/devices/DiWheelDrive/userthread.cpp - AMiRo-OS - Research for Cognitive Interaction

amiro-os / devices / DiWheelDrive / userthread.cpp @ e404e6c0

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       #include "global.hpp"
       #include <cmath>
       #include "linefollow.hpp"
       #include "userthread.hpp"
       #include "amiro_map.hpp"
       using namespace amiro;
       extern Global global;
       // a buffer for the z-value of the accelerometer
       int16_t accel_z;
       bool running = false;
       /**
        * Set speed.
+       *
        * @param rpmSpeed speed for left and right wheel in rounds/min
        */
       void UserThread::setRpmSpeedFuzzy(const int (&rpmSpeed)[2]) {
         global.motorcontrol.setTargetRPM(rpmSpeed[constants::DiWheelDrive::LEFT_WHEEL] * 1000000, rpmSpeed[constants::DiWheelDrive::RIGHT_WHEEL] * 1000000);
+      }
       void UserThread::setRpmSpeed(const int (&rpmSpeed)[2]) {
         global.motorcontrol.setTargetRPM(rpmSpeed[constants::DiWheelDrive::LEFT_WHEEL], rpmSpeed[constants::DiWheelDrive::RIGHT_WHEEL]);
+      }
       void UserThread::lightOneLed(Color color, int idx){
         global.robot.setLightColor(idx, Color(color));
+      }
       void UserThread::lightAllLeds(Color color){
         int led = 0;
         for(led=0; led<8; led++){
               lightOneLed(color, led);
+            }
+      }
       void UserThread::showChargingState(){
         uint8_t numLeds = global.robot.getPowerStatus().state_of_charge / 12;
         Color color = Color::GREEN;
         if (numLeds <= 2){
           color = Color::RED;
         }else if(numLeds <= 6){
           color = Color::YELLOW;
+        }
         for (int i=0; i<numLeds; i++){
           lightOneLed(color, i);
           this->sleep(300);
+        }
         this->sleep(1000);
         lightAllLeds(Color::BLACK);
+      }
       void UserThread::chargeAsLED(){
         uint8_t numLeds = global.robot.getPowerStatus().state_of_charge / 12;
         Color color = Color::GREEN;
         if (numLeds <= 2){
           color = Color::RED;
         }else if(numLeds <= 6){
           color = Color::YELLOW;
+        }
         for (int i=0; i<numLeds; i++){
           lightOneLed(color, i);
           // this->sleep(300);
+        }
         // this->sleep(1000);
         // lightAllLeds(Color::BLACK);
+      }
       // ----------------------------------------------------------------
       void UserThread::getProxySectorVals(uint16_t (&proxVals)[8], uint16_t (&sProx)[8]){
         for (int i=0; i<8; i++){
           sProx[i] = (proxVals[i] < proxVals[(i+1) % 8]) ? proxVals[i] : proxVals[(i+1) % 8];
           // chprintf((BaseSequentialStream*)&global.sercanmux1, "%d: %d, ", i, sProx[i]);
+        }
           // chprintf((BaseSequentialStream*)&global.sercanmux1, "\n");
+      }
       void UserThread::getMaxFrontSectorVal(uint16_t (&sProx)[8], int32_t &sPMax){
         for (int i=2; i<5; i++){
           sPMax = (sPMax < sProx[i]) ? sProx[i] : sPMax;
+        }
+      }
       void UserThread::proxSectorSpeedCorrection(int (&rpmSpeed)[2], uint16_t (&proxVals)[8]){
         int i;
         uint16_t sProx[8];
         int32_t sPMax = 0;
         getProxySectorVals(proxVals, sProx);
         getMaxFrontSectorVal(sProx, sPMax);
         int32_t speedL = rpmSpeed[0] - (sPMax * pCtrl.pFactor);
         int32_t speedR = rpmSpeed[1] - (sPMax * pCtrl.pFactor);
         if(sPMax > pCtrl.threshMid){
             rpmSpeed[0] = 0;
             rpmSpeed[1] = 0;
             pCtrl.staticCont++;
         }else if((speedL > 0) || (speedR > 0)){
           pCtrl.staticCont = 0;
           rpmSpeed[0] = speedL;
           rpmSpeed[1] = speedR;
         }else{
           rpmSpeed[0] = 4000000 + (rpmSpeed[0] - global.rpmForward[0] * 1000000);
           rpmSpeed[1] = 4000000 + (rpmSpeed[1] - global.rpmForward[0] * 1000000);
+        }
         for(i=4; i<5; i++){
           if ((proxVals[i] > pCtrl.threshMid) && (proxVals[i+1] > pCtrl.threshLow)){
             rpmSpeed[0] = -5000000 ;
             rpmSpeed[1] = -5000000 ;
             // pCtrl.staticCont++;
             break;
+          }
+        }
         chargeAsLED();
         // chprintf((BaseSequentialStream*)&global.sercanmux1, "Max: %d factor: %d, Panel: %d SpeedL: %d SpeedR: %d ActualL: %d ActualR: %d\n",sPMax,  pCtrl.pFactor,  sPMax * pCtrl.pFactor, speedL, speedR, rpmSpeed[0], rpmSpeed[1]);
