//=================================================================================================== // Setup //==================================================================================================== void setup() { // Lets initialize the Commander Serial.begin(); if (!command.begin("/dev/ttyXBEE", B38400)) { printf("Commander Begin failed\n"); return; } // Next initialize the Bioloid bioloid.poseSize = CNT_SERVOS; // Read in the current positions... printf("Before readPose\n"); bioloid.readPose(); printf("After readPose\n"); for (int i=1; i <= CNT_SERVOS; i++) { Serial.println(dxl_read_word(i, AX_PRESENT_POSITION_L), DEC); } // Start off to put arm to sleep... Serial.println("Kurt's Arm"); PutArmToSleep(); MSound(3, 60, 2000, 80, 2250, 100, 2500); }
void setup(void) { Serial.println(F("Touch Paint!")); tft.begin(); if (!ts.begin()) { Serial.println("Couldn't start touchscreen controller"); while (1); } Serial.println("Touchscreen started"); tft.fillScreen(ILI9341_BLACK); // make the color selection boxes tft.fillRect(0, 0, BOXSIZE, BOXSIZE, ILI9341_RED); tft.fillRect(BOXSIZE, 0, BOXSIZE, BOXSIZE, ILI9341_YELLOW); tft.fillRect(BOXSIZE*2, 0, BOXSIZE, BOXSIZE, ILI9341_GREEN); tft.fillRect(BOXSIZE*3, 0, BOXSIZE, BOXSIZE, ILI9341_CYAN); tft.fillRect(BOXSIZE*4, 0, BOXSIZE, BOXSIZE, ILI9341_BLUE); tft.fillRect(BOXSIZE*5, 0, BOXSIZE, BOXSIZE, ILI9341_MAGENTA); // select the current color 'red' tft.drawRect(0, 0, BOXSIZE, BOXSIZE, ILI9341_WHITE); currentcolor = ILI9341_RED; }
void CheckVoltages(void) { #ifdef AVS_PIN uint16_t wVS = analogRead(AVS_PIN); #ifdef DEBUG if (g_fDebugOutput && (wVS != g_wVSPrev)) { Serial.print("VS: "); Serial.println(wVS, DEC); g_wVSPrev = wVS; } #endif if ((wVS < (uint16_t)AVAL_MIN) && g_fServosInit) { // detach any servos we may have... MSound( 3, 100, 2500, 100, 2500, 100, 2500); } #elif defined(PACKET_MODE) // Using Roboclaw in packet mode, so we can ask it for the // motor voltages... Note: This requires us to send and receive // stuff serially, so probably only do this every so often. if ((millis()-g_ulCVTimeLast) > 1000) { // more than a second since we last tested uint16_t wVS = RClaw.ReadMainBatteryVoltage(PACKETS_ADDRESS); #ifdef DEBUG if (g_fDebugOutput && (wVS != g_wVSPrev)) { Serial.print("VS: "); Serial.println(wVS, DEC); g_wVSPrev = wVS; } #endif if ((wVS < (uint16_t)VOLTAGE_MIN1) && g_fServosInit) { // detach any servos we may have... MSound( 3, 100, 2500, 100, 2500, 100, 2500); } g_ulCVTimeLast = millis(); // remember last we did it. } #endif }
int main() { // Install signal handler to allow us to do some cleanup... struct sigaction sigIntHandler; sigIntHandler.sa_handler = SignalHandler; sigemptyset(&sigIntHandler.sa_mask); sigIntHandler.sa_flags = 0; sigaction(SIGINT, &sigIntHandler, NULL); Serial.begin(); setup(); for(;;) { loop(); } }
void MoveServo(PWM::Pin *apin, uint16_t wNew, uint16_t wTime) { long lPWNS = apin->GetDutyNS(); // Pulse Width in NS Serial.print((long)(wNew*1000), DEC); Serial.print(" "); Serial.print(lPWNS, DEC); uint16_t cCycles = (wTime/20); Serial.print(" "); Serial.print(cCycles, DEC); if (cCycles) { long lDeltaNSCycle = (((long)wNew*1000) - lPWNS) / cCycles; Serial.print(" "); Serial.println(lDeltaNSCycle, DEC); while (cCycles--) { lPWNS += lDeltaNSCycle; apin->SetDutyNS(lPWNS); delay(20); // delay a bit } } apin->SetDutyUS(wNew); }
