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Transcript of Introduction to Multistage Stochastic Programming Ryan Goodfellow – COSMO Laboratory.
![Page 1: Introduction to Multistage Stochastic Programming Ryan Goodfellow – COSMO Laboratory.](https://reader034.fdocuments.net/reader034/viewer/2022052308/56649ccb5503460f94994cca/html5/thumbnails/1.jpg)
Introduction to Multistage Stochastic Programming
Ryan Goodfellow – COSMO Laboratory
![Page 2: Introduction to Multistage Stochastic Programming Ryan Goodfellow – COSMO Laboratory.](https://reader034.fdocuments.net/reader034/viewer/2022052308/56649ccb5503460f94994cca/html5/thumbnails/2.jpg)
Outline
• Overview of multistage optimization
• Modelling example – investment portfolio
• Application – multistage optimization of long-term production schedules for open pit mines
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References• Books:
– Shapiro, Dentcheva, Ruszyynski (2009) Lectures on Stochastic Programming: Modeling and Theory. Chapter 3. E-book available through McGill library (i.e. FREE for students).
– King & Wallace (2012) Modeling with Stochastic Programming.
• Online lecture notes:– Linderoth (2003) Multistage Stochastic Programming.
http://homepages.cae.wisc.edu/~linderot/classes/ie495/lecture21.pdf
• Application:– Boland, Dumitrescu, Froyland (2008) A Multistage Stochastic Programming
Approach to Open Pit Mine Production Scheduling with Uncertain Geology http://www.optimization-online.org/DB_FILE/2008/10/2123.pdf
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Introduction
• Two-stage stochastic optimization1. Make a set of decisions (first-stage)2. Profit from outcome or clean up the mess (recourse)
• Multistage stochastic optimization– Information is slowly revealed over time:
1. Make a decision for today (t) based on what I know today.2. Observe the outcome from stochastic process in time t.3. Set t = t + 1. 4. Go to step 1.
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Introduction - Multistage
• Notations used:
– Let ξt, t=1,…,T, represent a sequence of random variables with a specified probability distribution (stochastic process).
– Let ξ[t]:=(ξ1,…, ξt) denote the history of the process up to time t.
– Let xt represent the decision vector, chosen at stage t.
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Introduction - Multistage
• Non-anticipativity: the values of xt may depend on the information ξ[t], the data available up to time t, but may not be influenced by the result of future observations (ξt+1,…, ξT).
• xt is a stochastic process because it depends on ξ[t] – our decisions made today are influenced by previous decisions and outcomes.
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Introduction - Multistage
• Nested formulation for T-stage stochastic program:
where:
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Introduction - Multistage
• Nested formulation for T-stage stochastic program:
where:
ξ1 :=(c1 ,A1 ,b1) are known first-stage information (non-random)
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Introduction - Multistage
• Nested formulation for T-stage stochastic program:
where:
ξt :=(ct ,Bt ,At ,bt) are data vectors where some or all elements may be random
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Introduction - Multistage
• Linear formulation:
How can we formally introduce “history” into our models?
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Period 2
Introduction – Scenario Trees
• Scenario trees are used to represent history of decision making.
Period 1
Period 3
Period 4
Root node – f1(x1) is deterministic
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Period 2
Introduction – Scenario Trees
• Scenario trees are used to represent history of decision making.
Period 1
Period 3
Period 4
A path from the root to a leaf is called a “scenario”.
S1 S2 S3 S4 S5 S6 S7 S8 S9 S10
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Period 2
Introduction – Scenario Trees
• Scenario trees are used to represent history of decision making.
Period 1
Period 3
Period 4
Probabilities can be assigned to branches – defines the conditional probability of moving from one node to the next.
0.6 0.4
0.25 0.250.5
10.1 0.9
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Period 2
Introduction – Scenario Trees
• Scenario trees are used to represent history of decision making.
Period 1
Period 3
Period 4
Probability of scenario #1: (0.6)*(0.25)*(0.1) = 0.015
0.6
0.25
0.1
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Period 2
Introduction – Scenario Trees
• Scenario trees are used to represent history of decision making.
