Content.njctl.org



TransformationsTransformations: CLASSWORKTell whether the transformation appears to be a rigid motion. Explain. 1. 2. Preimage Image Preimage Image3. Identify the type of transformation. What is the image of segment FG?4. Identify the type of transformation. What is the image of angle J?Transformations: HOMEWORKTell whether the transformation appears to be a rigid motion. Explain. 1. 2.Preimage Image Preimage Image3. Identify the type of transformation. What is the image of segment QR?4. Identify the type of transformation. What is the image of angle T?Translations: CLASSWORKGraph the image of each figure under the given translation.1. T<–1, 4> (ΔABC)2. T<3, -3> (JKLM) 3. Write a rule to describe the translation. 4. If T<10, 7> (QRST) = Q′R′S′T’, what translation maps ′Q′R′S′T’ onto QRST?5. ΔXYZ has coordinates X(2, 3), Y(1, 4), and Z(8, 9). A translation maps X to X′(4, 8). What are the coordinates for Y′ and Z′ for this translation?6.Write three different translation rules for which the image of ΔABC has a vertex at the origin.Translations: HomeworkGraph the image of each figure under the given translation.1. T<3, -2> (ΔDEF) 2. T<-4, 0> (WXYZ) 3. Write a rule to describe the translation.4. If T<-4, 9> (ΔLMN) = ΔL’M’N’, what translation maps ΔL’M’N’ onto ΔLMN?5. ΔABC has coordinates A(2, 3), B(4, –2), and C(3, 0). After a translation thecoordinates of A′ are (6, –2). What are the coordinates of B′ and C′?6. Write three different translation rules for which the image of ΔBCD has a vertex at the origin.Reflections: CLASSWORKFor numbers 1-6 find the coordinates of each image. 1. Rx-axis (A)2. Ry-axis (B)3. Ry = x (C)4. Rx = 2 (D)5. Ry= -1 (E) 6. Rx = -3 (F)7. Given points A(3, 3), B(5, -2), and C(4, 4), graph ΔABC and its reflection image as indicated.a.Ry-axis (ΔABC) b. Rx-axis (ΔABC) c.Rx = 1(ΔABC) d.Ry = –2(ΔABC) Draw the line of reflection you can use to map one figure onto the other.8. 9.10. Find the image of J(-2, 1) after two reflections, first across line ?1, and then across line ?2. a. ?1 : x = 2, ?2 : y-axisb. ?1 : y = –1, ?2 : y-axisc. ?1 : y = 2, ?2 : x-axisd. ?1 : x = –1, ?2 : y = –311. Give an example of a place you may see a geometric reflection in everyday life. Explain. Identify all of the lines of symmetry for the given shape.12. 13. 14.15.16.17.Reflections: HOMEWORKFor numbers 1-6 find the coordinates of each image. 1. Rx-axis (A)2. Ry-axis (B)3. Ry = x (C)4. Rx = 3 (D)5. Ry= 2 (E) 6. Rx = -1 (F)7. Given points D(-2, 1), E(1, 3), and F(2, -2), graph ΔDEF and its reflection image as indicated.a.Ry-axis (ΔDEF) b. Rx-axis (ΔDEF) c.Rx = 2(ΔDEF) d.Ry = –1(ΔDEF) Draw the line of reflection you can use to map one figure onto the other.8. 9. 10. Find the image of K(4, -3) after two reflections, first across line ?1, and then across line ?2. a. ?1 : x = 2, ?2 : y-axisb. ?1 : y = –1, ?2 : y-axisc. ?1 : y = 2, ?2 : x-axisd. ?1 : x = –1, ?2 : y = –311. Give an example of a place you may see a geometric reflection in everyday life (Different than your classwork answer). ExplainIdentify all of the lines of symmetry for the given shape.12. 13. 