# 2D Bisection Method - Roots Finding

I'm trying to use a Bisection Method to solve two highly nonlinear equations. Let us say; `f(x,y) = 0` with degree eight and `g(x,y) = 0` with degree six;

I need a matlab code for 2D Bisection Method to solve `f(x,y) = 0` and `g(x,y) = 0` and find all possible roots.

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This question appears to be off-topic because it is about you wanting us to do your work. – Stewie Griffin Jan 17 '14 at 12:39
@Robert: First, this is a general problem. solving this problem will help many people. Second, I do my work by myself; but I'm not a mathematician; this is why I asked this question. Third, this problem is not off-topic; If you don't understand the question or/and don't know the solution; keeping silence is better. – CS2013 Jan 17 '14 at 14:44
"Off-topic" might seem like a strange choice of words, but in SO context it actually isn't. There has always been a closing reason stating: "This question is off-topic: Questions asking for code must demonstrate a minimal understanding of the problem being solved. Include attempted solutions, why they didn't work, and the expected results." I believe your question falls under that category. "I need a code for ..." is asking us to write you a code, and not you trying to do it yourself. If you have tried some yourself, please share and we can try to help you out. Good luck! – Stewie Griffin Jan 17 '14 at 15:17
I made my question straightforward. I know that there is a solution for 1D Bisection Method and it's a trivial problem. no need to write or explain the solution in 1D. But I did not find any example/code to solve two highly nonlinear equations. This is the reason of asking such question; I hope some mathematician done this before. – CS2013 Jan 17 '14 at 15:35

Your idea does not work. With two polynomials in two variables you entered the area of algebra with Gröbner bases, resultants, Bezout theorems and solutions at infinity.

The Bezout theorem tells you that there are at most 6*8=48 solutions, real and complex. I do not think that matlab has a Gröbner package, use Maple, Magma or Singular for that.

With resultants one can reduce the number of variables. The resultant for x of f and g is a univariate polynomial in y that then can be solved by standard methods. It is the determinant of the Sylvester matrix containing polynomials in y, in principle one should be able to evaluate this in matlab, but it's not very practical.

The idea of resultants lends itself (over not that obvious detours) to homotopy methods. This was extensively done for fully numerical methods by Verschelde, Wampler et al.

If I remember correctly, the initial solvable problem for the homotopy is constructed by considering

``````g0(x,y)=(y-a1*x-b1)*...*(y-a6*x-b6)
``````

with random coefficients a1,..,a6,b1,...,b6. Then the initial solutions can be determined for every linear factor of g0 from the univariate polynomials

``````0=f1(x)=f(x,a1*x+b1),..., 0=f6(x)=f(x,a6*x+b6)
``````

using Jenkins-Traub or Laguerre, giving roots xjk and yjk=aj*xjk+bj. Bisection or quadrisection of the complex plane is not very helpful, but exists. See the work of Yakoubsohn and Didieu.

Now introduce a homotopy parameter t going from 0 to 1 in a straight line or a curve t=s+c*s*(1-s), s in [0,1], c random small imaginary, in the complex plane and consider the systems

``````0=f(x(t),y(t)),
0=t*g(x(t),y(t))+(1-t)*g0(x(t),y(t)),
``````

starting with x(0)=xjk and y(0)=yjk for all j=1,...,6, k=1,...,8.

For general values of the coefficients, the paths that are followed will not intersect, thus are regular from start to end, and all roots can be found. One tricky part is to decide that when a path drifts away if it is because of a very large solution or a non-solution at infinity.

Another homotopy starts with computing the roots x1,...,x8 of f(x,y0) for a fixed arbitrary y0 and then the roots y11,...,y61, y12,...,y68 of g(x1,y),...,g(x8,y). The homotopy is then given as

``````0=f( x(t), (1-t)*y0+t*y(t)),
0=g( x(t), y(t)),
``````

where x(0)=xk and y(0)=yjk.

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Thanks for the answer. What is the minimum and the maximum number of roots that we get from solving those two nonlinear equations (with degree eight and six, respectively)? Is the minimum eight roots and the maximum the lowest common denominator (in this case 24) ? – CS2013 Jan 17 '14 at 16:47
No, the maximum is 48, assuming that there is no common divisor. As example just take f only depending on x and g only on y, so that the common solution pairs are the cross product of both solution sets. The minimum number is zero, as an example take f(x,y)=g(x,y)*(1+x^2+y^2)+1. Then f(x,y)=1 whenever g(x,y)=0, so that there are no common solutions. – LutzL Jan 17 '14 at 19:33