Fight Finance

(a) The long trader paid the option premium at the start.

(b) The option is 'out of the money' at the start.

(c) The long trader wishes for the underlying CBA stock price to fall.

(d) The option can only be exercised at maturity.

(e) If the stock price falls to $60 at maturity, then the long trader can buy the underlying stock for $60, exercise his option to sell the underlying stock to his counterparty for $75, making a payoff at maturity of $15 and a profit of $13.

Two call options are exactly the same, but one has a low and the other has a high exercise price. Which option would you expect to have the higher price, the option with the or exercise price, or should they have the price?

(a) 970

(b) 1,530

(c) 1,552

(d) 2,487

(e) 2,522

(a) Under priced and should be bought.

(b) Under priced and should be sold.

(c) Over priced and should be bought.

(d) Over priced and should be sold.

(e) Fairly priced and an arbitrageur would be indifferent to buying or selling them.

(a) immediately after the option purchase date.

(b) After the option matures but only if it is exercised.

(c) After the option matures but only if it lapses and is not exercised.

(d) After the option matures, regardless of whether it is exercised or not.

(e) The option price is never a sunk cost.

(a) Price must be greater than zero (p>0).

(b) Price can be greater than its exercise price (p>K).

(c) Price can be greater than the underlying asset's price (p>S).

(d) Exercise price can be greater than the underlying asset's price (K>S).

(e) Profit must be less than the payoff at maturity from the long trader’s perspective.

(a) Options are always worth more than or equal to equivalent European-style options.

(b) Call options on dividend-paying stocks should sometimes be exercised just before the dividend.

(c) Put options on dividend-paying stocks should sometimes be exercised just after the dividend.

(d) Call options should be exercised now if the intrinsic option value ##(S-K)## is greater than the expected present value of the option’s future payoffs.

(e) Put options should be exercised now if the intrinsic option value ##(K-S)## is less than the expected present value of the option’s future payoffs.

(a)##Red \sim \mathcal{N}(\mu, \sigma^2)##,   ##Green \sim \mathcal{N}(\mu, \sigma^2)##   and   ##Blue \sim \mathcal{N}(\mu, \sigma^2)##

(b) ##Red \sim \mathcal{N}(\mu, \sigma^2)##,   ##Green \sim \mathcal{N}(\mu, \sigma^2)##   and   ##Blue \sim \mathbf{ln} \mathcal{N}(\mu, \sigma^2)##

(c) ##Red \sim \mathcal{N}(\mu, \sigma^2)##,   ##Green \sim \mathbf{ln} \mathcal{N}(\mu, \sigma^2)##   and   ##Blue \sim \mathbf{ln} \mathcal{N}(\mu, \sigma^2)##

(d) ##Red \sim \mathbf{ln} \mathcal{N}(\mu, \sigma^2)##,   ##Green \sim \mathcal{N}(\mu, \sigma^2)##   and   ##Blue \sim \mathbf{ln} \mathcal{N}(\mu, \sigma^2)##

(e) ##Red \sim \mathbf{ln} \mathcal{N}(\mu, \sigma^2)##,   ##Green \sim \mathbf{ln} \mathcal{N}(\mu, \sigma^2)##   and   ##Blue \sim \mathbf{ln} \mathcal{N}(\mu, \sigma^2)##

(a) Green is a stock's continuously compounded rate of return, also called the log gross discrete return. ##r_\text{cc} = \ln(P_1/P_0)##

(b) Blue is a stock's future price, ##P_1##

(c) Blue is a stock's gross discrete return. ##\text{GDR} = P_1/P_0##

(d) Blue is a stock's effective rate of return. ##r_\text{eff} = (P_1-P_0)/P_0##

(e) Red is a stock's net discrete return. ##\text{NDR} = \text{GDR}-1##

(a) The geometric average of the gross discrete returns (GAGDR) equals 1.04075 which is 104.075%.

(b) ##\exp \left( \text{GAGDR} \right) = \text{AALGDR}##. The natural exponent of the GAGDR equals the arithmetic average of the logarithms of the gross discrete returns (AALGDR).

(c) ##\text{GAGDR}^T = \left( P_T/P_0 \right)##. The GAGDR raised to the power of the number of time period that it's measured over equals the ratio of the first and last prices.

