# Tag Info

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Here direct links to the documentation: SGEQRF DGEQRF CGEQRF ZGEQRF

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Heres a C version which uses the dominant axis to give a more deterministic result. The caller needs to normalize the result of ortho_v3_v3. inline int axis_dominant_v3_single(const float vec[3]) { const float x = fabsf(vec[0]); const float y = fabsf(vec[1]); const float z = fabsf(vec[2]); return ((x > y) ? ((x > z) ? 0 : ...

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Yes, there is similar formula for three dimensions. Solution 1 The four points are in the same plane if and only if one of the areas of the four triangles you can make has an area equal to the sum of the other three areas. Heron formula states that the area A of the triangle with vertices a, b, c is where s = 0.5( a + b + c). Thus you can ...

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Linear Diophantine equations take the form ax + by = c. If c is the greatest common divisor of a and b this means a=z'c and b=z''c then this is Bézout's identity of the form with a=z' and b=z'' and the equation has an infinite number of solutions. So instead of trial searching method you can check if c is the greatest common divisor (GCD) of a and b If ...

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Your problem is an example of a linear Diophantine equation. About that, Wikipedia says: This Diophantine equation [i.e., a x + b y = c] has a solution (where x and y are integers) if and only if c is a multiple of the greatest common divisor of a and b. Moreover, if (x, y) is a solution, then the other solutions have the form (x + k v, y - k u), where k ...

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Notlikethat's answer is the way to go. But its efficiency (computation time) can actually be improved: sA = sort([A(:); inf]); %// sort A ind = diff(sA)~=0; %// index of last element of each run of equal values elements = sA(ind); %// unique elements counts = diff([0; find(ind)]); %// lengths of runs Benchmarking: clear all A = randi(100,1e6,1); %// ...

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It'd be hard to beat this for efficiency: elements = unique(A); counts = histc(A(:), elements);

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What you are missing is This is calculated as: This means that you need just two things now: multiply matrices of difference vectors (deviations from averages) multiply the result by 1 / (N - 1), note: N - 1 to get unbiased estimates from sample I have created this spreadsheet example to show how to do it step by step.

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Alternatively, you can use, after removing the average, the SVD function, which is also contained in Jama. The eigen decomposition computes W'*W=V*D*V', while the SVD computes W=U*S*V', U, V orthogonal, S and D diagonal, with the diagonal non-negative and descending order. Comparing both, one gets W'*W=(USV')'*USV'=VSU'*USV'=VS²V' so one can recover the ...

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You may do something like this (to deal with the matrix I am importing jama). Actually eigenfaces are implemented below, because there was a problem with this function for java. private static void evaluateEigenface(int M,int N,Matrix x,double[] average,double[] eigenvalues,Matrix eigenfaces){ // x is ...

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SimpleMatrix A1 = new SimpleMatrix(m,n); SimpleMatrix b1 = new SimpleMatrix(m,1); for(int i=0;i<m;i++) { for(int j=0;j<n;j++) { A1.setRow(i, j, A2[i][j]); double value1 = A1.get(i,j); System.out.print(" "+value1); // System.out.println(); } b1.setRow(i,0, B2[i]); double ...

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I did a survey of some other libraries, and here's what I found: hmatrix - actively maintained; classes of kind * -> *, GPL licensed vect - OpenGL bindings; not actively maintained; uses hardwired scalar types so things like dot can't be lifted Vec - sort of actively maintained; not overloaded correctly (see below); useful auxiliary functions; no OpenGL ...

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Following the helpful answer of Robert_P and the comments of Parag, I found the following to be the fastest for my particular large-scale sparse data: L=chol(X'*X,'lower'); L=full(L); invXtX = L'\(L\ speye(size(X,2))); nwse = sqrt(N.*sum(invXtX.*(Q*invXtX))); The last line computes the diagonal efficiently, idea taken from here.

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I think it doesn't stand. This can be seen in terms of graphs. Matrix A is adjacency matrix of un-directed graph. For A it hold that element (i,j) of matrix A^k represent number of paths between nodes i and j of length k, and sum of a i'th row means number of paths between i and any other node of length k. Assumption is based on number of neighbours which ...

