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Authors: Gerald Ogbonna (gco27), Hangyu Zhou (hz477), Roohi Menon (rm832), Vikram Raghavan (vr278) (SYSEN 6800 Fall 2021)
Authors: Roohi Menon, Hangyu Zhou, Gerald Ogbonna, Vikram Raghavan (SYSEN 6800 Fall 2021)


== Introduction ==
== Introduction ==
Stochastic Programming, also referred to as Stochastic Optimization, is a mathematical framework to help decision-making process under uncertainty <ref name=":0"> “Integration of Scheduling and Dynamic Optimization of Batch Processes under Uncertainty: Two-Stage Stochastic Programming Approach and Enhanced Generalized Benders Decomposition Algorithm,”Yunfei Chu and Fengqi You, Industrial & Engineering Chemistry Research 2013 52 (47), 16851-16869 DOI: 10.1021/ie402621t </ref>. With uncertainties being widespread, Stochastic Programming is a risk-neutral mathematical framework that finds application in areas, such as process systems engineering <ref name=":1">Li Can, Grossmann Ignacio E., “A Review of Stochastic Programming Methods for Optimization of Process Systems Under Uncertainty,” Frontiers in Chemical Engineering 2021, Vol. 2; DOI: 10.3389/fceng.2020.622241
[[File:Screen Shot 2021-11-28 at 10.02.36 AM.png|thumb|557x557px|Two-stage stochastic programming scheme: conceptual representation is on the left; scenario tree is on the right, where <math>x</math> denotes the first stage decisions, <math>y_{\omega}</math> denotes the second stage decisions for each scenario <math>\omega</math>. <math>\tau_{\omega}, h_{\omega}</math> denotes the probability and the constraints of each scenario, respectively. <ref name=":0">Li Can, Grossmann Ignacio E. [https://doi.org/10.3389/fceng.2020.622241 “A Review of Stochastic Programming Methods for Optimization of Process Systems Under Uncertainty,”] ''Frontiers in Chemical Engineering'' 2021, Vol. 2</ref>]]
</ref>. In process engineering, uncertainties are related to prices, purity of raw materials, customer demands, and yields of pilot reactors, among others. Batch processing has widely been adopted across process industries, and for the stated manufacturing process production scheduling is one of the most crucial decisions to be taken. In a deterministic optimization model, parameters, such as process of raw materials, availability of raw materials, price of different products, operation time and cost, and order demands are considered without factoring uncertainty. However, such assumptions are not realistic because uncertainty doesn’t come with a forewarning. Hence, uncertainty needs to be factored always <ref name=":3">“A Tutorial on Stochastic Programming,” Shapiro, Alexander and Philpott, Andy</ref>.  
 
Stochastic Programming is a mathematical framework to help decision-making under uncertainty. <ref name=":0" /> Deterministic optimization frameworks like the linear program (LP), nonlinear program (NLP), mixed-integer program (MILP), or mixed-integer nonlinear program (MINLP) are well-studied, playing a vital role in solving all kinds of optimization problems. But this sort of formulation assumes that one has perfect knowledge of the future outcome of the system, and the entire system is deterministic. <ref name=":1">J. Schif [https://www.eecs.tufts.edu/~aloupis/comp150/projects/Jeremy-S/2sLP-Report.pdf "The L Shaped Algorithm"]</ref> They tend to produce sub-optimal results in some real-world situations where uncertainties significantly impact the system behavior. To address this problem, stochastic programming extends the deterministic optimization methodology by introducing random variables that model the uncertain nature of real-world problems, trying to hedge against risks and find the optimal decision with the best-expected performance under all possible situations. With uncertainties being widespread, this general stochastic framework finds applications in a broad spectrum of problems across sectors, from electricity generation, financial planning, supply chain management to process systems engineering, mitigation of climate change, and pollution control, and many others. <ref name=":0" />
In conventional robust optimization, the assumption is made that all decision variables are realized before the realization of uncertainty. Such an approach makes the conventional robust optimization problem overly conservative <ref name=":3" />. Moreover, in manufacturing not all decisions need to be made “in-the-present,” a stagnated approach to decision making [two-stage approach] can also be adopted. Going beyond, Stochastic Programming framework can also be applied to a variety of problems across sectors, such as electricity generation, financial planning, supply chain management, mitigation of climate change, and pollution control <ref name=":1" />. The field has evolved from deterministic linear programming by introducing random variables <ref name=":6">Powell, W. B. (2019). A unified framework for stochastic optimization. European Journal of Operational Research, 275(3), 795-821. </ref>.  
 
Since its origin in the 1950s, the stochastic programming framework has been studied extensively. <ref name=":2">Dantzig, George B. [https://doi.org/10.1287/mnsc.1.3-4.197 “Linear Programming under Uncertainty.”] ''Management Science'', vol. 1, no. 3-4, 1955, pp. 197–206. </ref> A significant number of theoretical and algorithmic developments have been made to tackle uncertainty under different situations. To make an in-depth and fruitful investigation, we limited our topic to two-stage stochastic programming, the simplest form that focuses on situations with only one decision-making step. We will examine the most popular algorithm for solving such programs and discuss other aspects of this fascinating optimization framework.


== Theory, methodology, and/or algorithmic discussion ==
== Theory, methodology, and/or algorithmic discussion ==
Two-Stage Stochastic Linear Program with Fixed Recourse:


