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Real Options. Richard de Neufville Professor of Engineering Systems and of Civil and Environmental Engineering MIT. Outline. Motivational Example: Garage Case General Perspective. Garage Case Topics. Value at Risk Analyzing flexibility using spreadsheet Parking garage case.
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Real Options Richard de Neufville Professor of Engineering Systems and of Civil and Environmental Engineering MIT
Outline • Motivational Example: Garage Case • General Perspective
Garage Case Topics • Value at Risk • Analyzing flexibility using spreadsheet • Parking garage case
Value at Risk Concept • Value at Risk (VAR) recognizes fundamental reality: actual value of any design can only be known probabilistically • Because of inevitable uncertainty in • Future demands on system • Future performance of technology • Many other market, political factors
Value at Risk Definition • Value at Risk (VAR) definition: • A loss that will not be exceeded at some specified confidence level • “We are p percent certain that we will not lose more than V dollars for this project.” • VAR easy to see on cumulative probability distribution (see next figure)
Look at distribution of NPV of designs A, B: • 90% VAR for NPVA is -$91 • 90% VAR for NPVB is $102
VAR and Flexibility • VAR is a common financial concept • It stresses downside losses, risks • However, designers also need to look at upside potential: “Value of Gain” • Flexible design provides value by both: • Decreasing downside risk • Increasing upside potential • See next figure
Sources of value for flexibility Cut downside ; Expand Upside
Excel Analysis Sequence toillustrate value of flexibility 1: Examine situation without flexibility • This is Base case design 2: Introduce variability (simulation) • a different design (in general) 3: Introduce flexibility => a even different and better design
Parking Garage Case • Garage in area where population expands • Actual demand is necessarily uncertain • Design Opportunity: Strengthened structure • enables future addition of floor(s) (flexibility) • costs more (flexibility costs) • Design issue: is extra cost worthwhile?
Parking Garage Case details • Demand • At start is for 750 spaces • Over next 10 years is expected to rise exponentially by another 750 spaces • After year 10 may be 250 more spaces • could be 50% off the projections, either way; • Annual volatility for growth is 10% • Average annual revenue/space used = $10,000 • The discount rate is taken to be 12%
Step 1: Set up base case Demand growth as predicted, no variability
Lower demand => Loss Higher demand => Gain limited by garage size Step 2: Simulate uncertainty
NPV Cumulative Distributions Compare Actual (5 Fl) with unrealistic fixed 6 Fl design
Step 3: Introduce flexibility into design (expand when needed) Including Flexibility => Another, better design: 4 Floors with strengthened structure enabling expansion
Summary of design results from different perspectives Why is the optimal design much better when we design with flexibility?
Sources of value for flexibility: 1) Minimize exposure to downside risk
Sources of value for flexibility: 2) Maximize potential for upside gain
Comparison of designswith and without flexibility • Wow! Everything is better! How did it happen? • Root cause: change the framing of the problem • recognize uncertainty ; add in flexibility thinking
Summary from Garage Case • Sources of value for flexibility • Cut downside risk • Expand upside potential • VAR chart is a neat way to represent the sources of value for flexibility • Spreadsheet with simulation is a powerful tool for estimating value of flexibility
“Options” Embody Idea of Flexibility • An “Option” provides a formal way of defining flexibility • An “Option” has a specific technical definition • Semantic Caution: • The technical meaning of an “option” is… much more specific and limited than … ordinary meaning of “option” in conversation... where “option” = “alternative” • Pay careful attention to definition that follows!
Technical definition of an Option An Option is... • A right, but not an obligation… • “Exercise”, that is “use” only if advantageous • Asymmetric returns -- “all gain, no pain” • Usually acquired at some cost or effort • to take some action… • to grow or change system, buy or sell something, etc, etc, • now, or in the future... • May be indefinite • But can be for a limited time after which option expires • for a pre-determined price (the “strike” price). • Cost of action separate from cost of option
Financial Options • Focus first on financial options because • Consequences easiest to present • This is where options and valuation developed • Financial Options • Are tradable assets (see quotes finance.yahoo.com) • Sold through exchanges similar to stock markets • Are on all kinds of goods (known as “underlying assets”) • Stocks, that is, shares in companies • Commodities (oil, meat, cotton, electricity...) • Foreign exchange, etc., etc.
Real Options • “Real” because they refer to project and systems • Contrast with financial options that are contracts • Real Options are focus of interest for Design • They provide flexibility for evolution of system • Projects often contain option-like flexibilities • Rights, not obligations (example: to expand garage) • Exercise only if advantageous • These flexibilities are “real” options • Let’s develop idea by looking at possibilities…
Real Options are Everywhere • Examples: • Lease equipment with option to buy at end of lease • Action is to buy at end of lease (or to walk away) • Lease period defined up-front (typically 2-3 years) • Purchase price defined in lease contract • Flexible manufacturing processes • Ability to select mode of operation (e.g. thermal power by burning either gas or oil) • Switching between modes is action • Continuous opportunity (can switch at any time) • Switching often entails some cost (e.g.: set-up time)
These need knowledge of system Options ON projects Financial options Options IN projects Real Options Real Options “IN” and “ON” projects • Those “real” because, in contrast to financial options, they concern projects, they are “ON” projects • E.g.: the option to open a mine • These do not concern themselves with system design • Most common in literature • Those “real” because they concern the design elements of system, they are “IN” projects • EX: options for staging of system of communication satellites • These require detailed understanding of system • Most interesting to system designers
Real Options “ON” projects • These are financial options, but on technical things • They treat technology as a “black box” • Example: Antamina Copper • option to open the mine after a two-year exploration period • Uncertainty concerns: amount of ore and future price =>uncertainty in revenue and thus in value of mine • Option is a Financial Call Option (on Mine as asset) • Differs from normal Financial Option because • Much longer period -- financial option usually < 2 years • Special effort needed to model future value of asset, it can’t be projected simply from past data (as otherwise typical)
Real Options “IN” projects • These create options by design of technical system • They require understanding of technology • Example: Communications Satellites • Designers can create options for expansion of capacity by way they configure original satellites • Technical skill needed to create and exercise option • Differ from other “real” Options because • Special effort needed to model feasible flexibility within system itself (e.g.: modeling of ‘trade space” for design of communication satellites)
Summary • Options embody formal concept of flexibility • Options are not “alternatives” • 4 step Mantra “right, but not obligation, to act…” • “Calls” for opportunities, “puts” for downside risks • OPTIONS MAY HAVE GREAT VALUE • Options are Financial and “Real” • Many “real” options available to system designers • “Real” Options “ON ” and “IN” systems