Primary Formula (Using Radius):

\[ A = \pi r^2 \]

Where:

• \( A \) = Area of the circle (square units)
• \( r \) = Radius of the circle (linear units)
• \( \pi \) = Pi (approximately 3.14159 or \( \frac{22}{7} \))

Alternative Formulas:

Using Diameter:

\[ A = \frac{\pi d^2}{4} \]

Using Circumference:

\[ A = \frac{C^2}{4\pi} \]

Step-by-step derivation:

1. Imagine dividing the circle into many thin concentric rings
2. Cut these rings and straighten them out to form triangular shapes
3. When arranged, they approximate a triangle with:
   • Base = Circumference = \( 2\pi r \)
   • Height = Radius = \( r \)
4. Area of triangle: \( A = \frac{1}{2} \times \text{base} \times \text{height} \)
5. Substituting: \( A = \frac{1}{2} \times 2\pi r \times r = \pi r^2 \)

As the number of sides of a regular polygon inscribed in a circle increases, the polygon approaches the shape of the circle:

1. For a regular polygon with \( n \) sides, each forming an isosceles triangle with the center
2. Area of each triangle = \( \frac{1}{2} \times s \times h \) where \( s \) is the side length and \( h \) is the height
3. Total area = \( n \times \frac{1}{2} \times s \times h = \frac{1}{2}(ns)h \)
4. As \( n \to \infty \): \( ns \to 2\pi r \) (circumference) and \( h \to r \)
5. Therefore: \( A = \frac{1}{2} \times 2\pi r \times r = \pi r^2 \)

Circumference Formulas:

Using Radius:

\[ C = 2\pi r \]

Using Diameter:

\[ C = \pi d \]

Relationship with Area:

\[ r = \sqrt{\frac{A}{\pi}} \quad \text{then} \quad C = 2\pi\sqrt{\frac{A}{\pi}} \]

Diameter from Radius:

\[ d = 2r \]

Radius from Diameter:

\[ r = \frac{d}{2} \]

Radius from Area:

\[ r = \sqrt{\frac{A}{\pi}} \]

Radius from Circumference:

\[ r = \frac{C}{2\pi} \]

Sector Area Formula (Central Angle in Degrees):

\[ A_{\text{sector}} = \frac{\theta}{360°} \times \pi r^2 \]

Sector Area Formula (Central Angle in Radians):

\[ A_{\text{sector}} = \frac{1}{2}r^2\theta \]

Where:

• \( \theta \) = Central angle (the angle at the center of the circle)
• \( r \) = Radius of the circle

Derivation:

The sector area is proportional to the angle it subtends at the center:

\[ \frac{\text{Sector Area}}{\text{Circle Area}} = \frac{\text{Sector Angle}}{\text{Full Angle}} \]

\[ \frac{A_{\text{sector}}}{\pi r^2} = \frac{\theta}{360°} \]

Arc Length (Degrees):

\[ L = \frac{\theta}{360°} \times 2\pi r \]

Arc Length (Radians):

\[ L = r\theta \]

Area of Segment Formula:

\[ A_{\text{segment}} = A_{\text{sector}} - A_{\text{triangle}} \]

\[ A_{\text{segment}} = \frac{1}{2}r^2(\theta - \sin\theta) \]

Where \( \theta \) is in radians

For degrees:

\[ A_{\text{segment}} = \frac{\pi r^2\theta}{360} - \frac{1}{2}r^2\sin\theta \]

Semicircle Area Formula:

\[ A_{\text{semicircle}} = \frac{\pi r^2}{2} \]

Using Diameter:

\[ A_{\text{semicircle}} = \frac{\pi d^2}{8} \]

Perimeter of Semicircle:

The perimeter includes the curved part (half circumference) plus the diameter:

\[ P_{\text{semicircle}} = \pi r + 2r = r(\pi + 2) \]

Total Degrees in a Circle:

\[ \text{Full circle} = 360° = 2\pi \text{ radians} \]

Converting Between Degrees and Radians:

\[ \text{Radians} = \frac{\pi}{180°} \times \text{Degrees} \]

\[ \text{Degrees} = \frac{180°}{\pi} \times \text{Radians} \]

Standard Form (center at origin):

\[ x^2 + y^2 = r^2 \]

General Form (center at (h, k)):

\[ (x - h)^2 + (y - k)^2 = r^2 \]

Expanded General Form:

\[ x^2 + y^2 + 2gx + 2fy + c = 0 \]

Where center is \( (-g, -f) \) and radius is \( \sqrt{g^2 + f^2 - c} \)