Economics 423, Midterm
Examination #2, Fall 2005 – Professor Hackett
Name: Answer Key
[Worth one point :-) ] Answers in green font
PART I: Students enrolled for 4 units
only: Please provide the best answer to each of the
following three questions, each of which is worth 10 points:
Consider
the following model of a marine capture fishery. Fishery stock = X, effort = E,
stock growth is given by F(X) = aX – bX2. In a steady-state equilibrium where harvest equals
stock growth, we have stock X = a/b – E/b, and harvest H = E[a/b
– E/b]. For simplicity, assume the sales price per pound of fish = $1, so that
total revenue = $1 x H = E[a/b – E/b], and marginal
revenue product = a/b – 2E/b. Total effort cost = cE,
and marginal effort cost = c.
1.
(a) Derive the equation for the open-access level of
effort in a steady-state equilibrium. (b) If “a” = 1000, “b” = $1, and “c” =
$200, derive the numerical values for open-access equilibrium effort (E), stock
(X), and harvest (H). Show your work and indicate your answer below:
The open access
solution is found where profit equals zero è TR = TC. Based on the equations above,
that means E[a/b – E/b] = cE.
From this equation one can derive the following (reduced-form) solution: EO
= a – bc.
1.a. EO = a - bc
1.b. EO = 1000 – 200 = 800
XO = 1000 – 800 = 200
HO = 800*200 = 160,000
2.
Derive the equation for the group-optimal level of effort in a
steady-state equilibrium. (b) If “a” = 1000, “b” = $1, and “c” = $200,
derive the numerical values for group-optimal equilibrium effort (E), stock
(X), and harvest (H). Show your work and indicate your answer below:
The group
optimum solution is found where profit is maximized è
marginal revenue product equals marginal effort cost (MR = MC). Based on the
equations above, that means a/b – 2E/b = c. From this equation one can derive
the following (reduced-form) solution: E* = (a – bc)/2.
2.a. E* = (a – bc)/2
2.b. E* = (1000 – 200)/2 = 400
X*
= (1000 – 400) = 600
H*
= 400*600 = 240,000
3.
Use the diagram below to carefully indicate the correct numerical equilibrium
levels of harvest H (“y” axis) and stock X (“x” axis) associated with questions
1 and 2 above for open-access and group-optimal steady-state equilibria. Hint: By way of comparison, shown below is the
stock level and harvest rate consistent with maximum sustainable yield.
PART II: Students enrolled for 3 units
only: Please provide the best answer to each of the three
questions below, each of which is worth 10 points.
1.
(i) What is the purpose of the
contingent valuation method? Briefly list the reason(s) for using the
contingent valuation method for measuring the value of some aspect of the
natural environment, relative to other measurement methods. (ii) Briefly list
the shortcomings of the contingent valuation method. (iii) What is the purpose
of the travel cost method? List the reason(s) for using the travel cost method
for measuring the value of some aspect of the natural environment, relative to
other measurement methods. (iv) Briefly list the shortcomings
of the travel cost method.
CVM:
Purpose
= Valuation of
environmental or natural resource conservation, preservation, or restoration,
presented as a policy choice or contingency. Valuation results can become data
for benefit/cost analysis
Reasons
for using = Measure all
non-market values, including both active use values and especially non-use
values such as existence, option, or bequest value
Shortcomings
= As a stated preference approach, CVM
values do not derive from actual economic choices. People are unused to
assigning economic value to the environmental attributes in a CVM study, and
problems can arise in the way the attributes are framed in the questionnaire.
Some CVM valuation studies suffer from embedding bias.
TCM:
Purpose
= Valuation of
environmental or natural resource conservation, preservation, or restoration,
particularly sites with recreational value. Valuation results can become data
for benefit/cost analysis
Reasons
for using = Measure
non-market use values associated with a site, such as for hiking, river access,
hunting or fishing. Revealed preference data are based on actual economic
choices and thus are less controversial.
Shortcomings
= Cannot measure non-use values, and thus omits
important aspect of overall site valuation. Subject to difficulties in
attributing costs to a particular site when users engaged in multi-site travel.
2.
(i) Carefully draw a single
fully labeled diagram below correctly showing Keohane's
equilibrium political economy market model of effective support for legislation
or administrative rules. (ii) Show how the equilibrium is changed when those
groups that demand effective support are joined by several new and powerful
interest groups.
