Fixed Income Basics Spot Interest rates The zerocoupon
Fixed Income Basics Spot Interest rates The zero-coupon yield curve Bond yield-to-maturity Default-free bond pricing Forward Rates Term Structure Theory Finance 30233, Fall 2010 The Neeley School of Business at TCU ©Steven C. Mann, 2010
Term structure yield 7. 0 6. 5 6. 0 Typical interest rate term structure 5. 5 5. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 Maturity (years) “Term structure” may refer to various yields: “spot zero curve”: yield-to-maturity for zero-coupon bonds (0 yt ) source: current market bond prices (spot prices) “forward curve”: forward short-term interest rates: “forward rates: f(t, T)” source: zero curve, current market forward rates “par bond curve”: yield to maturity for bonds selling at par source: current market bond prices
Determination of the zero curve B(0, t) is discount factor: price of $1 received at t; B(0, t) (1+ 0 yt)-t. Example: find 2 -year zero yield use 1 -year zero-coupon bond price and 2 -year coupon bond price: bond price per $100: 1 -year zero-coupon bond 94. 7867 2 -year 6% annual coupon bond 100. 0000 yield 5. 500% 6. 000% B(0, 1) = 0. 9479. Solve for B(0, 2): 6% coupon bond value = B(0, 1)($6) + B(0, 2)($106) $100 = 0. 9479($6) + B(0, 2)($106) 100 = 5. 6872 + B(0, 2)($106) 94. 3128 = B(0, 2)(106) B(0, 2) = 94. 3128/106 = 0. 8897 so that 0 y 2 = (1/B(0, 2))(1/2) -1 = (1/0. 8897)(1/2) -1 = 6. 0151%
“Bootstrapping” the zero curve from Treasury prices Example: six-month T-bill price 12 -month T-bill price B(0, 6) = 0. 9748 B(0, 12) = 0. 9493 18 -month T-note with 8% coupon paid semi-annually price = 103. 77 find “implied” B(0, 18): 103. 77 = = = 96. 0736 = B(0, 18) = 4 B(0, 6) + 4 B(0, 12) + (104)B(0, 18) 4 (0. 9748+0. 9493) + 104 B(0, 18) 7. 6964 + 104 B(0, 18) 96. 0736/104 = 0. 9238 24 -month T-note with 7% semi-annual coupon: Price = 101. 25 = 3. 5 B(0, 6) + 3. 5 B(0, 12) + 3. 5 B(0, 18) + 103. 5 B(0, 24) = 3. 5(0. 9748+0. 9493+0. 9238) + 103. 5 B(0, 24) = (101. 25 - 9. 9677)/103. 5 = 0. 9016
Coupon Bonds T Price = S Ct B(0, t) t=1 + (Face) B(0, T) where B(0, t) is price of 1 dollar to be received at time t or T Price = S t=1 Ct 1 (1+rt)t + 1 (Face) (1+r )T t where rt is discretely compounded rate associated with a default-free cash flow (zero-coupon bond) at time t. Define par bond as bond where Price=Face Value = (par value)
Yield to Maturity Define yield-to-maturity, y, as: T Price S t=1 Ct 1 (1+y)t + 1 (Face)(1+y)T Solution by trial and error [calculator/computer algorithm] Example: 2 -year 7% annual coupon bond, price =104. 52 per 100. by definition, yield-to-maturity y is solution to: 104. 52 = 7/(1+y) + 7/(1+y)2 + 100/(1+y)2 initial guess : second guess: y = 0. 05 y = 0. 045 eventually: when y = 0. 04584 price = 103. 72 price = 104. 68 price = 104. 52 (guess too high) (guess too low) y = 4. 584% If annual yield = annual coupon, then price=face (par bond)
Coupon bond yield is “average” of zero-coupon yields Coupon bond yield-to maturity, y, is solution to:
Bonds with same maturity but different coupons will have different yields.
