public Humidity_Air_HIH4000(string Name, bool Simulation, Adc_MCP3208 Adc, int Channel, string CalibrationFile, Logger Logger) : this(Name, Simulation, Adc, Channel, Logger) { //Load the calibration file calibration = Calibration_2Points.Load(CalibrationFile); Initialization(); }
public Humidity_Air_HIH4000(string Name, bool Simulation, Adc_MCP3208 adc, int channel, Logger Logger) : base(Name, Simulation, Logger) { logger.Debug("Humidity_Air_HIH4000-Constructor_00"); logger = Logger; logger.Debug("Humidity_Air_HIH4000-Constructor_10"); this.Adc = adc; logger.Debug("Humidity_Air_HIH4000-Constructor_11"); MinValue = 0; MaxValue = 100; AlarmMin = MinValue; AlarmMax = MaxValue; voltage = 3.3; Channel = channel; firstValue = true; if (Simulation) SetFirstValue(); Initialization(); logger.Debug("Humidity_Air_HIH4000-Constructor_99"); }
public Light_PhotoResistor(string Name, bool Simulation, Adc_MCP3208 Adc, int Channel, Logger Logger) : base(Name, Simulation, Logger) { this.Adc = Adc; this.Channel = Channel; MinValue = 0; MaxValue = 1000; AlarmMin = MinValue; AlarmMax = MaxValue; voltage = 3.3; firstValue = true; if (Simulation) SetFirstValue(); Initialization(); }
static void Main(string[] args) { Adc_MCP3208 converter = new Adc_MCP3208(); Logger l = new Logger(); Light_PhotoResistor sensore = new Light_PhotoResistor("Luciometro", false, converter, 1, l); //int lux = 12345; DateTime data = DateTime.Now; Measurement m = sensore.Measure()[0]; // string riga = (data + "\t" + "Letto: Lux" + "\t" + m.Value); System.IO.StreamWriter file = new System.IO.StreamWriter(@"test.txt", true); // Console.WriteLine(riga); string temp; // do { temp = Console.ReadLine(); if (temp != "") file.WriteLine(m.Value + "\t" + "Campionatura: Lux" + "\t" + temp); // file.WriteLine(temp); } // while (temp != ""); // file.WriteLine(temp + riga ); file.Close(); string b = Console.ReadLine(); int a = int.Parse(b); switch(a) { case 1: Console.WriteLine("Letto: Lux" + m.Value + "\t" + "Campionatura: Lux" + "\t" + temp); break; case 2: Console.WriteLine("Letto: Lux" + "\t" + m.Value); break; case 3: Console.WriteLine("coming soon"); break; } }
public Humidity_Terrain_YL69YL38(string Name, bool Simulation, Adc_MCP3208 Adc, int Channel, Logger Logger) : base(Name, Simulation, Logger) { LastMeasurements[0] = new Measurement(); int channel; Initialization(); this.Adc = Adc; MinValue = 0; MaxValue = 100; AlarmMin = MinValue; AlarmMax = MaxValue; voltage = 3.3; channel = Channel; firstValue = true; if (Simulation) SetFirstValue(); }
protected void Page_Load(object sender, EventArgs e) { logger = new Logger(); logger.LoggingData = false; logger.LoggingDebug = false; logger.LoggingErrors = false; logger.LoggingEvents = false; logger.LoggingPrompts = false; converter = null; sensori = new List<Sensor>(); dt = new DataTable(); dt.Columns.Add("GrandezzaFisica"); dt.Columns.Add("InSimulazione"); dt.Columns.Add("Dato"); dt.Columns.Add("IdDatabase"); try { sensori = new List<Sensor>(); //using (StreamReader sr = new StreamReader(pathProgramma + "configuration.tsv")) using (StreamReader sr = new StreamReader(pathProgramma + "configurazione.tsv")) { while (sr.Peek() >= 0) { string[] dati = sr.ReadLine().Split('\t'); switch (dati[0]) { case "Temperature_DS1822": sensori.Add(new Temperature_DS1822(dati[1], bool.Parse(dati[4]), dati[2], logger)); sensori[sensori.Count - 1].GotCode = dati[3]; break; case "Humidity_Air_HIH4000": sensori.Add(new Humidity_Air_HIH4000(dati[1], bool.Parse(dati[4]), converter, int.Parse(dati[2]), logger)); sensori[sensori.Count - 1].GotCode = dati[3]; break; case "Light_PhotoResistor": sensori.Add(new Light_PhotoResistor(dati[1], bool.Parse(dati[4]), converter, int.Parse(dati[2]), logger)); sensori[sensori.Count - 1].GotCode = dati[3]; break; case "Humidity_Terrain_YL69YL38": sensori.Add(new Humidity_Terrain_YL69YL38(dati[1], bool.Parse(dati[4]), converter, int.Parse(dati[2]), logger)); sensori[sensori.Count - 1].GotCode = dati[3]; break; } } } } catch (Exception ex) { this.Alert("Errore nel caricamento dei sensori" + ex.Message); } foreach (Sensor s in sensori) AddRow(s); grdSensori.DataSource = dt; grdSensori.DataBind(); }
