Nonnegative Orthant Research Articles

Ideal, weakly efficient solutions for vector optimization problems

We establish existence results for finite dimensional vector minimization problems allowing the solution set to be unbounded. The solutions to be referred are ideal(strong)/weakly efficient(weakly Pareto). Also several necessary and/or sufficient conditions for the solution set to be non-empty and compact are established. Moreover, some characterizations of the non-emptiness (boundedness) of the (convex) solution set in case the solutions are searched in a subset of the real line, are also given. However, the solution set fails to be convex in general. In addition, special attention is addressed when the underlying cone is the non-negative orthant and when the semi-strict quasiconvexity of each component of the vector-valued function is assumed. Our approach is based on the asymptotic description of the functions and sets. Some examples illustrating such an approach are also exhibited.

Social choice with analytic preferences

Arrow's axioms for social welfare functions are shown to be inconsistent when the set of alternatives is the nonnegative orthant in a multidimensional Euclidean space and preferences are assumed to be either the set of analytic classical economic preferences or the set of Euclidean spatial preferences. When either of these preference domains is combined with an agenda domain consisting of compact sets with nonempty interiors, strengthened versions of the Arrovian social choice correspondence axioms are shown to be consistent. To help establish the economic possibility theorem, an ordinal version of the Analytic Continuation Principle is developed.

Kolmogorov Vector Fields with Robustly Permanent Subsystems

The following results are proven. All subsystems of a dissipative Kolmogorov vector field ẋi=xifi(x) are robustly permanent if and only if the external Lyapunov exponents are positive for every ergodic probability measure μ with support in the boundary of the nonnegative orthant. If the vector field is also totally competitive, its carrying simplex is C1. Applying these results to dissipative Lotka–Volterra systems, robust permanence of all subsystems is equivalent to every equilibrium x* satisfying fi(x*>0 whenever xi*=0. If in addition the Lotka–Volterra system is totally competitive, then its carrying simplex is C1.

Smoothing Functions for Second-Order-Cone Complementarity Problems

Smoothing functions have been much studied in the solution of optimization and complementarity problems with nonnegativity constraints. In this paper, we extend smoothing functions to problems in which the nonnegative orthant is replaced by the direct product of second-order cones. These smoothing functions include the Chen--Mangasarian class and the smoothed Fischer--Burmeister function. We study the Lipschitzian and differential properties of these functions and, in particular, we derive computable formulas for these functions and their Jacobians. These properties and formulas can then be used to develop and analyze noninterior continuation methods for solving the corresponding optimization and complementarity problems. In particular, we establish the existence and uniqueness of the Newton direction when the underlying mapping is monotone.

Robust Optimal Service Analysis of Single-Server Re-Entrant Queues

We generalize the analysis of J.A. Ball, M.V. Day, and P. Kachroo (Mathematics of Control, Signals, and Systems, vol. 12, pp. 307–345, 1999) to a fluid model of a single server re-entrant queue. The approach is to solve the Hamilton-Jacobi-Isaacs equation associated with optimal robust control of the system. The method of “staged” characteristics is generalized from Ball et al. (1999) to construct the solution explicitly. Formulas are developed allowing explicit calculations for the Skorokhod problem involved in the system equations. Such formulas are particularly important for numerical verification of conditions on the boundary of the nonnegative orthant. The optimal control (server) strategy is shown to be of linear-index type. Dai-type stability properties are discussed. A modification of the model in which new “customers” are allowed only at a specified entry queue is considered in 2 dimensions. The same optimal strategy is found in that case as well.

The quasimonotonicity of linear differential systems — the complex spectrum

The method of vector Lyapunov functions to determine stability in dynamical systems requires that the comparison system be quasimonotone nondecreasing with respect to a cone contained in the nonnegative orthant. For linear comparison systems in Rn with real spectra, Heikkilä solved the problem for n = 2 and gave necessary conditions for n > 2. We previously showed a sufficient condition for n > 2, and here, for systems with complex eigenvalues, we give conditions for which the problem reduces to the nonnegative inverse eigenvalue problem.

