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Chapter 32 Production. Exchange Economies (revisited). No production, only endowments, so no description of how resources are converted to consumables. General equilibrium: all markets clear simultaneously. 1st and 2nd Fundamental Theorems of Welfare Economics. Now Add Production. - PowerPoint PPT Presentation
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Chapter 32Production
Exchange Economies (revisited) No production, only endowments, so
no description of how resources are converted to consumables.
General equilibrium: all markets clear simultaneously.
1st and 2nd Fundamental Theorems of Welfare Economics.
2
Now Add Production ...
Add input markets, output markets, describe firms’ technologies, the distributions of firms’ outputs and profits …
3
Now Add Production ...
Add input markets, output markets, describe firms’ technologies, the distributions of firms’ outputs and profits … That’s not easy!
4
Robinson Crusoe’s Economy
One agent, RC. Endowed with a fixed quantity of one
resource -- 24 hours. Use time for labor (production) or
leisure (consumption). Labor time = L. Leisure time = 24 - L. What will RC choose?
5
Robinson Crusoe’s Technology Technology: Labor produces output
(coconuts) according to a concave production function.
6
Robinson Crusoe’s Technology
Labor (hours)
Coconuts
Production function
240
Feasible productionplans
7
Robinson Crusoe’s Preferences RC’s preferences:
coconut is a good leisure is a good
8
Robinson Crusoe’s Preferences
Leisure (hours)
Coconuts
More preferred
240
9
Robinson Crusoe’s Preferences
Leisure (hours)
Coconuts
More preferred
24 0
10
Robinson Crusoe’s Choice
Labor (hours)
Coconuts
Feasible productionplans
Production function
240
11
Robinson Crusoe’s Choice
Labor (hours)
Coconuts
Feasible productionplans
Production function
240
Leisure (hours)24 0
12
Robinson Crusoe’s Choice
Labor (hours)
Coconuts
Feasible productionplans
Production function
240
Leisure (hours)24 0
13
Robinson Crusoe’s Choice
Labor (hours)
Coconuts
Production function
240
Leisure (hours)24 0
C*
L*
14
Robinson Crusoe’s Choice
Labor (hours)
Coconuts
Production function
240
Leisure (hours)24 0
C*
L*
Labor
15
Robinson Crusoe’s Choice
Labor (hours)
Coconuts
Production function
240
Leisure (hours)24 0
C*
L*
Labor Leisure
16
Robinson Crusoe’s Choice
Labor (hours)
Coconuts
Production function
240
Leisure (hours)24 0
C*
L*
Labor Leisure
Output
17
Robinson Crusoe’s Choice
Labor (hours)
Coconuts
Production function
240
Leisure (hours)24 0
C*
L*
Labor Leisure
MRS = MPL
Output
18
Robinson Crusoe as a Firm
Now suppose RC is both a utility-maximizing consumer and a profit-maximizing firm.
Use coconuts as the numeraire good; i.e. price of a coconut = $1.
RC’s wage rate is w. Coconut output level is C.
19
Robinson Crusoe as a Firm
RC’s firm’s profit is = C - wL. = C - wL C = + wL, the
equation of an isoprofit line. Slope = + w . Intercept = .
20
Isoprofit Lines
Labor (hours)
Coconuts
24
C wL Higher profit; 1 2 3
Slopes = + w 3 21
0
21
Profit-Maximization
Labor (hours)
Coconuts
Feasible productionplans
Production function
240
22
Profit-Maximization
Labor (hours)
Coconuts
Production function
240
23
Profit-Maximization
Labor (hours)
Coconuts
Production function
240
24
Profit-Maximization
Labor (hours)
Coconuts
Production function
24
C*
L*0
25
Profit-Maximization
Labor (hours)
Coconuts
Production function
24
C*
L*
Isoprofit slope = production function slope i.e. w = MPL
0
26
Profit-Maximization
Labor (hours)
Coconuts
Production function
24
C*
L*
Isoprofit slope = production function slope i.e. w = MPL = 1 MPL = MRPL.
0
27
Profit-Maximization
Labor (hours)
Coconuts
Production function
24
C*
L*
Isoprofit slope = production function slope i.e. w = MPL = 1 MPL = MRPL.
*
* * * C wLRC gets
0
28
Profit-Maximization
Labor (hours)
Coconuts
Production function
24
C*
L*
Isoprofit slope = production function slope i.e. w = MPL = 1 MPL = MRPL.
* * * C wL
* Given w, RC’s firm’s quantitydemanded of labor is L*Labor
demand
RC gets
0
29
Profit-Maximization
Labor (hours)
Coconuts
Production function
24
C*
L*
Isoprofit slope = production function slope i.e. w = MPL = 1 MPL = MRPL.
