Question 1

Assume annual compounding. The one-year and two-year zero-coupon rates in the BDT model are 6% and 7%. The volatility is given to be $\sigma = 0.30$ . What is the price of a one-year maturity cap on the one-year interest rate at a strike rate of 8% and a notional of $100?

A) 1.000
B) 1.025
C) 1.050
D) 1.075

1.025

Accepted Answer

The price of a one-year maturity cap on the one-year interest rate with a strike rate of 8% and a notional of $100 can be calculated using the Black model formula for caps. Given the zero-coupon rates and the fact that the cap is on the one-year interest rate, we can infer that the relevant interest rate for the cap's underlying is the one-year zero-coupon rate, which is 6%. Since the strike rate is 8%, the cap is out of the money at inception, meaning its value will depend on the volatility and the difference between the strike rate and the underlying rate. However, without the need for detailed calculations or the Black model's formula specifics, the correct answer is determined by understanding that the cap's value is derived from its potential to pay off if the underlying rate exceeds the strike rate. Given the provided options and without the exact formula's calculation, the correct choice is selected based on the understanding of interest rate caps and the given parameters.

Question 2

A one-factor bond pricing model implies that interest-rates of all maturities are driven by a single source of stochastic randomness. For example the system of interest rates may be described by the following equation: $d r ( T ) = \alpha ( r ( T ) , T ) d t + \sigma ( r ( T ) , T ) d W , \quad \forall T$ where $T$ denotes the maturity of different rates. A single-factor model implies that

A) All rates either move up together or all move down together.
B) The yield curve experience parallel shifts.
C) Instantaneous changes in rates of all maturities are perfectly positively or negatively correlated with each other.
D) Twists in shape of the yield curve are not possible.

Instantaneous changes in rates of all maturities are perfectly positively or negatively correlated with each other.

Accepted Answer

In a one-factor model, all interest rates are driven by a single source of randomness, implying that changes in rates of all maturities are perfectly correlated, either positively or negatively.

Question 3

In the Black-Derman-Toy (BDT) model, short rates are distributed as
(a) Normal
(b) Lognormal
(c) Exponential
(d) None of the above

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Accepted Answer

In the BDT model, short rates have volatility that changes by maturity of the short rate. This is referred to as time-dependent volatility.

Question 4

Based on your answers to the previous two questions and a comparison of the prices of the cap and floor, what can you say about the forward rate between one and two years?
(a) The forward rate is roughly equal to the strike rate of the cap and floor. (b) The forward rate is such that the mark-to-market value of the FRA at the strike rate of the cap and floor will be zero.
(c) Both (a) and (b).
(d) There is not enough information to say anything about the forward rate.

Accepted Answer

Both statements A and B describe conditions that are typically true when the forward rate is at the level where the cap and floor prices would imply it to be. The forward rate being roughly equal to the strike rate of the cap and floor suggests that the market expects the future interest rate to be around that level. Additionally, the mark-to-market value of a forward rate agreement (FRA) being zero at the strike rate indicates that the forward rate is considered fair and balanced, aligning with the expectations embedded in the prices of the cap and floor.

Question 5

In the Cox-Ingersoll-Ross or CIR model, interest rates are specified by the following stochastic process: $d r _ { t } = k \left( \theta - r _ { t } \right) d t + \sigma \sqrt { r _ { t } } d W _ { t }$ One attractive feature of this process relative to the Vasicek interest rate process $d r _ { t } = k \left( \theta - r _ { t } \right) d t + \sigma d W _ { t }$ is that

A) Interest rates are always non-negative in CIR while they may be negative in the Vasicek model.
B) There are parameter restrictions which guarantee non-negative stochastic interest rates in the CIR model, but there are no such restrictions possible in the Vasicek model.
C) It has extra parameters, so can fit observed yield curves better.
D) It allows for imperfect instantaneous correlation between rates of different maturities, whereas in the Vasicek model, they are perfectly correlated.

Accepted Answer

The answer of In the Cox-Ingersoll-Ross or CIR model, interest...

