protected override double convertValue(string sHexVal, int index) { return(RQTemperature.convertToCelcius(sHexVal)); }
private void interpretMonitoringString(string monStr, long timestamp) { // Tracer.Trace("MON: " + monStr); int j = 0; for (int i = 1; i < monStr.Length && j < monitorStringValueNames.GetLength(0); i += 2) { string sHexVal = monStr.Substring(i, 2); string valueName = monitorStringValueNames[j]; RQMeasuredValue measuredValue = new RQMeasuredValue(); bool mustAdd = false; if (m_measuredValues.ContainsKey(valueName)) { measuredValue = (RQMeasuredValue)m_measuredValues[valueName]; } else { measuredValue = new RQMeasuredValue(); mustAdd = true; } lock (measuredValue) { measuredValue.timestamp = timestamp; measuredValue.valueName = valueName; measuredValue.stringValue = sHexVal; measuredValue.intValue = Int32.Parse(sHexVal, NumberStyles.HexNumber); switch (monitorStringValueConverters[j]) { default: measuredValue.doubleValue = (double)measuredValue.intValue; break; case 1: measuredValue.doubleValue = RQVoltage.convertToMainVoltage(sHexVal); break; case 2: measuredValue.doubleValue = RQVoltage.convertToInternalVoltage(sHexVal); break; case 3: measuredValue.doubleValue = RQTemperature.convertToCelcius(sHexVal); break; case 4: measuredValue.intValue = RQCompressedHex.convertToInt(sHexVal); measuredValue.doubleValue = (double)measuredValue.intValue; break; } } if (mustAdd) { m_measuredValues.Add(valueName, measuredValue); } // Tracer.Trace(valueName + "=" + sHexVal + "=" + measuredValue.doubleValue); j++; } }