# Algorithm which adapt (solve) the complex equations ( implicit function f(x,y) )

I'm trying to adapt some equations (implicit f(x,y)) in order to be able list the Y for corresponding X-Value.
The equations could be e.g. as follows:

``````y^2 = x^3 + 2x - 3xy
(X^2+y^2-1)^3-x^2y^3=0
X^3+y^3=3xy^2-x-1
X^3+y^2=6xy/sqrt(y/x)
cos(PI*Y) = cos(PI.X)
``````

Below you can see the plotted equations: Hint, I don't know, but maybe this can be helpful, the following applies:

``````Y^2 + X^2 =1  ==>  Y= sqrt(1-X^2)
``````

The equations are to be adapt (substitution), so that they are expressed by X (not Y).
For y^2=x^3+2x-3xy by means of substitution results:

y1 = (-(-3x) - sqr((-3x)^2 - 4(-1)(x^3+2x)))/2*(-1)
y2 = (-(-3x) + sqr((-3x)^2 - 4(-1)(x^3+2x)))/2*(-1)

By means of adapted equations I will be able to vary X and get the corresponding Y.
See here the solution of Arkadiusz Raszeja-Solution for the equation y^2=x^3+2x-3xy

The solution of "Arkadiusz Raszeja" is for Quadratic equation, but I need an algorithm, so that e.g. all above equations can be solved.

``````var x,y;
for(var n=0; n<=10; n++) {
x=n;
y = (-(-3*x)-Math.sqrt(((-3*x)*(-3*x)) - 4*(-1)*((x*x*x)+2*x)))/(2*(-1));
}
``````

The above alert(y); will show for Y something like below list:

``````X= 1 ; Y=0.79
X=2 ; Y=1.58
X=3 ; Y=2.79
X=4 ; Y=4.39
X=5 ; Y=6.33
X=6 ; Y=8.57
X=7 ; Y=11.12
X=8 ; Y=13.92
X=9 ; Y=16.98
X=10 ; Y= 20.29
``````

My question is how can I program an algorithm, which will adapt (solve) the equations like in above example?

(You can also use a JS library like math.js, but not a plot or graph library. The solution should be in javascript)

• What is issue with using JavaScript at Question? – guest271314 Mar 28 '17 at 22:12
• I agree, the problem would be almost the same in any programming langugage. Are you asking if there are any library that would do the job ? To me, this looks like formal calculus/symbolic calculus, and this is not what I call "a simple task" to program it. – LoneWanderer Mar 28 '17 at 22:14
• I gave a look to this: mathjs.org/examples/algebra.js.html This contains basic stuff you may need. – LoneWanderer Mar 28 '17 at 22:17
• For further reading, i would suggest : stackoverflow.com/questions/7540227/… (mathjs.org algebra doc page redirects here ) (That was just my 2 min web research.) – LoneWanderer Mar 28 '17 at 22:21
• Interesting question. @user3815508, I'd be intrigued to see what you done yourself thus far? Or are you literally at square 1, wondering how to begin? – fubar Mar 28 '17 at 22:27

Hopefully I'm understanding your question correctly. Would nerdamer help? It can help solve algebraically up to a 3rd degree polynomial. The buildFunction method can be called to get a JS function which can be used for graphing. I use it in a somewhat similar manner on the project website in combination with function-plot.js

``````var solutions = nerdamer('y^2=x^3+2x-3x*y').solveFor('y');
//You'll get back two solutions since it's quadratic wrt to y
console.log(solutions.toString());
//You can then parse the solutions to native javascript function
var f = nerdamer(solutions).buildFunction();
console.log(f.toString());

/* Evaluate */
var solutions = nerdamer('y^3*x^2=(x^2+y^2-1)').solveFor('y');
console.log(solutions.toString());
//You can then parse the solutions again to native javascript function
var f = nerdamer(solutions);
var points = {};
for(var i=1; i<10; i++)
points[i] = f.evaluate({x: i}).text();

console.log(points)``````
``````<script src="http://nerdamer.com/js/nerdamer.core.js"></script>
<script src="http://nerdamer.com/js/Algebra.js"></script>
<script src="http://nerdamer.com/js/Calculus.js"></script>
<script src="http://nerdamer.com/js/Solve.js"></script>``````

You could always just evaluate. This is slower than a pure JS function but it might be what you need. You'll have to probably use a try catch block for division by zero.

• Thanks for your answer! See the Heart-Graphic: (x^2+y^2-1)-x^2*y^3=0 or x^3+y^2=(6xy/sqrt(xy)). Do have an idea how can I adapt (solve) such polynomials? because there is Y-Exponent greater than 2 or there is used an square by Y. – user3815508 Mar 29 '17 at 7:28
• I'm not sure I understand the question. Are trying to find out if the max degree of one is greater than the other? – jiggzson Mar 29 '17 at 11:45
• Are trying ... other? --> NO. I mean, if you have a complicated equation, then it will be failed. For the equation y^2=x^3+2x-3x*y is ok! But try to solve this equation y^3*x^2=(x^2+y^2-1) or these (x^2+y^2-1)-x^2*y^3=0. Sadly, then you will see that it fails (see above the equations or theirs charts). – user3815508 Mar 29 '17 at 13:09
• I see what you mean. The problem lies with the buildFunction. It doesn't know what to do when it has complex values. I'm guessing you want to graph those. – jiggzson Mar 29 '17 at 13:14
• Yes right. At the end I will plot (graph) it. Therefore all parameters must be expressed only by means of X. – user3815508 Mar 29 '17 at 13:30

I'd like to point out that this problem cannot be solved exactly in general. The cited solution for the quadratic case (y^2) can be extended to the cubic case and quartic case (there are a general complicated solutions). But there is a math theorem (from Galois theory) that states that there is no general solution for the quintic equation (and so on). In your case, maximum degree is 3, so you can use the cubic equation from wikipedia. For the heart graphic write: x^2*y^3 - y^2 -(x^2-1) = 0 and treat x as constant. For the sqrt case, get rid of it. Square both sides of equation, isolate y and you end up with a quartic equation on y, that you can solve using wikipedia's quartic equation knowledge.

Anyway, if you don't have a very strong reason to do this, don't do it, as the computer can solve this numerically for you. Standard approach is to calculate this implicitly, as in the plots you made.

I hope this helps.

There ia a possible solution for the general quintic equation, when you addapt the solutionmethod from Cardano for the general cubic equation and the solutionmethod from Ferrari for the general quartic equation.