1-1 understanding points, lines, and...
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Name ________________________________________ Date __________________ Class__________________
Original content Copyright © by Holt McDougal. Additions and changes to the original content are the responsibility of the instructor.
1-6 Holt Geometry
Reteach Understanding Points, Lines, and Planes
A point has no size. It is named using a capital letter. All the figures below contain points.
Draw and label a diagram for each figure. 1. point W 2. line MN
3. JK 4. EF
Name each figure using words and symbols. 5. 6.
_________________________________________ ________________________________________
7. Name the plane in two different ways. 8.
_________________________________________ ________________________________________
LESSON
1-1
Figure Characteristics Diagram Words and Symbols
line 0 endpoints extends forever in two directions
line AB or AB
line segment or segment
2 endpoints
has a finite length
segment XY or XY
ray 1 endpoint
extends forever in one direction
ray RQ or RQ
A ray is named starting with its endpoint.
plane extends forever in all directions
plane FGH or plane V
•P point P
Name ________________________________________ Date __________________ Class__________________
Original content Copyright © by Holt McDougal. Additions and changes to the original content are the responsibility of the instructor.
1-7 Holt Geometry
Reteach Understanding Points, Lines, and Planes continued
Figures that intersect share a common set of points. In the first model above, FH intersects FG at point F. In the second model, XZ intersects plane WXY at point X.
Use the figure for Exercises 9–14. Name each of the following.
9. three collinear points 10. three noncollinear points
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11. four coplanar points 12. four noncoplanar points
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13. two lines that intersect CD 14. the intersection of JK and plane R
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LESSON
1-1
Term Meaning Model
collinear points that lie on the same line
noncollinear points that do not lie on the same line
F and G are collinear. F, G, and H are noncollinear.
coplanar points or lines that lie in the same plane
noncoplanar points or lines that do not lie in the same plane
W, X, and Y are coplanar. W, X, Y, and Z are noncoplanar.
Name ________________________________________ Date __________________ Class__________________
Original content Copyright © by Holt McDougal. Additions and changes to the original content are the responsibility of the instructor.
1-14 Holt Geometry
Reteach Measuring and Constructing Segments
The distance between any two points is the length of the segment that connects them.
The distance between E and J is EJ, the length of EJ . To find the distance, subtract the numbers corresponding to the points and then take the absolute value.
EJ = |7 − 1|
= |6| = 6 cm
Use the figure above to find each length. 1. EG 2. EF 3. FH
________________________ _________________________ ________________________
On PR , Q is between P and R. If PR = 16, we can find QR. PQ + QR = PR 9 + x = 16 x = 7 QR = 7
4. 5.
Find JK. ______ Find BC. ______
6. 7.
Find SV. ______ Find XY. ______
8. 9.
Find DF. ______ Find ST. ______
LESSON
1-2
Name ________________________________________ Date __________________ Class__________________
Original content Copyright © by Holt McDougal. Additions and changes to the original content are the responsibility of the instructor.
1-15 Holt Geometry
Reteach Measuring and Constructing Segments continued
Segments are congruent if their lengths are equal.
AB = BC The length of AB equals the length of BC .
AB BC≅ AB is congruent to BC .
Refer to triangle ABC above for Exercises 10 and 11.
10. Sketch LM that is congruent to AC . 11. Use a ruler to draw XY that is congruent
to BC .
12. Use a compass to construct ST that is congruent to JK .
The midpoint of a segment separates the segment into two congruent segments. In the figure, P is the midpoint of NQ .
13. PQ is congruent to _______________.
14. What is the value of x? _______________
15. Find NP, PQ, and NQ. _______________
LESSON
1-2
Copying a Segment
Method Steps
sketch using estimation Estimate the length of the segment. Sketch a segment that is about the same length.
draw with a ruler Use a ruler to measure the length of the segment. Use the ruler to draw a segment having the same length.
construct with a compass and straightedge
Draw a line and mark a point on it. Open the compass to the length of the original segment. Mark off a segment on your line at the same length.