14.15.16.17. Rotations: CLASSWORKDraw the image of each figure for the given rotation about P. Use prime notation to label the vertices of the image.r(-60°, P)(?ABC)2. r(85°, P)(?ABC) 3. Point O is the center of regular pentagon JKLMN. Find the image of the given point or segment for the given rotation. (counterclockwise)a.r(144°, O)(K)b.r(72°, O)(N)c.r(216°, O)(ML)d.r(360°, O)(JN)e.r(288°, O)(JO)4. ΔABC has vertices A(2, 2), B(3, – 2), and C(–1, 3).a. Graph r(270?, O)(?ABC). b. Graph r(180?, O)(?ABC). c. Graph r(90?, O)(?ABC).5.The vertices of ABCD have coordinates A(2, 6), B(-3, 4), C(-3, -5), andD(4, -2). What are the coordinates of the vertices of r (180?, O)(ABCD)?6.The vertices of r(270?, O) (DEFG) have coordinates D’(4, 5), E’(4, -3), F’(-2, -3), and G’(-2, 5). What are the coordinates of the vertices of DEFG?7.ABCD has vertices A(4, 2), B(–2, 2), C(–4, –2), and D(2, –2). Which of the following quadrilaterals is r(180?, O)(ABCD)?a. ABCDb. BCDAc. CDABd. DABC8. ?FGH has vertices F(–1, 2), G(0, 0), and H(3, – 1). What are the coordinates of the vertices of r(–270?, G)(?FGH)?Do the following figures have rotational symmetry? If yes, what is the degree of rotation?9.10.11.Rotations: HOMEWORK Draw the image of each figure for the given rotation about P. Use prime notation to label the vertices of the image.1. r(-90°, P)(?ABC)2. r(110°, P)(?ABC) 3. Point O is the center of regular hexagon ABCDEF. Find the image of the given point or segment for the given rotation. (counterclockwise)a.r(120°, O)(F)b.r(180°, O)(B)c.r(300°, O)(BC)d.r(360°, O)(FE)e.r(60°, O)(E)f.r(240°, O)(AB)4. Quadrilateral DEFG has vertices D(2, 3), E(4, -2), F(7, -2), and G(5, 2).a. Graph r(270?, O)(DEFG). b. Graph r(180?, O)(DEFG). c. Graph r(90?, O)(?DEFG).5.The vertices of PQRS have coordinates P(–1, 5), Q(3, 4), R(2, – 4), and S(–3, – 2). What are the coordinates of the vertices of r (90?, O)(PQRS)?6.The vertices of r(270?, O) (KLMN) have coordinates K’(–3, 2), L’(2, 3), M’(4, – 2), and N’(–2, – 4). What are the coordinates of the vertices of KLMN?7.The vertices of quadrilateral ABCD have coordinates A(4, 3), B(–3, 4), C(–4, – 3), and D(3, – 4). Explain how the transformation r(90?, O)(ABCD) = BCDA can be used to show that the quadrilateral is square.8. ?RST has vertices at R(0, 3), S(4, 0), and T(0, 0). What are the coordinates of the vertices of r(-270?,T)(?RST)?Do the following figures have rotational symmetry? If yes, what is the degree of rotation?9.10.positions of Transformations: CLASSWORKFind the image of each letter after the transformation Rm ? R?. Is the resulting transformation a translation or a rotation? For a translation, describe the distance and direction. For a rotation, tell the center of rotation and the angle of rotation. l 60? m P J 1. l2. K m For numbers 3 – 6 Graph ?ABC and its glide reflection image. A(-3, 3), B(0, 1) and C(-1,-4)3.(Ry-axis ○ T<3, 0>)(?ABC) 4.(Ry=1 ○ T<–1, 0>)(?ABC)5.(Rx=2 ○ T<0, 1>)(?ABC)6. (Ry=x ○ T<3, 3>)(?ABC)7. Lines ? and m intersect at point P and are perpendicular. If a point Q is reflected across ? and then across m, what transformation rule describes this composition?8. Graph AB and its image A’B’ after a reflection first across ?1 and then across ?2. Is the resulting transformation a translation or a rotation? For a translation, describe the direction and distance. For a rotation, tell the center of rotation and the angle of rotation.A(–3, 4), B(–1, 0);?1 : x = 1;?2 : y = –19. P maps to P′(2, 3) by the given glide reflection. What are the coordinates of P?