Forward rates Introductory example (annual compounding) : one-year zero yield : 0 y 1 =5. 85% ; B(0, 1) = 1/(1. 0585) = 0. 944733 two-year zero yield: 0 y 2 =6. 03% ; B(0, 2) = 1/(1. 0603)2 = 0. 889493 $1 investment in two-year bond produces $1(1+0. 0603)2 = $1. 1242 at year 2. $1 invested in one-year zero produces $1(1+0. 0585) = $1. 0585 at year 1. What “breakeven” rate at year 1 equates two outcomes? (1 + 0. 0603)2 = (1 + 0. 0585) [ 1 + f (1, 2) ] breakeven rate = forward interest rate from year 1 to year 2 = f (1, 2) (one year forward, one-year rate) 1 + f (1, 2) = (1. 0603)2/(1. 0585) f (1, 2) = 1. 0621 - 1 and $1. 0585 (1. 0621) = $1. 1242. = 1. 062103 = 6. 21%
Forward and spot rate relationships : annualized rates
Example: Using forward rates to find spot rates Given forward rates, find zero-coupon bond prices, and zero curve Bond paying $1, 000: maturity Price yield-to-maturity (1/1) year 1 $1, 000/(1. 08) = $925. 93 0 y 1=[1. 08] -1 year 2 $1, 000/[(1. 08)(1. 10)] = $841. 75 0 y 2 = year 3 $1, 000/[(1. 08)(1. 10)(1. 11)] = $758. 33 0 y 3 =[(1. 08)(1. 10)(1. 11)] year 4 $1, 000/[(1. 08)(1. 10)(1. 11)] = $683. 18 =8% [(1. 08)(1. 10)](1/2)- 1 =8. 995% (1/3) 0 y 4 =[(1. 08)(1. 10)(1. 11)] = 9. 660% (1/4) = 9. 993%
Yield curves rate Typical upward sloping yield curve Forward rate zero-coupon yield coupon bond yield maturity rate Typical downward sloping yield curve Coupon bond yield zero-coupon yield forward rate maturity
Holding period returns under certainty (forward rates are future short rates) One year later: f (0, 1) = 0 y 1 = 10% f (1, 2) = 11% f (2, 3) = 11% One-year holding period returns of zero-coupons: invest $100: one-year zero: $100 investment buys $100/92. 92593 = $108. 00 Face value. At end of 1 year, value = $108. 00 ; return = (108/100)-1 = 8. 0% two-year zero: $100 investment buys $100/84. 175 = $118. 80 Face value. at end of 1 year, Value = $118. 80/1. 10 = $108. 00 ; return = (108/100) -1 = 8. 0% three-year zero: $100 investement buys $100/75. 833 = $131. 87 face value at end of 1 year, value = $131. 87/[(1. 10)(1. 11)] = $108. 00 ; return = (108/100) -1 = 8. 0% If future short rates are certain, all bonds have same holding period return
Holding period returns when future short rates are uncertain One year holding period returns of $100 investment in zero-coupons: one-year zero: $100 investment buys $100/92. 92593 = $108. 00 Face value. 1 year later, value = $108. 00 ; return = (108/100)-1 = 8. 0% (no risk) two-year zero: $100 investment buys $118. 80 face value. 1 year later: short rate = 11%, value = 118. 80/1. 11 = 107. 03 short rate = 9%, value = 118. 80/1. 09 = 108. 99 7. 03% return 8. 99% return Risk-averse investor with one-year horizon holds two-year zero only if expected holding period return is greater than 8%: only if forward rate is higher than expected future short rate. Liquidity preference: investor demands risk premium for longer maturity
Term Structure Theories 1) Expectations: forward rates = expected future short rates 2) Market segmentation: supply and demand at different maturities 3) Liquidity preference: short-term investors demand risk premium rate Forward rate = expected short rate + constant Yield curve is upward sloping Expected short rate is constant Yield Curve: constant expected short rates constant risk premium maturity
Possible yield curves with liquidity preference rate Forward rate Yield curve Liquidity premium increasing with maturity Expected short rate is declining maturity rate Forward rate Humped yield curve Constant Liquidity premium Expected short rate is declining maturity
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