可以算多相

Signed-off-by: dmy@lab <dmy@lab.com>

SelfAdaptSimulation.m

@@ -11,10 +11,14 @@ ConductorX=[-14500,14500];%
 ConductorY=[16500,16500];%导线间距
 CSM_N=80;%每一个子导线的模拟电荷数
 subconductorR=30;%子导线半径
+phaseN=2;%相数，单回三相
 %%
 %设置电压
-Volt=[500;500;500;500;-500;-500;-500;-500];
-Volt=[500*ones(CSM_N*semi_lineCount,1);-500*ones(CSM_N*semi_lineCount,1)];
+Volt_=[500;-500;];
+Volt=[];
+for vLoop=1:length(Volt_)
+    Volt=[Volt;Volt_(vLoop)*ones(CSM_N*semi_lineCount,1);];
+end
 %按分裂数和分裂导线间距布置单相线路导线
 %用极坐标
 arc=2*pi/semi_lineCount;
@@ -28,24 +32,23 @@ step=1/10;
 maxLoop=round((subconductorR-r1)/step);
 for Loop=1:maxLoop;
     simulationChargePos=ones(CSM_N,1);
-    simulationChargeAPos=[];
-    simulationChargeBPos=[];
-    for sC=1:semi_lineCount
-        for I=1:CSM_N
-%             simulationChargePos(I)=exp(1j*((I-1)*CSM_arc+CSM_arc/2))*(R+r1);%逆时针转一个角度
-              simulationChargePos(I)=exp(1j*((I-1)*CSM_arc+CSM_arc/2))*r1;%逆时针转一个角度
+    simulationChargeABCPos=[];
+    for I=1:CSM_N
+        simulationChargePos(I)=exp(1j*((I-1)*CSM_arc+CSM_arc/2))*r1;%逆时针转一个角度
+    end
+    for phaseLoop=1:phaseN
+        for sC=1:semi_lineCount
+            simulationChargeABCPos=[simulationChargeABCPos;simulationChargePos+ConductorX(phaseLoop)+1j*ConductorY(phaseLoop)+exp(1j*((sC-1)*arc+arc/2))*R];%移动到子导线中心
         end
-        simulationChargeAPos=[simulationChargeAPos;simulationChargePos+ConductorX(1)+1j*ConductorY(1)+exp(1j*((sC-1)*arc+arc/2))*R];%移动到子导线中心
-        simulationChargeBPos=[simulationChargeBPos;simulationChargePos+ConductorX(2)+1j*ConductorY(2)+exp(1j*((sC-1)*arc+arc/2))*R];%移动到子导线中心
     end
 %     simulationChargeAPos=simulationChargePos+ConductorX(1)+1j*ConductorY(1);
 %     simulationChargeBPos=simulationChargePos+ConductorX(2)+1j*ConductorY(2);
-    simulationChargePos=[simulationChargeAPos;simulationChargeBPos];
+%     simulationChargePos=simulationChargeABCPos;
     %计算电位系数
-    H=diag(imag(simulationChargePos));
-    r=subconductorR*eye(length(imag(simulationChargePos)));%导线自几何均距
+    H=diag(imag(simulationChargeABCPos));
+    r=subconductorR*eye(length(imag(simulationChargeABCPos)));%导线自几何均距
     %导线与导线的距离
-    matSimulationChargePos=repmat(simulationChargePos,1,length(simulationChargePos));
+    matSimulationChargePos=repmat(simulationChargeABCPos,1,length(simulationChargeABCPos));
     conductor2conductorDistance=matSimulationChargePos-conj(matSimulationChargePos');
     conductor2conductorDistance=abs(conductor2conductorDistance-diag(diag(conductor2conductorDistance)));
     matMirrorChargePos=conj(matSimulationChargePos);%虚部取负号
@@ -69,18 +72,23 @@ for Loop=1:maxLoop;
     vrfRelPos=exp(1j*vrfRelA)*subconductorR;
     %移动坐标，使验证的子导线中心和实际子导线中心重合。
     vrfPos=[];
-    for sC=1:semi_lineCount
-        vrfPos=[vrfPos;exp(1j*((sC-1)*arc+arc/2))*R+ConductorX(1)+1j*ConductorY(1)+vrfRelPos];
+    for phaseLoop=1:phaseN
+        for sC=1:semi_lineCount
+            vrfPos=[vrfPos;exp(1j*((sC-1)*arc+arc/2))*R+ConductorX(phaseLoop)+1j*ConductorY(phaseLoop)+vrfRelPos];
+        end
     end
-%     vrfPos=ConductorX(1)+1j*ConductorY(1)+vrfRelPos;
     %计算这一点的电位系数
-    matVrfPos=repmat(vrfPos,1,length(simulationChargePos));
-    vrf2ConductorDistance=abs(matVrfPos-repmat(conj(simulationChargePos'),length(vrfPos),1));
-    vrf2MirrorDistance=abs(matVrfPos-repmat(conj(conj(simulationChargePos')),length(vrfPos),1));
+    matVrfPos=repmat(vrfPos,1,length(simulationChargeABCPos));
+    vrf2ConductorDistance=abs(matVrfPos-repmat(conj(simulationChargeABCPos'),length(vrfPos),1));
+    vrf2MirrorDistance=abs(matVrfPos-repmat(conj(conj(simulationChargeABCPos')),length(vrfPos),1));
     Pij=1/2/pi/eslong*log(vrf2MirrorDistance./vrf2ConductorDistance);
     %计算电压
     V=Pij*QRI;
-    error=sum(abs(V-500)./500)/length(V);
+    Vvalidation=[];
+    for phaseLoop=1:phaseN
+        Vvalidation=[Vvalidation;Volt_(phaseLoop)*ones(semi_lineCount*200,1);];
+    end
+    error=sum(abs((V-Vvalidation)./Vvalidation))/length(Vvalidation);
     r1=r1+step;
 end
 display('Finished.');
@@ -88,7 +96,8 @@ if Loop<maxLoop
     display('Converged.');
 end
 display(Loop);
-scatter(real(simulationChargeAPos),imag(simulationChargeAPos),[],'r');
+scatter(real(simulationChargeABCPos(1:length(simulationChargeABCPos)/1)),imag(simulationChargeABCPos(1:length(simulationChargeABCPos)/1)),[],'r');
+axis equal
 hold on;
 scatter(real(vrfPos),imag(vrfPos),[],'k');
 % scatter(real([simulationChargeAPos(1:10);]),imag([simulationChargeAPos(1:10);]),10,'red');