Iterative solving for unknowns in a fluids problem

I am a Mechanical engineer with a computer scientist question. This is an example of what the equations I'm working with are like:

x = √((y-z)×2/r)
z = f×(L/D)×(x/2g)
f = something crazy with x in it
etc…(there are more equations with x in it)

The situation is this:

I need r to find x, but I need x to find z. I also need x to find f which is a part of finding z. So I guess a value for x, and then I use that value to find r and f. Then I go back and use the value I found for r and f to find x. I keep doing this until the guess and the calculated are the same.

My question is:

How do I get the computer to do this? I've been using mathcad, but an example in another language like C++ is fine.

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You won't just get a solution here, you're going to have to make an effort first. Post your code, we'll help you fine-tune and debug. –  KevinDTimm Dec 14 '10 at 17:12
Post your "crazy things" and let's see them –  belisarius Dec 14 '10 at 17:16
What your are asking for is normally a full semester class at university level. There are multiple methods to solve such equations and whole books written about this. Do you want to understand one or more iterative approximation algorithms for this, of just to solve the equations? –  thkala Dec 14 '10 at 17:18
@Alexandre-c "How do I get the computer to do this?" is clearly asking for an algorithm. The system of equations wasn't actually posted, so it's really hard to imply that OP wanted a full solution. Your ad-hominem attack on the OP is also quite inappropriate. You should also note that the OP is a SHE, not a HE. –  Jon Bringhurst Dec 14 '10 at 17:37
Come on! Here is someone that wants to learn! He/She is not asking "how 2 off log in appz " –  belisarius Dec 14 '10 at 17:46

The very first thing you should do faced with iterative algorithms is write down on paper the sequence that will result from your idea:

Eg.:

`````` x_0 = ..., f_0 = ..., r_0 = ...
x_1 = ..., f_1 = ..., r_1 = ...

...

x_n = ..., f_n = ..., r_n = ...
``````

Now, you have an idea of what you should implement (even if you don't know how). If you don't manage to find a closed form expression for one of the x_i, r_i or whatever_i, you will need to solve one dimensional equations numerically. This will imply more work.

Now, for the implementation part, if you never wrote a program, you should seriously ask someone live who can help you (or hire an intern and have him write the code). We cannot help you beginning from scratch with, eg. C programming, but we are willing to help you with specific problems which should arise when you write the program.

Please note that your algorithm is not guaranteed to converge, even if you strongly think there is a unique solution. Solving non linear equations is a difficult subject.

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It appears that mathcad has many abstractions for iterative algorithms without the need to actually implement them directly using a "lower level" language. Perhaps this question is better suited for the mathcad forums at:

http://communities.ptc.com/index.jspa

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If you are using Mathcad, it has the functionality built in. It is called solve block.

Given

define the guess values for all unknowns

x:=2 f:=3 r:=2 ...

x = √((y-z)×2/r)

z = f×(L/D)×(x/2g)

f = something crazy with x in it

etc…(there are more equations with x in it)

calculate the solution

find(x, y, z, r, ...)=

Check Mathcad help or Quicksheets for examples of the exact syntax.

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@luminara19131 this looks like your answer to me –  David Heffernan Jan 4 '11 at 22:43

``````X = startingX;
lastF = Infinity;
F = 0;
tolerance = 1e-10;
while ((lastF - F)^2 > tolerance)
{
lastF = F;
X = ?;
R = ?;
F = FunctionOf(X,R);
}
``````

This may not do what you expect at all. It may give a valid but nonsense answer or it may loop endlessly between alternate wrong answers.

This is standard substitution to convergence. There are more advanced techniques like DIIS but I'm not sure you want to go there. I found this article while figuring out if I want to go there.

In general, it really pays to think about how you can transform your problem into an easier problem.

In my experience it is better to pose your problem as a univariate bounded root-finding problem and use Brent's Method if you can

Next worst option is multivariate minimization with something like BFGS.

Iterative solutions are horrible, but are more easily solved once you think of them as X2 = f(X1) where X is the input vector and you're trying to reduce the difference between X1 and X2.

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As the commenters have noted, the mathematical aspects of your question are beyond the scope of the help you can expect here, and are even beyond the help you could be offered based on the detail you posted.

However, I think that even if you understood the mathematics thoroughly there are computer science aspects to your question that should be addressed.

When you write your code, try to make organize it into functions that depend only upon the parameters you are passing in to a subroutine. So write a subroutine that takes in values for y, z, and r and returns you x. Make another that takes in f,L,D,G and returns z. Now you have testable routines that you can check to make sure they are computing correctly. Check the input values to your routines in the routines - for instance in computing x you will get a divide by 0 error if you pass in a 0 for r. Think about how you want to handle this.

If you are going to solve this problem interatively you will need a method that will decide, based on the results of one iteration, what the values for the next iteration will be. This also should be encapsulated within a subroutine. Now if you are using a language that allows only one value to be returned from a subroutine (which is most common computation languages C, C++, Java, C#) you need to package up all your variables into some kind of data structure to return them. You could use an array of reals or doubles, but it would be nicer to choose to make an object and then you can reference the variables by their name and not their position (less chance of error).

Another aspect of iteration is knowing when to stop. Certainly you'll do so when you get a solution that converges. Make this decision into another subroutine. Now when you need to change the convergence criteria there is only one place in the code to go to. But you need to consider other reasons for stopping - what do you do if your solution starts diverging instead of converging? How many iterations will you allow the run to go before giving up?

Another aspect of iteration of a computer is round-off error. Mathematically 10^40/10^38 is 100. Mathematically 10^20 + 1 > 10^20. These statements are not true in most computations. Your calculations may need to take this into account or you will end up with numbers that are garbage. This is an example of a cross-cutting concern that does not lend itself to encapsulation in a subroutine.

I would suggest that you go look at the Python language, and the pythonxy.com extensions. There are people in the associated forums that would be a good resource for helping you learn how to do iterative solving of a system of equations.

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Not true, there are plenty of mathematicians here I'm sure. I've got a PhD in maths and I know there are an awful lot of more capable mathematicians than myself here on SO. –  David Heffernan Jan 4 '11 at 22:41