Modeling through stochastic programming is often adopted because of its proactive-reactive decision-making feature to address uncertainty <ref name=":0" />. Two-stage stochastic programming (TSP) is helpful when a problem requires the analysis of policy scenarios, however, the associated system information is inherently characterized with uncertainty <ref name=":1" />. In a typical TSP, decision variables of an optimization problem under uncertainty are categorized into two periods. Decisions regarding the first-stage variables need to be made before the realization of the uncertain parameters. The first-stage decision variables are proactive for they hedge against uncertainty and ensure that the solution performs well under all uncertainty realizations <ref name=":0" />. Once the uncertain events have unfolded/realized, it is possible to further design improvements or make operational adjustments through the values of the second-stage variables, also known as recourse, at a given cost. The second-stage variables are reactive in their response to the observed realization of uncertainty <ref name=":0" />. Thus, optimal decisions should be made on data that is available at the time the decision is being made. In such a setup, future observations are not taken into consideration <ref name=":2">Barik, S.K., Biswal, M.P. & Chakravarty, D. Two-stage stochastic programming problems involving interval discrete random variables. OPSEARCH 49, 280–298 (2012). <nowiki>https://doi.org/10.1007/s12597-012-0078-1</nowiki></ref>. Two-stage stochastic programming is suited for problems with a hierarchical structure, such as integrated process design, and planning and scheduling <ref name=":0" />.
Modeling through stochastic programming is often adopted because of its proactive-reactive decision-making feature to address uncertainty. <ref name=":3"> Chu, Yunfei, and Fengqi You. [https://doi.org/10.1021/ie402621t “Integration of Scheduling and Dynamic Optimization of Batch Processes under Uncertainty: Two-Stage Stochastic Programming Approach and Enhanced Generalized Benders Decomposition Algorithm.”] ''Industrial & Engineering Chemistry Research'', vol. 52, no. 47, 2013, pp. 16851–16869.</ref> Two-stage stochastic programming (TSP) is helpful when a problem requires the analysis of policy scenarios, however, the associated system information is inherently characterized with uncertainty. <ref name=":0" /> In a typical TSP, decision variables of an optimization problem under uncertainty are categorized into two periods. Decisions regarding the first-stage variables need to be made before the realization of the uncertain parameters. The first-stage decision variables are proactive for they hedge against uncertainty and ensure that the solution performs well under all uncertainty realizations. <ref name=":3" /> Once the uncertain events have unfolded/realized, it is possible to further design improvements or make operational adjustments through the values of the second-stage variables, also known as recourse, at a given cost. The second-stage variables are reactive in their response to the observed realization of uncertainty. <ref name=":3" /> Thus, optimal decisions should be made on data that is available at the time the decision is being made. In such a setup, future observations are not taken into consideration. <ref name=":4">Barik, S.K., Biswal, M.P. & Chakravarty, D. [https://doi.org/10.1007/s12597-012-0078-1 "Two-stage stochastic programming problems involving interval discrete random variables."] ''OPSEARCH'' 49, 280–298 (2012).</ref> Two-stage stochastic programming is suited for problems with a hierarchical structure, such as integrated process design, and planning and scheduling. <ref name=":3" />
 
=== Methodology ===       
The classical two-stage stochastic linear program with fixed recourse <ref name=":5">Soares, Joao, et al. [https://doi.org/10.1109/tia.2017.2723339 “Two-Stage Stochastic Model Using Benders’ Decomposition for Large-Scale Energy Resource Management in Smart Grids.”] ''IEEE Transactions on Industry Applications'', vol. 53, no. 6, 2017, pp. 5905–5914.</ref> is given below:
 
<math> \min z=c^Tx + E_{\xi}[\min q(\omega)^Ty(\omega)] </math>
 
<math> s.t. \quad Ax = b </math>
 
<math> \qquad \quad T(\omega)x + Wy(\omega) = h(\omega) </math>
 
<math> \qquad \quad x \ge 0, y(\omega) \ge 0 </math>
 
Where <math>c</math> is a known vector in <math>\mathbb{R}^{n_1}</math>, <math>b</math> is a known vector in <math>\mathbb{R}^{m_1}</math>. <math>A</math> and <math>W</math> are known matrices of size <math>m_1 \times n_1</math> and <math>m_2 \times n_2</math> respectively. <math>W</math> is known as the recourse matrix.
 
The first-stage decisions are represented by the <math>n_1 \times 1</math> vector <math>x</math>. Corresponding to <math>x</math> are the first-stage vectors and matrices <math>c</math>, <math>b</math>, and <math>A</math>. In the second stage, a number of random events <math>\omega \in \Omega</math> may realize. For a given realization <math>\omega</math>, the second-stage problem data <math>q(\omega)</math>, <math>h(\omega)</math>, and <math>T(\omega)</math> become known. <ref name=":6">Birge, John R., and François Louveaux. [https://link.springer.com/book/10.1007/978-1-4614-0237-4 "Introduction to Stochastic Programming."] Springer, 2011. </ref>
 
 
=== Algorithm discussion ===
 
To solve problems related to Two-Stage Linear Stochastic Programming more effectively, algorithms such as Benders decomposition or the Lagrangean decomposition can be used. Benders decomposition was presented by J.F Benders and is a decomposition method used widely to solve mixed-integer problems. The algorithm is based on the principle of decomposing the main problem into sub-problems. The master problem is defined with only the first-stage decision variables. Once the first-stage decisions are fixed at an optimal solution of the master problem, thereafter, the subproblems are solved and valid inequalities of x are derived and added to the master problem. On solving the master problem again, the algorithm iterates until the upper and lower bound converge. <ref name=":0" /> The Benders master problem is defined as being linear or mixed-integer and having fewer technical constraints, while the sub-problems could be linear or nonlinear in nature. The subproblems’ primary aim is to validate the feasibility of the master problem’s solution. <ref name=":5" /> Benders decomposition is also known as L-shaped decomposition because once the first stage variables, <math>x</math>, are fixed then the rest of the problem has a structure of a block-diagonal. This structure can be decomposed by scenario and solved independently. <ref name=":0" />
 
...
We assume that the random vector <math>\xi</math> has finite support. Let <math>k=1,\ldots,K</math> index possible second stage realizations and let <math>p_k</math> be the corresponding probabilities. With that, we could write down the deterministic equivalent of the stochastic program. This form is created by associating one set of second-stage decisions (<math>y_k</math>) to each realization of <math>\xi</math>, i.e., to each realization of <math>q_k</math>, <math>h_k</math>, and <math>T_k</math>. This large-scale deterministic counterpart of the original stochastic program is known as the ''extensive form'':
 
<div class="center" style="width: auto; margin-left: auto; margin-right: auto;">
<math>
\begin{align}
\min c^T x + \sum_{k=1}^{K} p_k & q_k^T y_k \\
s.t. \qquad \quad Ax &= b \\
T_kx + W_{y_k} &= h_k, &k=1,...,K \\
x \ge 0, y_k &\ge 0, &k=1,...,K \\
\end{align}
</math>
</div>
 
It is equivalent with the following formulation. The L-shape block structure of this extensive form gives rise to the name, L-shaped method.
<div class="center" style="width: auto; margin-left: auto; margin-right: auto;">
[[File:Lshape.png|thumb|200px|Block structure of the two-stage extensive form <ref name=":6" />]]
<math>
\begin{array}{lccccccccccccc}
\min & c^T x & + & p_1 q_1^T y_1 & + & p_2q_2^T y_2 & + & \cdots & + & p_K q_K^T y_K &  &  \\
s.t. & Ax & &  &  &  &  &  & &  & = & b \\
& T_1 x & + & W_1 y_1 &  &  &  &  &  &  & = & h_1 \\
& T_2 x & + &  &  & W_2y_2 &  &  & &  & = & h_2 \\
& \vdots &  &  &  &  &  & \ddots &  &  &  & \vdots \\
& T_s x & + &  &  &  &  &  &  & W_K y_K & = & h_K \\
& x\ge 0 & , & y_1 \ge 0 & , & y_2 \ge 0 &  & \ldots &  & y_K \ge 0  \\
\end{array}
</math>
</div>
 
 
==== L-Shaped Algorithm ====
Step 0. Set <math> r=s=v=0 </math>
Step 1. Set <math> v = v+1 </math>. Solve the following linear program (master program)
<div class="center" style="width: auto; margin-left: auto; margin-right: auto;">
<math>
\begin{align}
\min z =c^Tx &+ \theta\\
s.t.  Ax &=b & & & (1) \\
D_{\ell}x &\ge d_{\ell}, & \ell = 1, \ldots, r & & (2)\\
E_{\ell}x + \theta &\ge e_{\ell}, & \ell = 1, \ldots, s & & (3) \\
x &\ge 0, & \theta \in \mathbb{R} & & (4)
 
\end{align}
</math>
</div>
 
Let <math>(x^k, \theta ^k)</math> be an optimal solution. If there is no constraint (3), set <math>\theta ^k = -\infty</math>, <math>x^k</math> is defined by the remaining constraints.
 
