**The Pentagon**, as a geometric shape, is a**polygon with five sides**that holds a unique place in the realm of mathematics and geometry. Derived from the Greek words “penta,” meaning “five,” and “gonia,” meaning “angle,” the Pentagon is defined by its**distinctive five straight sides and five interior angles**. It’s symmetrical design and balanced proportions have intrigued mathematicians, artists, and architects for centuries. From ancient civilizations to modern-day structures, the Pentagon’s geometric elegance continues to inspire and captivate those who appreciate the beauty and precision of mathematical forms.

This post will examine the intriguing features, historical significance, and creative applications of the**Pentagon**as a geometric shape.

## Definition

The**Pentagon**is a**geometric shape**that is characterized by its five sides and five angles. It is a**polygon**, which means it is a closed figure formed by connecting straight-line segments. The term “pentagon” is derived from the Greek words “penta,” meaning “five,” and “gonia,” meaning “angle.”

The**five sides**of a pentagon are straight lines that connect to form a closed shape. Each side of a pentagon intersects with two other sides, and a pentagon’s internal angles add up to 540 degrees. This means that each of the**five angles**in a pentagon measures**108 degrees**.

The**symmetry**of a pentagon is evident as it can be divided into five equal**isosceles triangles**. The**diagonals**of a pentagon are line segments that connect non-adjacent vertices, forming**internal triangles**. A pentagon has a total of**five diagonals**. Below is the generic diagram of a pentagon.

Figure-1: Generic pentagon.

Pentagons are commonly found in various contexts, including**architecture**,**design**, and**mathematics**. In architecture, they can be seen in the design of buildings such as the**Pentagon**in Washington, D.C., which is a famous five-sided structure. The Pentagon is also utilized in mathematical concepts, such as the**Pentagonal Number**series, it stands for the maximum possible number of dots that can be arranged to form a pentagon.

**Origins and Significance of the Pentagon Shape**

The **pentagon shape** has a rich historical background that traces back to **ancient civilizations**. Dating back thousands of years, the shape of the Pentagon holds **cultural**, **mystical**, and **symbolic significance** in various cultures and societies. The origins of its significance can be found in **religious**, **architectural**, and **mathematical contexts**, where the number five and its associated shape held special meaning.

**Ancient Civilizations and the Pentagon Shape**

In **ancient Greece**, the **Pentagon shape** was revered for its connection to the divine. The **Pythagoreans** associated it with the concept of the **Golden Ratio**, a mathematical proportion believed to represent perfect beauty and harmony. In **Chinese philosophy**, the five-sided shape symbolizes the **five elements of nature**: fire, earth, metal, water, and wood, representing balance and cosmic unity. Additionally, **ancient Mayan** and **Aztec civilizations** incorporated the Pentagon shape into their artwork, architecture, and calendar systems, depicting their understanding of the universe’s interconnectedness.

**Modern Symbolism and Usage of the Pentagon Shape**

The Pentagon’s shape gained renewed prominence in modern times, particularly with its association with **military** and **defense**. The **geometric design** of the Pentagon building, constructed during **World War II**, drew inspiration from the Pentagon shape. Its **strategic importance** led to the name “Pentagon” and further popularized the shape in contemporary culture.

**Pentagon Shape in Architecture and Design**

The **pentagon shape** has found its way into modern **architecture**, **design**, and even **pop culture**. Architects and designers have employed the shape in the creation of buildings, facades, and urban landscapes, seeking to evoke **strength**, **stability**, and a sense of **importance**. Its clean lines and distinct geometry make it visually striking and memorable.

**The Pentagon Shape’s Enduring Legacy**

The historical significance of the **Pentagon shape** lies in its **timeless appeal** and **enduring symbolism**. From ancient civilizations to the modern era, its geometric form has represented various concepts, including **divinity**, **balance**, **military strength**, and **architectural splendor**. Today, the Pentagon shape continues to be recognized globally, its historical background serving as a reminder of the profound influence of geometry on human culture, art, and design.

## Properties

**Number of Sides**

A pentagon has**five sides**. These sides are straight line segments that connect to form a closed shape.

