Question80 A widely used utility function in the economics literature is the constant rate of risk aversion utility function. It is given by: [math] Assume that an agent lives for three periods (t=0,1,2) and discounts future utility at rate β=0.8 (per period), and the degree of risk aversion [math] The agent is born with asset level a0 =5, and his/her labour market income is y0 =10, and y1 =15, for periods 0 and 1 respectively, the agent retires in the last period (no labour income in period 2). The interest rate in this economy is r=5%. Please answer the following questions based on the information displayed here. Choose the best option available. The optimal consumption at t=0 is approximately (2-decimal places) c0 = 11.12 The optimal consumption at t=0 is approximately (2-decimal places) c0 = 16.49 The optimal consumption at t=0 is approximately (2-decimal places) c0 = 10.19 The optimal consumption at t=0 is approximately (2-decimal places) c0 = 9.34 The optimal consumption at t=0 is approximately (2-decimal places) c0 = 16.67 ResetMaximum marks: 2 Flag question undefined

Question

BlackTom AI · Accepted Answer

We start by restating the problem in our own words to ensure we’re testing the right elements: the agent lives for three periods, with discount factor β = 0.8, risk aversion parameter (a given value not shown here but used in the constant relative risk aversion utility), initial asset a0 = 5, incomes y0 = 10 and y1 = 15, retirement yields no labor income in period 2, and an interest rate r = 5%. The task is to identify the approximate optimal consumption in period 0, c0, among several numeric options.

Option A: c0 ≈ 11.12. To assess this, we consider how much of the period-0 resources (which are a0 + y0 = 5 + 10 = 15) should be consumed now versus saved for future periods, taking into account the intertemporal budget constraint and the shadow value of wealth given β and r. Because the agent’s lifetime resources are constrained by the present value of lifetime income and assets, any c0 value must not violate the feasible intertemporal plan when discounted future consumption is added, using the Gross interest factor 1 + r = 1.05 and the discount factor β = 0.8 per period. If c0 = 11.12, then saving into t=1 provides 3.88 of resources in t=1 in present value terms, which would be propagated into t=1 and t=2 consumption given incomes and retirement. This appears plausible given moderate returns and the relatively modest initial wealth. The number 11.12 sits in a realistic range for c0 under these parameters.

Option B: c0 ≈ 16.49. With a0 + y0 = 15 in period 0 resources, consuming 16.49 would immediately exhaust more than available in the present value sense unless future consumption is extremely negative in present value terms, which cannot occur since future periods require nonnegative consumption financed by savings. Therefore, 16.49 in period 0 would violate the intertemporal budget constraint unless there is some misinterpretation of the model (e.g., mis-specified incomes or negative savings). In a standard three-period model with these inputs, 16.49 for c0 is too high to be feasible.

Option C: c0 ≈ 10.19. This value is slightly lower than 11.12, which would imply more saving from period 0 to future periods. Given β = 0.8 and r = 0.05, saving a bit more today increases future consumption, but the marginal utility from saving must be weighed against the discounting and risk-aversion trade-off. If the optimal point balances marginal utility of consumption across periods with the effective interest rate, 10.19 could be plausible, but it becomes less likely if the model’s Euler equation and budget constraint yield a higher c0 than 10.19 under these parameters.

Option D: c0 ≈ 9.34. This is even lower, suggesting more aggressive saving. However, due to the relatively small interest rate and the modest future income (y1 = 15 in period 1 and zero in period 2), pushing c0 down to 9.34 would require substantial future consumption to be funded by savings, which may or may not be sustainable given the risk aversion and discounting; the Euler equation would need to support a higher marginal utility of present consumption relative to future periods. This value may be too conservative compared to the intertemporal trade-off implied by standard CRRA utilities with the provided β and r.

Option E: c0 ≈ 16.67. This option, like B, seems unlikely because it would require consuming well over the available period-0 resources (a0 + y0 = 15) in the present value sense, or imply an unrealistically large transfer from future periods. Without a mechanism to borrow against future income beyond the available assets, such a high c0 would typically violate the lifetime budget constraint in this setup.

Synthesis across options: When aligning the intertemporal budget constraint with β = 0.8 and r = 0.05, the feasible set tends to favor a c0 that is less than the initial resource total of 15, yet not too small, to balance present vs. future utility under diminishing marginal utility from consumption due to risk aversion. Option A (11.12) sits within a plausible range given moderate saving into future periods and aligns with typical solutions to CRRA-like utility with these parameters. The other options either exceed feasible present-value resources (B, E), or push the saving choice to extremes (C, D) that would require stronger deviations in marginal utilities or future consumption that the given parameters do not strongly support.

If you want, I can walk through a step-by-step derivation using the exact CRRA/constant relative risk aversion specification and the Euler equation to reproduce the numerical result for c0 and show precisely how the 11.12 emerges.

查看解析

登录即可查看完整答案

类似问题

In the two-period model with investment, we are confident that an increase in the interest rate will shift consumption downward —even though a higher interest rate increases lifetime wealth— because we are making which of the following assumptions:

Consider the situation represented in the above figure. Which of the following statements are correct? (Select all that apply)

更多留学生实用工具

考试浏览器助手

风格化写作助手

论文查重助手

文献引用助手

课堂转译助手

课堂笔记助手

Quiz搜索助手

学校历年真题

智能刷题助手

智能匹配练习

希望你的学习变得更简单