Step 2. For <math>k = 1,\ldots,K</math> solve the following linear program:
<div class="center" style="width: auto; margin-left: auto; margin-right: auto;">
<math>
\begin{align}
\min &w' = e^Tv^+ + e^Tv^- \\
s.t. &Wy + Iv^+ - Iv^- = h_k - T_kx^v \\
&y \ge 0, v^+ \ge 0, v^- \ge 0 \\
\end{align}
</math>
</div>
where <math>e^T = (1,\ldots,1)</math>, <math>I</math> is the identity matrix. Until for some <math>k</math> the optimal value <math>w' > 0</math>. In this case, let <math>\sigma ^v</math> be the associated simplex multipliers and define
<div class="center" style="width: auto; margin-left: auto; margin-right: auto;">
<math>D_{r+1} = (\sigma ^v)^T T_k</math>
 
<math>d_{r+1} = (\sigma ^v)^T h_k</math>
</div>
to generate a constraint (called a <em>feasibility cut</em>) of type (2). Set <math>r=r+1</math>, add the constraint to the constraint set (2), and return to Step 1. If for all <math>k</math>, <math>w' = 0</math>, go to Step 3.
 
Step 3: For <math>k=1,\ldots,K</math> solve the linear program
<div class="center" style="width: auto; margin-left: auto; margin-right: auto;">
<math>
\begin{align}
\min &w = q^T_k y \\
s.t. &Wy = h_k - T_k x^v & & (4)\\
&y \ge 0
\end{align}
</math>
</div>
Let <math>\pi ^v_k</math> be the simplex multipliers associated with the optimal solution of Problem <math>k</math> of type (4). Define
<div class="center" style="width: auto; margin-left: auto; margin-right: auto;">
<math>E_{s+1} = \sum_{k=1}^K p_k(\pi ^v_k)^T T_k</math>
 
<math>e_{s+1} = \sum_{k=1}^K p_k(\pi ^v_k)^T h_k</math>
</div>
Let <math>w^v = e_{s+1}-E_{s+1}x^v</math>. If <math>\theta ^v \ge w^v</math>, stop; <math>x^v</math> is an optimal solution. Otherwise, set <math>s = s+1</math>, add to the constraint set (3) and return to Step 1.
 
This method approximates <math>\mathcal{L}</math> using an outer linearization. This approximation is achieved by the master program (1)-(4). It finds a proposal <math>x</math>, then sent it to the second stage. Two types of constraints are sequentially added: (i) <em>feasibility cuts</em> (2) determining <math>{x|\mathcal{L}(x) < +\infty}</math> and (ii) <em>optimality cuts</em> (3), which are linear approximations to <math>\mathcal{L}</math> on its domain of finiteness.
 
== Numerical Example ==
To illustrate the algorithm mentioned above, let's take a look at the following numerical example.
 
<math>
\begin{align}
z = \min 10{x_1} + 15&{x_2} + E_\xi (q_1y_1 + q_2y_2) \\
s.t. x_1 + x_2 &\le 12 \\
6y_1 + 10y_2 &\le 60x_1 \\
8y_1 + 5y_2 &\le 80x_2 \\
y_1 &\le d_1, y_2 \le d_2 \\
x_1 &\ge 4, x_2 \ge 2 \\
y_1, y_2 &\ge 0
 
\end{align}
</math>
 
where <math>\xi ^T = (d_1, d_2, q_1, q_2)</math> has 0.4 probability to be <math>\xi _1 = (50, 10, -2.4, -2.8)</math> and 0.6 probability to be <math>\xi _2 = (30, 30, -2.8, -3.2)</math>.
 
We should note that in this case, as <math>x \ge 0</math>, <math>d \ge 0</math> and <math>y_1, y_2 \ge 0</math>, the second stage is always feasible, which means <math> x \in K_2</math> always hold true. So we could skip the feasibility cuts (step 2) in all iterations. The <em>L</em>-shaped method iterations are shown below:
 
 
''' Iteration 1:'''
 
<em>Step 1.</em> With no <math>\theta </math>, the master program is <math>z = min\{10x_1 + 15x_2 | x_1 + x_2 \le 12, x_1 \ge 4, x_2 \ge 2\}</math>. Result is <math>x^1 = (4, 2)^T</math>. Set <math>\theta ^1 = -\infty </math>.
 
<em>Step 2.</em> No feasibility cut is needed.
 
<em>Step 3.</em>
* For <math>\xi = \xi _1</math>, solve:
:<math> w = min \{-2.4y_1 - 2.8y_2 | 6y_1 + 10y_2 \le 240, 8y_1 + 5y_2 \le 160, 0\le y_1 \le 50, 0\le y_2 \le 10 \} </math>
 
:The solution is <math>w_1 = -61, y^T = (13.75, 10), \pi _1^T = (0, -0.3, 0, -1.3)</math>
 
* For <math>\xi = \xi _2</math>, solve:
:<math> w = min \{-2.8y_1 - 3.2y_2 | 6y_1 + 10y_2 \le 240, 8y_1 + 5y_2 \le 160, 0\le y_1 \le 30, 0\le y_2 \le 30 \} </math>
 
:The solution is <math>w_2 = -83.84, y^T = (8, 19.2), \pi _2^T = (-0.232, -0.176, 0, 0)</math>
 
: Since <math>h_1 = (0, 0, 50, 10)^T, h_2 = (0, 0, 30, 30)^T </math>, we have
:<math>e_1 = 0.4\cdot \pi _1^T \cdot h_1 + 0.6\cdot \pi _2^T \cdot h_2 = 0.4 \times (-13) + 0.6 \times (0) = -5.2</math>
: Here, the matrix <math>T</math> is the same in these two scenarios, which is <math>\begin{bmatrix} -60 & 0 \\ 0 & -80 \\ 0 & 0 \\ 0 & 0 \end{bmatrix}</math>. Therefore, we have
 
:<math>E_1 = 0.4\cdot \pi _1^T \cdot T + 0.6\cdot \pi _2^T \cdot T = 0.4 \times (0, 24) + 0.6 \times (13.92, 14.08) = (8.352, 18.048)</math>
 
: Thus, <math>w^1 = -5.2 - (8.352, 18.048) \cdot x^1 = -74.704 > \theta ^1 = -\infty </math>, we add the cut
:<math>8.352x_1 + 18.048x_2 + \theta \ge -5.2</math>
 
 
''' Iteration 2:'''
 
<em>Step 1.</em> The master program is
 
:<math>
\begin{align}
z = min\{10x_1 + 15x_2 + \theta | x_1 + x_2 \le 12&, x_1 \ge 4, x_2 \ge 2, \\
&8.352x_1 + 18.048x_2 + \theta \ge -5.2\}
\end{align}
</math>
 
:Result is <math>z = -22.992, x^2 = (4, 8)^T, \theta ^2 = -182.992</math>.
 
