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Risk, Return, and the Time Value of Money. Chapter 14. Relationship Between Risk and Return. Risk Uncertainty about the actual rate of return over the holding period Required rate of return Risk-free rate. Types of Risk. Business risk (Changing Economy) Financial risk (Loan Default)
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Risk, Return, and the Time Value of Money Chapter 14
Relationship Between Risk and Return • Risk • Uncertainty about the actual rate of return over the holding period • Required rate of return • Risk-free rate
Types of Risk • Business risk (Changing Economy) • Financial risk (Loan Default) • Purchasing power risk (Inflation) • Liquidity risk (Converting to Cash)
The Time Value of Money • Money received today is worth more than money to be received in the future • Interest Rates • Nominal Rates = Real Rates + Inflation • Interest Rates are the rental cost of borrowing or the rental price charged for lending money • Simple Interest – Interest on the initial value only (Not commonly used except for some construction loans) • Compound Interest – Interest charged on Interest (Typical in Lending and Savings)
The Time Value of Money • Present Value (PV) - a lump sum amount of money today • Future Value (FV) - a lump sum amount of money in the future • Payment (PMT) or Annuity - multiple sums of money paid/received on a regularly scheduled basis
The Six Financial Functions • Future value of a lump sum invested today • Compound Growth • FV = PV(1+i)n • PV=value today, i= interest rate, & n= time periods • Example: where PV= $1, n=3, & i=10% • FV = $1 x (1+.10) x (1+.10) x (1+.10) • FV = $1 x 1.331 • FV = $1.331
The Six Financial Functions • Present Value of a Lump Sum • Discounting • Process of finding present values from a future lump sum • PV = FV [1/(1+i)n ] • Example: where FV= $1, n=3, & i=10% • PV = $1 x [1/(1+.10) x (1+.10) x (1+.10)] • PV = $1 x [1/1.331] • PV = $1 x 0.7513 • PV = $0.7513
The Six Financial Functions • Future Value of an Annuity • FVA = PMT[((1+i)n -1))/ i] • The future value of a stream of payments
The Six Financial Functions • Present Value of an Annuity • PVA = PMT[(1-(1/(1+i)n ))/ i] • The present worth of a stream of payments
The Six Financial Functions • Sinking Fund • SF PMT = FVA [ i / ((1+i)n -1))] • The payment necessary to accumulate a specific future value
The Six Financial Functions • Mortgage Payments (Mortgage Constant) • MTG PMT = PVA [ i / ((1 - (1/(1+i)n )))] • The payment necessary to amortize (retire) a specific present value
Effect of Changing the Compounding Frequency • Interest Rates are quoted on an annual basis • Increasing the frequency of compounding increases the amount of interest earned • Increasing the frequency of payments for an amortizing loan decreases the amount of interest paid
Examples • A Future Value Example: • You have just purchased a piece of residential land for $10,000. Based upon current and projected market conditions similar lots appreciate at 10% per year (annually). How much will your investment be worth in 10 years? How about 20 years. Is the effect of compounding 2 times greater?
Examples • A Present Value Example: • You have been offered the option of purchasing a condo which will be sold for $150,000 at the end of 15 years. You need to make a reasonable offer for the investment so that you can purchase it today. You expect that similar investments would provide an 8% return per year (annually). How much should you be willing to pay (in one lump sum) today for this investment?
Examples • Future Value of an Annuity Example: • You wish to save $2,000 per year over the 10 years you operate an apartment property. You can invest your savings at 8% per year (annually). How much money will you have in the account when you sell the investment?
Examples • Present Value of an Annuity Example : • You will receive $5,000 per year over the next 30 years as equity income from a ground lease you wish to purchase. Investors require an 8% return for similar investments If you wish to buy this property, how much should you offer (in one lump sum) for the investment today?
Examples • Sinking Fund Payment Example: • You wish to buy a house in 5 years. The down payment on a house, like you hope to purchase, will be $7,500. How much must you save every year to afford this down payment, given that you can invest the savings with the bank at 8%?
Examples • Mortgage Payment Example: • You have negotiated the purchase of a condominium for $70,000. You will need a loan of $60,000, which the local bank has offered based on a 30 year term at 6% interest (annually). How much will your annual payment be for the condo? • Since nearly all mortgages are calculated on a monthly basis what is the monthly payment for the loan?
Net Present Value (NPV) • Difference between how much an investment costs and how much it is worth to an investor • NPV Decision Rule • If the NPV is equal to or greater than zero, we choose to invest
Net Present Value (NPV) • PV inflows – PV outflows • NPV Formula:
Internal Rate of Return (IRR) • The discount rate that makes the NPV equal to zero - the rate of return on the investment • IRR Decision Rule • If the IRR is greater than or equal to our required rate of return, we choose to invest
Calculating Uneven Cash Flows • Initial Cash Flow is the Cost of the Investment • Initial Cash Flow is Zero (0) if solving for PV • Use the Nj Key for Repeating Sequential Cash Flows