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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.
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.
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.
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 |
LHS * b=RHS* b
a/c* b = a* b/c
LHS * (x-a)=RHS* (x-a)
.LHS /c.=.RHS /c.
LHS+a=RHS+a
Commutative Property of Addition
Substitute values
Subtract terms
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
This theorem can also be proven by using congruent triangles. Consider the parallelogram PQRS and its diagonal PR.
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.
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