<em>Step 2.</em> No feasibility cut is needed.
 
<em>Step 3.</em>
* For <math>\xi = \xi _1</math>, solve:
:<math> w = min \{-2.4y_1 - 2.8y_2 | 6y_1 + 10y_2 \le 240, 8y_1 + 5y_2 \le 640, 0\le y_1 \le 50, 0\le y_2 \le 10 \} </math>
 
:The solution is <math>w_1 = -96, y^T = (40, 0), \pi _1^T = (-0.4, 0, 0, 0)</math>
 
* For <math>\xi = \xi _2</math>, solve:
:<math> w = min \{-2.8y_1 - 3.2y_2 | 6y_1 + 10y_2 \le 240, 8y_1 + 5y_2 \le 640, 0\le y_1 \le 30, 0\le y_2 \le 30 \} </math>
 
:The solution is <math>w_2 = -103.2, y^T = (30, 6), \pi _2^T = (-0.32, 0, -0.88, 0)</math>
 
: Thus,
 
:<math> e_2 = 0.4\cdot \pi _1^T \cdot h_1 + 0.6\cdot \pi _2^T \cdot h_2 = 0.4 \times (0) + 0.6 \times (-26.4) = -15.84</math>
:<math>E_2 = 0.4\cdot \pi _1^T \cdot T + 0.6\cdot \pi _2^T \cdot T = 0.4 \times (24, 0) + 0.6 \times (19.2, 0) = (21.12, 0)</math>
 
: Since <math>w_2 = -15.84 - 21.12 \cdot 4 = -100.32 > -182.992</math>, add the cut
:<math>21.12x_1 + \theta \ge -15.84</math>
 
 
''' Iteration 3:'''
 
<em>Step 1.</em> The master program is
 
:<math>
\begin{align}
z = min\{10x_1 &+ 15x_2 + \theta | x_1 + x_2 \le 12, x_1 \ge 4, x_2 \ge 2, \\
&8.352x_1 + 18.048x_2 + \theta \ge -5.2, 21.12x_1 + \theta \ge -15.84\}
\end{align}
</math>
 
:Result is <math>z = -10.39375, x^3 = (6.6828, 5.3172)^T, \theta ^3 = -156.97994</math>.
 
<em>Step 2.</em> No feasibility cut is needed.
 
<em>Step 3.</em>
* For <math>\xi = \xi _1</math>, solve:
:<math> w = min \{-2.4y_1 - 2.8y_2 | 6y_1 + 10y_2 \le 400.968, 8y_1 + 5y_2 \le 425.376, 0\le y_1 \le 50, 0\le y_2 \le 10 \} </math>
 
:The solution is <math>w_1 = -140.6128, y^T = (46.922, 10), \pi _1^T = (0, -0.3, 0, -1.3)</math>
 
* For <math>\xi = \xi _2</math>, solve:
:<math> w = min \{-2.8y_1 - 3.2y_2 | 6y_1 + 10y_2 \le 400.968, 8y_1 + 5y_2 \le 425.376, 0\le y_1 \le 30, 0\le y_2 \le 30 \} </math>
 
:The solution is <math>w_2 = -154.7098, y^T = (30, 22.0968), \pi _2^T = (-0.32, 0, -0.88, 0)</math>
 
: Thus,
 
:<math> e_3 = 0.4\cdot \pi _1^T \cdot h_1 + 0.6\cdot \pi _2^T \cdot h_2 = 0.4 \times (-13) + 0.6 \times (-26.4) = -21.04</math>
:<math>E_3 = 0.4\cdot \pi _1^T \cdot T + 0.6\cdot \pi _2^T \cdot T = 0.4 \times (0, 24) + 0.6 \times (19.2, 0) = (11.52, 9.6)</math>
 
: Since <math>w_3 = -21.04 - 11.52 \cdot 6.6828 - 9.6 \cdot 5.3172 = -149.070976 > -156.97994</math>, add the cut
:<math>11.52x_1 + 9.6x_2 + \theta \ge -21.04</math>
 
 
''' Iteration 4:'''
 
<em>Step 1.</em> The master program is


Methodology:        
:<math>
\begin{align}
z = min\{10x_1 &+ 15x_2 + \theta | x_1 + x_2 \le 12, x_1 \ge 4, x_2 \ge 2, \\
&8.352x_1 + 18.048x_2 + \theta \ge -5.2, 21.12x_1 + \theta \ge -15.84, \\
&11.52x_1 + 9.6x_2 + \theta \ge -21.04\}
\end{align}
</math>


Algorithm discussion:  
:Result is <math>z = -8.895, x^4 = (4, 3.375)^T, \theta ^4 = -99.52</math>.


To solve problems related to Two-Stage Linear Stochastic Programming more effectively algorithms, such as Benders decomposition or the Lagrangean decomposition can be used. Benders decomposition was presented by J.F Benders, and is a decomposition method used widely to solve mixed-integer problems. The algorithm is based on the principle of decomposing the main problem into sub-problems. The master problem is defined with only the first-stage decision variables. Once the first-stage decisions are fixed at an optimal solution of the master problem, thereafter, the subproblems are solved and valid inequalities of x are derived and added to the master problem. On solving the master problem again, the algorithm iterates until the upper and lower bound converge <ref name=":1" />. The Benders master problem is defined as being linear or mixed-integer and having fewer technical constraints, while the sub-problems could be linear or nonlinear in nature. The subproblems’ primary aim is to validate the feasibility of the master problem’s solution <ref name=":7">Soares, J., Canizes, B., Ghazvini, M. A. F., Vale, Z., & Venayagamoorthy, G. K. (2017). Two-stage stochastic model using benders’ decomposition for large-scale energy resource management in smart grids. IEEE Transactions on Industry Applications, 53(6), 5905-5914.</ref>. Benders decomposition is also known as L-shaped decomposition because once the first stage variables, x, are fixed then the rest of the problem has a structure of a block-diagonal. This structure can be decomposed by scenario and solved independently <ref name=":1" />.
<em>Step 2.</em> No feasibility cut is needed.