(Rx-axis ? T <2, 1>)(P)Compositions of Transformations: HOMEWORKFind the image of each letter after the transformation Rm ? R?. Is the resulting transformation a translation or a rotation? For a translation, describe the distance and direction. For a rotation, tell the center of rotation and the angle of rotation.Nl m m A l K 1. 2. For numbers 3 – 6 Graph ?DEF and its glide reflection image. D(0, 2), E(2, 4) and F(4,0)3.(Rx-axis ○ T<2, 1>)(?DEF) 4. (Ry=2 ○ T<–3, 1>)(?DEF)5.(Rx=1 ○ T<0, -2>)(?DEF)6.. (Ry=x ○ T<2, 3>)(?DEF)7. A triangle is reflected across line ? and then across line m. If this composition of reflections is a translation, what is true about m and ??8. Graph AB and its image A’B’ after a reflection first across ?1 and then across ?2. Is the resulting transformation a translation or a rotation? For a translation, describe the direction and distance. For a rotation, tell the center of rotation and the angle of rotation.A(–5, 2), B(–3, 6); ?1 : x = –2;?2 : x = 39. P maps to P′(2, 3) by the given glide reflection. What are the coordinates of P?(Ry = x ? T <3, 3>)(P)Congruence Transformations: CLASSWORK?ABC ?DEF. What is a congruence transformation that maps ?ABC to ?DEF?1. 2. Identify a pair of congruent figures. Then determine a congruence transformation that maps the preimage to the congruent image.3. 4. Congruence Transformations: HOMEWORK?ABC ?DEF. What is a congruence transformation that maps ?ABC to ?DEF?1. 2. Identify a pair of congruent figures. Then determine a congruence transformation that maps the preimage to the congruent image.3. 4. Dilations: CLASSWORKA dilation has center (0, 0). Find the image of each point for the given scale factor.1.A(3, 4); D7(A)2.B(0, 4); D3.4(B)3.C(5, –6); D5/3(C)4.A square has 16-cm sides. Describe its image for a dilation with center at one of the vertices and scale factor 0.8.5. Graph quadrilateral ABCD and its image A′B′C′D’ for a dilation with center (0, 0) and a scale factor of 2. The vertices of ABCD are: A(2, 3), B(-2, 4), C(-3, -2), D(3, –3).The solid-line figure is a dilation of the dashed-line figure. The labeled point is the center of dilation. Tell whether the dilation is an enlargement or a reduction. Then find the scale factor of the dilation.6. 7. 8. D(2, K)(?ABC)9. ?ABC is dilated in the coordinate plane with center (2, -1) and scale factor 0.5. If A(6, 3) what is the y-coordinate of A’ ?Dilations: HOMEWORKA dilation has center (0, 0). Find the image of each point for the given scale factor.1.P(–3, 5); D1. 2(P)2.O(–2, –1); D4(O)3.M(4, 2); D3/2(M)4. A square has 12-cm sides. Describe its image for a dilation with center at one of the vertices and scale factor 0.8.5.Graph pentagon JKLMN and its image J′K′L′M′N′ for a dilation with center (0, 0) and a scale factor of 1.5. The vertices of JKLMN are: J(0, 3), K(3, 3), L(3, 0), M(0, –3), N(–1, 0).The dashed-line figure is a dilation of the solid-line figure. The labeled point is the center of dilation. Tell whether the dilation is an enlargement or a reduction. Then find the scale factor of the dilation.6. 7. 8. D(3, A)(?ABC) 9. ?DEFis dilated in the coordinate plane with center (-5, 2) and scale factor 2. If B(-5, 4) what is the y-coordinate of B’ ?Similarity Transformations: CLASSWORK?JKM has vertices J(0, 4), K(4, 4) and M(0, 3). Draw the image for each similarity transformation. 