Question 6

In the Cox-Ingersoll-Ross (CIR 1985) model, you are given that $d r _ { t } = \kappa \left( \theta - r _ { t } \right) d t + \sigma \sqrt { r _ { t } } d W _ { t }$ where $x = 0.5$ , $\theta = 0.06$ , $\sigma = 0.10$ , and the current short rate of interest is $r _ { 0 } = 0.08$ . What is the expected short rate of interest one year hence?

A) 6.6%
B) 7.2%
C) 7.6%
D) 8.2%

Accepted Answer

The expected short rate of interest one year hence can be calculated using the formula for the expected value of $r_t$ in the Cox-Ingersoll-Ross model: $E[r_t] = r_0 e^{-\kappa t} + \theta(1 - e^{-\kappa t})$. Substituting the given values ($\kappa = 0.5$, $\theta = 0.06$, $r_0 = 0.08$, and $t = 1$), we get $E[r_1] = 0.08e^{-0.5} + 0.06(1 - e^{-0.5}) \approx 0.072$ or 7.2%.

Question 7

In the Ho & Lee (1986) model, assume that the initial curve of zero-coupon rates for one and two years is 6% and 7%, respectively. Assume that the probability of an upshift in discount functions is equal to that of a downshift. If the parameter $\delta = 0.95$ , then the price of a one-year maturity call option on a two-year $100 face value zero-coupon bond in the up node after one year at a strike of $92 will be

A) 1.10
B) 1.20
C) 1.30
D) 1.40

Accepted Answer

The Ho & Lee model allows for the calculation of future bond prices based on initial curves and specified parameters. Given the initial price of a one-year zero-coupon bond is $0.9434$ and $\delta = 0.95$, the price of the bond in the up node after one year can be calculated as $0.9434 \times \delta = 0.9434 \times 0.95 = 0.89623$. However, since this result does not match any of the options and considering the nature of the Ho & Lee model's calculation for future prices, it seems there was a mistake in the calculation process. The correct approach involves adjusting the initial price by the factor $\delta$ in the context of the model's framework, which typically results in a new price that reflects the upward movement in interest rates. Given the options and the model's intent to reflect changes in bond prices due to shifts in the interest rate structure, without the exact formula application visible here, the correct answer is identified based on the understanding of the model's application to interest rate movements and bond pricing. The provided options suggest a misunderstanding in the calculation process, and the correct methodology involves using the Ho & Lee model's formulas to calculate the price of the bond in the up node correctly. The selection of option B as the correct answer is based on a reevaluation of how the model's parameters should be applied, indicating a need for clarification in the calculation explanation.

Question 8

The Ho & Lee (1986) model directly models the following on a binomial tree: &#10;A) Yields.&#10;B) Discount functions.&#10;C) Zero-coupon rates.&#10;D) Forward rates.&#10;

Accepted Answer

The answer of The Ho & Lee (1986) model directly...

Question 9

Assume annual compounding. The one-year and two-year zero-coupon rates in the BDT model are 6% and 7%. The volatility is given to be $\sigma = 0.30$ . What is the price of a one-year maturity cap on the one-year interest rate at a strike rate of 8% and a notional of $100?

A) 1.000
B) 1.025
C) 1.050
D) 1.075

1.025

Accepted Answer

A floor on the interest rate is a derivative that pays off when the interest rate falls below a certain level (the strike rate). The payoff is based on the difference between the strike rate and the actual rate, applied to the notional amount. Since we're looking at a one-year maturity floor on the one-year interest rate with a strike of 8%, we need to calculate the value of this floor given the current one-year zero-coupon rate of 6%.The formula to calculate the price of a floor is not directly provided, but we can infer that the floor is out of the money (since the strike rate of 8% is higher than the current one-year rate of 6%), and thus, its value will depend on the probability of the one-year rate falling below the strike rate in the future. However, given the information provided and the nature of the question, it seems we are expected to calculate the price of the floor using a simplified approach or a direct calculation.Given the lack of specific formula or method for calculating the floor's value in the question, and considering the BDT model's complexity, we can't directly compute the exact price without more information (like the risk-neutral probabilities of interest rate movements). However, the correct answer is provided as an option, suggesting that there might be a straightforward calculation or an assumption I'm missing in this explanation.In the context of the BDT model and given the information, the correct answer would typically involve calculating the expected payoff of the floor based on the probability of the interest rate falling below the strike rate and discounting that payoff back to the present value using the appropriate discount rate. Without the explicit formula or method to calculate this in the question, we rely on the provided options to guide the response.

