Presentation is loading. Please wait.

Presentation is loading. Please wait.

Static Efficiency, Dynamic Efficiency and Sustainability Wednesday, January 25.

Published byTheodore Allison Modified over 9 years ago

Similar presentations

Presentation on theme: "Static Efficiency, Dynamic Efficiency and Sustainability Wednesday, January 25."— Presentation transcript:

1 Static Efficiency, Dynamic Efficiency and Sustainability Wednesday, January 25

2 Represent the demand for a resource as: P = 8 – 0.4 q Demand = marginal willingness to pay = Marginal Benefit (MB) Demand Quantity Demand $

3 P = 8 - 0.4q qP 08 56 104 152 200

4 Represent the demand for a resource as: P = 8 – 0.4 q Demand Quantity Demand $ (5,6) (15,2)

5 Assume a constant marginal cost of extraction = $2.00 (Marginal cost = supply) Demand Quantity MB $ MC Efficient allocation occurs where MB = MC, q = 15 units

6 Static Efficiency MB = MC MB = MC Criteria for allocation in a given time period, with no consideration of future time periods Criteria for allocation in a given time period, with no consideration of future time periods Efficiency: no one can be made better off without making someone else worse off Efficiency: no one can be made better off without making someone else worse off

7 $ Q MC MB MB>MC MC>MB MB=MC

8 What are the net benefits of the efficient allocation? Demand Quantity MB $ MC Efficient allocation occurs where MB = MC, q = 15 units

9 TB (area under MB curve)=½(6x15) + (2x15)=45+30=75 MC MB Quantity $ TC (area under MC curve) = (2x15) = 30 NB = TB – TC = ½(6x15) = 45 NB

10 Quantity $ MNB Total NB (area under MNB curve) = ½(6x15) = 45 This graph illustrates marginal net benefits: MB-MC = (8-0.4q)-2 = 6-0.4q = MNB

11 Dynamic Efficiency When the concern is efficient allocation of a nonrenewable resource over multiple time periods When the concern is efficient allocation of a nonrenewable resource over multiple time periods MNB 0 = PV MNB 1 = PV MNB 2 = … = PV MNB t MNB 0 = PV MNB 1 = PV MNB 2 = … = PV MNB t t represents time period t represents time period

12 With only 20 units of the resource available, what is the present value of total net benefits if effective demand is met in the first period, with no consideration of the second period? Only two time periods in this example Only two time periods in this example For present value calculations, r=.10 For present value calculations, r=.10

13 Quantity Period t 0 MB MC $

14 Quantity Period t 0 MB NB = Area = ½(6x15) = 45 MC $

15 $ Quantity Period t 1 MB MC

16 $ Quantity Period t 1 MB NB = Area = ½(2x5) + (4x5) = 25 MC

17 NB for t 0 = $45 Present Value of NB for t 1 = 25/(1+r) = 25/1.1 = $22.73 PV Total net benefit for two periods = $45 + $22.73 = $67.73

18 With only 20 units of the resource available, what is the present value of total net benefits if the resource is allocated equally across two time periods? (q 0 = q 1 )

19 Quantity Period t 0 MB MC $

20 Quantity Period t 0 MB NB = Area = ½(4x10) + (2x10) = 40 MC $

21 Quantity Period t 1 MB NB = Area = ½(4x10) + (2x10) = 40 MC $

22 NB for t 0 = $40 Present Value of NB for t 1 = 40/(1+r) = 40/1.1 = $36.36 PV Total net benefit for two periods = = $40 + $36.36 = $76.36

23 Recall, for dynamic efficiency (to maximize PV of total net benefits), MNB 0 = PV MNB 1 Find the dynamically efficient quantities for q 0 and q 1. Find the efficient allocation of the resource over the two periods (dynamic efficiency).

24 1) MNB 0 = PV MNB 1 2) 2) MNB = MB - MC 3) 3) MB = 8 – 0.4q 4) 4) MB – MC = (8 – 0.4q) – 2 = 6 – 0.4q 5) 5) MNB = 6 – 0.4q

25 1) MNB 0 = PV MNB 1 2) 2) 6 -.4q 0 = (6 -.4q 1 )/1.1 3) 3) q 0 + q 1 = 20 4) 4) 6 -.4q 0 = (6 -.4[20-q 0 ])/1.1 5) 5) 1.1(6 -.4q 0 )= (6-8+.4q 0 ) 6) 6) 6.6-.44q 0 = (-2 +.4q 0 ) 7) 7) 8.6=.84q 0 8) 8) q 0 = 10.238 9) 9) q 1 = 9.762

