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Transcript of Chapter 11 PRODUCTION FUNCTIONS Copyright ©2002 by South-Western, a division of Thomson Learning....
Chapter 11
PRODUCTION FUNCTIONS
Copyright ©2002 by South-Western, a division of Thomson Learning. All rights reserved.
MICROECONOMIC THEORYBASIC PRINCIPLES AND EXTENSIONS
EIGHTH EDITION
WALTER NICHOLSON
Production Function
• The firm’s production function for a particular good (q) shows the maximum amount of the good that can be produced using alternative combinations of capital (K) and labor (L)
q = f(K,L)
Marginal Physical Product
• To study variation in a single input, we define marginal physical product as the additional output that can be produced by employing one more unit of that input while holding other inputs constant
KK fK
qMP
capital of product physical marginal
LL fL
qMP
labor of product physical marginal
Diminishing Marginal Productivity
• The marginal physical product of an input depends on how much of that input is used
• In general, we assume diminishing marginal productivity
02
KK
K fK
q
K
MP
02
LL
L fL
q
L
MP
Diminishing Marginal Productivity
• Because of diminishing marginal productivity, 19th century economist Thomas Malthus worried about the effect of population growth on labor productivity
• But changes in the marginal productivity of labor over time also depend on changes in other inputs such as capital– we need to consider fLK which is often > 0
Average Physical Product
• Labor productivity is often measured by average productivity
L
LKf
L
qAPL
),(
input labor
output
• Note that APL also depends on the amount of capital employed
A Two-Input Production Function
• Suppose the production function for flyswatters can be represented by
q = f(K,L) = 600K 2L2 - K 3L3
• To construct MPL and APL, we must assume a value for K – Let K = 10
• The production function becomes
q = 60,000L2 - 1000L3
A Two-Input Production Function
• The marginal productivity function is MPL = q/L = 120,000L - 3000L2
which diminishes as L increases• This implies that q has a maximum value:
120,000L - 3000L2 = 0
40L = L2
L = 40
• Labor input beyond L=40 reduces output
A Two-Input Production Function
• To find average productivity, we hold K=10 and solve
APL = q/L = 60,000L - 1000L2
• APL reaches its maximum where
APL/L = 60,000 - 2000L = 0
L = 30
A Two-Input Production Function
• In fact, when L=30, both APL and MPL are equal to 900,000
• Thus, when APL is at its maximum, APL and MPL are equal
Isoquant Maps
• To illustrate the possible substitution of one input for another, we use an isoquant map
• An isoquant shows those combinations of K and L that can produce a given level of output (q0)
f(K,L) = q0
Isoquant Map
L per period
K per period
• Each isoquant represents a different level of output– output rises as we move northeast
q = 30
q = 20
Marginal Rate of Technical Substitution (RTS)
L per period
K per period
q = 20
- slope = marginal rate of technical substitution (RTS)
• The slope of an isoquant shows the rate at which L can be substituted for K
LA
KA
KB
LB
A
B
RTS > 0 and is diminishing for
increasing inputs of labor
Marginal Rate of Technical Substitution (RTS)
• The marginal rate of technical substitution (RTS) shows the rate at which labor can be substituted for capital while holding output constant along an isoquant
0qqdL
dKKLRTS
) for (
RTS and Marginal Productivities• Take the total differential of the production
function:
dKMPdLMPdKK
fdL
L
fdq KL
• Along an isoquant dq = 0, so
dKMPdLMP KL
K
L
qq MP
MP
dL
dKKLRTS
0
) for (
RTS and Marginal Productivities
• Because MPL and MPK will both be nonnegative, RTS will also be nonnegative
• However, it is not possible to derive a diminishing RTS from the assumption of diminishing marginal productivity alone
RTS and Marginal Productivities
• To show that isoquants are convex, we would like to show that d(RTS)/dL < 0
• Since RTS = fL/fK
dL
ffd
dL
dRTS KL )/(
2)(
)]/()/([
K
KKKLLLKLLK
f
dLdKfffdLdKfff
dL
dRTS
RTS and Marginal Productivities• Using the fact that dK/dL = -fL/fK along an
isoquant and Young’s theorem (fKL = fLK)
3
22 2
)(
)(
K
KKLKLLKLLK
f
fffffff
dL
dRTS
• Because we have assumed fK > 0, the denominator is positive
• Because fLL and fKK are both assumed to be negative, the ratio will be negative if fKL is positive
RTS and Marginal Productivities• Intuitively, it seems reasonable that fKL=fLK
should be positive– if workers have more capital, they will be more
productive
• But some production functions have fKL < 0 over some input ranges– Thus, when we assume diminishing RTS we are
assuming that MPL and MPK diminish quickly enough to compensate for any possible negative cross-productivity effects
A Diminishing RTS
• Suppose the production function isq = f(K,L) = 600K 2L2 - K 3L3
• For this production functionMPL = fL = 1200K 2L - 3K 3L2
MPK = fK = 1200KL2 - 3K 2L3
• These marginal productivities will be positive for values of K and L for which KL < 400
A Diminishing RTS
• Because
fLL = 1200K 2 - 6K 3L
fKK = 1200L2 - 6KL3
this production function exhibits diminishing marginal productivities for sufficiently large values of K and L
– fLL and fKK < 0 if KL > 200
A Diminishing RTS
• Cross differentiation of either of the marginal productivity functions yields
fKL = fLK = 2400KL - 9K 2L2
which is positive only for KL < 266
A Diminishing RTS
• Thus, for this production function, RTS is diminishing throughout the range of K and L where marginal productivities are positive– for higher values of K and L, the diminishing
marginal productivities are sufficient to overcome the influence of a negative value for fKL to ensure convexity of the isoquants
Returns to Scale
• How does output respond to increases in all inputs together?
