A university spent $1.8 million to install solar panels atop a parking garage. These panels will have a capacity of 200 kilowatts (kW) and have a lifeexpectancy of 20 years. Suppose that the discount rate is 10%, that electricity can be purchased at $0.30 per kilowatt-hour (kWh), and that themarginal cost of electricity production using the solar panels is zero.Hint: It may be easier to think of the present value of operating the solar panels for 1 hour per year first.Approximately how many hours per year will the solar panels need to operate to enable this project to break even?O 4,228.58O 1,409.53O 3,523.82O 5,285.73If the solar panels can operate only for 3,171 hours a year at maximum, the project would notbreak even.Continue to assume that the solar panels can operate only for 3,171 hours a year at maximum.In order for the project to be worthwhile (i.e., at least break even), the university would need a grant of at least

Breakeven: In economics break even is a point where the total cost is equal (even) to the total…

Answered: A university spent $1.8 million to…

Managerial Economics: A Problem Solving Approach

5th Edition

ISBN:9781337106665

Author:Luke M. Froeb, Brian T. McCann, Michael R. Ward, Mike Shor

Publisher:Luke M. Froeb, Brian T. McCann, Michael R. Ward, Mike Shor

Chapter16: Bargaining

Section: Chapter Questions

Problem 2MC

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A university spent $1.6 million to install solar panels atop a parking garage. These panels will have a capacity of 700 kilowatts (kW) and have a life expectancy of 20 years. Suppose that the discount rate is 20%, that electricity can be purchased at $0.30 per kilowatt-hour (kWh), and that the marginal cost of electricity production using the solar panels is zero. Hint: It may be easier to think of the present value of operating the solar panels for 1 hour per year first. Approximately how many hours per year will the solar panels need to operate to enable this project to break even? 1,564.62 2,503.39 625.85 If the solar panels can operate only for 1,408 hours a year at maximum, the projectwould break even. Continue to assume that the solar panels can operate only for 1,408 hours a year at maximum. In order for the project to be worthwhile (i.e., at least break even), the university would need a grant of at least
A university spent $1.3 million to install solar panels atop a parking garage. These panels will have a capacity of 70 kilowatts (kW) and have a life expectancy of 20 years. Suppose that the discount rate is 30%, that electricity can be purchased at $0.20 per kilowatt-hour (kWh), and that the marginal cost of electricity production using the solar panels is zero. Hint : It may be easier to think of the present value
A university spent $1.5 million to install solar panels atop a parking garage. These panels will have a capacity of 700 kilowatts (kW) and have a life expectancy of 20 years. Suppose that the discount rate is 10%, that electricity can be purchased at $0.10 per kilowatt-hour (kWh), and that the marginal cost of electricity production using the solar panels is zero. Hint: It may be easier to think of the present value of operating the solar panels for 1 hour per year first. Approximately how many hours per year will the solar panels need to operate to enable this project to break even? 1,006.80 2,516.99 3,020.39 3,272.09 If the solar panels can operate only for 2,265 hours a year at maximum, the project (would/would not) break even. Continue to assume that the solar panels can operate only for 2,265 hours a year at maximum. In order for the project to be worthwhile (i.e., at least break even), the university would need a grant of at least…
A university spent $1.4 million to install solar panels atop a parking garage. These panels will have a capacity of 900 kilowatts (kW) and have a life expectancy of 20 years. Suppose that the discount rate is 20%, that electricity can be purchased at $0.20 per kilowatt-hour (kWh), and that the marginal cost of electricity production using the solar panels is zero. Hint: It may be easier to think of the present value of operating the solar panels for 1 hour per year first. Approximately how many hours per year will the solar panels need to operate to enable this project to break even? O 1,597.23 O 2,395.85 O 1,437.51 O 1,118.06 If the solar panels can operate only for 1,438 hours a year at maximum, the project break even. Continue to assume that the solar panels can operate only for 1,438 hours a year at maximum. In order for the project to be worthwhile (l.e., at least break even), the university would need a grant of at least
A university spent $2 million to install solar panels atop a parking garage. These panels will have a capacity of 700 kilowatts (kW) and have a life expectancy of 20 years. Suppose that the discount rate is 30%, that electricity can be purchased at $0.10 per kilowatt-hour (kWh), and that the marginal cost of electricity production using the solar panels is zero. Hint: It may be easier to think of the present value of operating the solar panels for 1 hour per year first. Approximately how many hours per year will the solar panels need to operate to enable this project to break even? 6,893.28 8,616.60 3,446.64 12,924.90 If the solar panels can operate only for 7,755 hours a year at maximum, the project break even. Continue to assume that the solar panels can operate only for 7,755 hours a year at maximum. In order for the project to be worthwhile (i.e., at least break even), the university would need a grant of at least Note:- Do not provide handwritten solution. Maintain accuracy and…
