Given: parallelogram and right angle; Prove: parallelogram

Join the discussion
Ask a follow-up here, or get your own question answered by working scientists, mathematicians and engineers — people, not an autocomplete.
Real named experts · corrections over time · the nuance an AI answer skips
4 replies · 4K views
Joodez
Messages
12
Reaction score
0
kaLbypg.png


I'm curious if it looks like I defined the reasons correctly to prove that FBCD is indeed a parallelogram. Specifically, I'm unsure if I'm using #4 "definition of coincident" and #5,6 "reflexive property" correctly in their terminology. I don't have anyone else, or any teacher to ping this back to or I would try to not waste space here. This is my finished proof:

IWMfDfz.jpg


I apologize about cutting the top half of the worked problem off. It should be mirrored to the unworked problem above. If it helps, I can repost the image upon request.
 
Physics news on Phys.org
Wasn't ##AD // BC## because ABCE is a parallelogram ?

And isn't there a theorem stating ##\angle F = \angle D \rightarrow FB // CD ## ?
And then you have enough to state FBCD is a parallelogram.
 
BvU said:
Wasn't ##AD // BC## because ABCE is a parallelogram ?

And isn't there a theorem stating ##\angle F = \angle D \rightarrow FB // CD ## ?
And then you have enough to state FBCD is a parallelogram.
Sorry for the late reply, just got back from school.

Am I allowed to automatically assume that AD // BC because of the two 90° angles lying upon the line. I understand that this is true, but am I allowed to state this like:
AD//BC : ABCE is a parallelogram

or is there another way in which I must state this, such as:
∠F and ∠D are both _|_ (or maybe supplementary together?), whilst lying on the same line AE, which is stated to be parallel to BC based on the property of a parallelogram having parallel opposite sides.

Also, finding "parallelogram converses," I see that:

If both pairs of opposite angles of a quadrilateral are congruent, the quadrilateral is a parallelogram.

Does this reason satisfy #4. I want to say that because both of these opposite angles are congruent to one another, and also a special case of 90°, that they form a rectangle and thus must be a parallelogram, based on the definition of a rectangle.
 
Joodez said:
Am I allowed to automatically assume that AD // BC because of the two 90° angles lying upon the line. I understand that this is true, but am I allowed to state this like:
AD//BC : ABCE is a parallelogram
ABCE is a parallelogram is a given. From that you conclude ##AD//BC## so ##FD//BC##.
To prove that FDBC is a parallelogram, you have to either prove ##FB//DC##, or, quoting
Joodez said:
If both pairs of opposite angles of a quadrilateral are congruent, the quadrilateral is a parallelogram.
that ##\angle B = \angle D## and ##\angle C = \angle F##.

With the first you are done when there is
BvU said:
a theorem stating ∠F=∠D→FB//CD∠F=∠D→FB//CD\angle F = \angle D \rightarrow FB // CD ?
With the second you kind of have the reverse theorem(And I am positive that one exists -- even after 50+ years):
##AB//CE \Rightarrow \angle BAF = \angle CED##. That can lead you to ## \angle BFD = \angle BCD## and idem ##\angle B = \angle D##
 
BvU said:
ABCE is a parallelogram is a given. From that you conclude ##AD//BC## so ##FD//BC##.
To prove that FDBC is a parallelogram, you have to either prove ##FB//DC##, or, quoting
that ##\angle B = \angle D## and ##\angle C = \angle F##.

With the first you are done when there is

With the second you kind of have the reverse theorem(And I am positive that one exists -- even after 50+ years):
##AB//CE \Rightarrow \angle BAF = \angle CED##. That can lead you to ## \angle BFD = \angle BCD## and idem ##\angle B = \angle D##

I've realized that I need to do a complete reboot of proofs. I understand most of the principles and techniques discovered in geometry. However, I cannot successfully illustrate proofs and especially the reasons for which statements are valid. Thank you for your assistance. I would like to ask one final question and that is:

What is a good resource for someone without a geometry book to learn the language and mechanics of "proofs" as utilized in geometry? So far I've been searching about for rules and etc, but if there's a comprehensive guide of any length, I would really appreciate being pointed in that direction.