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Try this: # Initialize a testing matrix (m <- matrix(1:12, 3, 4)) [,1] [,2] [,3] [,4] [1,] 1 4 7 10 [2,] 2 5 8 11 [3,] 3 6 9 12 # Calculate cumulative average by column for each row t(apply(m, 1, cumsum) / seq(ncol(m))) [,1] [,2] [,3] [,4] [1,] 1 2.5 4 5.5 [2,] 2 3.5 5 6.5 [3,] 3 4.5 6 ...

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Using the suggested cumsum and apply mat <- matrix(1:24,ncol=6) mat # [,1] [,2] [,3] [,4] [,5] [,6] #[1,] 1 5 9 13 17 21 #[2,] 2 6 10 14 18 22 #[3,] 3 7 11 15 19 23 #[4,] 4 8 12 16 20 24 t(apply(mat,1,cumsum)/(seq_len(ncol(mat)))) # [,1] [,2] [,3] [,4] [,5] [,6] #[1,] 1 3 5 7 ...

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I believe you can save a lot of computation time by explicitly doing an LU factorization, [l, u, p, q] = lu(X'*X); and use those factors when doing the calculations. Also, since X are constant for about 100 models, pre-calculating X'*X will most likely save you some time. Note that in your case, the most time demanding operation might very well be the ...

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The context bound makes the difference: scala> val as = Array.tabulate(10,10)((x,y)=>y) as: Array[Array[Int]] = Array(Array(0, 1, 2, 3, 4, 5, 6, 7, 8, 9), Array(0, 1, 2, 3, 4, 5, 6, 7, 8, 9), Array(0, 1, 2, 3, 4, 5, 6, 7, 8, 9), Array(0, 1, 2, 3, 4, 5, 6, 7, 8, 9), Array(0, 1, 2, 3, 4, 5, 6, 7, 8, 9), Array(0, 1, 2, 3, 4, 5, 6, 7, 8, 9), Array(0, 1, ...

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There's vector-space, which is indeed in many ways more elegant than the libraries that are parameterised over their scalars (VectorSpace has that field instead as an associated type synonym). Part of what I like about it is that it's totally not based on free vector spaces as linear is, which means a signature based on Foldables wouldn't make any sense in ...

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I guess you are looking for this: clear all close all a = [4 1 -1;5 1 2;6 1 1]; b = [-2 4 6]; width = size(a,2); height = size(a,1); % forward elimination for i=1 : width for y=i+1 : height factor = a(y,i) / a(i,i); for x=i : width a(y,x) = a(y,x) - a(i,x) * factor; end end end Note also that if a is not ...

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Check out the Ryacas package: > library(Ryacas) > x <- Sym("x") > mat1 <- List(List(x, 3), List(2*x, 4)) > PrettyForm(mat1) / \ | ( x ) ( 3 ) | | | | ( 2 * x ) ( 4 ) | \ / > mat2 <- List(List(1, x/2), List(x, 3)) > PrettyForm(mat2) / \ | ( 1 ) / x \ | | | ...

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Here is a library I (and others) use quite frequently. Hope this helps! http://numericjs.com

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If I understand your intent correctly, you are trying to estimate how far apart each "group" of vectors is from the centroids of the other groups. If that is the case, it looks like you are missing a normalization factor for the number of vectors in the group. Nevertheless, you can get a good estimate of this distance by simply considering ...

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Sparse matrix support in Armadillo is not yet complete. You can use ARPACK for (eigen-)decomposition of sparse matrix. Sparse matrix solvers will probably comes in the next release which may use the CXSparse library from the SuiteSparse project.

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Since the group is abelian, the simplest thing is to use that multiplication by any element is a bijection. Let F = {g1, g2, g3, ..., gn} and let h be an arbitrary element. Then also F = {h*g1, h*g2, ..., h*gn}. Hence multiplying all elements together we get g1 * g2 * g3 * ... * gn = h*g1 * h*g2 * ... * h*gn. But the latter equals h^n * g1 * g2 * ... * gn. ...

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You show that the cyclic group <x> generated by an element x is a subgroup of IF* and that "u~v iff u^(-1)*v in <x>" is an equivalence relation that divides the multiplicative group into equivalence classes of equal size. So that you get [size of IF*] = [size of <x>] * [number of equivalence classes] which means that the order of ...

