public void EfieldCalTest15()
{
string uan = uanstr; // TODO: 初始化为适当的值
ReadUan.GetGainPara(uan);
double power1 = 1; // TODO: 初始化为适当的值
double frequency = 1000; // TODO: 初始化为适当的值
Point originPoint = new Point(0, 0, 0); // TODO: 初始化为适当的值
Point targetPoint = new Point(1, 1, Math.Sqrt(2)); // TODO: 初始化为适当的值
Point rotateAngle = null; // TODO: 初始化为适当的值
EField expected = new EField(); // TODO: 初始化为适当的值
expected.X.Re = 0.191101863744437;
expected.X.Im = -0.330998137426465;
expected.Y.Re = -2.54751092378142;
expected.Y.Im = 4.41241835282609;
expected.Z.Re = 1.66623282560157;
expected.Z.Im = -2.88599991118093;
EField actual;
actual = DirectEfieldCal.EfieldCal(uan, power1, frequency, originPoint, targetPoint, rotateAngle);
Assert.IsTrue((Math.Abs(expected.X.Re - actual.X.Re) < 0.00001) && (Math.Abs(expected.X.Im - actual.X.Im) < 0.00001) &&
(Math.Abs(expected.Y.Re - actual.Y.Re) < 0.00001) && (Math.Abs(expected.Y.Im - actual.Y.Im) < 0.00001) &&
(Math.Abs(expected.Z.Re - actual.Z.Re) < 0.00001) && (Math.Abs(expected.Z.Im - actual.Z.Im) < 0.00001));
//Assert.Inconclusive("验证此测试方法的正确性。");
}
public void EfieldCalTest1()
{
string uan = uanstr; // TODO: 初始化为适当的值
ReadUan.GetGainPara(uan);
double power1 = 1; // TODO: 初始化为适当的值
double frequency = 1000; // TODO: 初始化为适当的值
Point originPoint = new Point(0, 0, 0); // TODO: 初始化为适当的值
Point targetPoint = new Point(1, 0, 0); // TODO: 初始化为适当的值
Point rotateAngle = null; // TODO: 初始化为适当的值
EField expected = new EField(); // TODO: 初始化为适当的值
expected.X.Re = 0;
expected.X.Im = 0;
expected.Y.Re = -3.8729833462074;
expected.Y.Im = -6.70820393249938;
expected.Z.Re = 6.66493056834915;
expected.Z.Im = 11.5439983732997;
EField actual;
actual = DirectEfieldCal.EfieldCal(uan, power1, frequency, originPoint, targetPoint, rotateAngle);
Assert.IsTrue((Math.Abs(expected.X.Re - actual.X.Re) < 0.00001) && (Math.Abs(expected.X.Im - actual.X.Im) < 0.00001) &&
(Math.Abs(expected.Y.Re - actual.Y.Re) < 0.00001) && (Math.Abs(expected.Y.Im - actual.Y.Im) < 0.00001) &&
(Math.Abs(expected.Z.Re - actual.Z.Re) < 0.00001) && (Math.Abs(expected.Z.Im - actual.Z.Im) < 0.00001));
//Assert.Inconclusive("验证此测试方法的正确性。");
}
public void EfieldCalTest12()
{
string uan = uanstr; // TODO: 初始化为适当的值
ReadUan.GetGainPara(uan);
double power1 = 1; // TODO: 初始化为适当的值
double frequency = 1000; // TODO: 初始化为适当的值
Point originPoint = new Point(0, 0, 0); // TODO: 初始化为适当的值
Point targetPoint = new Point(1, 0, Math.Sqrt(3) / 3); // TODO: 初始化为适当的值
Point rotateAngle = null; // TODO: 初始化为适当的值
EField expected = new EField(); // TODO: 初始化为适当的值
expected.X.Re = 2.9127396218559;
expected.X.Im = 4.06237996247662;
expected.Y.Re = 3.90886803931641;
expected.Y.Im = 5.45167411454598;
expected.Z.Re = -5.04501301427337;
expected.Z.Im = -7.03624849465925;
EField actual;
actual = DirectEfieldCal.EfieldCal(uan, power1, frequency, originPoint, targetPoint, rotateAngle);
Assert.IsTrue((Math.Abs(expected.X.Re - actual.X.Re) < 0.00001) && (Math.Abs(expected.X.Im - actual.X.Im) < 0.00001) &&
(Math.Abs(expected.Y.Re - actual.Y.Re) < 0.00001) && (Math.Abs(expected.Y.Im - actual.Y.Im) < 0.00001) &&
(Math.Abs(expected.Z.Re - actual.Z.Re) < 0.00001) && (Math.Abs(expected.Z.Im - actual.Z.Im) < 0.00001));