uint8_t doArmIK(boolean fCartesian, int sIKX, int sIKY, int sIKZ, int sIKGA) { int t; int sol0; uint8_t bRet = IKS_SUCCESS; // assume success #ifdef DEBUG if (g_fDebugOutput) { Serial.print("("); Serial.print(sIKX, DEC); Serial.print(","); Serial.print(sIKY, DEC); Serial.print(","); Serial.print(sIKZ, DEC); Serial.print(","); Serial.print(sIKGA, DEC); Serial.print(")="); } #endif if (fCartesian) { // first, make this a 2DOF problem... by solving base sol0 = radToServo(atan2(sIKX,sIKY)); // remove gripper offset from base t = sqrt(sq((long)sIKX)+sq((long)sIKY)); // BUGBUG... Not sure about G here #define G 30 sol0 -= radToServo(atan2((G/2)-G_OFFSET,t)); } else { // We are in cylindrical mode, probably simply set t to the y we passed in... t = sIKY; #ifdef DEBUG sol0 = 0; #endif } // convert to sIKX/sIKZ plane, remove wrist, prepare to solve other DOF float flGripRad = (float)(sIKGA)*3.14159/180.0; long trueX = t - (long)((float)WristLength*cos(flGripRad)); long trueZ = sIKZ - BaseHeight - (long)((float)WristLength*sin(flGripRad)); long im = sqrt(sq(trueX)+sq(trueZ)); // length of imaginary arm float q1 = atan2(trueZ,trueX); // angle between im and X axis long d1 = sq(ShoulderLength) - sq(ElbowLength) + sq((long)im); long d2 = 2*ShoulderLength*im; float q2 = acos((float)d1/float(d2)); q1 = q1 + q2; int sol1 = radToServo(q1-1.57); d1 = sq(ShoulderLength)-sq((long)im)+sq(ElbowLength); d2 = 2*ElbowLength*ShoulderLength; q2 = acos((float)d1/(float)d2); int sol2 = radToServo(3.14-q2); // solve for wrist rotate int sol3 = radToServo(3.2 + flGripRad - q1 - q2 ); #ifdef DEBUG if (g_fDebugOutput) { Serial.print("<"); Serial.print(sol0, DEC); Serial.print(","); Serial.print(trueX, DEC); Serial.print(","); Serial.print(trueZ, DEC); Serial.print(","); Serial.print(sol1, DEC); Serial.print(","); Serial.print(sol2, DEC); Serial.print(","); Serial.print(sol3, DEC); Serial.print(">"); } #endif // Lets calculate the actual servo values. if (fCartesian) { sBase = min(max(512 - sol0, BASE_MIN), BASE_MAX); } sShoulder = min(max(512 - sol1, SHOULDER_MIN), SHOULDER_MAX); // Magic Number 819??? sElbow = min(max(819 - sol2, SHOULDER_MIN), SHOULDER_MAX); #define Wrist_Offset 512 sWrist = min(max(Wrist_Offset + sol3, WRIST_MIN), WRIST_MAX); // Remember our current IK positions g_sIKX = sIKX; g_sIKY = sIKY; g_sIKZ = sIKZ; g_sIKGA = sIKGA; // Simple test im can not exceed the length of the Shoulder+Elbow joints... if (im > (ShoulderLength + ElbowLength)) { if (g_bIKStatus != IKS_ERROR) { #ifdef DEBUG if (g_fDebugOutput) { Serial.println("IK Error"); } #endif MSound(2, 50, 3000, 50, 3000); } bRet = IKS_ERROR; } else if(im > (ShoulderLength + ElbowLength-IK_FUDGE)) { if (g_bIKStatus != IKS_WARNING) { #ifdef DEBUG if (g_fDebugOutput) { Serial.println("IK Warning"); } #endif MSound(1, 75, 2500); } bRet = IKS_WARNING; } return bRet; }
//=================================================================================================== // MoveArmTo //=================================================================================================== void MoveArmTo(int sBase, int sShoulder, int sElbow, int sWrist, int sWristRot, int sGrip, int wTime, boolean fWait) { int sMaxDelta; int sDelta; // First make sure servos are not free... if (g_fServosFree) { g_fServosFree = false; for(uint8_t i=1; i <= CNT_SERVOS; i++) { TorqueOn(i); } bioloid.readPose(); } #ifdef DEBUG if (g_fDebugOutput) { Serial.print("["); Serial.print(sBase, DEC); Serial.print(" "); Serial.print(sShoulder, DEC); Serial.print(" "); Serial.print(sElbow, DEC); Serial.print(" "); Serial.print(sWrist, DEC); Serial.print(" "); Serial.print(sWristRot, DEC); Serial.print(" "); Serial.print(sGrip, DEC); Serial.println("]"); } #endif // Make sure the previous movement completed. // Need to do it