+      }
       // -------------------------------------------------------------------
       void UserThread::preventCollision( int (&rpmSpeed)[2], uint16_t (&proxVals)[8]) {
         if((proxVals[3] > pCtrl.threshLow) || (proxVals[4] > pCtrl.threshLow)){
             rpmSpeed[0] = rpmSpeed[0] / 2;
             rpmSpeed[1] = rpmSpeed[1] / 2;
+        }
         if((proxVals[3] > pCtrl.threshMid) || (proxVals[4] > pCtrl.threshMid)){
             rpmSpeed[0] = rpmSpeed[0] / 3;
             rpmSpeed[1] = rpmSpeed[1] / 3;
+        }
         if((proxVals[3] > pCtrl.threshHigh) || (proxVals[4] > pCtrl.threshHigh)){
             rpmSpeed[0] = 0;
             rpmSpeed[1] = 0;
             utCount.ringProxCount++;
         }else{
           utCount.ringProxCount = 0;
+        }
+      }
       /**
        * Blocks as long as the position changes.
        */
       void UserThread::checkForMotion(){
         bool motion = true;
         int led = 0;
         types::position oldPos = global.odometry.getPosition();
         while(motion){
           this->sleep(200);
           types::position tmp = global.odometry.getPosition();
           motion = oldPos.x != tmp.x; //abs(oldPos.x - tmp.x)+ abs(oldPos.y - tmp.y)+abs(oldPos.z - tmp.z);
           oldPos = tmp;
           global.robot.setLightColor((led + 1) % 8, Color(Color::YELLOW));
           global.robot.setLightColor(led % 8, Color(Color::BLACK));
           led++;
+        }
         lightAllLeds(Color::BLACK);
+      }
       bool UserThread::checkFrontalObject(){
         uint32_t thresh = pCtrl.threshMid;
         uint32_t prox;
         for(int i=0; i<8; i++){
           prox = global.robot.getProximityRingValue(i);
           if((i == 3) || (i == 4)){
             if(prox < thresh){
               return false;
+            }
           }else{
             if(prox > thresh){
               return false;
+            }
+          }
+        }
         return true;
+      }
       bool UserThread::checkPinVoltage(){
         return global.ltc4412.isPluggedIn();
+      }
       bool UserThread::checkPinEnabled(){
         return global.ltc4412.isEnabled();
+      }
       int UserThread::checkDockingSuccess(){
         // setRpmSpeed(stop);
         checkForMotion();
         int success = 0;
         // global.odometry.resetPosition();
         types::position start = global.startPos = global.odometry.getPosition();
         global.motorcontrol.setMotorEnable(false);
         this->sleep(1000);
         types::position stop_ = global.endPos = global.odometry.getPosition();
         // Amiro moved, docking was not successful
         // if ((start.x + stop_.x)  || (start.y + stop_.y)){
         if (abs(start.x - stop_.x) > 200 /* || (start.y + stop_.y) */){
           lightAllLeds(Color::RED);
           // Enable Motor again if docking was not successful
           global.motorcontrol.setMotorEnable(true);
           success = 0;
         }else{
           lightAllLeds(Color::GREEN);
           success = 1;
+        }
         // this->sleep(500);
         lightAllLeds(Color::BLACK);
         return success;
+      }
       int UserThread::getProxyRingSum(){
         int prox_sum = 0;
         for(int i=0; i<8;i++){
           prox_sum += global.robot.getProximityRingValue(i);;
+        }
         return prox_sum;
+      }
       int32_t UserThread::meanDeviation(uint16_t a, uint16_t b){
         int32_t diff = a - b;
         int32_t res = 0;
         devCor.proxbuf[devCor.pCount] = (diff*100)/((a+b)/2);
         for (int i = 0; i< PROX_DEVIATION_MEAN_WINDOW; i++){
           res += devCor.proxbuf[i];
+        }
         devCor.pCount++;
         devCor.pCount = devCor.pCount % PROX_DEVIATION_MEAN_WINDOW;
         devCor.currentDeviation =  res / PROX_DEVIATION_MEAN_WINDOW;
         return devCor.currentDeviation;
+      }
       void setAttributes(uint8_t (&map)[MAX_NODES][NODE_ATTRIBUTES],
                                 uint8_t id, uint8_t l, uint8_t r, uint8_t att) {
         map[id][0] = l;
         map[id][1] = r;
         map[id][2] = att;
+      }
       UserThread::UserThread() :
         chibios_rt::BaseStaticThread<USER_THREAD_STACK_SIZE>()
+      {
+      }
       UserThread::~UserThread()
+      {
+      }
       msg_t
       UserThread::main()
+      {
         /*
          * SETUP
          */
         // User thread state:
         for (uint8_t led = 0; led < 8; ++led) {
           global.robot.setLightColor(led, Color(Color::BLACK));
+        }
         running = false;
         LineFollowStrategy lStrategy = LineFollowStrategy::EDGE_RIGHT;
         LineFollow lf(&global);
         AmiroMap map(&global);
         /*
          * LOOP
          */
         while (!this->shouldTerminate())
+        {
           /*
           * read accelerometer z-value
           */
           accel_z = global.lis331dlh.getAccelerationForce(LIS331DLH::AXIS_Z);
           if (accel_z < -900 /*-0.9g*/) {
             // Start line following when AMiRo is rotated
             if(currentState == states::INACTIVE){
               newState = states::FOLLOW_LINE;
             }else{
               newState = states::IDLE;
+            }
             lightAllLeds(Color::GREEN);
             this->sleep(1000);
             lightAllLeds(Color::BLACK);
           // If message was received handle it here:
           } else if(global.msgReceived){
             global.msgReceived = false;
             // running = true;
             switch(global.lfStrategy){
             case msg_content::MSG_START:
               newState = states::CALIBRATION_CHECK;
               break;
             case msg_content::MSG_STOP:
               newState = states::IDLE;
               break;
             case msg_content::MSG_EDGE_RIGHT:
               // newState = states::FOLLOW_LINE;
               lStrategy = LineFollowStrategy::EDGE_RIGHT;
               break;
             case  msg_content::MSG_EDGE_LEFT:
               // newState = states::FOLLOW_LINE;
               lStrategy = LineFollowStrategy::EDGE_LEFT;
               break;
             case msg_content::MSG_FUZZY:
               // newState = states::FOLLOW_LINE;
               lStrategy = LineFollowStrategy::FUZZY;
               break;
             case msg_content::MSG_DOCK:
               newState = states::DETECT_STATION;
               break;
             case msg_content::MSG_UNDOCK:
               newState = states::RELEASE;
               break;
             case msg_content::MSG_CHARGE:
               newState = states::CHARGING;
               break;
             case msg_content::MSG_RESET_ODOMETRY:
               global.odometry.resetPosition();
               break;
             case msg_content::MSG_CALIBRATE_BLACK:
               proxCalib.calibrateBlack = true;
               // global.odometry.resetPosition();
               newState = states::CALIBRATION;
               break;
             case msg_content::MSG_CALIBRATE_WHITE:
               proxCalib.calibrateBlack = false;
               newState = states::CALIBRATION;
               break;
             case msg_content::MSG_TEST_MAP_STATE:
               newState = states::TEST_MAP_STATE;
               break;
             default:
               newState = states::IDLE;
               break;
+            }
+          }
           // newState = currentState;
           // Get sensor data
           // uint16_t WL = global.vcnl4020[constants::DiWheelDrive::PROX_WHEEL_LEFT].getProximityScaledWoOffset();
           // uint16_t WR = global.vcnl4020[constants::DiWheelDrive::PROX_WHEEL_RIGHT].getProximityScaledWoOffset();
           for(int i=0; i<8;i++){
             rProx[i] = global.robot.getProximityRingValue(i);
+          }
           // Continously update devication values
           meanDeviation(rProx[0] & 0xFFF0, rProx[7] & 0xFFF0);
           // int FL = global.vcnl4020[constants::DiWheelDrive::PROX_FRONT_LEFT].getProximityScaledWoOffset();
           // int FR = global.vcnl4020[constants::DiWheelDrive::PROX_FRONT_RIGHT].getProximityScaledWoOffset();
           switch(currentState){
             case states::INACTIVE:
               // Dummy state to deactivate every interaction
             break;
             // ---------------------------------------
             case states::CALIBRATION_CHECK:
               // global.robot.calibrate();
               if(global.linePID.BThresh >= global.linePID.WThresh){
                 newState = states::CALIBRATION_ERROR;
               }else{
                 newState = states::FOLLOW_LINE;
+              }
             break;
             // ---------------------------------------
             case states::CALIBRATION:
               /* Calibrate the global thresholds for black or white.