//Assert.Inconclusive("验证此测试方法的正确性。");
}
public void EfieldCalTest13()
{
string uan = uanstr; // TODO: 初始化为适当的值
ReadUan.GetGainPara(uan);
double power1 = 1; // TODO: 初始化为适当的值
double frequency = 1000; // TODO: 初始化为适当的值
Point originPoint = new Point(0, 0, 0); // TODO: 初始化为适当的值
Point targetPoint = new Point(1, 0, Math.Sqrt(3)); // TODO: 初始化为适当的值
Point rotateAngle = null; // TODO: 初始化为适当的值
EField expected = new EField(); // TODO: 初始化为适当的值
expected.X.Re = -1.44299978225551;
expected.X.Im = 2.4993489381773;
expected.Y.Re = -1.93649167310375;
expected.Y.Im = 3.35410196624966;
expected.Z.Re = 0.833116312725791;
expected.Z.Im = -1.44299978225547;
EField actual;
actual = DirectEfieldCal.EfieldCal(uan, power1, frequency, originPoint, targetPoint, rotateAngle);
Assert.IsTrue((Math.Abs(expected.X.Re - actual.X.Re) < 0.00001) && (Math.Abs(expected.X.Im - actual.X.Im) < 0.00001) &&
(Math.Abs(expected.Y.Re - actual.Y.Re) < 0.00001) && (Math.Abs(expected.Y.Im - actual.Y.Im) < 0.00001) &&
(Math.Abs(expected.Z.Re - actual.Z.Re) < 0.00001) && (Math.Abs(expected.Z.Im - actual.Z.Im) < 0.00001));
//Assert.Inconclusive("验证此测试方法的正确性。");
}
public void EfieldCalTest10()
{
string uan = uanstr; // TODO: 初始化为适当的值
ReadUan.GetGainPara(uan);
double power1 = 1; // TODO: 初始化为适当的值
double frequency = 1000; // TODO: 初始化为适当的值
Point originPoint = new Point(0, 0, 0); // TODO: 初始化为适当的值
Point targetPoint = new Point(1, Math.Sqrt(3), 0); // TODO: 初始化为适当的值
Point rotateAngle = null; // TODO: 初始化为适当的值
EField expected = new EField(); // TODO: 初始化为适当的值
expected.X.Re = 1.67705098312488;
expected.X.Im = -2.90473750965554;
expected.Y.Re = -0.968245836551877;
expected.Y.Im = 1.67705098312483;
expected.Z.Re = 3.33246528417467;
expected.Z.Im = -5.77199918664981;
EField actual;
actual = DirectEfieldCal.EfieldCal(uan, power1, frequency, originPoint, targetPoint, rotateAngle);
Assert.IsTrue((Math.Abs(expected.X.Re - actual.X.Re) < 0.00001) && (Math.Abs(expected.X.Im - actual.X.Im) < 0.00001) &&
(Math.Abs(expected.Y.Re - actual.Y.Re) < 0.00001) && (Math.Abs(expected.Y.Im - actual.Y.Im) < 0.00001) &&
(Math.Abs(expected.Z.Re - actual.Z.Re) < 0.00001) && (Math.Abs(expected.Z.Im - actual.Z.Im) < 0.00001));
//Assert.Inconclusive("验证此测试方法的正确性。");
}
public void EfieldCalTest11()
{
string uan = uanstr; // TODO: 初始化为适当的值
ReadUan.GetGainPara(uan);
double power1 = 1; // TODO: 初始化为适当的值
double frequency = 1000; // TODO: 初始化为适当的值
Point originPoint = new Point(0, 0, 0); // TODO: 初始化为适当的值
Point targetPoint = new Point(1, 0, 1); // TODO: 初始化为适当的值
Point rotateAngle = null; // TODO: 初始化为适当的值
EField expected = new EField(); // TODO: 初始化为适当的值
expected.X.Re = -1.05564268913923;
expected.X.Im = 4.59306794482337;
expected.Y.Re = -1.22686532511019;
expected.Y.Im = 5.33805221724575;
expected.Z.Re = 1.05564268913923;
expected.Z.Im = -4.59306794482337;
EField actual;
actual = DirectEfieldCal.EfieldCal(uan, power1, frequency, originPoint, targetPoint, rotateAngle);
Assert.IsTrue((Math.Abs(expected.X.Re - actual.X.Re) < 0.00001) && (Math.Abs(expected.X.Im - actual.X.Im) < 0.00001) &&
(Math.Abs(expected.Y.Re - actual.Y.Re) < 0.00001) && (Math.Abs(expected.Y.Im - actual.Y.Im) < 0.00001) &&
(Math.Abs(expected.Z.Re - actual.Z.Re) < 0.00001) && (Math.Abs(expected.Z.Im - actual.Z.Im) < 0.00001));
