69 research outputs found
Some recent advances in projection-type methods for variational inequalities
AbstractProjection-type methods are a class of simple methods for solving variational inequalities, especially for complementarity problems. In this paper we review and summarize recent developments in this class of methods, and focus mainly on some new trends in projection-type methods
Forward-backward truncated Newton methods for convex composite optimization
This paper proposes two proximal Newton-CG methods for convex nonsmooth
optimization problems in composite form. The algorithms are based on a a
reformulation of the original nonsmooth problem as the unconstrained
minimization of a continuously differentiable function, namely the
forward-backward envelope (FBE). The first algorithm is based on a standard
line search strategy, whereas the second one combines the global efficiency
estimates of the corresponding first-order methods, while achieving fast
asymptotic convergence rates. Furthermore, they are computationally attractive
since each Newton iteration requires the approximate solution of a linear
system of usually small dimension
An efficient sieving based secant method for sparse optimization problems with least-squares constraints
In this paper, we propose an efficient sieving based secant method to address
the computational challenges of solving sparse optimization problems with
least-squares constraints. A level-set method has been introduced in [X. Li,
D.F. Sun, and K.-C. Toh, SIAM J. Optim., 28 (2018), pp. 1842--1866] that solves
these problems by using the bisection method to find a root of a univariate
nonsmooth equation for some , where
is the value function computed by a solution of the
corresponding regularized least-squares optimization problem. When the
objective function in the constrained problem is a polyhedral gauge function,
we prove that (i) for any positive integer , is piecewise
in an open interval containing the solution to the equation
; (ii) the Clarke Jacobian of is
always positive. These results allow us to establish the essential ingredients
of the fast convergence rates of the secant method. Moreover, an adaptive
sieving technique is incorporated into the secant method to effectively reduce
the dimension of the level-set subproblems for computing the value of
. The high efficiency of the proposed algorithm is demonstrated
by extensive numerical results
Newton-type Alternating Minimization Algorithm for Convex Optimization
We propose NAMA (Newton-type Alternating Minimization Algorithm) for solving
structured nonsmooth convex optimization problems where the sum of two
functions is to be minimized, one being strongly convex and the other composed
with a linear mapping. The proposed algorithm is a line-search method over a
continuous, real-valued, exact penalty function for the corresponding dual
problem, which is computed by evaluating the augmented Lagrangian at the primal
points obtained by alternating minimizations. As a consequence, NAMA relies on
exactly the same computations as the classical alternating minimization
algorithm (AMA), also known as the dual proximal gradient method. Under
standard assumptions the proposed algorithm possesses strong convergence
properties, while under mild additional assumptions the asymptotic convergence
is superlinear, provided that the search directions are chosen according to
quasi-Newton formulas. Due to its simplicity, the proposed method is well
suited for embedded applications and large-scale problems. Experiments show
that using limited-memory directions in NAMA greatly improves the convergence
speed over AMA and its accelerated variant
Globally Convergent Coderivative-Based Generalized Newton Methods in Nonsmooth Optimization
This paper proposes and justifies two globally convergent Newton-type methods
to solve unconstrained and constrained problems of nonsmooth optimization by
using tools of variational analysis and generalized differentiation. Both
methods are coderivative-based and employ generalized Hessians (coderivatives
of subgradient mappings) associated with objective functions, which are either
of class , or are represented in the form of convex
composite optimization, where one of the terms may be extended-real-valued. The
proposed globally convergent algorithms are of two types. The first one extends
the damped Newton method and requires positive-definiteness of the generalized
Hessians for its well-posedness and efficient performance, while the other
algorithm is of {the regularized Newton type} being well-defined when the
generalized Hessians are merely positive-semidefinite. The obtained convergence
rates for both methods are at least linear, but become superlinear under the
semismooth property of subgradient mappings. Problems of convex composite
optimization are investigated with and without the strong convexity assumption
{on smooth parts} of objective functions by implementing the machinery of
forward-backward envelopes. Numerical experiments are conducted for Lasso
problems and for box constrained quadratic programs with providing performance
comparisons of the new algorithms and some other first-order and second-order
methods that are highly recognized in nonsmooth optimization.Comment: arXiv admin note: text overlap with arXiv:2101.1055
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