Eigenvalues corresponds to eigenvectors

AVM
2020 2 月 8
1 回答
回答採用済み
2020 2 月 9 に更新
10 ビュー (30 日間)

0 投票

In matlab, the command [V,L]=eig(h) produces the eigenvectors and eigenvalues of the square matirx h. But I would like to know in which order this eigenvectors appear? I mean how can I observe that which eigenvalues corresponds to which eigenvectors. I am really confused at this point. Pl somebody help me to understand this. Here I have taken an example.
clc;clear;
syms a b c
h=[a 0 1 0;0 b 2 0;1 0 c 0;0 3 0 a];
[V,L]=eig(h)
This produces the output as
V =
[ 0, 0, a/12 - b/6 + c/12 - (a^2 - 2*a*c + c^2 + 4)^(1/2)/12, a/12 - b/6 + c/12 + (a^2 - 2*a*c + c^2 + 4)^(1/2)/12]
[ 0, b/3 - a/3, c/6 - a/6 - (a^2 - 2*a*c + c^2 + 4)^(1/2)/6, c/6 - a/6 + (a^2 - 2*a*c + c^2 + 4)^(1/2)/6]
[ 0, 0, (a*b)/6 - (a*c)/6 - (b/6 - c/6)*(a/2 + c/2 - (a^2 - 2*a*c + c^2 + 4)^(1/2)/2) + 1/6, (a*b)/6 - (a*c)/6 - (b/6 - c/6)*(a/2 + c/2 + (a^2 - 2*a*c + c^2 + 4)^(1/2)/2) + 1/6]
[ 1, 1, 1, 1]
L =
[ a, 0, 0, 0]
[ 0, b, 0, 0]
[ 0, 0, a/2 + c/2 - (a^2 - 2*a*c + c^2 + 4)^(1/2)/2, 0]
[ 0, 0, 0, a/2 + c/2 + (a^2 - 2*a*c + c^2 + 4)^(1/2)/2]
But how do I associate the eigenvector with its corresponding eigenvealue.

サインインしてこの質問に回答する。

 採用された回答

Vladimir Sovkov
Vladimir Sovkov 2020 年 2 月 8 日

0 投票

Absolutely standard: L(k,k) ~ V(:,k).
You can check it with the code:
for k=1:size(h,1)
disp(strcat('k=',num2str(k),'; h*v-lambda*v=',num2str(double(norm(simplify(h*V(:,k) - L(k,k)*V(:,k)))))));
end

