Pike Module Reference:

The imaginary unit.

Exponential of a Complex number.

A complex number x = a + ib

We can create a complex given Its real and imaginary part, or only with one argument: an array.

Returns the real part of the complex number.

Returns the imaginary part of the complex number.

a - b

We can cast a Complex number to a string in a form Real + i * Imaginary

Returns the module of a complex number.

Given a + ib, returns a -ib

This function returns the derivative of f calculated simply applying the definition, with step h

This function returns the derivative of f calculated by a better algorhytm.

Does the discrete fourier transformation of some data.

Does the inverse discrete fourier transformation of data.

Power spectrum of data. This first does a discreteFourierTransformation of data, them computes the powerSpectrum.

This function computes the Higuchi fractal dimension of a time serie.

The time serie we want to analize.

Minimum value of the paramether we have to use to compute the fractal dimension

Maximum value of the paramether we have to use to compute the fractal dimension

Percentual error of each point in serie

A function which, given a value of k, returns the next value of k to use.

Generates n points following a linear distribucion y = a x + b ;

Generates n points following a sinusoidal function. Only one period.

Generates n points from the logistic map x -> r x (1-x)

Generates n points from a random walk (also called Fractional Brownian Function ), with fractal dimension 1.5 .

This function computes the Burlaga and Klein's fractal dimension of a time serie.

The time serie we want to analize.

Minimum value of the paramether we have to use to compute the fractal dimension

Maximum value of the paramether we have to use to compute the fractal dimension

Percentual error of each point in serie

A function which, given a value of k, returns the next value of k to use.

This function computes the fractal dimension of a time serie simply using as the curve length abs( y1 - y2 ). Very primitive method, It's here only to compare with BK and Higuchi methods.

The time serie we want to analize.

Minimum value of the paramether we have to use to compute the fractal dimension

Maximum value of the paramether we have to use to compute the fractal dimension

Percentual error of each point in serie

A function which, given a value of k, returns the next value of k to use.

Generates n points from the Weierstrass function. s is the fractal dimension of the graph. lamda must be greather than 1.

Generates points following an exponential power expectrum law, where P(k) ~ k^(-exponent). The angle is picked from a Uniform distribution between 0 and angle_max (in degree).

Tries to do a log-log adjust to get the exponent from a power spectrum which follows an exponential law.

The Weierstrass function. s is the fractal dimension, lamda must be greather than one.

Uses a simple Montecarlo algorithm to integrate f in the interval .

The function to integrate

The interval ({ a, b }) where we wish to do the integral.

The number of points that the montecarlo algorithm has to use.

Returns a column Matrix from an array

A NMatrix object is a matrix.

You can create a NMatrix object giving an array or two ints: the number of rows and columns.

Using get you obtain the element at row i, column j of the NMatrix.

Returns an array ({ rows, columns })

Number of rows of a NMatrix

Number of columns of a NMatrix

Shows a NMatrix on the screen.

Multiplies a NMatrix by a scalar, multiplying all its elements by that scalar.

Returns a new NMatrix, with rows i and j swapped.

Multiplies two matrices.

a * b

a - b

a + b

a + b

a - b

Returns a new matrix, transposed of the original matrix.

Returns a NMatrix object, with the same content of the i column of the original matrix.

This does the LU decomposition of the matrix. Returns an array ({ L , U , permutation_matrix , signum })

Given the LU decomposition of a NMatrix, solves the linear equations system AX = w

Solves the linear equations system AX = w

Returns the inverse of the matrix.

Returns the determinant of a matrix.

The Runge-Kutta method. Given the point (x0 , y0) / y0 = f(x0) and the step h, solves the differential equation dy / dt = f(x,y) ;

The point where the integration begins

The point to finish the integration

The initial condition to y.

The function which gives df/dt = f(x, y) ;

This function tries to find a root of f , given the interval (a,b) where you think that It's fitted.

The function that we are tryint to find a root.

The interval ({ a, b }) where we think that the root is fitted.

The relative error that It's allowed to the solution.

The maxim number of iterations that the method can do trying to find the root.

This function tries to find a root of f using the Newton-Raphson method.

The function

The derivative of f

A point to start the method from x = point

The absolute error that we tolerate to the solution

The maximum number of iterations that we can do trying to find the root.

This function tries to find a root of f using the Newton-Raphson method.

The function

A point to start the method from x = point

The absolute error that we tolerate to the solution

This function tries to find a root of f , given the interval (a,b) where you think that It's fitted. It uses the Regula-Falsi method. The paramethers have the same meaning than in Bisection.