                   This values will be used by the line follow object
               */
               proxCalib.buf = 0;
               if(proxCalib.calibrateBlack){
                 chprintf((BaseSequentialStream*)&global.sercanmux1, "Black Calibration, Place AMiRo on black Surface!\n");
                 global.robot.calibrate();
+              }
               for(int i=0; i <= proxCalib.meanWindow; i++){
                 proxCalib.buf += global.vcnl4020[constants::DiWheelDrive::PROX_FRONT_LEFT].getProximityScaledWoOffset()
                                 + global.vcnl4020[constants::DiWheelDrive::PROX_FRONT_RIGHT].getProximityScaledWoOffset();
                 this->sleep(CAN::UPDATE_PERIOD);
+              }
               proxCalib.buf = proxCalib.buf / (2*proxCalib.meanWindow);
               if(proxCalib.calibrateBlack){
                 global.linePID.BThresh = proxCalib.buf;
               }else  {
                 global.linePID.WThresh  = proxCalib.buf;
+              }
                 chprintf((BaseSequentialStream*)&global.sercanmux1, "Black: %d, White: %d!\n", global.linePID.BThresh, global.linePID.WThresh);
               newState = states::IDLE;
             break;
             // ---------------------------------------
             case states::IDLE:
               global.motorcontrol.setMotorEnable(true);
               setRpmSpeed(stop);
               if(/* checkPinVoltage() && */ checkPinEnabled()){
                 global.robot.requestCharging(0);
+              }
               // pCtrl.pFactor = 0;
               pCtrl.staticCont = 0;
               utCount.whiteCount = 0;
               utCount.ringProxCount = 0;
               utCount.errorCount = 0;
               newState = states::INACTIVE;
             break;
             // ---------------------------------------
             case states::FOLLOW_LINE:
             // Set correct forward speed to every strategy
               if (global.forwardSpeed != global.rpmForward[0]){
                 global.forwardSpeed = global.rpmForward[0];
+              }
               if(lf.getStrategy() != lStrategy){
                 lf.setStrategy(lStrategy);
+              }
               if(lf.followLine(rpmSpeed)){
                 utCount.whiteCount++;
                 if(utCount.whiteCount >= WHITE_DETETION_TIMEOUT){
                   setRpmSpeed(stop);
                   utCount.whiteCount = 0;
                   newState = states::WHITE_DETECTION_ERROR;
+                }
               }else{
                 utCount.whiteCount = 0;
+              }
               preventCollision(rpmSpeed, rProx);
               // proxSectorSpeedCorrection(rpmSpeed, rProx);
               if(utCount.ringProxCount > RING_PROX_DETECTION_TIMEOUT){
                 utCount.ringProxCount = 0;
                 checkForMotion();
                 // Check if only front sensors are active
                 if (checkFrontalObject()) {
                   // global.distcontrol.setTargetPosition(0, 2792526, ROTATION_DURATION);
                   // // BaseThread::sleep(8000);
                   // checkForMotion();
                   this->utCount.whiteCount = 0;
                   newState = states::TURN;
                   // lf.promptStrategyChange(LineFollowStrategy::EDGE_LEFT);
                 } else {
                   newState = states::PROXY_DETECTION_ERROR;
+                }
+              }
               if (lf.getStrategy() == LineFollowStrategy::FUZZY){
                 setRpmSpeedFuzzy(rpmSpeed);
               }else{
                 setRpmSpeed(rpmSpeed);
+              }
             break;
             // ---------------------------------------
           case states::TURN:{
               // Check the line strategy in order to continue driving on the right side
             int factor = SPEED_CONVERSION_FACTOR;
             int frontL = global.vcnl4020[constants::DiWheelDrive::PROX_FRONT_LEFT].getProximityScaledWoOffset();
             int frontR = global.vcnl4020[constants::DiWheelDrive::PROX_FRONT_RIGHT].getProximityScaledWoOffset();
             int blackSensor = 0;
             if (lf.getStrategy() == LineFollowStrategy::EDGE_RIGHT) {
               factor = -factor;
               blackSensor = frontL;
             }else{
               blackSensor = frontR;
+            }
             rpmSpeed[0] = factor * CHARGING_SPEED;
             rpmSpeed[1] = -factor * CHARGING_SPEED;
             setRpmSpeed(rpmSpeed);
             if ((blackSensor >= global.linePID.WThresh )){
