID controller. * @param d The differential gain of the Jaguar's PID controller. * */ public void setPositionMode(QuadEncoderTag tag, int codesPerRev, double p, double i, double d) { changeControlMode(JaguarControlMode.Position); setPositionReference(CANJNI.LM_REF_ENCODER); configEncoderCodesPerRev(codesPerRev); setPID(p, i, d); }
/** * Enable controlling the position with a feedback loop using a potentiometer.<br> * After calling this you must call {@link CANJaguar#enableControl()} or * {@link CANJaguar#enableControl(double)} to enable the device. * * @param tag The constant {@link CANJaguar#kPotentiometer} * @param p The proportional gain of the Jaguar's PID controller. * @param i The integral gain of the Jaguar's PID controller. * @param d The differential gain of the Jaguar's PID controller. */ public void setPositionMode(PotentiometerTag tag, double p, double i, double d) { changeControlMode(JaguarControlMode.Position); setPositionReference(CANJNI.LM_REF_POT); configPotentiometerTurns(1); setPID(p, i, d); }
/** * Enable controlling the motor voltage with speed feedback from a * non-quadrature encoder and no position feedback.<br> * After calling this you must call {@link CANJaguar#enableControl()} or * {@link CANJaguar#enableControl(double)} to enable the device. * * @param tag The constant {@link CANJaguar#kEncoder} * @param codesPerRev The counts per revolution on the encoder */ public void setVoltageMode(EncoderTag tag, int codesPerRev) { changeControlMode(JaguarControlMode.Voltage); setPositionReference(CANJNI.LM_REF_NONE); setSpeedReference(CANJNI.LM_REF_ENCODER); configEncoderCodesPerRev(codesPerRev); }
/** * Enable controlling the motor voltage with position and speed feedback from * a quadrature encoder.<br> * After calling this you must call {@link CANJaguar#enableControl()} or * {@link CANJaguar#enableControl(double)} to enable the device. * * @param tag The constant {@link CANJaguar#kQuadEncoder} * @param codesPerRev The counts per revolution on the encoder */ public void setVoltageMode(QuadEncoderTag tag, int codesPerRev) { changeControlMode(JaguarControlMode.Voltage); setPositionReference(CANJNI.LM_REF_ENCODER); setSpeedReference(CANJNI.LM_REF_QUAD_ENCODER); configEncoderCodesPerRev(codesPerRev); }
/** * Configure what the controller does to the H-Bridge when neutral (not * driving the output). * * This allows you to override the jumper configuration for brake or coast. * * @param mode Select to use the jumper setting or to override it to coast or * brake. */ public void configNeutralMode(NeutralMode mode) { sendMessage(CANJNI.LM_API_CFG_BRAKE_COAST, new byte[] {mode.value}, 1); m_neutralMode = mode; m_neutralModeVerified = false; }
/** * Enable controlling the motor voltage as a percentage of the bus voltage * without any position or speed feedback.<br> * After calling this you must call {@link CANJaguar#enableControl()} or * {@link CANJaguar#enableControl(double)} to enable the device. */ public void setPercentMode() { changeControlMode(JaguarControlMode.PercentVbus); setPositionReference(CANJNI.LM_REF_NONE); setSpeedReference(CANJNI.LM_REF_NONE); }
/** * Enable controlling the motor voltage without any position or speed * feedback.<br> * After calling this you must call {@link CANJaguar#enableControl()} or * {@link CANJaguar#enableControl(double)} to enable the device. */ public void setVoltageMode() { changeControlMode(JaguarControlMode.Voltage); setPositionReference(CANJNI.LM_REF_NONE); setSpeedReference(CANJNI.LM_REF_NONE); }