A self-adaptive projection and contraction algorithm for the traffic assignment problem with path-specific costs

This paper considers solving a special case of the nonadditive traffic equilibrium problem presented by Gabriel and Bernstein [Transportation Science 31 (4) (1997) 337–348] in which the cost incurred on each path is made up of the sum of the arc travel times plus a path-specific cost for traveling on that path. A self-adaptive projection and contraction method is suggested to solve the path-specific cost traffic equilibrium problem, which is formulated as a nonlinear complementarity problem (NCP). The computational effort required per iteration is very modest. It consists of only two function evaluations and a simple projection on the nonnegative orthant. A self-adaptive technique is embedded in the projection and contraction method to find suitable scaling factor without the need to do a line search. The method is simple and has the ability to handle a general monotone mapping F. Numerical results are provided to demonstrate the features of the projection and contraction method.

On deciding stability of constrained random walks and queueing systems

We consider in this paper two types of queueing systems which operate under a specific and fixed scheduling policy. The first system consists of a single server and several buffers in which arriving jobs are stored. We assume that arriving parts may require several stages of processing in which case each stage corresponds to a different buffer. The second system is a communication type queueing network given by a graph. The arriving jobs (packets) request a simple path along which they need to be processed. In both models the jobs arrive in a completely deterministic fashion: the interarrival times are fixed and known. All the processing times are also deterministic. A scheduling policy specifies a rule using which arriving parts are processed in the queueing system. A scheduling policy is defined to be stable if there is a finite uniform upper bound on the total number of parts in the system at all times. A necessary condition for stability of any work conserving policy is that the traffic intensity of the station (of each link in the graph in the communication model) is not bigger than one. Many results have demonstrated that this condition is not sufficient for stability. The results were obtained primarily in the context of stochastic networks ([24],[20],[5],[6],[10]), deterministic fluid networks ([6],[9],[7],[8],[2]), deterministic adversarial networks ([4],[1],[14],[12]). One of the earliest result in the area were obtained by Rybko and Stolyar [24] and Lu and Kumar [20]. They showed that a simple priority policy can lead to instability in some queueing networks. Bramson [5] and Seidman [25] showed that even FIFO policy can be unstable in stochastic networks. Instability of FIFO was later demonstrated in an adversarial queueing setting by Andrews et. al. [1]. Dai [6] established that stability of a fluid deterministic queueing network implies stability of a stochastic queueing network. A similar result was established by Gamarnik [12], which connects stability of fluid and adversarial queueing networks. A complete characterization of two-station fluid networks which are stable under any work conserving policy was established by Bertsimas, Gamarnik and Tsitsiklis [2] and Dai and Vande Vate [7]. Goel [14] constructed a complete characterization of adversarial queueing networks which are stable under the usual load condition. The result is extended by Gamarnik [13]. Motivated by a queueing network model stability of homogeneous random walks in a nonnegative orthant was considered in several papers: Malyshev [21], Menshikov [23], Fayolle [11], Ignatyuk and Malyshev [18], Malyshev [22]. Such random walks Q ( t ), t = 0, 1, 2,¡­ have Z + d as a state space ( Z + is the set of nonnegative integers). The transition vectors ¦¤ have deterministically bounded length in max norm and the transition probability p (¦«, ¦¤) along the direction ¦¤ depends only on the face ¦« that the random walk is currently on (the transition probabilities depend only on which coordinates of the current state are positive and which are zero). Such a random walk is defined to be stable if it is positive recurrent. We will also consider deterministic walks, for which p (¦«, ¦¤) is always zero or one (the transition deterministically depends on the face that the walk is currently on). A complete characterization of stable homogeneous random walks in Z + d for d ¡Ü 4 was obtained in Malyshev [21], Menshikov [23] and Ignatyuk and Malyshev [18], but no extension of this classification to higher dimensions has been obtained. Malyshev in [22] establishes a connection between homogeneous random walks and general dynamical systems on compact manifolds and shows that the difficulty of classifying stable random walks is of the same nature as the difficulty of understanding the dynamics of these dynamical systems. Specifically, the complicated dynamics precludes obtaining classification of stable random walks for d = 5. Thus despite many efforts the classification of stable random walks for general dimensions is not known. Likewise classification of stable policies in queueing systems is an open problem.

