s ------- lambda : ndarray of the shape ``(k, )``. Array of ``k`` approximate eigenvalues. v : ndarray of the same shape as ``X.shape``. An array of ``k`` approximate eigenvectors. lambdaHistory : ndarray, optional. The eigenvalue history, if `retLambdaHistory` is ``True``. ResidualNormsHistory : ndarray, optional. The history of residual norms, if `retResidualNormsHistory` is ``True``. Notes ----- The iterative loop runs ``maxit=maxiter`` (20 if ``maxit=None``) iterations at most and finishes earlier if the tolerance is met. Breaking backward compatibility with the previous version, LOBPCG now returns the block of iterative vectors with the best accuracy rather than the last one iterated, as a cure for possible divergence. If ``X.dtype == np.float32`` and user-provided operations/multiplications by `A`, `B`, and `M` all preserve the ``np.float32`` data type, all the calculations and the output are in ``np.float32``. The size of the iteration history output equals to the number of the best (limited by `maxit`) iterations plus 3: initial, final, and postprocessing. If both `retLambdaHistory` and `retResidualNormsHistory` are ``True``, the return tuple has the following format ``(lambda, V, lambda history, residual norms history)``. In the following ``n`` denotes the matrix size and ``k`` the number of required eigenvalues (smallest or largest). The LOBPCG code internally solves eigenproblems of the size ``3k`` on every iteration by calling the dense eigensolver `eigh`, so if ``k`` is not small enough compared to ``n``, it makes no sense to call the LOBPCG code. Moreover, if one calls the LOBPCG algorithm for ``5k > n``, it would likely break internally, so the code calls the standard function `eigh` instead. It is not that ``n`` should be large for the LOBPCG to work, but rather the ratio ``n / k`` should be large. It you call LOBPCG with ``k=1`` and ``n=10``, it works though ``n`` is small. The method is intended for extremely large ``n / k``. The convergence speed depends basically on three factors: 1. Quality of the initial approximations `X` to the seeking eigenvectors. Randomly distributed around the origin vectors work well if no better choice is known. 2. Relative separation of the desired eigenvalues from the rest of the eigenvalues. One can vary ``k`` to improve the separation. 3. Proper preconditioning to shrink the spectral spread. For example, a rod vibration test problem (under tests directory) is ill-conditioned for large ``n``, so convergence will be slow, unless efficient preconditioning is used. For this specific problem, a good simple preconditioner function would be a linear solve for `A`, which is easy to code since `A` is tridiagonal. References ---------- .. [1] A. V. Knyazev (2001), Toward the Optimal Preconditioned Eigensolver: Locally Optimal Block Preconditioned Conjugate Gradient Method. SIAM Journal on Scientific Computing 23, no. 2, pp. 517-541. :doi:`10.1137/S1064827500366124` .. [2] A. V. Knyazev, I. Lashuk, M. E. Argentati, and E. Ovchinnikov (2007), Block Locally Optimal Preconditioned Eigenvalue Xolvers (BLOPEX) in hypre and PETSc. :arxiv:`0705.2626` .. [3] A. V. Knyazev's C and MATLAB implementations: https://github.com/lobpcg/blopex Examples -------- Our first example is minimalistic - find the largest eigenvalue of a diagonal matrix by solving the non-generalized eigenvalue problem ``A x = lambda x`` without constraints or preconditioning. >>> import numpy as np >>> from scipy.sparse import spdiags >>> from scipy.sparse.linalg import LinearOperator, aslinearoperator >>> from scipy.sparse.linalg import lobpcg The square matrix size is >>> n = 100 and its diagonal entries are 1, ..., 100 defined by >>> vals = np.arange(1, n + 1).astype(np.int16) The first mandatory input parameter in this test is the sparse diagonal matrix `A` of the eigenvalue problem ``A x = lambda x`` to solve. >>> A = spdiags(vals, 0, n, n) >>> A = A.astype(np.int16) >>> A.toarray() array([[ 1, 0, 0, ..., 0, 0, 0], [ 0, 2, 0, ..., 0, 0, 0], [ 0, 0, 3, ..., 0, 0, 