void ChangeColor(string color) { Debug.Print(color); redLights.Write(false); switch (color) { case "red": multicolorLed.TurnRed(); ChangeLights(true, false, false, false); break; case "green": multicolorLed.TurnGreen(); ChangeLights(false, true, false, false); break; case "blue": multicolorLed.TurnBlue(); ChangeLights(false, false, true, false); break; case "orange": multicolorLed.TurnColor(GT.Color.Orange); ChangeLights(false, false, false, true); break; } }
/// <summary> /// Sets the sleep control pin to active state (sleep request). /// </summary> public void Sleep() { if (_connectedToGadgeteerSocket) { _gadgeteerSleepPin.Write(SleepState.Sleeping); } else { _netmfSleepPin.Write(SleepState.Sleeping); } }
/// <summary> /// Disables the module (power off). /// </summary> public void Disable() { if (_connectedToGadgeteerSocket) { _gadgeteerResetPin.Write(ResetState.NotRunning); } else { _netmfResetPin.Write(ResetState.NotRunning); } }
void ChangeLights(bool red, bool green, bool blue, bool orange) { redLights.Write(!red); greenLights.Write(!green); blueLights.Write(!blue); orangeLights.Write(!orange); }
public void Write(bool state) { if (_outputPort == null) { return; } _outputPort.Write(state); }
void timer_Tick(GT.Timer timer) { var isButtonPressed = _digitalInput.Read(); Mainboard.SetDebugLED(isButtonPressed); _digitalOutput.Write(isButtonPressed); _digitalOutput2.Write(_analogValue); Debug.Print("signal measured: " + _digitalInput2.Read().ToString()); _analogValue = !_analogValue; }
void dataReadTimer_Tick(GT.Timer timer) { output_pl.Write(false); output_pl.Write(true); output_ce.Write(false); int retval = 0; for (int i = 0; i <= 7; i++) { retval = retval << 1; if (input.Read()) { retval = retval + 1; } Clock(); } output_ce.Write(true); Debug.Print(retval.ToString()); // if (retval > 0) // uncomment if you want to keep the lights on DisplayLeds(retval); }
private void DisplayLeds(int retval) { output_srclk.Write(false); // Bit reversal :) int copy = (int)((((ulong)retval * 0x0202020202UL) & 0x010884422010UL) % 1023); for (int i = 0; i <= 7; i++) { int x = copy & 1; if (x == 0) { output_ser.Write(false); } else { output_ser.Write(true); } output_clk.Write(true); output_clk.Write(false); copy = copy >> 1; } output_srclk.Write(true); output_srclk.Write(false); }
void ProgramStarted() { // My breakout board is on socket 1 // 74HC165 output_ser = breadBoardX1.CreateDigitalOutput(GT.Socket.Pin.Six, false); // data output_clk = breadBoardX1.CreateDigitalOutput(GT.Socket.Pin.Seven, false); // clock output_srclk = breadBoardX1.CreateDigitalOutput(GT.Socket.Pin.Eight, false); // latch // 74HC165 input = breadBoardX1.CreateDigitalInput(GT.Socket.Pin.Nine, GlitchFilterMode.Off, ResistorMode.Disabled); // data output_cp = breadBoardX1.CreateDigitalOutput(GT.Socket.Pin.Four, false); // clock input output_ce = breadBoardX1.CreateDigitalOutput(GT.Socket.Pin.Five, false); // clock enable output_pl = breadBoardX1.CreateDigitalOutput(GT.Socket.Pin.Three, false); // load Debug.Print("Program Started"); button.ButtonPressed += button_ButtonPressed; Debug.Print("Setting up 74HC165"); output_pl.Write(true); output_ce.Write(true); output_cp.Write(false); dataReadTimer.Tick += dataReadTimer_Tick; }
public void SetDebugLED(bool on) { debugLedPin.Write(on); }