protected bool PrintVoltageValueInfo(VM_VoltageInfo vi) { if (OnVoltageValueChanges != null) { return(OnVoltageValueChanges(vi)); } else { return(false); } }
public bool PrintVoltageValueChanged(VM_VoltageInfo vi) { decimal retValue = 0; if (vi == null) { return(false); } decimal voltageValue = 0; string v0 = vi.V0.ToString().Replace("V", ""); string v1 = vi.V1.ToString().Replace("V", ""); string v2 = vi.V2.ToString().Replace("V", ""); if (decimal.Parse(v0) < 0) { v0 = "0"; } if (decimal.Parse(v1) < 0) { v1 = "0"; } if (decimal.Parse(v2) < 0) { v2 = "0"; } voltageValue = (decimal.Parse(v0) + decimal.Parse(v1) + decimal.Parse(v2)) / 3; retValue = voltageValue; if (VoltageBLL == null) { VoltageBLL = new VoltageBLL(); } IList <VM_VoltageParam> vm_vp = VoltageBLL.GetVoltageDsToListInfo(); vm_vp = vm_vp.Where(a => a.PreVoltage <= retValue && a.CurVoltage > retValue).ToList(); if (vm_vp == null || vm_vp.Count <= 0) { return(false); } foreach (VM_VoltageParam item in vm_vp) { n_VoltageLevel = item.VoltageLevel; } return(true); }
private void GetVoltageValue() { float[] fVals; int[] iVals; Adam4000_ChannelStatus[] status; VM_VoltageInfo vi = new VM_VoltageInfo(); m_iCount++; strReadCount = "Polling " + m_iCount.ToString() + " times..."; if (m_adamConfig.Format == Adam4000_DataFormat.TwosComplementHex) { //if (adamCom.AnalogInput(m_iAddr).GetValues(8, out iVals)) //{ // vi.V0 = "0x" + iVals[0].ToString("X04"); // vi.V1 = "0x" + iVals[1].ToString("X04"); // vi.V2 = "0x" + iVals[2].ToString("X04"); // vi.V3 = "0x" + iVals[3].ToString("X04"); // vi.V4 = "0x" + iVals[4].ToString("X04"); // vi.V5 = "0x" + iVals[5].ToString("X04"); // vi.V6 = "0x" + iVals[6].ToString("X04"); // vi.V7 = "0x" + iVals[7].ToString("X04"); //} //else //{ // vi.V0 = "Failed to get!"; // vi.V1 = "Failed to get!"; // vi.V2 = "Failed to get!"; // vi.V3 = "Failed to get!"; // vi.V4 = "Failed to get!"; // vi.V5 = "Failed to get!"; // vi.V6 = "Failed to get!"; // vi.V7 = "Failed to get!"; //} } else { if (adamCom.AnalogInput(m_iAddr).GetValues(8, out fVals, out status)) { string a0 = ""; string a1 = ""; string a2 = ""; string a3 = ""; string a4 = ""; string a5 = ""; string a6 = ""; string a7 = ""; if (vi == null) { vi = new VM_VoltageInfo(); } RefreshValue(ref a0, status[0], fVals[0], m_byRange[0]); vi.V0 = a0; RefreshValue(ref a1, status[1], fVals[1], m_byRange[1]); vi.V1 = a1; RefreshValue(ref a2, status[2], fVals[2], m_byRange[2]); vi.V2 = a2; RefreshValue(ref a3, status[3], fVals[3], m_byRange[3]); vi.V3 = a3; RefreshValue(ref a4, status[4], fVals[4], m_byRange[4]); vi.V4 = a4; RefreshValue(ref a5, status[5], fVals[5], m_byRange[5]); vi.V5 = a5; RefreshValue(ref a6, status[6], fVals[6], m_byRange[6]); vi.V6 = a6; RefreshValue(ref a7, status[7], fVals[7], m_byRange[7]); vi.V7 = a7; ///传送电压变化值 PrintVoltageValueInfo(vi); } else { vi.V0 = "0"; vi.V1 = "0"; vi.V2 = "0"; vi.V3 = "0"; vi.V4 = "0"; vi.V5 = "0"; vi.V6 = "0"; vi.V7 = "0"; } } }