• Suppose that all inputs are doubled, would output double?
• Returns to scale have been of interest to economists since the days of Adam Smith
Returns to Scale
• Smith identified two forces that come into operation as inputs are doubled– greater division of labor and specialization
of function– loss in efficiency because management
may become more difficult given the larger scale of the firm
Returns to Scale• If the production function is given by q = f(K,L) and all
inputs are multiplied by the same positive constant (m > 1), then
Effect on Output Returns to Scale
f(mK,mL) = mf(K,L) Constant
f(mK,mL) < mf(K,L) Decreasing
f(mK,mL) > mf(K,L) Increasing
Returns to Scale
• It is possible for a production function to exhibit constant returns to scale for some levels of input usage and increasing or decreasing returns for other levels– economists refer to the degree of returns to
scale with the implicit notion that only a fairly narrow range of variation in input usage and the related level of output is being considered
Constant Returns to Scale• Constant returns-to-scale production
functions have the useful theoretical property that that the RTS between K and L depends only on the ratio of K to L, not the scale of operation
• Geometrically, all of the isoquants are “radial blowups” of the unit isoquant
Constant Returns to Scale
L per period
K per period
• Along a ray from the origin (constant K/L), the RTS will be the same on all isoquants
q = 3
q = 2
q = 1
The isoquants are equallyspaced as output expands
Returns to Scale• Returns to scale can be generalized to a
production function with n inputsq = f(X1,X2,…,Xn)
• If all inputs are multiplied by a positive constant m, we have
f(mX1,mX2,…,mXn) = mkf(X1,X2,…,Xn)=mkq
– If k=1, we have constant returns to scale– If k<1, we have decreasing returns to scale– If k>1, we have increasing returns to scale
Elasticity of Substitution• The elasticity of substitution () measures
the proportionate change in K/L relative to the proportionate change in the RTS along an isoquant
RTS
LK
LK
RTS
dRTS
LKd
RTS
LK
ln
)/ln(
/
)/(
%
)/(%
• The value of will always be positive because K/L and RTS move in the same direction
Elasticity of Substitution
L per period
K per period
• Both RTS and K/L will change as we move from point A to point B
A
B q = q0
RTSA
RTSB
(K/L)A
(K/L)B
is the ratio of theseproportional changes
measures thecurvature of theisoquant
Elasticity of Substitution• If is high, the RTS will not change much
relative to K/L– the isoquant will be relatively flat
• If is low, the RTS will change by a substantial amount as K/L changes– the isoquant will be sharply curved
• It is possible for to change along an isoquant or as the scale of production changes
The Linear Production Function
• Suppose that the production function isq = f(K,L) = aK + bL
• This production function exhibits constant returns to scalef(mK,mL) = amK + bmL = m(aK + bL) = mf(K,L)
• All isoquants are straight lines– RTS is constant =
The Linear Production Function
L per period
K per period
q1q2 q3
Capital and labor are perfect substitutes
RTS is constant as K/L changes
slope = -b/a =
Fixed Proportions
• Suppose that the production function isq = min (aK,bL) a,b > 0
• Capital and labor must always be used in a fixed ratio– the firm will always operate along a ray
where K/L is constant
• Because K/L is constant, = 0
Fixed Proportions
L per period
K per period
q1
q2
q3
No substitution between labor and capital is possible
= 0
K/L is fixed at b/a
q3/b
q3/a
Cobb-Douglas Production Function
• Suppose that the production function isq = f(K,L) = AKaLb A,a,b > 0
• This production function can exhibit any returns to scale
f(mK,mL) = A(mK)a(mL) b = Ama+b KaLb = ma+bf(K,L)– if a + b = 1 constant returns to scale– if a + b > 1 increasing returns to scale– if a + b < 1 decreasing returns to scale
Cobb-Douglas Production Function
• Suppose that hamburgers are produced according to the Cobb-Douglas function
q = 10K 0.5 L0.5
• Since a+b=1 constant returns to scale
• The isoquant map can be derivedq = 50 = 10K 0.5 L0.5 KL = 25
q = 100 = 10K 0.5 L0.5 KL = 100– The isoquants are rectangular hyperbolas
Cobb-Douglas Production Function
• The RTS can easily be calculated
L
K
KL
KL
f
fKLRTS
K
L
5050
5050
5
5..