Question 10

In the Ho & Lee (1986) model, assume that the initial curve of zero-coupon rates for one and two years is 6% and 7%, respectively. Assume that the probability of an upshift in discount functions is equal to that of a downshift. If the parameter $\delta = 0.95$ , then the price of a one-year maturity call option on a two-year $100 face value zero-coupon bond in the up node after one year at a strike of $92 will be

A) 1.10
B) 1.20
C) 1.30
D) 1.40

Accepted Answer

The answer of In the Ho & Lee (1986) model,...

Question 11

Assume annual compounding. The one-year and two-year zero-coupon rates in the BDT model are 6% and 7%. The volatility is given to be $\sigma = 0.30$ . What is the price of a one-year maturity cap on the one-year interest rate at a strike rate of 8% and a notional of $100?

A) 1.000
B) 1.025
C) 1.050
D) 1.075

1.025

Accepted Answer

The answer of Assume annual compounding. The one-year and two-year...

Question 12

Assume annual compounding. The one-year and two-year zero-coupon rates in the BDT model are 6% and 7%. The volatility is given to be $\sigma = 0.30$ . What is the price of a one-year maturity cap on the one-year interest rate at a strike rate of 8% and a notional of $100?

A) 1.000
B) 1.025
C) 1.050
D) 1.075

1.025

Accepted Answer

The answer of Assume annual compounding. The one-year and two-year...

Question 13

In the Cox-Ingersoll-Ross (1985) model, interest rates are specified by the following stochastic process: $d r _ { t } = k \left( \theta - r _ { t } \right) d t + \sigma _ { } \sqrt { r _ { t } } d W _ { t }$ The process for interest rates is mean-reverting if

A)

k > 0

B)

k < 0

C)

\theta > 0

D)

\theta < r _ { t }

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Accepted Answer

The answer of In the Cox-Ingersoll-Ross (1985) model, interest rates...

Question 14

Vasicek (1977) posits a general mean-reverting form for the short-rate: $d r _ { t } = \kappa \left( \theta - r _ { t } \right) d t + \sigma d W _ { t }$ He then derives, in the absence of arbitrage, a restriction on the market price of risk $\lambda$ of any bond, where $( \mu - r ) / \eta = \lambda$ of any bond, with $\mu$ being the instantaneous return on the bond, and $\eta$ being the bond's instantaneous volatility. The derived restriction is that

A)

\lambda

is a constant.
B)

\lambda

may be a function of time

t

, but not of any other time-

t

information or of the maturity

T

of the bond.
C)

\lambda

may be a function of the time-

t

short rate

r _ { t }

, but not of current time

t

or of the bond maturity

T

.
D)

\lambda

may be a function of time

t

and the time-

t

short rate

r _ { t }

, but not of the bond maturity

T

.

Accepted Answer

The answer of Vasicek (1977) posits a general mean-reverting form...

Question 15

Assume annual compounding. The one-year and two-year zero-coupon rates in the BDT model are 6% and 7%. The volatility is given to be $\sigma = 0.30$ . What is the price of a one-year maturity cap on the one-year interest rate at a strike rate of 8% and a notional of $100?

A) 1.000
B) 1.025
C) 1.050
D) 1.075

1.025

Accepted Answer

The answer of Assume annual compounding. The one-year and two-year...

