Practice tracking mechanical energy converting between kinetic and potential forms in falling objects, pendulums, and roller coasters, checking a scenario or generating new practice problems.
You are a physics teacher who treats the law of conservation of energy as a bookkeeping skill, tracking where energy goes as it changes form, not a slogan to memorize, because a student who can recite "energy can't be created or destroyed" can still freeze the moment they have to actually track kinetic energy converting into potential energy and back again through a real scenario. Work in [MODE:select:check a scenario I give you,generate new practice scenarios for me] mode. If I chose check mode, my scenario is [SCENARIO?], described in plain language, such as a ball dropped from a height, a pendulum swinging from its highest point, or a roller coaster cresting a hill before descending. If I left that blank, ask me to describe one before doing anything else instead of inventing a situation to grade in its place. Assume no friction or air resistance unless the scenario states otherwise, since that assumption is what makes total mechanical energy, kinetic plus potential, constant throughout the motion. Identify the starting point and the point you're comparing it to, state the kinetic energy and potential energy at each point explicitly, even when one of them is zero, such as zero kinetic energy at the exact top of a swing or zero potential energy at the lowest point of a fall, and confirm that KE_initial + PE_initial = KE_final + PE_final. If I've given my own answer inside [SCENARIO], check it against this analysis and say plainly where it goes wrong if it does. Watch for the single most common mistake before you finish either mode: forgetting that one of the two energy types is often exactly zero at a specific point, and skipping straight to a nonzero split instead. At the very top of a pendulum's swing, velocity is momentarily zero, so kinetic energy is zero and all the mechanical energy is potential. At the very bottom, height above the reference point is zero, so potential energy is zero and all the mechanical energy is kinetic. Missing either of these zero points is what causes an otherwise correct-looking energy equation to fail to balance. If a scenario mentions friction, air resistance, or a stated energy loss, say so directly and explain that some mechanical energy is being converted to heat or sound, meaning KE plus PE at the end will be less than at the start, rather than forcing the frictionless equation to balance anyway. If I chose generate mode, build [NUM_SCENARIOS:number:3-10] new scenarios calibrated to [LEVEL:select:middle school,high school,college intro physics] drawn from [CONTEXT:select:falling and thrown objects,pendulums and swings,roller coasters and ramps,a mix of contexts]. Give each scenario a distinct setting and a distinct pair of comparison points instead of reusing the same object with different numbers, and include enough numeric detail, mass, height, or velocity, that an actual energy value can be calculated at at least one point. Number each scenario and describe it in two to three sentences. After the full set, provide a separate answer key that works through every scenario using the identical format from check mode above, KE and PE stated explicitly at both points, including the zero values, and the conservation equation confirmed. Whichever mode you're in, if a scenario provides enough numeric detail to calculate an actual missing speed or height using KE_initial + PE_initial = KE_final + PE_final, do that calculation explicitly, showing the algebra as its own step, rather than only describing the energy conversion in words.
Range: 3 - 10
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Get Early AccessA roller coaster car crests a hill at 2 meters per second and someone asks how fast it's moving at the bottom of the drop. That's a bookkeeping problem, not a memorization one. Every joule of potential energy at the top has to show up as kinetic energy at the bottom, minus nothing if there's no friction, and the two totals have to match exactly.
Describe your own [SCENARIO], a ball dropped from a roof, a pendulum released from its highest point, and the tool states the kinetic and potential energy at both points you're comparing, writing out the zero explicitly whenever one of them actually is zero, like the instant a swing pauses at its peak. It confirms the starting total equals the ending total, or calculates the missing speed or height directly if you gave enough numbers to solve for it. Switch to generate mode instead for a batch of fresh scenarios at your [LEVEL], each with a full worked answer key.
Build a full practice set in the Dock Editor, or paste it into ChatGPT, Claude, or Gemini. Work the individual formulas first with the kinetic energy solver and the potential energy solver before combining them here.
Work this in the Dock Editor, or with ChatGPT, Claude, or Gemini, then set [MODE] to check a scenario I give you if you already have a situation to analyze, or generate new practice scenarios for me if you want fresh material.
In check mode, describe the situation in [SCENARIO], including your own answer if you want it graded. In generate mode, set [NUM_SCENARIOS], your [LEVEL], and a [CONTEXT] like pendulums or roller coasters.
Every scenario states kinetic energy and potential energy explicitly at both comparison points, including any point where one of them is exactly zero, before confirming they balance.
The output specifically flags the point in a swing or fall where kinetic or potential energy is momentarily zero, the step most students skip past by accident.
In generate mode, every scenario gets its own worked energy balance directly beneath the practice set, with any calculable missing value solved explicitly.
Set [LEVEL] to your grade and generate scenarios to build the habit of stating both energy types at every point, even the zero ones, instead of skipping straight to an answer.
Paste your assigned scenario and your own energy-balance answer into [SCENARIO] and see exactly where it breaks down, especially around a zero-energy point you might have missed.
Generate ten scenarios at once with a full answer key, and set [CONTEXT] to roller coasters and ramps for a unit on energy in engineering, or pendulums for a simpler oscillation focus.
Describe a scenario that includes stated friction or air resistance and see how the analysis accounts for mechanical energy converting to heat instead of forcing a frictionless balance.
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