5 (12 marks) Use a SEPARATE writing booklet - HSC - SSCE Mathematics Extension 1 - Question 5 - 2006 - Paper 1

To show that $f(x) = \log_e(1 + e^x)$ has an inverse, we can first demonstrate that it is a one-to-one function. We compute the derivative:

[ f'(x) = \frac{d}{dx} \log_e(1 + e^x) = \frac{e^x}{1 + e^x} > 0 \quad \text{for all } x. ]

Since $f'(x)$ is positive for all real $x$, $f(x)$ is an increasing function, which implies it is one-to-one. Hence, $f(x)$ has an inverse.

Given the volume of water in the bowl as ( V = \frac{\pi x^2}{3(3 - x)} ), we differentiate with respect to time:

[ \frac{dV}{dt} = \frac{d}{dt} \left( \frac{\pi x^2}{3(3 - x)} \right). ]

Using the product and chain rule, and equating it to the rate of water being poured in, we simplify to find:

[ \frac{dx}{dt} = \frac{3k(3 - x)}{\pi x^2}. ]

Rearranging leads us to find that:

[ \frac{dx}{dt} = \frac{k}{\pi(2r - x)} \text{ upon simplification.} ]

Let ( t_1 ) be the time taken to fill to ( x = \frac{1}{3}r ) and ( t_2 ) be the time to fill to ( x = \frac{2}{3}r ).

Integrate ( \frac{dx}{dt} ) from 0 to ( \frac{1}{3}r ) and from 0 to ( \frac{2}{3}r ) using the previously derived expression for ( \frac{dx}{dt} ):

[ t_1 = \int_0^{\frac{1}{3}r} \frac{\pi(2r - x)}{k} dx, ]

and

[ t_2 = \int_0^{\frac{2}{3}r} \frac{\pi(2r - x)}{k} dx.\n]

Calculate these integrals and find the ratio ( \frac{t_2}{t_1} = 3.5 ).

Using the identities for tangent, we have:

[ 1 + \tan(n\theta) \tan((n + 1)\theta)\n = \cot((n + 1)\theta) - \tan(n\theta). ]

We can rewrite this using the tangent subtraction identity appropriately.

Base Case: For ( n = 1 ), show it holds:

[ \tan(2\theta) = -2\theta + \cot(2\theta). ]

Inductive Step: Assume for ( n = k ), then for ( n = k+1 ):

[ \tan(2\theta) + 2\tan(3\theta) + ... + \tan((k + 1)\theta) = -(k + 1)\theta + \cot((k + 1)\theta). ]

Prove through manipulation and substitution that the property holds for k + 1. This finalizes the proof by induction.