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ResQPASS: Algorithm for Bounded Variable Linear Least Squares


Kernekoncepter
The author presents the ResQPASS method for solving large-scale linear least-squares problems with bound constraints, utilizing a series of small problems and active-set methods. The approach links convergence to an asymptotic Krylov subspace.
Resumé

The ResQPASS algorithm solves linear least squares with bound constraints efficiently by projecting onto residuals and using active-set methods. It converges like CG and LSQR when few constraints are active, showing promise for large-scale problems.

The paper introduces an efficient implementation updating QR factorizations over iterations and Cholesky factorizations over outer iterations. The method's convergence is linked to Krylov theory, offering insights into solving bounded-variable least squares problems effectively.

Key contributions include warm-starting capabilities, Cholesky factorization updates, and limiting inner iterations for optimal performance. The algorithm's recursive relationships improve efficiency, while stopping criteria ensure accurate solutions within specified tolerances.

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Statistik
A ∈ Rm×n models the propagation of X-rays through the object. A is often ill-conditioned in straightforward least-squares solutions. A sparse matrix A with 3.98% fill is used in experiments. Aspect ratio of 10:6 in underdetermined systems. Matrix AT A is close to full matrix in experiments. Synthetic numerical experiments explore ResQPASS efficiency.
Citater
"The method coincides with conjugate gradients (CG) or LSQR applied to normal equations." "An analysis links the convergence to an asymptotic Krylov subspace." "The result is a constrained quadratic programming problem with objective f(x)."

Vigtigste indsigter udtrukket fra

by Bas Symoens,... kl. arxiv.org 03-07-2024

https://arxiv.org/pdf/2302.13616.pdf
ResQPASS

Dybere Forespørgsler

How does warm-starting impact the efficiency of solving large-scale least squares problems

Warm-starting impacts the efficiency of solving large-scale least squares problems by providing a starting point that is closer to the optimal solution. In ResQPASS, warm-starting allows for the reuse of the previous working set and solution as an initial guess for the next iteration. This reduces the number of iterations needed to converge to a solution, leading to faster computation times. By starting closer to the optimal solution, warm-starting helps in accelerating convergence and improving overall efficiency in solving large-scale least squares problems.

What are the implications of limiting inner iterations on the accuracy of ResQPASS solutions

Limiting inner iterations can have implications on both accuracy and efficiency in ResQPASS solutions. When inner iterations are limited, it may result in premature termination before reaching optimality or feasibility. This can lead to suboptimal solutions with reduced accuracy compared to allowing more inner iterations for finer optimization. However, limiting inner iterations can also improve computational efficiency by reducing runtime, especially when dealing with complex or time-consuming calculations within each iteration.

How can ResQPASS be extended to handle general convex Hessian matrices beyond positive definite cases

To handle general convex Hessian matrices beyond positive definite cases in ResQPASS, modifications need to be made to accommodate non-positive definite matrices while ensuring convergence and accuracy. One approach could involve incorporating techniques such as regularization methods or preconditioners tailored for handling indefinite matrices into ResQPASS algorithm. By adapting the algorithm's framework and computations to address non-positive definiteness effectively, ResQPASS can be extended to handle a broader range of convex Hessian matrices efficiently while maintaining robustness and precision in its solutions.
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