Using Coordinates in Proofs
Rule

Parallelogram Opposite Sides Theorem

The opposite sides of a parallelogram are congruent.
parallelogram

In respects to the characteristics of the diagram, the following statement holds true.


PQ≅SR and QR≅PS

Two proofs will be provided for this theorem.

Proof

Using Coordinates

This theorem can be proven by placing the parallelogram on a coordinate plane. For simplicity, vertex P will be placed at the origin and vertex S on the x-axis.

parallelogram on a coordinate plane

Since P lies on the origin, its coordinates are (0,0). Point S is on the x-axis, meaning its y-coordinate is 0. Let a be the x-coordinate of S. Furthermore, let b and c be the coordinates of Q. P(0,0) Q(b,c) S(a,0) Note that both P and S lie on the x-axis. Therefore, SP is a horizontal segment. Since opposite sides of a parallelogram are parallel, QR is also a horizontal segment. This means that Q and R have the same y-coordinate. Let x be the x-coordinate of R.

parallelogram and its vertices labeled with their coordinates
Next, the x-coordinate of R will be determined. Since PQ and SR are parallel, they have the same slope. The slope of PQ can be found using the Slope Formula.
m = y_2-y_1/x_2-x_1
m=c- 0/b- 0
m=c/b
The slope of PQ is cb. By following the same procedure, the slope of SR can be expressed in terms of x.
m = y_2-y_1/x_2-x_1
Side Endpoints Substitute Simplify
PQ P( 0, 0) and Q( b, c) m_(PQ)=c- 0/b- 0 m_(PQ)=c/b
SR S( a, 0) and R( x, c) m_(SR)=c- 0/x- a m_(SR)=c/x-a
As it has been previously stated, since PQ and SR are parallel, their slopes are equal. m_(PQ)=m_(SR) ⇕ c/b=c/x-a The above equation can be solved for x.
c/b=c/x-a
Solve for x
c=c/x-a(b)
c=c(b)/x-a
c(x-a)=c(b)
x-a=b
x=b+a
x=a+b
The x-coordinate of R is a+b.
parallelogram with its vertices in terms of a and b
Finally, by using the Distance Formula, the length of each side of the parallelogram can be calculated. The length of PQ will be calculated first.
d = sqrt((x_2-x_1)^2 + (y_2-y_1)^2)
PQ=sqrt(( b- 0)^2+( c- 0)^2)
PQ=sqrt(b^2+c^2)
By following the same procedure, all the side lengths can be calculated.
d = sqrt((x_2-x_1)^2 + (y_2-y_1)^2)
Side Endpoints Substitute Simplify
PQ P( 0, 0) and Q( b, c) PQ= sqrt(( b- 0)^2+( c- 0)^2) PQ=sqrt(b^2+c^2)
QR Q( b, c) and R( a+b, c) QR= sqrt(( a+b- b)^2+( c- c)^2) QR=a
SR S( a, 0) and R( a+b, c) SR= sqrt(( a+b- a)^2+( c- 0)^2) SR=sqrt(b^2+c^2)
PS P( 0, 0) and S( a, 0) PS= sqrt(( a- 0)^2+( 0- 0)^2) PS=a

By the Transitive Property of Equality, it can be said that PQ=SR and that QR=PS. cc PQ=sqrt(b^2+c^2) SR=sqrt(b^2+c^2) & QR=a PS=a ⇓ & ⇓ PQ=SR & QR=PS By definition of congruent segments, it can be stated that the opposite sides of a parallelogram are congruent.


PQ≅SR and QR≅PS

Proof

Using Congruent Triangles

This theorem can also be proven by using congruent triangles. Consider the parallelogram PQRS and its diagonal PR.

parallelogram and one of its diagonals

It can be noted that two triangles are formed with PR as a common side. △ PQR and △ RSP By the definition of a parallelogram, PQ and SR are parallel. Therefore, by the Alternate Interior Angles Theorem, it can be stated that ∠ QPR ≅ ∠ SRP and that ∠ QRP ≅ ∠ SPR. Furthermore, by the Reflexive Property of Congruence, PR is congruent to itself.

parallelogram and one of its diagonals and the two pair of congruent angles

Consequently, △ PQR and △ RSP have two pairs of congruent angles and an included congruent side. ∠ QPR &≅ ∠ SRP PR&≅PR ∠ QRP &≅ ∠ SPR Therefore, by the Angle-Side-Angle Congruence Theorem, △ PQR and △ RSP are congruent triangles. △ PQR ≅ △ RSP Since corresponding parts of congruent figures are congruent, PS is congruent to QR and PQ is congruent to RS.


PQ≅SR and QR≅PS

Exercises