(d) ##\text{GAGDR} = \exp \left( \text{AALGDR} \right)##. This is always true, regardless of the distribution of the prices or returns. The logarithm of the geometric average of the gross discrete returns (LGAGDR) is always equal to the arithmetic average of the logarithm of the gross discrete returns (AALGDR).

(e) ##\text{AAGDR} \approx \exp \left( \text{AALGDR} + \text{SDLGDR}^2/2 \right)##. This is only approximately true and depends on the distribution of the prices and returns. It's asymptotically true as the time period that the returns are measured over reaches infinity.

(a) If the underlying stock price suddenly rose by $0.01, the put option price would be expected to fall by less than $0.00552034777953178.

(b) If the underlying stock price suddenly fell by $0.01, the put option price would be expected to rise by more than $0.00552034777953178.

(c) If the underlying stock price suddenly rose by $0.01, the call option price would be expected to rise by more than $0.00888138404936379.

(d) To Delta hedge the 1000 long put options, long 552.0348 stocks.

(e) To Delta and Gamma hedge the 1000 long put options, long 2078.4226 call options and short 2397.9617 stocks.

(a) A one cent ($0.01) increase in the underlying stock price is expected to lead to a 0.747891 cent ($0.00747891) increase in the call option price.

(b) The (risk-neutral) probability of the call option maturing ‘in-the-money’ is 0.643514.

(c) A one cent ($0.01) increase in the underlying stock price is expected to lead to a 0.00053199 unit increase in the call option Delta.

(d) The underlying stocks’ standard deviation of returns per day is 0.015702718 assuming 365 days per year and zero auto-correlation.

(e) After one day, all other things remaining equal, the option price is expected to fall by $1.566433 assuming 365 days per year.

(a) Continuously compounded mean and median returns are both 37.96% over the 4 year period.

(b) 95% confidence interval of the continuously compounded returns is between -28.3664% and 104.2864% over the 4 year period.

(c) Mean dollar value is $1.547835m while its median dollar value is $1.4617m in 4 years.

(d) 95% confidence interval of the dollar value is between $0.75302m and $2.17038m in 4 years.

(e) 95% confidence interval of the effective annual return is between -24.698% and 183.7332% over the 4 year period.

(a) As time elapses, call option prices always fall.

(b) As time elapses, put option prices always fall.

(c) The long future always has a zero Gamma.

(d) The more in-the-money the long call option is, the higher (more positive) is its Delta.

(e) The more in-the-money the long put option is, the lower (more negative) is its Delta.

(a) The option’s expected future continuously compounded returns are always more than or equal to the underlying stock’s expected future continuously compounded returns.

(b) The option’s standard deviation of dollar price changes is always less than or equal to the underlying stock’s standard deviation of dollar price changes.

(c) The option’s standard deviation of continuously compounded returns are always less than or equal to the underlying stock’s standard deviation of continuously compounded returns.

(d) As time elapses and the maturity date of an option approaches, its price will fall, all other things remaining equal.

(e) If the underlying stock’s price rises by $0.01, the call option’s price will rise by less than $0.01 and the put option’s price will fall by less than $0.01.

(a) Best day of the 5% worst days’ results.

(b) Worst day of the 5% worst days’ results.

(c) Best day of the 5% best days’ results.

(d) Worst day of the 5% best days’ results.

(e) Best day of the 95% worst days’ results.

(a) Future portfolio values have a log-normal distribution. The mean (expected or arithmetic average) portfolio value in one year is $115,603,957.

(b) The median (50th percentile) portfolio value in one year is $115,603,957.

(c) The 90% confidence interval of continuously compounded portfolio returns over the next year ##(r_{0 \rightarrow 1})## is ##-39.3456088\% < r_{0 \rightarrow 1} < 59.3456088\%##.

(d) The 90% confidence interval of portfolio values in one year ##(V_1)## is ##\$67,472,095 < V_1 < \$181,023,395##.

(e) The annual 95% relative VaR is $48,131,863 and the absolute VaR is $32,527,905.

(a) 23.17 years.

(b) 41.31 years.

(c) 134.19 years.

(d) 536.75 years.

(e) Never.

(a) 23.17 years.

(b) 41.31 years.

(c) 134.19 years.

