College Mathematics Lecture Notes, Section 5.1

College Mathematics NotesSection 5.1Page 1 of 16

Chapter 5: Geometry

Section 5.1: Plane geometry

Big Idea:Conversion between Metric and English units are a necessary evil until all the world abandons their private units of measurement for the metric system.

Big Skill: You should be able to convert between the systems.

Basic Facts About Points and Lines:

• Two different points define one and only one line that passes through both of them
• We shall use capital letters such as A to label points and a pair of letters such as AB to label the segment of the line between A and B.
• Line segments are measured in units of length such as feet or meters.
• The shortest distance between the two points is along the line passing through them.
• Two lines in a plane either meet (or “intersect”) at a single point or are parallel, meaning that the two lines never touch.
• Where the lines meet four “openings” or angles are formed as shown below. The symbol is used for the word angle. ( See figure below )

Angles

Thevertex of an angle is the common point shared by the two line segments or lines that form the sides of the angle.

One way to name angles is to write the “angle symbol” , then the name for a point on one side, the name for the vertex, and then the name of a point on the other side.

Thus BAD is the angle with vertex at A and with sides that include segments AB and AD .

This same angle could also be labeled as DAB .

Another way is to write the angle symbol, and then a single letter or number, like1in the above diagram.

Measuring Angles

• The most common unit for measuring angles is called the degree.
• The symbol for the degree is: 
• The Babylonians decided that there are 360 degrees (360) in one full rotation.
• A right angle is one-fourth of a full rotation and measures 90.
• A straight angle is one-half of a full rotation and measures 180.

• An angle between 0 and 90 is called an acute angle.
• An angle between 90 and 180 is called an obtuse angle.

Complementary and Supplementary Angles

• Complementary angles have measures that add up to 90.

• Supplementary angles have measures that add up to 180.

Practice:

1. Find the complement and supplement of an angle measuring 38.

1. Find  in the picture below.

1. Find  in the picture below.

Fractions of a Degree

• An old-school technique for talking about angle measures less than a degree is to subdivide the degree in the same way we subdivide time: into minutes and seconds.
• One minute of angle is one-sixtieth of a degree:
• One second of angle is one-sixtieth of a minute:
• Example of an angle measurement stated in degrees, minutes, and seconds (DMS):

Converting from degrees, minutes, and seconds (DMS) to decimal degrees (DD)

• Example: convert to DD
• Divide the number of second by sixty to convert it to an equivalent number in minutes.
• Add that to the number of minutes, then divide by sixty again to convert to an equivalent number in degrees.
• Add that number to the number of degrees, and round to an appropriate number of places:
• Note that . Thus, stating DMS measurements to the nearest thousandth of a degree won’t result in much round-off error, but stating your answer beyond a ten-thousandth of a degree implies a precision not conveyed by mere seconds.
• Note: on a graphing calculator, you can type in a DMS measurement using the degree and minute symbols found in the ANGLE menu, and the quotation marks for the seconds.

Practice:

1. Convert 992247 to DD.

1. 1574839 + 953642 =

1. Find the complement of an angle measuring 381218.

Converting from decimal degrees (DD) to degrees, minutes, and seconds (DMS)

• Example: convert to DMS
• Multiply the decimal portion by sixty to convert it to an equivalent number in minutes.
• Multiply the resulting decimal portion by sixty again to convert to an equivalent number in seconds.
• Round to an appropriate number of places:
• Note: on a graphing calculator, you can type in a DD measurement and convert it to a DMS measurement using the DMS function found in the ANGLE menu.

Practice:

1. Convert 22.128 to DMS.

When two lines intersect, the angles that are opposite each other are equal. These equal angles formed by two intersecting lines are called vertex ( or vertical ) angles.

Practice:

1. Find the angles in the diagram below.

Parallel lines lie in the same plane and do not intersect.

• Picture:

A transversal is a line that intersects two parallel lines.

• Picture:

• Different angles formed by the transversal are given special names to reflect special relationships between their measures:
• Corresponding angles are on the same side of the transversal and on the same corresponding sides of the parallel lines. Corresponding angles have equal measures
• Picture:

• Alternate interior angles have equal measures.
• Picture:

• Alternate exterior angles have equal measures.

• Interior angles on the same side of the transversal are supplementary (add to 180).
• Picture:

Practice:

1. Find all angle measures on the diagram below.

Polygons

Polygons are closed figures in the plane whose sides are line segments.

Triangles

The simplest polygon is the three-sided triangle. The points at the corners A , B , and C are the vertices of the triangle, and the angles BAC , BCA , and ABC are called the interior angles of the triangle. The triangle is often then labeled as triangle ABC .

Important Fact:

The interior angles of a triangle always add up to to.

