# Tag Info

14

The command you need (since version 7) is VectorPlot. There are good examples in the documentation. I think the case that you're interested in is a differential equation y'[x] == f[x, y[x]] In the case you gave in your question, f[x_, y_] := y Which integrates to the exponential In[]:= sol = DSolve[y'[x] == f[x, y[x]], y, x] Out[]= {{y -> ...

12

Your RK4 function is taking fixed steps that are much smaller than those that ode45 is taking. What you're really seeing is the error due to polynomial interpolation that is used to produce the points in between the true steps that ode45 takes. This is often referred to as "dense output." When you specify a TSPAN vector with more than two elements, Matlab's ...

10

The key points have already been mentioned by hammar and by Philip JF. But let me collect them and add a little bit of explanation nevertheless. I will proceed from top to bottom. data EulerState = EulerState !Double !Double !Double !Double Your type has strict fields, so whenever a object of that type is evaluated to WHNF, its fields are also evaluated ...

9

Time-series differential equations can be simulated numerically by taking dt = a small number, and using one of several numerical integration techniques e.g. Euler's method, or Runge-Kutta. Euler's method may be primitive but it works OK for some equations and it's simple enough that you might give it a try. e.g.: S'(t) = - l(t) * S(t) I'(t) = l(t) ...

9

import scipy.integrate as integrate import matplotlib.pyplot as plt import numpy as np pi = np.pi sqrt = np.sqrt cos = np.cos sin = np.sin def deriv_z(z, phi): u, udot = z return [udot, -u + sqrt(u)] phi = np.linspace(0, 7.0*pi, 2000) zinit = [1.49907, 0] z = integrate.odeint(deriv_z, zinit, phi) u, udot = z.T # plt.plot(phi, u) fig, ax = ...

8

The time variable in Modelica is called time and it is accessible in any model or block (but not packages, record, connectors or functions). Also, instead of using the start attribute I suggest using initial equations. So your complete model would look like this: model FirstOrder Real x; initial equation x = 1; equation der(x) = time; end ...

8

Just a quick check: RT = 1 R = 1 FUNC = NDSolve[{D[T[x, y, t], t] == RT*(D[T[x, y, t], x, x] + D[T[x, y, t], y, y]), T[x, y, 0] == 0, T[0, y, t] == R*t, T[9, y, t] == R*t, T[x, 0, t] == R*t, T[x, 9, t] == R*t}, T, {x, 0, 9}, {y, 0, 9}, {t, 0, 6}]; a = Table[ Plot3D[T[x, y, t] /. FUNC, {x, 0, 9}, {y, 0, 9}, Mesh -> 15, ...

8

Your problem is that Plot[] does some funny things to make plotting more convenient, and one of the things it does is just not plot things it can't evaluate numerically. So in the expression you posted, Plot[x[t], {t, 0, 10}] just goes ahead and evaluates before doing the rule substitution with the solution from NDSolve, producing a graphics object of an ...

8

There is no "fastest library for solving differential equations". There is no one method that gives suitable answers for all differential equations(1), much less one that is fastest. This question is more-or-less akin to asking "what vehicle is fastest for the following tasks: going to town for coffee, crossing the atlantic, mowing the lawn, grooming a ski ...

7

Depends on which PDEs you want to solve and how you want to approach them. Every approach that I know of will require linear algebra. You'll want to find a good matrix package for .NET, the best you can find, one that can handle sparse matricies efficiently. Linear elliptic (steady state diffusion), parabolic (transient diffusion), and hyperbolic (F= MA ...

7

As you've shown, you can write this as a system of six first-order ode's: x' = x2 y' = y2 z' = z2 x2' = -mu / np.sqrt(x ** 2 + y ** 2 + z ** 2) * x y2' = -mu / np.sqrt(x ** 2 + y ** 2 + z ** 2) * y z2' = -mu / np.sqrt(x ** 2 + y ** 2 + z ** 2) * z You can save this as a vector: u = (x, y, z, x2, y2, z2) and thus create a function that returns its ...

6

I can suggest a way to reduce your equation to an integral equation, which can be solved numerically by approximating its kernel with a matrix, thereby reducing the integration to matrix multiplication. First, it is clear that the equation can be integrated twice over x, first from 1 to x, and then from 0 to x, so that: We can now discretize this ...

6

Actually, with a small modification your code does work. FUNC = T /. NDSolve[{ D[T[x, y, t], t] == (D[T[x, y, t], x, x] + D[T[x, y, t], y, y]), T[x, y, 0] == 100, T[0, y, t] == 90, T[9, y, t] == 90, T[x, 0, t] == 90, T[x, 9, t] == 90}, T, {x, 0, 9}, {y, 0, 9}, {t, 0, 10}][[1]] Modifications are the T/. (ReplaceAll) part in front ...

