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Drawing lines and quadrilaterals

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visibility 139update 8 months agobookmarkshare

🎯 In this topic you will

Draw quadrilaterals accurately
Draw perpendicular lines
Draw parallel lines

🧠 Key Words

protractor
perpendicular
parallel
quadrilateral
set square

Show Definitions

protractor: A semicircular or circular instrument marked in degrees, used to measure or draw angles.
perpendicular: Describes lines or segments that meet to form a right angle (90°).
parallel: Lines in the same plane that stay the same distance apart and never meet.
quadrilateral: A polygon with four sides and four interior angles.
set square: A right-angled triangular drawing tool with fixed angles (often 45–45–90 or 30–60–90) for drawing perpendicular/parallel lines.

1. Here is a line

This diagram shows how you can use a set square to draw a second line at $A$ that is perpendicular to the first line. Put one edge of the set square on the line. Draw along the other edge.

The next diagram shows how you can also use a protractor to draw the same line. Put the centre mark of the flat edge of the protractor at $A$ so that the $90^\circ$ marker is on the line. Draw along the flat edge of the protractor.

2. Here are a line and a point $B$.

This diagram shows how you can use a set square to draw a second line through $B$ that is perpendicular to the first line. Draw a line along the edge of it.

The next diagram shows how you can also use a protractor to draw the same line. Draw a line along the protractor’s flat edge, with the original line aligned with the $90^\circ$ mark.

3. Here is a line.

You want to draw a second line that is parallel to the first line. The lines must be $5\text{ cm}$ apart.

Draw a perpendicular line with a set square or a protractor. Measure $5\text{ cm}$.

Use a protractor to draw the parallel line, as shown.

You can also use a set square to draw the same line.

If you want to draw a quadrilateral, you need to know some of the sides and angles. You don’t need to know all of the sides and angles.

Worked example 5.6 shows you how to draw a quadrilateral using a ruler and a protractor.

📘 Worked example

This is a sketch of a quadrilateral.

Answer:

Draw a line whose length you know. Choose, for example, $AD$.

Place the protractor at vertex $A$. Draw a line at an angle of $130^\circ$. Measure $3\text{ cm}$ and label the end point of the line $B$.

Now put the protractor at $D$. Draw a line at an angle of $110^\circ$. Measure $6\text{ cm}$ and label the end point of the line $C$.

Now join points $B$ and $C$.

You did not need to know the angles at $B$ and $C$ or the length of $BC$.

Why this works. The quadrilateral is fully determined by two adjacent sides and their included angles: $AD=4\text{ cm}$, $AB=3\text{ cm}$, with angles $\angle DAB=130^\circ$ and $\angle ADC=110^\circ$, plus side $DC=6\text{ cm}$. Constructing from those data locates $B$ and $C$ uniquely; then $BC$ follows by joining the points.

If you start with $CD$ instead: Draw $CD=6\text{ cm}$. At $D$, draw the $110^\circ$ ray and measure $DA=4\text{ cm}$ to locate $A$. At $A$, draw the $130^\circ$ ray and measure $AB=3\text{ cm}$ to locate $B$. Finally join $B$ to $C$.

🧠 PROBLEM-SOLVING Strategy

Accurate Constructions with Ruler, Set Square & Protractor

Use these steps to draw perpendiculars, parallels, and quadrilaterals to scale.

Plan from knowns. Highlight all given lengths (e.g., $3\ \text{cm}$, $4\ \text{cm}$, $7.5\ \text{cm}$, $8\ \text{cm}$, $10.5\ \text{cm}$) and angles (e.g., $35^\circ$, $52^\circ$, $60^\circ$, $65^\circ$, $70^\circ$, $75^\circ$, $80^\circ$, $110^\circ$, $120^\circ$, $122^\circ$, $125^\circ$, $130^\circ$).
Perpendicular through a point on a line.
- Set square: place one edge flush with the line; draw along the other edge to get $90^\circ$.
- Protractor: put the centre on the point, align the baseline to the line, mark $90^\circ$, draw the ray.
Perpendicular from a point to a line. With the protractor centre at the point, align to the line and mark the two $90^\circ$ directions; draw the segment to meet the line at right angles and label the foot (e.g., $P$).
Parallel through a point.
- Sliding set-square: hold a ruler along the given line; slide the set square against it and draw through the point.
- Offset method (fixed gap): draw a perpendicular to the given line, measure the required separation (e.g., $5\ \text{cm}$) on the perpendicular, then draw a second perpendicular at that mark. The new line is parallel and at the correct distance.
Building a quadrilateral from side–angle data.
1. Draw a convenient base (e.g., $10.5\ \text{cm}$).
2. At each end, use the protractor to set the given base angles (e.g., $65^\circ$ and $80^\circ$).
3. Measure along the rays the adjacent side lengths (e.g., $7.5\ \text{cm}$ and $8\ \text{cm}$) to locate the next vertices.
4. Join the remaining pair of vertices to close the figure. For concave cases, ensure the interior angle (e.g., $122^\circ$) opens inward.
Reasoning checks.
- Straight line totals $180^\circ$; angles around a point total $360^\circ$.
- Opposite (vertical) angles are equal; corresponding/alternate angles are equal for parallel lines; co-interior angles sum to $180^\circ$.
- For a quadrilateral, interior angles sum to $360^\circ$. If three angles are $120^\circ$, the fourth would be $0^\circ$ (degenerate) — useful sanity check.
Accuracy tips. Work to within $\pm 1\ \text{mm}$ and $\pm 1^\circ$. Keep pencil sharp, read the correct protractor scale ($0^\circ$–$180^\circ$), and label as you go (e.g., $A,B,C,D$, $P$).