before setNextPos calls as this // is used in the interpolating code... while (bioloid.interpolating() > 0) { bioloid.interpolateStep(); delay(3); } // Also lets limit how fast the servos will move as to not get whiplash. bioloid.setNextPoseByIndex(SID_BASE, sBase); sMaxDelta = abs(bioloid.getNextPoseByIndex(SID_RSHOULDER) - sShoulder); bioloid.setNextPoseByIndex(SID_RSHOULDER, sShoulder); bioloid.setNextPoseByIndex(SID_LSHOULDER, 1024-sShoulder); sDelta = abs(bioloid.getNextPoseByIndex(SID_RELBOW) - sElbow); if (sDelta > sMaxDelta) sMaxDelta = sDelta; bioloid.setNextPoseByIndex(SID_RELBOW, sElbow); bioloid.setNextPoseByIndex(SID_LELBOW, 1024-sElbow); sDelta = abs(bioloid.getNextPoseByIndex(SID_WRIST) - sWrist); if (sDelta > sMaxDelta) sMaxDelta = sDelta; bioloid.setNextPoseByIndex(SID_WRIST, sWrist); #ifdef OPT_WRISTROT bioloid.setNextPoseByIndex(SID_WRISTROT, sWristRot); #endif bioloid.setNextPoseByIndex(SID_GRIP, sGrip); // Save away the current positions... g_sBase = sBase; g_sShoulder = sShoulder; g_sElbow = sElbow; g_sWrist = sWrist; g_sWristRot = sWristRot; g_sGrip = sGrip; // Now start the move - But first make sure we don't move too fast. if (((long)sMaxDelta*wTime/1000L) > MAX_SERVO_DELTA_PERSEC) { wTime = ((long)sMaxDelta*1000L)/ MAX_SERVO_DELTA_PERSEC; } bioloid.interpolateSetup(wTime); // Do at least the first movement bioloid.interpolateStep(); // And if asked to, wait for the previous move to complete... if (fWait) { while (bioloid.interpolating() > 0) { bioloid.interpolateStep(); delay(3); } } }
void FindServoZeroPoints() { // not clean but... int data; short sSN; // which servo number boolean fNew = true; // is this a new servo to work with? boolean fExit = false; // when to exit int ich; word wCenter; // OK lets move all of the servos to their zero point. InitializeServos(); Serial.println("Find Servo Zeros.\n$-Exit, +- changes, *-change servo"); // Lets move all of the servos to their default location... for (sSN=0; sSN < MNUMSERVOS; sSN++) g_aServos[sSN]->SetDutyUS(rcd.aServos[sSN].wCenter); sSN = 0; // start at our first servo. while(!fExit) { if (fNew) { wCenter = rcd.aServos[sSN].wCenter; Serial.print("Servo: "); Serial.print(g_apszServos[sSN]); Serial.print("("); Serial.print(wCenter-1500, DEC); Serial.println(")"); // Now lets wiggle the servo MoveServo(g_aServos[sSN], wCenter+250, 500); MoveServo(g_aServos[sSN], wCenter-250, 500); MoveServo(g_aServos[sSN], wCenter, 500); fNew = false; } //get user entered data data = Serial.read(); //if data received if (data !=-1) { if (data == '$') fExit = true; // not sure how the keypad will map so give NL, CR, LF... all implies exit else if ((data == '+') || (data == '-')) { if (data == '+') rcd.aServos[sSN].wCenter += 5; // increment by 5us else rcd.aServos[sSN].wCenter -= 5; // increment by 5us Serial.print(" "); Serial.println(rcd.aServos[sSN].wCenter, DEC); // Lets try to use attach to change the offsets... MoveServo(g_aServos[sSN], rcd.aServos[sSN].wCenter, 100); } else if ((data >= '0') && (data < ('0'+ MNUMSERVOS))) { // direct enter of which servo to change fNew = true; sSN = data - '0'; } else if (data == '*') { // direct enter of which servo to change fNew = true; sSN++; if (sSN == MNUMSERVOS) sSN = 0; } } } Serial.print("Find Servo exit "); for (sSN=0; sSN < MNUMSERVOS; sSN++){ Serial.print(" "); Serial.print(g_aServos[sSN]->GetDutyNS()/1000, DEC); } Serial.print("\nSave Changes? Y/N: "); //get user entered data while (((data = Serial.read()) == -1) || ((data >= 10) && (data <= 15))) ; if ((data == 'Y') || (data == 'y')) { // call off to save away the updated data. rcd.Save(); } else { g_fServosInit = false; // Lets go back and reinit... rcd.Load(); } }
