Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 Topic 7 Part I Partial Differentiation Part II Marginal Functions Part II Partial Elasticity Part III Total Differentiation Part IV Returns to scale.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "1 Topic 7 Part I Partial Differentiation Part II Marginal Functions Part II Partial Elasticity Part III Total Differentiation Part IV Returns to scale."— Presentation transcript:

1

2 1 Topic 7 Part I Partial Differentiation Part II Marginal Functions Part II Partial Elasticity Part III Total Differentiation Part IV Returns to scale Jacques (4th Edition): 5.1-5.3

3 2 Functions of Several Variables More realistic in economics to assume an economic variable is a function of a number of different factors: Y =f(X, Z) Demand may depend on the price of the good and the income level of the consumer Q d =f(P,Y) Output of a firm depends on inputs into the production process like capital and labour Q =f(K,L)

4 3 Graphically Sketching functions of two variables Y= f (X, Z) Sketch this function in 3-dimensional space or plot relationship between 2 variables for constant values of the third

5 4 For example I Consider a linear function form: y =a+bx+cz For different values of z we can represent the relationship between x and y

6 5 For example II Consider a non-linear function form: Y=X  Z  0<  < 1 & 0<  < 1 For different values of z we can represent the relationship between x and y

7 6 Part I: Partial Differentiation (Differentiating functions of several variables)

8 7 Consider our function of two variables: Y= f (x, z) = a + bx + cz

9 8 FOUR Second Order Partial Derivatives

10 9 Consider our function of two variables: Y= f (X, Z) = X  Z  First Partial Derivatives  Y/  X = f X =  X  -1 Z  > 0  Y/  Z = f Z =  X  Z  -1 > 0

11 10 Since  Y/  X = f X =  X  -1 Z   Y/  Z = f Z =  X  Z  -1 Second own partial  2 Y/  X 2 = f XX = (  -1)  X  -2 Z  < 0  2 Y/  Z 2 = f ZZ = (  -1)  X  Z  -2 < 0 Second cross partial  2 Y/  X  Z = f XZ =  X  -1 Z  -1 > 0  2 Y/  Z  X = f ZX =  X  -1 Z  -1 > 0

12 11 Example Jacques Y= f (X, Z) = X 2 +Z 3 f X = 2X > 0 Positive relation between x and y f XX = 2> 0 but at an increasing rate with x f XZ = 0, (= f zx ) and a constant rate with z impact of change in x on y is bigger at bigger values of x but the same for all values of z f Z = 3Z 2 > 0 Positive relation between z and y f ZZ = 6Z> 0 but at an increasing rate with z f ZX = 0 (= f xz ) and a constant rate with x impact of change in z on y is bigger at bigger values of z, but the same for all values of x

13 12 Example Jacques Y= f (X, Z) = X 2 Z f X = 2XZ>0 Positive relation between x and y f XX = 2Z>0 but at an increasing rate with x f XZ = 2X >0 and at an increasing rate with z impact of change in x on y is bigger at bigger values of x and bigger values of z f Z = X 2 >0 Positive relation between z and y f ZZ = 0 but at a constant rate with z f ZX = 2X>0 and an increasing rate with x impact of change in z on y is the same for all values of z but is bigger at higher values of x

14 13 Production function example Y= f(K L) = K 1/3 L 2/3 First partial derivatives of input gives Marginal product of input MPL=  Y/  L=Y L = ( 2 / 3 K 1/3 L 2/3 -1 ) = 2 / 3 Y/L >0 An increase in L holding other inputs constant will increase output Y MPK=  Y/  K = Y K =( 1 / 3 K 1/3-1 L 2/3 ) = 1 / 3 Y/K > 0 An increase in K holding other inputs constant will increase output Y

15 14 MPL =  Y/  L = ( 2 / 3 K 1/3 L -1/3 ) = 2 / 3 Y/L. MPK =  Y/  K = ( 1 / 3 K -2/3 L 2/3 ) = 1 / 3 Y/K. Second Own derivatives of input gives Marginal Returns of input (or the change in the marginal product of an input with the level of that input)   Y/  L 2 = - 2 / 9 K 1/3 L -4/3 < 0 Diminishing marginal returns to L (the change in MPL with L shows that the MPL decreases at higher values of L)   Y/  L 2 = - 2 / 9 K -5/3 L 2/3 < 0 Diminishing marginal returns to K (the change in the MPK with K shows that the MPK decreases at higher values of K)