**Number of Angles**

A pentagon has**five angles**. Each angle is formed by two adjacent sides. A pentagon’s internal angles always add up to 540 degrees. This means that if you add up all the angles inside a pentagon, the total will always be **540 degrees**.

**Angle Measure**

Since a pentagon has five angles, each angle measures**108 degrees**. This is because the sum of the interior angles (540 degrees) is divided equally among the five angles.

**Symmetry:**

A pentagon exhibits**symmetry**. It can be divided into five equal**isosceles triangles**. An isosceles triangle has two sides of equal length and two angles of equal measure.

**Diagonals**

The**diagonals**of a pentagon are line segments that connect non-adjacent vertices. In a pentagon, there are**five diagonals**. Diagonals divide the Pentagon into internal triangles.

**Regular and Irregular Pentagons**

A**regular pentagon**has equal side lengths and equal interior angles. All the angles in a regular pentagon are **108 degrees**, and all the sides are of the same length. An**irregular pentagon**has different side lengths and angles.

**Golden Ratio**

The **golden ratio**, approximately equal to 1.618, is closely associated with regular pentagons. It is the **ratio** between the length of the diagonal and the length of a side of a **regular pentagon**.

**Construction**

A **pentagon** can be constructed using various methods, such as using a compass and straightedge or utilizing geometric principles like the **Pythagorean theorem**.

## Related formulas

**The perimeter of a Regular Pentagon**

The **perimeter** **(P)** of a regular pentagon can be calculated by multiplying the length of one side (s) by **5** since a regular pentagon has five equal sides. P = 5s

**Interior Angle of a Regular Pentagon**

The** interior angle** **(I)** of a regular pentagon can be calculated using the formula: **I = (5 – 2) × 180° / 5 A = 108°**

**Exterior Angle of a Regular Pentagon**

The **exterior angle** **(E)** of a regular pentagon can be calculated using the formula: **E = 360° / 5 E = 72°**

**Apothem of a Regular Pentagon**

The **distance** from a regular **Pentagon’s centre** to any of its sides’ midpoints is known as the apothem **(a)**. The apothem can be calculated using the following formula, where s is the length of a side and R is the radius of the circ*mscribed circle: **a = R × cos(36°).** Alternatively, the apothem can be calculated using the formula: **a = s / (2 × tan(54°))**

**Area of a Regular Pentagon**

You may determine the regular** pentagon’s area** **(A)** by multiplying the apothem **(a)** by the perimeter **(P)** and dividing the result by **2**: **A = (P × a) / 2**. Alternatively, the area can also be calculated using the formula: **A = (s² × 5) / (4 × tan(54°))**

These formulas are applicable specifically to regular pentagons, where all sides and angles are equal. For irregular pentagons with varying side lengths and angles, specific measurements and calculations may vary.

## Pentagon Types

**Regular Pentagon**

A **regular pentagon** is a type of Pentagon that has**equal side lengths**and**equal interior angles**. All five angles in a regular pentagon measure**108 degrees**. The regular Pentagon possesses**rotational symmetry** of order 5, meaning that it looks the same after rotating it by multiples of **72 degrees**. Examples of regular pentagons can be found in the shape of a star, where the outer points form the vertices of the Pentagon. Below is the generic diagram of a regular pentagon.

Figure-2: Regular pentagon.

**Irregular Pentagon**

An **irregular pentagon** is a pentagon that does not have **equal side lengths** or **equal angles**. In an irregular pentagon, the lengths of its sides and the measures of its angles can differ. Irregular pentagons can take on various shapes and configurations, and their angles can range from **acute** to **obtuse**. Below is the generic diagram of an irregular pentagon.

Figure-3: Irregular pentagon.

**Convex Pentagon**

Any **pentagon** whose internal angles are all smaller than 180 degrees is indeed considered **convex**. Convex pentagons have a **bulging** shape and do not have any **dents** or **concave parts**. The sides of a convex pentagon do not intersect when extended. Thank you for pointing that out.Below is the generic diagram of an irregular convex pentagon.

Figure-4: Irregular convex pentagon.

**Concave Pentagon**

A **pentagon** with at least one internal angle greater than **180 degrees** is indeed said to be **concave**. In a concave pentagon, some of its sides intersect when extended, creating inward “dents” or **concave parts**. Concave pentagons can have a variety of shapes, and their angles can range from **acute** to **reflex**. Below is the generic diagram of an irregular concave pentagon.