//============================================================================== // TerminalMonitor - Simple background task checks to see if the user is asking // us to do anything, like update debug levels ore the like. //============================================================================== boolean TerminalMonitor(void) { uint8_t szCmdLine[20]; int ich; int ch; // See if we need to output a prompt. if (g_fShowDebugPrompt) { Serial.println("Rover Debug Monitor"); Serial.println("D - Toggle debug on or off"); #ifdef BBB_SERVO_SUPPORT Serial.println("O - Enter Servo offset mode"); Serial.println("S <SN> <ANGLE> - Move Servo"); #endif g_fShowDebugPrompt = false; } // First check to see if there is any characters to process. if (ich = Serial.available()) { ich = 0; // For now assume we receive a packet of data from serial monitor, as the user has // to click the send button... for (ich=0; ich < sizeof(szCmdLine); ich++) { ch = Serial.read(); // get the next character if ((ch == -1) || ((ch >= 10) && (ch <= 15))) break; szCmdLine[ich] = ch; } szCmdLine[ich] = '\0'; // go ahead and null terminate it... Serial.print("Serial Cmd Line:"); Serial.write(szCmdLine, ich); Serial.println("!!!"); // So see what are command is. if (ich == 0) { g_fShowDebugPrompt = true; } else if ((ich == 1) && ((szCmdLine[0] == 'd') || (szCmdLine[0] == 'D'))) { g_fDebugOutput = !g_fDebugOutput; if (g_fDebugOutput) Serial.println("Debug is on"); else Serial.println("Debug is off"); #ifdef BBB_SERVO_SUPPORT } else if ((ich == 1) && ((szCmdLine[0] == 'o') || (szCmdLine[0] == 'O'))) { FindServoZeroPoints(); } else if (((szCmdLine[0] == 's') || (szCmdLine[0] == 'S'))) { // ok lets grab a servo number int iServo = 0; int iAngle = 0; int i; for (i=1; i< ich; i++) { if (szCmdLine[i] != ' ') break; } if ((szCmdLine[i] >= '0') && (szCmdLine[i] <= '9')) { iServo = szCmdLine[i++] - '0'; // now angle while (szCmdLine[i] == ' ') i++; while ((szCmdLine[i] >= '0') && (szCmdLine[i] <= '9')) { iAngle = iAngle*10 + szCmdLine[i++] - '0'; } // Ok lets try moving the servo there... g_aServos[iServo]->SetDutyUS(iAngle); } #endif } return true; } return false; }
//-------------------------------------------------------------------------- // Main: the main function. //-------------------------------------------------------------------------- int main(int argc, char *argv[]) { // Install signal handler to allow us to do some cleanup... struct sigaction sigIntHandler; sigIntHandler.sa_handler = SignalHandler; sigemptyset(&sigIntHandler.sa_mask); sigIntHandler.sa_flags = 0; sigaction(SIGINT, &sigIntHandler, NULL); char abT[40]; // give a nice large buffer. uint8_t cbRead; printf("Start\n"); if (argc > 1) { for (int i=1; i < argc; i++) { printf("%d - %s\n", i, argv[i]); } } char *pszDevice; if (!RClaw.begin(pszDevice = (argc > 1? argv[1] : szRClawDevice), B38400)) { printf("RClaw (%s) Begin failed\n", pszDevice); return 0; } if (!command.begin(pszDevice = (argc > 2? argv[2] : szCommanderDevice), B38400)) { printf("Commander (%s) Begin failed\n", pszDevice); return 0; } int error; delay(250); Serial.begin(/*57600*/); // Try to load the Rover Configuration Data rcd.Load(); g_MotorsDriver.Init(); Serial.println("Kurt's Rover Program Startup\n"); g_fDebugOutput = false; // start with it off! g_fShowDebugPrompt = true; g_fRoverActive = false; g_fRoverActivePrev = false; g_fServosInit = false; g_bGear = 3; // We init in 3rd gear. g_bSteeringMode = ONE_STICK_MODE; // Initialize our pan and tilt servos InitializeServos(); // Make sure the servos are active for(;;) { //-------------------------------------------------------------------------- // Loop: the main arduino main Loop function //-------------------------------------------------------------------------- // We also have a simple debug monitor that allows us to // check things. call it here.. if (TerminalMonitor()) continue; CheckVoltages(); // check voltages - if we get too low shut down the servos... // Lets get the PS2 data... ControlInput(); // Drive the rover if (g_fRoverActive) { if (g_bSteeringMode == TANK_MODE) { sRDrivePWM = LStickY; //RStickY; // BUGBUG - appears like wrong ones doing each... sLDrivePWM = RStickY; // LStickY; } else { // One stick driving if ((RStickY >=0) && (RStickX >= 0)) { // Quadrant 1 sRDrivePWM = RStickY - RStickX; sLDrivePWM = max(RStickX, RStickY); } else if ((RStickY<0) && (RStickX>=0)) { //Quadrant 2 sRDrivePWM = (RStickY + RStickX); sLDrivePWM = min (-RStickX, RStickY); } else if ((RStickY<0) && (RStickX<0)) { //Quadrant 3 sRDrivePWM = min (RStickX, RStickY); sLDrivePWM = (RStickY - RStickX); } else if ((RStickY>=0) && (RStickX<0)) { // Quadrant 4 sRDrivePWM = max(-RStickX, RStickY); sLDrivePWM = (RStickY + RStickX); } else { sRDrivePWM = 0; sLDrivePWM = 0; } } // Lets output the appropriate stuff to the motor controller // ok lets figure out our speeds to output to the two motors. two different commands // depending on going forward or backward. // Scale the two values for the motors. sRDrivePWM = max(min((sRDrivePWM * g_bGear) / 4, 127), -127); // This should keep up in the -127 to +127 range and scale it depending on what gear we are in. sLDrivePWM = max(min((sLDrivePWM * g_bGear) / 4, 127), -127); #ifdef DEBUG if (g_fDebugOutput) { if ((RStickY != RStickYPrev) || (RStickX != RStickXPrev) || (LStickY != LStickYPrev) || (LStickX != LStickXPrev) || (sRDrivePWM != sRDrivePWMPrev) || (sLDrivePWM != sLDrivePWMPrev)) { Serial.print(LStickY, DEC); Serial.print(","); Serial.print(LStickX, DEC); Serial.print(" "); Serial.print(RStickY, DEC); Serial.print(","); Serial.print(RStickX, DEC); Serial.print(" - "); Serial.print(sLDrivePWM, DEC); Serial.print(","); Serial.println(sRDrivePWM, DEC); LStickYPrev = LStickY; LStickXPrev = LStickX; RStickYPrev = RStickY; RStickXPrev = RStickX; sRDrivePWMPrev = sRDrivePWM; sLDrivePWMPrev = sLDrivePWM; } } #endif // Call our motors driver code which may change depending on how we talk to the motors... g_MotorsDriver.RDrive(sRDrivePWM); g_MotorsDriver.LDrive(sLDrivePWM); // Also if we have a pan/tilt lets update that as well.. #ifdef BBB_SERVO_SUPPORT if (g_bSteeringMode != TANK_MODE) { if (LStickX ) { if (command.buttons & BUT_L6) { //modify which thing we are controlling depending on if L6 is down or not. w = max(min(g_wRot + LStickX/8, rcd.aServos[RoverConfigData::ROTATE].wMax), rcd.aServos[RoverConfigData::ROTATE].wMin); if (w != g_wRot) { pinRot.SetDutyUS(w); g_wRot = w; } } else { w = max(min(g_wPan + LStickX/8, rcd.aServos[RoverConfigData::PAN].wMax), rcd.aServos[RoverConfigData::PAN].wMin); if (w != g_wPan) { pinPan.SetDutyUS(w); g_wPan = w; } } } if (LStickY) { w = max(min(g_wTilt + LStickY/8, rcd.aServos[RoverConfigData::TILT].wMax), rcd.aServos[RoverConfigData::TILT].wMin); if (w != g_wTilt) { pinTilt.SetDutyUS(w); g_wTilt = w; } } } #endif delay (10); } else { if (g_fRoverActivePrev) { MSound( 3, 100, 2500, 80, 2250, 60, 2000); g_MotorsDriver.RDrive(0); g_MotorsDriver.LDrive(0); } delay (10); } g_fRoverActivePrev = g_fRoverActive; } }