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Polygon Diagonals Explained: Formula, Calculation & Uses

Polygon Diagonals Explained: Formula, Calculation & Uses

Q: 1. What is the basic definition of a polygon in geometry?

A polygon is a two-dimensional closed shape made up of straight line segments. To be a polygon, a figure must be enclosed, and its sides cannot be curved. The simplest polygon is a triangle, which has three sides. Other examples include quadrilaterals (4 sides), pentagons (5 sides), and hexagons (6 sides).

Q: 2. What exactly is a diagonal of a polygon?

A diagonal is a line segment that connects two non-adjacent vertices of a polygon. Vertices are the corners where the sides meet. A diagonal passes through the interior of the polygon, unlike a side, which forms the boundary of the shape. For example, in a square, a line drawn from the top-left corner to the bottom-right corner is a diagonal.

Q: 5. How many diagonals does a hexagon have? Show the calculation.

A hexagon has 6 sides, so n=6. To find the number of diagonals, we use the formula n(n-3)/2:Substitute n=6 into the formula: 6(6-3)/2Solve the parenthesis: 6(3)/2Multiply the numbers: 18/2Divide to get the final answer: 9Therefore, a hexagon has 9 diagonals.

Q: 8. What is the fundamental difference between a side and a diagonal of a polygon?

The key difference lies in the vertices they connect. A side of a polygon connects two adjacent (or consecutive) vertices, forming the boundary of the shape. In contrast, a diagonal connects two non-adjacent (or non-consecutive) vertices, passing through the polygon's interior (in convex polygons).

Q: 10. Can you give a real-world example where polygon diagonals are important?

A great real-world example is in construction and structural engineering. When building a rectangular frame for a wall or a gate, it can be flimsy. To make it rigid and prevent it from collapsing into a parallelogram, a diagonal brace is added. This brace acts as a diagonal, effectively creating two triangles within the frame. Since triangles are rigid shapes, the diagonal adds immense stability to the entire structure.

Reviewed by:

Rama Sharma

How to Calculate Diagonals in Polygons with Step-by-Step Examples

The diagonal of a polygon is a line segment that connects any two non-adjacent vertices. The number of diagonals and their attributes vary depending on the type of polygon and the number of sides. Let's review what a polygon is and what a diagonal is before learning the diagonal of a polygon formula.

A closed shape made up of three or more line segments is called a polygon. A line segment generated by joining any two non-adjacent vertices forms the diagonal of a polygon. Let's look at the formula for a polygon's diagonal, as well as some examples of solved problems. You can quickly count all of the possible diagonals of a basic polygon with a few sides. Counting polygons can be difficult when they become more intricate.

Fortunately, there is a straightforward formula for calculating the number of diagonals in a polygon. Because any vertex (corner) is connected to two other vertices by sides, those connections cannot be considered diagonals. That vertex, too, is unable to make a connection with itself. As a result, ‘n’ we'll immediately lower the number of viable diagonals by three.

That vertex, too, is unable to make a connection with itself. For example, our door only has two diagonals if you don't include moving from the top hinge to the bottom opposite and back. Any solution will have to be divided by two.

Diagonal- Polygons Diagonals

A diagonal is a segment of a polygon that connects two non-consecutive vertices. In a polygon, the number of diagonals that can be drawn from any vertex is three less than the number of sides. Multiply the number into totaling of diagonals per vertex (n - 3) by the number of vertices, n, then divide by 2 to get the total number of diagonals in a polygon (otherwise each diagonal is counted twice).

Number of Diagonals = \[\frac{n(n-3)}{2}\]

Simply subtract the total sides from the diagonals given by each vertex to another vertex to arrive at this formula. To put it another way, an n-sided polygon has n-vertices that can be connected in nC2 ways.

The formula obtained by subtracting n using nC2 methods is \[\frac{n(n-3)}{2}\].

