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Production Functions (PF)

Production Functions (PF). Outline 1. Definition 2. Technical Efficiency 3. Mathematical Representation 4. Characteristics. Production Function - Basic Model for Modeling Engineering Systems. Definition:

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Production Functions (PF)

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  1. Production Functions (PF) Outline 1. Definition 2. Technical Efficiency 3. Mathematical Representation 4. Characteristics

  2. Production Function - Basic Model for Modeling Engineering Systems • Definition: • Represents technically efficient transform of physical resources X = (X1…Xn) into product or outputs Y (may be good or bad) • Example: • Use of aircraft, pilots, fuel (the X factors) to carry cargo, passengers and create pollution (the Y) • Typical focus on 1-dimensional output

  3. Technical Efficiency • A Process is Technically Efficient if it provides Maximum product from a given set of resources X = X1 , ... Xn • Graph: Max Feasible Region Note Output Resource

  4. c o n t r a s t Mathematical Representation -- General • Two Possibilities • Deductive -- Economic • Standard economic analysis • Fit data to convenient equation • Advantage - ease of use • Disadvantage - poor accuracy • Inductive -- Engineering • Create system model from knowledge of details • Advantage - accuracy • Disadvantage - careful technical analysis needed

  5. Mathematical Representation -- Deductive • Standard Cobb-Douglas Production Function Y = a0 Xiai = a0X1a1 ... Xnan [  means multiplication] • Interpretation: ‘ai’ are physically significant • Easy estimation by linear least squareslog Y = a0 + ai log Xi • Translog PF -- more recent, less common • log Y = a0 + ai log Xi + aij log Xi log Xj • Allows for interactive effects • More subtle, more realistic • Economist models (no technical knowledge)

  6. One of the advantage of the “economist” models is that they make calculations easy. This is good for examples, even if not as realistic as Technical Cost Models (next) Thus: Output = 2 M 0.4 N 0.8 Let’s see what this looks like... PF Example

  7. PF Example -- Calculation

  8. PF Example -- Graphs

  9. PF Example -- Graphs

  10. Mathematical Representation -- Inductive • “Engineering models” of PF • Analytic expressions • Rarely applicable: manufacturing is inherently discontinuous • Exceptions: process exists in force field, for example transport in fluid, river • Detailed simulation, Technical Cost Model • Generally applicable • Requires research, data, effort • Wave of future -- not yet standard practice

  11. Cooling Time, Part Weight, Cycle Time Correlation (MIT MSL, Dr.Field)

  12. PF: Characteristics • Isoquants • Marginal Products • Marginal Rates of Substitution • Returns to Scale • Possible Convexity of Feasible Region

  13. Characteristic: Isoquants • Isoquant is the Locus (contour) of equal product on production function • Graph: Y Production Function Surface Xj Isoquant Projection Xi

  14. Important Implication of Isoquants • Many designs are technically efficient • All points on isoquant are technically efficient • no technical basis for choice among them • Example: • little land, much steel => tall building • more land, less steel => low building • Best System Design depends on Economics • Values are decisive

  15. Isoquant Example -- Calculation

  16. Isoquant Example -- Graph

  17. Xi Characteristic: Marginal Products • Marginal Product is the change in output as only one resource changes MPi = Y/ Xi • Graph: MPi

  18. Diminishing Marginal Products • Math: Y = a0X1a1 ... Xiai ...Xnan Y/ Xi = (ai/Xi)Y = f (Xiai-1) Diminishing Marginal Product if ai < 1.0 • “Law” of Diminishing Marginal Products • Commonly observed -- but not necessary • “Critical Mass” phenomenon => increasing marginal products

  19. MP Example -- Calculations

  20. MP Example -- Graph

  21. Characteristic: Marginal Rate of Substitution • Marginal Rate of Substitution is the Rate at which one resource must substitute for another so that product is constant • Graph: Xj Xi Xj Isoquant Xi

  22. Marginal Rate of Substitution (cont’d) • Math:since XIMPI + XJMPJ = 0 (no change in product) then MRSIJ = XJ/XI • = - MPI / MPJ = - [(aI/ XI) Y] / [(aJ/ XJ ) Y] • = - (aI/aJ) (XJ/XI ) • MRS is “slope” of isoquant • It is negative • Loss in 1 dimension made up by gain in other

  23. For our example PF: Output = 2 M 0.4 N 0.8 aM = 0.4 ; aN = 0.8 At a specific point, say M = 5, N = 12.65 MRS = - (0.4 / 0.8) (12.65 / 5) = - 1.265 At that point, it takes ~ 5/4 times as much M as N to get the same change in output MRS Example

  24. Xj RTS – along a ray from origin MPj MPi Xi Characteristic: Returns to Scale • Returns to Scale is the Ratio of rate of change in Y to rate of change in ALL X (each Xi changes by same factor) • Graph: • Directions in which the rate of change in output is measured for MP and RTS

  25. Returns to Scale (cont’d) • Math:Y’ = a0 Xiai Y’’ = a (sXi)ai = Y’(s)a all inputs increase by sRTS = (Y”/Y’)/s = s(ai - 1) Y”/Y’ = % increase in Y if Y”/Y’ > s => Increasing RTSIncreasing returns to scale (IRTS) if ai > 1.0

  26. The PF is: Output = 2 M 0.4 N 0.8 Thus ai = 0.4 + 0.8 = 1.2 > 1.0 So the PF has Increasing Returns to Scale Compare outputs for (5,10), (10,20), (20,40) Increasing RTS Example

  27. Importance of Increasing RTS • Increasing RTS means that bigger units are more productive than small ones • IRTS => concentration of production into larger units • Examples: • Generation of Electric power • Chemical, pharmaceutical processes

  28. Practical Occurrence of IRTS • Frequent! • Generally where • Product = f (volume) and • Resources = f (surface) • Example: • ships, aircraft, rockets • pipelines, cables • chemical plants • etc.

  29. Characteristic: Convexity of Feasible Region • A region is convex if it has no “reentrant” corners • Graph: CONVEX NOT CONVEX

  30.  Origin Informal Test for Convexity ofFeasible Region (cont’d) • Math: If A, B are two vectors to any 2 points in region Convex if all T = KA + (1-K)B 0 K 1 entirely in region

  31. Y Y Non- Convex Convex X X Convexity of Feasible Region for Production Function • Feasible region of Production function is convex if no reentrant corners • Convexity => Easier Optimization • by linear programming (discussed later)

  32. B Y Y B T A T A X X Test for Convexity of Feasible Region of Production Function • Test for Convexity: Given A,B on PFIf T = KA + (1-K)B 0  K  1Convex if all T in region • For Cobb-Douglas, the test is if: all ai 1.0 and ai 1.0

  33. Example PF has Diminishing MP, so in the MP direction it looks like left side But: it has IRTS, like bottom of right side Feasible Region is not convex Convexity Test Example

  34. Summary • Production models are the way to describe technicallyefficient systems • Important characteristics • Isoquants, Marginal products, Marginal rates of Substitution, Returns to scale, possible convexity • Two ways to represent • Economist formulas • Technical models (generally more accurate)

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