# Tag Info

8

The conceptually easiest option (as you mentioned) is to make y a function of x and use the partial derivative operator D[] In[1]:= D[x^2/a^2 + y[x]^2/b^2 == 100, x] Solve[%, y'[x]] Out[1]= (2 x)/a^2 + (2 y[x] y'[x])/b^2 == 0 Out[2]= {{y'[x] -> -((b^2 x)/(a^2 y[x]))}} But for more complicated relations, it's best to use the total derivative ...

6

I assume that you're trying to find the exact derivative of a function. (Symbolic differentiation) You need to parse the mathematical expression and store the individual operations in the function in a tree structure. For example, x + sinĀ²(x) would be stored as a + operation, applied to the expression x and a ^ (exponentiation) operation of sin(x) and 2. ...

6

These are just some quick-and-dirty suggestions. Hopefully somebody will find them helpful! 1. Do you have a symbolic function or a set of points? If you have a symbolic function, you may be able to calculate the derivative analytically. (Chances are, you would have done this if it were that easy, and you would not be here looking for alternatives.) If ...

5

There are a couple things that might be going on. You don't mention re-normalizing that quaternion. Bad things will definitely happen if you're not doing that. You also don't say that you multiply the delta-quaternion components by the amount of time that has passed dt before you add them to the original quaternion. If your angular velocity is in radians ...

4

There is probably a cleaner way to do s, but if it's purely for presentation purposes, you could do something like pdConv[f_, vv_] := Module[{v}, (HoldForm[ Evaluate@ TraditionalForm[((f /. Thread[vv -> #]) /. Derivative[inds__][g_][vars__] :> Apply[Defer[D[g[vars], ##]] &, ...

4

you need to remember your calculus. basically you need two things: table of derivatives of basic functions and rules of how to derivate compound expressions (like d(f + g)/dx = df/dx + dg/dx). Then take expressions parser and recursively go other the tree. (http://www.sosmath.com/tables/derivative/derivative.html)

4

Here is how I implemented this in case anyone else is trying to do this (I have limited it to 2-button combos but I could easily extend the logic to 3 & 4-button combos as well). I chose to handle each touch individually using the ccTouchBegan/Ended/Moved instead of using the ccTouchesBegan/Ended/Moved because I just couldn't get it to work with the ...

4

Suppose you have two touches. You get a touch down event for the two, say at (1,1) and (2,2). Let's say the user the sides both fingers, you then get another event, but this time maybe at (3,3) and (4,4). The question is, did (1,1) move to (3,3) and (2,2) move to (4,4) - or did the opposite happen - where (1,1) moved to (4,4) and (2,2) moved to (3,3). This ...

4

Parse your string into an S-expression (even though this is usually taken in Lisp context, you can do an equivalent thing in pretty much any language), easiest with lex/yacc or equivalent, then write a recursive "derive" function. In OCaml-ish dialect, something like this: let rec derive var = function | Const(_) -> Const(0) | Var(x) -> if x = ...

4

You're using the vertex positions for normals? This will work only (and only) for a unit radius sphere! You need to calculate the normal. That is The nice thing about a torus is, that you can evaluate this easily on paper, giving you an exact formula, instead of working with a numerical approximation.

4

Because 1:1:(size(velocity)-1) does not do what you want it to. velocity is an 1xN array, size(velocity) therefore returns [1 N]. The colon operator only cares about the first value in the array and the array you want to loop over ends up being empty since 1:1:[1 N]-1 == 1:1:1-1 == 1:1:0 == Empty matrix Due to problems like these you should always use ...

4

I cannot find any faults in that. The first value returned, on the first call will be (ABuffer[0] - 0.0) / dt which is based on the assumption that the signal starts with a zero. I presume that is what you intend. Now, rather than asking the Stack Overflow community to check your code, you can do much better yourself. You should test the code to prove it ...

4

After reading this question I have implemented this functionality in Sympy and it is currently available in: my branch: https://github.com/bjodah/sympy/tree/finite_difference sympy master (https://github.com/sympy/sympy), and will be availble in 0.7.6 Here is an example: >>> from sympy import symbols, Function, as_finite_diff >>> x, h = ...

3

The reason is that because the function is concave (or convex if you're doing maximisation---these problems are equivalent), you know that there is a single minimum (maximum). This means that there is a single point where the gradient is equal to zero. There are techniques that use the function itself, but if you can compute the gradient, you can converge ...