== Numerical Example: ==
<em>Step 3.</em>
The farmer example and solution approach, for two-stage stochastic programming, is from Birge & Louveaux’s book on stochastic optimization (2011) <ref name=":10">Birge, John R., and Francois Louveaux. Introduction to stochastic programming. Springer Science & Business Media, 2011.</ref>. The initial problem statement is solved using a linear programming solver. However, this method fails to consider variability with respect to yields which is highly linked to weather conditions. Crop yields for a year can be termed as below average, average and above average. Yields have been fixed as 20% above and below the average given this, the farmer would like to understand how sensitive the optimal solution is to variations in yields. To address this, two optimization models – above average and below average- have been framed and executed.  
* For <math>\xi = \xi _1</math>, solve:
:<math> w = min \{-2.4y_1 - 2.8y_2 | 6y_1 + 10y_2 \le 240, 8y_1 + 5y_2 \le 270, 0\le y_1 \le 50, 0\le y_2 \le 10 \} </math>


Results from the two models suggest that when yields are high a small surface is sufficient to meet the minimum production requirement. However, when yields are low larger surface areas are needed to meet the minimum production requirement. In fact, with low yields corn must be purchased from the market to meet requirements. Thus, the key takeaway being that the optimal solution is sensitive to changes in yields. The farmer would benefit tremendously if they had access to the weather forecast. But, given the absence of perfect information the farmer must take a decision based on the existing data.  
:The solution is <math>w_1 = -88.8, y^T = (30, 6), \pi _1^T = (-0.208, -0.144, 0, 0)</math>


Among all the three crops, i.e., wheat, corn and sugar beets, making a decision pertaining to sugar beets cultivation seems difficult for the farmer. On the one hand, if the farmer were to dedicate large surface areas to sugar beet cultivation the farmer would certainly meet the requirement and sell at the quota, but would also have to sell the excess amount of sugar beets at the unfavorable price. On the other hand, if small surface areas were dedicated to sugar beet cultivation, then the farmer would miss the opportunity of selling at the quota (favorable) price. In the stated situation, the farmer realizes that a perfect decision cannot be taken - a decision that would work in all possible scenarios. The farmer would like to evaluate the benefits and losses of every decision at each stage, and to do so adopts the two-stage stochastic linear programming approach.
* For <math>\xi = \xi _2</math>, solve:
:<math> w = min \{-2.8y_1 - 3.2y_2 | 6y_1 + 10y_2 \le 240, 8y_1 + 5y_2 \le 270, 0\le y_1 \le 30, 0\le y_2 \le 30 \} </math>


In the first stage, decisions that are to be taken ‘now’, are those pertaining to land assignment of each crop. Let land assignment to wheat be ‘x1’, land assignment to corn be ‘x2’ and land assignment to sugar beets be ‘x3’. While decisions pertaining to sales and purchases depend on the yield. The second-stage variables can be indexed based on scenarios, where ‘s1’ corresponds to above average yields, ‘s2’ corresponds to average yields and ‘s3’ corresponds to below average yields. If the farmer seeks to maximize long-run profit then the three defined scenarios have an equal probability of 1/3. Given how explicitly the second- stage variables have been defined, this problem can be considered as an extensive form of stochastic programming. Having stated the approach, the problem can be formulated as given below:
: There are multiple optimal solutions. Selecting one of them, we have


<math>\min 150{x_1} + 230{x_2} + 260{x_3} - 13(170w_{11} - 238y_{11} + 150w_{21} - 210y_{21} + 36w_{31} + 10w_{41}) - 13(170w_{12} - 238y_{12} + 150w_{22} - 210y_{22} + 36w_{32} + 10w_{42}) - 13(170w_{13} - 238y_{13} + 150w_{23} - 210y_{23} + 36w_{33} + 10w_{43})</math>
:<math> e_4 = 0</math>
:<math>E_4 = (13.344, 13.056)</math>


<math>s.t. \quad x_{1} + x_{2} + x_{3} \le 500</math>
: Since <math>w_3 = 0 - 13.344 \cdot 4 - 13.056 \cdot 3.375 = -97.44 > -99.52</math>, add the cut
:<math>13.344x_1 + 13.056x_2 + \theta \ge 0</math>


<math>\qquad \quad 3x_{1} + y_{11} - w_{11} \ge 200</math>


<math>\qquad \quad 3.6x_{2} + y_{21} - w_{21} \ge 240</math>
''' Iteration 5:'''


<math>\qquad \quad w_{31} + w_{41} \le 24x_{3}, w_{31} \le 6000</math>
<em>Step 1.</em> The master program is


<math>\qquad \quad 2.5x_{1} + y_{12} + w_{12} \ge 200</math>
:<math>
\begin{align}
z = min\{10x_1 &+ 15x_2 + \theta | x_1 + x_2 \le 12, x_1 \ge 4, x_2 \ge 2, \\
&8.352x_1 + 18.048x_2 + \theta \ge -5.2, 21.12x_1 + \theta \ge -15.84, \\
&11.52x_1 + 9.6x_2 + \theta \ge -21.04, 13.344x_1 + 13.056x_2 + \theta \ge 0\}
\end{align}
</math>


<math>\qquad \quad 3x_{2} + y_{22} - w_{22} \ge 240</math>
:Result is <math>z = -8.5583, x^5 = (4.6667, 3.625)^T, \theta ^5 = -109.6</math>.


<math>\qquad \quad w_{32} + w_{42} \le 20x_{3}</math>
<em>Step 2.</em> No feasibility cut is needed.


<math>\qquad \quad w_{32} \le 6000</math>
<em>Step 3.</em>
* For <math>\xi = \xi _1</math>, solve:
:<math> w = min \{-2.4y_1 - 2.8y_2 | 6y_1 + 10y_2 \le 280, 8y_1 + 5y_2 \le 290, 0\le y_1 \le 50, 0\le y_2 \le 10 \} </math>


<math>\qquad \quad 2x_{1} + y_{13} - w_{13} \ge 200</math>
:The solution is <math>w_1 = -100, y^T = (30, 10), \pi _1^T = (0, -0.3, 0, -1.3)</math>


<math>\qquad \quad 2.4x_{2} + y_{23} - w_{23} \ge 240</math>
* For <math>\xi = \xi _2</math>, solve:
:<math> w = min \{-2.8y_1 - 3.2y_2 | 6y_1 + 10y_2 \le 280, 8y_1 + 5y_2 \le 290, 0\le y_1 \le 30, 0\le y_2 \le 30 \} </math>


<math>\qquad \quad w_{33} + w_{43} \le 16x_{3}</math>
:The solution is <math>w_2 = -116, y^T = (30, 10), \pi _2^T = (-0.232, -0.176, 0, 0)</math>


<math>\qquad \quad w_{33} \le 6000</math>
: Thus,


<math>\qquad \quad x, y, w \ge 0</math>
:<math> e_5 = 0.4\cdot \pi _1^T \cdot h_1 + 0.6\cdot \pi _2^T \cdot h_2 = 0.4 \times (-13) + 0.6 \times (0) = -5.2</math>
:<math>E_5 = 0.4\cdot \pi _1^T \cdot T + 0.6\cdot \pi _2^T \cdot T = 0.4 \times (0, 24) + 0.6 \times (13.92, 14.08) = (8.352, 18.048)</math>