//Assert.Inconclusive("验证此测试方法的正确性。");
}
public void EfieldCalTest9()
{
string uan = uanstr; // TODO: 初始化为适当的值
ReadUan.GetGainPara(uan);
double power1 = 1; // TODO: 初始化为适当的值
double frequency = 1000; // TODO: 初始化为适当的值
Point originPoint = new Point(0, 0, 0); // TODO: 初始化为适当的值
Point targetPoint = new Point(1, Math.Sqrt(3) / 3, 0); // TODO: 初始化为适当的值
Point rotateAngle = null; // TODO: 初始化为适当的值
EField expected = new EField(); // TODO: 初始化为适当的值
expected.X.Re = -1.95443401965821;
expected.X.Im = -2.72583705727299;
expected.Y.Re = 3.38517902208908;
expected.Y.Im = 4.72128827635085;
expected.Z.Re = -6.72668373552254;
expected.Z.Im = -9.38166426413794;
EField actual;
actual = DirectEfieldCal.EfieldCal(uan, power1, frequency, originPoint, targetPoint, rotateAngle);
Assert.IsTrue((Math.Abs(expected.X.Re - actual.X.Re) < 0.00001) && (Math.Abs(expected.X.Im - actual.X.Im) < 0.00001) &&
(Math.Abs(expected.Y.Re - actual.Y.Re) < 0.00001) && (Math.Abs(expected.Y.Im - actual.Y.Im) < 0.00001) &&
(Math.Abs(expected.Z.Re - actual.Z.Re) < 0.00001) && (Math.Abs(expected.Z.Im - actual.Z.Im) < 0.00001));
//Assert.Inconclusive("验证此测试方法的正确性。");
}
public void EfieldCalTest8()
{
string uan = uanstr; // TODO: 初始化为适当的值
ReadUan.GetGainPara(uan);
double power1 = 1; // TODO: 初始化为适当的值
double frequency = 1000; // TODO: 初始化为适当的值
Point originPoint = new Point(0, 0, 0); // TODO: 初始化为适当的值
Point targetPoint = new Point(1, -1, 0); // TODO: 初始化为适当的值
Point rotateAngle = null; // TODO: 初始化为适当的值
EField expected = new EField(); // TODO: 初始化为适当的值
expected.X.Re = -0.867524790988055;
expected.X.Im = 3.77457292114235;
expected.Y.Re = -0.867524790988055;
expected.Y.Im = 3.77457292114236;
expected.Z.Re = 2.11128514574735;
expected.Z.Im = -9.18613487791125;
EField actual;
actual = DirectEfieldCal.EfieldCal(uan, power1, frequency, originPoint, targetPoint, rotateAngle);
Assert.IsTrue((Math.Abs(expected.X.Re - actual.X.Re) < 0.00001) && (Math.Abs(expected.X.Im - actual.X.Im) < 0.00001) &&
(Math.Abs(expected.Y.Re - actual.Y.Re) < 0.00001) && (Math.Abs(expected.Y.Im - actual.Y.Im) < 0.00001) &&
(Math.Abs(expected.Z.Re - actual.Z.Re) < 0.00001) && (Math.Abs(expected.Z.Im - actual.Z.Im) < 0.00001));
//Assert.Inconclusive("验证此测试方法的正确性。");
}
public PowerTest()
{
StreamReader sr = new StreamReader(@"C:\Users\wangnan\Desktop\EMC_Project\FinalCode6\1st_ctrl\WI_Wrapper\TestForCal\bin\Debug\HalfWaveDipole.uan");
string s2 = sr.ReadToEnd();
ReadUan.GetGainPara(s2);
}
public PowerTest()
{
StreamReader sr = new StreamReader(@"C:\Users\wangnan\Desktop\新建文件夹\FinalCode6\1st_ctrl\WI_Wrapper\TestForCal\bin\Debug\");
string s2 = sr.ReadToEnd();
ReadUan.GetGainPara(s2);
}
public static void Calculate(string setuppath, string terpath, string txpath, string rxpath)
{
//此判断用来将ter文件中的三角面读入Intersection.Tris中
Terrain newTer = new Terrain(terpath);
string DirectoryPath = GetDirectory(setuppath) + "result\\";
SetupObject setupOne = SetupFileProceed.GetSetupFile.GetSetup(setuppath);
int txTotal = setupOne.tr.FirstAvailableTxNumber;
string ProName = GetProName(setuppath);
List <Node> txs = TxFileProceed.GetTx(txpath, setuppath, terpath);
myLog.Info(txs.Count);