3

At the beginning your question seem a bit vague (although we did offer more specifics later). There is a deriv function that allows simple symbolic differentiation. Since you did not offer any data at first, I assumed symbolic results were you wanted until the second comment. ex <- expression( x^2*y, 5*x+sin(y) ) sapply(ex, deriv, c("x", "y") ) ...

3

Structured document look for: ClinicalDocument/component/structuredBody Blob - unstructured look for: ClinicalDocument/component/nonXmlBody Use nonXmlBody/text to include blob or reference using the ED datatype

2

(1) Generic analytic ODE solver is not possible. (2) If you're given an n-th order ODE you can convert it into n 1st order ODE, e.g. y'' + 2y' + 3y + 4 = 0 now let z = y', you've got a coupled 1st order ODE: z' = -2z - 3y - 4 y' = z (3) For C, try GSL: http://www.gnu.org/software/gsl/manual/html_node/Ordinary-Differential-Equations.html.

2

SLaks already described the procedure for symbolic differentiation. I'd just like to add a few things: Symbolic math is mostly parsing and tree transformations. ANTLR is a great tool for both. I'd suggest starting with this great book Language implementation patterns There are open-source programs that do what you want (e.g. Maxima). Dissecting such a ...

2

This is not at all about javascript, actually. Reducing the separation between the points will not increase you precision of the derivative. The values of the function in the close points will be computed with some error in the last digits, and finally your error will be much larger than the point separation. Then you divide very small difference which ...

2

This method uses unsafe code, assuming bitmaps are the same size and are 4 bytes per pixel. Rectangle bounds = new Rectangle(0,0,bitmapA.Width,bitmapA.Height); var bmpDataA = bitmapA.LockBits(bounds, ImageLockMode.ReadWrite, bitmapA.PixelFormat); var bmpDataB = bitmapB.LockBits(bounds, ImageLockMode.ReadWrite, bitmapB.PixelFormat); const int height = 720; ...

2

Differential operators do not exist in the core of SymPy, and even if they existed "multiplication by an operator" instead of "application of an operator" is an abuse of notation that is not supported by SymPy. [1] Another problem is that SymPy expressions can be build only from subclasses of sympy.Basic, so it is probable that your class D simply raises an ...

2

Why is the arg ordering important for it to be correct? The only way to prevent this is to set your symbols to be non-commutative (x = Symbol('x', commutative=False)). SymPy objects compare by comparing the args, so for x*y*z == y*x*z to work, the args have to be sorted canonically. There have been some attempts to get this working without explicit ...

2

In your while loop: x = xold - ((cos(xold)-pow(xold,3))/(-sin(xold)-(3*pow(xold,2)))); the value of the = right operand is always the same, how could you exit the loop once you enter it?

2

Here's a different approach using a simplification rule for "if" expressions. The unsolved part here is to detect discontinuities and generate delta functions for those locations. If you want to ignore those, you can define FOO to return 0. Note that I didn't attempt to implement the function discontinuities; that part is unsolved here. I can give it a try ...

2

None of those. This is the correct expression: D(expression(3*x*cos(x*y)),"x") #3 * cos(x * y) - 3 * x * (sin(x * y) * y) This treats xy as one variable: D(expression(3*x*cos(xy)),"x") #3 * cos(xy) This treats xy as one variable and cos as a variable (and not a function): D(expression(3*x*cos*(xy)),"x") #3 * cos * (xy) This treats cos as a ...

2

The following thread from the Apache mailing list seems to illustrate the two possible ways of how the derivative of a UnivariateDifferentiableFunction can be defined. I am adding a new answer as I'm unable to comment on the previous one (insufficient reputation). The used sample specification of the function is f(x) = x^2. (1) Using a DerivativeStructure: ...

2

You could proceed along the array t and look for points where the values change sign. That would indicate the presence of a zero. Actaully, MATLAB's fzero function uses a similar method. You said you didn't use it because you required an array, rather than an anonymous function, but you could convert the array into an anonymous function using simple linear ...

2

To solve the problem, matlabFunction was required. The solution looks like this: syms x y f = @(x, y) x.*y.^2; Df = matlabFunction(subs(diff(f,y),y,2)); Int = integral(Df , 0 , 1);

2

Use flip in conjunction with iterate: (flip diff) "x" f = diff f "x" so iterate ((flip diff) "x") f = [ f, f', f'', ...]

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