Can Mathlab solve this
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Can Mathlab solve this
x1^2 +2.x1 - 2.x2^2 -5.x2 =5
2.x1^2 -3.x1 +x2^2 +3.x2 =19
2 Comments
Walter Roberson
on 3 Sep 2013
You know that has four solutions, right?
Walter Roberson
on 3 Sep 2013
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Answers (4)
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Shashank Prasanna
on 3 Sep 2013
0 votes
You can solve a system of nonlinear equations using FSOLVE:
This will yield numerical solutions for x1 and x2
3 Comments
Walter Roberson
on 3 Sep 2013
Note: fsolve() will only find one solution at a time.
rob
on 3 Sep 2013
Walter Roberson
on 3 Sep 2013
Correct, fsolve() is numeric not algebraic. However can you really make use of the algebraic solutions? For example one of the four solutions to the above system has x1 be
-349/140 + (1/5040) * (4860 * (112706532 + 2940 * 1239703701^(1/2))^(1/3) - 6 * (112706532 + 2940 * 1239703701^(1/2))^(2/3) - 754344) / (112706532 + 2940 * 1239703701^(1/2))^(1/3) - (1/90720) * ((4860 * (112706532 + 2940 * 1239703701^(1/2))^(1/3) - 6 * (112706532 + 2940 * 1239703701^(1/2))^(2/3) - 754344)/(112706532 + 2940 * 1239703701^(1/2))^(1/3))^(1/2) * 6^(1/2) * 36^(1/2) * 2^(1/2) * (((810* (112706532 + 2940 * 1239703701^(1/2))^(1/3) + 18^(1/3) * ((9392211 + 245 * 1239703701^(1/2))^2)^(1/3) + 62862) * ((4860 * (112706532 + 2940 * 1239703701^(1/2))^(1/3) - 6 * (112706532 + 2940 * 1239703701^(1/2))^(2/3) - 754344) / (112706532 + 2940 * 1239703701^(1/2))^(1/3))^(1/2) + 1764 * (112706532 + 2940 * 1239703701^(1/2))^(1/3)) * 18^(1/3) * ((112706532 + 2940 * 1239703701^(1/2))^(1/3) / (810 * (112706532 + 2940 * 1239703701^(1/2))^(1/3) - (112706532 + 2940 * 1239703701^(1/2))^(2/3) - 125724))^(1/2) * ((9392211 + 245 * 1239703701^(1/2))^2)^(1/3) * 6^(1/2) / (9392211 + 245 * 1239703701^(1/2)))^(1/2) + (1/30240) * (1620 * (112706532 + 2940 * 1239703701^(1/2))^(1/3) * ((4860 * (112706532 + 2940 * 1239703701^(1/2))^(1/3) - 6 * (112706532 + 2940 * 1239703701^(1/2))^(2/3) - 754344) / (112706532 + 2940 * 1239703701^(1/2))^(1/3))^(1/2) + 2 * ((4860 * (112706532 + 2940 * 1239703701^(1/2))^(1/3) - 6 * (112706532 + 2940 * 1239703701^(1/2))^(2/3) - 754344) / (112706532 + 2940 * 1239703701^(1/2))^(1/3))^(1/2) * 18^(1/3) * ((9392211 + 245 * 1239703701^(1/2))^2)^(1/3) + 125724 * ((4860 * (112706532 + 2940 * 1239703701^(1/2))^(1/3) - 6 * (112706532 + 2940 * 1239703701^(1/2))^(2/3) - 754344) / (112706532 + 2940 * 1239703701^(1/2))^(1/3))^(1/2) + 3528 * (112706532 + 2940 * 1239703701^(1/2))^(1/3)) * 6^(1/2) * ((112706532 + 2940 * 1239703701^(1/2))^(1/3) / (810 * (112706532 + 2940 * 1239703701^(1/2))^(1/3) - (112706532 + 2940 * 1239703701^(1/2))^(2/3) - 125724))^(1/2) * 18^(1/3) * ((9392211 + 245 * 1239703701^(1/2))^2)^(1/3) / (9392211 + 245 * 1239703701^(1/2))
Would your work seriously be affected if all those 112706532 where 112706533 instead? (That would make a difference in the 6th decimal place.)
Roger Stafford
on 3 Sep 2013
It is useful to know how to solve such equations by hand rather than always depending on matlab. The trick is to eliminate either the x1^2 term or the x2^2 term by combining the equations appropriately. If we double the second equation and then add the equations, we get
5*x1^2-4*x1+x2 = 43
which can be solved for x2
x2 = -5*x1^2+4*x1+43
You can then substitute this value of x2 into either one of the original equations and get a fourth degree polynomial equation in x1. The four roots of this can be obtained with matlab's 'roots' program (we need matlab after all) and then corresponding values of x2 from these with the above equation.
7 Comments
Walter Roberson
on 3 Sep 2013
roots() will give numeric answers in decimal form that approximate the solutions.
MATLAB's symbolic toolbox will not expand symbolic solutions to quartics by default but it can be made to do it.
rob
on 3 Sep 2013
Walter Roberson
on 3 Sep 2013
Possibly, under some restrictions on the combinations of coefficients. In the general case, if you have any power 5 or higher then algebraic solutions can usually not be found. With lower powers it would depend in part on the cross-product terms as to whether there is an algebraic solution or not.
rob
on 3 Sep 2013
Walter Roberson
on 3 Sep 2013
You have not defined "it" sufficiently for an answer.
In your example, each variable appears only in the first or second degree, and never in the third degree or higher, and never any fractional or negative exponent. The constant multipliers and the value equated to are all rational and integer in your example. Your example also has no cross-products, no occurrence of x1^n * x2^m for n, m > 0. Effectively, each of your entries is the sum of exactly two quadratic equations with integer coefficients.
in the 3 x 3 and larger versions, which (if any) of those conditions is modified? Is each entry in the 1000 x 1000 still the sum of exactly two quadratic equations in integer coefficients?
rob
on 4 Sep 2013
Walter Roberson
on 4 Sep 2013
Edited: Walter Roberson
on 4 Sep 2013
Suppose you had
a = b^2 + d
b = c^2
c = d^2
then a = d^8 + d, and that has no closed-form solution for d in terms of a. Therefore the generalized 3 x 3 or larger is not always resolvable to algebraic solutions. However, if the forms of the equations are constrained, so that one was not working with the generalized form, then it might be possible to find algebraic solutions; that would vary with the exact constraints.
Edwin
on 17 Sep 2022
0 votes
solve('6/(1-x^2) =5/(1+x) - 3/(1-x)')
Check for incorrect argument data type or missing argument in call to function 'solve'.
1 Comment
syms x
solve(6/(1-x^2) == 5/(1+x) - 3/(1-x))
Historically, solve() used to support character vectors like you show, but that changed around R2017b or so.
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on 17 Sep 2022
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