List <List <ReceiveBall> > rxs = RxFileProceed.GetRx(rxpath, setuppath, terpath);
myLog.Info(rxs.Count);
//rxs.AddRange(TxFileProceed.GetTxAsRx(txpath, setuppath, terpath));
City buildings = new City(GetDirectory(setuppath) + ProName + ".city");
buildings.RestructTerrainByBuildings(newTer.TerRect);
if (buildings.Build != null && buildings.Build.Count != 0)
{
newTer.OutPutNewTerrain(GetDirectory(setuppath));
} //输出新地形
int?[] index = { null, null };
int txindex = 0;
for (int i = 0; i < txs.Count; i++)
{
List <FrequencyBand> txFrequencyBand = TxFileProceed.GetTxFrequenceBand(txpath, setuppath, i);//获取频段信息
myLog.Debug("这是第" + (i + 1) + "个发射机的射线追踪==========================================================================");
for (int j = 0; j < rxs.Count; j++)
{
//该接收区只有一个接收机
if (rxs[j].Count == 1)
{
if (rxs[j][0].GetType().ToString().Equals("CalculateModelClasses.ReceiveArea"))
{
//电磁态势的追踪模块
ReceiveArea reArea = (ReceiveArea)rxs[j][0];
//第一步:构建态势区域
myLog.Debug("构建态势区域");
reArea.CreateAreaSituation(newTer.TerRect);
//第二步:正向追踪,获取路径
myLog.Debug("正向追踪,获取粗略路径");
RayTubeMethod areaTracing = new RayTubeMethod(txs[i], reArea, newTer, buildings, 64);
//读取发射天线的极化信息
string txPol = GetRxTxPol("tx", txs[i].TxNum);
//读取接收天线的极化信息(删除??)
string rxPol = GetRxTxPol("areaSituation", rxs[j][0].RxNum);
//第三步:反向追踪,获取准确路径
//for (int m = 0; m < reArea.areaSituationNodes.Count; m++)
//{
// areaTracing.ReverseAreaTracingPathsAndDeleteRepeatedPaths(reArea.areaSituationNodes[m].paths);
//}
//获取发射天线的4个参数
ReadUan.GetGainPara(txs[i].UAN);
for (int m = 0; m < reArea.areaSituationNodes.Count; m++)
{
reArea.areaSituationNodes[m].classifiedFrequencyPaths = new List <List <CalculateModelClasses.Path> >();
if (reArea.areaSituationNodes[m].paths.Count != 0)
{
PathsafterPolization(reArea.areaSituationNodes[m].paths, txPol, rxPol);//极化代码
//第四步:分频段求每条路径上的场强
reArea.areaSituationNodes[m].classifiedFrequencyPaths = new List <List <CalculateModelClasses.Path> >();
//areaTracing.ScreenAreaSituationPathsByFrequencyAndCalculateEField(txFrequencyBand, reArea.areaSituationNodes[m].paths, reArea.areaSituationNodes[m].classifiedFrequencyPaths);
//计算每个频段上的各个路径叠加的总场强
for (int n = 0; n < txFrequencyBand.Count; n++)
{
EField tempEfield = new EField();
tempEfield.X = tempEfield.GetTolEx(reArea.areaSituationNodes[m].classifiedFrequencyPaths[n]);
tempEfield.Y = tempEfield.GetTolEy(reArea.areaSituationNodes[m].classifiedFrequencyPaths[n]);
tempEfield.Z = tempEfield.GetTolEz(reArea.areaSituationNodes[m].classifiedFrequencyPaths[n]);
//得到每个频段上各个路径叠加的场强
reArea.areaSituationNodes[m].totleEfields.Add(tempEfield);
//得到各个频段上各个路径后得到的总场强
reArea.areaSituationNodes[m].totleEfield.X += tempEfield.X;
reArea.areaSituationNodes[m].totleEfield.Y += tempEfield.Y;
reArea.areaSituationNodes[m].totleEfield.Z += tempEfield.Z;
}
}
}
//文件输出
string path = ".\\.\\project\\station\\areaSituationResult.txt";
if (!System.IO.File.Exists(path))
{
System.IO.File.Create(path).Close();
}
StringBuilder sb = new StringBuilder();
for (int m = 0; m < reArea.areaSituationNodes.Count; m++)
{
if (reArea.areaSituationNodes[m].paths.Count != 0)
{
//string appendText1 = m+" " + reArea.areaSituationNodes[m].paths.Count+" " ;
//sb.Append(appendText1);