* Given w, RC’s firm’s quantitydemanded of labor is L* andoutput quantity supplied is C*.
Labordemand
Outputsupply
* * * C wLRC gets
0
30
Utility-Maximization
Now consider RC as a consumer endowed with $* who can work for $w per hour.
What is RC’s most preferred consumption bundle?
Budget constraint isC wL * .
31
Utility-Maximization
Labor (hours)
Coconuts
*
240
C wL * .Budget constraint; slope = w
32
Utility-Maximization
Labor (hours)
Coconuts
More preferred
240
33
Utility-Maximization
Labor (hours)
Coconuts
*
240
C wL * .Budget constraint; slope = w
34
Utility-Maximization
Labor (hours)
Coconuts
*
Budget constraint; slope = w
240
C wL * .
35
Utility-Maximization
Labor (hours)
Coconuts
*
240
C wL * .C*
L*
Budget constraint; slope = w
36
Utility-Maximization
Labor (hours)
Coconuts
*
240
C wL * .C*
L*
MRS = wBudget constraint; slope = w
37
Utility-Maximization
Labor (hours)
Coconuts
*
240
C wL * .C*
L*
Laborsupply
Budget constraint; slope = wMRS = w
Given w, RC’s quantitysupplied of labor is L*
38
Utility-Maximization
Labor (hours)
Coconuts
*
240
C wL * .C*
L*
Given w, RC’s quantitysupplied of labor is L* andoutput quantity demanded is C*.
Laborsupply
Outputdemand
Budget constraint; slope = wMRS = w
39
Utility-Maximization & Profit-Maximization
Profit-maximization: w = MPL
quantity of output supplied = C*quantity of labor demanded = L*
40
Utility-Maximization & Profit-Maximization
Profit-maximization: w = MPL
quantity of output supplied = C*quantity of labor demanded = L*
Utility-maximization: w = MRSquantity of output demanded = C*quantity of labor supplied = L*
41
Utility-Maximization & Profit-Maximization
Profit-maximization: w = MPL
quantity of output supplied = C*quantity of labor demanded = L*
Utility-maximization: w = MRSquantity of output demanded = C*quantity of labor supplied = L*
Coconut and labormarkets both clear.
42
Utility-Maximization & Profit-Maximization
Labor (hours)
Coconuts
24
C*
L*
*
0
MRS = w = MPL
Given w, RC’s quantitysupplied of labor = quantitydemanded of labor = L* andoutput quantity demanded =output quantity supplied = C*.
43
Pareto Efficiency
Must have MRS = MPL.
44
Pareto Efficiency
Labor (hours)
Coconuts
240
MRS MPL
45
Pareto Efficiency
Labor (hours)
Coconuts
240
MRS MPL
Preferred consumptionbundles.
46
Pareto Efficiency
Labor (hours)
Coconuts
240
MRS = MPL
47
Pareto Efficiency
Labor (hours)
Coconuts
240
MRS = MPL. The common slope relative wage rate w that implements the Pareto efficient plan by decentralized pricing.
48
First Fundamental Theorem of Welfare Economics
A competitive market equilibrium is Pareto efficient ifconsumers’ preferences are convexthere are no externalities in
consumption or production.
49
Second Fundamental Theorem of Welfare Economics Any Pareto efficient economic state
can be achieved as a competitive market equilibrium ifconsumers’ preferences are convexfirms’ technologies are convexthere are no externalities in
consumption or production.
50
Non-Convex Technologies
Do the Welfare Theorems hold if firms have non-convex technologies?
51
Non-Convex Technologies
Do the Welfare Theorems hold if firms have non-convex technologies?
The 1st Theorem does not rely upon firms’ technologies being convex.
52
Non-Convex Technologies
Labor (hours)
Coconuts
240
MRS = MPL The common slope relative wage rate w that implements the Pareto efficient plan by decentralized pricing.
53
Non-Convex Technologies
Do the Welfare Theorems hold if firms have non-convex technologies?
The 2nd Theorem does require that firms’ technologies be convex.
54
Non-Convex Technologies
Labor (hours)
Coconuts
240
MRS = MPL. The Pareto optimal allocation cannot be implemented by a competitive equilibrium.
55
Production Possibilities
Resource and technological limitations restrict what an economy can produce.
The set of all feasible output bundles is the economy’s production possibility set.
The set’s outer boundary is the production possibility frontier.