1. (D2 Rx-axis) (?JKM)2. (T<-3, -2> D1.5 ) (?JKM)3. (D0.5 r(270?, O)) (?JKM)4. For the graph, describe the composition of transformations that maps ΔDEF to ΔLMN. 5. Show that ΔABC~ΔFGH by finding a similarity transformation that maps one triangle to the other. 6. Determine if there is a similarity transformation that maps one figure onto the other. If so, identify the similarity transformation and write a similarity statement. If not, explain.7. Do the compositions T<4, – 2> ○ D2 and D2 ○ T<2, – 1> describe the same similarity transformation? Explain.Similarity Transformations: HOMEWORK?JKM has vertices J(-2, 2), K(2, 0) and M(1, -2). Draw the image for each similarity transformation. 1. (D2 Ry-axis) (?JKM)2. (D0.5 T<2, -2>) (?JKM)3. (r(-90?, O) D1.5 )(?JKM)4. For the graph, describe the composition of transformations that maps ΔDEF to ΔLMN.5. Show that ΔABC~ΔFGH by finding a similarity transformation that maps one triangle to the other. 6. Determine if there is a similarity transformation that maps one figure onto the other. If so, identify the similarity transformation and write a similarity statement. If not, explain.7. A similarity transformation is described by the composition T<2, 1> ○ D3. If the order of the composition is changed to be D3 ○ T<2, 1>,does that describe the same transformation? Explain.ANSWER KEYTransformations: CLASSWORK1. Yes, distances and angle measures are preserved. 2. No, distances are not preserved. 3. Rotation; F’G’4. Dilation; angle J’Transformations: HOMEWORK1. No, distances are not preserved. 2. Yes, distances and angle measures are preserved. 3. Reflection; segment G’R’4.Translation; angle T’Translations: CLASSWORK1. 2.3. T<10, -1> (ABDC)4. T<-10, -7> (Q’R’S’T’) = QRST5. Y’(3, 9); Z’(10, 14)6. T<-2, -2> (ΔABC); T<-2, 6> (ΔABC); T<-5, -3> (ΔABC)Translations: HOMEWORK1.2.3. T<-4, 10> (ΔIJK)4.T<4, -9> (ΔL’M’N’) = ΔLMN5. B’(8, -7); C’(7, -5)6. T<-4, -2> (ΔBCD); T<-4, -9> (ΔBCD); T<-8, -6> (ΔBCD)Reflections: CLASSWORK1. A’(1, -3)2. B’(-5, 5)3. C’(-1, 3)4. D’(7, 1)5. E’(-2, 1)6. F’(-3, 4)7. a. A’(-3, 3), B’(-5, -2), C’(-4, 4)b. A’(3, -3), B’(5, 2), C’(4, -4)c. A’(-1, 3), B’(-3, -2), C’(-2, 4)d. A’(3, -7), B’(5, -2), C’(4, -8)8.9. 10. a. J’(-6, 1) b. J’(2, -3) c. J’(-2, 1) d. J’(0, -7)11. Answers may vary. Sample answer: Patterns in tiles, wallpaper, etc. Reflections: HOMEWORK1. A’(5, -1)2. B’(-3, 2)3. C’(-2, 1)4. D’(12, 1)5. E’(-1, 4)6. F’(0, -5)7. a. D’(2, 1), E’(-1, 3), F’(-2, -2)b. D’(-2, -1), E’(1, -3), F’(2, 2)c. D’(6, 1), E’(3, 3), F’(2, -2)d. D’(-2, -3), E’(1, -5), F’(2, 0)8.9. 10. a. K’(0, -3) b. K’(-4, 1) c. K’(4, -7) d. K’(-6, -3) 11. Answers may vary. Sample answer: Patterns in tiles, wallpaper, etc. Rotations: CLASSWORK1.2.3. a. N b. M c. NJ d. JN e. KO4. a. A’(-2, 2), B’(2, 3), C’(-3, -1) b. A’(-2, -2), B’(-3, 2), C’(1, -3) c. A’(2, -2), B’(-2, -3), C’(3, 1) 5. A’(-2, 6), B’(3, -4), C’(3, 5), D’(-4, 2)6. D’(5, -4), E’(-3, -4), F’(-3, 2), G’(5, 2)7. C8. F’(-2, -1), G’(0, 0), H’(1, 3) 9. Yes, 180? 10. Yes, 90? 11. Yes, 180? Rotations: HOMEWORK1. 