public static void main(String args[]) { Display display = IntelliBrain.getLcdDisplay(); IBB ibb = new IBB(); try { SerialPort comPort = IntelliBrain.getCom1(); // Serial Parameters comPort.setSerialPortParams( 38400, SerialPort.DATABITS_8, SerialPort.STOPBITS_1, SerialPort.PARITY_NONE); InputStream inputStream = comPort.getInputStream(); OutputStream outputStream = comPort.getOutputStream(); // clear screen display.print(0, ""); display.print(1, ""); // test the readLine routine byte[] buf = new byte[128]; while (true) { int len = readLine(inputStream, outputStream, display, true, buf, 128); if (len == 0) continue; switch (buf[0]) { case 'B': ibb.getVersion(outputStream, buf, len); break; case 'D': ibb.setSpeed(outputStream, buf, len); break; case 'H': ibb.sysBeep(outputStream, buf, len); break; case 'L': ibb.setLedState(outputStream, buf, len); break; case 'N': ibb.readProximitySensors(outputStream, buf, len); break; case 'O': ibb.readLightSensors(outputStream, buf, len); break; case 'Z': ibb.motorsOff(outputStream, buf, len); break; } } } catch (Exception e) { e.printStackTrace(); } }
public static void run(String args[]) { try { System.out.println("WheelWatcher WW-01"); // Get the user interface objects Display display = IntelliBrain.getLcdDisplay(); AnalogInput thumbwheel = IntelliBrain.getThumbWheel(); // Get the servo object and give it a Motor interface by encapsulating it // in a ContinuousRotationServo object. Motor motor = new ContinuousRotationServo(IntelliBrain.getServo(3), true); motor.setPower(1); motor.setPower(0); motor.setPower(-1); Thread.sleep(2000); // Get a shaft encoder object and initialize it with the two digital inputs it uses. IntelliBrainShaftEncoder encoder = IntelliBrain.getShaftEncoder(1); encoder.initialize(IntelliBrain.getDigitalIO(11), IntelliBrain.getDigitalIO(10)); int previousCounts = 0; int power = 0; int rpm = 0; long time = System.currentTimeMillis(); while (true) { // Calculate RPM (Revolutions Per Minute) // RPM = countsThisIteration * iterationsPerMinute / countsPerRevolution // countsThisIteration - current encoder counts minus previous count // iterationsPerMinute = 600 - ten loops per second // countsPerRevolution = 128 - fixed by design of sensor/codewheel int counts = encoder.getCounts(); display.print(1, "RPM: " + ((counts - previousCounts) * 600) / 128); previousCounts = counts; // Read the thumbwheel and scale the value to set the motor power. int velocity = (thumbwheel.sample() - 512) / 31; while (velocity == 3 || velocity == 4) { if (velocity == 3) velocity = (thumbwheel.sample() - 512) / 31; else velocity = -(thumbwheel.sample() - 512) / 31; // counts and rpm logic counts = encoder.getCounts(); previousCounts = counts; rpm = ((counts - previousCounts) * 600) / 128; display.print(0, "RPM: " + rpm); // governer logic power += (velocity - (rpm / 16.25)); // limiter if (power > 16) power = 16; if (power < -16) power = -16; display.print(0, "Power: " + power); // set power motor.setPower(power); time += 100; Thread.sleep(time - System.currentTimeMillis()); } motor.setPower(velocity); display.print(0, "Power: " + velocity); // Calculate sleep time so the next iteration starts 1/2 second after the // the previous one. time += 100; Thread.sleep(time - System.currentTimeMillis()); } } catch (Throwable t) { // Display a stack trace if an exception occurs. t.printStackTrace(); } }