wherem,nare integers.
So the general solution is
θ=kπ,or
2 π
3
+ 2 mπ,or−
2 π
3
+ 2 nπ k,m,nare integers
NB – it is a common error to forget the sinθ=0 part of the solution.
(ii) cos 3θ=cosθis an example of cosA=cosBfor which we know
3 θ= 2 kπ±θ wherek=an integer
So 4θ= 2 kπ or 2θ= 2 kπ
We therefore obtain
θ=
2 kπ
4
=
kπ
2
or
2 kπ
2
=kπ
and so the general solution is
kπ
2
orkπ, withk=an integer.
6.2.9 TheacosqYbsinqform
➤
173 197➤
The compound angle identities may be used, with a little help from Pythagoras (154
➤
),
to convert an expression of the formacosθ+bsinθ to one of the more manageable
formsrcos(θ±α)orrsin(θ±α). The latter forms, for example, tell us immediately by
inspection the maximum and minimum values of such expressions, and where they occur.
This section uses a lot of what we have done, in particular the ‘minimal set’ of results to
remember – cos^2 θ+sin^2 θ=1, and the expansions of sin(A+B)and cos(A+B).To
illustrate conversion of this form, we consider the example of
acosθ+bsinθ≡rsin(θ+α)
Using the compound angle formula this implies
acosθ+bsinθ≡rcosαsinθ+rsinαcosθ
This has got to be true for all possible values ofθ, and to ensure this we equate the
coefficients of cosθ,sinθon each side to get
rcosα=a
rsinα=b
where, by squaring and adding (185
➤
),r=
√
a^2 +b^2 and
cosα=
a
r
sinα=
b
r
from whichαmay be determined. Care is needed here if eitheraorbis negative – we
have to look carefully at the quadrant thatαlies in.