Return to IB Mathematics (SL)

The aim of this section is to introduce candidates to some basic algebraic concepts and applications. Number systems are now in the presumed knowledge section.

A series is a sum of numbers. For example,

    1 + 1/2 + 1/4 + 1/8 + 1/16 + ...

A sequence is a list of numbers, usually separated by a comma. The order in which the numbers are listed is important, so for instance

    1, 2, 3, 4, 5, ...

A more formal definition of a finite sequence with terms in a set S is a function from {1,2,...,n} to S for some n ≥ 0.

An infinite sequence in S is a function from {1,2,...} (the set of natural numbers) to infinity.

Arithmetic series or sequences simply involve addition.

    1, 2, 3, 4, 5, ...

Is an example of addition, where 1 is added each time to the prior term.

The formula for finding the nth term of an arithmetic sequence is:

${\displaystyle u_n=u_1+(n-1)d.}$

Where ${\displaystyle u_n}$ is the nth term, ${\displaystyle u_1}$ is the first term, d is the difference, and n is the number of terms

An infinite arithmetic series is an infinite series whose terms are in an arithmetic progression. Examples are 1 + 1 + 1 + 1 + · · · and 1 + 2 + 3 + 4 + · · ·.

The sum (Sn) of a finite sequence is:

${\displaystyle S_n=\frac{n}{2}\cdot (2u_1+(n-1)d)=\frac{n}{2}\cdot (u_1+u_n)}$.

The nth term of a geometric sequence:

${\displaystyle \begin{array}{cc}{u}_n=u_1\cdot r^{n-1}& .\end{array}}$

${\displaystyle S_n=\frac{u_1(r^n-1)}{r-1}=\frac{u_1(1-r^n)}{1-r}}$.

The sum of all terms (an infinite geometric sequence): If -1 < r < 1, then

${\displaystyle S=\frac{u_1}{1-r}}$

${\displaystyle a^x=b}$ is the same as ${\displaystyle lo{g}_a\cdot b}$

${\displaystyle \begin{array}{c}{a}^x=e^{x\cdot \ln a}\end{array}}$

The algebra section requires an understanding of exponents and manipulating numbers of exponents. An example of an exponential function is ${\displaystyle a^c}$ where a is being raised to the ${\displaystyle c^{th}}$ power. An exponent is evaluated by multiplying the lower number by itself the amount of times as the upper number. For example, ${\displaystyle 2^3=2\times 2\times 2=8}$. If the exponent is fractional, this implies a root. For example, ${\displaystyle 4^{\frac{1}{2}}=\sqrt{4}=2}$. Following are laws of exponents that should be memorized:

• ${\displaystyle a^m{a}^n=a^{m+n}}$
• ${\displaystyle (ab{)}^m=a^m{b}^m}$
• ${\displaystyle (a^m{)}^n=a^{mn}}$
• ${\displaystyle a^{m/n}=\sqrt[n]{a^m}}$

${\displaystyle {\log }_b(xy)={\log }_{b}x+{\log }_{b}y}$

${\displaystyle {\log }_b(\frac{x}{y})={\log }_{b}x-{\log }_{b}y}$

${\displaystyle {\log }_b{x}^y=y{\log }_{b}x}$

Change of Base formula:

${\displaystyle {\log }_b(a)=\frac{{\log }_c(a)}{{\log }_c(b)}.}$

Moreover, this result implies that all logarithm functions (whatever the base) are similar to each other. So to calculate the log with base 2 of the number 16 with a calculator:

${\displaystyle {\log }_2(16)=\frac{\log (16)}{\log (2)}.}$

${\displaystyle (x+y{)}^n{=}_n{C}_0{x}^n{y}^0{+}_n{C}_1{x}^{n-1}{y}^1{+}_n{C}_2{x}^{n-2}{y}^2+...{+}_n{C}_n{x}^0{y}^n}$