56
Production Possibilities
Fish
Coconuts
Production possibility frontier (ppf)
57
Production Possibilities
Fish
Coconuts
Production possibility frontier (ppf)
Production possibility set
58
Production Possibilities
Fish
Coconuts
Feasible butinefficient
59
Production Possibilities
Fish
Coconuts
Feasible butinefficient
Feasible and efficient
60
Production Possibilities
Fish
Coconuts
Feasible butinefficient
Feasible and efficient
Infeasible
61
Production Possibilities
Fish
Coconuts
Ppf’s slope is the marginal rateof product transformation.
62
Production Possibilities
Fish
Coconuts
Ppf’s slope is the marginal rateof transformation.
Increasingly negative MRT increasing opportunitycost to specialization.
63
Production Possibilities
If there are no production externalities then a ppf will be concave w.r.t. the origin.
Why?
64
Production Possibilities
If there are no production externalities then a ppf will be concave w.r.t. the origin.
Why? Because efficient production requires
exploitation of comparative advantages.
65
Comparative Advantage
Two agents, RC and Man Friday (MF). RC can produce at most 20 coconuts
or 30 fish. MF can produce at most 50 coconuts
or 25 fish.
66
Comparative Advantage
F
C
F
C
RC
MF
20
50
30
2567
Comparative Advantage
F
C
F
C
RC
MF
20
50
30
25
MRT = -2/3 coconuts/fish so opp. cost of onemore fish is 2/3 foregone coconuts.
68
Comparative Advantage
F
C
F
C
RC
MF
20
50
30
25
MRT = -2/3 coconuts/fish so opp. cost of onemore fish is 2/3 foregone coconuts.
MRT = -2 coconuts/fish so opp. cost of onemore fish is 2 foregone coconuts.
69
Comparative Advantage
F
C
F
C
RC
MF
20
50
30
25
MRT = -2/3 coconuts/fish so opp. cost of onemore fish is 2/3 foregone coconuts.
MRT = -2 coconuts/fish so opp. cost of onemore fish is 2 foregone coconuts.
RC has the comparativeopp. cost advantage inproducing fish.
70
Comparative Advantage
F
C
F
C
RC
MF
20
50
30
25
MRT = -2/3 coconuts/fish so opp. cost of onemore coconut is 3/2 foregone fish.
71
Comparative Advantage
F
C
F
C
RC
MF
20
50
30
25
MRT = -2/3 coconuts/fish so opp. cost of onemore coconut is 3/2 foregone fish.
MRT = -2 coconuts/fish so opp. cost of onemore coconut is 1/2 foregone fish.
72
Comparative Advantage
F
C
F
C
RC
MF
20
50
30
25
MRT = -2/3 coconuts/fish so opp. cost of onemore coconut is 3/2 foregone fish.
MRT = -2 coconuts/fish so opp. cost of onemore coconut is 1/2 foregone fish.
MF has the comparativeopp. cost advantage inproducing coconuts.
73
Comparative Advantage
F
C
Economy
F
C
F
C
RC
MF
20
50
30
25
70
55
50
30
Use RC to producefish before using MF.
Use MF toproducecoconuts before using RC.
74
Comparative Advantage
F
C
Economy
F
C
F
C
RC
MF
20
50
30
25
70
55
50
30
Using low opp. costproducers first resultsin a ppf that is concave w.r.t the origin.
75
Comparative Advantage
F
C
Economy
More producers withdifferent opp. costs“smooth out” the ppf.
76
Coordinating Production & Consumption The ppf contains many technically
efficient output bundles. Which are Pareto efficient for
consumers?
77
Coordinating Production & Consumption
Fish
Coconuts
C
F
Output bundle isand is the aggregateendowment for distribution to consumers RC and MF.
( , ) F C
78
Coordinating Production & Consumption
Fish
Coconuts
ORC
OMFC
F
Output bundle isand is the aggregateendowment for distribution to consumers RC and MF.
( , ) F C
79
Coordinating Production & Consumption
Fish
Coconuts
ORC
OMFC
F
Allocate efficiently;say to RC and to MF.
( , ) F C
CRC CMF
FMF
FRC
( , ) F CRC RC
( , ) F CMF MF
80
Coordinating Production & Consumption
Fish
Coconuts
ORC
OMFC
F
CRC CMF
FMF
FRC
81
Coordinating Production & Consumption
Fish
Coconuts
ORC
OMFC
F
CRC CMF
FMF
FRC
82
Coordinating Production & Consumption
Fish
Coconuts
ORC
OMFC
F
CRC CMF
FMF
FRC
MRS MRT
83
Coordinating Production & Consumption
Fish
Coconuts
ORC
OMFC
F
CRC CMF
FMF
FRC
O’MFC
F
( , ). F CInstead produce
84
Coordinating Production & Consumption
Fish
Coconuts
ORC
OMFC
F
CRC CMF
FMF
FRC
C
F
( , ). F C
O’MF
CMF
Instead produceGive MF same allocation as before.FMF
85
Coordinating Production & Consumption
Fish
Coconuts
ORC
OMFC
F
CRC CMF
FMF
FRC
C
F
( , ). F C
O’MF
CMF
Instead produceGive MF same allocation as before. MF’s utility is unchanged.
