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Geometry

Geometry Help: Coordinates To Find Perimeter And Area

Review real example questions for Coordinates To Find Perimeter And Area in Geometry.

Question 1

Rectangle PQRS has vertices P(1, 2), Q(7, 2), R(7, 6), and S(1, 6). Point T is located at (4, 9). What is the area of quadrilateral PQTS?

  1. 15 square units
  2. 18 square units
  3. 21 square units
  4. 24 square units
Explanation: The correct answer is B. Using the shoelace formula for quadrilateral PQTS with vertices P(1,2), Q(7,2), T(4,9), S(1,6): Area = ½|x₁(y₂-y₄) + x₂(y₃-y₁) + x₃(y₄-y₂) + x₄(y₁-y₃)| = ½|1(2-6) + 7(9-2) + 4(6-2) + 1(2-9)| = ½|(-4) + 49 + 16 + (-7)| = ½|36| = 18. Choice A results from incorrectly calculating the rectangle area as 3×5. Choice C comes from adding the rectangle area (24) and subtracting 3 incorrectly. Choice D is simply the area of rectangle PQRS, ignoring point T.

Question 2

Quadrilateral ABCD has vertices A(0,1)A(0,1)A(0,1), B(4,4)B(4,4)B(4,4), C(7,0)C(7,0)C(7,0), and D(3,−3)D(3,-3)D(3,−3) connected in that order. What is the perimeter of the figure?

  1. 5+5+5+5=205+5+5+5=205+5+5+5=20
  2. (4−0)2+(4−1)2+(7−4)2+(0−4)2+(3−7)2+(−3−0)2+(0−3)2+(1−(−3))2\sqrt{(4-0)^2+(4-1)^2}+\sqrt{(7-4)^2+(0-4)^2}+\sqrt{(3-7)^2+(-3-0)^2}+\sqrt{(0-3)^2+(1-(-3))^2}(4−0)2+(4−1)2​+(7−4)2+(0−4)2​+(3−7)2+(−3−0)2​+(0−3)2+(1−(−3))2​
  3. (4−0)2+(4−1)2+(7−4)2+(0−4)2+(3−7)2+(−3−0)2\sqrt{(4-0)^2+(4-1)^2}+\sqrt{(7-4)^2+(0-4)^2}+\sqrt{(3-7)^2+(-3-0)^2}(4−0)2+(4−1)2​+(7−4)2+(0−4)2​+(3−7)2+(−3−0)2​
  4. 12∣0(4−0)+4(0+3)+7(−3−1)+3(1−4)∣\frac{1}{2}\left|0(4-0)+4(0+3)+7(-3-1)+3(1-4)\right|21​∣0(4−0)+4(0+3)+7(−3−1)+3(1−4)∣
Explanation: The skill is finding the perimeter of a quadrilateral using coordinates. The vertices are A(0,1)A(0,1)A(0,1), B(4,4)B(4,4)B(4,4), C(7,0)C(7,0)C(7,0), and D(3,−3)D(3,-3)D(3,−3). Side lengths are computed using the distance formula between consecutive points. The perimeter is the sum of these four side lengths. Each simplifies to 5, summing to 20, justifying the expression in the correct choice. A distractor misconception is summing only three sides, as in choice C. To transfer this strategy, always compute individual side lengths before summing for the perimeter.

Question 3

Triangle ABC has vertices at A(2, 3), B(8, 7), and C(5, 11). If the triangle is reflected across the y-axis to form triangle A'B'C', what is the difference between the perimeter of triangle ABC and the perimeter of triangle A'B'C'?

  1. 0
  2. 4
  3. 8
  4. 12
Explanation: The correct answer is A. Reflections preserve distances, so the perimeter remains unchanged. Using the distance formula: AB = √[(8-2)² + (7-3)²] = √52, BC = √[(5-8)² + (11-7)²] = √25 = 5, and AC = √[(5-2)² + (11-3)²] = √73. After reflection across the y-axis, A'(-2,3), B'(-8,7), C'(-5,11) form a congruent triangle with identical side lengths, so the difference is 0. Choice B incorrectly uses the difference in x-coordinates of one vertex. Choice C doubles this error. Choice D represents three times the coordinate difference, possibly from adding coordinate changes.

Question 4

A rectangle RSTU is shown with vertices R(−2,−3)R(-2,-3)R(−2,−3), S(4,−3)S(4,-3)S(4,−3), T(4,1)T(4,1)T(4,1), and U(−2,1)U(-2,1)U(−2,1). Which calculation is required to find the area?

