private static void test()
{ // per test Adc: definizione del convertitore analogico digitale
DigitalConverterMCP3208 adc = new DigitalConverterMCP3208();
// per test IO digitale: definizione di canali di IO digitale
const int chanLed1 = 40;
const int chanLed2 = 38;
const int chanButton1 = 37;
const int chanButton2 = 35;
DigitalIO pinIn1 = new DigitalIO(chanButton1, GpioPinDriveMode.Input);
DigitalIO pinIn2 = new DigitalIO(chanButton2, GpioPinDriveMode.Input);
DigitalIO pinOut1 = new DigitalIO(chanLed1, GpioPinDriveMode.Output);
DigitalIO pinOut2 = new DigitalIO(chanLed2, GpioPinDriveMode.Output);
// si può anche fare così:
//DigitalIO pinIn1 = new DigitalIO(ConnectorPin.P1Pin37, GpioPinDriveMode.Input);
//DigitalIO pinOut1 = new DigitalIO(ConnectorPin.P1Pin40, GpioPinDriveMode.Output);
//DigitalIO pinIn2 = new DigitalIO(ConnectorPin.P1Pin35, GpioPinDriveMode.Input);
//DigitalIO pinOut2 = new DigitalIO(ConnectorPin.P1Pin38, GpioPinDriveMode.Output);
// definizioni per test output digitali su shift register
OutShiftRegister shift = new OutShiftRegister(16, 25, 24, 23);
Device_OnOffShift irrigator = new Device_OnOffShift(shift, 8); // ottavo pin dello shift register
Device_OnOffShift humidifier = new Device_OnOffShift(shift, 2); // secondo pin dello shift register
//TestAllDigitalInputs(pinTuttiIn);
//return;
while (true)
{
Console.CursorTop = 0;
Console.Clear();
ReadAllAdc();
// test two digital inputs
Console.WriteLine("Canale bottone 1: {0}, Canale bottone 2: {1} ",
chanButton1, chanButton2);
Console.WriteLine("Bottone 1: {0}, Bottone 2: {1} ",
pinIn1.Read().ToString(), pinIn2.Read().ToString());
// test two digital outputs
Console.WriteLine("\r\nCanale LED 1: {0}, Canale LED 2: {1} ",
chanLed1, chanLed2);
pinOut1.Write(pinIn1.Read());
pinOut2.Write(pinIn2.Read());
ActuateShiftRegister();
Thread.Sleep(500);
}
}
private static void datalog()
{
while (true)
{
fileLog = new FileLogger("file.log");
// Crea ed utilizza un ADC. Il codice del ADC utilizzerà un gestore del bus SPI
adc = new DigitalConverterMCP3208();
lux = new LightSensor(adc, 0, 3.3);
temp = new TemperatureSensor(adc, 1, 3.3);
moisture = new SoilMoistureSensor(adc, 2, 3.3);
co2 = new CO2Sensor(adc, 3, 4.9);
rh = new RelativeHumiditySensor(adc, 4, 5.0);
shift = new OutShiftRegister(16, 25, 24, 23);
lcd = new LCD1602Shift(shift, 12, 11, 10, 9, 13, 14);
irrigator = new Device_OnOffShift(shift, 8);
////////irrigator.WriteLog += WriteFileLog;
humidifier = new Device_OnOffShift(shift, 2);
////////humidifier.WriteLog += WriteFileLog;
lightDevice = new LightDevice(shift, 3, 4, 5, 6, 7, 21, 20);
lightDevice.PercentualeApertura(50);
//irrigator.TimeOn(3000);
//_timer = new DispatcherTimer();
//_timer.Interval = TimeSpan.FromMilliseconds(1000);
//_timer.Tick += Timer_Tick;
//if (_pin != null)
//{
// _timer.Start();
//}
}
}
static void Main(string[] args)
{
const int NUM_BITS = 16;
const int DATA_PIN = 16;
const int CLOCK_PIN = 16;
const int LATCH_PIN = 16;
const int ONOFFSHIFT_BIT = 16;
OutShiftRegister reg = new OutShiftRegister(NUM_BITS, DATA_PIN, CLOCK_PIN, LATCH_PIN);
Device_OnOffShift tester = new Device_OnOffShift(reg, ONOFFSHIFT_BIT);
tester.On();
Console.WriteLine("Tester on");
Task.Delay(1000);
tester.Off();
Console.WriteLine("Tester off");
Task.Delay(500);
Console.WriteLine("Tester on for 2 seconds");
tester.TimeOn(2000);
Task.Delay(2000);
Console.WriteLine("Test termined");
}
