潮流计算的MATLAB源程序.docx
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潮流计算的MATLAB源程序
%简单潮流计算的牛顿拉夫逊程序,相关的原始数据数据数据输入格式如下:
%B1是支路参数矩阵,第一列和第二列是节点编号。
节点编号由小到大编写
%对于含有变压器的支路,第一列为低压侧节点编号,第二列为高压侧节点%编号,将变压器的串联阻抗置于低压侧处理。
%第三列为支路的串列阻抗参数。
%第四列为支路的对地导纳参数。
%第五列为含变压器支路的变压器的变比
%第六列为变压器是否含有变压器的参数,其中“1”为含有变压器
%“0”为不含有变压器。
%B2为节点参数矩阵,其中第一列为节点注入发电功率参数;第二列为节点负荷
1”为平衡节
功率参数;第三列为节点电压参数;第六列为节点类型参数,其中“
点,“2”为PQ节点,“3”为V节点参数。
%X为节点号和对地参数矩阵。
其中第一列为节点编号,第二列为节点对地
%参数。
n=input('请输入节点数:
n=');n1=input('请输入支路数:
n1=');
isb=input('请输入平衡节点号:
isb=');pr=input('请输入误差精度:
pr=');B1=input('请输入支路参数:
B1=');B2=input('请输入节点参数:
B2=');X=input('节点号和对地参数:
X=');Y=zeros(n);
Times=1;%置迭代次数为初始值
%创建节点导纳矩阵
fori=1:
n1
ifB1(i,6)==0%不含变压器的支路
p=B1(i,1);
q=B1(i,2);
Y(p,q)=Y(p,q)-1/B1(i,3);
Y(q,p)=Y(p,q);
Y(p,p)=Y(p,p)+1/B1(i,3)+0.5*B1(i,4);
Y(q,q)=Y(q,q)+1/B1(i,3)+0.5*B1(i,4);
else%含有变压器的支路
p=B1(i,1);
q=B1(i,2);
Y(p,q)=Y(p,q)-1/(B1(i,3)*B1(i,5));
Y(q,p)=Y(p,q);
Y(p,p)=Y(p,p)+1/B1(i,3);
Y(q,q)二Y(q,q)+1/(B1(i,5F2*B1(i,3));
end
end
Y
OrgS=zeros(2*n-2,1);
DetaS二zeros(2*n-2,1);%将OrgS、DetaS初始化
%创建OrgS,用于存储初始功率参数
h=0;
j=0;
ifi~=isb&B2(i,6)==2
h=h+1;
forj=1:
n
OrgS(2*h-1,1)=OrgS(2*h-1,1)+real(B2(i,3))*(real(Y(i,j))*real(B2(j,3))-imag(Y(i,j))*i
mag(B2(j,3)))+imag(B2(i,3))*(real(Y(i,j))*imag(B2(j,3))+imag(Y(i,j))*real(B2(j,3)));
OrgS(2*h,1)=OrgS(2*h,1)+imag(B2(i,3))*(real(Y(i,j))*real(B2(j,3))-imag(Y(i,j))*ima
g(B2(j,3)))-real(B2(i,3))*(real(Y(i,j))*imag(B2(j,3))+imag(Y(i,j))*real(B2(j,3)));
end
end
end
fori=1:
n%对PV节点的处理,注意这时不可再将h初始化为0
ifi~=isb&B2(i,6)==3
h=h+1;
forj=1:
n
OrgS(2*h-1,1)=OrgS(2*h-1,1)+real(B2(i,3))*(real(Y(i,j))*real(B2(j,3))-imag(Y(i,j))*i
mag(B2(j,3)))+imag(B2(i,3))*(real(Y(i,j))*imag(B2(j,3))+imag(Y(i,j))*real(B2(j,3)));
OrgS(2*h,1)=OrgS(2*h,1)+imag(B2(i,3))*(real(Y(i,j))*real(B2(j,3))-imag(Y(i,j))*ima
g(B2(j,3)))-real(B2(i,3))*(real(Y(i,j))*imag(B2(j,3))+imag(Y(i,j))*real(B2(j,3)));
end
end
end
OrgS
%创建PVU用于存储PV节点的初始电压
PVU=zeros(n-h-1,1);
t=0;
fori=1:
n
ifB2(i,6)==3
t=t+1;
PVU(t,1)=B2(i,3);
end
end
PVU
%创建DetaS,用于存储有功功率、无功功率和电压幅值的不平衡量
h=0;
fori=1:
n%对PQ节点的处理
ifi~=isb&B2(i,6)==2
h=h+1;
