Presentation is loading. Please wait.

Presentation is loading. Please wait.

Trigonometry Review Find sin(  /4) = cos(  /4) = tan(  /4) = Find sin(  /4) = cos(  /4) = tan(  /4) = csc(  /4) = sec(  /4) = cot(  /4) = csc(

Published byRahul Stickland Modified over 10 years ago

Similar presentations

Presentation on theme: "Trigonometry Review Find sin(  /4) = cos(  /4) = tan(  /4) = Find sin(  /4) = cos(  /4) = tan(  /4) = csc(  /4) = sec(  /4) = cot(  /4) = csc("— Presentation transcript:

1 Trigonometry Review Find sin(  /4) = cos(  /4) = tan(  /4) = Find sin(  /4) = cos(  /4) = tan(  /4) = csc(  /4) = sec(  /4) = cot(  /4) = csc(  /4) = sec(  /4) = cot(  /4) =

2 Evaluate tan(  /4) A. Root 2 B. 2 C. Root 2 /2 D. 2 / Root 2 E. 1

3 Trigonometry Review sin(2  /3) = cos(2  /3) = tan(2  /3) = sin(2  /3) = cos(2  /3) = tan(2  /3) = csc(2  /3) = sec(2  /3) = cot(2  /3) = csc(2  /3) = sec(2  /3) = cot(2  /3) =

4 Evaluate sec(2  /3) A. -1 B. -2 C. -3 D. Root(3) E. 2 / Root(3)

5 Trig. Derivatives sin’(x) = cos(x) cos’(x) = - sin(x)

6 Trig. Derivatives sin’(x) = cos(x) sin’(x) =

7 sin’(x) =. sin’(x) =

8 Rule 4 says. A. 0 B. 0.5 C. 1 D. 1.5

9 Rule 5 says. A. 0 B. 0.5 C. 1 D. 1.5

10 sin’(x) =. sin’(x) =

11 Trig. Derivatives sin’(x) = cos(x) cos’(x) = - sin(x)

12 If y = sin(x) + 2x 2, find dy/dx A. - cos(x) + 4x B. cos(x) + 4 C. cos(x) + 4x

13 Trig. Derivatives sin’(x) = cos(x) cos’(x) = - sin(x) sin’(x) = cos(x) cos’(x) = - sin(x) A) sin’(0) = cos(0) = 1 A) sin’(0) = cos(0) = 1 B) sin’(  /4) = cos(  /4) = 0.707 B) sin’(  /4) = cos(  /4) = 0.707 C) sin’(-  /3) = cos(-  /3) = 0.5 C) sin’(-  /3) = cos(-  /3) = 0.5

14 x= 0, 2  /3, - 3  /4 cos’(x) = - sin(x) cos’(x) = - sin(x) A) cos’(0) = - sin (0) = 0 A) cos’(0) = - sin (0) = 0 B) cos’(-3  /4) = - sin(5  /4) = 0.707 B) cos’(-3  /4) = - sin(5  /4) = 0.707 C) cos’(2  /3) = - sin(2  /3) = - 0.866 C) cos’(2  /3) = - sin(2  /3) = - 0.866

15 Evaluate cos’(  /2) A. -1 B. -.707 C. 1 D. 0.707

16 Evaluate sin’(  /3) A. - 0.5 B. 0.5 C. 0.707 D. 0.866

17 Trig. Derivatives sin’(x) = cos(x) cos’(x) = - sin(x) sin’(x) = cos(x) cos’(x) = - sin(x) tan’(x) = sec 2 (x) cot’(x) = - csc 2 (x) tan’(x) = sec 2 (x) cot’(x) = - csc 2 (x) sec’(x) = sec(x)tan(x) csc’(x) = -csc(x)cot(x) sec’(x) = sec(x)tan(x) csc’(x) = -csc(x)cot(x)

18 Trig. Derivatives Theorem tan’(x) = sec 2 (x) Theorem tan’(x) = sec 2 (x) Proof : tan’(x) = [sin(x)/cos(x)]’ Proof : tan’(x) = [sin(x)/cos(x)]’