  1. (4−(−2))+(1−(−3))(4-(-2))+(1-(-3))(4−(−2))+(1−(−3))
  2. 2((4−(−2))+(1−(−3)))2\big((4-(-2))+(1-(-3))\big)2((4−(−2))+(1−(−3)))
  3. (4−(−2))⋅(1−(−3))(4-(-2))\cdot(1-(-3))(4−(−2))⋅(1−(−3))
  4. (4−(−2))2+(1−(−3))2\sqrt{(4-(-2))^2+(1-(-3))^2}(4−(−2))2+(1−(−3))2​
Explanation: The skill is finding the area of a rectangle using coordinates. The vertices are R(-2,-3), S(4,-3), T(4,1), and U(-2,1). Side lengths are computed by differences in x and y for length and width. The area logic is length times width. This gives 6 times 4 equals 24, justifying the calculation in the correct choice. A distractor misconception is confusing area with perimeter, as in choice B. To transfer this strategy, compute length and width before multiplying for area.

Question 5

Quadrilateral ABCDABCDABCD has vertices A(0,0)A(0,0)A(0,0), B(4,0)B(4,0)B(4,0), C(3,3)C(3,3)C(3,3), and D(−1,3)D(-1,3)D(−1,3) in that order. What is the perimeter of the figure?

  1. 141414
  2. 4+3+4+34+3+4+34+3+4+3
  3. 4+10+4+104+\sqrt{10}+4+\sqrt{10}4+10​+4+10​
  4. 4+18+4+184+\sqrt{18}+4+\sqrt{18}4+18​+4+18​
Explanation: The skill is finding the perimeter of a quadrilateral using coordinates. The vertices are A(0,0), B(4,0), C(3,3), and D(-1,3). Side lengths are computed using the distance formula, which is the square root of the sum of the squares of the differences in x and y coordinates. The perimeter is the sum of all four side lengths. Calculating each distance gives AB = 4, BC = √10, CD = 4, and DA = √10, justifying the final value as 4 + √10 + 4 + √10. A common distractor misconception is using √18 instead of √10 by doubling a difference. To transfer this strategy, compute side lengths before summing for perimeter or using them for area in other figures.

Question 6

A right triangle has vertices at O(0, 0), P(6, 0), and Q(0, 8). If this triangle is rotated 90° counterclockwise about the origin to form triangle O'P'Q', what is the area of the quadrilateral formed by the union of both triangles?

  1. 24 square units
  2. 36 square units
  3. 48 square units
  4. 60 square units
Explanation: The correct answer is C. The original triangle OPQ has area ½(6)(8) = 24. After 90° counterclockwise rotation about origin: O'(0,0), P'(0,6), Q'(-8,0). The rotated triangle O'P'Q' also has area 24. However, the triangles overlap only at the origin, so the total area of their union is 24 + 24 = 48. Choice A gives the area of just one triangle. Choice B incorrectly assumes some overlap beyond the origin point. Choice D might result from adding the areas and including additional area incorrectly.

Question 7

Rectangle WXYZ has W(2, 1), X(2, 7), Y(8, 7), and Z(8, 1). If point P is at (5, 4), what is the area of the region inside rectangle WXYZ but outside triangle WPZ?

  1. 27 square units
  2. 30 square units
  3. 33 square units
  4. 36 square units
Explanation: The correct answer is A. First find the area of rectangle WXYZ: length = 8-2 = 6, width = 7-1 = 6, so area = 36 square units. Next find the area of triangle WPZ with vertices W(2,1), P(5,4), Z(8,1). Using the triangle area formula: Area = ½|x₁(y₂-y₃) + x₂(y₃-y₁) + x₃(y₁-y₂)| = ½|2(4-1) + 5(1-1) + 8(1-4)| = ½|6 + 0 - 24| = ½|18| = 9 square units. The area inside the rectangle but outside the triangle is 36 - 9 = 27 square units. Choice B results from incorrectly calculating the triangle area as 6. Choice C results from calculating the triangle area as 3. Choice D gives the full rectangle area without subtracting the triangle.

Question 8

Points A(−1,2)A(-1,2)A(−1,2), B(3,1)B(3,1)B(3,1), and C(1,5)C(1,5)C(1,5) are plotted on a coordinate plane and connected to form triangle ABCABCABC (segments AB‾\overline{AB}AB, BC‾\overline{BC}BC, and CA‾\overline{CA}CA). What is the perimeter of the figure?