Name ________________________________________ Date __________________ Class__________________
Original content Copyright © by Holt McDougal. Additions and changes to the original content are the responsibility of the instructor.
1-22 Holt Geometry
Reteach Measuring and Constructing Angles
An angle is a figure made up of two rays, or sides, that have a common endpoint, called the vertex of the angle.
There are four ways to name this angle. ∠Y Use the vertex. ∠XYZ or ∠ZYX Use the vertex and a point on each side. ∠2 Use the number.
Name each angle in three ways. 1. 2.
_________________________________________ ________________________________________
3. Name three different angles in the figure.
_________________________________________
Angle acute right obtuse straight
Model
Possible Measures 0° < a° < 90° a° = 90° 90° < a° < 180° a° = 180°
Classify each angle as acute, right, obtuse, or straight. 4. ∠NMP
_________________________________________
5. ∠QMN
_________________________________________
6. ∠PMQ
_________________________________________
LESSON
1-3
Name ________________________________________ Date __________________ Class__________________
Original content Copyright © by Holt McDougal. Additions and changes to the original content are the responsibility of the instructor.
1-23 Holt Geometry
Reteach Measuring and Constructing Angles continued
You can use a protractor to find the measure of an angle.
Use the figure above to find the measure of each angle. 7. ∠DEG 8. ∠GEF
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The measure of ∠XVU can be found by adding.
m∠XVU = m∠XVW + m∠WVU
= 48° + 48°
= 96° Angles are congruent if their measures are equal. In the figure, ∠XVW ≅ ∠WVU because the angles have equal measures. VW is an angle bisector of ∠XVU because it divides ∠XVU into two congruent angles.
Find each angle measure.
9. m∠CFB if ∠AFC is a straight angle. 10. m∠EFA if the angle is congruent to ∠DFE.
_________________________________________ ________________________________________
11. m∠EFC if ∠DFC ≅ ∠AFB. 12. m∠CFG if FG is an angle bisector of ∠CFB.
_________________________________________ ________________________________________
LESSON
1-3
∠DEG is acute.
∠GEF is obtuse.
Name ________________________________________ Date __________________ Class__________________
Original content Copyright © by Holt McDougal. Additions and changes to the original content are the responsibility of the instructor.
1-30 Holt Geometry
Reteach Pairs of Angles
Tell whether ∠7 and ∠8 in each figure are only adjacent, are adjacent and form a linear pair, or are not adjacent. 1. 2. 3.
________________________ _________________________ ________________________
Tell whether the indicated angles are only adjacent, are adjacent and form a linear pair, or are not adjacent.
4. ∠5 and ∠4_____________________________
5. ∠1 and ∠4_____________________________
6. ∠2 and ∠3_____________________________
Name each of the following.
7. a pair of vertical angles __________________
8. a linear pair ___________________________
9. an angle adjacent to ∠4 __________________
Angle Pairs
Adjacent Angles Linear Pairs Vertical Angles
have the same vertex and share a common side
adjacent angles whose noncommon sides are opposite rays
nonadjacent angles formed by two intersecting lines
∠1 and ∠2 are adjacent.
∠3 and ∠4 are adjacent and form a linear pair.
∠5 and ∠6 are vertical angles.
LESSON
1-4
Name ________________________________________ Date __________________ Class__________________
Original content Copyright © by Holt McDougal. Additions and changes to the original content are the responsibility of the instructor.
1-31 Holt Geometry
Reteach Pairs of Angles continued
Tell whether each pair of labeled angles is complementary, supplementary, or neither. 10. 11.
_________________________________________ ________________________________________
Find the measure of each of the following angles.
12. complement of ∠S ______________________
13. supplement of ∠S ______________________
14. complement of ∠R ______________________
15. supplement of ∠R ______________________
16. ∠LMN and ∠UVW are complementary. Find the measure of each angle if m∠LMN = (3x + 5)° and m∠UVW = 2x°.
_________________________________________________________________________________________
Angle Pairs
Complementary Angles Supplementary Angles
sum of angle measures is 90° sum of angle measures is 180°
m∠1 + m∠2 = 90°
In each pair, ∠1 and ∠2 are complementary.
m∠3 + m∠4 = 180° In each pair, ∠3 and ∠4 are supplementary.
