Coordinate Proofs with Quadrilaterals
Coordinate Proofs with Quadrilaterals
A coordinate proof uses algebra on the coordinate plane to prove geometric properties. When working with quadrilaterals, we can determine whether a shape is a general quadrilateral, parallelogram, rectangle, rhombus, or square by analyzing the coordinates of its vertices.
The Three Essential Formulas
To write coordinate proofs, you only need three basic algebraic formulas:
-
Distance Formula: Used to prove sides or diagonals are equal in length (congruent). d=(x2โโx1โ)2+(y2โโy1โ)2โ
-
Slope Formula: Used to prove lines are parallel (equal slopes) or perpendicular (slopes are negative reciprocals, meaning m1โโ m2โ=โ1). m=x2โโx1โy2โโy1โโ
-
Midpoint Formula: Used to prove diagonals bisect each other (they share the exact same midpoint). M=(2x1โ+x2โโ,2y1โ+y2โโ)
Proving Specific Quadrilaterals
Depending on what you want to prove, you can choose the most efficient formula:
- Parallelogram: Prove both pairs of opposite sides are parallel (Slope Formula) OR prove the diagonals bisect each other (Midpoint Formula).
- Rectangle: First prove it is a parallelogram, then prove one interior angle is 90โ (Slope Formula for perpendicular adjacent sides) OR prove the diagonals are congruent (Distance Formula).
- Rhombus: First prove it is a parallelogram, then prove adjacent sides are congruent (Distance Formula) OR prove the diagonals are perpendicular (Slope Formula).
- Square: Prove it has the properties of both a rectangle (congruent diagonals / right angles) and a rhombus (perpendicular diagonals / congruent sides).
Example: Proving a Parallelogram
Problem: Prove that the quadrilateral with vertices A(1,1), B(4,1), C(5,4), and D(2,4) is a parallelogram using slopes.
Step 1: Find the slope of opposite sides AB and DC.
- Slope of AB: mABโ=4โ11โ1โ=30โ=0
- Slope of DC: mDCโ=5โ24โ4โ=30โ=0
Since mABโ=mDCโ, side AB is parallel to side DC.
Step 2: Find the slope of opposite sides AD and BC.
- Slope of AD: mADโ=2โ14โ1โ=13โ=3
- Slope of BC: mBCโ=5โ44โ1โ=13โ=3
Since mADโ=mBCโ, side AD is parallel to side BC.
Conclusion: Because both pairs of opposite sides have equal slopes, they are parallel. Therefore, quadrilateral ABCD is a parallelogram.