A market trader notices that daily sales are dependent on two variables: number of hours, t, after the stall opens total sales, x, in pounds since the stall opened - AQA - A-Level Maths Mechanics - Question 9 - 2018 - Paper 2

Starting from the equation established in part (a):

[ x \frac{dx}{dt} = \frac{4032}{8 - t} ]

We integrate both sides. Integrating the left-hand side gives:

[ \int x , dx = \frac{x^2}{2} + C ]

On the right-hand side, we integrate:

[ \int \frac{4032}{8 - t} , dt = -4032 \ln |8 - t| + C_1 ]

Setting the constants equal (as they can be combined), we solve:

Combining both results gives:

[ \frac{x^2}{2} = -4032 \ln |8 - t| + C ]

Using the initial condition with ( t = 2 ) and ( x = 336 ):

Solving for ( C ), we plug in the known values:

[ \frac{336^2}{2} = -4032 \ln |8 - 2| + C ]

Calculate these and simplify:

The answer leads to:

[ x^2 = 4032(16 - t) ]

Here we need to find when the rate of sales falls below £24 per hour.

Using part (a) where:

[ \frac{dx}{dt} = \frac{4032(8 - t)}{x} ]

We replace ( \frac{dx}{dt} = 24 ):

[ 24 = \frac{4032(8 - t)}{x} ]

Thus,

[ x = \frac{4032(8 - t)}{24} = 168(8 - t) ]

Considering that ( x = 4032(16 - t) ) :

Substituting back gives:

[ 168(8 - t)^2 \leq 4032(16 - t) ]

After simplifying and solving for ( t ) gives:

Evaluating reaches:

[ t = 5.571 \text{ hours after stall opens, which is } 14:40. ]

Here, we found that the earliest time the stall closes is 14:40.

At 09:30, the stall has just opened, which implies that:

• The value of ( t = 0 ) and the equation becomes invalid as the denominator ( 8 - t ) leads to undefined behavior at the very instant of opening.
• Additionally, if ( t = 0 ), since the model relies on the proportion of (time elapsed to total sales), the initial rate of sales can't be determined. Thus the model is not applicable at this specific time.