The total sides of a hexagon, for example, are six. As a result, the total diagonals are 6(6-3)/2 = 9

Let’s know what a diagonal is. A diagonal of a polygon can be defined as a line segment joining two vertices. From any given vertex, there are no diagonals to the vertex on either side of it, since that would lay on top of the side. Also, remember that there is obviously no diagonal from a vertex back to itself. This means there are three less diagonals than the number of vertices. (We do not count diagonals to itself and one either side). This is a diagonal definition.

Here, we are going to discuss the number of diagonals in a polygon, diagonal definition.

Formula for the Number of Diagonals

As described above, the number of diagonals from a single vertex is three less than the number of vertices or sides, or (n-3).

There are a total number of N vertices, which gives us n(n-3) diagonals.

But each diagonal of the polygon has two ends, so this would count each one twice. So as a final step we need to divide by 2, for the final formula:

Number of distinct diagonals = \[\frac{n(n-3)}{2}\]

where,

n is the number of sides (or vertices).

Diagonals of Polygon

The diagonals of a polygon is a segment line in which the ends are non-adjacent vertices of a polygon.

How many diagonals does n-polygon have? Let’s see the diagonals of a polygon and the no. of diagonals in a polygon.

For n = 3 we have a triangle. We can clearly see the triangle has no diagonals because each vertex has only adjacent vertices. Therefore, the number of diagonals in a polygon triangle is 0.

For n = 4 we have quadrilateral. It has 2 diagonals. Therefore, the number of diagonals in a polygon quadrilateral is 2.

For n = 5, we have a pentagon with 5 diagonals. Therefore, the number of diagonals in a polygon pentagon is 5.

For n = 6, n-polygon is called hexagon and it has 9 diagonals. Therefore, the number of diagonals in a polygon hexagon is 9.

Since n was a lower number we could easily draw the diagonals of n-polygons and then count the number of diagonals in a polygon.

Diagonals in Real Life

Diagonals in rectangles, as well as diagonals in squares, add toughness to construction, whether for a house wall, bridge, or tall building. You may have seen diagonal wires used to keep the bridges steady. When houses are being built, look for the diagonal braces that tend to hold the walls straight and true.

Bookshelves and scaffolding are braced with diagonals. For a catcher in softball or for a catcher in baseball to throw out a runner at second base, the catcher throws along a diagonal from home plate to second.

The phone screen or computer screen you are viewing this lesson on is measured along its diagonal. A 21" screen never tells you the width and height of the screen; it is 21" from one corner to an opposite corner.

Diagonal Formulas

1) Diagonal of a Rectangle Formula:

Diagonal of a Rectangle = \[\sqrt{l^{2} + b^{2}}\]

For rectangles, l is the length of the rectangle and b is the breadth of the rectangle.

2) Diagonal of a Square Formula:

Now let's look at a few different diagonal formulas to find the length of a diagonal of a square.

Diagonal of a Square = \[a\sqrt{2}\]

For squares, a is the side of a square

3) Diagonal of a Cube Formula:

For any given cube, we find the diagonal by using a three-dimensional version of the Pythagorean Theorem/distance formula:

Diagonal of a cube = \[\sqrt{s^{2} + s^{2} + s^{2}}\]

For cubes, s is the side of a cube

Important Note

The above-given formula gives us the number of distinct diagonals - that is, the number of actual line segments. At times it is easy to miscount the diagonals of a polygon when doing it by eye.

If you glance quickly at the pentagon given below, you may be tempted to say that the number of diagonals is 10. After all, there are 2 at each vertex and 5 vertices. Few people watch them making 3 triangles, for 6 diagonals. But there are only 5 diagonals. You need to count them carefully.

Solved Examples

Question 1) Find the total number of diagonals contained in an 11-sided regular polygon.

Solution) In an 11-sided polygon, total vertices are 11. Now, the 11 vertices can be joined with each other by C₂¹¹ ways i.e. 55 ways.

Now, there are a total of 55 diagonals possible for an 11-sided polygon which includes its sides also. So, subtracting the sides will give the total number of diagonals contained by the polygon.

So, total diagonals contained within an 11-sided polygon = 55 -11 which is equal to 44.

Formula Method:

According to the formula, the number of diagonals equals \[\frac{n(n-3)}{2}\].

