private int displayAnalogValueInt(AGauge anaGauge, raceFileClass rF, int analogNumber, int digitalValue, int meterValue, float multiplier) { // this calculates one measured analog value pointed by index i.e. analogNumber float flValue = (float)(rF.Analog[analogNumber] - digitalValue) * multiplier + (float)meterValue; int intValue = System.Convert.ToInt32(flValue); anaGauge.Value = intValue; anaGauge.CapText = formCapText(analogNumber, intValue); return(intValue); }
private void StartMonitor_button_Click(object sender, EventArgs e) { bool status = true; initComPort(); try { serialPort1.Open(); } catch (Exception ex) { MessageBox.Show("Error: Could not open serial port connection. Original error: " + ex.Message); status = false; } if (status == true) { status = startSession(); int sesSta = readComAll(); if (status == false) { MessageBox.Show("Error: Could not start terminal connection."); } } else { if (serialPort1.IsOpen) { serialPort1.WriteLine("ZE"); serialPort1.Close(); } MessageBox.Show("Error: Could not open terminal connection."); } if (status == true) { status = sendMonitorCommand(); } if (status == true) { monFile = new raceFileClass(); monFile.OpenW("Monitor." + System.Convert.ToString(monNbr)); monNbr++; readComTimer.Start(); } }
private void Simulate_button_Click(object sender, EventArgs e) { DialogResult result; result = openFileDialog1.ShowDialog(); if (result == DialogResult.OK) { string path1 = openFileDialog1.FileName; try { if ((raceFileStr = openFileDialog1.OpenFile( )) != null) { // Insert code to read the stream here. raceFileStr.Close(); rFile = new raceFileClass(); rFile.Open(openFileDialog1.FileName); int count = rFile.ReadOneLine(); if (count > 10) { count = rFile.ParseLine(); } int time = rFile.ms; if (time == 0 || time > 1000) { time = 50; } updateScreenTimer.Interval = time; updateScreenTimer.Enabled = true; updateScreenTimer.Start(); } } catch (Exception ex) { MessageBox.Show("Error: Could not read file from disk. Original error: " + ex.Message); } } }
private void updateGauges(raceFileClass raceFile) { string vText; int value; float fValue; aGauge1.Value = raceFile.RPM[0]; vText = raceFile.RPM[0].ToString(); gauge1_label.Text = vText; fValue = (float)raceFile.RPM[1] * (float)sets.speedPerShaftRPM; aGauge2.Value = fValue; value = System.Convert.ToInt32(fValue); gauge2_label.Text = value.ToString(); aGauge3.Value = raceFile.RPM[2]; aGauge4.Value = raceFile.RPM[3]; if (raceFile.onOff[0] == true) { if (sets.OnOffs.getState(0) == true) { OnOff1_progressBar.Value = 100; } else { OnOff1_progressBar.Value = 0; } } else if (sets.OnOffs.getState(0) == true) { OnOff1_progressBar.Value = 0; } else { OnOff1_progressBar.Value = 100; } if (raceFile.onOff[1] == true) { if (sets.OnOffs.getState(1) == true) { OnOff2_progressBar.Value = 100; } else { OnOff2_progressBar.Value = 0; } } else if (sets.OnOffs.getState(1) == true) { OnOff2_progressBar.Value = 0; } else { OnOff2_progressBar.Value = 100; } if (raceFile.onOff[2] == true) { if (sets.OnOffs.getState(2) == true) { OnOff3_progressBar.Value = 100; } else { OnOff3_progressBar.Value = 0; } } else if (sets.OnOffs.getState(2) == true) { OnOff3_progressBar.Value = 0; } else { OnOff3_progressBar.Value = 100; } float multip = (float)(sets.temp_2 - sets.temp_1) / (float)(sets.analog_value_2 - sets.analog_value_1); int tmpIndex = sets.first_temp_sensor_index; value = displayAnalogValueInt(aGauge5, raceFile, tmpIndex, sets.analog_value_2, sets.temp_2, multip); tmpIndex++; value = displayAnalogValueInt(aGauge6, raceFile, tmpIndex, sets.analog_value_2, sets.temp_2, multip); tmpIndex++; value = displayAnalogValueInt(aGauge7, raceFile, tmpIndex, sets.analog_value_2, sets.temp_2, multip); tmpIndex++; value = displayAnalogValueInt(aGauge8, raceFile, tmpIndex, sets.analog_value_2, sets.temp_2, multip); tmpIndex++; value = displayAnalogValueInt(aGauge9, raceFile, tmpIndex, sets.analog_value_2, sets.temp_2, multip); tmpIndex++; value = displayAnalogValueInt(aGauge10, raceFile, tmpIndex, sets.analog_value_2, sets.temp_2, multip); tmpIndex++; value = displayAnalogValueInt(aGauge11, raceFile, tmpIndex, sets.analog_value_2, sets.temp_2, multip); tmpIndex++; value = displayAnalogValueInt(aGauge12, raceFile, tmpIndex, sets.analog_value_2, sets.temp_2, multip); float [] volt = new float[8]; int aIndex = 0; for (int i = 0; i < 8; i++) { volt[i] = (float)raceFile.Analog[sets.first_analog_index + i] * 5.0F / 256.0F; } float [] val = new float[8]; for (int i = 0; i < 8; i++) { aIndex = sets.first_analog_index + i; val[i] = (float)(volt[i] - sets.analog1.getVolt2(aIndex)) / sets.analog1.getMultip(aIndex) + sets.analog1.getVal2(aIndex); } addGauge1.Value = val[0]; addGauge2.Value = val[1]; addGauge3.Value = val[2]; addGauge4.Value = val[3]; addGauge5.Value = val[4]; addGauge6.Value = val[5]; addGauge7.Value = val[6]; addGauge8.Value = val[7]; }
private float calcFloatAnalogValue(AGauge anaGauge, raceFileClass rF, int analogNumber, int digitalValue, int meterValue, float multiplier) { float flValue = (float)(rF.Analog[analogNumber] - digitalValue) * multiplier + (float)meterValue; return(flValue); }