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The black option valuation model is a modified version of the BSM model used for options on underlying securities that are costless to carry, including options on futures and forward contracts.
Similar to the BSM model, the black model assumes that future prices follow geometric Brownian motion.
The black option model values for European call and put options are expressed as:
European call: \(c_{0}=e^{-rT}[F_{0}(T)N(d_{1})-KN(d_{2})]\)
European put: \(p_{0}=e^{-rT}[KN(-d_{2})-F_{0}(T)N(-d_{1})]\)
Where:
$$d_{1}=\frac{ln\bigg(\frac{F_{0}(T)}{K}\bigg)+\frac{\sigma^{2}}{2}T}{\sigma\sqrt{T}}$$
and
$$d_{2}=d_{1}-\sigma\sqrt{T}$$
\(F_{0}(T)\) = Futures price at time 0 that expires at time T
\(\sigma\)= volatility of returns on the futures price
The NASDAQ index is currently at $12,900. A three-month futures contract on the index trades at $12,800. The exercise price is $12,750, the continuously compounded risk-free rate is 1%, volatility is 15%, and the index has a dividend yield of 2%.
The above information has been used to obtain the following results for both call and put options on the futures contract:
$$\small{\begin{array}{|cc|cc|}\hline\textbf{Calls}&{}&\textbf{Puts}&{}\\\hline\text{N}(\text{d}_{1})&0.5636&\text{N}(-\text{d}_{1})&0.4364\\ \hline\text{N}(\text{d}_{2})&0.5339&\text{N}(-\text{d}_{2})&0.4661\\ \hline\text{C}_{0}&405.84&\text{p}_{0}&355.83\\ \hline\end{array}}$$
The values of a European call option and the put option on the futures contract are closest to:
European call: \(c_{0}=e^{-rT}[F_{0}(T)N(d_{1})-KN(d_{2})]\)
$$c_{0}=e^{-0.01\times0.25}[12,800\times0.5636-12,750\times0.5339]=$405.84$$
European put: \(p_{0}=e^{-rT}[KN(-d_{2})-F_{0}(T)N(-d_{1})]\)
$$p_{0}=e^{-0.01\times0.25}[12,750\times0.4661-12,800\times0.4364]=$355.96$$
Question
The US 30 index is at $30,605. A futures contract on it trades at $30,400. The exercise price is $30,000, the continuously compounded risk-free rate is 1.75%, the time to a futures contract and options expiration is two months, and the volatility is 15%. The US 30 dividend yield is 1.8%. The following results have been determined using the above information:
$$\small{\begin{array}{|cc|cc|}\hline\textbf{Calls}&{}&\textbf{Puts}&{}\\\hline\text{N}(\text{d}_{1})&0.6388&\text{N}(-\text{d}_{1})&0.3612\\ \hline\text{N}(\text{d}_{2})&0.6156&\text{N}(-\text{d}_{2})&0.3844\\ \hline\text{C}_{0}&948.75&\text{p}_{0}&549.91\\ \hline\end{array}}$$
Which of the following options best describes how the Black model is used to value a European call option on the futures contract. The call value is the present value of the difference between:
- The current futures price times 0.6388 and the exercise price times 0.6156.
- The exercise price times 6156 and the current futures price times 0.6388.
- The current spot price times 0.6388, and the exercise price times 0.6156.
Solution
The correct answer is A:
The value of a European call option on a futures contract is obtained using the formula:
$$c_{0}=e^{-rT}[F_{0}(T)N(d_{1})-KN(d_{2})]$$
The above formula implies that the valuation of a European call option based on the Black model involves calculating the present value of the difference between the futures price and the exercise price.
Reading 38: Valuation of Contingent Claims
LOS 38 (i) describe how the Black model is used to value European options on futures;