Why the Definition Guarantees Equal Measures
Rigid motions never change lengths or angles. So if a sequence maps one figure onto another:
- Every side length must already match
- Every angle measure must already match
"Same shape and size" comes out automatically — for free.
The Symbol and Vertex Correspondence
The order of letters tells you which parts match.
means , ,- Side
corresponds to side - Angle
corresponds to angle
Order is not optional — it carries information.
A Single Reflection Can Map It
Triangle
, ,- One reflection lands every vertex — so they're congruent
What If One Move Is Not Enough?
So far, a single slide or flip did the job.
But some congruent figures are slid and turned — or slid and flipped.
No single motion will land one on the other. What now?
When No Single Motion Works
- These triangles are congruent, but they differ in both position and orientation
- A slide alone leaves the orientation wrong; a turn alone leaves it in the wrong place
A Two-Step Strategy That Always Helps
When one motion isn't enough, work in two steps:
- Translate to land one vertex on its partner
- Rotate or reflect to swing the other vertices into place
Fix one corner first, then pivot the rest around it.
Step One: Translate to Align a Vertex
- Goal: map
onto , aligning with - Translate 2 left and 2 down:
- Now
, — not yet on and
Step Two: Rotate to Finish the Job
- With
pinned on , rotate about : - And
— every vertex now matches
Check Every Vertex, and More Than One Works
Always verify all three vertices land correctly.
✓, ✓, ✓- A different translation-then-reflection could also work
There's no single "right" sequence — any valid one counts.
The Order of Moves Matters
A sequence is an ordered list, not a set.
- Translate-then-rotate gives one result
- Rotate-then-translate gives a different result
- Like socks-then-shoes versus shoes-then-socks
Same Moves, Reversed, Different Landing
Take point
- Up 3, then rotate
CCW: - Rotate first, then up 3:
A Sequence That Needs a Reflection
Not every second step is a rotation — sometimes you must flip.
and are mirror images, then shifted- Step 1: translate so
lands on - Step 2: reflect to match the flipped orientation
A rotation alone can never un-mirror a figure.
Your Turn: Find the Sequence
Map
and- Vertex
already matches — so no translation needed - What single rotation about
sends and home?
When Can No Sequence Ever Work?
We've been building sequences to show congruence.
But some pairs have no sequence at all.
How could you ever be sure no sequence works — without trying forever?
Different Side Lengths Mean Not Congruent
These triangles look similar, but measure the base.
- One base is
, the other is - Rigid motions never change a length — so
can't become
Same Sides but Different Angles
Equal side lengths still aren't enough on their own.
- A rectangle and a slanted parallelogram can share all side lengths
- The rectangle has
angles; the parallelogram has and - Rigid motions preserve angles — so different angles rule it out
Predict: Equal Perimeter Means Congruent?
A
Same perimeter — does that make them congruent? Predict before advancing.
Sort Them: Congruent or Not?
For each pair, decide and justify:
- Two triangles related by a slide
- One triangle enlarged
- A pentagon flipped then shifted
- A triangle and its mirror image
Congruent? Name the moves. Not congruent? Name the difference.
Build the Full Sequence Yourself
Two congruent triangles, no hints, no pre-aligned vertices.
- Pick a vertex to translate first
- Then choose a rotation or reflection to finish
- Write each step in order, with its parameters
- Verify all three vertices land — then state your sequence
How to Prove It, How to Disprove It
✓ Congruent: a sequence of rigid motions maps one figure exactly onto the other
✓ To prove it: describe the sequence, each move in order
✓ To disprove it: find one measurement that differs
"Looks the same" isn't proof; order matters; equal perimeter is not congruence
Coming Up: From Same Size to Similar
Every move today kept the figure the same size.
Next, we allow a new move: dilation — shrinking or stretching a figure.
That one new move is the difference between congruence and similarity.