symbolic integration depends on different equivalent forms of function

조회 수: 5 (최근 30일)
Michal
Michal 2022년 7월 15일
댓글: Michal 2022년 7월 17일
I performed the following equaivalent symbolic integrations:
syms x y
A = int(x+y,x);
A_ = expand(A); % just expanded (equaivalent) form of A
B = expand(int(A,y))
B_ = expand(int(A_,y))
with the following results:
A =
(x*(x + 2*y))/2
A_ =
x^2/2 + y*x
B =
x^3/8 + (x^2*y)/2 + (x*y^2)/2
B_ =
(x^2*y)/2 + (x*y^2)/2
I expect B equal to B_, but there is a misterious additional term x^3/8 at B ??!!
Is that a bug???

이 질문에 답변하려면 로그인하십시오.

답변 (2개)

Torsten
Torsten 2022년 7월 15일
Ran in:
The difference is a usual "constant of integration".
If you differentiate both B and B_ with respect to y and then with respect to x, you'll arrive at the expression x+y in both cases:
syms x y
B_ = (x^2*y)/2 + (x*y^2)/2;
B = x^3/8 + (x^2*y)/2 + (x*y^2)/2;
A_ = diff(B_,y);
A = diff(B,y);
expr1 = diff(A_,x)
expr1 = 
expr2 = diff(A,x)
expr2 = 
  댓글 수: 7
이전 댓글 5개 표시
Torsten
Torsten 2022년 7월 15일
Ran in:
I'm not surprised that
int((x*(x + 2*y))/2,y)
gives a result different from
int(x^2/2 + y*x,y).
See
syms x
int((x-1)^2,x)
ans = 
compared to
int(x^2-2*x+1,x)
ans = 
Paul
Paul 2022년 7월 15일
편집: Paul 2022년 7월 15일
Ran in:
I'm not surprised either. I've seen cases where int() couldn't find a solution unless the integrand was manipulated using simplify, expand, etc. Here is an example from this Question
syms t
assume(t, "real")
f1 = 3*t-t*t*t;
f2 = 3*t*t;
f = [f1, f2];
df = diff(f, t);
a = 0;
b = 1;
normDf = sqrt(df(1)*df(1)+df(2)*df(2));
int(normDf,t,a,b) % no solution
ans = 
normDf = simplify(normDf)
normDf = 
int(normDf, t, a, b) % easy
ans = 
4

댓글을 달려면 로그인하십시오.

Michal
Michal 2022년 7월 16일
편집: Michal 2022년 7월 16일
Simple solution to avoid integration constant effect:
int(f(x),x,0,x)
  댓글 수: 4
이전 댓글 2개 표시
Torsten
Torsten 2022년 7월 16일
편집: Torsten 2022년 7월 16일
Ran in:
syms x y
A1 = int(sin(x)+sin(y),x,0,x);
B1 = int(A1,y,0,y)
B1 = 
simplify(B1)
ans = 
A2 = int(sin(x)+sin(y),x);
B2 = int(A2,y)
B2 = 
You see, the integration constant of your method is x+y.
All I want to say is:
Each integration gives its individual integration constant. For the differential equation
d/dx (d/dy(F(x,y))) = x+y
e.g., the "integration constants" are functions of the form
G(x,y) = g1(x) + g2(y)
unless you fix F on a curve in the (x,y) plane (not parallel to one of he coordiante axes).
Some integration constants look more plausible, others less.
And now I will be quiet and you can have "the last word", if you want.

댓글을 달려면 로그인하십시오.

카테고리

Help CenterFile Exchange에서 Calculus에 대해 자세히 알아보기

태그

제품


릴리스

R2022a

Community Treasure Hunt

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

Start Hunting!

Translated by