예제 #1
0
        // This method will do the main data processing job.
        coredata::dmcp::ModuleExitCodeMessage::ModuleExitCode Overtaker::body() {
            const int32_t ULTRASONIC_FRONT_CENTER = 3;
            const int32_t ULTRASONIC_FRONT_RIGHT = 4;
            const int32_t INFRARED_FRONT_RIGHT = 0;
            const int32_t INFRARED_REAR_RIGHT = 2;

            const double OVERTAKING_DISTANCE = 5.5;
            const double HEADING_PARALLEL = 0.04;

            // Overall state machines for moving and measuring.
            enum StateMachineMoving { FORWARD, TO_LEFT_LANE_LEFT_TURN, TO_LEFT_LANE_RIGHT_TURN, CONTINUE_ON_LEFT_LANE, TO_RIGHT_LANE_RIGHT_TURN, TO_RIGHT_LANE_LEFT_TURN };
            enum StateMachineMeasuring { DISABLE, FIND_OBJECT_INIT, FIND_OBJECT, FIND_OBJECT_PLAUSIBLE, HAVE_BOTH_IR, HAVE_BOTH_IR_SAME_DISTANCE, END_OF_OBJECT };

            StateMachineMoving stageMoving = FORWARD;
            StateMachineMeasuring stageMeasuring = FIND_OBJECT_INIT;

            // State counter for dynamically moving back to right lane.
            int32_t stageToRightLaneRightTurn = 0;
            int32_t stageToRightLaneLeftTurn = 0;

            // Distance variables to ensure we are overtaking only stationary or slowly driving obstacles.
            double distanceToObstacle = 0;
            double distanceToObstacleOld = 0;

            while (getModuleStateAndWaitForRemainingTimeInTimeslice() == coredata::dmcp::ModuleStateMessage::RUNNING) {
	            // 1. Get most recent vehicle data:
	            Container containerVehicleData = getKeyValueDataStore().get(Container::VEHICLEDATA);
	            VehicleData vd = containerVehicleData.getData<VehicleData> ();

	            // 2. Get most recent sensor board data:
	            Container containerSensorBoardData = getKeyValueDataStore().get(Container::USER_DATA_0);
	            SensorBoardData sbd = containerSensorBoardData.getData<SensorBoardData> ();

	            // Create vehicle control data.
	            VehicleControl vc;

                // Moving state machine.
                if (stageMoving == FORWARD) {
                    // Go forward.
                    vc.setSpeed(2);
                    vc.setSteeringWheelAngle(0);

                    stageToRightLaneLeftTurn = 0;
                    stageToRightLaneRightTurn = 0;
                }
                else if (stageMoving == TO_LEFT_LANE_LEFT_TURN) {
                    // Move to the left lane: Turn left part until both IRs see something.
                    vc.setSpeed(1);
                    vc.setSteeringWheelAngle(-25);

                    // State machine measuring: Both IRs need to see something before leaving this moving state.
                    stageMeasuring = HAVE_BOTH_IR;

                    stageToRightLaneRightTurn++;
                }
                else if (stageMoving == TO_LEFT_LANE_RIGHT_TURN) {
                    // Move to the left lane: Turn right part until both IRs have the same distance to obstacle.
                    vc.setSpeed(1);
                    vc.setSteeringWheelAngle(25);

                    // State machine measuring: Both IRs need to have the same distance before leaving this moving state.
                    stageMeasuring = HAVE_BOTH_IR_SAME_DISTANCE;

                    stageToRightLaneLeftTurn++;
                }
                else if (stageMoving == CONTINUE_ON_LEFT_LANE) {
                    // Move to the left lane: Passing stage.
                    vc.setSpeed(2);
                    vc.setSteeringWheelAngle(0);

