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Market Preferences and Process Selection (MAPPS): the Value of Perfect Flexibility

Stephen Lawrence University of Colorado. George Monahan University of Illinois. Tim Smunt Wake Forest University. Market Preferences and Process Selection (MAPPS): the Value of Perfect Flexibility.

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Market Preferences and Process Selection (MAPPS): the Value of Perfect Flexibility

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  1. Stephen Lawrence University of Colorado George Monahan University of Illinois Tim Smunt Wake Forest University Market Preferences and Process Selection (MAPPS): the Value of Perfect Flexibility This research was partially funded by a College of BusinessCompetitive Summer Research Grant in Entrepreneurship

  2. Objectives of Research • Develop a methodology for timing and acquiring process technologies and selecting production processes • market evolution is stochastic • market demands and process capabilities must be matched • Conduct experiments to better understand important factors in acquiring process technologies (i.e., robust strategies) • Define and illustrate value of perfect flexibility

  3. Problem Statement • Problem Determine the value of perfect flexibility for process design conversions when market evolution is stochastic • Perfect Flexibility defined: Increase in profit that can be obtained a policy of perfect flexibility in responding to market preferences, compared to a robust policy of keeping one process design throughout the planning horizon.

  4. Application to Entrepreneurship • Start-up companies must make critical decisions regarding technology selection • Inappropriate technology selection can be economically fatal • Market preferences and market evolution uncertain for new products in new industries

  5. Assumptions • Time • can be discretized (i.e., months, quarters, years) • Markets • can be modeled as discrete scenarios • markets move between scenarios as a Markov process • Technologies • can be modeled as discrete option bundles • Costs • The costs associated with market/technology pairs can be estimated

  6. Prior Research • Monahan and Smunt, OR (1989) • Optimal Acquisition of Automated Flexible Manufacturing Processes • Rajagopalan, Singh and Morton, MS (1998) • Capacity Expansion and Replacement in Growing Markets with Uncertain Technological Breakthroughs • Gupta, Gerchak and Buzacott, IJPE (1992) • The Optimal Mix of Flexible and Dedicated Manufacturing Capacities: Hedging Against Demand Uncertainty • de Groote, IPJE (1994) • Flexibility and Marketing/Manufacturing Coordination • Paraskevopoulos, Karakitsos and Rustem, MS (1991) • Robust Capacity Planning Under Uncertainty • Mulvey and Vanderbei, OR (1995) • Robust Optimization of Large-Scale Systems

  7. Solution Methodology • Stochastic dynamic programming • MAPPS– Market Preferences and Process Selection

  8. A Simple Example Market Requirements High Variety Moderate Variety Standardized Job Shop High Flexibility Batch Shop Moderate Flexibility Process Capabilities Flow Shop StandardizedProduction Hayes and Wheelwright, “The dynamics of process-product life cycles,” Harvard Business Review, March-April 1979

  9. A Simple Example Market Requirements High Variety Moderate Variety Standardized Flexible Shop Job Shop High Flexibility Batch Shop Moderate Flexibility Process Capabilities Flow Shop StandardizedProduction Hayes and Wheelwright, “The dynamics of process-product life cycles,” Harvard Business Review, March-April 1979

  10. A Simple Example Market Requirements High Variety Moderate Variety Standardized MassCustomization Flexible Shop Job Shop High Flexibility Batch Shop Moderate Flexibility Process Capabilities Flow Shop StandardizedProduction Hayes and Wheelwright, “The dynamics of process-product life cycles,” Harvard Business Review, March-April 1979

  11. Marketing Scenarios • Discrete market scenarios or states M={1,…,M} • Market state mM defined by pertinent market variables (product type, product mix, demand levels, etc.) • Scenarios highly dependent on specific characteristics of the market under study. • Model market change as an M  M transition matrix . • Element ijrepresents the probability that the market will evolve to from state ito j in one period.

  12. Market Scenarios for Example • Three possible market scenarios 1. High variety high product variability, price not a large facto 2. Moderate variety medium product variability, moderate prices 3. Low variety  standardized “commodity product, low prices required • Market scenario transition matrix :

  13. Technology Options • Assume set of technological options T={1,…,T} • Option tT defined by important attributes (e.g., equipment descriptions, process capabilities, tolerances, capacity) • Availability of technological scenarios modeled usingT  T technological possibility matrix  • Element ij represents the probability that technology j will be available in the next period h+1 • If option tT has been available in the past, it will always be available in the future.

  14. Technology Options for Example Four technology options: 1. Job shop – low volumes, high product variation, high cost 2. Batch shop – medium volumes and variation, moderate cost 3. Flow shop – high volumes, low product variation, low cost 4. Flexible shop – moderate/high volume, high product variation, moderate cost • Option selected is a management decision

  15. Economic Structure • Revenues modeled as M  T matrix R • element rmt is expected period revenues with market scenario m and technology option t. • Production costs represented as M  Tmatrix K • element kmt represents expected period production costs when the market is in state m and technology is in state t. • Technology adoption costs modeled as T  Tmatrix C • element cij is cost of switching from option i to j. • Single period operating profit p • p = rmt - kmt - ctt’

  16. Revenue & Production Costs for Example • Revenue matrix R • Production cost matrix K

  17. Adoption Costs for Example • Technology adoption and maintenance cost matrix A

  18. Dynamic Programming Solution • In period hH, state of system is uniquely defined by market scenario mMand technology option tT. • Expected profits hfor remaining periods {h, h+1, … , H} are found by the recursive relationship m,m'M and t,t'T. • Optimal solution is technology the set of tT that maximize 0 given hand m.

  19. Optimal Strategy for Example

  20. Simulation of Optimal Strategy

  21. Chart of Optimal Strategy

  22. Solution with Perfect Flexibility

  23. Robust Solution • By increasing technology adoption costs, we can identify “robust” strategies

  24. Perfect Flexibility • Theorem 1: A policy of perfect flexibility provides an upper bound on profitability for the MAPPS problem. That is: • Corollary 2: When technology switching costs are free (ctt’=0, for all t,t’T), then a policy of perfect flexibility is optimal.

  25. Robust Technology Selection • Theorem 3: A perfectly robust policy provides a lower bound on profitability for the MAPPS problem. That is: • Corollary 4: When technology switching costs are sufficiently expensive (ctt’  for all t,t’tT), then a perfectly robust policy is optimal.

  26. Contributions of Research • Demonstrate MAPPS as method for good technology acquisition decisions • Establish robust strategy as a lower bound • Establish perfect flexibility as an upper bound • Define value of perfect flexibility • Provides benchmark for valuing flexibility

  27. Future Work • Increase size and complexity of market scenarios and technology options • include cost models for market scenarios • include cost models for production and adoption • include revenue models for market/technology pairs • Fully test and understand implications of MAPPS, including the development of analytic results • Test on industrial problems • identify an industrial client • gather data and run model

  28. Some other examples...

  29. Questions? Market Preferences and Process Selection (MAPPS): the Value of Perfect Flexibility

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