LESSON
1-4
Name ________________________________________ Date __________________ Class__________________
Original content Copyright © by Holt McDougal. Additions and changes to the original content are the responsibility of the instructor.
1-38 Holt Geometry
Reteach Using Formulas in Geometry
The perimeter of a figure is the sum of the lengths of the sides. The area is the number of square units enclosed by the figure.
Find the perimeter and area of each figure. 1. rectangle with = 4 ft, w = 1 ft 2. square with s = 8 mm
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3. 4.
_________________________________________ ________________________________________
The perimeter of a triangle is the sum of its side lengths. The base and height are used to find the area.
Perimeter Area
P = a + b + c A = 12
bh or 2
bh
Find the perimeter and area of each triangle. 5. 6.
_________________________________________ ________________________________________
LESSON
1-5
Figure Rectangle Square
Model
Perimeter P = 2 + 2w or 2( + w) P = 4s
Area A = w A = s2
Name ________________________________________ Date __________________ Class__________________
Original content Copyright © by Holt McDougal. Additions and changes to the original content are the responsibility of the instructor.
1-39 Holt Geometry
Reteach Using Formulas in Geometry continued
C = 2πr A = πr
2
C = 2π(4) A = π(4)2
C = 8π A = 16π
C ≈ 25.1 m A ≈ 50.3 m2
Find the circumference and area of each circle. Use the π key on your calculator. Round to the nearest tenth. 7. circle with a radius of 11 inches 8. circle with a diameter of 15 millimeters
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9. 10.
_________________________________________ ________________________________________
11. 12.
_________________________________________ ________________________________________
LESSON
1-5
Circles
Circumference Area
Models
Words pi times the diameter or 2 times pi times the radius
pi times the square of the radius
Formulas C = πd or C = 2πr A = πr 2
distance around the circle
space inside the circle
Name ________________________________________ Date __________________ Class__________________
Original content Copyright © by Holt McDougal. Additions and changes to the original content are the responsibility of the instructor.
1-46 Holt Geometry
Reteach Midpoint and Distance in the Coordinate Plane
The midpoint of a line segment separates the segment into two halves. You can use the Midpoint Formula to find the midpoint of the segment with endpoints G(1, 2) and H(7, 6).
1 2 1 2 1 7 2 6, ,2 2 2 2
x x y yM M+ + + +⎛ ⎞ ⎛ ⎞= ⎜ ⎟⎜ ⎟ ⎝ ⎠⎝ ⎠
= 8 8,2 2
M ⎛ ⎞⎜ ⎟⎝ ⎠
= M(4, 4)
Find the coordinates of the midpoint of each segment. 1. 2.
_________________________________________ ________________________________________
3. QR with endpoints Q(0, 5) and R(6, 7) __________
4. JK with endpoints J(1, –4) and K(9, 3) __________
Suppose M(3, −1) is the midpoint of CD and C has coordinates (1, 4). You can use the Midpoint Formula to find the coordinates of D.
1 2 1 2(3, 1) ,2 2
x x y yM M + +⎛ ⎞− = ⎜ ⎟⎝ ⎠
x-coordinate of D y-coordinate of D
1 232
x x+= Set the coordinates equal. −1 = 1 2
2y y+
2132x+
= Replace (x1, y1) with (1, 4). −1 = 242y+
6 = 1 + x2 Multiply both sides by 2. −2 = 4 + y2 5 = x2 Subtract to solve for x2 and y2. −6 = y2
The coordinates of D are (5, −6).
5. M(−3, 2) is the midpoint of RS , and R has coordinates (6, 0). What are the coordinates of S? _______________
6. M(7, 1) is the midpoint of WX , and X has coordinates (−1, 5). What are the coordinates of W ? _______________
LESSON
1-6
M is the midpoint of HG .
Name ________________________________________ Date __________________ Class__________________
Original content Copyright © by Holt McDougal. Additions and changes to the original content are the responsibility of the instructor.