                    // Find end of object.
                    stageMeasuring = END_OF_OBJECT;
                }
                else if (stageMoving == TO_RIGHT_LANE_RIGHT_TURN) {
                    // Move to the right lane: Turn right part.
                    vc.setSpeed(1.5);
                    vc.setSteeringWheelAngle(25);

                    stageToRightLaneRightTurn--;
                    if (stageToRightLaneRightTurn == 0) {
                        stageMoving = TO_RIGHT_LANE_LEFT_TURN;
                    }
                }
                else if (stageMoving == TO_RIGHT_LANE_LEFT_TURN) {
                    // Move to the left lane: Turn left part.
                    vc.setSpeed(.9);
                    vc.setSteeringWheelAngle(-25);

                    stageToRightLaneLeftTurn--;
                    if (stageToRightLaneLeftTurn == 0) {
                        // Start over.
                        stageMoving = FORWARD;
                        stageMeasuring = FIND_OBJECT_INIT;

                        distanceToObstacle = 0;
                        distanceToObstacleOld = 0;
                    }
                }

                // Measuring state machine.
                if (stageMeasuring == FIND_OBJECT_INIT) {
                    distanceToObstacleOld = sbd.getValueForKey_MapOfDistances(ULTRASONIC_FRONT_CENTER);
                    stageMeasuring = FIND_OBJECT;
                }
                else if (stageMeasuring == FIND_OBJECT) {
                    distanceToObstacle = sbd.getValueForKey_MapOfDistances(ULTRASONIC_FRONT_CENTER);

                    // Approaching an obstacle (stationary or driving slower than us).
                    if ( (distanceToObstacle > 0) && (((distanceToObstacleOld - distanceToObstacle) > 0) || (fabs(distanceToObstacleOld - distanceToObstacle) < 1e-2)) ) {
                        // Check if overtaking shall be started.                        
                        stageMeasuring = FIND_OBJECT_PLAUSIBLE;
                    }

                    distanceToObstacleOld = distanceToObstacle;
                }
                else if (stageMeasuring == FIND_OBJECT_PLAUSIBLE) {
                    if (sbd.getValueForKey_MapOfDistances(ULTRASONIC_FRONT_CENTER) < OVERTAKING_DISTANCE) {
                        stageMoving = TO_LEFT_LANE_LEFT_TURN;

                        // Disable measuring until requested from moving state machine again.
                        stageMeasuring = DISABLE;
                    }
                    else {
                        stageMeasuring = FIND_OBJECT;
                    }
                }
                else if (stageMeasuring == HAVE_BOTH_IR) {
                    // Remain in this stage until both IRs see something.
                    if ( (sbd.getValueForKey_MapOfDistances(INFRARED_FRONT_RIGHT) > 0) && (sbd.getValueForKey_MapOfDistances(INFRARED_REAR_RIGHT) > 0) ) {
                        // Turn to right.
                        stageMoving = TO_LEFT_LANE_RIGHT_TURN;
                    }
                }
                else if (stageMeasuring == HAVE_BOTH_IR_SAME_DISTANCE) {
                    // Remain in this stage until both IRs have the similar distance to obstacle (i.e. turn car)
                    // and the driven parts of the turn are plausible.
                    const double IR_FR = sbd.getValueForKey_MapOfDistances(INFRARED_FRONT_RIGHT);
                    const double IR_RR = sbd.getValueForKey_MapOfDistances(INFRARED_REAR_RIGHT);

                    if ((fabs(IR_FR - IR_RR) < HEADING_PARALLEL) && ((stageToRightLaneLeftTurn - stageToRightLaneRightTurn) > 0)) {
                        // Straight forward again.
                        stageMoving = CONTINUE_ON_LEFT_LANE;
                    }
                }
                else if (stageMeasuring == END_OF_OBJECT) {
                    // Find end of object.
                    distanceToObstacle = sbd.getValueForKey_MapOfDistances(ULTRASONIC_FRONT_RIGHT);

                    if (distanceToObstacle < 0) {
                        // Move to right lane again.
                        stageMoving = TO_RIGHT_LANE_RIGHT_TURN;

