Trigonometry

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21

TRIGONOMETRIC IDENTITIES

Reciprocal identities

Tangent and cotangent identities

Pythagorean identities

Sum and difference formulas

Double-angle formulas

Half-angle formulas

Products as sums

Sums as products


AN IDENTITY IS AN EQUALITY that is true for any value of the variable.(An equation is an equality that is true only for certain values of the variable.)

In algebra, for example, we have this identity:

(a + b)² = a² + 2ab + b²

This means that, in calculation, we may replace either member of the identity with the other.

We use an identity to give an expression a more convenient form.  In calculus and all its applications, the trigonometric identities are of central importance.

On this page, we will present the main identities.  The student will have no better way of practicing algebra than by proving them.  Links to the proofs appear below.

Reciprocal identities

sin θ  =      1  
csc θ		         csc θ  =      1  
sin θ
 
cos θ  =      1  
sec θ		         sec θ  =      1  
cos θ
 
tan θ  =      1  
cot θ		         cot θ  =      1  
tan θ

Proof

Again, the point about an identity is that, in calculation, either member of the identity may be substituted for the other.  Thus if we see

  "sin θ", then we may, if we wish, replace it with "    1  
csc θ		 ";  and,
  symmetrically, if we see  "    1  
csc θ		 ", then we may replace it with "sin θ".

Tangent and cotangent identities

tan θ  =   sin θ
cos θ		          cot θ  =   cos θ
sin θ

Proof


Pythagorean identities

a) sin²θ + cos²θ   =   1
 
b) 1 + tan²θ   =   sec²θ
 
c) 1 + cot²θ   =   csc ²θ

a')     sin²θ  =  1 − cos²θ.       cos²θ  =  1 − sin²θ.

These are called Pythagorean identities, because, as we will see in their proof, they are the trigonometric version of the Pythagorean theorem.

The two identities labeled a') -- "a-prime" -- are simply different versions of a).  The first shows how sin θ may be expressed in terms of cos θ; the second shows how cos θ may be expressed in terms of sin θ.

Note:  sin²θ -- "sine squared theta" -- means (sin θ)².


Sum and difference formulas

sin ( + β)   =   sin cos β + cos sin β
 
sin (β)  =   sin cos β − cos sin β
 
cos ( + β)  =   cos cos β − sin sin β
 
cos (β)  =   cos cos β + sin sin β

Note:  In the sine formulas, + or − on the left is also + or − on the right.  But in the cosine formulas, + on the left becomes − on the right; and vice-versa.

Since these identities are proved directly from geometry, the student is not normally required to master the proof.  However, all the identities that follow are based on these sum and difference formulas.  The student should definitely know them.

To see the proof of the sum formulas, click here.

Double-angle formulas

Proof

There are three versions of cos 2.  The first is in terms of both cos  and sin .  The second is in terms only of cos .  The third is in terms only of sin

The following half-angle formulas are inversions of these double-angle formulas, which must be proved first.

Half-angle formulas

Proof

Note:  The cosine has the + sign; the sine, the − sign.

Products as sums

a)  sin cos β  =   ½[sin ( + β) + sin (β)]
 
b)  cos sin β  =   ½[sin ( + β) − sin (β)]
 
c)  cos cos β  =   ½[cos ( + β) + cos (β)]
 
d)  sin sin β  =   −½[cos ( + β) − cos (β)]

Proof


Sums as products

e)  sin A + sin B   =   2 sin ½ (A + B) cos ½ (AB)
 
f)  sin A − sin B   =   2 sin ½ (AB) cos ½ (A + B)
 
g)  cos A + cos B   =   2 cos ½ (A + B) cos ½ (AB)
 
h)  cos A − cos B   =   −2 sin ½ (A + B) sin ½ (AB)

In the proofs, the student will see that the identities e) through h) are inversions of a) through d) respectively, which are proved first.  In calculus, the identity f) is used to prove one of the main theorems, namely, the derivative of sin x.

The student should not attempt to memorize these identities.  Practicing their proofs -- and seeing that they come from the sum and difference formulas -- is enough.


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