//string appendText2 = "Ex " + reArea.areaSituationNodes[m].totleEfield.X.Re + "+j" + reArea.areaSituationNodes[m].totleEfield.X.Im + ",Ey " + reArea.areaSituationNodes[m].totleEfield.Y.Re + "+j" + reArea.areaSituationNodes[m].totleEfield.Y.Im + ",Ez " + reArea.areaSituationNodes[m].totleEfield.Z.Re + "+j" + reArea.areaSituationNodes[m].totleEfield.Z.Im + "\r\n";
//sb.Append(appendText2);
string appendText1 = "第" + m + "个态势点上有" + reArea.areaSituationNodes[m].paths.Count + "条路径,";
sb.Append(appendText1);
string appendText2 = "总场强为:Ex " + reArea.areaSituationNodes[m].totleEfield.X.Re + "+j" + reArea.areaSituationNodes[m].totleEfield.X.Im + ",Ey " + reArea.areaSituationNodes[m].totleEfield.Y.Re + "+j" + reArea.areaSituationNodes[m].totleEfield.Y.Im + ",Ez " + reArea.areaSituationNodes[m].totleEfield.Z.Re + "+j" + reArea.areaSituationNodes[m].totleEfield.Z.Im + "\r\n";
sb.Append(appendText2);
}
//else
//{
// string appendText1 = "没有到达第" + m + "个态势点的路径\r\n";
// sb.Append(appendText1);
//}
}
StreamWriter stw = new StreamWriter(path);
stw.Write(sb);
stw.Flush(); //清空缓冲区
stw.Close(); //关闭流
//---------------------------------
myLog.Debug("结果计算和文件输出过程结束,进入下一个接收机的追踪--------------------------------------");
}
else
{
if (("tx_" + txs[i].NodeName).Equals(rxs[j][0].RxName))
{
myLog.Debug("这是第" + (i + 1) + "个发射机第" + (j + 1) + "个接收机的射线追踪:是同一个发射机");
continue;
}
myLog.Debug("这是第" + (i + 1) + "个发射机第" + (j + 1) + "个接收机的射线追踪*****************************************************");
index[0] = j;
RayTubeMethod rayTubeMethod = new RayTubeMethod(txs[i], rxs[j][0], newTer, buildings, 32);
rayTubeMethod.ReverseTracingPathsAndDeleteRepeatedPaths();
rayTubeMethod.UpdateRayInForNodes();
// PunctiformLaunchMethod punctiformMethod = new PunctiformLaunchMethod(txs[i], rxs[j][0], newTer, buildings, 64, txFrequencyBand);
// List<CalculateModelClasses.Path> temp = punctiformMethod.GetPunctiformRxPath(tx, rxs[j][0], newTer,cityBuilding, 32, 128,TxFrequencyBand);
// if (rayTubeMethod.ReceivedPaths.Count != 0)//若存在直射射线
// {
// string txPol = GetRxTxPol("tx", txs[i].TxNum);//极化代码
// string rxPol = null;
// if (rxs[j][0].isTx == true)
// {
// rxPol = GetRxTxPol("tx", rxs[j][0].RxNum);
// }
// else
// {
// rxPol = GetRxTxPol("rx", rxs[j][0].RxNum);//
// }
// PathsafterPolization(rayTubeMethod.ReceivedPaths, txPol, rxPol);//
// }
myLog.Debug("射线追踪过程结束,进入射线筛选和计算过程-----------------------------------------");
//输出结果
ReadUan.GetGainPara(rxs[j][0].UAN);
List <List <CalculateModelClasses.Path> > ClassifiedPaths = rayTubeMethod.ScreenPunctiformPathsByFrequencyAndCalculateEField(txFrequencyBand);
for (int m = 0; m < txFrequencyBand.Count; m++)
{
P2mFileOutput.p2mfileoutput(ClassifiedPaths[m], DirectoryPath, ProName, txs[i].TxNum, txTotal, txindex, rxs[j][0], txs[i].Position, txFrequencyBand[m].MidPointFrequence, txFrequencyBand[m].FrequenceWidthMin, txFrequencyBand[m].FrequenceWidthMax);
}
List <CalculateModelClasses.Path> totalPowerPath = GetTotalPowerPath(ClassifiedPaths);
PowerOutput.GetRxTotalPower(totalPowerPath, DirectoryPath, ProName, txs[i].TxNum, txTotal, rxs[j][0], txs[i].Position);
myLog.Debug("结果计算和文件输出过程结束,进入下一个接收机的追踪---------------------------------------");
}
}
else
{
throw new Exception("没有接收机");
}
}
}
GC.Collect();
}