一维抛物线偏微分方程数值解法(4)(附图及matlab程序)
一维抛物线偏微分方程数值解法(4)
上一篇参看一维抛物线偏微分方程数值解法(3)(附图及matlab程序)
解一维抛物线型方程(理论书籍可以参看孙志忠:偏微分方程数值解法)
Ut-Uxx=0, 0
U(x,0)=e^x, 0<=x<=1,
U(0,t)=e^t,U(1,t)=e^(1+t), 0 精确解为:U(x,t)=e^(x+t); 用紧差分格式: 此种方法精度为o(h1^2+h2^4),无条件差分稳定; 一:用追赶法解线性方程组(还可以用迭代法解) Matlab程序为: function [u p e x t]=JCHGS(h1,h2,m,n) %紧差分格式解一维抛物线型偏微分方程 %此程序用的是追赶法解线性方程组 %h1为空间步长,h2为时间步长 %m,n分别为空间,时间网格数 %p为精确解,u为数值解,e为误差 x=(0:m)*h1+0; x0=(0:m)*h1;%定义x0,t0是为了f(x,t)~=0的情况% t=(0:n)*h2+0; t0=(0:n)*h2+1/2*h2; syms f; for(i=1:n+1) for(j=1:m+1) f(i,j)=0; %f(i,j)=f(x0(j),t0(i))==0% end end for(i=1:n+1) u(i,1)=exp(t(i)); u(i,m+1)=exp(1+t(i)); end for(i=1:m+1) u(1,i)=exp(x(i)); end r=h2/(h1*h1); for(i=1:n) %外循环,先固定每一时间层,每一时间层上解一线性方程组% a(1)=0;b(1)=5/6+r;c(1)=1/12-r/2;d(1)=(r/2-1/12)*u(i+1,1)+... (1/12+r/2)*u(i,1)+(5/6-r)*u(i,2)+(1/12+r/2)*u(i,3)+... h2/12*(f(i,1)+10*f(i,2)+f(i,3)); for(k=2:m-2) a(k)=1/12-r/2;b(k)=5/6+r;c(k)=1/12-r/2;d(k)=h2/12*(f(i,k)+... 10*f(i,k+1)+f(i,k+2))+(1/12+r/2)*(u(i,k)+u(i,k+2))+(5/6-r)... *u(i,k+1); %输入部分系数矩阵,为0的矩阵元素不输入%一定要注意输入元素的正确性end a(m-1)=1/12-r/2;b(m-1)=5/6+r;d(m-1)=(1/12+r/2)*(u(i,m-1)+u(i,m+1) )+... (5/6-r)*u(i,m)+(r/2-1/12)*u(i+1,m+1)+ ... h2/12*(f(i,m-1)+10*f(i,m)+f(i,m+1)); for(k=1:m-2) %开始解线性方程组消元过程 a(k+1)=-a(k+1)/b(k); b(k+1)=b(k+1)+a(k+1)*c(k); d(k+1)=d(k+1)+a(k+1)*d(k); end u(i+1,m)=d(m-1)/b(m-1); %回代过程% for(k=m-2:-1:1) u(i+1,k+1)=(d(k)-c(k)*u(i+1,k+2))/b(k); end end for(i=1:n+1) for(j=1:m+1) p(i,j)=exp(x(j)+t(i)); %p为精确解 e(i,j)=abs(u(i,j)-p(i,j));%e为误差 end end [u p e x t]=JCHGS(0.1,0.005,10,200); surf(x,t,e) >> title('误差');运行约43秒; [u p e x t]=JCHGS(0.1,0.01,10,100);surf(x,t,e) 20多秒; [u p e x t]=JCHGS(0.2,0.04,5,25);surf(x,t,e) 3秒; 此方法精度很高; 二:g-s迭代法求解线性方程组 Matlab程序 function [u e p x t k]=JCFGS1(h1,h2,m,n,kmax,ep) % 解抛物线型一维方程格式(Ut-aUxx=f(x,t),a>0) %用g-s(高斯-赛德尔)迭代法解 %kmax为最大迭代次数 %m,n为x,t方向的网格数,例如(2-0)/0.01=200; %e为误差,p为精确解 syms temp; u=zeros(n+1,m+1); x=0+(0:m)*h1; t=0+(0:n)*h2; for(i=1:n+1) u(i,1)=exp(t(i)); u(i,m+1)=exp(1+t(i)); end for(i=1:m+1) u(1,i)=exp(x(i)); end for(i=1:n+1) for(j=1:m+1) f(i,j)=0; end end a=zeros(n,m-1); r=h2/(h1*h1); %此处r=a*h2/(h1*h1);a=1 for(k=1:kmax) for(i=1:n) for(j=2:m) temp=((1/12+r/2)*(u(i,j-1)+u(i,j+1))+(5/6-r)*u(i,j)+... h2/12*(f(i,j-1)+10*f(i,j)+f(i,j+1))+(r/2-1/12)*(u(i+1,... j-1)+u(i+1,j+1)))/(5/6+r); a(i+1,j)=(temp-u(i+1,j))*(temp-u(i+1,j)); u(i+1,j)=temp;%此处注意是u(i+1,j),,而不是u(i+1,j+1)% end end a(i+1,j)=sqrt(a(i+1,j)); if(k>kmax) break; end if(max(max(a)) break; end end for(i=1:n+1) for(j=1:m+1) p(i,j)=exp(x(j)+t(i)); e(i,j)=abs(u(i,j)-p(i,j)); end end [u e p x t k]=JCFGS1(0.1,0.005,10,200,100000,1e-12);k=67;运行速度1秒左右;surf(x,t,e) [u e p x t k]=JCFGS1(0.01,0.001,100,1000,1000000,1e-12);k=5780;surf(x,t,e)