Practice:

1. Find all angle measures on the diagram below.

1. Find all angle measures on the diagram below.

Types of Triangles

Triangles are classified according to their angles and sides.

• Angle classifications:
• Acute triangles have all angles less than 90.

• Right triangles have one angle of 90.

• Obtuse triangles have one angle greater than 90.

• Side classifications:
• Equilateral triangles have all sides the same length. Also, all angles are 60.

• Isosceles triangles have two sides of the same length, and the angles opposite those two sides are equal.

• Scalene triangles have no sides of the same length.

Congruent triangles have all the same side lengths and all the same angles.

Congruent is the proper way to say that two triangles are “equal” or “the same”. We use the word congruent because there are really six measurements that have to be equal for two triangles to be the same: the three angle measurements, and the three side length measurements.

Pictures:

Despite the fact that all three angles and all three sides have to be the same for triangles to be congruent, there are three shortcut rules for determining congruency. In each of these rules, only 3 of the 6 measurements have to be the same and then the other three end up being equal as a result of the geometry of triangles. The three rules for congruency when using triangles:

Side Angle Side ( abbreviated SAS) ,

Angle Side Angle ( abbreviated ASA ), and

Side Side Side ( abbreviated SSS ).

In the diagram shown, the hypotenuse is c and the legs are a and b . The two acute (less than ) angles are 1 and 2 with 1 opposite to the side of length a and 2 opposite to the

The Pythagorean Theorem: .

To calculate a leg, say a, knowing the hypotenuse and the other leg, b, rearrange the formula to

or.

Remember the square root symbol is also a grouping symbol. Parantheses need to be used!

Practice: Find the hypotenuse of the right triangle pictured below.

Practice:

Other Polygons ( Polygons with more than 3 sides )

• The sum of the interior angles of a quadrilateral (on the left) is 360 because any quadrilateral can be sub-divided into two triangles, and 2(180) = 360.
• The sum of the interior angles of a pentagon (on the right) is 540 because any pentagon can be sub-divided into three triangles, and 3(180) = 540.
• In general, if a polygon has n sides, then the sum of the interior angles is (n – 2)(180).

Practice:

1. What do you get when you add up all of the interior angles in a 7 sided polygon?

1. What do you get when you add up all of the interior angles in a 100 sided polygon?

Perimeter and Area

Perimeter is the total linear distance around the boundary of a polygon (or any closed shape).

Area is the number of unit squares of measurement it takes to fill a closed shape.

Practice:

1. Compute the perimeter of the pentagon shown below.

1. Compute the perimeter of the rectangle below.

1. Derive a formula for the perimeter of a rectangle.

1. If a STOP sign measures 8.0 on one side, compute its perimeter.

1. The area of a rectangle, is given by . Compute the area of the rectangle below.

Area and Peremiter of a Parallelogram

• A parallelogram is a four sided polygon (or quadralateral) with opposite sides parallel.
• All squares and rectangles are parallelograms, but a general parallelogram does not have to have angles.

• The easiest formula for the area of a parallelogram arises when you measure the length of one side (b in the diagram below), and the perpendicular height from side to the opposite side (h in the diagram below).
• Then,
• The diagram below also shows where the formula comes from; if you chop off a triangle from the left0hand side, then turn it upside down and paste it on the right hand side, a perfect rectangle is formed.

Area and Perimeter of a Triangle

• One easy formula for the area of a triangle comes from measuring one side (the base bin the picture below), and the perpendicular height (hin the picture below) from the base to the top vertex.

• If you glue a copy of the triangle to itself, a parallelogram is formed.

• Since the parallelogram has the are of two of the original triangles:
• .
• Another formula for the area of a triangle with sides a , b , and c is Heron’s formula:
• , where .

Practice:

1. Compute the area and perimeter of the following triangle.

Area and Perimeter of a Trapezoid

A quadrilateral with two opposite sides parallel is called a trapezoid. Suppose that the two parallel faces have lengths a and b and are separated by a perpendicular distance h .

Imagine making an exact copy of this trapezoid and joining it to the original trapezoid as shown.

The result is a parallelogram of base a + b and height h . Since the area of the original trapezoid is half of the area of this parallelogram, we arrive at the result that the area of a trapezoid is given by the folowing formula:

1. Calculate the perimeter and area of the following trapezoid.

Circles

A circle is formed by generating all points in a plane which are a fixed distance called the radius from a center point here labeled as C. A line segment with end points on the circle that passes through the center is called a diameter. D and r symbolize the lengths of the diameter and radius, respectively.

Since AC = CB = r and D = AB = AC + CB = 2r , we have the following formulas:

and.

Circumference (i.e., perimeter) of a circle:

Area of a Circle:

1. Compute the circumference and area of a circle of diameter 2.500 cm.