5,371 research outputs found
Inexact Convex Relaxations for AC Optimal Power Flow: Towards AC Feasibility
Convex relaxations of AC optimal power flow (AC-OPF) problems have attracted
significant interest as in several instances they provably yield the global
optimum to the original non-convex problem. If, however, the relaxation is
inexact, the obtained solution is not AC-feasible. The quality of the obtained
solution is essential for several practical applications of AC-OPF, but
detailed analyses are lacking in existing literature. This paper aims to cover
this gap. We provide an in-depth investigation of the solution characteristics
when convex relaxations are inexact, we assess the most promising AC
feasibility recovery methods for large-scale systems, and we propose two new
metrics that lead to a better understanding of the quality of the identified
solutions. We perform a comprehensive assessment on 96 different test cases,
ranging from 14 to 3120 buses, and we show the following: (i) Despite an
optimality gap of less than 1%, several test cases still exhibit substantial
distances to both AC feasibility and local optimality and the newly proposed
metrics characterize these deviations. (ii) Penalization methods fail to
recover an AC-feasible solution in 15 out of 45 cases, and using the proposed
metrics, we show that most failed test instances exhibit substantial distances
to both AC-feasibility and local optimality. For failed test instances with
small distances, we show how our proposed metrics inform a fine-tuning of
penalty weights to obtain AC-feasible solutions. (iii) The computational
benefits of warm-starting non-convex solvers have significant variation, but a
computational speedup exists in over 75% of the cases
Solving variational inequalities defined on a domain with infinitely many linear constraints
We study a variational inequality problem whose domain is defined by infinitely many linear inequalities. A discretization method and an analytic center based inexact cutting plane method are proposed. Under proper assumptions, the convergence results for both methods are given. We also provide numerical examples to illustrate the proposed method
An Inexact Successive Quadratic Approximation Method for Convex L-1 Regularized Optimization
We study a Newton-like method for the minimization of an objective function
that is the sum of a smooth convex function and an l-1 regularization term.
This method, which is sometimes referred to in the literature as a proximal
Newton method, computes a step by minimizing a piecewise quadratic model of the
objective function. In order to make this approach efficient in practice, it is
imperative to perform this inner minimization inexactly. In this paper, we give
inexactness conditions that guarantee global convergence and that can be used
to control the local rate of convergence of the iteration. Our inexactness
conditions are based on a semi-smooth function that represents a (continuous)
measure of the optimality conditions of the problem, and that embodies the
soft-thresholding iteration. We give careful consideration to the algorithm
employed for the inner minimization, and report numerical results on two test
sets originating in machine learning
Computing Least Fixed Points of Probabilistic Systems of Polynomials
We study systems of equations of the form X1 = f1(X1, ..., Xn), ..., Xn =
fn(X1, ..., Xn), where each fi is a polynomial with nonnegative coefficients
that add up to 1. The least nonnegative solution, say mu, of such equation
systems is central to problems from various areas, like physics, biology,
computational linguistics and probabilistic program verification. We give a
simple and strongly polynomial algorithm to decide whether mu=(1, ..., 1)
holds. Furthermore, we present an algorithm that computes reliable sequences of
lower and upper bounds on mu, converging linearly to mu. Our algorithm has
these features despite using inexact arithmetic for efficiency. We report on
experiments that show the performance of our algorithms.Comment: Published in the Proceedings of the 27th International Symposium on
Theoretical Aspects of Computer Science (STACS). Technical Report is also
available via arxiv.or
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