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Check this out: np.sum(np.unique(mat0.ravel())) So, mat0.ravel() does this: [[1,0,0],[0,0,0],[1,1,0]] ---> [1,0,0,0,0,0,1,1,0] This new object is an array, namely the [1,0,0,0,0,0,1,1,0] object above. Now, np.unique(mat0.ravel()) finds all the unique elements and sorts them and puts them in a set, like this: [1,0,0,0,0,0,1,1,0] ---> {0,1} From ...

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void solve(int n, float a[][MAX], float b[], float x[]){ int i,j; float s; for(i = 0; i < n; i++) { s = 0; for(j = 0; j < i; j++) { ^ s = s + a[ i][ j] * x[ j]; } x[ i] = ( b[ i] - s) / a[ i][ i]; } } BackSubstitution.pdf compiled example

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This line: for(j = 0; j < n; j++){ Should be: for(j = 0; j < i; j++){ Then it works fine - assuming your pivots are always non zero.

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You can use unique import numpy as np mat1 = np.array([[1,0,1], [1,1,0], [0,0,0]]) np.unique(mat1) # array([0, 1]) 1 in np.unique(mat1) # True 0 in np.unique(mat1) # True np.unique(mat1) == [0, 1] # array([ True, True], dtype=bool) You can also use setdiff1d np.setdiff1d(mat1, [0, 1]) # array([], dtype=int64) np.setdiff1d(mat1, [0, 1]).size # 0

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If you know it's int dtype, then (suprisingly) it's faster to check the max and min (even without doing these operations simultaneously): In [11]: m = np.random.randint(0, 2, (10, 10)) In [12]: %timeit np.all((m == 0) | (m == 1)) 10000 loops, best of 3: 33.7 µs per loop In [13]: %timeit m.dtype == int and m.min() == 0 and m.max() == 1 10000 loops, best of ...

1

How about this: >>> def check(matrix): ... # flatten up the matrix into one single list ... # and set on the list it should be [0,1] if it ... # contains only 0 and 1. Then do sum on that will ... # return 1 ... if sum(set(sum(matrix,[]))) > 1: ... return False ... return True ... >>> >>> ...

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Simply: In [6]: set((mat1+mat2).ravel()).issubset(set((1,0))) Out[6]: True In [7]: mat3 = np.array([[0,5,0], [0,0,1], [1,1,1]]) set((mat1+mat3).ravel()).issubset(set((1,0))) Out[7]: False

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You can use np.apply_along_axis to apply np.convolve along the desired axis. Here is an example of applying a boxcar filter to a 2d array: import numpy as np a = np.arange(10) a = np.vstack((a,a)).T filt = np.ones(3) np.apply_along_axis(lambda m: np.convolve(m, filt, mode='full'), axis=0, arr=a) This is an easy way to generalize many functions that ...

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Use numpy.all, numpy.any: all 0: np.all(mat == 0) all 1: np.all(mat == 1) some 0: np.any(mat == 0) some 1: np.any(mat == 1) >>> mat1 = np.array([[1,0,1], [1,1,0], [0,0,0]]) >>> mat2 = np.array([[0,1,0], [0,0,1], [1,1,1]]) >>> np.all(mat1 == 0) False >>> np.any(mat1 == 0) True >>> np.all(mat1 == 1) False ...

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Step 1. Generate random vector vr. Step 2. Copy vr to vo and update as follows: for every already generated vector v in v1, v2... vn, subtract the projection of vo on vi. The result is a random vector orthogonal to the subspace spanned by v1, v2... vn. If that subspace is a basis, then it is the zero vector, of course :) The decision of whether the ...

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Your problem is that in Python (2.x) 1/2 gives zero. This is (was) a long standard, and certainly isn't the only language that does this. If you run the file with Sage you should be fine. \$ sage test1.sage [1 2 3] [4 5 6] [1/2 1 3/2] [ 2 5/2 3] The comments indicate that %run must be an IPython "magic" function. My guess is that it isn't ...

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You just simply have to get rid of y and replace any occurrence of y with x. for j=1:n x(j)=(b(j)-A(j,1:j-1)*x(1:j-1)-A(j,j+1:n)*x(j+1:n))/A(j,j) end if max(abs(A*x-b))<tol iter=i; break; end Jacobi computes a new vector from the old and then replaces all variables at once. Gauß-Seidel computes in-place and uses always the most current ...