Period 1
Period 3
Period 4
Constraint matrices (A4, B4, b4) may be equal, however decision history from (x1, x2, x3) is different.
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Period 2
Introduction – Scenario Trees
• Scenario trees are used to define non-anticipativity constraints.
Period 1
Period 3
Period 4x1 x2 x3 x4 x5 x6 x7 x8 x9 x10
For the moment, let xkt represent the decisions made for scenario k and time t. Let
xk represent the set of decisions (xk1,…,xk
T)
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Introduction – Multistage Formulation
• Let k={1,…,K} denote the index of a given scenario.• Let pk denote the probability of scenario k={1,…,K}.
• Let (Atk, Bt
k, xtk, bt
k) denote the decision variables and LHS/RHS coefficients for scenario k in period t={2,…,T}.
• Let ctk denote the objective function coefficient for
decision vector xtk for scenario k in period t.
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Introduction – Multistage Formulation
• Multistage linear formulation:
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Period 2
Introduction – Scenario Trees
• Scenario trees are used to define non-anticipativity constraints.
Period 1
Period 3
Period 4x1 x2 x3 x4 x5 x6 x7 x8 x9 x10
Without scenario trees or histories, solving x1-x10 would be solving each scenario independently.
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Period 2
Introduction – Scenario Trees
• Scenario trees are used to define non-anticipativity constraints.
Period 1
Period 3
Period 4x1 x2 x3 x4 x5 x6 x7 x8 x9 x10
We can group xit variables according to the scenario tree.
x12=x2
2=x32=x4
2=x52=x6
2
x11=x2
1=x31=x4
1=x51=x6
1=x71=x8
1=x91=x10
1
x72=x8
2=x92=x10
2
x13=x2
3 x43=x4
3=x53 x8
3=x93=x10
3
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Introduction – Multistage Formulation
• Multistage linear formulation:
Non-anticipativity constraints
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Introduction – Aggregation
• Multistage stochastic programming is useful to integrate flexibility in models.– However, as the number of periods or branches increases,
the scenario tree grows exponentially, making it very challenging to optimize.
• Many types of multistage problems are meant to be re-solved in each period.– Solve multistage problem to get good answer for today.– Tomorrow, observe outcome of random variables, re-
optimize decisions.
• To control computational explosion, we can aggregate decisions.
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Period 2
Introduction – Aggregation
• Scenario trees may be simplified through aggregation
Period 1
Period 3
Period 4x1
4 x24 x3
4 x44 x5
4 x64 x7
4 x84 x9
4 x104
As depth of scenario tree increases, total probability for a deep node decreases, so it may be useful to simplify the problem.
0.6
0.25 0.250.5
10.1 0.9
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Period 2
Introduction – Aggregation
• Scenario trees may be simplified through aggregation
Period 1
Period 3
Period 4x1
4 x24 x3
4 x44 x5
4 x64 x7
4 x84 x9
4 x104
As depth of scenario tree increases, total probability for a deep node decreases, so it may be useful to simplify the problem.
0.015 0.135 0.3Probability:
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Period 2
Introduction – Aggregation
• Scenario trees may be simplified through aggregation
Period 1
Period 3
Period 4x1
4=x24 x3 x4
4=x54=x6
4 x7 x84=x9
4=x104
0.15 0.3 0.15Probability:
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Period 2
Introduction – Aggregation
• Scenario trees may be simplified through aggregation
Period 1
Period 3
Period 4x1
4=x24 x3 x4
4=x54=x6
4 x7 x84=x9
4=x104
Most models that include the time value of money are not heavily influenced by decisions made very far in the future – impact of aggregation may be negligible.
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Example – Ryan & Veronica’s Retirement Jobs
• Ryan and Veronica wish to have a large nest-egg for their retirement job.
+ +
Primary goal: Gastro-pub Secondary goal: Goats!