On the invariant faces associated with a cone-preserving map

For an n×n nonnegative matrix P , an isomorphism is obtained between the lattice of initial subsets (of {1, · · · , n}) for P and the lattice of P -invariant faces of the nonnegative orthant R+. Motivated by this isomorphism, we generalize some of the known combinatorial spectral results on a nonnegative matrix that are given in terms of its classes to results for a cone-preserving map on a polyhedral cone, formulated in terms of its invariant faces. In particular, we obtain the following extension of the famous Rothblum Index Theorem for a nonnegative matrix: If A leaves invariant a polyhedral cone K, then for each distinguished eigenvalue λ ofA forK, there is a chain of mλ distinct A-invariant join-irreducible faces of K, each containing in its relative interior a generalized eigenvector of A corresponding to λ (referred to as semi-distinguished A-invariant faces associated with λ), where mλ is the maximal order of distinguished generalized eigenvectors of A corresponding to λ, but there is no such chain with more than mλ members. We introduce the important new concepts of semi-distinguished A-invariant faces, and of spectral pairs of faces associated with a cone-preserving map, and obtain several properties of a cone-preserving map that mostly involve these two concepts, when the underlying cone is polyhedral, perfect, or strictly convex and/or smooth, or is the cone of all real polynomials of degree not exceeding n that are nonnegative on a closed interval. Plentiful illustrative examples are provided. Some open problems are posed at the end. 1991 Mathematics Subject Classification. Primary 15A48; Secondary 47B65, 47A25, 46B42.

On Ranking Opportunity Sets in Economic Environments

This paper examines how freedom of choice as reflected in an agent's opportunity sets can be measured in economic environments where opportunity sets are non empty and compact subsets of the non-negative orthant of the n-dimensional real space. Several plausible axioms are proposed for this purpose. It is then shown that, under different sets of axioms, one can represent the ranking of compact opportunity sets by different types of real-valued functions with intuitively plausible properties. Journal of Economic Literature Classification Numbers: D63, D70.

Interior-point methodology for 3-D PET reconstruction.

Interior-point methods have been successfully applied to a wide variety of linear and nonlinear programming applications. This paper presents a class of algorithms, based on path-following interior-point methodology, for performing regularized maximum-likelihood (ML) reconstructions on three-dimensional (3-D) emission tomography data. The algorithms solve a sequence of subproblems that converge to the regularized maximum likelihood solution from the interior of the feasible region (the nonnegative orthant). We propose two methods, a primal method which updates only the primal image variables and a primal-dual method which simultaneously updates the primal variables and the Lagrange multipliers. A parallel implementation permits the interior-point methods to scale to very large reconstruction problems. Termination is based on well-defined convergence measures, namely, the Karush-Kuhn-Tucker first-order necessary conditions for optimality. We demonstrate the rapid convergence of the path-following interior-point methods using both data from a small animal scanner and Monte Carlo simulated data. The proposed methods can readily be applied to solve the regularized, weighted least squares reconstruction problem.

On level sets of marginal functions

The investigation of level sets of marginal functions is motivated by several aspects of standard and generalized semi-infinite programming. The feasible- set M of such a prob­lem is easily seen to be a level set of the marginal function corresponding to the lower level problem. In the present paper we study the local structure of M at feasible bound­ary points in the generic case. A codimension formula shows that there is a wide range of these generic situations, but that the number of active indices is always bounded by the state space dimension. We restrict our attention to two special subcases In the first case, where the number of active indices is maximalM is shown to be locally diffeomorphic to the non-negative orthant. This situation is well-known from finite and also from standard semi-infinite programming. However, in the second case a generic situation arises which is typical for generalized semi-infinite programming. Here, the active index set is a singleton, and M can exhibit a re-entrant corner or even local non-closedness, depending on whether the Mangasarian-Fromovitz constraint qualifica­tion holds at the active index. If an objective function is minimized over M then in the setting of the second case a local minimizer cannot occur

A threshold representation for the strength distribution of a complex load sharing system

Abstract In many reliability contexts, the distribution, P(T⩽t), for a combination of k components with strengths (or lifetimes) X =(X 1 ,…,X k ) , is a first passage probability of the form P(T⩽t)=P( X ∈tC) for t⩾0, where C is a cone containing the origin. For example, in a load sharing system, a load sharing rule describes how load is transferred from a failed component to the collection of unfailed components as the pattern of breaks evolves. The rule quantifies the component interactions leading to failure and, with the component breaking patterns, characterize certain conical regions in the nonnegative orthant of Rk which define the system strength. In this paper we show that, for independent component strengths (or lifetimes) having exponential distributions, T has a threshold representation, S/θ, where S and θ are independent random variables with S having a gamma distribution with unit scale and shape parameter depending on the structure of the cone. The consequent mixture representation has two noteworthy implications: First, failure rate relationships are established between the distributions of θ and T which are related to some recent work on mixtures of increasing failure rates resulting in a decreasing failure rate. Second, it makes tools such as the EM-algorithm and the gradient function applicable for data analytic purposes. A methodology for analyzing this model and based on these tools is proposed and illustrated on some data sets.