2.3. a. Db. E c. DC d. FE e. Df. DC4. a. D’(-3, 2), E’(2, 4), F’(2, 7), G’(-2, 5)b. D’(-2, -3), E’(-4, 2), F’(-7, 2),G’(-5, -2)c. D’(3, -2), E’(-2, -4), F’(-2, -7),G’(2, -5)5. P’(5, 1), Q’(4, -3), R’(-4, -2), S’(-2, 3)6. K(2, 3), L(3, -2), M(-2, -4), N(-4, 2)7. Answers may vary. Sample: A rotation is a rigid motion therefore distances and angle measures are preserved. AB = BC = CD = AD and m<A = m<B = m<C = m<D. If all angles of a quadrilateral are equal then they each must measure 90 degrees. By definition the quadrilateral is a square. 8. R’(-3, 0), S’(0, 4), T’(0, 0)9. Yes, 45? 10. Yes, 22.5? 11. Yes, 180? Compositions of Transformations: CLASSWORK1. translation, down and to the right, twice the distance between lines l and m2. rotation, about point P, 120? clockwise3. A’(0, 3), B’ (-3, 1), C’(-2, -4)4. A’(-4, -1), B’ (-1, 1), C’(-2, 6)5. A’(7, 4), B’ (4, 2), C’(5, -3)6. A’(6, 0), B’ (4, 3), C’(-1, 2)7. 180? rotation8. A rotation, about point (1, -1), 180? clockwise9. P(0, -4)Compositions of Transformations: HOMEWORK1. rotation, about point K, 180? counterclockwise2. translation, directly down, twice the distance between lines l and m3. D’(2, -3), E’ (4, -5), F’(6, -1)4. D’(-3, 1), E’ (-1, -1), F’(1, 3)5. D’(2, 0), E’ (0, 2), F’(-2, -2)6. D’(5, 2), E’ (7, 4), F’(3, 6)7. m || l8. A translation, 10 units to the right9. P(0, -1)Congruence Transformations: CLASSWORK1. Check student work. Sample Answer: (T <1, 0>? Ry -axis ? r(270?, O))(ΔABC) = ΔDEF2. Check student work. Sample Answer: (T <2, 0>? Ry -axis ? r(180?, O))(ΔABC) = ΔDEF3. ΔABC?ΔGHI; Check student work. Sample Answer: r(180?, O))(ΔABC) = ΔGHI4. ABCD?LIJK; Check student work. Sample Answer: T <-5, -4>(ABCD)?LIJKCongruence Transformations: HOMEWORK1. Check student work. Sample Answer: (Rx -axis ? T <5, 0> (ΔABC) = ΔDEF2. Check student work. Sample Answer: (r(90?, O) ? Ry -axis )(ΔABC) = ΔDEF3. CD?EF; Check student work. Sample Answer: Ry -axis (CD) = EF4. ΔABC?ΔIHG; Check student work. Sample Answer: Ry =2 ?T <6, 0> (ΔABC) = ΔIHGDilations: CLASSWORK1. A’(21, 28)2. B’(0, 13.6)3. C’(25/3, -10)4. A square with 12.8 cm sides.5. A’ (4, 6), B’(-4, 8), C’(-6, -4), D’(6, -6)6. scale factor: 3; enlargement7. scale factor: 1/4; reduction8. 9. 1Dilations: HOMEWORK1. A’(-3.6, 6.0)2. B’(-8, -4)3. C’(6, 3)4. A square with 9.6 cm sides.5. J’ (0, 4.5), K’(4.5, 4.5), L’(4.5, 0), M’(0, -4.5), N’(-1.5, 0)6. scale factor: 9/5; enlargement7. scale factor: 1/3; reduction 8.9. 6Similarity Transformations: CLASSWORK1. J’(0, -8), K’(8, -8), M’(0,6)2. J’(-3, 4), K’(3, 4), M’(-3, 2.5)3. J’(-2, 0), K’(-2, 2), M’(-1.5, 0)4. Answers may vary. Sample: (D0.5 ?r(180 ,O))(ΔDEF) = ΔLMN5. Answers may vary. Sample: (T<-4, -10>? D3)(ΔABC) = ΔFGH6. No, the corresponding sides are not proportional. 7. Yes. For a point (x, y), the first transformation will transform (x, y) to (2x + 4, 2y-2) while the second transformation will transform it to (2(x+2), 2(y-1)) which = (2x + 4, 2y-2)Similarity Transformations: HOMEWORK1. J’(4, 4), K’(-4, 0), M’(-2, -4)2. J’(0, 0), K’(2, -1), M’(1.5, -2)3. J’(-3, -3), K’(0, 3), M’(3, 1.5)4. Answers may vary. Sample: (Rx -axis ? D2)(ΔDEF) = ΔLMN5. Answers may vary. Sample: (r(90 ,O) ? D1.5 )(ΔABC) = ΔFGH6. Yes. A reflection followed by a dilation with a scale factor of 0.5. ΔABC~ΔEDC7. No. For a point (x, y), the first transformation will transform (x, y) to (3x + 2, 3y+1) while the second transformation will transform it to (3(x+2), 3(y+1)). ................
................

In order to avoid copyright disputes, this page is only a partial summary.

Google Online Preview   Download