                        // Disable measuring until requested from moving state machine again.
                        stageMeasuring = DISABLE;
                    }
                }

	            // Create container for finally sending the data.
	            Container c(Container::VEHICLECONTROL, vc);
	            // Send container.
	            getConference().send(c);
            }

            return coredata::dmcp::ModuleExitCodeMessage::OKAY;
        }
예제 #2
0
        // This method will do the main data processing job.
        coredata::dmcp::ModuleExitCodeMessage::ModuleExitCode BoxParker::body() {
            double distanceOld = 0;
            double absPathStart = 0;
            double absPathEnd = 0;

            int stageMoving = 0;
            int stageMeasuring = 0;

            while (getModuleStateAndWaitForRemainingTimeInTimeslice() == coredata::dmcp::ModuleStateMessage::RUNNING) {
                // 1. Get most recent vehicle data:
                Container containerVehicleData = getKeyValueDataStore().get(Container::VEHICLEDATA);
                VehicleData vd = containerVehicleData.getData<VehicleData> ();

                // 2. Get most recent sensor board data describing virtual sensor data:
                Container containerSensorBoardData = getKeyValueDataStore().get(Container::USER_DATA_0);
                SensorBoardData sbd = containerSensorBoardData.getData<SensorBoardData> ();

                // Create vehicle control data.
                VehicleControl vc;

                // Moving state machine.
                if (stageMoving == 0) {
                    // Go forward.
                    vc.setSpeed(1);
                    vc.setSteeringWheelAngle(0);
                }
                if ((stageMoving > 0) && (stageMoving < 20)) {
                    // Move slightly forward.
                    vc.setSpeed(1);
                    vc.setSteeringWheelAngle(0);
                    stageMoving++;
                }
                if ((stageMoving >= 20) && (stageMoving < 25)) {
                    // Stop.
                    vc.setSpeed(0);
                    vc.setSteeringWheelAngle(0);
                    stageMoving++;
                }
                if ((stageMoving >= 25) && (stageMoving < 80)) {
                    // Backwards, steering wheel to the right.
                    vc.setSpeed(-2);
                    vc.setSteeringWheelAngle(25);
                    stageMoving++;
                }
                if (stageMoving >= 80) {
                    // Stop.
                    vc.setSpeed(0);
                    vc.setSteeringWheelAngle(0);

                    stageMoving++;
                }
                if (stageMoving >= 150) {
                    // End component.
                    break;
                }

                // Measuring state machine.
                switch (stageMeasuring) {
                    case 0:
                        {
                            // Initialize measurement.
                            distanceOld = sbd.getValueForKey_MapOfDistances(2);
                            stageMeasuring++;
                        }
                    break;
                    case 1:
                        {
                            // Checking for distance sequence +, -.
                            if ((distanceOld > 0) && (sbd.getValueForKey_MapOfDistances(2) < 0)) {
                                // Found distance sequence +, -.
                                stageMeasuring = 2;
                                absPathStart = vd.getAbsTraveledPath();
                            }
                            distanceOld = sbd.getValueForKey_MapOfDistances(2);
                        }
                    break;
                    case 2:
                        {
                            // Checking for distance sequence -, +.
                            if ((distanceOld < 0) && (sbd.getValueForKey_MapOfDistances(2) > 0)) {
                                // Found distance sequence -, +.
                                stageMeasuring = 1;
                                absPathEnd = vd.getAbsTraveledPath();

                                const double GAP_SIZE = (absPathEnd - absPathStart);
                                cerr << "Size = " << GAP_SIZE << endl;
                                m_foundGaps.push_back(GAP_SIZE);

                                if ((stageMoving < 1) && (GAP_SIZE > 3.5)) {
                                    stageMoving = 1;
                                }
                            }
                            distanceOld = sbd.getValueForKey_MapOfDistances(2);
                        }
                    break;
                }

