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Straightedge and Compass Constructions

Objective

In this lesson, you will study definitions for the following objects: complementary and supplementary angles, angle bisectors, and perpendicular bisector of a line segment. You will also construct these objects using a straightedge and compass.

Previously Covered:

If two lines are cut by a transversal and any pair of alternate interior angles is congruent, then the lines are parallel.

What are the theorems involving parallel and perpendicular lines?

Existence and Uniqueness of Parallel Lines Let L be any line and P be a point not on L. Then there is
only one line containing P parallel to L. There is also an analogue to the theorem above for perpendicular lines.

- - Existence and Uniqueness of Perpendicular Lines
  - Let L be any line and P be a point not on L. Then there is only one line containing P perpendicular to L.

Although we may have implicitly referred to supplementary and complementary angles in previous sections, let us define them here for completeness.

If the sum of the measures of two angles is 180°, then the angles are called supplementary, and each angle is called the supplement of the other.

If the sum of the measures of two angles is 90°, then the angles are called complementary and each angle is called the complement of the other.

How do we construct an angle supplement?

In this section, we will be dealing with angles formed by rays, which are parts of a line that start at a point and extend infinitely in the other direction. Below, BAC is formed by the rays and . We’ll start off with the simplest construction— angle supplements.

$Angle formed by two rays$

Suppose we are given an angle BAC as above where mBAC < 180°. We can construct the supplement to BAC with the same vertex A using a straightedge.

Step 1: Extend the line containing the ray in the opposite direction using your straightedge.

Step 2: Choose a point D on this new ray.

$Supplementary Angle$

The angle DAC that we have just constructed is the supplementary angle to BAC because .

The angle bisector of BAC is the ray , such that BAD DAC. In other words, an angle bisector divides an angle into two congruent angles.

$Supplementary Angle$

How do we construct an angle bisector of a given angle?

Suppose we are given A.

Step 1: Using A as a center we draw an arc of a circle intersecting the two sides of the angle. Label these points B and C. The segments and are congruent (these are both radii of the circle).

$Angle A with circle intersecting the two sides$

Step 2: Draw the circle with center B and radius r = BC.

$Angle A with two circles intersecting$

Step 3: Draw the circle with center C and radius r = BC.

$circle with center C and r=BC$

Step 4: These two circles will intersect at exactly two points. Choose the point on the other side of the segment BC and label this point P. Draw the ray originating at A through P. This ray is the angle bisector of BAC.

$Angle bisector of angle BAC$

Important Tidbit

In steps 2 and 3, we could have used any radius greater than . This ensures that the circles will intersect.

Let’s try an example. When constructing an angle on a given side of a ray congruent to a given A,
what is the minimum number of arcs (or circles) necessary to construct the angle?

$Construction of an angle$

The correct answer is 3. We need to draw the first arc on the given angle A to create a triangle ABC with congruent sides r = AB = AC and a third side BC = s.

$Angle Construction part 2$

We draw a circle of radius r with center D that intersects the given ray at a point E. This gives us one side of a triangle that will eventually be congruent to BAC.

$Construction of an angle Part 3$

Next, we draw a circle of radius s and center E. This intersects this first circle in two points, but we choose the one on the given side. The ray drawn through this point (F) creates the desired congruent triangle (by SSS), and thus the corresponding angles A and D we have constructed are also congruent.

$Angle Construction final step$

How do we construct a line parallel to a given line containing an external given point?

Suppose we are given a line L and a point P that is not on L. Let Q and R be any two points on L.

$Line L with point P$

Step 1: To construct a parallel line to point P, first draw the line .

$Line L and line PQ$

Step 2: We can draw angle QPS congruent to angle PQR on the opposite side of from R. These two angles, QPS and PQR, are alternate interior angles.

$Alternate interior angles$

Because these angles are congruent, the line is parallel to the line L.

How do we construct a perpendicular bisector?

The perpendicular bisector of a line segment is the line perpendicular to the segment at its midpoint.

Suppose we are given a line segment .

Step 1 : To construct a perpendicular bisector, first draw a circle with center B and radius r = AB.

$Circle with radius AB$

Step 2: Draw a circle with center at A and radius r = AB.

$Circle with center B and radius AB$

Step 3: The two circles intersect at two points on opposite sides of . Label these points P and Q. Draw .

$Two circles intersect at two points on opposite sides of AB$

PQ is equidistant from A and B, and is, therefore, the perpendicular bisector of .

How do we construct a line perpendicular to a given line containing an external given point?

The process of constructing a line perpendicular to a given line containing an external point is quite similar to the construction we have just completed. Basically, all we need to do is find the right segment to bisect. So let’s just do this one step.

Again suppose we are given a line L and a point P that is not on L. Draw a circle with center P and with large enough radius so that it intersects L in two points, Q and R . If we construct the perpendicular bisector of QR, the line passes through P, because P is equidistant from R and S. So by the previous construction, the perpendicular bisector of QR contains P and is perpendicular to L.

How do we construct an angle complement?

If you recall, we gave the definition of an angle complement at the very beginning of the section. This construction follows from work we’ve already practiced.

The construction of an angle complementary to a given A sharing the same vertex, A, is a corollary of the construction of a perpendicular bisector.

If we extend one ray of angle A to a line and create a segment BC, such that A is the midpoint of , then the perpendicular bisector of will give us a ray, AD, which creates the angle complement to angle A.

$Angle Complement$

How do we divide a given line segment into n congruent subsegments?

Suppose we are given a line segment that we wish to subdivide into n congruent subsegments. The figure below shows the case for n = 5.

$Line segment divided into n=5 subsegments$

Step 1: Draw any ray originating at the point A, but not containing B. Name this ray

Step 2: Draw an arc of a circle centered at A with positive radius r and intersecting L at a point P₁.

Step 3: Draw an arc of a circle centered at P₁with the same radius r and intersecting L at a point P₂.

Step 4: Repeat step 3 until you reach P_n. At this point you’ve drawn n congruent segments on L:P₁, P₁P₂, P₂P₃, . . . P_{n – 1}P_n.

Step 5: Using your straightedge, connect P_nto B.

Step 6: Through the other points P₁, P₂, . . .P_{n – 1}, draw lines parallel to P_nB, intersecting at points Q₁, Q₂,…Q_n–1, respectively.

Because the parallel lines intercept congruent segments on L, they intersect congruent segments on .

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