1 / 49

Lecture # 05 Consumer Preferences and the Concept of Utility (cont.) Lecturer: Martin Paredes

Lecture # 05 Consumer Preferences and the Concept of Utility (cont.) Lecturer: Martin Paredes. Outline. Indifference Curves (end) The Marginal Rate of Substitution The Utility Function Marginal Utility Some Special Functional Forms. Indifference Curves.

shaman
Download Presentation

Lecture # 05 Consumer Preferences and the Concept of Utility (cont.) Lecturer: Martin Paredes

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Lecture # 05 Consumer Preferences and the Concept of Utility (cont.) Lecturer: Martin Paredes

  2. Outline • Indifference Curves (end) • The Marginal Rate of Substitution • The Utility Function • Marginal Utility • Some Special Functional Forms

  3. Indifference Curves Definition: An Indifference Curve is the set of all baskets for which the consumer is indifferent Definition: An Indifference Map illustrates the set of indifference curves for a particular consumer

  4. Properties of Indifference Maps: • Completeness • Each basket lies on only one indifference curve • Monotonicity • Indifference curves have negative slope • Indifference curves are not “thick”

  5. y Monotonicity • A x

  6. y Monotonicity Preferred to A • A x

  7. y Monotonicity Preferred to A • A Less preferred x

  8. y Monotonicity Preferred to A • A Less preferred IC1 x

  9. y Indifference Curves are NOT Thick B • • A IC1 x

  10. Properties of Indifference Maps: 3. Transitivity • Indifference curves do not cross 4. Averages preferred to extremes • Indifference curves are bowed toward the origin (convex to the origin).

  11. y Indifference Curves Cannot Cross • Suppose a consumer is indifferent between A and C • Suppose that B preferred to A. IC1 B • • A C • x

  12. y Indifference Curves Cannot Cross • It cannot be the case that an IC contains both B and C • Why? because, by definition of IC the consumer is: • Indifferent between A & C • Indifferent between B & C • Hence he should be indifferent between A & B (by transitivity). • => Contradiction. IC2 IC1 B • • A C • x

  13. y Averages Preferred to Extremes A • • IC1 B x

  14. y Averages Preferred to Extremes A • (.5A, .5B) • • IC1 B x

  15. y Averages Preferred to Extremes A • (.5A, .5B) • IC2 • IC1 B x

  16. Marginal Rate Of Substitution There are several ways to define the Marginal Rate of Substitution Definition 1: It is the maximum rate at which the consumer would be willing to substitute a little more of good x for a little less of good y in order to leave the consumer just indifferent between consuming the old basket or the new basket

  17. Marginal Rate Of Substitution Definition 2: It is the negative of the slope of the indifference curve: MRSx,y = — dy (for a constant level of dx preference)

  18. Diminishing Marginal Rate Of Substitution An indifference curve exhibits a diminishing marginal rate of substitution: • The more of good x you have, the more you are willing to give up to get a little of good y. • The indifference curves • Get flatter as we move out along the horizontal axis • Get steeper as we move up along the vertical axis.

  19. Example: The Diminishing Marginal Rate of Substitution

  20. The Utility Function Definition: The utility function measures the level of satisfaction that a consumer receives from any basket of goods.

  21. The Utility Function • The utility function assigns a number to each basket • More preferred baskets get a higher number than less preferred baskets. • Utility is an ordinal concept • The precise magnitude of the number that the function assigns has no significance.

  22. Ordinal and Cardinal Ranking • Ordinalranking gives information about the order in which a consumer ranks baskets • E.g. a consumer may prefer A to B, but we cannot know how much more she likes A to B • Cardinal ranking gives information about the intensity of a consumer’s preferences. • We can measure the strength of a consumer’s preference for A over B.

  23. Example: Consider the result of an exam • An ordinal ranking lists the students in order of their performance • E.g., Harry did best, Sean did second best, Betty did third best, and so on. • A cardinal ranking gives the marks of the exam, based on an absolute marking standard • E.g. Harry got 90, Sean got 85, Betty got 80, and so on.

  24. The Utility Function Implications of an ordinal utility function: • Difference in magnitudes of utility have no interpretation per se • Utility is not comparable across individuals • Any transformation of a utility function that preserves the original ranking of bundles is an equally good representation of preferences. eg. U = xy U = xy + 2 U = 2xy all represent the same preferences.