Figure-5: Irregular concave pentagon.

**Golden Pentagon**

A **golden pentagon**, also known as a **golden ratio pentagon**, is a **regular pentagon** with a unique relationship between the length of its diagonal and its side length. The **ratio of the diagonal length** to the **side length** in a golden pentagon is approximately equal to the **golden ratio**, which is approximately 1.618. The golden pentagon is considered **aesthetically pleasing** and is often associated with **harmonious proportions.**

## Applications

**Pentagons** find applications in various fields due to their unique properties and aesthetic appeal. Here are some notable applications of pentagons in different areas.

**Architecture and Design**

**Pentagons** are indeed frequently used in **architecture** and **design** for their distinct shape and symmetry. The **Pentagon building** in Washington, D.C., serves as an iconic example of a **pentagon-shaped structure**. Additionally, pentagons can be found in the design of **facades**, **windows**, **tiles**, and **decorative elements** in various buildings. The unique characteristics of the pentagon shape make it a popular choice for creating visually appealing architectural and design elements.

**Mathematics and Geometry**

**Pentagons** do indeed play a significant role in **mathematics** and **geometry**. They are commonly used as illustrative examples in geometry textbooks, providing a foundation for studying **polygonal shapes**. Properties of pentagons, such as their angles, diagonals, and side lengths, are explored in **mathematical proofs** and calculations. The study of pentagons contributes to a deeper understanding of geometric principles and serves as a building block for more complex mathematical concepts.

**Art and Aesthetics**

**Pentagons** are indeed visually appealing and are frequently used in **art** and **aesthetics**. Artists and designers incorporate pentagon shapes in **paintings**, **sculptures**, **patterns**, and various artistic compositions. The **regular pentagon**, with its symmetrical angles and sides, often represents **balance** and **harmony** in visual art. The distinct geometry of the pentagon shape offers artists a versatile and engaging element to incorporate into their creative expressions.

**Tessellations and Patterns**

**Pentagons** are indeed used in **tessellations**, which are repeating patterns that cover a plane without any gaps or overlaps. Pentagonal tessellations can be found in various contexts, including **Islamic art**, **tiling designs**, and **mathematical investigations**. Artists and designers utilize pentagons to create **intricate patterns** and achieve visually captivating arrangements within tessellations. The unique properties of pentagons allow for the creation of diverse and aesthetically pleasing tessellation designs.

**Crystallography**

In **crystallography**, which is the study of crystal structures, pentagons can indeed be observed in certain types of crystals. For instance, **dodecahedral crystals** have twelve pentagonal faces, while **icosahedral crystals** have twenty triangular faces, some of which contain embedded pentagons. These unique crystal structures with pentagonal elements contribute to the diverse and fascinating world of crystallography, revealing the natural occurrence of pentagon shapes in the formation of crystals.

**Chemistry**

In **organic chemistry**, pentagons are indeed encountered in the study of carbon-based compounds known as **aromatic hydrocarbons**. Pentagonal rings, such as in the case of **cyclopentane** or pentagonal aromatic molecules like **pentalene**, have unique **electronic properties** and are studied for their **reactivity** and **stability**.

**Sports**

**Pentagons** do indeed find applications in various sports equipment designs. For instance, **soccer balls** (also known as **footballs**) traditionally consist of **pentagonal** and **hexagonal panels** stitched together to form a **spherical shape**. This pattern of pentagons and hexagons provides **stability** and **uniform distribution of pressure** on the ball’s surface.

**Logo Design and Branding**

**Pentagons** are indeed often used in **logo designs** and **branding** to convey certain meanings or characteristics. Companies may incorporate pentagons in their logos to symbolize **strength**, **stability**, **innovation**, or a sense of **geometric precision**. The distinctive shape of a pentagon can make a logo visually striking and memorable.

## Exercise

### Example 1

Determine the **surface area** and **circumference** of a regular pentagon with 6 cm sides.

### Solution

Given: Side length (s) = 6 cm

To find the perimeter **(P)**, we can use the formula **P = 5 × s** since a regular pentagon has five equal sides: **P = 5 × 6 cm P = 30 cm**.

