Skip to content

Latest commit

 

History

History
50 lines (37 loc) · 6.6 KB

README.md

File metadata and controls

50 lines (37 loc) · 6.6 KB

The exact solution of LandS

This page is devoted to providing a proof on the exact solution of a classical stochastic optimization problem LandS (Louveaux & Smeer, 1988) on its most common version presented by Linderoth et al (2006) and available on this link. I also write this page as a way to encourage other researchers and practitioners to try the (Generalized) Adaptive Partition Method on their stochastic programmming problems.

What is LandS?

LandS is an energy planning investment problem, where the goal is to decide the capacities of four new plants while minimizing allocation and operational costs. The problem can be formulated as its deterministic equivalent formulation:

where S is a set of scenarios. In Linderoth et al (2006), authors propose to solve this problem where for each plant j=1..3 the demand djs has 100 equiprobable scenarios with values 0.04(i-1) for i=1...100. So the total number of scenarios is 106. Since is not possible (nowadays) to solve this formulation with such number of scenarios directly, this problem has been a classical instance to benchmark different methods and approximations for stochastic programs.

Which is the optimal solution?

The optimal solution is, as expected, x*=(0.84, 3.40, 1.88, 5.88) and the exact optimal value is 225.6294001.

How can I validate that this is true?

Well, using some aggregations and an exact optimization software like QSopt_ex (Espinoza et al, 2007), available here (https://github.com/jonls/qsopt-ex).

In this file, we present a partition of the 106 scenarios into 1374 subsets. For each subset P, we present the corresponding average demand djP and its probability (|P|/106). If you solve the problem for these aggregated scenarios, you get a lower bound of the optimal solution (because this is equivalent to aggregate the last constraints of the problem for each subset P). On the other hand, if you fix the solution x=(0.84, 3.40, 1.88, 5.88), then you can solve the remaining problem (more simply, solve each subproblem ys separately) and get an upper bound of the optimal solution. You should get the same bounds, showing the optimality of x*!

Very important: To do this, an exact solver is needed, like QSopt_ex, which use rational numbers to avoid rounding errors.

You can find here a Jupyter notebook to validate this result. It requires the Python interface of QSopt_ex from https://github.com/jonls/python-qsoptex.

How did you get this partition and this idea?

Using the marvelous Adaptive Partition Method (Song & Luedtke (2015), Ramirez-Pico & Moreno (2021)) for two-stage stochastic linear problems. Starting will all scenarios aggregated into a single one, you solve the problem and get a candidate solution x(t). Then, you solve the subproblems and refine the partition by grouping scenarios with the same optimal duals, and iterate. On the LandS problem, it only requires 8 iterations!.

You can find here a Jupyter notebook that solve this problem using the Adaptive Partition Method. It requires Gurobi (https://www.gurobi.com) as solver.

Who are you?

I'm Eduardo Moreno, professor at Universidad Adolfo Ibáñez, Santiago, Chile. Please visit my homepage and feel you free to contact me if you have any question or comment.

Bibliography and related publications

  • Espinoza, D., Applegate, D.L., Cook, W. & Dash, S. (2007). https://www.math.uwaterloo.ca/~bico/qsopt/ex/
  • Espinoza, D. & Moreno, E. (2014). A primal-dual aggregation algorithm for minimizing conditional value-at-risk in linear programs. Computational Optimization and Applications, 59(3):617–638. DOI:10.1007/s10589-014-9692-6
  • Forcier, M. & Leclère, V. (2021). Generalized adaptive partition-based method for two-stage stochastic linear programs: convergence and generalization. arXiv preprint arXiv:2109.04818
  • Linderoth, J., Shapiro, A. & Wright, S. (2006). The empirical behavior of sampling methods for stochastic programming. Annals of Operations Research, 142(1), 215-241. DOI:10.1007/s10479-006-6169-8
  • Louveaux, F.V. & Smeers, Y. (1988). Optimal investments for electricity generation: A stochastic model and a test problem. In Y. Ermoliev and R. J.-B. Wets, editors, Numerical techniques for stochastic optimization problems, pages 445–452. Springer-Verlag.
  • Pay, B.S. & Song, Y. (2020). Partition-based decomposition algorithms for two-stage stochastic integer programs with continuous recourse. Annals of Operations Research, 284:583—604. DOI:10.1007/s10479-017-2689-7
  • Ramirez-Pico, C. & Moreno, E. (2021). Generalized adaptive partition-based method for two-stage stochastic linear programs with fixed recourse. Mathematical Programming, to appear. DOI:10.1007/s10107-020-01609-8
  • Ramirez-Pico, C., Ljubić, I. & Moreno, E. (2022). Benders Adaptive-Cuts Method for Two-Stage Stochastic Programs. Submitted. Available at arXiv:2203.00752
  • Siddig, M. & Song, Y. (2022) Adaptive partition-based SDDP algorithms for multistage stochastic linear programming. Computational Optimization and Applications 81:201–250. DOI:10.1007/s10589-021-00323-1
  • Song, Y. & Luedtke, J. (2015). An adaptive partition-based approach for solving two-stage stochastic programs with fixed recourse. SIAM Journal on Optimization, 25(3), 1344-1367. DOI:10.1137/140967337
  • van Ackooij, W., de Oliveira, W. & Song, Y. (2018). Adaptive partition-based level decomposition methods for solving two-stage stochastic programs with fixed recourse. INFORMS Journal on Computing, 30(1):57–70. DOI:10.1287/ijoc.2017.0765