16 15 Part II: Partial Elasticity

17 16 e.g. Y= f(K L) = K 1/3 L 2/3

18 17 Q = f(P,P S,Y) = 100-2P+P S +0.1Y P = 10, P S = 12, Y= 1000  Q=192 Partial Own-Price Elasticity of Demand  QP =  Q/  P. P/Q = -2 * (10/192) = - 0.10 Partial Cross-Price Elasticity of Demand  QPS =  Q/  P S. P S /Q = +1 * (12/192) = 0.06 Partial Income Elasticity of Demand  QI =  Q/  Y. Y/Q = +0.1 * (1000/192) = 0.52 e.g. demand function Q = f( P, P S, Y)

19 18 Part III: Total Differential Total Differential: Y= f (X)  Y= dY/dX.  X If  X =10 and dY/dX = 2,   Y = 2. 10 = 20 Total Differential: Y= f (X, Z)  Y=  Y/  X.  X +  Y/  Z.  Z or dY=  Y/  X. dX +  Y/  Z. dZ

20 19 Example: Y= f (K, L) = Y = K 1/3 L 2/3 dY=  Y/  K. dK +  Y/  L. dL or dY= ( 1 / 3 K -2/3 L 2/3 ).dK + ( 2 / 3 K 1/3 L -1/3 ).dL Rewriting: dY= ( 1 / 3 K 1/3 K -1 L 2/3 ).dK + ( 2 / 3 K 1/3 L 2/3 L -1 ).dL or dY= 1 / 3. Y / K. dK + 2 / 3. Y / L. dL To find proportionate change in Y dY / Y = 1 / 3. dK / K + 2 / 3. dL / L

21 20 Y= A f (K, L) = Y = A K  L  dY=  Y/  K.dK +  Y/  L.dL +  Y/  A.dA or dY= .AK  -1 L  dK + .AK  L  -1.dL + K  L . dA dY= .Y/K. dK + .Y/L. dL + Y/A. dA Or for proportionate change in Y: dY/Y= .dK/K + .dL/L + dA/A Or for proportionate change in A: dA/A = dY/Y–( .dK/K+ .dL/L) Total Differential: Y= f (X, Z)

22 21 Part IV: Returns to Scale Returns to scale shows the change in Y due to a proportionate change in ALL factors of production. So if Y= f(K, L) Constant Returns to Scale f( K, L ) = f(K, L) = Y Increasing Returns to Scale f( K, L ) > f(K, L) > Y Decreasing Returns to Scale f( K, L ) < f(K, L) < Y

23 22 Cobb-Douglas Production Function: Y = AK  L  Quick way to check returns to scale in Cobb- Douglas production function Y = AK  L  then if  +  = 1 : CRS if  +  > 1 : IRS if  +  < 1 : DRS

24 23 Y * = f( K, L) = A ( K)  ( L)  Y * = A  K   L  =  +  AK  L  =  +  Y  +  = 1 Constant Returns to Scale  +  > 1 Increasing Returns to Scale  +  < 1 Decreasing Returns to Scale Example: Y= f(K, L) = A K  L 

25 24 Homogeneous of Degree r if: f( X, Z ) = r f(X, Z) = r Y Homogenous function if by scaling all variables by, can write Y in terms of r Note superscripts! Note then, for cobb-douglas Y = K  L , the function is homogenous of degree  + 

26 25 X f X + Z f Z = r f(X, Z) = rY E.g. r =1, Constant Returns to Scale If Y= f(K, L) = A K  L (1-  ) Does K f K + L f L = rY = Y? K (  Y/K) + L((1-  )Y/L) = ?  Y + (1-  )Y =  Y + Y -  Y = Y Thus, Eulers theorem shows (MPk * K ) + (MPL * L) = Y in the case of homogenous production functions of degree 1 Eulers Theorem

27 26 then Y( K, L) = ( K) ½ ( L) ½ = ½ K ½ ½ L ½ = 1 K ½ L ½ = Y homogenous degree 1..... constant returns to scale Eulers Theorem: show that K.  Y /  K + L.  Y /  L = r.Y = Y (r=1 as homog. degree 1) = K. (½.K ½ -1.L ½ ) + L.(½.K ½.L ½ -1 ) = K(½. Y/K) + L(½.Y/L) = ½.Y + ½.Y = Y Example.. If Y = K ½ L ½

28 27 Summary: Function of Two Variables Partial Differentiation - Production Functions– first derivatives (marginal product of K or L) and second derivatives (returns to K or L) Partial Elasticity – Demand with respect to own price, price of another good, or income Total Differentials Returns to Scale Plenty of Self-Assessment Problems and Tutorial Questions on these things….