FMF
86
Coordinating Production & Consumption
Fish
Coconuts
ORC
OMF
C
F
( , ). F C
O’MFFMF
Instead produceGive MF same allocation as before. MF’s utility is unchanged
CMF
87
Coordinating Production & Consumption
Fish
Coconuts
ORC
OMF
FRC
C
F
( , ). F C
O’MF
CRC
FMF
CMF
Instead produceGive MF same allocation as before. MF’s utility is unchanged
88
Coordinating Production & Consumption
Fish
Coconuts
ORC
OMF
FRC
C
F
( , ). F C
O’MF
CRC
FMF
CMF
Instead produceGive MF same allocation as before. MF’s utility is unchanged, RC’s utility is higher
89
Coordinating Production & Consumption
Fish
Coconuts
ORC
OMF
FRC
C
F
( , ). F C
O’MF
CRC
FMF
CMF
Instead produceGive MF same allocation as before. MF’s utility is unchanged, RC’s utility is higher; Pareto improvement.
90
Coordinating Production & Consumption MRS MRT inefficient coordination
of production and consumption. Hence, MRS = MRT is necessary for a
Pareto optimal economic state.
91
Coordinating Production & Consumption
Fish
Coconuts
ORC
OMF
FRC
C
F
CRC
FMF
CMF
92
Decentralized Coordination of Production & Consumption RC and MF jointly run a firm
producing coconuts and fish. RC and MF are also consumers who
can sell labor. Price of coconut = pC.
Price of fish = pF.
RC’s wage rate = wRC.
MF’s wage rate = wMF.93
Decentralized Coordination of Production & Consumption LRC, LMF are amounts of labor
purchased from RC and MF. Firm’s profit-maximization problem is
choose C, F, LRC and LMF tomax . p C p F w L w LC F RC RC MF MF
94
Decentralized Coordination of Production & Consumptionmax . p C p F w L w LC F RC RC MF MF
Isoprofit line equation isconstant p C p F w L w LC F RC RC MF MF
95
Decentralized Coordination of Production & Consumptionmax . p C p F w L w LC F RC RC MF MF
Isoprofit line equation isconstant p C p F w L w LC F RC RC MF MF
which rearranges to
Cw L w L
ppp
FRC RC MF MF
C
F
C
.
96
Decentralized Coordination of Production & Consumptionmax . p C p F w L w LC F RC RC MF MF
Isoprofit line equation isconstant p C p F w L w LC F RC RC MF MF
which rearranges to
.
slopeintercept
Fp
p
p
LwLwC
C
F
C
MFMFRCRC
97
Decentralized Coordination of Production & Consumption
Fish
CoconutsHigher profit
Slopes = pp
F
C
98
Decentralized Coordination of Production & Consumption
Fish
Coconuts
The firm’s productionpossibility set.
99
Decentralized Coordination of Production & Consumption
Fish
Coconuts
Slopes = pp
F
C
100
Decentralized Coordination of Production & Consumption
Fish
Coconuts
Profit-max. plan
Slopes = pp
F
C
101
Decentralized Coordination of Production & Consumption
Fish
Coconuts
Profit-max. plan
Slope = pp
F
C
102
Decentralized Coordination of Production & Consumption
Fish
Coconuts
Profit-max. plan
Slope = pp
F
CCompetitive marketsand profit-maximization
.C
F
p
pMRT
103
Decentralized Coordination of Production & Consumption So competitive markets, profit-
maximization, and utility maximization all together cause
the condition necessary for a Pareto optimal economic state.
,MRSp
pMRT
C
F
104
Decentralized Coordination of Production & Consumption
Fish
Coconuts
ORC
OMF
FRC
C
F
CRC
FMF
CMF
Competitive marketsand utility-maximization
MRSpp
F
C .
105
Decentralized Coordination of Production & Consumption
Fish
Coconuts
ORC
OMF
FRC
C
F
CRC
FMF
CMF
Competitive markets, utility-maximization and profit- maximization
.MRTp
pMRS
C
F
106