So, 11-sided polygon will contain 11(11-3)/2 = 44 diagonals.

FAQs on Polygon Diagonals Explained: Formula, Calculation & Uses

1. What is the basic definition of a polygon in geometry?

A polygon is a two-dimensional closed shape made up of straight line segments. To be a polygon, a figure must be enclosed, and its sides cannot be curved. The simplest polygon is a triangle, which has three sides. Other examples include quadrilaterals (4 sides), pentagons (5 sides), and hexagons (6 sides).

2. What exactly is a diagonal of a polygon?

A diagonal is a line segment that connects two non-adjacent vertices of a polygon. Vertices are the corners where the sides meet. A diagonal passes through the interior of the polygon, unlike a side, which forms the boundary of the shape. For example, in a square, a line drawn from the top-left corner to the bottom-right corner is a diagonal.

3. How do you calculate the total number of diagonals in a polygon with 'n' sides?

You can calculate the number of diagonals in any polygon using a simple formula. If a polygon has 'n' sides (or 'n' vertices), the total number of diagonals is given by: Number of Diagonals = n(n-3)/2. This formula works for any polygon with more than three sides.

4. Why does a triangle have no diagonals?

A triangle has no diagonals because all of its vertices are adjacent to each other. A diagonal must connect two non-adjacent vertices. In a triangle, any vertex you pick is directly connected to the other two vertices by sides. There are no non-adjacent pairs of vertices to connect, so no diagonals can be drawn. Using the formula with n=3 gives: 3(3-3)/2 = 0.

5. How many diagonals does a hexagon have? Show the calculation.

A hexagon has 6 sides, so n=6. To find the number of diagonals, we use the formula n(n-3)/2:

Substitute n=6 into the formula: 6(6-3)/2
Solve the parenthesis: 6(3)/2
Multiply the numbers: 18/2
Divide to get the final answer: 9

Therefore, a hexagon has 9 diagonals.

6. How is the formula for the number of diagonals, n(n-3)/2, derived?

The formula is derived from principles of combinations. Here's the logic:

A polygon with 'n' vertices has 'n' points. The total number of lines you can draw between any two points is nC2, which equals n(n-1)/2.
This total includes both the sides of the polygon and its diagonals.
The number of sides is 'n'.
Therefore, to find only the diagonals, you subtract the number of sides from the total number of possible lines: Diagonals = [n(n-1)/2] - n.
Simplifying this expression gives n(n-3)/2, which is the standard formula.

7. Do all diagonals of a polygon lie inside it?

Not always. This property depends on whether the polygon is convex or concave.

In a convex polygon, all interior angles are less than 180°, and all diagonals lie completely inside the figure. Examples include regular squares, pentagons, and hexagons.
In a concave polygon, at least one interior angle is greater than 180° (a reflex angle). This causes at least one diagonal to lie partially or fully outside the polygon.

8. What is the fundamental difference between a side and a diagonal of a polygon?

The key difference lies in the vertices they connect. A side of a polygon connects two adjacent (or consecutive) vertices, forming the boundary of the shape. In contrast, a diagonal connects two non-adjacent (or non-consecutive) vertices, passing through the polygon's interior (in convex polygons).

9. Which common types of quadrilaterals have diagonals of equal length?

In the family of quadrilaterals, two common types are known for having diagonals of equal length:

Rectangles: By definition, the diagonals of a rectangle are always equal.
Squares: Since a square is a special type of rectangle, its diagonals are also equal in length. They also have the additional property of being perpendicular bisectors of each other.

While a rhombus has diagonals that are perpendicular, they are not typically equal in length unless the rhombus is also a square.

10. Can you give a real-world example where polygon diagonals are important?

A great real-world example is in construction and structural engineering. When building a rectangular frame for a wall or a gate, it can be flimsy. To make it rigid and prevent it from collapsing into a parallelogram, a diagonal brace is added. This brace acts as a diagonal, effectively creating two triangles within the frame. Since triangles are rigid shapes, the diagonal adds immense stability to the entire structure.