In this presentation we’ll cover the valuation of contracts that are comprised of multiple cash flows. These contracts will cover: Show
AnnuitiesAn annuity is a contract which pays a fixed amount at the end of each period for a fixed number of periods. Many common financial contracts are annuities, such as fixed rate mortgages and auto loans. If the payments are in the beginning of a period (such as renting an apartment) the contract is known as an annuity due. The annuity is defined by its:
It is important that each quantity you use is over the same period, i.e. don’t use a yearly rate with monthly payments. The Present Value of an AnnuityTo calculate the present value of an annuity we can simply discount each payment individually, to the same period, and sum them. In other words we can: `PV_0 = \frac{C}{(1+r)^1} + \frac{C}{(1+r)^2} + ... + \frac{C}{(1+r)^n}` Note the PV is at time 0 (one period before the first payment in time 1). This calculation is very easy to do in a spreadsheet. However annuities are old, so historically we have used a simplified version of the above equation. Specifically the above is equal to: `PV_0 = C(\frac{1 - \frac{1}{(1+r)^n}}{r})` Applications of the PV of an AnnuityYou can use the above formula to find your monthly mortgage payment. Say you are going to borrow $150,000 to buy a house, and your 30-year mortgage rate is 5%. We can plug these values into the formula: `\$150,000 = C(\frac{1 - \frac{1}{(1 + \frac{5\%}{12})^{12(30)}}}{\frac{5\%}{12}})` rearranging for `C` (the monthly payment) gives: `C = \$805.23` PV of an Annuity CalculatorThe Future Value (FV) of an AnnuityWe can instead push each cash flow into the last period, and find the total value of the payments then. This is the FV of the annuity. The FV at the last period of the annuity (time `n`) is simply: `FV_n = C(1+r)^{n-1} + C(1+r)^{n-2} + ... + C` This is equivalent to: `FV_n = \frac{C(1 + r)^n - 1}{r}` Applications of the FV of an AnnuityCalculating the FV of an annuity is most often used in retirement calculations. For example, if you put $300 per month into an account earning 4% annual interest, how much money would you have in the account in 30 years? You will have `\frac{\$300(1 + \frac{4\%}{12})^{30(12)}}{\frac{4\%}{12}} = \$298,214.80` Future Value of an Annuity CalculatorFV of a Growing AnnuityThe FV of a growing annuity (in the last period `n`) is: `FV_n = C(1 + r)^{n-1} + C(1+g)(1+r)^{n-2} + ... + C(1+g)^{n-1}` which can be simplified to: `FV_n = C(\frac{(1+r)^n - (1+g)^n}{r - g})` where `r \ne g`. Again, you can try the calculation, and check your answer on the calculator below. PerpetuityA perpetuity is a contract which pays a fixed amount at the end of each period for an infinite number of periods. Despite having an infinite number of payments, the PV is a finite amount (assuming a positive interest rate). This is because later payments become negligible. The present value of a perpetuity is: `PV = \frac{C}{1+r} + \frac{C}{(1+r)^2} + \frac{C}{(1+r)^3} + \ldots =\frac{C}{r}` Applications of the PerpetuityLikely the best known perpetuity is preferred stock. Preferred stock pays a fixed dividend, unlike common stock whose dividend changes over time. Say ABC company’s preferred stock pays a fixed dividend of $7 per year every year. The discount rate is 10%. Then the preferred stock is worth: `PV = \frac{\$7}{0.10} = \$70` A Growing PerpetuityA growing perpetuity is a contract which pays a constantly increasing amount at the end of each period for an infinite number of periods. That is, if the first payment is `\$C`, then the following payments are `\$C(1+g)`, `\$C(1+g)^2` off to infinity. Assuming `g < r` the PV of the growing perpetuity is: $PV = + + + … = If `g \geq r` then the value is infinite. Applications of the Growing PerpetuityPerhaps the most famous application is the Gordon Growth Model of stock valuation. The model assumes a stock’s dividends grow at a constant rate. Since stock is infinitely lived, we can find the PV of the dividends (the stock’s value), as the PV of a growing perpetuity.
`PV = \frac{\$5}{7% - 3%} = \$125` Which of the following is true for calculating the future value of multiple cash flow?Which of the following is true for calculating the future value of multiple cash flows? To find the FV of multiple annuities, multiply the sum of all the present values by the interest rate plus time period.
Which of the following processes can be used to calculate future value for multiple cash flows multiple select questions?which of the following processes can be used to calculate future value for multiple cash flows? <> compounded accumulated balance forward one year at a time.
How is the present value and future value model is calculated for multiple cash flows?Present and Future Value of Cash Flow
The future value of a lump-sum of money is calculated using the formula FV = PV(1+i)^n. In this formula, FV is the future value, PV is the lump sum, i is the rate at which it grows, and n is the number of periods into the future.
What is the present value of this cash flow?The present value of a cash flow is the value of that cash flow at the present time, discounted back to the original investment date at the discount rate. The discount rate is multiplied by the present value of one period's cash flow to calculate the present value of a cash flow stream.
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Which of the following is true for calculating the present value of multiple cash flows
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