  25. y Example: Utility and a single indifference curve 5 2 10 = xy 0 x 2 5

  26. y Example: Utility and a single indifference curve Preference direction 5 20 = xy 2 10 = xy 0 x 2 5

  27. Marginal Utility Definition: The marginal utility of good x is the additional utility that the consumer gets from consuming a little more of x MUx = dU dx • It is is the slope of the utility function with respect to x. • It assumes that the consumption of all other goods in consumer’s basket remain constant.

  28. Diminishing Marginal Utility Definition: The principle of diminishing marginal utility states that the marginal utility of a good falls as consumption of that good increases. Note: A positive marginal utility implies monotonicity.

  29. Example: Relative Income and Life Satisfaction (within nations) Relative IncomePercent > “Satisfied” Lowest quartile 70 Second quartile 78 Third quartile 82 Highest quartile 85 Source: Hirshleifer, Jack and D. Hirshleifer, Price Theory and Applications. Sixth Edition. Prentice Hall: Upper Saddle River, New Jersey. 1998.

  30. Marginal Utility and the Marginal Rate of Substitution We can express the MRS for any basket as a ratio of the marginal utilities of the goods in that basket • Suppose the consumer changes the level of consumption of x and y. Using differentials: dU = MUx . dx + MUy . dy • Along a particular indifference curve, dU = 0, so: 0 = MUx . dx + MUy . dy

  31. Marginal Utility and the Marginal Rate of Substitution • Solving for dy/dx: dy = _ MUx dx MUy • By definition, MRSx,y is the negative of the slope of the indifference curve: MRSx,y = MUx MUy

  32. Marginal Utility and the Marginal Rate of Substitution • Diminishing marginal utility implies the indifference curves are convex to the origin (implies averages preferred to extremes)

  33. Example: • U= (xy)0.5 • MUx=y0.5/2x0.5 • MUy=x0.5/2y0.5 • Marginal utility is positive for both goods: • => Monotonicity satisfied • Diminishing marginal utility for both goods • => Averages preferred to extremes • Marginal rate of substitution: • MRSx,y = MUx = y • MUy x • Indifference curves do not intersect the axes

  34. y Example: Graphing Indifference Curves IC1 x

  35. y Example: Graphing Indifference Curves Preference direction IC2 IC1 x

  36. Special Functional Forms • Cobb-Douglas (“Standard case”) U = Axy where:  +  = 1; A, , positive constants Properties: MUx = Ax-1y MUy = Axy-1 MRSx,y = y x

  37. y Example: Cobb-Douglas IC1 x

  38. y Example: Cobb-Douglas Preference direction IC2 IC1 x

  39. Special Functional Forms • 2. Perfect Substitutes: • U = Ax + By where: A,B are positive constants Properties: MUx = A MUy = B MRSx,y = A (constant MRS) B

  40. Example: Perfect Substitutes (butter and margarine) y IC1 0 x

  41. Example: Perfect Substitutes (butter and margarine) y IC2 IC1 0 x

  42. Example: Perfect Substitutes (butter and margarine) y Slope = -A/B IC2 IC3 IC1 0 x

  43. Special Functional Forms • 3. Perfect Complements: • U = min {Ax,By} where: A,B are positive constants Properties: MUx = A or 0 MUy = B or 0 MRSx,y = 0 or  or undefined

  44. Example: Perfect Complements (nuts and bolts) y IC1 0 x

  45. Example: Perfect Complements (nuts and bolts) y IC2 IC1 0 x

  46. Special Functional Forms • 4. Quasi-Linear Utility Functions: • U = v(x) + Ay where: A is a positive constant, and v(0) = 0 Properties: MUx = v’(x) MUy = A MRSx,y = v’(x) (constant for any x) A

  47. y Example: Quasi-linear Preferences (consumption of beverages) IC1 • 0 x

  48. y Example: Quasi-linear Preferences (consumption of beverages) IC2 IC’s have same slopes on any vertical line IC1 • • 0 x

  49. Summary • Characterization of consumer preferences without any restrictions imposed by budget • Minimal assumptions on preferences to get interesting conclusions on demand…seem to be satisfied for most people. (ordinal utility function)

More Related