private static void Initialize(bool inSimulation) { Common.logger.Debug("Initialize_00"); converter = null; // per default il convertitore è null if (!inSimulation) { // acquisizione reale, convertitore converter = new Adc_MCP3208(); } Common.logger.Debug("Initialize_10"); if (readConfigFromFile) { // lettura della configurazione da file configureFromFile(); // intestazione del file dei dati: appende nel file .tsv l'intestazione string rigaIntestazione = "Istante campionamento"; Common.logger.Debug("Initialize_20"); foreach(Sensor s in Sensors) { foreach (Measurement m in s.LastMeasurements) { rigaIntestazione += "\t" + m.Name + " " + m.Unit; } } Common.logger.Debug("Initialize_30"); textFileAppend(rigaIntestazione, Gor.Common.DatalogFile); Common.logger.Debug("Initialize_40"); } else { // configurazione fissa Common.logger.Debug("Initialize_50"); fixedConfiguration(inSimulation); Common.logger.Debug("Initialize_60"); } //Rtc_PCF8563 rtc = new Rtc_PCF8563(RTC_ADDRESS); // mette zero nel file che stabilisce se il programma deve fermarsi putZeroInControlFile(Common.CloseCommandFile); putZeroInControlFile(Common.AcquireCommandFile); Common.logger.Debug("Initialize_99"); return; }
private static void Initialize(bool inSimulation) { logger.Debug("Initialize_01"); if (inSimulation) { // inizializzazioni per la parte di simulazione // convertitore converter = null; } else { // inizializzazioni per la parte di acquisizione reale // convertitore converter = new Adc_MCP3208(); } // istanziazione dei sensori //relativeHumidity = new Humidity_Air_HIH4000(inSimulation, converter, RELATIVE_HUMIDITY_CHANNEL); airHumidityAndTemperature = new Humidity_Temperature_Air_DHT22("Umidita", inSimulation, DHT22_IO_PIN, logger); //log.Test(airHumidityAndTemperature.AlarmMax.ToString()); //Sensors.Add(airHumidityAndTemperature); logger.Debug("Initialize_10"); light = new Light_PhotoResistor("Luce", inSimulation, converter, PHOTO_RESISTOR_CHANNEL, logger); logger.Debug(light.Measure().ToString()); Sensors.Add(light); logger.Debug("Initialize_20"); try { T1 = new Temperature_DS1822("T1", inSimulation, idT1, logger); Sensors.Add(T1); } catch (Exception ex) { logger.Error("Initialize_T1" + ex.Message); } try { T2 = new Temperature_DS1822("T2", inSimulation, idT2, logger); Sensors.Add(T2); } catch (Exception ex) { logger.Error("Initialize_T2" + ex.Message); } try { T3 = new Temperature_DS1822("T3", inSimulation, idT3, logger); Sensors.Add(T3); } catch (Exception ex) { logger.Error("Initialize_T3" + ex.Message); } try { T4 = new Temperature_DS1822("T4", inSimulation, idT4, logger); Sensors.Add(T4); } catch (Exception ex) { logger.Error("Initialize_T4" + ex.Message); } //terrainHumidity = new Humidity_Terrain_YL69YL38(inSimulation, converter, TERRAIN_HUMIDITY_CHANNEL); //TODO legge la lista Sensori: le linee precedenti devono essere sostituite // Sensori = ////////////dbWriter = new GorDbWriter(Sensori); // appende nel file .tsv l'intestazione string intestazione = "Istante\tUmidita'\tTemper. aria\tTemper. sonda 1\t" + "Temper. sonda 2\tTemper. sonda 3\tTemper. sonda 4\tPunti ADC sens. illum.\t" + "Punti ADC sens. umid.\n"; // #+ socket.gethostname() +"\n" logger.DataLog(intestazione); //using (StreamWriter sw = File.AppendText(progamPath + dataLogFile)) //{ // string intestazione = "Istante\tUmidita'\tTemper. aria\tTemper. sonda 1\t" + // "Temper. sonda 2\tTemper. sonda 3\tTemper. sonda 4\tPunti ADC sens. illum.\t" + // "Punti ADC sens. umid.\n"; // #+ socket.gethostname() +"\n" // sw.WriteLine(intestazione); //} //Rtc_PCF8563 rtc = new Rtc_PCF8563(RTC_ADDRESS); // mette zero nel file che stabilisce se il programma deve fermarsi zeroInClose(); logger.Debug("Initialize_99"); return; }