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Proof - Opposite Sides of Parallelogram Congruent

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    What we're going to
    prove in this video
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    is a couple of fairly
    straightforward
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    parallelogram-related proofs.
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    And this first one,
    we're going to say, hey,
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    if we have this
    parallelogram ABCD,
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    let's prove that the opposite
    sides have the same length.
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    So prove that AB is equal to
    DC and that AD is equal to BC.
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    So let me draw a diagonal here.
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    And this diagonal, depending
    on how you view it,
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    is intersecting two
    sets of parallel lines.
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    So you could also consider
    it to be a transversal.
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    Actually, let me draw it a
    little bit neater than that.
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    I can do a better job.
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    Nope.
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    That's not any better.
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    That is about as
    good as I can do.
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    So if we view DB,
    this diagonal DB--
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    we can view it as a transversal
    for the parallel lines AB
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    and DC.
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    And if you view it that
    way, you can pick out
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    that angle ABD is going to
    be congruent-- so angle ABD.
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    That's that angle
    right there-- is
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    going to be congruent
    to angle BDC,
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    because they are
    alternate interior angles.
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    You have a transversal--
    parallel lines.
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    So we know that
    angle ABD is going
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    to be congruent to angle BDC.
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    Now, you could also
    view this diagonal,
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    DB-- you could view it as
    a transversal of these two
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    parallel lines, of the other
    pair of parallel lines, AD
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    and BC.
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    And if you look at it that
    way, then you immediately
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    see that angle DBC
    right over here
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    is going to be
    congruent to angle
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    ADB for the exact same reason.
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    They are alternate
    interior angles
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    of a transversal intersecting
    these two parallel lines.
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    So I could write this.
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    This is alternate
    interior angles
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    are congruent when you have
    a transversal intersecting
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    two parallel lines.
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    And we also see that
    both of these triangles,
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    triangle ADB and triangle CDB,
    both share this side over here.
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    It's obviously equal to itself.
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    Now, why is this useful?
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    Well, you might
    realize that we've just
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    shown that both of
    these triangles,
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    they have this pink angle.
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    Then they have this
    side in common.
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    And then they have
    the green angle.
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    Pink angle, side in common,
    and then the green angle.
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    So we've just shown
    by angle-side-angle
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    that these two
    triangles are congruent.
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    So let me write this down.
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    We have shown that
    triangle-- I'll
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    go from non-labeled
    to pink to green-- ADB
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    is congruent to triangle--
    non-labeled to pink to green--
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    CBD.
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    And this comes out of
    angle-side-angle congruency.
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    Well, what does that do for us?
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    Well, if two triangles
    are congruent, then
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    all of the corresponding
    features of the two triangles
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    are going to be congruent.
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    In particular, side DC
    on this bottom triangle
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    corresponds to side BA
    on that top triangle.
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    So they need to be congruent.
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    So we get DC is going
    to be equal to BA.
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    And that's because they
    are corresponding sides
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    of congruent triangles.
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    So this is going to
    be equal to that.
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    And by that exact same
    logic, AD corresponds to CB.
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    AD is equal to CB.
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    And for the exact same
    reason-- corresponding sides
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    of congruent triangles.
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    And then we're done.
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    We've proven that opposite
    sides are congruent.
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    Now let's go the other way.
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    Let's say that we have some
    type of a quadrilateral,
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    and we know that the
    opposite sides are congruent.
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    Can we prove to ourselves
    that this is a parallelogram?
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    Well, it's kind of the
    same proof in reverse.
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    So let's draw a
    diagonal here, since we
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    know a lot about triangles.
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    So let me draw.
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    There we go.
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    That's the hardest part.
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    Draw it.
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    That's pretty good.
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    All right.
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    So we obviously know that CB
    is going to be equal to itself.
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    So I'll draw it like that.
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    Obviously, because
    it's the same line.
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    And then we have
    something interesting.
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    We've split this quadrilateral
    into two triangles, triangle
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    ACB and triangle DBC.
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    And notice, all three sides
    of these two triangles
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    are equal to each other.
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    So we know by side-side-side
    that they are congruent.
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    So we know that triangle
    A-- and we're starting at A,
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    and then I'm going
    to the one-hash side.
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    So ACB is congruent
    to triangle DBC.
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    And this is by
    side-side-side congruency.
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    Well, what does that do for us?
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    Well, it tells us that all
    of the corresponding angles
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    are going to be congruent.
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    So for example, angle ABC
    is going to be-- so let
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    me mark that.
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    You can say ABC is going
    to be congruent to DCB.
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    And you could say, by
    corresponding angles congruent
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    of congruent triangles.
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    I'm just using some shorthand
    here to save some time.
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    So ABC is going to
    be congruent to DCB,
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    so these two angles are
    going to be congruent.
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    Well, this is interesting,
    because here you have a line.
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    And it's intersecting AB and CD.
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    And we clearly see
    that these things that
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    could be alternate interior
    angles are congruent.
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    And because we have these
    congruent alternate interior
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    angles, we know that AB
    must be parallel to CD.
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    So this must be
    parallel to that.
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    So we know that AB
    is parallel to CD
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    by alternate interior angles
    of a transversal intersecting
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    parallel lines.
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    Now, we can use that
    exact same logic.
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    We also know that angle--
    let me get this right.
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    Angle ACB is congruent
    to angle DBC.
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    And we know that by
    corresponding angles congruent
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    of congruent triangles.
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    So we're just saying this
    angle is equal to that angle.
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    Well, once again, these could
    be alternate interior angles.
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    They look like they could be.
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    This is a transversal.
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    And here's two lines
    here, which we're not sure
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    whether they're parallel.
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    But because the alternate
    interior angles are congruent,
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    we know that they are parallel.
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    So this is parallel to that.
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    So we know that AC
    is parallel to BD
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    by alternate interior angles.
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    And we're done.
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    So what we've done
    is-- it's interesting.
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    We've shown if you
    have a parallelogram,
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    opposite sides have
    the same length.
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    And if opposite sides
    have the same length,
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    then you have a parallelogram.
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    And so we've actually proven
    it in both directions.
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    And so we can actually make what
    you call an "if and only if"
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    statement.
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    You could say opposite sides of
    a quadrilateral are parallel if
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    and only if their
    lengths are equal.
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    And you say if and only if.
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    So if they are
    parallel, then you
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    could say their
    lengths are equal.
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    And only if their lengths
    are equal are they parallel.
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    We've proven it in
    both directions.
Title:
Proof - Opposite Sides of Parallelogram Congruent
Description:
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Video Language:
English
Team:
Khan Academy
Duration:
08:30

English subtitles

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