matrix – Proxies-free.com: 100% Free Daily Proxy Lists Every Day!

co.combinatorics – total unimodularity of a matrix

Let G be the node-arc incidence matrix of a given directed network (rows of $ G $ correspond to nodes and their columns correspond to arcs. To let $ B_1, dots, B_K $ designate a partition of the nodes of the network. Suppose the network is such that a directed arc can go in from a node $ B_k $ to another node in $ B_ ell $ only if $ k < ell $, To let $ H $ denote a matrix with $ K $ Rows and assume that its columns are indexed by the arcs of the underlying network. We assume that $ H $ is that his $ (k, e) $-th entry is equal to one $ e in B_k $and nothing else.

Is the matrix (H; G) (obtained by the concatenation of rows of $ H $ and $ G $) completely unimodular? If not, can you give a counterexample?

I numerically examined some examples and confirmed the complete unimodularity for these examples. I thought it might be possible to exploit the structure of $ H $ (Note the special line structure) to formally prove the result. I tried to use the Ghouila Houri condition (see https://en.wikipedia.org/wiki/Unimodular_matrix), which appears to be a good candidate for exploiting the line structure. So far I have not been successful.

How complex is it to find e ^ (A) for a Hermitian matrix A?

If A is a hermitic matrix of size NxN. of steps required to calculate e ^ (A).

ordinary differential equations – Calculate the determinant of a solution matrix for the following linear system.

Thank you for your reply to Mathematics Stack Exchange!

Please be sure too answer the question, Provide details and share your research!

But avoid …

Ask for help, clarify or respond to other answers.
Make statements based on opinions; Cover them with references or personal experience.

Use MathJax to format equations. Mathjax reference.

For more information, see our tips for writing great answers.

analytic geometry – semiaxes of the ellipsoid from the square matrix

In three-dimensional Euclidean space, a quadratic surface can be defined by the following analytic equation:

$$ e_1 x ^ 2 + e_5 y ^ 2 + e_8 z ^ 2 + 2 e_2 y z + 2 e_3 x z + 2 e_4 xy + 2 e_6 x + 2 e_7 y + 2 e_9 z + e_ {10} = 0 $$

or in homogeneous matrix form:

$$ texttt {x} ^ T cdot texttt {E} cdot texttt {x} =
begin {bmatrix}
x_1 & x_2 & x_3 & 1
end {bmatrix}
begin {bmatrix}
e_1 & e_2 & e_3 & e_4 \
e_2 & e_5 & e_6 & e_7 \
e_3 & e_6 & e_8 & e_9 \
e_4 & e_7 & e_9 & e_ {10}
end {bmatrix}
begin {bmatrix}
x_1 \
x_2 \
x_3 \
1
end {bmatrix}
= 0
$$

Given only the matrix $ texttt {E} $ and to know that the surface is an ellipsoid, the center $ texttt {x} _ texttt {c} $ Ellipsoid is won by
$$ texttt {x} _ texttt {c} = texttt {E} _ {33} ^ {- 1} begin {bmatrix}
e_4 \
e_7 \
e_9
end {bmatrix},
Where ,
texttt {E} _ {33} =
begin {bmatrix}
e_1 & e_2 & e_3 \
e_2 & e_5 & e_6 \
e_3 & e_6 & e_8
end {bmatrix} $$

and the rotation matrix can be extracted from normalized eigenvectors of $ texttt {E} _ {33} $,

But I do not know how to get the semi-axes of the ellipsoid. Any help grateful.

solve the equation by explaining the n * n matrix or the equation team

I want Solve n equations with the Gaussian elimination method, I have indicated root formulation and methodology in the picture. But I do not know how to do that. Should I explain n * n matrix? Or should I explain Equation team as picture above? Thanks for your help.
Enter image description here

Coordinate transformation – distance matrix within a neural network

So I want to create a NetGraph, which is a $ n times $ 3 (With $ n $ varying length) List of 3D coordinates as input and creates one $ n times n $ Distance matrix or one $ frac {n (n-1)} {2} $ List of distances between these points. I would run this net for two lists of 3D coordinates and feed the results into a MeanSquaredLossLayer. This would allow the neural network to learn to reproduce an array of points with the loss that is invariant with respect to shifts and rotations in 3D. However, I have only vague ideas about which modules to use. Maybe NetMapOperators and NetMapThreadOperators? If yes how? Thank you for the reply in advance!

