Table of contents

0. Review of College Algebra4h 43m

Rationalizing Denominators
15m

Pythagorean Theorem & Basics of Triangles
17m

Basics of Graphing
30m

Functions
41m

Transformations
45m

Asymptotes
4m

Solving Linear Equations
31m

Solving Quadratic Equations
55m

Complex Numbers
41m

1. Measuring Angles40m

Angles in Standard Position
12m

Coterminal Angles
8m

Complementary and Supplementary Angles
10m

Radians
8m

2. Trigonometric Functions on Right Triangles2h 5m

Trigonometric Functions on Right Triangles
45m

Special Right Triangles
30m

Cofunctions of Complementary Angles
26m

Solving Right Triangles
23m

3. Unit Circle1h 19m

Defining the Unit Circle
14m

Trigonometric Functions on the Unit Circle
9m

Common Values of Sine, Cosine, & Tangent
11m

Reference Angles
38m

Reciprocal Trigonometric Functions on the Unit Circle
6m

4. Graphing Trigonometric Functions1h 19m

Graphs of the Sine and Cosine Functions
32m

Phase Shifts
14m

Graphs of Secant and Cosecant Functions
10m

Graphs of Tangent and Cotangent Functions
21m

5. Inverse Trigonometric Functions and Basic Trigonometric Equations1h 41m

Inverse Sine, Cosine, & Tangent
28m

Evaluate Composite Trig Functions
44m

Linear Trigonometric Equations
28m

6. Trigonometric Identities and More Equations2h 34m

Introduction to Trigonometric Identities
1h 4m

Sum and Difference Identities
1h 3m

Double Angle Identities
16m

Solving Trigonometric Equations Using Identities
9m

7. Non-Right Triangles1h 38m

Law of Sines
49m

Law of Cosines
30m

Area of SAS & ASA Triangles
19m

8. Vectors2h 25m

Geometric Vectors
28m

Vectors in Component Form
32m

Direction of a Vector
23m

Unit Vectors and i & j Notation
27m

Dot Product
22m

Cross Product
11m

9. Polar Equations2h 5m

Polar Coordinate System
29m

Convert Points Between Polar and Rectangular Coordinates
26m

Convert Equations Between Polar and Rectangular Forms
29m

Graphing Other Common Polar Equations
39m

10. Parametric Equations1h 6m

Graphing Parametric Equations
12m

Eliminate the Parameter
32m

Writing Parametric Equations
21m

11. Graphing Complex Numbers1h 7m

Graphing Complex Numbers
6m

Polar Form of Complex Numbers
22m

Products and Quotients of Complex Numbers
14m

Powers of Complex Numbers (DeMoivre's Theorem)
23m

OLD 1. Angles and the Trigonometric Functions Coming soon

OLD 2. Trigonometric Functions graphs, Inverse Trigonometric Functions Coming soon

OLD 3. Trigonometric Identities and Equations Coming soon

OLD 4. Laws of Sines, Cosines and Vectors Coming soon

OLD 5. Complex Numbers, Polar Coordinates and Parametric Equations Coming soon

NEW (not used) 7. Laws of Sines, Cosines and Vectors Coming soon

NEW (not used) 8. Vectors Coming soon

NEW(not used) 9. Polar equations Coming soon

NEW (not used) 11. Graphing Complex Numbers Coming soon

7. Non-Right Triangles

Area of SAS & ASA Triangles

Trigonometry

7. Non-Right Triangles

Area of SAS & ASA Triangles

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Multiple Choice

Given the polar curves $r = 3 \sin (θ)$ and $r = 3 \cos (θ)$ , what is the area of the region that lies inside both curves?

9

\frac{9}{8}

\frac{9}{4}

\frac{9}{2}

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Verified step by step guidance

Identify the two polar curves given: $r = 3 \sin(\theta)$ and $r = 3 \cos(\theta)$. These represent circles in polar coordinates.

Find the points of intersection by setting the two equations equal: $3 \sin(\theta) = 3 \cos(\theta)$, which simplifies to $\sin(\theta) = \cos(\theta)$. Solve for $\theta$ to find the angles where the curves intersect.

Determine the region inside both curves. Since both are circles centered on the axes, the overlapping region is symmetric and lies between the intersection angles found in the previous step.

Set up the integral for the area of the overlapping region. The area inside a polar curve $r(\theta)$ from $\alpha$ to $\beta$ is given by $\frac{1}{2} \int_{\alpha}^{\beta} r(\theta)^2 \, d\theta$. For the overlapping region, integrate the minimum of the two $r$ values over the appropriate interval.

Calculate the area by integrating $\frac{1}{2} (3 \sin(\theta))^2$ and $\frac{1}{2} (3 \cos(\theta))^2$ over their respective intervals determined by the intersection points, then sum these areas to find the total area inside both curves.