Tag Archives: geogebra

whY is X minus H & plus K?

We all have our methods of helping students gain an understanding of this:


Let’s start simple as most of us do in the classroom.  In years past, I (and many others) have helped students explore this concept with something like:

Function transformation Intro Activity

This concept develops as students explore more.  They learn that operations inside the primary piece of the function have horizontal effects, while outside correlates to vertical changes.  Easy enough.  But then, it happens.

Student: “Mr. Butler, I get that plus or minus moves the parabola.  But how come when you do vertical is goes the way it’s supposed to, and sideways is like opposite.”
Butler: “That’s a great question.  What do you mean by opposite.” (trying to get the student to articulate more specifically what he/she is trying to say while I ponder it myself in hoping to come up with an appropriate answer).
S: “Like vertical stuff goes up for plus, down for minus.  Just like the graph”
B: “What do you mean the graph?”
S: “The axis.  The y-axis.  But then for the other axis, the x-axis, it moves opposite.  Like negative is left, but when it’s minus it goes right.  And positive is right, but when it’s plus inside the parabola goes left.”
B: “Who else sees the pattern, or something like it?”

Lots of Hands.

B: “Well, you see whenever its inside, the transformation is opposite.  We’ll see more of that when we look at multiplying too.”

Cue the tilt head, “Huh?” OR “Oh …..I get it,” fake voice.

Credit: LIz West via Flickr
Credit: LIz West via Flickr

This process with examples didn’t answer the question conceptually, it just confirmed that there’s a pattern.  Yes, inside opposite, outside normal.  But why?

There’s an opportunity here to go deeper.  Something that I explored with students was the idea of changing inputs and outputs.  I’m pretty sure you’ve heard of the function machine:

Credit: Chris Robinson via 101qs.com

Students get this, kinda.  You choose an input, do some math, then get an output.  It’s helpful to reference the inside and outside as add-ons to the machine.


Students can kinda get a grasp on that, but it’s still abstract.  So we iterate with a few different function machines: quadratic, cubic, and maybe even some square root functions.

gifsmos gifsmos (1)

We often lean on words like shift and stretch, and then that whole confusion with the opposite comes in.  What is the opposite of stretch?  Do we say compress?  Can we compress by a negative?  What does that look like?  In this case many would favor more appropriate vocabulary like translate, reflect and dilate.  Either way through repetition and memorization we hope our students can eventually break down the effects of a,b,h and k for:

do we really need a b?

Wait, do we really understand what’s going on with the inside/opposite confusion yet?

Finally, Some Insight with the Inside

When we are making a change to the inside, we are making a change to the input, before it goes into the function machine.  That’s like making a change to all the inputs at the same time.  We conveniently have an organized visual set of the inputs: the x-axis.  So any change to the inside/input is actually a change to the x-axis.  Play with this and see if it starts to conceptualize a little better for you now.

The Applet


I’m not opposed to starting simple. In fact, I’m all for it.  There are so many layers in function transformation and it takes a while to handle what’s really going on under the hood.  I do suggest that once that question of “Why?” is primed and ready, get the students to explore with this.

Quadratic Formulae

Quadratic Amy
courtesy of Samuel Winter via flickr CC-BY-NC-SA License
How would you graph?   QuadraticToGraph

Would you factor?  Would you complete the square?  Quadratic Formula?  Are those my only options?

The idea of multiple representations  of the same thing, or multiple methods toward the same end, has strong correlation for learning (and teaching) mathematics.  Jo Boaler demonstrates this in her number talks.  Dan Meyer and Robert Kaplinksy discuss these through the open middle problem design. One way we see this in polynomials (including quadratics) is…


There’s the famous XBox method, often abbreviated to a formulaic method by teachers.  I like this approach, especially because it incorporates area models, grouping, flexibility for multiple values of the lead coefficient “a”.    James Key (aka @iheartgeo), brings in more of the number talk by using powers of 10 in addition to powers of x

Here’s a quick preview of his vine that relates:

XBox Numerical


Transitioning to more algebraic/abstract examples seems simpler when relating quadratics to numerical examples like this vine. He looks at the factors and the relationships between the terms.  Students in his class are prescribed a formula, but asked to make sense of the relationships and then transition to methods with more regularity.

Complete the Square

A method often confusing to Algebra 1 students because of its abstract structure is again made simple with looping short videos.

Courtesy of @NatBanting
Courtesy of @NatBanting

Plenty of teachers try to support their process with visualization, all that is intended here is to start with the visual reasoning and pattern making, then move to abstract.

The hybrid

It’s not exactly completing the square.  It’s not exactly factoring and using the roots.  It’s the compromise between the two.

  • plot the points (0,0) and (-b,0)
  • shift vertical c units.

Let’s make that easier.  Here’s a dynamic version:


Open up the Middle

But wait, the two points (x1,0) and (x2,0) that plot on the horizontal axis can be any combination that adds up to your linear coefficient “b”.  The vertical shift just needs to balance those numbers with c.

So for our example: QuadraticToGraph, the 8x needs to be split, and c needs to be balanced with the shift:

x1 x2 c shift?
8 0 20 20
0 8 20 20
4 4 20 4
2 6 20 8
1 7 20 ?
-2 10 20 ?
3 5 20 ?