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As explained in the documentation, the ComputeThin* options are only for Dynamic sized matrices. For fixed sizes, you must use ComputeFull*. Nevertheless, in your case it is better to use Dynamic size matrices, i.e., MatrixXf. Fixed size matrices only makes sense for very small ones. Finally, ColPivHouseholderQR is probably a better choice for least-square ...

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Yes. It is also a linear code. A linear code of length n and rank k is a linear subspace C with dimension k of the vector space V. Given subspaces U and W of a vector space V, then their intersection U ∩ W := {v ∈ V : v is an element of both U and W} is also a subspace of V. To obtain H dimension this statement may be used: Let (G,+G,∘)K be a K-vector ...

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It seems that is having a problem with the matrix multiplication in your solve(B*y); part. Try doing B*y separately and use solve(result); instead. Eigen::GeneralProduct<Eigen::Matrix<float, 36, 13>, Eigen::Matrix<double, -1, 1>, 4> That line gave me this suspicion. It says that the y variable came with a size of -1x1, thus your program ...

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You could first do a matrix multiplication of A and X using loops. Then you could write another 2 loops to compute the difference (B - AX). This would simply your problem. Edit After you compute the product of A and X, assuming that you store the product in a variable named AX,the following code will give you the difference between corresponding elements. ...

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You can use the pseudoinverse matrix of A denoted as A+. A solution exist if and only if AA+b = b and all solutions are given by x = A+b + (I - A+A)*u This can be done with numpy.linalg.tensorsolv Example: >>> A = np.array([[1, 2, 3], [4, 5, 6],[8, 10, 12]]) >>> b = np.array([22., 7., 14.]) >>> Ap = np.linalg.pinv(A) # Check if ...

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You can use numpy to do scientific computing. E.g.: In [23]: import numpy as np In [24]: a=np.arange(16).reshape((4,4)) In [25]: a Out[25]: array([[ 0, 1, 2, 3], [ 4, 5, 6, 7], [ 8, 9, 10, 11], [12, 13, 14, 15]]) In [26]: np.delete(a, 2, axis=1) #delete the 3rd column Out[26]: array([[ 0, 1, 3], [ 4, 5, 7], ...

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In essence, this question is asking if rank(A*B)=n implies rank(B)=n. This is a consequence of rank(A*B) <= min( rank(A), rank(B) ) and the fact that for reasons of dimension of the spaces involved, rank(A) <= n and rank(B) <= min(k, n), so that the combined chain n = rank(A*B) <= min( rank(A), rank(B) ) <= min(k, n) leaves not much ...

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The vector x must be (1 x n); the matrix A must be (n x m); the vector b must be (1 x m). If you take the transpose of both sides, you get: (xA)^T = b^T Rearranging the LHS: (A^T)(x^T) = b^T Now A^T is an (m x n) matrix; x is a (n x 1) vector; b is an (m x 1) vector. If A is square and symmetric, then by definition A^T = A. No work needed. You can ...

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According to the documentation in (http://www.netlib.org/lapack/explore-html/da/d82/dormqr_8f.html) you are computing in vec the product Q^T*e3, where e3 is the third canonical basis vector (0,0,1,0,0,...,0). If you want to compute Q, then vec should contain a matrix sized array filled with the unit matrix, and TRANS should be "N". dormqr (SIDE, TRANS, ...

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In General, The solutioin to the matrix equation Ax=b need not exist and even if it does, need not be unique. In your case, you know that multiple solutions exist. In such a situation, you have a "particular solution" which is basically, any x that solves Ax=b and now, to get multiple solutions, you can keep adding vectors from the Nullspace of A. Proof: ...

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This question is old. Anyway, if someone here is looking for it, they should consider the GeneralizedEigenSolver (http://eigen.tuxfamily.org/dox-devel/classEigen_1_1GeneralizedEigenSolver.html) that is available in the Eigen library. Although, at this time, as far as I know, it is not completely ready.

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Simple: v * T numpy overload arithmetic operates in ways that make sense most of the time. In your case, since T is a matrix, it converts v to a matrix as well before doing the multiplication. That turns v into a row-vector. Therefore v*T performs matrix multiplication, but T*v throws an exception because v is the wrong shape. However you can make v the ...

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