               utCount.whiteCount = 1;
             }else {
               if((utCount.whiteCount == 1) && (blackSensor <= global.linePID.BThresh)){
                 utCount.whiteCount = 0;
                 newState = states::FOLLOW_LINE;
                 setRpmSpeed(stop);
+              }
+            }
             break;
+          }
             // ---------------------------------------
           case states::DETECT_STATION:
               if (global.forwardSpeed != DETECTION_SPEED){
                 global.forwardSpeed = DETECTION_SPEED;
+              }
               if(lf.getStrategy() != LineFollowStrategy::EDGE_RIGHT){
                 lf.setStrategy(LineFollowStrategy::EDGE_RIGHT);
+              }
               lf.followLine(rpmSpeed);
               setRpmSpeed(rpmSpeed);
               // // Detect marker before docking station
               // if ((WL+WR) < PROXY_WHEEL_THRESH){
               // Use proxy ring
               if ((rProx[3]+rProx[4]) > RING_PROX_FRONT_THRESH){
                 setRpmSpeed(stop);
                 checkForMotion();
                 // 180° Rotation
                 global.distcontrol.setTargetPosition(0, ROTATION_180, ROTATION_DURATION);
                 // BaseThread::sleep(8000);
                 checkForMotion();
                 newState = states::CORRECT_POSITIONING;
+              }
             break;
             // ---------------------------------------
           case states::CORRECT_POSITIONING:
               if (global.forwardSpeed != CHARGING_SPEED){
                 global.forwardSpeed = CHARGING_SPEED;
+              }
               if(lf.getStrategy() != LineFollowStrategy::EDGE_LEFT){
                 lf.promptStrategyChange(LineFollowStrategy::EDGE_LEFT);
+              }
               lf.followLine(rpmSpeed);
               setRpmSpeed(rpmSpeed);
               utCount.stateTime++;
               if (utCount.stateTime >= DOCKING_CORRECTION_TIMEOUT){
                 utCount.stateTime = 0;
                 newState = states::REVERSE;
                 setRpmSpeed(stop);
                 checkForMotion();
+              }
             break;
             // ---------------------------------------
           case states::REVERSE:
               if(lf.getStrategy() != LineFollowStrategy::REVERSE){
                 lf.setStrategy(LineFollowStrategy::REVERSE);
+              }
               lf.followLine(rpmSpeed);
               setRpmSpeed(rpmSpeed);
               // utCount.stateTime++;
               // Docking is only successful if Deviation is in range and sensors are at their max values.
               if((rProx[0] >= PROX_MAX_VAL)
                  && (rProx[7] >= PROX_MAX_VAL)
                  && ((devCor.currentDeviation > -MAX_DEVIATION_FACTOR) && (devCor.currentDeviation < MAX_DEVIATION_FACTOR) )){
                 // setRpmSpeed(stop);
                 // checkForMotion();
                 utCount.stateTime = 0;
                 newState = states::PUSH_BACK;
               }else if ((devCor.currentDeviation <= -MAX_DEVIATION_FACTOR) && ((rProx[0] > DEVIATION_DIST_THRESH) || (rProx[7] > DEVIATION_DIST_THRESH))){
                 // Case R
                 utCount.stateTime = 0;
                 setRpmSpeed(stop);
                 devCor.RCase = true;
                 lightAllLeds(Color::YELLOW);
                 newState = states::DEVIATION_CORRECTION;
               }else if ((devCor.currentDeviation >= MAX_DEVIATION_FACTOR) && ((rProx[0] > DEVIATION_DIST_THRESH) || (rProx[7] > DEVIATION_DIST_THRESH))){
                 // Case L
                 utCount.stateTime = 0;
                 setRpmSpeed(stop);
                 devCor.RCase = false;
                 lightAllLeds(Color::WHITE);
                 newState = states::DEVIATION_CORRECTION;
               }else if (utCount.stateTime >= REVERSE_DOCKING_TIMEOUT){
                 setRpmSpeed(stop);
                 utCount.stateTime = 0;
                 utCount.errorCount++;
                 if (utCount.errorCount >= DOCKING_ERROR_THRESH){
                   newState = states::DOCKING_ERROR;
                 }else{
                   newState = states::CORRECT_POSITIONING;
+                }
+              }
               // if((devCor.currentDeviation <= -10)){
               //   rpmSpeed[0] -= 2000000;
               // }else if(devCor.currentDeviation >= 10){
               //   rpmSpeed[1] -= 2000000;
               // }
               // setRpmSpeed(rpmSpeed);