26 Quantity $ MNB This graph illustrates marginal net benefits: MB-MC=MNB

27 Quantity $ MNB 0 Period t 0 MNB = MB – MC = 6 – 0.4q

28 Period t 1 Quantity $ PV MNB 1 5.45 Present value calculation: 6/1.1 = 5.45

29 0 1 2 3 4 5 6 7 0 51015 Quantity $ MNB 0 5 1015 MNB 1 5.45 q 0 =10.238 q 1 =9.762 t0t0 t1t1

30 MNB 0 = 6 – 0.4(10.238) = 1.9048 MNB 0 = 6 – 0.4(10.238) = 1.9048 MNB 1 = [6 – 0.4(9.762)]/1.1 MNB 1 = [6 – 0.4(9.762)]/1.1 = 2.9052/1.1 = 1.9048 = 2.9052/1.1 = 1.9048

31 0 1 2 3 4 5 6 7 0 51015 Quantity $ MNB 0 5 1015 MNB 1 5.45 q0q0 q1q1 t0t0 t1t1 MNB=1.9048

32 To calculate total benefits, total costs, and net benefits: P 0 = 8 -.4q 0 P 0 = 8 -.4(10.238) P 0 = 3.905 P 1 = 8 -.4q 1 P 1 = 8 -.4(9.762) P 1 = 4.095

33 Quantity Period t 0 MB MC $ 10.238 NB = ½(4.095x10.238) + (1.905x10.238) = 40.46 3.905

34 $ Quantity Period t 1 MB MC 9.762 NB = ½(3.905x9.762) + (2.095x9.762) = 39.51 4.095

35 NB for t 0 = $40.46 Present Value of NB for t 1 = 39.51/(1+r) = 39.51/1.1 = $35.92 Total net benefit for two periods = $40.46+35.92 = $76.38

36 Comparing allocations: Maximize NB to period 0 Maximize NB to period 0 TNB = $67.73 TNB = $67.73 q 0 = q 1 q 0 = q 1 TNB = $76.36 TNB = $76.36 Dynamically efficient allocation Dynamically efficient allocation TNB = $76.38 TNB = $76.38

37 Sustainability Environmental sustainability Environmental sustainability Do not reduce total stock of natural capital Do not reduce total stock of natural capital Strong sustainability Strong sustainability Do not reduce productivity (value) of natural capital stock Do not reduce productivity (value) of natural capital stock One type of natural capital may substitute for another One type of natural capital may substitute for another Weak sustainability Weak sustainability Do not reduce productivity of capital Do not reduce productivity of capital May substitute manufactured capital for natural capital May substitute manufactured capital for natural capital

38 With equal distribution NB 0 = $40 NB 1 = $40 With efficient distribution NB 0 = $40.46 NB 1 = $39.51 With sharing, keep NB 0 = $40, invest $.46 @ 10%, send to t 1.46(1.1) =.506 NB 1 = $39.51 +.51 = $40.02

39 Marginal User Cost MNB 0 = 6 – 0.4(10.238) = 1.905 MNB 0 = 6 – 0.4(10.238) = 1.905 MNB 1 = [6 – 0.4(9.762)]/1.1 MNB 1 = [6 – 0.4(9.762)]/1.1 = 2.0952/1.1 = 1.905 = 2.0952/1.1 = 1.905 The value of the last unit extracted in t 0 The value of the last unit extracted in t 0 Foregone benefit for t 1 Foregone benefit for t 1 Opportunity cost of choosing to extract the last unit used in t 0 Opportunity cost of choosing to extract the last unit used in t 0

40 P = MEC + MUC P = MEC + MUC $3.905 = $2.00 + 1.905 $3.905 = $2.00 + 1.905 User Cost and Natural Resource Rent Quantity Period t 0 MB MC $ 10.238 3.905 Rent Wages, etc. User Cost

41 P = MEC + MUC P = MEC + MUC $4.095 = $2.00 + 2.095 $4.095 = $2.00 + 2.095 MUC increases at the rate of discount MUC increases at the rate of discount 2.095 = 1.1(1.905) 2.095 = 1.1(1.905) Period t 1 $ Quantity MB MC 9.762 4.095 Rent User Cost

42 Reading for Wed. Feb. 2: Hartwick and Olewiler, on ANGEL and Field, Ch. 6

Download ppt "Static Efficiency, Dynamic Efficiency and Sustainability Wednesday, January 25."

