When we teach math we are helping our students establish a framework for interpreting the world. One of the worst ways I know to help them establish that framework is to print an illustration of a real-world scenario in a textbook, write in only the relevant measurements, and tell the students in the text of the problem which formula or strategy to apply. This leaves a student helpless and unprepared (in the mathematical, analytical sense) should she ever encounter the world that exists outside the pages of her textbook.

So we instead bring digital media from the world into the classroom, artifacts from the world as students experience it, artifacts which students can discuss and to which they can apply frameworks of their choice. In order to leave students capable and prepared for their encounters with the world, this media must be captured and presented very intentionally.


We must capture this media — an audio clip, a photo, or a video, for example — so that it most closely approximates the student perspective, so that the media appears as nearly as possible to be the world as the students experience it, rather than as some audio, photo, or video that has already been interpreted for them by a photographer or a cinematographer or an editor. It must be captured to allow for the most possible classroom uses, the most possible interpretations, and the most framework applications — allowing even for the application of useless frameworks.

  • Frame wide on the scene rather than narrow. Capture the entire scene inside a static frame and add 5% to the margins. This forces a useful question on the student, "Where do I focus my attention?"
  • Compose the shot parallel to the plane of action. Extravagant camera framing makes mathematical photogrammetry difficult but also makes the camera operator an interloper on the scene. An extreme low angle, for example, begs the question, "Who shot this?" when you'd rather the student forget about everything but the scene itself.
  • Record ambient audio only, exactly as the student would hear at that scene.
  • Use location lighting only, exactly as the student would experience at that scene.
  • Maintain a fixed camera position. Use a tripod. A handheld camera allows the camera operator to impose her point-of-view on a student's interpretation of the scene. We want the student to decide for herself what parts of the scene are relevant, important, or useful, not the camera operator.
  • Record several alternate takes, changing variables, illustrating different iterations of the scene.
  • Take a photo of a ruler or meter stick within the plane of action for reference.
  • Do not edit the video. Edits invalidate timecodes, and, again, they impose an outside party's interpretation of a scene on the student when we'd rather the student interpret the scene for herself. There are, of course, two unavoidable edits — where you start the clip and where you end it.
  • Allow at least five seconds on either end of the scene, though more time is preferred. This will force students to decide when something relevant has begun and ended.
  • No narration. This allows the teacher and students to determine the dialogue.
  • Shoot the highest-definition video possible.
  • Shoot at the fastest possible frame rate given the location lighting.


The goal with classroom presentation is to eliminate the presence of interlopers, to eliminate everyone from the scene but the student, including the teacher, to whatever extent possible. The teacher exists here to scaffold and curate the artifacts, not to suggest, explain, or gesture.

  • The artifact must beg an obvious, compelling, seemingly unsolvable question, a question which begs for more questions and for more information. If the teacher has to suggest, explain, or gesture in order to persuade the student of an artifact's interest, then it isn't compelling or obvious enough for classroom use. (This is the most challenging criterion in this framework. This is the criterion that begs most loudly for open sourcing. The technical aspects of this framework are fairly intuitive but the creative aspects of this framework are extremely challenging and demand collaboration.)
  • Declare nothing and ask only two questions: "What is the next question?" and "What measurements do you need to answer that question?" Again, our ideal digital media shouldn't require any introduction or explanation.
  • Impose a mathematical framework on the scene only as students request it. This is where textbooks fail, imposing a grid or labeling points or establishing measurements before the student has even begun to process the scene. Once the overarching question has been introduced (eg. "will the water balloon land on the target?") the students will see the need for measurements. ("We don't know how high it was dropped.") The teacher then plays the exact same clip with a measurement grid superimposed on the footage. The ideal digital media artifact consists, then, of multiple video or picture or audio files.
  • It is essential to add a timecode, if for no other reason but for student reference ("Can you scan back to five seconds in? I thought I saw something.") but also because the timecode will allow for time-based calculation. The timecode needs to take the format Minutes:Seconds:HundredthsOfASecond not Minutes:Seconds:Frames.
  • Invite the students to estimate the answer to the chosen question. Take five student estimates and post them on the wall. This offers the students a low-stress opportunity to consider a correct range for the answer. It also invests them in the problem.
  • Offer the students something tangible to manipulate or measure. A hard copy of a video still, for example, or a digital copy of a video still they can import into a dynamic Geometry system like Geogebra or a photo and video analysis program like LoggerPro or Tracker.
  • The final element in one of these digital media artifacts must provide the payoff for the mathematical work. It needs to confirm, for example, that the water balloon did or did not land on its target, or it needs to flashback to the moment the water balloon was dropped, revealing the height of the drop. The classroom discussion can then turn to possible sources of error or calculations of percent error.