             break;
             // ---------------------------------------
           case states::DEVIATION_CORRECTION:
               // if(lf.getStrategy() != LineFollowStrategy::REVERSE){
               //   lf.setStrategy(LineFollowStrategy::REVERSE);
               // }
               // lf.followLine(rpmSpeed);
               // setRpmSpeed(rpmSpeed);
               if(utCount.stateTime < DEVIATION_CORRECTION_DURATION / 2 ){
                 if(devCor.RCase){
                   rpmSpeed[0] = 0;
                   rpmSpeed[1] = DEVIATION_CORRECTION_SPEED;
                 }else {
                   rpmSpeed[0] = DEVIATION_CORRECTION_SPEED;
                   rpmSpeed[1] = 0;
+                }
                 setRpmSpeed(rpmSpeed);
               }else if (((utCount.stateTime >= DEVIATION_CORRECTION_DURATION / 2) && (utCount.stateTime < DEVIATION_CORRECTION_DURATION +10)) ){
                 if(devCor.RCase){
                   rpmSpeed[0] = DEVIATION_CORRECTION_SPEED;
                   rpmSpeed[1] = 0;
                 }else {
                   rpmSpeed[0] = 0;
                   rpmSpeed[1] = DEVIATION_CORRECTION_SPEED;
+                }
                 setRpmSpeed(rpmSpeed);
                 if(((devCor.currentDeviation >= -5) && (devCor.currentDeviation <= 5))){
                   utCount.stateTime = 0;
                   newState = states::REVERSE;
                   setRpmSpeed(stop);
+                }
               }else{
                 utCount.stateTime = 0;
                 newState = states::REVERSE;
                 setRpmSpeed(stop);
+              }
               utCount.stateTime++;
               // if (utCount.stateTime > PUSH_BACK_TIMEOUT){
               //   utCount.stateTime = 0;
               //   newState = states::CHECK_POSITIONING;
               // }
             break;
             // ---------------------------------------
           case states::PUSH_BACK:
               if(lf.getStrategy() != LineFollowStrategy::REVERSE){
                 lf.setStrategy(LineFollowStrategy::REVERSE);
+              }
               lf.followLine(rpmSpeed);
               setRpmSpeed(rpmSpeed);
               utCount.stateTime++;
               if (utCount.stateTime > PUSH_BACK_TIMEOUT){
                 utCount.stateTime = 0;
                 newState = states::CHECK_POSITIONING;
+              }
             break;
             // ---------------------------------------
           case states::CHECK_POSITIONING:
               setRpmSpeed(stop);
               checkForMotion();
               if(checkDockingSuccess()){
                 newState = states::CHECK_VOLTAGE;
               }else{
                 utCount.errorCount++;
                 newState = states::CORRECT_POSITIONING;
                 if (utCount.errorCount >= DOCKING_ERROR_THRESH){
                     newState = states::DOCKING_ERROR;
+                  }
+              }
             break;
             // ---------------------------------------
           case states::CHECK_VOLTAGE:
               if(!checkPinEnabled()){
                 global.robot.requestCharging(1);
               } else {
                 if(checkPinVoltage()){
                   // Pins are under voltage -> correctly docked
                   newState = states::CHARGING;
                 }else{
                   utCount.errorCount++;
                   // No voltage on pins -> falsely docked
                   // deactivate pins
                   global.motorcontrol.setMotorEnable(true);
                   global.robot.requestCharging(0);
                   // TODO: Soft release when docking falsely
                   if((rProx[0] >= PROX_MAX_VAL) && (rProx[7] >= PROX_MAX_VAL)){
                     newState = states::RELEASE_TO_CORRECT;
                   } else {
                     newState = states::RELEASE_TO_CORRECT; //states::CORRECT_POSITIONING;
+                  }
                   if (utCount.errorCount > DOCKING_ERROR_THRESH){
                     newState = states::DOCKING_ERROR;
+                  }
+                }
+              }
             break;
             // ---------------------------------------
           case states::RELEASE_TO_CORRECT:
               global.distcontrol.setTargetPosition(0, ROTATION_20, ROTATION_DURATION);
               checkForMotion();
               // move 1cm forward
               global.distcontrol.setTargetPosition(5000, 0, ROTATION_DURATION);
               checkForMotion();
