Forward and Backward Deviation Measures and Robust Optimization

Forward and Backward Deviation Measures and Robust Optimization Peng Sun (Duke) with Xin Chen (UIUC) and Melvyn Sim (NUS)

Agenda • Overview of Robust Optimization • Forward and Backward Deviation Measures • Uncertainty Sets and Probability Bounds • Conclusions

Uncertain linear constraints • Uncertain linear constraint • Chance constraint • Hard to solve when  is small

Linear constraints with uncertainty • Affine Uncertainty : zero mean, independent but not necessarily identically distributed

Overview of Robust Optimization • Worst case • Relies only on the distribution support • Easy to solve (Soyster 1973) • Extremely conservative

Overview of Robust Optimization • Goal of Robust Optimization: • Easy to obtain feasible solutions that satisfy chance constraint • Not as conservative as worst case

Overview of Robust Optimization • Design of Uncertainty Set • Subset of worst case set, W • : Budget of uncertainty • Control radius of uncertainty set, S • max: Worse case budget • For reasonable probability bound,  << max

Overview of Robust Optimization • Robust Counterpart • Semi-infinite constraint • Tractability • Polyhedral Uncertainty Set • Linear Programming (LP) • Conic Quadratic Uncertainty Set • Second Order Cone Programming (SOCP)

Overview of Robust Optimization • Ellipsoidal Uncertainty Set • Ben-Tal and Nemirovski (1997), El-Ghaoui et al. (1996) • Robust Counterpart is a SOCP • Probability bound for symmetrically bounded uncertainties:

Overview of Robust Optimization • Polyhedral Uncertainty Set • Bertsimas and Sim (2000) • Robust Counterpart is a LP • Probability bound for symmetrically bounded uncertainties: • More conservative compared to Ellipsoidal Uncertainty Set

Overview of Robust Optimization • Norm Uncertainty Set • Robust Counterpart depends on the choice of norm • Probability bound for symmetrically bounded uncertainties:

Overview of Robust Optimization • Modeling limitations of Classical Uncertainty Sets • Uncertainty set is symmetrical, but distributions are generally asymmetrical • Can we use more information on distributions to obtain less conservative solution in achieveing the same probability bound? --- Forward and Backward Deviation Measures

Forward and Backward Deviation Measures • Set of forward deviation measures • Set of backward deviation measures

Forward deviation Backward deviation Alternatively,

Forward and Backward Deviation Measures • Key idea

Important property • Subadditivity

Least conservative forward and backward deviation measures • Suppose distribution is known • p* =q* if distribution is symmetrical • p*, q*¸ (standard deviation) • p* =q* =  if distribution is Normal

Least conservative forward and backward deviation measures • p* ,q* can be obtained numerically • E.g: p* =q* = 0.58 for uniform distribution in [-1,1] • E.g:

Forward and backward deviation measures – two point distribution example

Distribution not known • Suppose distribution is bounded in [-1,1] (but not necessarily symmetrical)

Only know mean and support

Forward and Backward Deviation Measures: Function g()

General Deviation Measures

General Deviation Measure

Agenda • Overview of Robust Optimization • Forward and Backward Deviation Measures • Uncertainty Sets and Probability Bounds • Conclusions

Uncertainty Sets and Probability Bounds • Model of Data Uncertainty • Recall: Affine Uncertainty : zero mean, independent but not necessarily identically distributed

Model of Data Uncertainty Uncertainty Sets and Probability Bounds

Uncertainty Sets and Probability Bounds • New Uncertainty Set (Asymmetrical)

Uncertainty Sets and Probability Bounds • Recall: Norm Uncertainty Set (Symmetrical)

Uncertainty Sets and Probability Bounds • Generalizes Symmetrical Uncertainty Set

Uncertainty Sets and Probability Bounds

Uncertainty Sets and Probability Bounds • Robust Counterpart

Uncertainty Sets and Probability Bounds • Probability Bound • More information achieve less conservative solution while preserving the bound. E.g • pj=qj= 1 for symmetric distribution in [-1,1] • pj =qj= 0.58 for uniform distribution in [-1,1]

Conclusions • RO framework • Affine uncertainty constraints • Independent r.v.’s with asymmetric distributions • Forward and backward Deviation measures • Defined from moment generating functions – implying probability bound • Sub-additivity – linear combinations • Easy to calculate and approximate from support information • Advantage -- less conservative solution • Next • Stochastic programming with chance constraints

Forward and Backward Deviation Measures and Robust Optimization

Forward and Backward Deviation Measures and Robust Optimization

Presentation Transcript

The Forward-Backward Method

Forward-backward algorithm

Robust Optimization and Applications in Machine Learning

Icebreakers: Christmas Forward and Backward

Robust Design and Two-Step Optimization

Forward and Backward Chaining

3.6 Robust Measures

Factors influencing Forward and Backward chaining

Robust Optimization

Robust Optimization and Applications

Forward-backward algorithm

Robust Solutions for Constraint Satisfaction and Optimization

Forward-backward algorithm

Backward and forward looking at dependable and secure computing

Backward and forward multiwave stimulated Raman scattering

Jets at the LHC: Looking Forward and Backward

Looking Backward, Guessing Forward

Forward and Backward Chaining

Robust Optimization and Applications in Machine Learning

Forward and Backward Chaining

TDWG – Looking Backward and Forward