(i) See the diagram in the political economy chapter of your
textbook, and/or the PowerPoint slides for this topic on the course website.
(ii) This will increase the demand for effective support for the regulation in
question. An outward shift in demand will result in an increase in the
equilibrium quantity of effective support, and an increase in the equilibrium
price in political currency.
3.
Suppose that proposed environmental legislation includes a provision that those
who violate the law must pay a penalty equal to triple the economic gains from
being out of compliance with environmental law. It is common knowledge that 50
percent of all facilities are inspected for compliance each year, and that in
recent years judges have imposed the full statutory penalty 90 percent of the
time that a violation is detected. Based on this information, will the proposed
legislation create deterrence (i) for risk-neutral
violators, (ii) for risk-loving violators, and/or for (iii) risk-averse
violators?
Let “X” stand
for the economic gains from being out of compliance. Then the expected penalty
is given by the following expression: 0.90 * 0.50 * 3X, which simplifies to the
expected penalty being 1.35X. Note that the expected penalty exceeds the
economic gains from being out of compliance (1.35X > X).
(i) Is the risk-neutral violator deterred? Circle one: YES NO CANNOT BE
DETERMINED
(ii)
Is the risk-loving violator deterred? Circle one: YES NO CANNOT BE
DETERMINED
(iii)
Is the risk-averse violator deterred? Circle one: YES NO CANNOT BE
DETERMINED
Part
III. ALL STUDENTS: There are five questions below. Please answer any
three of them, and cross out the two that you do not wish to answer with
a BIG
X. Each
question is worth 10 points.
1.
Suppose that the marginal benefit from reducing emissions is given by the
equation MB = 100 - Z, and marginal cost from reducing emissions is given by
the equation MC = Z. Note that "Z" is the percentage of total
emissions to be reduced. Solve for the percentage of total emissions reduced
that maximizes total net benefits. Show your work.
Total net
benefit is maximized at a level of emissions reduction where MB = MC. If we
substitute the right-hand-side values for MB and MC from the question, we get:
100 – Z = Z. Solving for Z results in Z* = 50.
2.
Suppose that a risk-neutral chemical factory can save $20 million per year in
compliance costs by not complying with environmental regulations. Suppose that
the probability of the infraction being detected by field monitors is 70
percent, and that the probability of a judge imposing the statutory penalty
given detection is 80 percent. If the statutory penalty calls for a fine equal
to double the annual cost savings gained by the offender, then will this system
create deterrence? Show your work.
Expected
penalty = 0.70 * 0.80 * 2 * $20 million = $22.4 million.
Cost savings
from being out of compliance = $20 million.
Therefore the
system creates deterrence given the firm is risk-neutral.
3.
Given the information in question 2 above, what is the minimum statutory
penalty that would be just sufficient to create deterrence for this
risk-neutral firm? Show your work.
Let “Y” stand
for the minimum statutory penalty. Then the numerical value for Y must satisfy
the following:
0.70 * 0.80 * Y
= $20,000,001 (the
extra $1 is to provide minimal deterrence). Solving for Y yields the following
value:
Y =
$35,714,287.
4.
Suppose that a job is identical to many others in a competitive labor market
except that there is an additional 8 per 100,000 annual chance of accidental
death, and that the job pays a risk premium of $1,000 per year. Use the
"value of a statistical life" approach to determine the implied
economic value of a statistical life. Show your work.
VSL = $1,000/(8/100,000) = $1000/0.00008 = $12,500,000
5. The data in the table below refers to pollution emissions and marginal
pollution abatement cost per ton in an industry. Total industry-wide emissions
are to be reduced by 50 percent (2400 tons/year):
|
Firms |
Historical
Emissions (Tons/Yr) |
Marginal
Abatement Cost ($/Ton) |
Allowances
Bought |
Allowances
Sold |
Total
Abatement Cost (No Tradable Allowances) |
Total
Abatement Cost (Tradable Allowances) |
|
A |
400 |
200 |
|
200 |
40,000 |
80,000 |
|
B |
400 |
400 |
|
200 |
80,000 |
160,000 |
|
C |
400 |
600 |
|
200 |
120,000 |
240,000 |
|
D |
400 |
800 |
|
200 |
160,000 |
320,000 |
|
E |
800 |
1,000 |
*** |
*** |
400,000 |
400,000 |
|
F |
800 |
1,200 |
400 |
|
480,000 |
0 |
|
G |
800 |
1,400 |
400 |
|
560,000 |
0 |
|
TOTAL |
4000 |
--- |
800 |
800 |
1,840,000 |
1,200,000 |
a. Suppose that the
regulatory target of cutting total emissions by 50 percent is accomplished with
a command-and-control regulatory system that requires each firm to cut its
emissions by 50 percent. Correctly fill in the "total abatement cost"
column for "no tradable allowances" in the table above.
