# Converging to 2 different values

I have a piece of code that basically solves a system of 2 non-linear equations using a numeric approximation method.

Code:

``````l1 = 8
l2 = 10
x2 = 12.66
y2 = 11.928
maxError = 1e-30
maxIterations = 100

theta = 1: 0, 2: 0
theta1 = 0
theta2 = 0
i = 0
loop # Block 1
i++
theta1 = Math.acos (x2 - l2 * Math.cos theta2) / l1
theta2 = Math.asin (y2 - l1 * Math.sin theta1) / l2
break if Math.sqrt(Math.pow(theta[1] - theta1, 2) + Math.pow(theta[2] - theta2, 2)) <= maxError or i is maxIterations
theta = 1: theta1, 2: theta2
console.log "Converged to first solution {theta1: #{theta1 * 180 / Math.PI}, theta2: #{theta2 * 180 / Math.PI}} in #{i} iterations."

theta = 1: 0, 2: 0
theta1 = 0
theta2 = 0
i = 0
loop # Block 2
i++
theta2 = Math.acos (x2 - l1 * Math.cos theta1) / l2
theta1 = Math.asin (y2 - l2 * Math.sin theta2) / l1
break if Math.sqrt(Math.pow(theta[1] - theta1, 2) + Math.pow(theta[2] - theta2, 2)) <= maxError or i is maxIterations
theta = 1: theta1, 2: theta2
console.log "Converged to second solution {theta1: #{theta1 * 180 / Math.PI}, theta2: #{theta2 * 180 / Math.PI}} in #{i} iterations."
``````

Output:

``````Converged to first solution {theta1: 60.004606260047474, theta2: 29.99652810779697} in 34 iterations.
Converged to second solution {theta1: 26.584939314539064, theta2: 56.593017466789554} in 35 iterations.
``````

The 2 equations are:

``````8cos(θ₁) + 10cos(θ₂) = 12.66
8sin(θ₁) + 10sin(θ₂) = 11.928
``````

In both the blocks (Block 1 and Block 2), `θ₁` and `θ₂` both are set to `0` initially. Then one θ is substituted in one of the equations to find a value for the other θ. This 2nd θ is then substituted in the other equation to find a value for the first θ. This is done recursively, converging at `θ₁` and `θ₂`.

In the first block, I start with substituting `θ₂` as `0` and finding a value for `θ₁`. Vice-versa in the second block.

Now my question is, Why do I end up with 2 different solutions when the only difference between the blocks is the starting variable?

PS: I do understand that there would be 2 different solutions for the given set of equations. What I don't understand is the reason for arriving at the 2 different solutions just because I'm using different starting variables.

PPS: I did try starting with different initial values for `θ₁` and `θ₂` instead of `0`. That didn't change anything.

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You can analyze your methods as a kind of fixed-point method. A fixed-point method is one such that

``````v_{n+1} = f(v_{n})
``````

``````v = (θ₁,θ₂)
``````

and you rearranged your equations such that

``````f(v) = (acos(x₂ - l₂*cos(θ₂))/l₁, acos(y₂ - l₁*cos(θ₁))/l₂)
``````

...more or less. As you use the already updated variable at the second calculation, it is the same as if you started with another `v0`, one where the second calculated variable is "one step ahead" the other. In the first case, your starting position is `(0,acos(y₂ - l₁)/l₂)`, and in the second in the starting position `(acos(x₂ - l₂)/l₁, 0)`. Despite what you said in your post-post-scriptum, it is a case of converging to different roots with different initial values.

It's hard to state why this happens. The basin of attraction of a root may have a weird boundary, as shown in the Newton-Raphson page in Wikipedia. You could try plotting the basins, selecting lots of initial starting points in your (θ₁,θ₂) domain and painting pixels of different colors depending to where they converge to.

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