..
) for (
• The RTS declines as L rises and K falls• The RTS depends only on the ratio of K and
L• Because the RTS changes exactly in
proportion to changes in K/L, = 1
Cobb-Douglas Production Function
• The Cobb-Douglas production function is linear in logarithms
ln q = ln A + a ln K + b ln L– a is the elasticity of output with respect to K– b is the elasticity of output with respect to L
CES Production Function• Suppose that the production function is
q = f(K,L) = [K + L] / 1, 0, > 0 > 1 increasing returns to scale < 1 decreasing returns to scale
• For this production function = 1/(1-)
= 1 linear production function = - fixed proportions production function = 0 Cobb-Douglas production function
Technical Progress
• Methods of production change over time
• Following the development of superior production techniques, the same level of output can be produced with fewer inputs– the isoquant shifts in
Technical Progress
• Suppose that the production function isq = A(t)f(K,L)
where A(t) represents all influences that go into determining q other than K and L– changes in A over time represent technical
progress• A is shown as a function of time (t)• dA/dt > 0
Technical Progress
• Differentiating the production function with respect to time we get
dt
LKdfALKf
dt
dA
dt
dq ),(),(
dt
dL
L
f
dt
dK
K
f
LKf
q
A
q
dt
dA
dt
dq
),(
Technical Progress
• Dividing by q gives us
dt
dL
LKf
Lf
dt
dk
LKf
Kf
A
dtdA
q
dtdq
),(
/
),(
///
L
dtdL
LKf
L
L
f
K
dtdK
LKf
K
K
f
A
dtdA
q
dtdq /
),(
/
),(
//
Technical Progress
• For any variable x, [(dx/dt)/x] is the proportional growth rate in x– denote this by Gx
• Then, we can write the equation in terms of growth rates
LKAq GLKf
L
L
fG
LKf
K
K
fGG
),(),(
Technical Progress
• Since
LLqKKqAq GeGeGG ,,
Kqeq
K
K
q
LKf
K
K
f,),(
Lqeq
L
L
q
LKf
L
L
f,),(
Technical Progress in the Cobb-Douglas Function
• Suppose that the production function isq = 10e 0.05t K 0.5 L0.5
• Taking logarithms yieldsln q = ln 10 + 0.05t + 0.5 ln K + 0.5 ln L
• Differentiating with respect to t gives the growth equation
L
dtdL
K
dtdK
q
dtdq /.
/..
/5050050
Technical Progress in the Cobb-Douglas Function
• We can put this in terms of growth ratesGq = 0.05 + 0.5GK + 0.5GL
• When K and L are constant, output grows at 5 percent per period– GK = GL = 0
– Gq = 0.05
Important Points to Note:• If all but one of the inputs are held constant,
a relationship between the single variable input and output can be derived– the marginal physical productivity is the change
in output resulting from a one-unit increase in the use of the input
– the marginal physical productivity of an input is assumed to decline as use of the input increases
Important Points to Note:• The entire production function can be
illustrated by an isoquant map– The slope of an isoquant is the marginal rate of
technical substitution• RTS measures how one input can be substituted for
another while holding output constant• RTS is the ratio of the marginal physical
productivities of the two inputs
– Isoquants are assumed to be convex• they obey the assumption of a diminishing RTS
Important Points to Note:• The returns to scale exhibited by a
production function record how output responds to proportionate increases in all inputs– if output increases proportionately with input
use, there are constant returns to scale– if there are greater than proportionate increases
in output, there are increasing returns to scale– if there are less than proportionate increases in
output, there are decreasing returns to scale
Important Points to Note:• The elasticity of substitution () provides a
measure of how easy it is to substitute on input for another in production– a high implies nearly straight isoquants– a low implies that isoquants are nearly L-
shaped
• Technical progress shifts the entire production function and isoquant map– may arise from the use of more productive
inputs or better economic organization