{| class="wikitable"
: Since <math>w_5 = -5.2 - 8.352 \cdot 4.6667 - 18.048 \cdot 3.625 = -109.6 = \theta ^5</math>, stop.
|
|
|Wheat
|Corn
|Sugar beets
|-
|First decision
|Area in terms of Acres
|170
|80
|250
|-
| rowspan="3" |s=1 (above average yield)
|Yield (t)
|510
|288
|6000
|-
|Sales (t)
|310
|48
|6000 (favorable price)
|-
|Purchase (t)
|<nowiki>-</nowiki>
|<nowiki>-</nowiki>
|<nowiki>-</nowiki>
|-
| rowspan="3" |s=2 (average yield)
|Yield (t)
|425
|240
|5000
|-
|Sales (t)
|225
|<nowiki>-</nowiki>
|5000 (favorable price)
|-
|Purchase (t)
|<nowiki>-</nowiki>
|<nowiki>-</nowiki>
|<nowiki>-</nowiki>
|-
| rowspan="3" |s=3 (below average yield)
|Yield (t)
|340
|192
|4000
|-
|Sales (t)
|140
|<nowiki>-</nowiki>
|4000(favorable price)
|-
|Purchase (t)
|<nowiki>-</nowiki>
|48
|
|-
|Overall profit ($)
| colspan="4" |108,390
|}
Table A: Solution from the two-stage linear stochastic model.  


The solution showcases a key aspect, under uncertainty finding a solution that works for all circumstances is quite not possible. For one, the farmer would always have to decide on the trade-off between selling some sugar beets at an unfavorable price or having some unused quota. Such a predicament would never arise if the farmer had access to a perfect weather forecast. Given the uncertainty, stochastic programming helps model balanced decisions
:<math>x_5 = (4.6667, 3.625)^T</math> is the optimal solution.


== Applications ==
== Applications ==
Apart from the process industry, two-stage linear stochastic programming finds application in other fields as well. For instance, in the optimal design of distributed energy systems there are various uncertainties that need to be considered. Uncertainty related to aspects such as, demand and supply of energy, economic factors like unit investment cost and energy price, and uncertainty related to technology parameters like efficiency. Zhou et al. <ref name=":8">Zhe Zhou, Jianyun Zhang, Pei Liu, Zheng Li, Michael C. Georgiadis, Efstratios N. Pistikopoulos, “A two-stage stochastic programming model for the optimal design of distributed energy systems,” Applied Energy, Volume 103, 2013, Pages 135-144, ISSN 0306-2619, <nowiki>https://doi.org/10.1016/j.apenergy.2012.09.019</nowiki>.</ref>, developed a two-stage stochastic programming model for the optimal design of a distributed energy system with a stage decomposition based solution strategy. The authors accounted for both demand and supply uncertainty. They used the genetic algorithm on the first stage variables and the Monte Carlo method on the second-stage variables.  
Apart from the process industry, two-stage linear stochastic programming finds application in other fields as well. For instance, in the optimal design of distributed energy systems, there are various uncertainties that need to be considered. Uncertainty is related to aspects such as demand and supply of energy, economic factors like unit investment cost and energy price, and uncertainty related to technical parameters like efficiency. <ref name=":7">Zhe Zhou, Jianyun Zhang, Pei Liu, Zheng Li, Michael C. Georgiadis, Efstratios N. Pistikopoulos, [https://doi.org/10.1016/j.apenergy.2012.09.019 “A two-stage stochastic programming model for the optimal design of distributed energy systems,”] ''Applied Energy'', Volume 103, 2013, Pages 135-144, ISSN 0306-2619.</ref>, developed a two-stage stochastic programming model for the optimal design of a distributed energy system with a stage decomposition-based solution strategy. The authors accounted for both demand and supply uncertainty. They used the genetic algorithm on the first stage variables and the Monte Carlo method on the second-stage variables.  


Another application of the two-stage linear stochastic programming is in the bike-sharing system (BSS). The system needs to ensure that bikes are available at all stations per the given demand. To ensure this balance, redistribution trucks are used to transfer bikes from one bike surplus station to a bike deficient station. Such a problem is referred to as the bike repositioning problem (BRS) in the aforementioned system <ref name=":9">Qiong Tang, Zhuo Fu, Dezhi Zhang, Hao Guo, Minyi Li, "Addressing the Bike Repositioning Problem in Bike Sharing System: A Two-Stage Stochastic Programming Model", Scientific Programming, vol. 2020, Article ID 8868892, 12 pages, 2020.<nowiki>https://doi.org/10.1155/2020/8868892</nowiki>
Another application of the two-stage linear stochastic programming is in the bike-sharing system (BSS). The system needs to ensure that bikes are available at all stations per the given demand. To ensure this balance, redistribution trucks are used to transfer bikes from one bike surplus station to a bike deficient station. Such a problem is referred to as the bike repositioning problem (BRS) in the aforementioned system. <ref name=":8">Qiong Tang, Zhuo Fu, Dezhi Zhang, Hao Guo, Minyi Li, [https://doi.org/10.1155/2020/8868892 "Addressing the Bike Repositioning Problem in Bike Sharing System: A Two-Stage Stochastic Programming Model,"] ''Scientific Programming'', vol. 2020, Article ID 8868892, 12 pages, 2020.</ref> Another challenge related to BRP is the aspect related to the holding cost of the depot. While transferring bikes from one station to another they could get damaged or be lost in the process which could lead to an imbalance between demand and supply in the BSS. As for bikes that cannot be balanced among the stations of the BSS are either placed back at the depot to increase the holding cost of the depot. To address the stated concerns, researchers developed a two-stage stochastic program that would capture the uncertainty related to redistribution of demand within the system. <ref name=":8" /> In the first stage, before the realization of redistribution demand, a decision regarding routing was made. In the second stage, decisions regarding loading/unloading at each station and depot are made. Holding cost is incorporated into the model, such that the model’s primary objective is to determine the best routes of the repositioning truck and the optimal loading/unloading quantities at each station and depot. The model is framed to minimize the expected total sum of transportation cost, the penalty cost of all stations, and the holding cost of the depot.
</ref>. Another challenge related to BRP is the aspect related to the holding cost of the depot. While transferring bikes from one station to another they could get damaged or be lost in the process which could lead to imbalance between demand and supply in the BSS. As for bikes that cannot be balanced among the stations of the BSS are either placed back at the depot at increasing holding cost of the depot. To address the stated concerns, Tang et al <ref name=":9" />, developed a two-stage stochastic program that would capture the uncertainty related to redistribution of demand within the system. In the first-stage, before the realization of redistribution demand, a decision regarding routing was made. In the second-stage, decisions regarding loading/unloading at each station and depot are made. Holding cost is incorporated into the model, such that the model’s primary objective is to determine the best routes of the repositioning truck and the optimal loading/unloading quantities at each station and depot. The model is framed to minimize the expected total sum of transportation cost, the penalty cost of all stations and the holding cost of the depot.  