DetaS(2*h-1,1)=real(B2(i,2))-OrgS(2*h-1,1);DetaS(2*h,1)=imag(B2(i,2))-OrgS(2*h,1);
end
end
t=0;
fori=1:
n%对PV节点的处理,注意这时不可再将h初始化为0
ifi~=isb&B2(i,6)==3
h=h+1;
t=t+1;
DetaS(2*h-1,1)=real(B2(i,2))-OrgS(2*h-1,1);
DetaS(2*h,1)=real(PVU(t,1))A2+imag(PVU(t,1)F2-real(B2(i,3))A2-imag(B2(i,3)F2;
end
end
DetaS
%创建I,用于存储节点电流参数
i=zeros(n-1,1);
h=0;
fori=1:
n
ifi~=isb
h=h+1;
I(h,1)=(OrgS(2*h-1,1)-OrgS(2*h,1)*sqrt(-1))/conj(B2(i,3));
end
end
%创建Jacbi雅可比矩阵)
Jacbi=zeros(2*n-2);
h=0;
k=0;
fori=1:
n%对PQ节点的处理
ifB2(i,6)==2
h=h+1;
forj=1:
n
ifj~=isb
k=k+1;
ifi==j%对角元素的处理
Jacbi(2*h-1,2*k-1)=-imag(Y(i,j))*real(B2(i,3))+real(Y(i,j))*imag(B2(i,3))+imag(I(h,1));
Jacbi(2*h-1,2*k)=real(Y(i,j))*real(B2(i,3))+imag(Y(i,j))*imag(B2(i,3))+real(I(h,
Jacbi(2*h,2*k-1)=-Jacbi(2*h-1,2*k)+2*real(I(h,1));
Jacbi(2*h,2*k)=Jacbi(2*h-1,2*k-1)-2*imag(I(h,1));
Jacbi(2*h-1,2*k-1)=-imag(Y(i,j))*real(B2(i,3))+real(Y(i,j))*imag(B2(i,3));Jacbi(2*h-1,2*k)=real(Y(i,j))*real(B2(i,3))+imag(Y(i,j))*imag(B2(i,3));
Jacbi(2*h,2*k-1)=-Jacbi(2*h-1,2*k);
Jacbi(2*h,2*k)=Jacbi(2*h-1,2*k-1);
end
ifk==(n-1)%将用于内循环的指针置于初始值,以确保雅可比矩阵换行k=0;
end
end
end
end
end
k=0;
fori=1:
n%对PV节点的处理
ifB2(i,6)==3
h=h+1;
forj=1:
n
ifj~=isb
k=k+1;
ifi==j%对角元素的处理
Jacbi(2*h-1,2*k-1)=-imag(Y(i,j))*real(B2(i,3))+real(Y(i,j))*imag(B2(i,3))+imag(I(h,1));
Jacbi(2*h-1,2*k)=real(Y(i,j))*real(B2(i,3))+imag(Y(i,j))*imag(B2(i,3))+real(I(h,
1));
Jacbi(2*h,2*k-1)=2*imag(B2(i,3));
Jacbi(2*h,2*k)=2*real(B2(i,3));
else%非对角元素的处理
Jacbi(2*h-1,2*k-1)=-imag(Y(i,j))*real(B2(i,3))+real(Y(i,j))*imag(B2(i,3));
Jacbi(2*h-1,2*k)=real(Y(i,j))*real(B2(i,3))+imag(Y(i,j))*imag(B2(i,3));
Jacbi(2*h,2*k-1)=0;
Jacbi(2*h,2*k)=0;
end
ifk==(n-1)%将用于内循环的指针置于初始值,以确保雅可比矩阵换
行
k=0;
end
end
end
end
end
Jacbi
%求解修正方程,获取节点电压的不平衡量
DetaU=zeros(2*n-2,1);
DetaU=inv(Jacbi)*DetaS;
DetaU
%修正节点电压j=0;
ifB2(i,6)==2
j=j+1;
B2(i,3)=B2(i,3)+DetaU(2*j,1)+DetaU(2*j-1,1)*sqrt(-1);
end
end
fori=1:
n%对PV节点的处理
ifB2(i,6)==3
j=j+1;
B2(i,3)=B2(i,3)+DetaU(2*j,1)+DetaU(2*j-1,1)*sqrt(-1);
end
end
B2
%开始循环**********************************************************************whileabs(max(DetaU))>pr
OrgS=zeros(2*n-2,1);%!
!
!
