20.07 Further exponential equations (Extended)

Rearrange the equation into the form x = \dfrac{\log A}{\log B}.

Evaluate x to three decimal places.

13^{x} = 5

5^{x} = \dfrac{1}{11}

3^{x} = 2

4^{x} = 6.4

\left(0.4\right)^{x} = 5

5^{x} + 4 = 3129

2^{ - x } = 6

27^{x} + 4 = 19\,211

Make x the subject of the equation.

Evaluate x to three decimal places.

Which step was incorrect? Explain your answer.

Rearrange the original equation into the form a = \dfrac{\log A}{\log B}.

Evaluate a to three decimal places.

\begin{aligned} 9 ^ {a} &= 40 \\ \log9^{a} &= \log40 & (1)\\ a + \log 9 &= \log40 & (2)\\ a &= \log40 - \log9 & (3)\\ &\approx 0.648 & (4) \end{aligned}

\begin{aligned} 2 ^ {a} &= 89 \\ \log2^{a} &= \log89 & (1) \\ a \log 2 &= \log89 & (2)\\ a &= \log_{89} 2 & (3)\\ &\approx 0.154 & (4) \end{aligned}

1024

3000

State the initial population.

By what percentage is the poulation increasing by each month?

Find the time when the population reaches 1500 to two decimal places.

State the initial population.

By what percentage is the poulation decreasing by each year?

Find the time when the population reaches 200 to two decimal places.