To find the area (A), we can use the formula:

A = (s² × 5) / (4 × tan(54°))

A = 6² × 5 / (4 × tan(54°))

A ≈ 61.88 cm² (rounded to two decimal places)

### Example 2

Determine the **measure** of each** interior angle** of a regular pentagon.

### Solution

To find the measure of each interior angle (A), we can use the formula

A = (5 – 2) × 180° / 5

A = (5 – 2) × 180° / 5

A = 108°

Therefore, a regular pentagon has **108°** for each inner angle.

### Example 3

Measure each of the **outer angles** of a standard pentagon.

### Solution

To determine each exterior angle’s (E) measurement, we can use the formula

E = 360° / 5

E = 360° / 5

E = 72°

Therefore, each exterior angle of a regular pentagon measures** 72°**.

### Example 4

Find the** apothem** of the pentagon given in Figure-6.

Figure-6.

### Solution

Given: Side length (s) = 10 units

To find the apothem (a), we can use the formula

a = s / (2 × tan(54°))

a = 10 units / (2 × tan(54°))

a ≈ 5.07 units (rounded to two decimal places)

Therefore, the apothem of the regular Pentagon is approximately **5.07 units**.

### Example 5

Determine the **radius** of the **circ*mscribed circle** for a regular pentagon with an apothem of **8 cm**.

### Solution

Given: Apothem (a) = 8 cm

To find the radius of the circ*mscribed circle (R), we can use the formula

R = a / cos(36°)

R = 8 cm / cos(36°)

R ≈ 9.76 cm (rounded to two decimal places)

Therefore, the radius of the circ*mscribed circle for the regular Pentagon is approximately** 9.76 cm**.

### Example 6

Find the **area** of a regular pentagon with an apothem of **12 units**.

### Solution

Given: Apothem (a) = 12 units

To find the area (A), we can use the formula

A = (P × a) / 2

where P is the perimeter of the Pentagon:

P = 5s (where s is the side length of the Pentagon).

Since the Pentagon is regular, all sides are equal, so let’s assume s = 1 unit (this is arbitrary for calculation purposes).

P = 5 × 1 unit

P = 5 units

A = (P × a) / 2

A = (5 units × 12 units) / 2

A = 30 units²

Therefore, the area of the regular Pentagon is** 30 square units**.

### Example 7

Determine the **length of a side** of a regular pentagon with a perimeter of **40 cm**.

### Solution

Given: Perimeter (P) = 40 cm

To find the length of each side (s), we can rearrange the formula

P = 5 × s and solve for s:

40 cm = 5 × s

s = 40 cm / 5

s = 8 cm

Therefore, each side of the regular Pentagon measures **8 cm**.

### Example 8

Calculate the ratio of the** area** of a **regular pentagon** to the **area** of its **circ*mscribed circle**.

### Solution

To calculate the ratio of the area of a regular pentagon to the area of its circ*mscribed circle, we need to consider their formulas.

The **area (A)** of a regular pentagon can be calculated using the formula A = (s² × 5) / (4 × tan(54°)), where **s** is the side length of the Pentagon.

The **area** **(C)** of the circ*mscribed circle can be calculated using the formula C = πR², where **R** is the radius of the circ*mscribed circle.

Since the radius of the circ*mscribed circle is equal to the apothem **(a)** of the Pentagon, the formula becomes **C = πa²**.

The ratio of the area of the Pentagon to the area of the circle is then **A / C**.

This ratio depends on the specific values of s and a.

### Example 9

Determine the **number of diagonals** in a pentagon.

### Solution

A diagonal is a line segment that connects non-adjacent vertices in a polygon.

In a pentagon, each vertex is connected to three non-adjacent vertices by diagonals.

Since a pentagon has **5** vertices, the total number of diagonals is **5 × 3 = 15**.

However, we must divide by 2 to avoid counting each diagonal twice (as it connects two vertices).

Therefore, a pentagon has **15 / 2 = 7.5 diagonals** (note that diagonals must be whole numbers, so we round down).

Therefore, a pentagon has **7 diagonals**.

*All images were created with GeoGebra.*