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Example – Ryan & Veronica’s Retirement Jobs
• We have a set N of stocks that we can invest in.• We have T={1,…,40} investment periods before
retirement.• Let ωit, i N, t T be the return on stock i in period t.• If we exceed goal G, we get $y to invest in the goat
farm.• If we don’t meet G, we will need to win $r from the
lottery to make up for the loss.• We can invest $bt in period t (hopefully not stochastic).
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Example – Ryan & Veronica’s Retirement Jobs
• Variables:– xit: amount of money to invest in stock i during
period t.– y: money that we can spend on goats after
retiring.– w: money needed from lottery winnings to open
the gastro-pub.
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Example – Ryan & Veronica’s Retirement Jobs
• Deterministic formulation:
Deterministic decision made today.
Amount of money available for re-investment next period.
Determine how much $ we have or need.
Non-negativity constraints.
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Example – Ryan & Veronica’s Retirement Jobs
• Multistage formulation:
– I may be naïve, but not enough to think that investing in the stock market is a deterministic problem.
– I can simulate prices for stocks and combine them into scenarios.
– Scenarios do not have to be dependent on the performance of a single stock, but the general performance over all stocks in a given year.
– Create a binomial scenario tree based on “High/Low” returns for a given period.
– Let ps define the probability of scenario s occurring.
– Let define the set of scenarios that are indistinguishable to scenario s in period t.
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Period 2
Example – Ryan & Veronica’s Retirement Jobs
Period 1
Period 3
Period 4
High
High
HighHighHigh
High
High
Low
Low
Low Low Low Low
… … … … … … … …
Investment Portfolio Binomial Tree
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Example – Ryan & Veronica’s Retirement Jobs
• Multistage formulation:
Non-anticipativity constraints
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A Multistage Stochastic Programming Approach to Open Pit Mine Production
Scheduling with Uncertain Geology
Authors: Natashia Boland, Irina Dumitrescu, Gary FroylandWritten: October, 2008
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Outline
• Introduction• Deterministic case: MIP production schedule• Stochastic case:
– Scenario-dependent mining & processing decisions
• Conclusions• Discussion
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IntroductionFrom geological estimation to generating cash flows
• The first step to start a mine is to drill and interpolate the remaining volume.– Traditional geostatistical interpolation (kriging) produces a
single “image” of what the deposit looks like.
Estimated (Kriged) DepositDrillholes & Orebody
Cross-Section Plan View
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IntroductionFrom geological estimation to generating cash flows
• Open pit mine production scheduling problem:– Schedule the extraction sequence of blocks such
that the net present value (NPV) of the mine is maximized.
• Cash flows generated directly related to when a block is mined.– The catch: we aren’t certain about the value of a
block until we have mined it. How can we decide which block to mine first?
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IntroductionDefinitions
• Volume of earth is discretized into K blocks:Empty volume of rock Discretized volume of rock
Set of blocks K={1,2,…,K}
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IntroductionDefinitions
• In order to reduce the number of variables, the blocks are combined into N “aggregates”.
Aggregates:
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IntroductionDefinitions
• In order to reduce the number of variables, the blocks are combined into N “aggregates”.
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IntroductionVariables
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Deterministic CaseMIP Production Schedule (D-MIP)
Mill production capacity
Mine production capacity
Precedence/time constraints
Variable definitions
Objective function
Mine/mill extraction relationship
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Stochastic Case
• Motivation:– Deterministic MIP ignores geological uncertainty– Use sequential simulation to produce many equiprobable
“images”/scenarios of what the deposit looks like.– Goal: create a schedule that can adapt to changes in
information using stochastic geological simulations.Simulated Deposits
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Stochastic Case
• Mining has endogenous uncertainty.– More information is revealed as the operation proceeds.– Uncertainty is generally reduced as more information is
revealed.– The information that we reveal is based on the decisions
that we made.
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Stochastic Case
• Multistage stochastic programming accommodates endogenous uncertainty through “adaptive” scheduling.– Rather than producing a schedule to accommodate all
scenarios well, produce a series of schedules telling you how to adapt under certain conditions.