6

First, you have to reduce the order. Let z = y' => z' = y" Your ODE then becomes z' = sqrt(-2*z - 3*y + sin(x)), with z(0) = 0 y' = z, with y(0) = 1 You can now write a function in MATLAB to represent this ODE: (where M = [ z y ]') function dMdx = odefunc(x,M) z = M(1); y = M(2); dMdx(1) = sqrt(-2*z - 3*y + sin(x)); dMdx(2) = z; end ...

6

As Barton Chittenden noted in a comment, the pendulum should keep going in the absence of friction. This is expected. As for why it slows and stops when you use the Euler method, that's touching on a subtle and interesting subject. A (ideal, friction-free) physical pendulum has the property that energy in the system is conserved. Different integration ...

6

I got a nice boost by applying a worker-wrapper transformation to runEuler. runEuler :: EulerState -> EulerFunction -> Double -> Double -> EulerState runEuler s f dt limit = go s where go s@(EulerState _ _ _ t) = if t < limit then go (euler s f dt) else s This helps f get inlined into the loop (which probably also happens in the C ...

5

That's a first order ODE. There's an analytical solution for it (just use an integrating factor). No integration required. http://www.math.hmc.edu/calculus/tutorials/odes/ However, if you want to solve it in MATLAB: >> k15 = 0.2; k16 = 0.3; % type your constants here >> a = @(t) t^2; % type your expression for a here >> dbdt = @(t,b) ...

5

If you need to solve large nonlinear systems (especially stiff ones), the scipy tools will be slow and awkward. The PyDSTool package is now quite commonly used in this situation. It lets your equations be automatically converted into C code and integrates them with good solvers. It's especially good if you want to define state-defined events such as ...

5

The simplest is x + abs(x), though technically abs(x) is itself piecewise. If you want something smoother, then try x^3 + abs(x^3), or any higher, odd exponent. And another option that avoids using abs and is actually continuous: x + sqrt(x^2)

5

You use SciPy's integrate, which interfaces with the standard LAPACK routines for something like this. See this tutorial, which is just one I found on Google. Here are the docs.

5

This has nothing to do with matlab, you are just trying to numerically differentiate a function twice. Depending on the behaviour of the higher (3rd, 4th) derivatives of the function this will or will not yield reasonable results. You will also have to expect an error of order |T3 - T1|^2 with a formula like the one you are using, assuming L is four times ...

5

I don't have a functioning LLVM at the moment, but I get within a factor of two by Using -O2 instead of -O3 in GHC (although I doubt it matters, -O3 is not maintained) Using -funbox-strict-fields Using x*x instead of x ** 2 (same as your C code) Moving your "euler function" to be an independent function the same way it is in C. ie func :: ...

5

odeint(deriv_x, xinit, t) uses xinit as its initial guess for x. This value for x is used when evaluating deriv_x. deriv_x(xinit, t) raises a divide-by-zero error since x[0] = xinit[0] equals 0, and deriv_x divides by x[0]. It looks like you are trying to solve the second-order ODE r'' = - C rhat --------- |r|**2 where rhat is the ...

4

Let's have a look at a simple example. We assume N = 3, i.e. three inner points, but we will first also include the boundary points in the matrix D2 describing the approximate second derivatives: 1 / 1 -2 1 0 0 \ D2 = --- | 0 1 -2 1 0 | h^2 \ 0 0 1 -2 1 / The first line means the approximate second derivative at x_1 is 1/h^2 * ...

4

This is complementary to Leonid Shifrin's approach. We start with a linear function that interpolates the value and first derivative at the starting point. We use that in the integration with the given kernel function. We can then iterate, using each previous approximation in the integrated kernel that is used to make the next approximation. I show an ...

4

As you asked for source code: From HERE you can download MATLAB and FORTRAN code for symplectic methods for Hamiltonian systems and symmetric methods for reversible problems. And a lot of other methods for dealing with diff equations too. And in THIS paper you can find the description of the algorithms. Edit If you use Mathematica this may help too.

4

The GNU Scientific Library has several differential equation solvers. They have one that uses Prince-Dormand. It's written in C so you shouldn't have trouble compiling it.

4

That question was asked on the time people found out that the world was spherical. They wanted to make rectangular maps of the surface of the world... It is not possible. The reason why is not possible is because the sphere has an intrinsic curvature, while the cube/parallelepiped has not. It can be shown that for two elements with different intrinsic ...

4

You can use the "class" version, but modify it so that it is initialized with the R value of interest to you. class lorenz_class { double R_; public: lorenz_class (double r) : R_(r) {} void operator()( state_type &x , state_type &dxdt , double t ) { dxdt[0] = sigma * ( x[1] - x[0] ); dxdt[1] = R_ * x[0] - x[1] - x[0] * ...

4

Few references: http://www.haskell.org/haskellwiki/Performance http://blog.johantibell.com/2010/09/slides-from-my-high-performance-haskell.html http://donsbot.wordpress.com/2010/03/01/evolving-faster-haskell-programs-now-with-llvm/ Below is evangelism representing common folklore. So take it with a grain of salt. You cannot get stable C-like performance ...

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