Problem 1. Write a module symtoep
for creating various symmetric Toeplitz matrices with the following functions:
general(L)
that returns a symmetric Toeplitz matrix with the first row equal to the elements of the list L
.
tridiagonal(n, d, sd)
that returns a tridiagonal symmetric Toeplitz matrix of order n
, with the float number d
on the diagonal and the float number sd
right below and above it (the rest of the elements are zero).
filled(n, d, nd)
that returns a symmetric Toeplitz matrix of order n
, with the float number d
on the diagonal and all the non-diagonal elements equal to nd
.
menu()
that displays a choice
Load a symmetric Toeplitz matrix:
1. General symmetric Toeplitz matrix
2. Tridiagonal symmetric Toeplitz matrix
3. Filled symmetric Toeplitz matrix
Your choice (1-3):
and asks the user to choose. Then,
"1"
, the function asks for a list L
of numbers (preferably as a string of comma-separated floats, but you can use some other method as well), and then returns general(L)
,"2"
, the function asks for an integer n
and floats d
and sd
, and returns tridiagonal(n, d, sd)
."3"
, the function asks for an integer n
and floats d
and nd
, and returns filled(n, d, sd)
.When run like a program, this module should do nothing.
Toeplitz matrices are those that have constant elements on all diagonals.
All the functions have to return the matrices as NumPy
's matrix
type, which is easily created from a list or any other two-dimensional array-like type, using the function numpy.matrix
. For example, the first of the three matrices shown above can be created as follows:
In [1]:
import numpy as np
L = list(range(1,6))
res = list()
for i in range(5):
row = list()
for j in range(5):
row.append(L[abs(i-j)])
res.append(row)
res = np.matrix(res)
print(res)
It can be done more easily using a generator expression:
In [2]:
import numpy as np
L = list(range(1,6))
res = np.matrix([[L[abs(i-j)] for i in range(5)] for j in range(5)])
print(res)
You may implement the functions tridiagonal(n, d, sd)
and filled(n, d, nd)
either on their own or simply by creating L
and calling general(L)
. The former approach is prefered, in which case numpy.zeros
, numpy.ones
, numpy.fill_diagonal
, and numpy.tri
may help you, along with the matrix addition (done with the usual plus +
operator) and multiplication with a constant (done with the usual multiplication *
operator). These functions are much faster than setting the elements index by index, but you are free to work without them.
Problem 2. Using the module symtoep
, write a program that loads a matrix (one of the 3 supported types), and then prints it and its eigenvalues.
To compute the eigenvalues of a symmetric matrix, use scipy.linalg.eigvalsh
. If, for some reason, SciPy doesn't work, use numpy.linalg.eigvalsh
.
Ideally, make your program run properly with either (but this is not a must). For example,
try:
import scipy.linalg as la
except ImportError:
import numpy.linalg as la
...
print(la.eigvalsh(A))
Problem 3. Using the module symtoep
, write a program that loads a matrix (one of the 3 supported types), and then prints it and a message explaining if it is positive semidefinite or not.
To test positive semidefiniteness, try to compute the Cholesky factorization, using either scipy.linalg.cholesky
or numpy.linalg.cholesky
. If the computation fails (i.e., a numpy.linalg.linalg.LinAlgError
exception is raised), the matrix is not positive semidefinite. Otherwise, it is.
The same remarks from Problem 2 regarding the import of SciPy/NumPy modules apply.