Cambridge Additional Mathematics

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130 Logarithms (Chapter 5)

Opening problem


In a plentiful springtime, a population of 1000 mice will double
every week.
The population aftertweeks is given by the exponential
function P(t) = 1000£ 2 t mice.
Things to think about:
a What does the graph of the population over time look
like?
b How long will it take for the population to reach20 000
mice?
c Can we write a function fortin terms ofP, which
determines the time at which the populationPis reached?
d What does the graph of this function look like?

Consider the exponential function f:x 7! 10 x
or f(x)=10x.
The graph of y=f(x) is shown alongside, along with
its inverse function f¡^1.

Sincefis defined by y=10x,
f¡^1 is defined by x=10y.
finterchangingxandyg

yis the exponent to which the base 10 is raised in order to
getx.

We write this as y= log 10 x or lgx and say thatyis thelogarithm in base 10 ,ofx.
Logarithms are thus defined to be the inverse of exponential functions:

If f(x)=10x then f¡^1 (x) = log 10 x or lgx.

WORKING WITH LOGARITHMS


For example: 10 000 = 10^4
1000 = 10^3
100 = 10^2
10 = 10^1
1=10^0
0 :1=10¡^1
0 :01 = 10¡^2
0 :001 = 10¡^3

Many positive numbers can be
easily written in the form 10 x.

A LOGARITHMS IN BASE 10


y

1 x

1

f-1

y=x

y = f(x)

O

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Additional Mathematics
Y:\HAESE\CAM4037\CamAdd_05\130CamAdd_05.cdr Friday, 20 December 2013 1:04:24 PM BRIAN

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