10 件のコメント
8 件の古いコメントを表示 8 件の古いコメントを非表示

Vladimir Sovkov
Vladimir Sovkov 2020 年 2 月 8 日
Notice that your matrix is not even symmetric, and a, b, c are considered arbitrary complex numbers. Some extra assumptions can simplify the result.
AVM
AVM 2020 年 2 月 8 日
Thanks for your reply. Sorry,I didn't get your point. I just need to know for which eigenvalue, what is its corresponding eigenvector. I am runnig your code but what is tets it signifies. Is it that characteristics equation? Pl tell me in detail if possible.
Vladimir Sovkov
Vladimir Sovkov 2020 年 2 月 8 日
It is not the characteristic equation. It just tests the straightforward definition of the eigenvalues and eigenvectors: (v is the eigenvector and λ is the eigenvalue).
AVM
AVM 2020 年 2 月 8 日
@Vladimir: Thanks for your clarification. Now, I got the point. It is to test that \nu is an eigenvector with corresponding eigenvalues \lambda. It's basically that eigenvalue equation.
AVM
AVM 2020 年 2 月 8 日
@Vladimir: Is this eigenvector is normalized to unity? Or I have to make them normalize using V(:,k) / norm(V:,k)) ? Pl inform me.
Vladimir Sovkov
Vladimir Sovkov 2020 年 2 月 8 日
Generally, not normalized. I have noticed that the eigenvectors are normalized for real symmetric matrices but not in a general case.
AVM
AVM 2020 年 2 月 8 日
Thanks for your reply.
AVM
AVM 2020 年 2 月 8 日
@Vladimir: Is there any way to call c particular compoment of a column vector? I mean to say how can I call a component of column matrix in matlab? Here, I taken an example,
syms a b c d
h=[a;b;c;d]
How can I call 'c' element? What is the corresponding command? Pl help me.
AVM
AVM 2020 年 2 月 8 日
And what about in this case also?
clc;
clear;
syms a b c
assume(a,'real');
assume(b,'real');
assume(c,'real');
h=[a 1 0;3 b 1;1 0 c];
[V,L]=eig(h);
u=simplify(V(:,1),'Steps',50)
The u is here
u =
a/3 + b/3 - (2*c)/3 + ((((a*b)/3 + (a*c)/3 + (b*c)/3 - (a + b + c)^2/9 - 1)^3 + ((a + b + c)^3/27 - ((a + b + c)*(a*b + a*c + b*c - 3))/6 - (3*c)/2 + (a*b*c)/2 + 1/2)^2)^(1/2) - (3*c)/2 - ((a + b + c)*(a*b + a*c + b*c - 3))/6 + (a + b + c)^3/27 + (a*b*c)/2 + 1/2)^(1/3) - ((a*b)/3 + (a*c)/3 + (b*c)/3 - (a + b + c)^2/9 - 1)/((((a*b)/3 + (a*c)/3 + (b*c)/3 - (a + b + c)^2/9 - 1)^3 + ((a + b + c)^3/27 - ((a + b + c)*(a*b + a*c + b*c - 3))/6 - (3*c)/2 + (a*b*c)/2 + 1/2)^2)^(1/2) - (3*c)/2 - ((a + b + c)*(a*b + a*c + b*c - 3))/6 + (a + b + c)^3/27 + (a*b*c)/2 + 1/2)^(1/3)
a*c + (a/3 + b/3 + c/3 + ((((a*b)/3 + (a*c)/3 + (b*c)/3 - (a + b + c)^2/9 - 1)^3 + ((a + b + c)^3/27 - ((a + b + c)*(a*b + a*c + b*c - 3))/6 - (3*c)/2 + (a*b*c)/2 + 1/2)^2)^(1/2) - (3*c)/2 - ((a + b + c)*(a*b + a*c + b*c - 3))/6 + (a + b + c)^3/27 + (a*b*c)/2 + 1/2)^(1/3) - ((a*b)/3 + (a*c)/3 + (b*c)/3 - (a + b + c)^2/9 - 1)/((((a*b)/3 + (a*c)/3 + (b*c)/3 - (a + b + c)^2/9 - 1)^3 + ((a + b + c)^3/27 - ((a + b + c)*(a*b + a*c + b*c - 3))/6 - (3*c)/2 + (a*b*c)/2 + 1/2)^2)^(1/2) - (3*c)/2 - ((a + b + c)*(a*b + a*c + b*c - 3))/6 + (a + b + c)^3/27 + (a*b*c)/2 + 1/2)^(1/3))^2 - (a + c)*(a/3 + b/3 + c/3 + ((((a*b)/3 + (a*c)/3 + (b*c)/3 - (a + b + c)^2/9 - 1)^3 + ((a + b + c)^3/27 - ((a + b + c)*(a*b + a*c + b*c - 3))/6 - (3*c)/2 + (a*b*c)/2 + 1/2)^2)^(1/2) - (3*c)/2 - ((a + b + c)*(a*b + a*c + b*c - 3))/6 + (a + b + c)^3/27 + (a*b*c)/2 + 1/2)^(1/3) - ((a*b)/3 + (a*c)/3 + (b*c)/3 - (a + b + c)^2/9 - 1)/((((a*b)/3 + (a*c)/3 + (b*c)/3 - (a + b + c)^2/9 - 1)^3 + ((a + b + c)^3/27 - ((a + b + c)*(a*b + a*c + b*c - 3))/6 - (3*c)/2 + (a*b*c)/2 + 1/2)^2)^(1/2) - (3*c)/2 - ((a + b + c)*(a*b + a*c + b*c - 3))/6 + (a + b + c)^3/27 + (a*b*c)/2 + 1/2)^(1/3))
1
Now if I would like to call 2nd component of this column matrix u, then what should I have to do?
Vladimir Sovkov
Vladimir Sovkov 2020 年 2 月 9 日
The array indexing is described at https://www.mathworks.com/help/matlab/math/array-indexing.html?searchHighlight=matrix%20indexing&s_tid=doc_srchtitle
E.g., you address the entire k-th column of a matrix as V(:,k).

サインインしてコメントする。

その他の回答 (0 件)

カテゴリ

ヘルプ センター および File ExchangeLinear Algebra についてさらに検索

タグ

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!

Translated by