//=================================================================================================== // 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); }
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(); } }
//-------------------------------------------------------------------------- // 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; } }