               // rotate back
               global.distcontrol.setTargetPosition(0, -2*ROTATION_20, ROTATION_DURATION);
               checkForMotion();
               global.distcontrol.setTargetPosition(1500, 0, ROTATION_DURATION);
               checkForMotion();
               newState = states::CORRECT_POSITIONING;
             break;
             // ---------------------------------------
           case states::CHARGING:
               global.motorcontrol.setMotorEnable(false);
               utCount.errorCount = 0;
               // Formulate Request to enable charging
               if(/* checkPinVoltage() && */ !checkPinEnabled()){
                 global.robot.requestCharging(1);
+              }
               if(checkPinEnabled()){
                 showChargingState();
+              }
             break;
             // ---------------------------------------
           case states::RELEASE:
             if (global.forwardSpeed != DETECTION_SPEED){
                 global.rpmForward[0] = DETECTION_SPEED;
+              }
               if(/* checkPinVoltage() && */ checkPinEnabled()){
                 global.robot.requestCharging(0);
               }else{
                 global.motorcontrol.setMotorEnable(true);
                 // TODO: Use controlled
                 //Rotate -20° to free from magnet
                 global.distcontrol.setTargetPosition(0, ROTATION_20, ROTATION_DURATION);
                 checkForMotion();
                 // move 1cm forward
                 global.distcontrol.setTargetPosition(5000, 0, ROTATION_DURATION);
                 checkForMotion();
                 // rotate back
                 // global.distcontrol.setTargetPosition(0, -ROTATION_20, ROTATION_DURATION);
                 // checkForMotion();
                 // global.distcontrol.setTargetPosition(5000, 0, ROTATION_DURATION);
                 // checkForMotion();
                 lStrategy = LineFollowStrategy::EDGE_RIGHT;
                 newState = states::FOLLOW_LINE;
                   // whiteBuf = -100;
                 // lf.followLine(rpmSpeed);
                 // setRpmSpeed(rpmSpeed);
+              }
               // lightAllLeds(Color::BLACK);
             break;
             // ---------------------------------------
           case states::DOCKING_ERROR:
             newState = states::RELEASE;
             break;
             // ---------------------------------------
           case states::REVERSE_TIMEOUT_ERROR:
             newState = states::IDLE;
             break;
             // ---------------------------------------
           case states::CALIBRATION_ERROR:
             newState = states::IDLE;
             break;
             // ---------------------------------------
           case states::WHITE_DETECTION_ERROR:
             newState = states::IDLE;
             break;
             // ---------------------------------------
           case states::PROXY_DETECTION_ERROR:
             newState = states::IDLE;
             break;
             // ---------------------------------------
           case states::NO_CHARGING_POWER_ERROR:
             newState = states::IDLE;
             break;
             // ---------------------------------------
           case states::UNKNOWN_STATE_ERROR:
               newState = states::IDLE;
             break;
             // ---------------------------------------
           case states::TEST_MAP_STATE:{
             /* Test suit for amiro map */
             setAttributes(global.testmap, 0, 1, 2, 1);
             setAttributes(global.testmap, 1, 2, 2, 0);
             setAttributes(global.testmap, 2, 1, 0, 0);
             setAttributes(global.testmap, 3, 0, 0, 0xff);
             // AmiroMap map = AmiroMap(&global);
           //   // --------------------------------------------------
             global.tcase = 0;
             map.initialize();
             global.testres[global.tcase] = map.get_state()->valid;
               global.tcase++; // 1
             setAttributes(global.testmap, 0, 1, 2, 0xff);
             map.initialize();
             global.testres[global.tcase] = !map.get_state()->valid;
             global.tcase++; // 2
             setAttributes(global.testmap, 0, 1, 2, 0);
             setAttributes(global.testmap, 2, 1, 0, 1);
             map.initialize();
             global.testres[global.tcase] = map.get_state()->current == 2;
             global.tcase++; // 3
             setAttributes(global.testmap, 3, 0, 0, 0);
