会议形式:网络会议
会议日期:2020年9月25日上午 8:50-11:20
加入方式:腾讯会议ID: 870 938 043 密码:9999
会议日程:
主持人:李欣欣 |
时间 |
报告人 |
题目 |
08:50-09:25 |
蔡邢菊 |
Some Inertial Alternating Proximal(-Like) Gradient Methods for a Class of Nonconvex Optimization Problems |
09:25-10:00 |
韩德仁 |
Some Extended Proximal Point Algorithms with Applications |
10:00-10:10 |
休息 |
主持人:宋海明 |
10:10-10:45 |
张在坤 |
A Space Decomposition Framework for Nonlinear Optimization |
10:45-11:20 |
孙海琳 |
Decomposition Methods for Solving Two-Stage Distributionally Robust Optimization Problems |
题目:Some Inertial Alternating Proximal(-like) Gradient Methods for a Class of Nonconvex optimization problems
报告人: 蔡邢菊 副教授
南京师范大学
摘要:We study a broad class of nonconvex nonsmooth minimization problems, whose objective function is the sum of a function of the entire variables and two nonconvex functions of each variable. For the different cases, we linearized different fart of the objective function, adopting inertial strategy to accelerate the convergence. We also propose an inertial alternating proximal-like gradient descent algorithm for the problem with abstract constraint sets whose geometry can be captured by using the domain of kernel generating distances. This algorithm can circumvent the restrictive assumption of global Lipschitz continuity of gradient. We prove that each bounded sequence generated by these algorithms globally converge to a critical point of the problem under the assumption that the underlying functions satisfy the Kurdyka-Łojasiewicz property.
报告题目:Some Extended Proximal Point Algorithms with Applications
报告人: 韩德仁 教授
北京航空航天大学数学科学学院
摘要:The proximal point algorithm (PPA) has been widely used in convex optimization. Many algorithms fall into the framework of PPA. To guarantee the convergence of the PPA, however, existing results conventionally need to ensure the positive definiteness of the corresponding proximal measure. In this talk, we present some useful extensions of PPA.
题目:A Space Decomposition Framework for Nonlinear Optimization
报告人:张在坤 博士
香港理工大学
摘要:Space decomposition has been a popular methodology in both the community of optimization and that of numerical PDEs. Under the name of Domain Decomposition Methods, the latter community has developed highly successful techniques like Restricted Additive Schwarz and Coarse Grid. Being crucial for the performance of Domain Decomposition Methods, these techniques are however less studied in optimization. This talk presents a framework that allows us to extend these techniques to general nonlinear optimization. We establish the global convergence and convergence rate of the framework. Numerical results, although preliminary, show the Restricted Additive Schwarz and Coarse Grid (now Coarse Space) techniques can effectively accelerate space decomposition methods as they do in Domain Decomposition Methods.
This is a joint work with Serge Gratton (ENSEEIHT/INPT, University of Toulouse) and Luis Nunes Vicente (Liehigh University).
题目:Decomposition Methods for Solving Two-Stage Distributionally Robust Optimization Problems
报告人:孙海琳 教授
南京师范大学
摘要:Decomposition methods have been well studied for solving two-stage and multi-stage stochastic programming problems. In this paper, we propose an algorithmic framework based on the fundamental ideas of the methods for solving two-stage minimax distributionally robust optimization (DRO) problems where the underlying random variables take a finite number of distinct values. This is achieved by introducing nonanticipativity constraint for the first stage decision variables, rearranging the minimax problem through Lagrange decomposition and applying the well-known primal-dual hybrid gradient (PDHG) method to the new minimax problem. The algorithmic framework does not depend on specific structure of the ambiguity set. To extend the algorithm to the case that the underlying random variables are continuously distributed, we propose a discretization scheme and quantify the error arising from the discretization in terms of the optimal value and the optimal solutions when the ambiguity set is constructed through generalized prior moment conditions, the Kantorovich ball and $\phi$-divergence centred at an empirical probability distribution. Some preliminary numerical tests show the proposed decomposition algorithm featured with parallel computing performs well.