                // Create container for finally sending the data.
                Container c(Container::VEHICLECONTROL, vc);
                // Send container.
                getConference().send(c);
            }

            return coredata::dmcp::ModuleExitCodeMessage::OKAY;
        }
예제 #3
0
        // This method will do the main data processing job.
        ModuleState::MODULE_EXITCODE Driver::body() {
                std::ofstream myFile("sensors.bin", ios::binary);
	        while (getModuleState() == ModuleState::RUNNING) {
                // In the following, you find example for the various data sources that are available:

		        // 1. Get most recent vehicle data:
		        Container containerVehicleData = getKeyValueDataStore().get(Container::VEHICLEDATA);
		        VehicleData vd = containerVehicleData.getData<VehicleData> ();
		 //       cerr << "Most recent vehicle data: '" << vd.toString() << "'" << endl;

		        // 2. Get most recent sensor board data:
		        Container containerSensorBoardData = getKeyValueDataStore().get(Container::USER_DATA_0);
		        SensorBoardData sbd = containerSensorBoardData.getData<SensorBoardData> ();
			
		      timeval time;
		      string test;
		      stringstream teststream;		      
		      
		      double val = sbd.getDistance(0);
		      myFile.write((char*)&val, sizeof(val));
		      
		      val = sbd.getDistance(1);
		      myFile.write((char*)&val, sizeof(val));
		      
		      val = sbd.getDistance(2);
		      myFile.write((char*)&val, sizeof(val));
		      
		      val = sbd.getDistance(3);
		      myFile.write((char*)&val, sizeof(val));
		      
		      val = sbd.getDistance(4);
		      myFile.write((char*)&val, sizeof(val));

		      gettimeofday(&time, NULL);
		      unsigned long millis = (time.tv_usec / 1000);
		      
		      teststream << millis;
		      if (millis < 10){
			test = remove_letter(currentDateTime(), ':') + "00" + teststream.str();
		      }
		      else if (millis < 100 and millis >= 10) {
			test = remove_letter(currentDateTime(), ':') + "0" + teststream.str();
			
		      }
		      else {
			test = remove_letter(currentDateTime(), ':') + teststream.str();
			
		      }
		      
		      
		      cerr << test << endl;
		      int timestamp;
		      timestamp = atoi(test.c_str());

		      myFile.write((char*)&timestamp, sizeof(timestamp));
			

		        // 3. Get most recent user button data:
		        Container containerUserButtonData = getKeyValueDataStore().get(Container::USER_BUTTON);
		        UserButtonData ubd = containerUserButtonData.getData<UserButtonData> ();
		  //      cerr << "Most recent user button data: '" << ubd.toString() << "'" << endl;

		        // 4. Get most recent steering data as fill from lanedetector for example:
		        Container containerSteeringData = getKeyValueDataStore().get(Container::USER_DATA_1);
		        SteeringData sd = containerSteeringData.getData<SteeringData> ();
		 //       cerr << "Most recent steering data: '" << sd.toString() << "'" << endl;



                // Design your control algorithm here depending on the input data from above.



		        // Create vehicle control data.
		        VehicleControl vc;

                // With setSpeed you can set a desired speed for the vehicle in the range of -2.0 (backwards) .. 0 (stop) .. +2.0 (forwards)
		        vc.setSpeed(1.5);

                // With setSteeringWheelAngle, you can steer in the range of -26 (left) .. 0 (straight) .. +25 (right)
                double desiredSteeringWheelAngle = 0; // 4 degree but SteeringWheelAngle expects the angle in radians!
		        vc.setSteeringWheelAngle(desiredSteeringWheelAngle * Constants::DEG2RAD);

                // You can also turn on or off various lights:
                vc.setBrakeLights(false);
                vc.setLeftFlashingLights(false);
                vc.setRightFlashingLights(true);

		        // Create container for finally sending the data.
		        Container c(Container::VEHICLECONTROL, vc);
		        // Send container.
		        getConference().send(c);
	        }
            myFile.close();
	        return ModuleState::OKAY;
        }