Linear Algebra – What will be the third column of the given matrix?

That's the problem Enter image description here

My attempt: $ frac {1} { sqrt 2} x + 0.y + frac {1} { sqrt2} z = 0, x + z = 0, x = -z $ .

And $ frac {-1} { sqrt 3} x + frac {-1} { sqrt 3} y + frac {1} { sqrt 3} z = 0 $Now put $ x = -z $ we have $ frac {-2} { sqrt 3} x + frac {-1} { sqrt 3} y = 0 $ .$ -2x -y = 0 $. $ x = -y / 2 $

Now I take $ x = c $, then third column becomes $ begin {bmatrix} -2 \ -1 \ 2 end {bmatrix} $

Is it true?

Matrix – How do I solve a large system of differential equations with indexed functions?

I firmly believe that matrix methods are the right answer here, but I can not imagine how to set them up. Imagine a large number of coupled functions:

AB(m,n)(t)

Where m and n are integer indices that can be up to hundreds of thousands or thousands of thousands, and t is a continuous time variable. Imagine AB (m, n) as the concentration of AB of type (m, n), and these concentrations of different types can evolve over time. In addition, we have a single additional feature:

B(t)

it is also a concentration that evolves over time, but for which there is only one type. Initial conditions are:

AB(a,0)(0) = A0
AB(anythingelse)(0) = 0
B(0) = B0

Here a is a constant integer in the hundreds to thousands.

AB (m, n) can be converted into other types by two processes:

AB(m,n) + B --> AB(m-1,n+b)
AB(m,n) --> AB(m-1,n-1)

Here b is a constant integer that is significantly smaller than a. That is, the differential equations that determine the evolution of the system are:

D(AB(m, n)(t), t) == -k1(m, n) AB(m, n)(t) B(t) 
                     +k1(m + 1, n - b) AB(m + 1, n - b)(t) B(t) 
                     -k2(m, n) AB(m, n)(t) 
                     +k2(m + 1, n + 1) AB(m + 1, n + 1)(t)
D(B(t), t) == -k1(m, n) AB(m, n)(t) B(t)

Good assumptions for the forms for k1 and k2 that we can use for testing are:

k1(m_) = (m/a) k3
k2(m_, n_) = k4 n/(n + k5/m) + n k6 k1(m)

Here k3, k4, k5 and k6 are positive real numbers.

How on earth do I organize this system to solve it numerically? NDSolve (or ParametricNDSolve) or similar? The ultimate goal will be to have a measurable function that looks something like this:

Sum(m AB(m,n),{m,0,a},{n,0,infinity})

This function would then be suitable for experimental data that varies k3-k6 and possibly a and b. Later generalizations may be to have a broader distribution of starting concentrations, rather than all being identical, a range of different possible bs, etc.

Control Systems – Problem Solving the Kalman Filter in Mathematica: How to Define a Spectral Density Matrix and Calculate the Covariance Matrix?

I read the classic book on the theory of space control by Bernard Friedland.

To deepen my understanding of the Kalman filter, I would like to illustrate Example 11A Inverted Pendulum on page 418.

However, I can not find a way to define the spectral density matrices (of excitation noise and observation in equation (11A.2)) in Mathematica. How can I also calculate the covariance matrix of noise from a spectral density matrix?

Thank you very much.

Example 11A

numerical analysis – How to solve a quadratic matrix equation with a positive semidefinite constant?

I have the following quadratic matrix equation:

$ XAX + X = B $

Where $ A $ and $ B $ are all positive definite matrix.

The limitation here is that $ X $ is actually a covariance matrix and should definitely be positive.

All I have is that if there is no restriction, the equation can be solved by Bernoulli iteration in the following form:

$ X_ {k + 1} = -A ^ {- 1} (I-BX_k ^ {- 1}) $

However, this does not seem to uphold the restriction.

Any guides would be appreciated, thank you.