  1. 4+17+134+\sqrt{17}+\sqrt{13}4+17​+13​
  2. 17+20+13\sqrt{17}+\sqrt{20}+\sqrt{13}17​+20​+13​
  3. 17+20\sqrt{17}+\sqrt{20}17​+20​
  4. 17+20+1317+20+1317+20+13
Explanation: The skill is finding the perimeter of a triangle using coordinates. The vertices are A(-1,2), B(3,1), and C(1,5). Side lengths are computed using the distance formula, which is the square root of the sum of the squares of the differences in x and y coordinates. The perimeter is the sum of all three side lengths. Calculating each distance gives AB = √17, BC = √20, and CA = √13, justifying the final value as √17 + √20 + √13. A common distractor misconception is adding the squared distances without taking square roots, resulting in 17 + 20 + 13. To transfer this strategy, compute side lengths before summing for perimeter or using them for area in other figures.

Question 9

Quadrilateral ABCD has vertices A(0,1)A(0,1)A(0,1), B(4,4)B(4,4)B(4,4), C(7,0)C(7,0)C(7,0), and D(3,−3)D(3,-3)D(3,−3) connected in that order. What is the perimeter of the figure?​​

  1. 5+5+5+5=205+5+5+5=205+5+5+5=20
  2. (4−0)2+(4−1)2+(7−4)2+(0−4)2+(3−7)2+(−3−0)2+(0−3)2+(1−(−3))2\sqrt{(4-0)^2+(4-1)^2}+\sqrt{(7-4)^2+(0-4)^2}+\sqrt{(3-7)^2+(-3-0)^2}+\sqrt{(0-3)^2+(1-(-3))^2}(4−0)2+(4−1)2​+(7−4)2+(0−4)2​+(3−7)2+(−3−0)2​+(0−3)2+(1−(−3))2​
  3. (4−0)2+(4−1)2+(7−4)2+(0−4)2+(3−7)2+(−3−0)2\sqrt{(4-0)^2+(4-1)^2}+\sqrt{(7-4)^2+(0-4)^2}+\sqrt{(3-7)^2+(-3-0)^2}(4−0)2+(4−1)2​+(7−4)2+(0−4)2​+(3−7)2+(−3−0)2​
  4. 12∣0(4−0)+4(0+3)+7(−3−1)+3(1−4)∣\frac{1}{2}\left|0(4-0)+4(0+3)+7(-3-1)+3(1-4)\right|21​∣0(4−0)+4(0+3)+7(−3−1)+3(1−4)∣
Explanation: The skill is finding the perimeter of a quadrilateral using coordinates. The vertices are A(0,1), B(4,4), C(7,0), and D(3,-3). Side lengths are computed using the distance formula between consecutive points. The perimeter is the sum of these four side lengths. Each simplifies to 5, summing to 20, justifying the expression in the correct choice. A distractor misconception is summing only three sides, as in choice C. To transfer this strategy, always compute individual side lengths before summing for the perimeter.

Question 10

Triangle ABC has vertices A(1, 2), B(7, 5), and C(4, 8). The triangle is translated 3 units left and 2 units down to form triangle A'B'C'. What is the ratio of the area of triangle ABC to the area of triangle A'B'C'?

  1. 9:4
  2. 3:2
  3. 5:1
  4. 1:1
Explanation: When you encounter transformation problems in geometry, the key insight is understanding how different transformations affect area and other measurements. Translation is a transformation that slides a figure from one position to another without changing its size, shape, or orientation. When triangle ABC is translated 3 units left and 2 units down, every point moves the same distance in the same direction. The new vertices A'B'C' are simply the original vertices with each x-coordinate decreased by 3 and each y-coordinate decreased by 2. Since translation preserves all distances and angles, the translated triangle A'B'C' is congruent to the original triangle ABC. Congruent figures have identical areas, so the ratio of their areas is 1:11:11:1. Looking at the incorrect choices: Answer A) 9:49:49:4 might tempt you if you incorrectly squared the translation distances (3² and 2²), but translation distances don't affect area ratios. Answer B) 3:23:23:2 could mislead you into thinking the ratio relates directly to the translation amounts (3 units and 2 units), but again, translation preserves area. Answer C) 5:15:15:1 has no logical connection to this problem and represents a common distractor with no mathematical basis. Remember this crucial distinction: translations, rotations, and reflections (rigid transformations) preserve area, while dilations (scaling transformations) change area by the square of the scale factor. When you see translation problems, immediately think "same area, same shape" – the ratio will always be 1:11:11:1.