In Australia, domestic university students are allowed to buy concession tickets for the bus, train and ferry which sell at a discount of **50**% to full-price tickets.

The Australian Government do not allow international university students to buy concession tickets, they have to pay the full price.

Some international students see this as unfair and they are willing to pay for fake university identification cards which have the concession sticker.

What is the most that an international student would be willing to pay for a fake identification card?

Assume that international students:

- consider buying their fake card on the morning of the first day of university from their neighbour, just before they leave to take the train into university.
- buy their weekly train tickets on the morning of the first day of each week.
- ride the train to university and back home again every day seven days per week until summer holidays
**40**weeks from now. The concession card only lasts for those 40 weeks. Assume that there are**52**weeks in the year for the purpose of interest rate conversion. - a single full-priced one-way train ride costs $
**5**. - have a discount rate of
**11**% pa, given as an effective annual rate.

Approach this question from a purely financial view point, ignoring the illegality, embarrassment and the morality of committing fraud.

When using the dividend discount model to price a stock:

### p_{0} = \frac{d_1}{r - g} ###

The growth rate of dividends (g):

A stock is expected to pay the following dividends:

Cash Flows of a Stock | ||||||

Time (yrs) | 0 | 1 | 2 | 3 | 4 | ... |

Dividend ($) | 8 | 8 | 8 | 20 | 8 | ... |

After year 4, the dividend will grow in perpetuity at 4% pa. The required return on the stock is 10% pa. Both the growth rate and required return are given as effective annual rates.

What is the current price of the stock?

Find the sample standard deviation of returns using the data in the table:

Stock Returns | |

Year | Return pa |

2008 | 0.3 |

2009 | 0.02 |

2010 | -0.2 |

2011 | 0.4 |

The returns above and standard deviations below are given in decimal form.

Which of the following statements about option contracts is **NOT** correct? For every:

**Question 606** foreign exchange rate, American and European terms

Which of the following FX quotes (current in October 2015) is given in American terms?

A company can invest funds in a five year project at LIBOR plus **50** basis points pa. The five-year swap rate is **4**% pa. What fixed rate of interest can the company earn over the next five years by using the swap?

**Question 722** mean and median returns, return distribution, arithmetic and geometric averages, continuously compounding rate

Here is a table of stock prices and returns. Which of the statements below the table is **NOT** correct?

Price and Return Population Statistics |
||||

Time | Prices | LGDR | GDR | NDR |

0 | 100 | |||

1 | 50 | -0.6931 | 0.5 | -0.5 |

2 | 100 | 0.6931 | 2 | 1 |

Arithmetic average | 0 | 1.25 | 0.25 | |

Arithmetic standard deviation | -0.6931 | 0.75 | 0.75 | |

A share’s current price is $**60**. It’s expected to pay a dividend of $**1.50** in one year. The growth rate of the dividend is **0.5**% pa and the stock’s required total return is **3**% pa. The stock’s price can be modeled using the dividend discount model (DDM):

##P_0=\dfrac{C_1}{r-g}##

Which of the following methods is **NOT** equal to the stock’s expected price in one year and six months (t=**1.5** years)? Note that the symbolic formulas shown in each line below do equal the formulas with numbers. The formula is just repeated with symbols and then numbers in case it helps you to identify the incorrect statement more quickly.

**Question 908** effective rate, return types, gross discrete return, return distribution, price gains and returns over time

For an asset's price to double from say $1 to $2 in one year, what must its gross discrete return (GDR) be? If the price now is ##P_0## and the price in one year is ##P_1## then the gross discrete return over the next year is:

###\text{GDR}_\text{annual} = \dfrac{P_1}{P_0}###