== Conclusion ==
== Conclusion ==
From the previous examples it is evident that two-stage linear stochastic programming finds applicability across many areas, such as petrochemical, pharmaceutical industry, carbon capture and energy storage among others <ref name=":1" />. Stochastic programming can primarily be used to model two types of uncertainties: 1) exogenous uncertainty, which is the most widely considered one, and 2) endogenous uncertainty, where realization regarding uncertainty depends on the decision taken. Main challenge, with respect to stochastic programming, is that the type of problems that can be solved is limited. An ‘ideal’ problem would be multi-stage stochastic mixed-integer nonlinear programming under both exogenous and endogenous uncertainty with an arbitrary probability distribution that is stagewise dependent <ref name=":1" />. However, current algorithms, in terms of development and computation resources, are still limited with respect to ability to solve the ‘ideal’ problem.  
From the previous examples, it is evident that two-stage linear stochastic programming finds applicability across many areas, such as the petrochemical, pharmaceutical industry, carbon capture, and energy storage among others. <ref name=":0" /> Stochastic programming can primarily be used to model two types of uncertainties: 1) exogenous uncertainty, which is the most widely considered one, and 2) endogenous uncertainty, where realization regarding uncertainty depends on the decision taken. The main challenge, with respect to stochastic programming, is that the type of problems that can be solved is limited. An ‘ideal’ problem would be multi-stage stochastic mixed-integer nonlinear programming under both exogenous and endogenous uncertainty with an arbitrary probability distribution that is stagewise dependent. <ref name=":0" /> However, current algorithms, in terms of development and computation resources, are still limited with respect to the ability to solve the ‘ideal’ problem.  


== References ==
== References ==

Latest revision as of 23:59, 15 December 2021

Authors: Roohi Menon, Hangyu Zhou, Gerald Ogbonna, Vikram Raghavan (SYSEN 6800 Fall 2021)

Introduction

Two-stage stochastic programming scheme: conceptual representation is on the left; scenario tree is on the right, where denotes the first stage decisions, denotes the second stage decisions for each scenario . denotes the probability and the constraints of each scenario, respectively. [1]

Stochastic Programming is a mathematical framework to help decision-making under uncertainty. [1] Deterministic optimization frameworks like the linear program (LP), nonlinear program (NLP), mixed-integer program (MILP), or mixed-integer nonlinear program (MINLP) are well-studied, playing a vital role in solving all kinds of optimization problems. But this sort of formulation assumes that one has perfect knowledge of the future outcome of the system, and the entire system is deterministic. [2] They tend to produce sub-optimal results in some real-world situations where uncertainties significantly impact the system behavior. To address this problem, stochastic programming extends the deterministic optimization methodology by introducing random variables that model the uncertain nature of real-world problems, trying to hedge against risks and find the optimal decision with the best-expected performance under all possible situations. With uncertainties being widespread, this general stochastic framework finds applications in a broad spectrum of problems across sectors, from electricity generation, financial planning, supply chain management to process systems engineering, mitigation of climate change, and pollution control, and many others. [1]

Since its origin in the 1950s, the stochastic programming framework has been studied extensively. [3] A significant number of theoretical and algorithmic developments have been made to tackle uncertainty under different situations. To make an in-depth and fruitful investigation, we limited our topic to two-stage stochastic programming, the simplest form that focuses on situations with only one decision-making step. We will examine the most popular algorithm for solving such programs and discuss other aspects of this fascinating optimization framework.

Theory, methodology, and/or algorithmic discussion

Modeling through stochastic programming is often adopted because of its proactive-reactive decision-making feature to address uncertainty. [4] Two-stage stochastic programming (TSP) is helpful when a problem requires the analysis of policy scenarios, however, the associated system information is inherently characterized with uncertainty. [1] In a typical TSP, decision variables of an optimization problem under uncertainty are categorized into two periods. Decisions regarding the first-stage variables need to be made before the realization of the uncertain parameters. The first-stage decision variables are proactive for they hedge against uncertainty and ensure that the solution performs well under all uncertainty realizations. [4] Once the uncertain events have unfolded/realized, it is possible to further design improvements or make operational adjustments through the values of the second-stage variables, also known as recourse, at a given cost. The second-stage variables are reactive in their response to the observed realization of uncertainty. [4] Thus, optimal decisions should be made on data that is available at the time the decision is being made. In such a setup, future observations are not taken into consideration. [5] Two-stage stochastic programming is suited for problems with a hierarchical structure, such as integrated process design, and planning and scheduling. [4]

Methodology

The classical two-stage stochastic linear program with fixed recourse [6] is given below:

Where is a known vector in , is a known vector in . and are known matrices of size and respectively. is known as the recourse matrix.

The first-stage decisions are represented by the vector . Corresponding to are the first-stage vectors and matrices , , and . In the second stage, a number of random events may realize. For a given realization , the second-stage problem data , , and become known. [7]


Algorithm discussion

To solve problems related to Two-Stage Linear Stochastic Programming more effectively, algorithms such as Benders decomposition or the Lagrangean decomposition can be used. Benders decomposition was presented by J.F Benders and is a decomposition method used widely to solve mixed-integer problems. The algorithm is based on the principle of decomposing the main problem into sub-problems. The master problem is defined with only the first-stage decision variables. Once the first-stage decisions are fixed at an optimal solution of the master problem, thereafter, the subproblems are solved and valid inequalities of x are derived and added to the master problem. On solving the master problem again, the algorithm iterates until the upper and lower bound converge. [1] The Benders master problem is defined as being linear or mixed-integer and having fewer technical constraints, while the sub-problems could be linear or nonlinear in nature. The subproblems’ primary aim is to validate the feasibility of the master problem’s solution. [6] Benders decomposition is also known as L-shaped decomposition because once the first stage variables, , are fixed then the rest of the problem has a structure of a block-diagonal. This structure can be decomposed by scenario and solved independently. [1]

... We assume that the random vector has finite support. Let index possible second stage realizations and let be the corresponding probabilities. With that, we could write down the deterministic equivalent of the stochastic program. This form is created by associating one set of second-stage decisions () to each realization of , i.e., to each realization of , , and . This large-scale deterministic counterpart of the original stochastic program is known as the extensive form:

It is equivalent with the following formulation. The L-shape block structure of this extensive form gives rise to the name, L-shaped method.

Block structure of the two-stage extensive form [7]


L-Shaped Algorithm

Step 0. Set Step 1. Set . Solve the following linear program (master program)

Let be an optimal solution. If there is no constraint (3), set , is defined by the remaining constraints.