A university spent $1.5 million to install solar panels atop a parking garage. These panels will have a capacity of 200 kilowatts (kW) and have a life expectancy of 20 years. Suppose that the discount rate is 10%, that electricity can be purchased at $0.30 per kilowatt-hour (kWh), and that the marginal cost of electricity production using the solar panels is zero. Hint: It may be easier to think of the present value of operating the solar panels for 1 hour per year first. Approximately how many hours per year will the solar panels need to operate to enable this project to break even? 1,468.26 2,936.51 3,230.16 4,111.11 If the solar panels can operate only for 2,643 hours a year at maximum, the project Continue to assume that the solar panels can operate only for 2,643 hours a year at maximum. break even. In order for the project to be worthwhile (1.e., at least break even), the university would need a grant of at least,
A university spent $1.4 million to install solar panels atop a parking garage. These panels will have a capacity of 200 kilowatts (kW) and have a life expectancy of 20 years. Suppose that the discount rate is 20%, that electricity can be purchased at $0.30 per kilowatt-hour (kWh), and that the marginal cost of electricity production using the solar panels is zero. Hint: It may be easier to think of the present value of operating the solar panels for 1 hour per year first. Approximately how many hours per year will the solar panels need to operate to enable this project to break even? 4,791.73 O 6,708.42 3,354.21 5,750.08 If the solar panels can operate only for 4,313 hours a year at maximum,, the project would not Continue to assume that the solar panels can operate only for 4,313 hours à year at maximum. break even In order for the project to be worthwhile (i.e., at least break even), the university would need a grant of at least $223,793.26 $139,870.79 $83,922.47
A university spent $2 million to install solar panels atop a parking garage. These panels will have a capacity of 700 kilowatts (kW) and have a life expectancy of 20 years. Suppose that the discount rate is 20%, that electricity can be purchased at $0.10 per kilowatt-hour (kWh), and that the marginal cost of electricity production using the solar panels is zero. Hint: It may be easier to think of the present value of operating the solar panels for 1 hour per year first. Approximately how many hours per year will the solar panels need to operate to enable this project to break even? 8,214.28 5,867.34 2,346.94 4,693.87 If the solar panels can operate only for 5,281 hours a year at maximum, the project break even. Continue to assume that the solar panels can operate only for 5,281 hours a year at maximum. In order for the project to be worthwhile (i.e., at least break even), the university would need a grant of at least blank
A university spent $1.4 million to install solar panels atop a parking garage. These panels will have a capacity of 600 kilowatts (kW) and have a life expectancy of 20 years. Suppose that the discount rate is 20%, that electricity can be purchased at $0.20 per kilowatt-hour (kWh), and that the marginal cost of electricity production using the solar panels is zero. Hint: It may be easier to think of the present value of operating the solar panels for 1 hour per year first. Approximately how many hours per year will the solar panels need to operate to enable this project to break even? O3,593.73 O2,395.82 O 1,437.49 2,156.24 If the solar panels can operate only for 2,156 hours a year at maximum, the project Continue to assume that the solar panels can operate only for 2,156 hours a year at maximum. break even. In order for the project to be worthwhile (i.e., at least break even), the university would need a grant of at least
The accompanying table shows the relationship between the speed of a computer's CPU and its benefits and costs. Assume that all other features of the computer are the same (that is, CPU speed is the only source of variation), and only the CPU speeds listed in the table are available for purchase. CPU Total Marginal Total Marginal GHz Benefit Benefit Cost Costs 2.0 $1,000 $900 2.5 $1,400 $ 100 3.0 $300 $1,200 3.5 $1,900 $ 1,500 4.0 $2,000 $ 400 The marginal cost of upgrading from a 2.5GHz to 3.0GHz computer is O $400. O $300. $200. O $100.
The following accompanying table shows the relationship between the speed of a computer's CPU and its benefits and costs. Assume that all other features of the computer are the same (that is, CPU speed is the only source of variation), and only the CPU speeds listed below are available for purchase. CPU Total Marginal Total Marginal GHz Benefit Benefit Cost Costs 2.0 $1,000 $900 2.5 $1,400 $100 $1,200 $1,500 3.0 $300 3.5 $1,900 4.0 $2,000 $400 The total benefit of a 3.0GHZ computer is:
A community has a nighttime energy demand of 50 megawatts but a peak daytime demand of 75 megawatts. It has the chance to build a 90-megawatt coal-fired plant that could easily supply all of its energy needs even at peak daytime demand. Should it necessarily proceed? Could there be lower-cost options? Explain

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