The quasimonotonicity of linear differential systems

The method of vector Lyapunov functions to determine stability in dynamical systems requires that the comparison system be quasimonotone nondecreasing with respect to a cone contained in the nonnegative orthant. For linear comparison systems with real eigenvalues, we show some necessary and sufficient conditions for such cones to exist, and we show a method to construct such cones.

Approximating Extreme Points of Infinite Dimensional Convex Sets

The property that an optimal solution to the problem of minimizing a continuous concave function over a compact convex set in ℝn is attained at an extreme point is generalized by the Bauer Minimum Principle to the infinite dimensional context. The problem of approximating and characterizing infinite dimensional extreme points thus becomes an important problem. Consider now an infinite dimensional compact convex set in the nonnegative orthant of the product space ℝ∞. We show that the sets of extreme points EN of its corresponding finite dimensional projections onto ℝN converge in the product topology to the closure of the set of extreme points E of the infinite dimensional set. As an application, we extend the concept of total unimodularity to infinite systems of linear equalities in nonnegative variables where we show when extreme points inherit integrality from approximating finite systems. An application to infinite horizon production planning is considered.

Global Convergence of the Affine Scaling Algorithm for Convex Quadratic Programming

In this paper we give a global convergence proof of the second-order affine scaling algorithm for convex quadratic programming problems, where the new iterate is the point which minimizes the objective function over the intersection of the feasible region with the ellipsoid centered at the current point and whose radius is a fixed fraction $\beta \in (0,1]$ of the radius of the largest scaled ellipsoid inscribed in the nonnegative orthant. The analysis is based on the local Karmarkar potential function introduced by Tsuchiya. For any $\beta \in (0, 1)$ and without assuming any nondegeneracy assumption on the problem, it is shown that the sequences of primal iterates and dual estimates converge to optimal solutions of the quadratic program and its dual, respectively.

On Unconstrained and Constrained Stationary Points of the Implicit Lagrangian

Mangasarian and Solodov (Ref. 1) proposed to solve nonlinear complementarity problems by seeking the unconstrained global minima of a new merit function, which they called implicit Lagrangian. A crucial point in such an approach is to determine conditions which guarantee that every unconstrained stationary point of the implicit Lagrangian is a global solution, since standard unconstrained minimization techniques are only able to locate stationary points. Some authors partially answered this question by giving sufficient conditions which guarantee this key property. In this paper, we settle the issue by giving a necessary and sufficient condition for a stationary point of the implicit Lagrangian to be a global solution and, hence, a solution of the nonlinear complementarity problem. We show that this new condition easily allows us to recover all previous results and to establish new sufficient conditions. We then consider a constrained reformulation based on the implicit Lagrangian in which nonnegative constraints on the variables are added to the original unconstrained reformulation. This is motivated by the fact that often, in applications, the function which defines the complementarity problem is defined only on the nonnegative orthant. We consider the KKT-points of this new reformulation and show that the same necessary and sufficient condition which guarantees, in the unconstrained case, that every unconstrained stationary point is a global solution, also guarantees that every KKT-point of the new problem is a global solution.

The Case of a Giffen Good: Comment

(1997). The Case of a Giffen Good: Comment. The Journal of Economic Education: Vol. 28, No. 1, pp. 36-44.

Minimal order realizations for a class of positive linear systems

The positive realization problem for linear systems is to find, for a given transfer function, all possible realizations with a state space of minimal dimension such that the resulting system is a positive system. In this paper, discrete-time positive linear systems having the nonnegative orthant reachable from the origin in a finite time interval with nonnegative inputs, are considered and the solution of the positive realization problem for this class of systems is given.

An effective version of Pólya's theorem on positive definite forms

Given a real homogeneous polynomial F, strictly positive in the non-negative orthant, Pólya's theorem says that for a sufficiently large exponent p the coefficients of F( x 1,…, x n ) · ( x 1 + … + x n ) p are strictly positive. The smallest such p will be called the Pólya exponent of F. We present a new proof for Pólya's result, which allows us to obtain an explicit upper bound on the Pólya exponent when F has rational coefficients. An algorithm to obtain reasonably good bounds for specific instances is also derived. Pólya's theorem has appeared before in constructive solutions of Hilbert's 17th problem for positive definite forms [4]. We also present a different procedure to do this kind of construction.