Step 2. For solve the following linear program:

where , is the identity matrix. Until for some the optimal value . In this case, let be the associated simplex multipliers and define

to generate a constraint (called a feasibility cut) of type (2). Set , add the constraint to the constraint set (2), and return to Step 1. If for all , , go to Step 3.

Step 3: For solve the linear program

Let be the simplex multipliers associated with the optimal solution of Problem of type (4). Define

Let . If , stop; is an optimal solution. Otherwise, set , add to the constraint set (3) and return to Step 1.

This method approximates using an outer linearization. This approximation is achieved by the master program (1)-(4). It finds a proposal , then sent it to the second stage. Two types of constraints are sequentially added: (i) feasibility cuts (2) determining and (ii) optimality cuts (3), which are linear approximations to on its domain of finiteness.

Numerical Example

To illustrate the algorithm mentioned above, let's take a look at the following numerical example.

where has 0.4 probability to be and 0.6 probability to be .

We should note that in this case, as , and , the second stage is always feasible, which means always hold true. So we could skip the feasibility cuts (step 2) in all iterations. The L-shaped method iterations are shown below:


Iteration 1:

Step 1. With no , the master program is . Result is . Set .

Step 2. No feasibility cut is needed.

Step 3.

  • For , solve:
The solution is
  • For , solve:
The solution is
Since , we have
Here, the matrix is the same in these two scenarios, which is . Therefore, we have
Thus, , we add the cut


Iteration 2:

Step 1. The master program is

Result is .

Step 2. No feasibility cut is needed.

Step 3.

  • For , solve:
The solution is
  • For , solve:
The solution is
Thus,
Since , add the cut


Iteration 3:

Step 1. The master program is

Result is .

Step 2. No feasibility cut is needed.

Step 3.

  • For , solve:
The solution is
  • For , solve:
The solution is
Thus,
Since , add the cut


Iteration 4:

Step 1. The master program is

Result is .

Step 2. No feasibility cut is needed.

Step 3.

  • For , solve:
The solution is
  • For , solve:
There are multiple optimal solutions. Selecting one of them, we have
Since , add the cut


Iteration 5:

Step 1. The master program is

Result is .

Step 2. No feasibility cut is needed.

Step 3.

  • For , solve:
The solution is
  • For , solve:
The solution is
Thus,
Since , stop.
is the optimal solution.

Applications

Apart from the process industry, two-stage linear stochastic programming finds application in other fields as well. For instance, in the optimal design of distributed energy systems, there are various uncertainties that need to be considered. Uncertainty is related to aspects such as demand and supply of energy, economic factors like unit investment cost and energy price, and uncertainty related to technical parameters like efficiency. [8], developed a two-stage stochastic programming model for the optimal design of a distributed energy system with a stage decomposition-based solution strategy. The authors accounted for both demand and supply uncertainty. They used the genetic algorithm on the first stage variables and the Monte Carlo method on the second-stage variables.  

Another application of the two-stage linear stochastic programming is in the bike-sharing system (BSS). The system needs to ensure that bikes are available at all stations per the given demand. To ensure this balance, redistribution trucks are used to transfer bikes from one bike surplus station to a bike deficient station. Such a problem is referred to as the bike repositioning problem (BRS) in the aforementioned system. [9] Another challenge related to BRP is the aspect related to the holding cost of the depot. While transferring bikes from one station to another they could get damaged or be lost in the process which could lead to an imbalance between demand and supply in the BSS. As for bikes that cannot be balanced among the stations of the BSS are either placed back at the depot to increase the holding cost of the depot. To address the stated concerns, researchers developed a two-stage stochastic program that would capture the uncertainty related to redistribution of demand within the system. [9] In the first stage, before the realization of redistribution demand, a decision regarding routing was made. In the second stage, decisions regarding loading/unloading at each station and depot are made. Holding cost is incorporated into the model, such that the model’s primary objective is to determine the best routes of the repositioning truck and the optimal loading/unloading quantities at each station and depot. The model is framed to minimize the expected total sum of transportation cost, the penalty cost of all stations, and the holding cost of the depot.

Conclusion

From the previous examples, it is evident that two-stage linear stochastic programming finds applicability across many areas, such as the petrochemical, pharmaceutical industry, carbon capture, and energy storage among others. [1] Stochastic programming can primarily be used to model two types of uncertainties: 1) exogenous uncertainty, which is the most widely considered one, and 2) endogenous uncertainty, where realization regarding uncertainty depends on the decision taken. The main challenge, with respect to stochastic programming, is that the type of problems that can be solved is limited. An ‘ideal’ problem would be multi-stage stochastic mixed-integer nonlinear programming under both exogenous and endogenous uncertainty with an arbitrary probability distribution that is stagewise dependent. [1] However, current algorithms, in terms of development and computation resources, are still limited with respect to the ability to solve the ‘ideal’ problem.

References

  1. 1.0 1.1 1.2 1.3 1.4 1.5 1.6 1.7 Li Can, Grossmann Ignacio E. “A Review of Stochastic Programming Methods for Optimization of Process Systems Under Uncertainty,” Frontiers in Chemical Engineering 2021, Vol. 2
  2. J. Schif "The L Shaped Algorithm"
  3. Dantzig, George B. “Linear Programming under Uncertainty.” Management Science, vol. 1, no. 3-4, 1955, pp. 197–206.
  4. 4.0 4.1 4.2 4.3 Chu, Yunfei, and Fengqi You. “Integration of Scheduling and Dynamic Optimization of Batch Processes under Uncertainty: Two-Stage Stochastic Programming Approach and Enhanced Generalized Benders Decomposition Algorithm.” Industrial & Engineering Chemistry Research, vol. 52, no. 47, 2013, pp. 16851–16869.
  5. Barik, S.K., Biswal, M.P. & Chakravarty, D. "Two-stage stochastic programming problems involving interval discrete random variables." OPSEARCH 49, 280–298 (2012).
  6. 6.0 6.1 Soares, Joao, et al. “Two-Stage Stochastic Model Using Benders’ Decomposition for Large-Scale Energy Resource Management in Smart Grids.” IEEE Transactions on Industry Applications, vol. 53, no. 6, 2017, pp. 5905–5914.
  7. 7.0 7.1 Birge, John R., and François Louveaux. "Introduction to Stochastic Programming." Springer, 2011.
  8. Zhe Zhou, Jianyun Zhang, Pei Liu, Zheng Li, Michael C. Georgiadis, Efstratios N. Pistikopoulos, “A two-stage stochastic programming model for the optimal design of distributed energy systems,” Applied Energy, Volume 103, 2013, Pages 135-144, ISSN 0306-2619.
  9. 9.0 9.1 Qiong Tang, Zhuo Fu, Dezhi Zhang, Hao Guo, Minyi Li, "Addressing the Bike Repositioning Problem in Bike Sharing System: A Two-Stage Stochastic Programming Model," Scientific Programming, vol. 2020, Article ID 8868892, 12 pages, 2020.