Download ppt "1 Topic 7 Part I Partial Differentiation Part II Marginal Functions Part II Partial Elasticity Part III Total Differentiation Part IV Returns to scale."

Similar presentations

1 Chapter 6: Firms and Production Firms’ goal is to maximize their profit. Profit function: π= R – C = P*Q – C(Q) where R is revenue, C is cost, P is price,

1 Chapter 6: Firms and Production Firms’ goal is to maximize their profit. Profit function: π= R – C = P*Q – C(Q) where R is revenue, C is cost, P is price,
1 Topic 8: Optimisation of functions of several variables Unconstrained Optimisation (Maximisation and Minimisation) Jacques (4th Edition): 5.4.

1 Topic 8: Optimisation of functions of several variables Unconstrained Optimisation (Maximisation and Minimisation) Jacques (4th Edition): 5.4.
ECO 402 Fall 2013 Prof. Erdinç Economic Growth The Solow Model.

ECO 402 Fall 2013 Prof. Erdinç Economic Growth The Solow Model.
© 2010 W. W. Norton & Company, Inc. 15 Market Demand.

© 2010 W. W. Norton & Company, Inc. 15 Market Demand.
Chapter 15 Market Demand. 2 From Individual to Market Demand Functions Think of an economy containing n consumers, denoted by i = 1, …,n. Consumer i’s.

Chapter 15 Market Demand. 2 From Individual to Market Demand Functions Think of an economy containing n consumers, denoted by i = 1, …,n. Consumer i’s.
1 Topic 1 Topic 1 : Elementary functions Reading: Jacques Section 1.1 - Graphs of linear equations Section 2.1 – Quadratic functions Section 2.2 – Revenue,

1 Topic 1 Topic 1 : Elementary functions Reading: Jacques Section Graphs of linear equations Section 2.1 – Quadratic functions Section 2.2 – Revenue,
1 Topic 6: Optimization I Maximisation and Minimisation Jacques (4th Edition): Chapter 4.6 & 4.7.

1 Topic 6: Optimization I Maximisation and Minimisation Jacques (4th Edition): Chapter 4.6 & 4.7.
Production Theory 2.

Production Theory 2.
Chapter 4: Labor Demand Elasticities

Chapter 4: Labor Demand Elasticities
© 2008 Pearson Addison Wesley. All rights reserved Chapter Six Firms and Production.

© 2008 Pearson Addison Wesley. All rights reserved Chapter Six Firms and Production.
Chapter 11 PRODUCTION FUNCTIONS Copyright ©2002 by South-Western, a division of Thomson Learning. All rights reserved. MICROECONOMIC THEORY BASIC PRINCIPLES.

Chapter 11 PRODUCTION FUNCTIONS Copyright ©2002 by South-Western, a division of Thomson Learning. All rights reserved. MICROECONOMIC THEORY BASIC PRINCIPLES.
MARKET DEMAND AND ELASTICITY

MARKET DEMAND AND ELASTICITY
Who Wants to be an Economist? Part II Disclaimer: questions in the exam will not have this kind of multiple choice format. The type of exercises in the.

Who Wants to be an Economist? Part II Disclaimer: questions in the exam will not have this kind of multiple choice format. The type of exercises in the.
Chapter 3: National Income. Production Function Output of goods and services as a function of factor inputs Y = F(K, L) Y = product output K = capital.

Chapter 3: National Income. Production Function Output of goods and services as a function of factor inputs Y = F(K, L) Y = product output K = capital.
Chapter Fifteen Market Demand. From Individual to Market Demand Functions  The market demand curve is the “horizontal sum” of the individual consumers’

Chapter Fifteen Market Demand. From Individual to Market Demand Functions  The market demand curve is the “horizontal sum” of the individual consumers’
Introduction In the last lecture we defined and measured some key macroeconomic variables. Now we start building theories about what determines these key.

Introduction In the last lecture we defined and measured some key macroeconomic variables. Now we start building theories about what determines these key.
Chapter Eighteen Technology. Technologies  A technology is a process by which inputs are converted to an output  E.g. seed, chemical fertilizer, pesticides,

Chapter Eighteen Technology. Technologies  A technology is a process by which inputs are converted to an output  E.g. seed, chemical fertilizer, pesticides,
Economics 214 Lecture 29 Multivariate Calculus. Homogeneous Function.

Economics 214 Lecture 29 Multivariate Calculus. Homogeneous Function.
The Theory of Production

The Theory of Production
Chap. 4, The Theory of Aggregate Supply

Chap. 4, The Theory of Aggregate Supply

Similar presentations

Ads by Google