#1.04a
Understand and be able to use the binomial expansion of \((a + bx)^n\) for positive integer \(n\) and the notations \(n!\) and \(^nC_r\), \(_nC_r\) or \(\dbinom{n}{r}\), with \(^nC_0 =\) \(^nC_n = 1\).
e.g. Find the coefficient of the \(x^3\) term in the expansion of \((2 - 3x)^7\).
Learners should be able to calculate binomial coefficients. They should also know the relationship of the binomial coefficients to Pascal’s triangle and their use in a binomial expansion.
They should also know that \(0! = 1\).
#1.04c
Be able to extend the binomial expansion of \((a + bx)^n\) to any rational \(n\), including its use for approximation.
Learners may be asked to find a particular term, but the general term will not be required.
Learners should be able to write \((a + bx)^n\) in the form \(a^n\Bigg(1+\dfrac{bx}{a}\Bigg)^n\) prior to expansion.
#1.04d
Know that the expansion is valid for \(\Big|\dfrac{bx}{a}\Big| < 1\).
[The proof is not required.]
e.g. Find the coefficient of the \(x^3\) term in the expansion of \((2-3x)^{\frac{1}{3}}\) and state the range of values for which the expansion is valid.
#1.04e
Be able to work with sequences including those given by a formula for the nth term and those generated by a simple relation of the form \(x_{n+1} = f(x_n)\).
Learners may be asked to generate terms, find \(n\)th terms and comment on the mathematical behaviour of the sequence.
#1.04f
Understand the meaning of and work with increasing sequences, decreasing sequences and periodic sequences.
Learners should know the difference between and be able to recognise:
1. a sequence and a series,
2. finite and infinite sequences.
#1.04h
Understand and be able to work with arithmetic sequences and series, including the formulae for the \(n\)th term and the sum to n terms.
The term arithmetic progression (AP) may also be used. The first term will usually be denoted by \(a\), the last term by \(l\) and the common difference by \(d\).
The sum to \(n\) terms will usually be denoted by \(S_n\).
#1.04i
Understand and be able to work with geometric sequences and series including the formulae for the \(n\)th term and the sum of a finite geometric series.
Learners should know the difference between convergent and divergent geometric sequences and series.
#1.04j
Understand and be able to work with the sum to infinity of a convergent geometric series, including the use of \(|r| < 1\) and the use of modulus notation in the condition for convergence.
The term geometric progression (GP) may also be used. The first term will usually be denoted by \(a\) and the common ratio by \(r\).
The sum to \(n\) terms will usually be denoted by \(S_n\) and the sum to infinity by \(S_∞\).
#1.04k
Be able to use sequences and series in modelling.
e.g. Contexts involving compound and simple interest on bank deposits, loans, mortgages, etc. and other contexts in which growth or decay can be modelled by an arithmetic or geometric sequence.
Includes solving inequalities involving exponentials and logarithms.
Arithmetic sequences and series Geometric sequences and series