# Tag Info

## New answers tagged solver

0

The problem is indeed in your validity checker, specifically in that your bottowRow is never valid. On the first run you generate a 5 character string which is invalid, then you start again but you never reset that string and instead keep appending to it so it constantly grows. I modified your programme to output every bottom row it checks and this is ...

0

I've selected the above as it provides a working solution. Just to add to it, I've had to modify the model as it seems that the ValueOf property will not accept range as input, I've had to rework my module to make it return 0 when conditions are met. The iteration part of the above answer is fine and I've accepted this as an answer.

1

You can use the Address property of the Range object to loop through all 300 columns. First you need 3 variables to hold locations of SetCell, ValueOf, and ByChange. Dim setCellRange as Range, valueOfRange as Range, byChangeRange as Range Set setCellRange = ActiveSheet.Range("B20") Set valueOfRange = ActiveSheet.Range("B3") Set byChangeRange = ...

0

In my experience, non-linear equations are solved by linearizing to solve for a temperature increment and iterating to convergence using something like Newton Raphson solver. So if you're using an implicit integration schema, you have an outer time step solution with an inner non-linear solution for the temperature step over the time step.

1

If you have an instance of ab_semigroup_mult or ab_semigroup_add than adding ac_simps to the simpset often does the trick. For example, if I replace your above goal by the following (since I get a syntax error with ⊔): lemma fixes ccProd :: "_ ⇒ _ ⇒ 'a::ab_semigroup_add" shows "ccProd {x} (set xs) + (ccProd {x} (set ys) + (ccFromList xs + (ccFromList ...

3

Reasoning upto associativity and commutativity is usually done in Isabelle with the simplifier and ordered rewriting. In your example, you provide the simplifier with the associativity rule (oriented from left to right), the commutativity rule, and the left-commutativity rule. The details are explained in the Tutorial on Isabelle/HOL (Section 9.1, ...

0

Try different starting values (initScal) than zero; the sum( w * 0^2) = 0 for all w.

0

If you rewrite the matrix entries in terms of exp and don't check the answer, it works well: >>> print(filldedent( ... solve(s.applyfunc(lambda x:x.rewrite(exp)).subs({x:2,y:0}), q0, q1, check=0))) [(0, 0), (zoo, pi), (pi, 0), (-I*log(-sqrt(exp(zoo))), zoo), (-I*log(sqrt(exp(zoo))), zoo)]

0

Since symbolic solutions are supported, one thing you can do is solve the generic quadratic and substitute in your specific coefficients: >>> eq = eq23.lhs-eq23.rhs >>> a,b,c = Poly(eq,c3).all_coeffs() >>> var('A:C') (A, B, C) >>> ans=[i.xreplace({A:a,B:b,C:c}) for i in solve(A*x**2 + B*x + C,x)] >>> print ...

1

Here is a partial solution: import sympy as sy q0, q1, x, y = sy.symbols('q_0,q_1,x,y', real=True, positive=True) cq0, cq1, sq0, sq1 = sy.symbols('cq0, cq1, sq0, sq1', real=True) s = sy.Matrix([sy.Eq(x - sy.cos(q0) - sy.cos(q0 + q1), 0), sy.Eq(y - sy.sin(q0) - sy.sin(q0 + q1), 0)]) # Matrix([ # [x - cos(q_0) - cos(q_0 + q_1) == 0], # [y - ...

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