Favorite secondary math manipulatives?

Question

I read this is the mathematics educators stack exchange so hopefully this is the right place for this question. I was curious what is your favorite math toys, manipulatives, math games, or tools to use in your math class. Pretend your principal has said you could spend 1500 dollars and you teach secondary math.

Answer 1

Secondary math is a pretty broad subject for something as individualized as the use of manipulatives to enhance teaching, but this is a list of things I'd love to have if I were teaching every subject in the same year for some reason.

• A two-pan balance scale and a bunch of clearly-labeled weights (Algebra I) - I feel that it can be really evocative how an equation like $3x+4=16$ can lead to $3x=12$ and from there to $x=4$ if you can manipulate labeled and unlabeled weights on a two-pan balance. The notion that doing the same thing to both sides to an equation is really brought home by seeing that that's what it takes for a balance to remain ... balanced.

• A wall-sized slide rule (Algebra II) - Logarithms had a clearly useful purpose fifty years ago that helped us to put humans in space. Slide rules bring that home. One of the sad stories of my teaching life is that my mother was at an estate sale and saw a giant promotional slide rule that was on sale for \$50. (Apparently, in the old days, if you bought a classroom full of handheld slide rules, you'd get a wall model for free.) My mom thought it looked cool but didn't buy it for me. Those things are usually $500, and I'd love to have one.

• A collection of 3D shapes (Geometry) - This one at least is affordable, and something I actually have in my room. They're a set of plexiglass polyhedra like a cube, rectangular prism, pyramid, cylinder, cone, hemisphere, and so on. There is a little hole in each one and they tend to share radii and heights when it would be convenient to use water to show that, for instance, the volume of a cone is $\frac13$ the volume of a cylinder with the same height and radius.

• A similar triangle "convincer" (Geometry) - I've never seen one of these before, but I'd really like my father to make a simple two piece jigsaw puzzle for me. (A 3-d printer would probably rock at this too. One of the key triangle similarity proofs is that a right triangle is split into two similar triangles by the altitude to the hypotenuse.

But I think it's hard for students to see because the common angle has to be "reflected". With manipulatives, it's easy to flip the piece over and see that it fits all of the angles and is the same size. I've never seen one of these for sale, but again I'd appreciate having it in my room.

Answer 2

I don't know if this is the right dollar amount, but I think getting access to a 3d printer and making some useful manipulatives of your choice with it would be cool. That is, if you are in a large district and have enough time to invest in trying them out - I don't think it's a one-off process!

As an example, Henry Segerman's website has some absolutely amazing examples - and the code is all available on Thingiverse, which is the go-to site for 3d printing.

And once you start seeing these, it's hard to stop looking for more! There are a lot of things out there, so you don't necessarily have to reinvent the wheel at all. Again, the caveats are important - this is a significant investment that is only worth it if you have people who would do it. But if you do, the sky's the limit.

Answer 3

I might think about some iconic objects of the past that excite interest, perhaps mainly in geometry. Drafting table (probably $500 for a professional one, but you can check second hand). French curve as Rust mentioned. Slide rules. Parallel rulers and 10 point dividers (good for poking people when bored...I would know). Sextant. Abacus. Towers of Hanoi puzzle.

Different types of scientific graph paper along the walls or in framed pictures (and have a file of sheets as well): Regular, thick/thin for, semilog (and with decibel markings), log-log, triangular phase diagram, hex sheets, circular maneuvering boards. Posters with different geographic projections shown and explained. 2-D space group Escher tile posters. Random tables, used as wallpaper (log, trig, Bessel, etc.). Maybe some posters showing different functions/relations (doesn't need to be stuff they are learning...this is more for art and for intrigue): Bessel, epicycle, etc.

Handleable models of platonic solids and sphere packing (AB, ABC) and point group examples.

Get stuff that is sturdy and old and looks like it has seen the blood and sweat of combat. Part of the charm. Dress the place up. Make it look like a Hogwarts classroom. All sorts of mysterious instruments of mathematical torture arrayed on the walls and shelves.

Answer 4

As a no-cost option that gives you so many capabilities besides the conventional black/white-board, I always use geogebra. Not only as a demonstration tool, but also as a functionality for the students to investigate almost anything in precalculus or algebra.

By simply adding, e.g. some moving graphics you can easily explain why, say, $e^x\approx\left(1+\frac{x}{n}\right)^n$ for large values of $n$ or several other interesting but difficult to formally approach in secondary school mathematics.