❓ EXERCISES

1. a. Make an accurate drawing of this line.

b. Draw a line at $B$ that is perpendicular to $AD$.

c. Draw a line at $C$ that is perpendicular to $AD$.

d. Your lines from parts $b$ and $c$ should be parallel. Are they?

👀 Show answer

b. Through $B$, draw a line making a right angle $90^\circ$ with $AD$.

c. Through $C$, draw a line making a right angle $90^\circ$ with $AD$.

d.Yes. Two lines that are both perpendicular to the same line $AD$ are parallel.

2. a. Make an accurate drawing of this diagram.

b. Draw a perpendicular line from $X$ to line $YZ$. Label the intersection as $P$.

c. Measure: i.$XP$ ii.$YP$

d. Compare your answers to part $c$ with a learner’s answers. Do you have the same answers? If not, check your accuracy.

👀 Show answer

a–b. Recreate the angle at $Y$ with measure $52^\circ$, lengths $YX=6\text{ cm}$ and $YZ=7\text{ cm}$. From $X$, drop a perpendicular to line $YZ$ to meet it at $P$.

c. In right triangle $\triangle XYP$, the angle at $Y$ is $52^\circ$ and the hypotenuse is $XY=6\text{ cm}$. Therefore
$XP = XY\sin 52^\circ \approx 6\times \sin 52^\circ \approx 4.7\text{ cm}$,
$YP = XY\cos 52^\circ \approx 6\times \cos 52^\circ \approx 3.7\text{ cm}$.
(Your ruler measurements should be close to these values.)

d. If your values differ, recheck the angle $52^\circ$, the lengths $6\text{ cm}$ and $7\text{ cm}$, and that $XP \perp YZ$.

❓ EXERCISES

3. a. Make an accurate drawing of this diagram. The length of $PC$ is $4.5\ \text{cm}$.

b. Draw a line through $P$ that is parallel to $AB$.

👀 Show answer

a. Draw $PC$ of length $4.5\ \text{cm}$. At $C$, construct the given angle (e.g., $63^\circ$) to form line $CB$; place $A$ on the same slanted line as shown.

b. Through $P$, draw a line making the same angle with $PC$ as $AB$ does (or use a set square). This line is parallel to $AB$.

4. a. Make an accurate drawing of this quadrilateral.

b. Measure $CD$.

c. The length of $CD$ should be $13.3\ \text{cm}$. Is your measurement in part $b$ close to $13.3\ \text{cm}$? If not, check your drawing.

👀 Show answer

a. Draw $AB=6.9\ \text{cm}$. At $A$ construct $120^\circ$ and mark $AD=5.1\ \text{cm}$. At $B$ construct $110^\circ$ and mark $BC=8.2\ \text{cm}$. Join $C$ to $D$.

b–c. Measure $CD$. A correct drawing gives approximately $CD \approx 13.3\ \text{cm}$. If not, recheck lengths and angles.

5. This diagram has two pairs of parallel lines.

a. Make an accurate drawing of the diagram.

b. Draw the line $AC$ and measure the length of this line.

c. The length of $AC$ should be $5.4\ \text{cm}$. Is your measurement in part $b$ close to $5.4\ \text{cm}$? If not, check your drawing.

👀 Show answer

a. Reproduce the two horizontal parallel lines and the two slanted parallel lines with the given distances and angle.

b–c. Draw diagonal $AC$ and measure. A correct construction gives $AC \approx 5.4\ \text{cm}$.

6. Three angles of a quadrilateral are $60^\circ$, $75^\circ$ and $130^\circ$.

a. Calculate the fourth angle of the quadrilateral.

b. Draw a quadrilateral with these four angles. The $60^\circ$ angle must be opposite the $75^\circ$ angle, as shown in this diagram.

c. Draw a different quadrilateral with the same four angles. This time put the $60^\circ$ angle opposite the $130^\circ$ angle.