Now with that bit of intuition, we can open up the middle and have the user do some exploration.  Here’s a question that encourages looking at multiple representations and seeing how the values are connected:


When thinking of factors, roots, and vertical shifts, the relationship becomes more dynamic.  We could revisit the open middle prompt and ask to define / express the relationship between a,b and c.   Struggling students can simplify the algebra using Jame’s Keys approach with substituting a value for x.  Here’s a Geogebra applet to help visualize the multiple representations:


 Play with the applet and notice that as long as the quadratics share the same line of symmetry, only a vertical shift is needed to overlap.  This also reveals the congruence in some quadratics.  Ask yourself what makes the quadratics congruent?  

Here’s a similar interactive graph built with Desmos.

What now?

I would expect that this more flexible visualization allows for more depth in understanding how a quadratic function works, both visually and algebraically.  Students who are asked to match quadratic algebraic expressions may be little less intimidated by starting with some dynamic pictures.  So now let’s return to the original question (that has multiple possibilities):

How would you graph?   QuadraticToGraph

What other questions might you ask?

Satellites Spinning Round: Circles Part 3 (Tangents and Incircle)


Have you ever wondered how far a satellite is from the planet?  Sometimes people think about these objects flying through the sky and rotating around a planet.  Such wonders have even inspired greats like Isaac Newton and Kepler.

Some good folk over at illustrative mathematics put this whole satellite into some simpler geometry with circles, triangles, and tangents.



Inspired by these I sought out to simplify the idea of tangents and how they fit around a circle.  We played with this:




Warm up with some questions about the applet,
    • What shapes do you see?
    • Which measures, do you think are congruent?
go into some more typical math questions,
    • What is the perimeter of the triangle?
get a little geeky
    • What is the total area of the triangle (circle included)?
Then get all geeky advanced.
  • How do you calculate the value for the area of the blue shaded area (circle excluded)?

 Student discourse:

Along the way here were some awesome teachable moments:

T: What kind of segments do you see?
S1: Tangents
T: How do you know?
S1: ’cause it says ‘tangent’.
T: I’m still not convinced. Maybe I mislabeled it. Prove it.
S2: They’re perpendicular. Tangents are perpendicular.
T: Anything else? Any other types of segments or is that it?
T: What about inside? Any segments inside the circle?
S3: Radius! There’s a radius!
T: Where?
S3: Here?
T: Where? Pretend I’m blind.
S3: You already are blind Butler, that’s why you wear glasses.
T: [fake smile]
S3: Here at AJ. Ohh, and also AF. And these ones to but you didn’t label them.
T: Do you notice anything else? What if you drag around that red thing?
S3: They’re all the same?
T: What are the same?
S3: The radiussus. Does that mean they’re equal?
T: What do you think?
S3: Yeah, equal. They have to be, cause of the red thing.

S: Hey Butler, is that a kite?
T: It sure looks like it huh? What do we know about kites?
S: There’s stuff that’s the same. Like congruent.
T: For example…?
S: The pieces that match.
T: So how can you use that?
S: They’re equal. Oh wait, they’re equal. Sooo….
And then the student goes on to apply that understanding to fill in the blanks for the missing segment lengths.

The idea of using a few measures, congruent relationships, and some triangle calculations helped the students apply the geometry and calculations further than just one calculation.  As a follow up assessment they completed a static version of the question.  This was easy to create by just taking a screenshot of the applet at some particular balance.

Some day I want to advance this further with some clock math.

Circles Part 1: Similarity Intuition

All circles are similar, right?

Okay, maybe it’s not given.  In fact, it needs to be proven.  This proof is yet another that is so easily demonstrated with dynamic math tools (like desmos and geogebra

Circle Similarity with Desmos

So long as you can move one center onto the other (translate) and dilate one radius to equal the other, similarity is achieved.  This works for every circle.  The perfect proportional balance achieved with circles lays the foundation for most of not all relationships found in them.

Proportional Measures

Similarity gives us a simple system for comparing measures in multiple figures.


You can even explore this with repetition of congruent triangles:

Dimensional Analysis with Scale


Below are a couple of applications that push further with exploring the measures of circles, proportionality, and relationships in the measures.

Pizza Pi 

This activity was first inspired by a posting on John Stevens‘ website wyrmath.wordpress.com .  It looks at proportions with a different angle (pun intended) and asks user to compare various portions of different sized (but similarly shaped) pizza.

Rolling Tires

Another great one from Andrew Stadel.  This is a 3 act math lesson looking at relationships with circumference of a tire and cumulative rotations.

Coming up next…

So where do we go from here.  Following the basic intuition of similarity and proportions in a circle, we can build into

  1. More Angle Relationships with circles
    • Central angles and/or non-central angles
    • Circles circumscribed around a triangle start to simplify some of these relationships.
  2. Segment Relationships
    • Tangents and Incircle
    • Dynamic Relationship with Intersection of Chords, Tangent-Secant, and Secant-Secant (hint: they’re all a similar relationship)

See you in Circles Part 2: Angle Relationships.