(d) 536.75 years.

(e) Never.

(a) 23.17 years.

(b) 41.31 years.

(c) 134.19 years.

(d) 536.75 years.

(e) Never.

(a) 1.336851119

(b) 1.782468159

(c) 1.836881513

(d) 1.969931972

(e) 2.030068028

(a) 0.401817831

(b) 0.430922619

(c) 0.444077381

(d) 0.490781407

(e) 0.861038209

(a) Daniel Bernoulli.

(b) John Larry Kelly Jr.

(c) Henry Allen Latane.

(d) Ole Peters.

(e) Paul Anthony Samuelson.

(a) Daniel Bernoulli.

(b) John Larry Kelly Jr.

(c) Henry Allen Latane.

(d) Ole Peters.

(e) Paul Anthony Samuelson.

(a) Forward contracts are traded over-the-counter (OTC).

(b) Futures contracts are exchange traded.

(c) Futures contracts are highly standardised in their contract sizes and expiry dates.

(d) Forward contracts expose the winner to credit risk at maturity.

(e) Forward contracts are novated.

(a) Buy debt.

(b) Own debt.

(c) Are owed money.

(d) Write debt.

(e) Have debt assets.

(a) A 3 for 2 stock split means that for every 2 existing shares, all shareholders will receive 1 extra share.

(b) A 3 for 10 bonus issue means that for every 10 existing shares, all shareholders will receive 3 extra shares.

(c) A 20% stock dividend means that for every 10 existing shares, all shareholders will receive 2 extra shares.

(d) A 1 for 10 reverse stock split means that for every 10 existing shares, all shareholders will lose 9 shares, so they will only be left with 1 share.

(e) A 3 for 10 rights issue at a subscription price of $8 means that for every 10 existing shares, all shareholders can sell 3 of their shares back to the company at a price of $8 each, so shareholders receive money.

(a) DRP's are voluntary, shareholders only participate if they choose.

(b) DRP's increase the number of shares.

(c) The number of shares issued to a shareholder participating in a DRP is usually calculated as their total dividends owed, divided by the allocation share price which is usually close to the current market share price.

(d) DRP's do not incur brokerage costs for the shareholder. This is unlike the case where the shareholder uses the cash dividend to buy more shares herself.

(e) If all shareholders participated in a company's DRP, the company would not pay any dividends and the firm's share price would not fall due to the cash dividend or the DRP.

(a) 0.143476 is the implicit rate. The buying firm should borrow from the bank and pay at day 5.

(b) 0.130771 is the implicit rate. The buying firm should NOT borrow from the bank and just pay at day 60.

(c) 0.125473 is the implicit rate. The buying firm should borrow from the bank and pay at day 5.

(d) 0.120131 is the implicit rate. The buying firm should NOT borrow from the bank and just pay at day 60.

(e) 0.020408 is the implicit rate. The buying firm should borrow from the bank and pay at day 5.

(a) The 3-month government bill yield is likely to be given as a simple interest rate.

(b) The 10-year government bond yield is likely to be given as an annualised percentage rate compounding every six months since Japanese government bonds pay semi-annual coupons.

(c) As 10-year government bond yields fell over the last few years, bond investors would have made capital gains assuming that the bonds are fixed-coupon.

(d) The Japanese yield curve is ‘inverse’ at the latest time in mid-2017.

(e) The Japanese central bank has been maintaining expansionary monetary policy over the last few years.

(a) 4.5% for Common Equity Tier 1 (CET1).

(b) 2% for Other Tier 1.

(c) 2% for Tier 2.

(d) 8% for overall regulatory capital.

(a) The efficient markets hypothesis.

(b) Time value of money.

(c) Separation of the investment and financing decisions.

(d) Diversification.

(e) Sunk costs.

(a) $20,000

(b) $28,000

(c) $35,000

(d) $40,000

(e) $50,000

(a) The DuPont formula gives the book Return on Equity (ROE).

(b) The net profit to sales ratio is called the ‘gross profit margin’.

(c) The sales to total assets ratio is called the ‘total asset turnover’ ratio.

(d) The total assets to owners' equity ratio is called the ‘equity multiplier’.

(e) The equity multiplier and ROE will rise if the firm uses more leverage by replacing equity with debt.