b. Now suppose that the
regulatory target of cutting total emissions by 50 percent is accomplished by
allowing each firm to emit only 50 percent of its historical emissions. These
allowances are fully tradable. Correctly fill in the "allowances
bought", "allowances sold", and "total abatement cost,
tradable allowances" columns in the table above.
*** Note: This
problem is more challenging than the ones I have used on previous exams. Firms
A – D cannot supply enough allowances to meet the quantity demanded by firms
E-G. Firms A – D can supply enough for firms F and G. Firm E may try to supply
allowances, but can only do so at a price above $1,000 per allowance. Under
competitive conditions, however, firms A – D can meet all of firms F and G’s
allowance demand at an allowance price less than $1,000 (and above $800), which
will drive firm E out as an allowance supplier. At any price below $1,000,
however, firm E will want to buy allowances. Therefore we would expect an
equilibrium allowance price of $1,000 at which firms A – D sell 800 allowances
and firms F and G buy 800 allowances. Firm E is shut out of the allowance
market completely, and must cut ½ of its emissions based on its original
endowment of only 400 allowances.
PART
IV: ALL STUDENTS. Matching (13 matches, 3 points each,
39 points total). There is one uniquely correct match that connects a word or phrase on
the left with a description on the right. Only clear and unambiguous answers
can be marked as correct.
|
Word or Phrase |
Description |
|
a. Risk-averse |
1. __P__ Example of the direct cost of environmental regulation. |
|
b. Marginal benefit equals marginal cost |
2. __ A__ If the expected penalty is equal to the benefit from violating environmental or resource law, this sort of individual will be deterred from violating the law. |
|
c. Total benefit equals total cost |
3. __ G__ People with this attitude towards risk will not be deterred from environmental crime if the expected penalty equals the gain from being out of compliance. |
|
d. Market reputation |
4. __ I__ Environmental valuation technique that estimates the value of non-market aspects of the environment (such as a park) that are bundled together with things (such as houses adjacent to the park) that are traded in markets. |
|
e. Firms have heterogeneous marginal abatement costs |
5. __ C__ Occurs at the level of pollution control where total net benefits equal zero. |
|
f. Command-and-control regulation |
6. __ E__ In order for cap-and-trade systems to reduce industry-wide costs of compliance, this must be true for the firms in the industry. |
|
g. Risk-loving |
7. __ L__ Examples of these include nutrient cycling provided by wetlands, carbon absorption by trees and plankton, fruit pollination by wild insects, and water filtering provided by aquifers and watersheds. |
|
h. Environmental taxes |
8. __ K__ This can occur when a polluter buys lots of allowances in a cap-and-trade system, and can result in environmental injustice for nearby residents. |
|
i. Hedonic regression method |
9. __ F__ This type of regulation is subdivided into technology-based standards and uniform performance-based standards. |
|
j. Travel cost method |
10 __ H__ Examples include effluent taxes on pollution emissions and excise taxes on goods made using polluting production methods. |
|
k. A localized pollution “hot spot” |
11. __ O__ Law that requires a minimum percentage of a state's total electricity production must come from renewable sources. |
|
l. Ecosystem services not traded in markets |
12. __ D__ When effective, this can give firms an incentive to voluntarily over-comply with environmental or resource regulations due to the actions of vigilant, selective, and environmentally conscious consumers. |
|
m. |
13. __ M__ Treaty to control greenhouse gases that the
|
|
n. |
|
|
o. Renewable Portfolio Standard |
|
|
p. The cost of pollution abatement equipment like scrubbers. |
|