             setAttributes(global.testmap, 4, 0, 0, 0xff);
             map.initialize();
             global.testres[global.tcase] = !map.get_state()->valid;
             int failed = 0;
             int passed = 0;
             for (int i = 0; i <= global.tcase; i++) {
               if (global.testres[i]) {
                 passed++;
                 chprintf((BaseSequentialStream *)&global.sercanmux1,
                          "Test %d Passed!\n", i);
               } else {
                 failed++;
                 chprintf((BaseSequentialStream *)&global.sercanmux1,
                          "Test %d Failed\n", i);
+              }
+            }
             chprintf((BaseSequentialStream *)&global.sercanmux1,
                      "Total: %d, Passed: %d, Failed: %d\n", global.tcase + 1, passed,
                      failed);
             newState = states::IDLE;
             break;
+          }
             // --------------------------------------------------
           default:
             newState = states::UNKNOWN_STATE_ERROR;
             break;
+          }
           if (currentState != newState){
             chprintf((BaseSequentialStream*)&global.sercanmux1, "Transmit state %d\n", newState);
             global.robot.transmitState(newState);
           //   if (newState == states::IDLE)
           //     {global.stateTracker[states::IDLE] += 1;}
           //   else if (newState == states::FOLLOW_LINE)
           //     {global.stateTracker[states::FOLLOW_LINE] += 1;}
           //   else if (newState == states::DETECT_STATION)
           //     {global.stateTracker[states::DETECT_STATION] += 1;}
           //   else if (newState == states::REVERSE)
           //     {global.stateTracker[states::REVERSE] += 1;}
           //   else if (newState == states::PUSH_BACK)
           //     {global.stateTracker[states::PUSH_BACK] += 1;}
           //   else if (newState == states::CHECK_POSITIONING)
           //     {global.stateTracker[states::CHECK_POSITIONING] += 1;}
           //   else if (newState == states::CHECK_VOLTAGE)
           //     {global.stateTracker[states::CHECK_VOLTAGE] += 1;}
           //   else if (newState == states::CHARGING)
           //     {global.stateTracker[states::CHARGING] += 1;}
           //   else if (newState == states::RELEASE)
           //     {global.stateTracker[states::RELEASE] += 1;}
           //   else if (newState == states::RELEASE_TO_CORRECT)
           //     {global.stateTracker[states::RELEASE_TO_CORRECT] += 1;}
           //   else if (newState == states::CORRECT_POSITIONING)
           //     {global.stateTracker[states::CORRECT_POSITIONING] += 1;}
           //   else if (newState == states::TURN)
           //     {global.stateTracker[states::TURN] += 1;}
           //   else if (newState == states::INACTIVE)
           //     {global.stateTracker[states::INACTIVE] += 1;}
           //   else if (newState == states::CALIBRATION)
           //     {global.stateTracker[states::CALIBRATION] += 1;}
           //   else if (newState == states::CALIBRATION_CHECK)
           //     {global.stateTracker[states::CALIBRATION_CHECK] += 1;}
           //   else if (newState == states::DEVIATION_CORRECTION)
           //     {global.stateTracker[states::DEVIATION_CORRECTION] += 1;}
           //   else if (newState == states::DOCKING_ERROR)
           //     {global.stateTracker[16+(-states::DOCKING_ERROR)] += 1;}
           //   else if (newState == states::REVERSE_TIMEOUT_ERROR)
           //     {global.stateTracker[16+(-states::REVERSE_TIMEOUT_ERROR)] += 1;}
           //   else if (newState == states::CALIBRATION_ERROR)
           //     {global.stateTracker[16+(-states::CALIBRATION_ERROR)] += 1;}
           //   else if (newState == states::WHITE_DETECTION_ERROR)
           //     {global.stateTracker[16+(-states::WHITE_DETECTION_ERROR)] += 1;}
           //   else if (newState == states::PROXY_DETECTION_ERROR)
           //     {global.stateTracker[16+(-states::PROXY_DETECTION_ERROR)] += 1;}
           //   else if (newState == states::NO_CHARGING_POWER_ERROR)
           //     {global.stateTracker[16+(-states::NO_CHARGING_POWER_ERROR)] += 1;}
           //   else if (newState == states::UNKNOWN_STATE_ERROR)
           //     {global.stateTracker[16+(-states::UNKNOWN_STATE_ERROR)] += 1;}
+          }
           prevState = currentState;
           currentState = newState;
           this->sleep(CAN::UPDATE_PERIOD);
+        }
         return RDY_OK;
+      }