Similar presentations

Homework #9 due Thursday Quiz #4 on Thursday Homework #10 due Dec. 2 nd Exam #4 on Dec. 2 nd Last week of class – Group Presentations.

Homework #9 due Thursday Quiz #4 on Thursday Homework #10 due Dec. 2 nd Exam #4 on Dec. 2 nd Last week of class – Group Presentations.
Price discrimination Definition: charging different prices for the same product to different consumers Examples –senior citizen discounts –airfares: business.

Price discrimination Definition: charging different prices for the same product to different consumers Examples –senior citizen discounts –airfares: business.
Efficient Supply of Renewable and Non-Renewable Resources Econ 1661 Review Section February 24 th, 2012 Rich Sweeney (Based on slides from Robyn Meeks.

Efficient Supply of Renewable and Non-Renewable Resources Econ 1661 Review Section February 24 th, 2012 Rich Sweeney (Based on slides from Robyn Meeks.
Upcoming in Class Homework #5 Due Today Homework #6 Due Oct. 25

Upcoming in Class Homework #5 Due Today Homework #6 Due Oct. 25
Section 3/6/2009  VSL  Static vs. Dynamic Efficiency (Example: optimal extraction of a non-renewable resource)  Defining/ measuring scarcity  Definitions.

Section 3/6/2009  VSL  Static vs. Dynamic Efficiency (Example: optimal extraction of a non-renewable resource)  Defining/ measuring scarcity  Definitions.
Non-renewable Resources: Optimal Extraction

Non-renewable Resources: Optimal Extraction
 Homework #5 Due Monday  Homework #6 Due Oct. 22  Extra Credit Writing Assignment Oct. 17th  Writing Assignment Due Oct. 24th.

 Homework #5 Due Monday  Homework #6 Due Oct. 22  Extra Credit Writing Assignment Oct. 17th  Writing Assignment Due Oct. 24th.
General Equilibrium and Efficiency. General Equilibrium Analysis is the study of the simultaneous determination of prices and quantities in all relevant.

General Equilibrium and Efficiency. General Equilibrium Analysis is the study of the simultaneous determination of prices and quantities in all relevant.
Continuation of benefit estimation and non-renewable resources Econ 1661 Review Section February 25 th, 2011 Robyn Meeks (Based on slides from Avinash.

Continuation of benefit estimation and non-renewable resources Econ 1661 Review Section February 25 th, 2011 Robyn Meeks (Based on slides from Avinash.
Natural Resource Economics: An Overview. 2 period model MUC rises at rate of discount In period 2, MUC 1+r as large as in period 1 Suggests that efficiency.

Natural Resource Economics: An Overview. 2 period model MUC rises at rate of discount In period 2, MUC 1+r as large as in period 1 Suggests that efficiency.
Welfare Analysis. Ranking Economic systems  Objective: to find a criteria that allows us to rank different systems or allocations of resources.  This.

Welfare Analysis. Ranking Economic systems  Objective: to find a criteria that allows us to rank different systems or allocations of resources.  This.
Sustainable Development – defining the concept Quest of all of us.

Sustainable Development – defining the concept Quest of all of us.
1 Topic 1(e): Three normative questions What have we learned about efficiency so far? If we take as given the quantity of a good, we should: –distribute.

1 Topic 1(e): Three normative questions What have we learned about efficiency so far? If we take as given the quantity of a good, we should: –distribute.
Part 3 Markets and Efficiency

Part 3 Markets and Efficiency
1 Topic 1(e): Three normative questions Normative questions of interest are: 1.Which consumers should get to consume these goods? We know that in equilibrium.

1 Topic 1(e): Three normative questions Normative questions of interest are: 1.Which consumers should get to consume these goods? We know that in equilibrium.
Why study natural resource economics?

Why study natural resource economics?
Upcoming in Class Homework #5 Due Next Tuesday Oct.

Upcoming in Class Homework #5 Due Next Tuesday Oct.
AGEC/FNR 406 LECTURE 8 A rural market in the Philippines.

AGEC/FNR 406 LECTURE 8 A rural market in the Philippines.
Marginal Analysis for Optimal Decision Making

Marginal Analysis for Optimal Decision Making
Ch. 5: EFFICIENCY AND EQUITY

Ch. 5: EFFICIENCY AND EQUITY

Similar presentations

Ads by Google