Chapter 7: Analytic Trigonometry
Chapter 7: Analytic Trigonometry Chapter 7: Analytic Trigonometry
Math 150, Fall 2008, c○Benjamin Aurispa Chapter 7: Analytic Trigonometry Note: There are quite a few identities in Chapter 7. I will let you know which you need to memorize, and which you don’t. Start learning them now. Don’t wait until right before the next test. The good thing about all the identities is that many of them are just found by rearranging other identities. 7.1 Trigonometric Identities Most of the following identities you already know. The new ones are the cofunction identities. Reciprocal Identities Pythagorean Identities Even-Odd Identities csc x = 1 sin x sec x = 1 cos x cot x = 1 tan x sin x tan x = cos x cos x cot x = sin x sin 2 x + cos 2 x = 1 tan 2 x + 1 = sec 2 x 1 + cot 2 x = csc 2 x sin(−x) = − sin x cos(−x) = cos x tan(−x) = − tan x The following cofunction identities can easily be seen by using triangles. Cofunction Identities π sin 2 π csc − u 2 π − u = cos u cos Simplify the following trig expressions. • sin(−u) + cot(−u) cos(−u) • sin x cos x + csc x sec x π = sec u sec − u 2 2 π − u = sin u tan 1 2 π = csc u cot − u 2 − u = cot u = tan u
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Math 150, Fall 2008, c○Benjamin Aurispa<br />
<strong>Chapter</strong> 7: <strong>Analytic</strong> <strong>Trigonometry</strong><br />
Note: There are quite a few identities in <strong>Chapter</strong> 7. I will let you know which you need to memorize, and<br />
which you don’t. Start learning them now. Don’t wait until right before the next test. The good thing<br />
about all the identities is that many of them are just found by rearranging other identities.<br />
7.1 Trigonometric Identities<br />
Most of the following identities you already know. The new ones are the cofunction identities.<br />
Reciprocal Identities<br />
Pythagorean Identities<br />
Even-Odd Identities<br />
csc x = 1<br />
sin x<br />
sec x = 1<br />
cos x<br />
cot x = 1<br />
tan x<br />
sin x<br />
tan x =<br />
cos x<br />
cos x<br />
cot x =<br />
sin x<br />
sin 2 x + cos 2 x = 1 tan 2 x + 1 = sec 2 x 1 + cot 2 x = csc 2 x<br />
sin(−x) = − sin x cos(−x) = cos x tan(−x) = − tan x<br />
The following cofunction identities can easily be seen by using triangles.<br />
Cofunction Identities<br />
<br />
π<br />
sin<br />
2<br />
<br />
π<br />
csc − u<br />
2<br />
<br />
<br />
π<br />
− u = cos u cos<br />
Simplify the following trig expressions.<br />
• sin(−u) + cot(−u) cos(−u)<br />
•<br />
sin x cos x<br />
+<br />
csc x sec x<br />
<br />
π<br />
= sec u sec − u<br />
2<br />
2<br />
<br />
<br />
π<br />
− u = sin u tan<br />
1<br />
2<br />
<br />
π<br />
= csc u cot − u<br />
2<br />
<br />
− u = cot u<br />
<br />
= tan u
Math 150, Fall 2008, c○Benjamin Aurispa<br />
•<br />
1 + sin u<br />
cos u<br />
π sin( 2 − u)<br />
+<br />
1 + sin u<br />
Tips to Proving Trigonometric Identities<br />
1. Start with one side of the equation and transform it to the other side of the equation. It’s usually<br />
easier to start with the more complicated side. Do NOT just do the same operations to both<br />
sides of the equation.<br />
2. Use identities that you already know to change the side you started with. Combine fractions under a<br />
common denominator (if necessary), then factor and simplify.<br />
3. A good strategy if you are stuck is to covert everything into sines and cosines. These are the functions<br />
you are most familiar with.<br />
4. Always keep in mind what you are trying to get to. This will help you know what to do if you are<br />
stuck.<br />
Prove the following trig identities.<br />
•<br />
•<br />
cot x sec x<br />
csc x<br />
= 1<br />
sec x + csc x<br />
= sin x + cos x<br />
tan x + cot x<br />
2
Math 150, Fall 2008, c○Benjamin Aurispa<br />
•<br />
1 + sin x 1 − sin x<br />
− = 4 tan x sec x<br />
1 − sin x 1 + sin x<br />
Trig Substitution is a technique you WILL use in Calculus II.<br />
Example: Substitute x = 2 tan θ into the expression<br />
7.2 Addition and Subtraction Formulas<br />
Formulas for Sine:<br />
Formulas for Cosine:<br />
Formulas for Tangent:<br />
1<br />
x2√ π<br />
and simplify. Assume that 0 ≤ θ <<br />
4 + x2 2 .<br />
sin(s + t) = sin s cos t + cos s sin t<br />
sin(s − t) = sin s cos t − cos s sin t<br />
cos(s + t) = cos s cos t − sin s sin t<br />
cos(s − t) = cos s cos t + sin s sin t<br />
tan s + tan t<br />
tan(s + t) =<br />
1 − tan s tan t<br />
tan s − tan t<br />
tan(s − t) =<br />
1 + tan s tan t<br />
With these formulas, we now can evaluate sines and cosines of angles other than 30 ◦ , 45 ◦ , and 60 ◦ .<br />
Find the exact value of each expression.<br />
• sin 15 ◦<br />
• cos 7π<br />
12<br />
3
Math 150, Fall 2008, c○Benjamin Aurispa<br />
• tan 75 ◦<br />
Prove the cofunction identity csc( π<br />
2 − u) = sec u by using an addition or subtraction formula.<br />
Prove the following identities.<br />
• 1 − tan x tan y =<br />
cos(x + y)<br />
cos x cos y<br />
• sin(x + y) − sin(x − y) = 2 cos x sin y<br />
• cos(x + y) cos(x − y) = cos 2 x − sin 2 y<br />
4
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