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Here, we will aim to provide you with a number of exercises and solutions with a varying degree of difficulty. There will also occur exercises that requires you to use functions that has not yet been described in Matrices and linear algebra.

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Determinant

Exercise 1: Simple matrix

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titleExercise: Simple matrix

Compute the determinant


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titleSolution: Simple matrix


Code Block
languagepy
titleSolution: Simple matrix
import numpy as np 

# Defining the matrix
A = np.array([[1, 3, 2],
            [4, 1, 3],
            [2, 5, 2]])

det = np.linalg.det(A)
print(det)


# Output:
16.999999999999993   # e.i. det(A) = 17



Exercise 2: Complex numbers

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titleExercise: Complex numbers

This example is taken from an example exam in TMA4110 - Calculus 3, check out the exam and the solution for hand calculations (only in norwegain). This is task 4.

Comput the determinant


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titleSolution: Complex numbers


Code Block
languagepy
titleSolution: Complex Numbers
import numpy as np 

# Defining the matrix
# Notice how we can define complex numbers in python by adding the letter "j"
# "j" is used to denote an imaginary unit instead of "i", because Python follows engineering,
# where "i" denotes the electric current as a function of time (especially electrial engineering)
A = np.array([[3, 1-1j, 1j, 4],
            [3, 1, 1-2j, 4+7j],
            [6j, 2+2j, -2, 3j],
            [-3, -1+1j, 1, 3-4j]], dtype=complex)

det = np.linalg.det(A)
print(det)


# Output:
(-15-15j)   # e.i. det(A) = -15-15i




Eigenvalues and eigenvectors

Exercise 1

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titleExercise 1

Find the eigenvalues and corresponding eigenvectors to the following matrix:


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titleSolution


Code Block
languagepy
titleSolution


Exercise 2
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titleExercise 2
Find the eigenvalues and corresponding eigenvectors to the following matrix:

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titleSolution

 Code Block
languagepy
titleSolution


Exercise 3
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titleExercise 3
Find the eigenvalues and corresponding eigenvectors to the following matrix:

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titleSolution

 Code Block
languagepy
titleSolution



Inverse
Exercise 1
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titleExercise
Find the inverse of the matrix

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titleSolution

 Code Block
languagepy
titleSolution
import numpy as np 

A = np.array([[2, 2, 0],
            [0, 0, 1],
            [4, 2, 0]])
inv_A = np.linalg.inv(A)
print(inv_A)


# Output:
[[-0.5  0.   0.5]
 [ 1.   0.  -0.5]
 [ 0.   1.   0. ]]



Least squares solution to a linear system
Exercise 1
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titleExercise
This example is taken from an example exam in TMA4110 - Calculus 3, check out the exam and the solution for hand calculations (only in norwegain). This is task 5.
Use the least squares method to find an approximation to the linear system

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titleSolution
First, lets write the equations as matrices on the format 
, where
To solve the problem in NumPy, we will use the function numpy.linalg.lstsq (or with SciPys scipy.linalg.lstsq) which is currently not described in Matrices and linear algebra. We recommend you to read the function documentation before proceeding.
 Code Block
languagepy
titleSolution
import numpy as np 

# Defining the matrices
A = np.array([[1, 2],
            [3, 4],
            [5, 6]])
b = np.array([[1],[2],[3]])

x, residuals, rank, s = np.linalg.lstsq(A, b, rcond=None)   
# "rcond=None" sets new default for rcond, see function documentation

print(x)    # "x" is the solution


# Output:
[[-5.97106181e-17]
 [ 5.00000000e-01]]
We can interpret this such as the least squares solution is



Solving a system of linear equations
Exercise 1
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titleExercise 1
Solve the following system of linear equations:

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titleSolution

 Code Block
languagepy
titleSolution
import numpy as np 

A = np.array([[2, -4, 9],       # Right-hand side
            [4, -3, 8],
            [-2, 4, -2]])
b = np.array([-38, -26, 17])    # Left-hand side

solution = np.linalg.solve(A, b)
print(solution)


# Output:
[ 2.5  4.  -3. ]
This is interpreted as
and


Exercise 2
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titleExercise 2
Solve the following system of linear equations:

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titleSolution

 Code Block
languagepy
titleSolution
import numpy as np 

A = np.array([[1, 3, 6],       	# Right-hand side
            [2, 8, 16],
            [2, 6, 12]])
b = np.array([4, 8, 8])     	# Left-hand side

solution = np.linalg.solve(A, b)

print(solution)


# Output:
numpy.linalg.LinAlgError: Singular matrix
As we can see, using np.linalg.solve returns a LinAlgError telling us that the matrix (in this case A) is a singular matrix. A singular matrix is one that is not invertible. This means that the system of equations we are trying to solve does not have a unique solution (either none or multiple); np.linalg.solve can't handle this.
By using np.linalg.lstsq (least squares solution) instead, we will at least get one solution.
 Code Block
languagepy
titleSolution using least squares method
import numpy as np 

A = np.array([[1, 3, 6],       	# Right-hand side
            [2, 8, 16],
            [2, 6, 12]])
b = np.array([4, 8, 8])     	# Left-hand side

x, residuals, rank, s = np.linalg.lstsq(A, b, rcond=None) 
# "rcond=None" sets new default for rcond, see function documentation

print(x)    # "x" is the solution


# Output:
[4. 0. 0.]
This is interpreted as
and

 Note
Keep in mind that this is only one of multiple solutions!



 

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