1-47 Holt Geometry
Reteach Midpoint and Distance in the Coordinate Plane continued
The Distance Formula can be used to find the distance d between points A and B in the coordinate plane.
d = 2 22 1 2 1( ) ( )x x y y− + −
= 2 2(7 1) (6 2)− + − (x1, y1) = (1, 2); (x2, y2) = (7, 6)
= 2 26 4+ Subtract.
= 36 16+ Square 6 and 4.
= 52 Add.
≈ 7.2 Use a calculator.
Use the Distance Formula to find the length of each segment or the distance between each pair of points. Round to the nearest tenth.
7. QR with endpoints Q(2, 4) and R(−3, 9) 8. EF with endpoints E(−8, 1) and F(1, 1)
_________________________________________ ________________________________________
9. T(8, −3) and U(5, 5) 10. N(4, −2) and P(−7, 1)
_________________________________________ ________________________________________
You can also use the Pythagorean Theorem to find distances in the coordinate plane. Find the distance between J and K. c2 = a2 + b2 Pythagorean Theorem = 52 + 62 a = 5 units and b = 6 units = 25 + 36 Square 5 and 6. = 61 Add.
c = 61 or about 7.8 Take the square root.
Use the Pythagorean Theorem to find the distance, to the nearest tenth, between each pair of points. 11. 12.
_________________________________________ ________________________________________
LESSON
1-6
The distance d between points A and B is the length of AB .
Side a is 5 units.
Side b is 6 units.
Name ________________________________________ Date __________________ Class__________________
Original content Copyright © by Holt McDougal. Additions and changes to the original content are the responsibility of the instructor.
1-54 Holt Geometry
Reteach Transformations in the Coordinate Plane
In a transformation, each point of a figure is moved to a new position.
Identify each transformation. Then use arrow notation to describe the transformation. 1. 2.
_________________________________________ ________________________________________
3. 4.
_________________________________________ ________________________________________
LESSON
1-7
Reflection Rotation Translation
ABC → A′B′C′
JKL → J′K′L′
RST → R′S′T′
A figure is flipped over a line.
A figure is turned around a fixed point.
A figure is slid to a new position without turning.
Name ________________________________________ Date __________________ Class__________________
Original content Copyright © by Holt McDougal. Additions and changes to the original content are the responsibility of the instructor.
1-55 Holt Geometry
Reteach Transformations in the Coordinate Plane continued
Triangle QRS has vertices at Q(−4, 1), R(−3, 4), and S(0, 0). After a transformation, the image of the figure has vertices at Q′(1, 4), R′(4, 3), and S′(0, 0). The transformation is a rotation.
A translation can be described using a rule such as (x, y) → (x + 4, y −1).
Draw each figure and its image. Then identify the transformation. 5. Triangle HJK has vertices at H(−3, −1),
J(−3, 4), and K(0, 0). After a transformation, the image of the figure has vertices at H′(1, −3), J′(1, 2), and K′(4, −2).
_________________________________________
6. Triangle CDE has vertices at C(−4, 6), D(−1, 6), and E(−2, 1). After a transformation, the image of the figure has vertices at C′(4, 6), D′(1, 6), and E′(2, 1).
_________________________________________
Find the coordinates for each image after the given translation. 7. preimage: XYZ at X(−6, 1), Y(4, 0), Z(1, 3)
rule: (x, y) → (x + 2, y + 5) __________________________________ 8. preimage: FGH at F(9, 8), G(−6, 1), H(−2, 4)
rule: (x, y) → (x − 3, y + 1) __________________________________ 9. preimage: BCD at B(0, 2), C(−7, 1), D(1, 5)
rule: (x, y) → (x + 7, y − 1) __________________________________
Preimage Apply Rule Image
R(3, 5) R(3 + 4, 5 − 1) R′(7, 4)
S(0, 1) S(0 + 4, 1 − 1) S′(4, 0)
T(2, –1) T(2 + 4, −1 − 1) T ′(6, −2)
LESSON
1-7
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