• Two proposed models for stochastic scheduling:– Scenario-dependent processing decisions– Scenario-dependent mining & processing decisions
• We are allowed to dynamically change mining sequence and processing decisions based on new information.
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Stochastic Case
• Non-anticipativity constraints:– If multiple scenarios have a common history, then
we must make the same set of decisions for each of those scenarios.
– In the mining context: we have mined the exact same areas of the mine, thus we have revealed the same geological information. We must make the same decisions for all of those scenarios for future mining/processing.
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Stochastic Case
• More definitions– Set of scenarios (geostatistical simulations): – α-{r,s}-differentiator:
• •
–
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Stochastic CaseScenario-Dependent Mining & Processing Decisions
• Premise: – Mines are slow to react to changes.– We can change our mining sequence, however
there is a (1 year) delay between when we get information and when we can make changes for the sequence.
– Processing decisions are made ad-hoc.– We need to redefine our variables for each
scenario:•
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Stochastic CaseScenario-Dependent Processing Decisions (SMP-MIP)
Mill production capacity
Mine production capacity
Precedence/time constraints
Variable definitions
Objective function
Mine/mill relationship
Non-anticipativity constraints
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Stochastic CaseScenario-Dependent Mining & Processing Decisions (SMP-MIP)
• Non-anticipativity constraints:
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Stochastic CaseScenario-Dependent Mining & Processing Decisions (SMP-MIP)
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Stochastic CaseScenario-Dependent Mining & Processing Decisions (SMP-MIP)
• Year 1:
At the beginning of production, we start with the exact same information!We must make the same mining/extraction decisions (not necessarily processing)!
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Stochastic CaseScenario-Dependent Mining & Processing Decisions (SMP-MIP)
• Year 2:
The SMP-MIP will be forced to satisfy the NAC’s. It will choose to mine this, even if we reveal Scenario 1 to be the real deposit.
Under Scenario 1, we want to mine this.
Under Scenario 2, we want to mine this.
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Stochastic CaseScenario-Dependent Mining & Processing Decisions (SMP-MIP)
• Year 3:
We have 2 possible outcomes:1) Don’t mine the aggregate (and stop entirely)2) Mine the aggregate
Under Scenario 1, we want to mine this.
Under Scenario 2, we want to STOP.
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Stochastic CaseScenario-Dependent Mining & Processing Decisions (SMP-MIP)
• Year 3:
1) Don’t mine the aggregate (stop mining entirely):
Under Scenario 1, we want to mine this.
Under Scenario 2, we want to STOP.
- Why? Expected value of scenarios < 0.
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Stochastic CaseScenario-Dependent Mining & Processing Decisions (SMP-MIP)
• Year 3:
2) Mine the aggregate:
Under Scenario 1, we want to mine this.
Under Scenario 2, we want to STOP.
- Why? Expected value of scenarios > 0.- Outcome: We finally get out of NAP constraints! (Yay!) We can now process
the two however we need.
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Stochastic CaseScenario-Dependent Mining & Processing Decisions (SMP-MIP)
• Year 4:
We are finally free of all NAC’s! We can continue mining under Scenario 1.
Under Scenario 1, we want to mine this.
Under Scenario 2, we want to STOP.
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Conclusions
• This paper attempts to solve the problem of endogenous uncertainty using multistage stochastic programming.– The output from the optimizer for the stochastic
formulation is a set of policies for how to react if we reveal certain information.
– In a benchmark comparison, the SPM-MIP yielded an average increase in NPV of 2.13% over the D-MIP (out of a maximum 5.09% if we have perfect information before we mine).
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Discussion
• Fundamental issues:– Use of simulations:
• COSMO uses simulations to describe uncertainty.• Multi-stage approach uses simulations to describe possibilities.• What if the sims don’t cover all possibilities? Re-optimize!
– Definition of history requires subjective parameter (α)– Use of block aggregation & NAP constraints:
• This method cannot be applied without block aggregation – ultimately destroys value & may get different solutions (Δr,s)
– Use of output schedule policy:• Solution has multiple options for how to mine the depsoit.• How can an engineer take the solution and make it “mineable”?