Compound Angle Formulae (DP IB Maths: AA HL)

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Compound Angle Formulae

What are the compound angle formulae?

  • There are six compound angle formulae (also known as addition formulae), two each for sin, cos and tan:
  • For sin the +/- sign on the left-hand side matches the one on the right-hand side
    • sin(A+B)≡sinAcosB + cosAsinB
    • sin(A-B)≡sinAcosB - cosAsinB
  • For cos the +/- sign on the left-hand side is opposite to the one on the right-hand side
    • cos(A+B)≡cosAcosB - sinAsinB
    • cos(A-B)≡cosAcosB + sinAsinB
  • For tan the +/- sign on the left-hand side matches the one in the numerator on the right-hand side, and is opposite to the one in the denominator
    • tan invisible function application open parentheses A plus B close parentheses blank identical to fraction numerator tan invisible function application A plus tan invisible function application B over denominator 1 minus tan invisible function application A tan invisible function application B end fraction
    • tan invisible function application open parentheses A minus B close parentheses blank identical to fraction numerator tan invisible function application A minus tan invisible function application B over denominator 1 plus tan invisible function application A tan invisible function application B end fraction

  • The compound angle formulae can all the found in the formula booklet, you do not need to remember them

 

When are the compound angle formulae used?

  • The compound angle formulae are particularly useful when finding the values of trigonometric ratios without the use of a calculator
    • For example to find the value of sin15° rewrite it as sin (45 – 30)° and then
      • apply the compound formula for sin(A – B)
      • use your knowledge of exact values to calculate the answer
  • The compound angle formulae are also used…
    • … to derive further multiple angle trig identities such as the double angle formulae
    • … in trigonometric proof
    • … to simplify complicated trigonometric equations before solving

How are the compound angle formulae for cosine proved?

  • The proof for the compound angle identity cos (A – B ) = cos A cos B  + sin A sin B can be seen by considering two coordinates on a unit circle, P (cos A, sin A) and Q (cos B, sin B )
    • The angle between the positive x- axis and the point P is A
    • The angle between the positive x- axis and the point Q is B
    • The angle between P and Q is B – A
  • Using the distance formula (Pythagoras) the distance PQ can be given as
    • |PQ|2 = (cos A – cos B)2 + (sin A – sin B)2
  • Using the cosine rule the distance PQ can be given as
    • |PQ|=  12 + 12 -2(1)(1)cos(B – A) = 2 - 2 cos(B – A)
  • Equating these two formulae, expanding and rearranging gives
    • 2 - 2 cos(B – A) = cos2A + sin2A + cos2B + sin2B –2 cos A cos B  - 2sin A sin B
    • 2 - 2 cos(B – A) = 2 – 2(cos A cos B  + sin A sin B )
  • Therefore cos (B – A) = cos A cos B  + sin A sin B
  • Changing -A for A in this identity and rearranging proves the identity for cos (A + B)
    • cos (B – (-A)) = cos(-A) cos B  + sin(-A) sin B =  cos A cos B – sin A sin B

 3-6-2-ib-aa-hl-caf-diagram-1

How are the compound angle formulae for sine proved?

  • The proof for the compound angle identity sin (A + B ) can be seen by using the above proof for cos (B – A) and
    • Considering cos (π/2 – (A + B)) = cos (π/2)cos(A + B) + sin(π/2)sin(A + B)
    • Therefore cos (π/2 – (A + B)) = sin(A + B)
    • Rewriting cos (π/2 – (A + B)) as cos ((π/2 – A) + B) gives
      • cos (π/2 – (A + B)) = cos (π/2 – A) cos B + sin (π/2 – A) sin B
    • Using cos (π/2 – A) = sin A and sin (π/2 – A) = cos A and equating gives
      • sin (A + B) = sin A cos B + cos A cos B
  • Substituting B for -B proves the result for sin (A – B)

How are the compound angle formulae for tan proved?

  • The proof for the compound angle identities tan (A ± B) can be seen by
    • Rewriting tan (A ± B ) as begin mathsize 16px style fraction numerator sin invisible function application left parenthesis A blank plus-or-minus blank B right parenthesis over denominator cos invisible function application left parenthesis A blank plus-or-minus blank B right parenthesis end fraction end style
    • Substituting the compound angle formulae in
    • Dividing the numerator and denominator by cos A cos B

Examiner Tip

  • All these formulae are in the Topic 3: Geometry and Trigonometry section of the formula booklet – make sure that you use them correctly paying particular attention to any negative/positive signs

Worked example

a)
Show that begin mathsize 16px style tan invisible function application open parentheses x plus pi over 4 close parentheses minus blank tan invisible function application open parentheses x minus pi over 4 close parentheses equals blank fraction numerator 2 left parenthesis tan squared invisible function application x plus 1 right parenthesis over denominator 1 minus tan squared invisible function application x end fraction blank end style

3-6-2-ib-aa-hl-c-a-form-we-solution-a

b)
Hence, solve begin mathsize 16px style space tan invisible function application open parentheses x plus pi over 4 close parentheses minus blank tan invisible function application open parentheses x minus pi over 4 close parentheses equals blank minus 4 end style  for begin mathsize 16px style 0 blank less or equal than x blank less or equal than blank pi over 2 end style

3-6-2-ib-aa-hl-c-a-form-we-solution-b

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Amber

Author: Amber

Expertise: Maths

Amber gained a first class degree in Mathematics & Meteorology from the University of Reading before training to become a teacher. She is passionate about teaching, having spent 8 years teaching GCSE and A Level Mathematics both in the UK and internationally. Amber loves creating bright and informative resources to help students reach their potential.