19 Trig. Derivatives Theorem tan’(x) = sec 2 (x) Theorem tan’(x) = sec 2 (x) tan’(  /4) = tan’(  /4) =

20 Trig. Derivatives Theorem tan’(x) = sec 2 (x) Theorem tan’(x) = sec 2 (x) tan’(  /4) = sec 2 (  /4) = 2 while tan(  /4) = tan’(  /4) = sec 2 (  /4) = 2 while tan(  /4) = 1

21 Trig. Derivatives Theorem cot’(x) = - csc 2 (x) Theorem cot’(x) = - csc 2 (x) Proof : cot’(x) = [cos(x)/sin(x)]’ Proof : cot’(x) = [cos(x)/sin(x)]’

22 Trig. Derivatives Theorem sec’(x) = sec(x)tan(x) Theorem sec’(x) = sec(x)tan(x) Proof : sec’(x) = [1/cos(x)]’ Proof : sec’(x) = [1/cos(x)]’

23 Trig. Derivatives Theorem csc’(x) = - csc(x)cot(x) Theorem csc’(x) = - csc(x)cot(x) Proof : csc’(x) = [1/sin(x)]’ Proof : csc’(x) = [1/sin(x)]’

24 Trig. Derivatives sin’(x) = cos(x) cos’(x) = - sin(x) sin’(x) = cos(x) cos’(x) = - sin(x) tan’(x) = sec 2 (x) cot’(x) = - csc 2 (x) tan’(x) = sec 2 (x) cot’(x) = - csc 2 (x) sec’(x) = sec(x)tan(x) csc’(x) = - csc(x)cot(x) sec’(x) = sec(x)tan(x) csc’(x) = - csc(x)cot(x)

25 If y = tan(x) sec(x) find the velocity and y’(  /3) sec’(x) = sec(x)tan(x) tan’(x) = sec 2 (x) sec’(x) = sec(x)tan(x) tan’(x) = sec 2 (x) y ’ = tan(x)sec(x)tan(x) + sec(x)sec 2 (x) y ’ = tan(x)sec(x)tan(x) + sec(x)sec 2 (x) y’=sec(x)[sec 2 (x)-1] + sec 3 (x)=2sec 3 (x)-sec(x) y’=sec(x)[sec 2 (x)-1] + sec 3 (x)=2sec 3 (x)-sec(x) y’(  /3) = 2sec 3 (  /3)-sec(  /3) = y’(  /3) = 2sec 3 (  /3)-sec(  /3) = sin 2 x+cos 2 x=1 dividing by cos 2( x) sin 2 x+cos 2 x=1 dividing by cos 2( x) tan 2 (x)+1=sec 2 (x) tan 2 (x)+1=sec 2 (x)

26 If y = tan(x) cos(x) find the acceleration and y’’(  /3) y’ = cos(x) y’ = cos(x) y’’ = -sin(x) y’’(  /3)= y’’ = -sin(x) y’’(  /3)=

27 If y = tan(x) + cos(x) find the initial acceleration, y’’(0) tan’(x) = sec 2 (x) sec’(x) = sec(x)tan(x) tan’(x) = sec 2 (x) sec’(x) = sec(x)tan(x) y’ = sec(x)sec(x) - sin(x) y’’ = sec(x) sec(x)tan(x) + sec(x) sec(x)tan(x) - cos(x) = 2 sec 2 (x) tan(x) – cos(x) y’’(0) = 2 * 1 * 0 -......

28 y” = 2 sec 2 (x) tan(x) – cos(x) y”(0) =

29 If y = sec(x), find the acceleration, y’’(0) using the product rule on sec’(x).

30 Find the slope of the tangent line to y = x + sin(x) when x = 0

31 Write the equation of the line tangent to y = x + sin(x) when x = 0 A. y = 2x + 1 B. y = 2x + 0.5 C. y = 2x

Download ppt "Trigonometry Review Find sin(  /4) = cos(  /4) = tan(  /4) = Find sin(  /4) = cos(  /4) = tan(  /4) = csc(  /4) = sec(  /4) = cot(  /4) = csc("

Similar presentations

The Chain Rule Section 3.6c.