Question 16

Assume annual compounding. The one-year and two-year zero-coupon rates in the BDT model are 6% and 7%. The volatility is given to be $\sigma = 0.30$ . What is the price of a one-year maturity cap on the one-year interest rate at a strike rate of 8% and a notional of $100?

A) 1.000
B) 1.025
C) 1.050
D) 1.075

1.025

Accepted Answer

The answer of Assume annual compounding. The one-year and two-year...

Question 17

In the Vasieck (1977) model, you are given that $d r _ { t } = \kappa \left( \theta - r _ { t } \right) d t + \sigma d W _ { t }$ where $k = 0.5$ , $\theta = 0.06$ , $\sigma = 0.10$ , and the current short rate of interest is $r _ { 0 } = 0.08$ . What is the expected standard deviation of the short rate of interest one year hence?

A) 0.08
B) 0.09
C) 0.10
D) 0.11

Accepted Answer

The answer of In the Vasieck (1977) model, you are...

Question 18

In the Ho & Lee (1986) model, the parameter  $\delta$ plays a crucial role. Which of the following statements best describes this parameter?&#10;A) $\delta > 1$ .&#10;B) As $\delta$ increases the volatility of interest rates increases.&#10;C) As $\delta$ increases the volatility of interest rates decreases.&#10;D) $\delta < 0$ .&#10;

Accepted Answer

The answer of In the Ho & Lee (1986) model,...

Question 19

In the Cox-Ingersoll-Ross (1985) model, interest rates are specified by the following stochastic process: $d r _ { t } = k \left( \theta - r _ { t } \right) d t + \sigma _ { } \sqrt { r _ { t } } d W _ { t }$ The process for interest rates is mean-reverting if

A)

k > 0

B)

k < 0

C)

\theta > 0

D)

\theta < r _ { t }

Accepted Answer

The answer of In the Cox-Ingersoll-Ross (1985) model, interest rates...

Question 20

In the Black-Derman-Toy (BDT) model, short rates are distributed as&#10;(a) Normal&#10;(b) Lognormal&#10;(c) Exponential&#10;(d) None of the above

Accepted Answer

The answer of In the Black-Derman-Toy (BDT) model, short rates...

Question 21

In the Cox-Ingersoll-Ross (CIR 1985) model, you are given that $d r _ { t } = \kappa \left( \theta - r _ { t } \right) d t + \sigma \sqrt { r _ { t } } d W _ { t }$ where $x = 0.5$ , $\theta = 0.06$ , $\sigma = 0.10$ , and the current short rate of interest is $r _ { 0 } = 0.08$ . What is the expected short rate of interest one year hence?

A) 6.6%
B) 7.2%
C) 7.6%
D) 8.2%

Accepted Answer

The answer of In the Cox-Ingersoll-Ross (CIR 1985) model, you...

Question 22

An exponential-affine short rate bond model is one &#10;A) That most bond traders have an affinity for.&#10;B) Where the bond prices are linear in the short-rate.&#10;C) Where the logarithm of bond prices is linear in the short rate.&#10;D) Where the bond price is based on discrete compounding.&#10;

Accepted Answer

The answer of An exponential-affine short rate bond model is...

Question 23

In the CIR (1985) model, which of the following statements is true? The price of the bond increases when &#10;A) The short rate $r _ { t }$ increases.&#10;B) The rate of mean reversion $ { K }$ rises.&#10;C) The long-run mean rate $\theta$ increases.&#10;D) The volatility $\sigma$ increases.&#10;

Accepted Answer

The answer of In the CIR (1985) model, which of...

Question 24

An affine factor model is one in which multiple factors  $X$ may be present. Which of the following is not true of an affine factor model.&#10;A) The drift $\mu ( X )$ will be linear in $X$ .&#10;B) The volatility $\sigma ( X )$ will be linear in $X$ .&#10;C) The yield $R ( X )$ will be linear in $X$ .&#10;D) The logarithm of the price scaled by maturity is the yield.&#10;

Accepted Answer

The answer of An affine factor model is one in...

Deck 27: Factor Models of the Term Structure