初始功率参数在迭代过程中是不累加的,所以在这里
必须将其初始化为零矩阵
h=0;
j=0;
fori=1:
n
ifi~=isb&B2(i,6)==2
h=h+1;
forj=1:
n
OrgS(2*h-1,1)=OrgS(2*h-1,1)+real(B2(i,3))*(real(Y(i,j))*real(B2(j,3))-imag(Y(i,j))*imag(B2(j,3)))+imag(B2(i,3))*(real(Y(i,j))*imag(B2(j,3))+imag(Y(i,j))*real(B2(j,3)));
OrgS(2*h,1)=OrgS(2*h,1)+imag(B2(i,3))*(real(Y(i,j))*real(B2(j,3))-imag(Y(i,j))*ima
g(B2(j,3)))-real(B2(i,3))*(real(Y(i,j))*imag(B2(j,3))+imag(Y(i,j))*real(B2(j,3)));
end
end
endfori=1:
n
ifi~=isb&B2(i,6)==3
h=h+1;
forj=1:
n
OrgS(2*h-1,1)=OrgS(2*h-1,1)+real(B2(i,3))*(real(Y(i,j))*real(B2(j,3))-imag(Y(i,j))*i
mag(B2(j,3)))+imag(B2(i,3))*(real(Y(i,j))*imag(B2(j,3))+imag(Y(i,j))*real(B2(j,3)));
OrgS(2*h,1)=OrgS(2*h,1)+imag(B2(i,3))*(real(Y(i,j))*real(B2(j,3))-imag(Y(i,j))*ima
g(B2(j,3)))-real(B2(i,3))*(real(Y(i,j))*imag(B2(j,3))+imag(Y(i,j))*real(B2(j,3)));
end
end
end
OrgS
%创建DetaS
h=0;
fori=1:
n
ifi~=isb&B2(i,6)==2
h=h+1;
DetaS(2*h-1,1)=real(B2(i,2))-OrgS(2*h-1,1);
DetaS(2*h,1)=imag(B2(i,2))-OrgS(2*h,1);
end
end
t=0;
fori=1:
n
ifi~=isb&B2(i,6)==3
h=h+1;
t=t+1;
DetaS(2*h-1,1)=real(B2(i,2))-OrgS(2*h-1,1);
DetaS(2*h,1)=real(PVU(t,1))A2+imag(PVU(t,1)F2-real(B2(i,3))A2-imag(B2(i,3)F2;
end
end
DetaS
%创建Ii=zeros(n-1,1);
h=0;
fori=1:
n
ifi~=isb
h=h+1;
I(h,1)=(OrgS(2*h-1,1)-OrgS(2*h,1)*sqrt(-1))/conj(B2(i,3));
end
end
I
%创建Jacbi
Jacbi=zeros(2*n-2);
h=0;
k=0;
fori=1:
n
ifB2(i,6)==2
h=h+1;
forj=1:
n
ifj~=isb
k=k+1;
ifi==j
(I(h,1));
1));
Jacbi(2*h-1,2*k-1)=-imag(Y(i,j))*real(B2(i,3))+real(Y(i,j))*imag(B2(i,3))+imag
Jacbi(2*h-1,2*k)=real(Y(i,j))*real(B2(i,3))+imag(Y(i,j))*imag(B2(i,3))+real(I(h,
Jacbi(2*h,2*k-1)=-Jacbi(2*h-1,2*k)+2*real(I(h,1));
Jacbi(2*h,2*k)=Jacbi(2*h-1,2*k-1)-2*imag(I(h,1));
else
Jacbi(2*h-1,2*k-1)=-imag(Y(i,j))*real(B2(i,3))+real(Y(i,j))*imag(B2(i,3));
Jacbi(2*h-1,2*k)=real(Y(i,j))*real(B2(i,3))+imag(Y(i,j))*imag(B2(i,3));
Jacbi(2*h,2*k-1)=-Jacbi(2*h-1,2*k);
Jacbi(2*h,2*k)=Jacbi(2*h-1,2*k-1);
endifk==(n-1)
k=0;
end
end
end
end
end
k=0;
fori=1:
n
ifB2(i,6)==3
h=h+1;
forj=1:
n
ifj~=isb
k=k+1;
ifi==j
Jacbi(2*h-1,2*k-1)=-imag(Y(i,j))*real(B2(i,3))+real(Y(i,j))*imag(B2(i,3))+imag
(I(h,1));
Jacbi(2*h-1,2*k)=real(Y(i,j))*real(B2(i,3))+imag(Y(i,j))*imag(B2(i,3))+real(I(h,
1));
Jacbi(2*h,2*k-1)=2*imag(B2(i,3));
Jacbi(2*h,2*k)=2*real(B2(i,3));
else
Jacbi(2*h-1,2*k-1)=-imag(Y(i,j))*real(B2(i,3))+real(Y(i,j))*imag(B2(i,3));
Jacbi(2*h-1,2*k)=real(Y(i,j))*real(B2(i,3))+imag(Y(i,j))*imag(B2(i,3));
Jacbi(2*h,2*k-1)=0;
Jacbi(2*h,2*k)=0;
end
ifk==(n-1)
k=0;
end
end
end
end
end
Jacbi
DetaU=zeros(2*n-2,1);
DetaU=inv(Jacbi)*DetaS;
DetaU
%修正节点电压
j=0;
fori=1:
n
ifB2(i,6)==2
j=j+1;
B2(i,3)=B2(i,3)+DetaU(2*j,1)+DetaU(2*j-1,1)*sqrt(-1);
end
end
fori=1:
n
ifB2(i,6)==3
j=j+1;
B2(i,3)=B2(i,3)+DetaU(2*j,1)+DetaU(2*j-1,1)*sqrt(-1);
end
end
B2
Times=Times+1;%迭代次数加1
end
Times
一个原始数据的例子
节点数5
支路数5
平衡节点编号5
精度pr0.000001
B1(支路参数矩阵)
[120.04+0.25i0.5i10;130.1+0.35i010;230.08+0.30i0.5i10;420.015i01.051;53
0.03i01.051]
B2(节点参数矩阵)[0-1.6-0.8i1002;0-2-1i1002;0-3.7-1.3i1002;05+0i1.051.0503;001.051.0501]X(节点号和对地参数)
[10;20;30;40;50]