The Chain Rule Section 3.6c.
Derivatives - Equation of the Tangent Line Now that we can find the slope of the tangent line of a function at a given point, we need to find the equation.

Derivatives - Equation of the Tangent Line Now that we can find the slope of the tangent line of a function at a given point, we need to find the equation.
The Inverse Trigonometric Functions Section 4.2. Objectives Find the exact value of expressions involving the inverse sine, cosine, and tangent functions.

The Inverse Trigonometric Functions Section 4.2. Objectives Find the exact value of expressions involving the inverse sine, cosine, and tangent functions.
Tic-Tac-Toe Using the Graphing Calculator for Derivatives.

Tic-Tac-Toe Using the Graphing Calculator for Derivatives.
Trig Graphs. y = sin x y = cos x y = tan x y = sin x + 2.

Trig Graphs. y = sin x y = cos x y = tan x y = sin x + 2.
1 Special Angle Values DEGREES. 2 Directions A slide will appear showing a trig function with a special angle. Say the value aloud before the computer.

1 Special Angle Values DEGREES. 2 Directions A slide will appear showing a trig function with a special angle. Say the value aloud before the computer.
Write the following trigonometric expression in terms of sine and cosine, and then simplify: sin x cot x Select the correct answer: 1234567891011121314151617181920.

Write the following trigonometric expression in terms of sine and cosine, and then simplify: sin x cot x Select the correct answer:
Pg. 346/352 Homework Pg. 352 #6, 8 – 11, 15 – 17, 21, 22, 24, 27, 28, 30 – 32.

Pg. 346/352 Homework Pg. 352 #6, 8 – 11, 15 – 17, 21, 22, 24, 27, 28, 30 – 32.
4.4 Trigonometric Functions of any Angle Objective: Students will know how to evaluate trigonometric functions of any angle, and use reference angles to.

4.4 Trigonometric Functions of any Angle Objective: Students will know how to evaluate trigonometric functions of any angle, and use reference angles to.
Chapter 6: Trigonometry 6.5: Basic Trigonometric Identities

Chapter 6: Trigonometry 6.5: Basic Trigonometric Identities
3.8 Derivatives of Inverse Trigonometric Functions.

3.8 Derivatives of Inverse Trigonometric Functions.
Product and Quotient Rules and Higher – Order Derivatives

Product and Quotient Rules and Higher – Order Derivatives
Calculus Chapter 3 Derivatives. 3.1 Informal definition of derivative.

Calculus Chapter 3 Derivatives. 3.1 Informal definition of derivative.
Right Triangle Trigonometry

Right Triangle Trigonometry
Trigonometry Review Game. Do not use a calculator on any of these questions until specified otherwise.

Trigonometry Review Game. Do not use a calculator on any of these questions until specified otherwise.
6.2: Right angle trigonometry

6.2: Right angle trigonometry
Angle Identities. θsin θcos θtan θ 0010 –π/6–1/2√3/2–√3/3 –π/4–√2/2√2/2–1 –π/3–√3/21/2–√3 –π/2–10Undef –2π/3–√3/2–1/2√3 –3π/4–√2/2 1 –5π/6–1/2–√3/2√3/3.

Angle Identities. θsin θcos θtan θ 0010 –π/6–1/2√3/2–√3/3 –π/4–√2/2√2/2–1 –π/3–√3/21/2–√3 –π/2–10Undef –2π/3–√3/2–1/2√3 –3π/4–√2/2 1 –5π/6–1/2–√3/2√3/3.
TOP 10 Missed Mid-Unit Quiz Questions. Use the given function values and trigonometric identities to find the indicated trig functions. Cot and Cos 1.Csc.

TOP 10 Missed Mid-Unit Quiz Questions. Use the given function values and trigonometric identities to find the indicated trig functions. Cot and Cos 1.Csc.
Example: Later, though, we will meet functions, such as y = x 2 sinx, for which the product rule is the only possible method.

Example: Later, though, we will meet functions, such as y = x 2 sinx, for which the product rule is the only possible method.
Odds and Even functions Evaluating trig functions Use a calculator to evaluate trig functions.

Odds and Even functions Evaluating trig functions Use a calculator to evaluate trig functions.

Similar presentations

Ads by Google