0], ..., [ 0, 0, 0, ..., 98, 0, 0], [ 0, 0, 0, ..., 0, 99, 0], [ 0, 0, 0, ..., 0, 0, 100]], shape=(100, 100), dtype=int16) The second mandatory input parameter `X` is a 2D array with the row dimension determining the number of requested eigenvalues. `X` is an initial guess for targeted eigenvectors. `X` must have linearly independent columns. If no initial approximations available, randomly oriented vectors commonly work best, e.g., with components normally distributed around zero or uniformly distributed on the interval [-1 1]. Setting the initial approximations to dtype ``np.float32`` forces all iterative values to dtype ``np.float32`` speeding up the run while still allowing accurate eigenvalue computations. >>> k = 1 >>> rng = np.random.default_rng() >>> X = rng.normal(size=(n, k)) >>> X = X.astype(np.float32) >>> eigenvalues, _ = lobpcg(A, X, maxiter=60) >>> eigenvalues array([100.], dtype=float32) `lobpcg` needs only access the matrix product with `A` rather then the matrix itself. Since the matrix `A` is diagonal in this example, one can write a function of the matrix product ``A @ X`` using the diagonal values ``vals`` only, e.g., by element-wise multiplication with broadcasting in the lambda-function >>> A_lambda = lambda X: vals[:, np.newaxis] * X or the regular function >>> def A_matmat(X): ... return vals[:, np.newaxis] * X and use the handle to one of these callables as an input >>> eigenvalues, _ = lobpcg(A_lambda, X, maxiter=60) >>> eigenvalues array([100.], dtype=float32) >>> eigenvalues, _ = lobpcg(A_matmat, X, maxiter=60) >>> eigenvalues array([100.], dtype=float32) The traditional callable `LinearOperator` is no longer necessary but still supported as the input to `lobpcg`. Specifying ``matmat=A_matmat`` explicitly improves performance. >>> A_lo = LinearOperator((n, n), matvec=A_matmat, matmat=A_matmat, dtype=np.int16) >>> eigenvalues, _ = lobpcg(A_lo, X, maxiter=80) >>> eigenvalues array([100.], dtype=float32) The least efficient callable option is `aslinearoperator`: >>> eigenvalues, _ = lobpcg(aslinearoperator(A), X, maxiter=80) >>> eigenvalues array([100.], dtype=float32) We now switch to computing the three smallest eigenvalues specifying >>> k = 3 >>> X = np.random.default_rng().normal(size=(n, k)) and ``largest=False`` parameter >>> eigenvalues, _ = lobpcg(A, X, largest=False, maxiter=90) >>> print(eigenvalues) [1. 2. 3.] The next example illustrates computing 3 smallest eigenvalues of the same matrix `A` given by the function handle ``A_matmat`` but with constraints and preconditioning. Constraints - an optional input parameter is a 2D array comprising of column vectors that the eigenvectors must be orthogonal to >>> Y = np.eye(n, 3) The preconditioner acts as the inverse of `A` in this example, but in the reduced precision ``np.float32`` even though the initial `X` and thus all iterates and the output are in full ``np.float64``. >>> inv_vals = 1./vals >>> inv_vals = inv_vals.astype(np.float32) >>> M = lambda X: inv_vals[:, np.newaxis] * X Let us now solve the eigenvalue problem for the matrix `A` first without preconditioning requesting 80 iterations >>> eigenvalues, _ = lobpcg(A_matmat, X, Y=Y, largest=False, maxiter=80) >>> eigenvalues array([4., 5., 6.]) >>> eigenvalues.dtype dtype('float64') With preconditioning we need only 20 iterations from the same `X` >>> eigenvalues, _ = lobpcg(A_matmat, X, Y=Y, M=M, largest=False, maxiter=20) >>> eigenvalues array([4., 5., 6.]) Note that the vectors passed in `Y` are the eigenvectors of the 3 smallest eigenvalues. The results returned above are orthogonal to those. The primary matrix `A` may be indefinite, e.g., after shifting ``vals`` by 50 from 1, ..., 100 to -49, ..., 50, we still can compute the 3 smallest or largest eigenvalues. >>> vals = vals - 50 >>> X = rng.normal(size=(n, k)) >>> eigenvalues, _ = lobpcg(A_matmat, X, largest=False, maxiter=99) >>> eigenvalues array([-49., -48., -47.]) >>> eigenvalues, _ = lobpcg(A_matmat, X, largest=True, maxiter=99) >>> eigenvalues array([50., 49., 48.]) Né