👀 Show answer

a. Sum of interior angles of a quadrilateral is $360^\circ$.
Fourth angle $= 360^\circ - (60^\circ 75^\circ 130^\circ) = 360^\circ - 265^\circ = 95^\circ$.

b. Use any side lengths; fix vertices so that opposite angles are $60^\circ$ and $75^\circ$. (Construct with a protractor and join in order.)

c. Repeat with opposite angles $60^\circ$ and $130^\circ$. Check that each vertex angle matches one of $\{60^\circ, 75^\circ, 95^\circ, 130^\circ\}$ and that the polygon closes.

❓ EXERCISES

7. Try to draw a quadrilateral where three of the angles are $120^\circ$. What happens? Why?

👀 Show answer

The interior angles of a quadrilateral add to $360^\circ$. If three angles are $120^\circ$, their sum is $3\times120^\circ=360^\circ$, leaving the fourth angle as $0^\circ$. A $0^\circ$ angle is impossible in a proper quadrilateral—the sides at that vertex become collinear and the shape collapses. So you cannot draw a non-degenerate quadrilateral with three angles of $120^\circ$.

🧠 Think like a Mathematician

8.a. Make an accurate drawing of this quadrilateral.

b. You were given the size of every side and angle. Did you need all this information to draw the quadrilateral? What is the least number of measurements you need to draw the quadrilateral accurately?

c. Describe the least set of measurements you need in general to draw a quadrilateral accurately.

👀 show answer

a. One accurate method:
1. Draw the base of length $10.5\ \text{cm}$.
2. At the left end, construct an angle of $65^\circ$ and mark the adjacent side of length $7.5\ \text{cm}$.
3. At the right end, construct an angle of $80^\circ$ and mark the adjacent side of length $8\ \text{cm}$.
4. Join the two new endpoints to complete the quadrilateral (the top side will come out close to $6\ \text{cm}$ and the top-left angle close to $125^\circ$).
b.No. You don’t need all seven numbers. The least number is five independent measurements. For this figure, one convenient minimal set is: base $10.5\ \text{cm}$, adjacent sides $7.5\ \text{cm}$ and $8\ \text{cm}$, and the two base angles $65^\circ$ and $80^\circ$.
c. In general a quadrilateral is fixed (up to congruence) by five independent measurements. Useful choices include:
- one side, the two adjacent sides, and the two angles at the ends of that side; or
- the four sides and one diagonal; or
- three sides and two included angles arranged so the construction closes.

❓ EXERCISES

9. Use the measurements shown to make an accurate drawing of this quadrilateral.

👀 Show answer

Draw a base segment of length $8\text{ cm}$ as shown (left vertex to lower-right tip).
At the lower-right tip, construct an interior angle of $35^\circ$ above the base and draw a ray along that direction.
From the left vertex, draw the upper side of length $8\text{ cm}$ to the top tip.
At the top tip, construct an interior angle of $35^\circ$ opening downwards/right and draw a ray.
Adjust the two rays so that they meet; the included angle at their intersection is $122^\circ$. Mark this meeting point as the re-entrant (inside) vertex.
Join the intersection point to the two tips to complete the quadrilateral. Check: two sides are $8\text{ cm}$, the small tip angles are each $35^\circ$, and the interior angle between the two inner edges is $122^\circ$.

📘 What we've learned

How to draw perpendicular lines using a set square or protractor (align and mark $90^\circ$).
How to draw a line parallel to a given line, including the fixed-distance method via a perpendicular offset (e.g., $5\ \text{cm}$).
Angle facts at an intersection: vertically opposite angles are equal; adjacent (linear pair) sum to $180^\circ$.
Angle facts with parallel lines cut by a transversal: corresponding and alternate interior angles are equal; co-interior angles sum to $180^\circ$.
Sums of angles: on a straight line $180^\circ$ and around a point $360^\circ$.
Interior angles of any quadrilateral add to $360^\circ$; three angles of $120^\circ$ force the fourth to be $0^\circ$ (degenerate), so such a quadrilateral is impossible.
Practical construction of quadrilaterals from side–angle data using ruler and protractor (e.g., build from a known base and two base angles/side lengths).
That a quadrilateral can be fixed by about five independent measurements (e.g., one side, the two adjacent sides, and the two end angles).
How to use right-triangle trigonometry or measurement to check lengths dropped perpendicular to a line (e.g., find $XP$ and $YP$ with a known angle and side).
Checked accuracy by comparing measured results against expected values (e.g., diagonals/segments close to target lengths).

Drawing lines and quadrilaterals

🎯 In this topic you will

🧠 Key Words

🧠 PROBLEM-SOLVING Strategy

Accurate Constructions with Ruler, Set Square & Protractor

❓ EXERCISES

❓ EXERCISES

❓ EXERCISES

🧠 Think like a Mathematician

❓ EXERCISES

📘 What we've learned

Related Past Papers

Related Tutorials

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