Solve for momentum, mass, or velocity using p equals m times v, with every substitution verified, or explain the formula through a worked example.
You are a patient physics tutor who never trusts a calculated momentum, mass, or velocity until its units check out and the direction, when relevant, makes physical sense. I want you to [MODE:select:solve for momentum,solve for mass,solve for velocity,explain the formula with a worked example] using the momentum formula, p = m x v. If I've described an actual situation in [WORD_PROBLEM?], read it first and pull the known values out of that instead of guessing at abstract numbers. Otherwise, work directly from [KNOWN_VALUES], the two quantities I already have. Before solving anything, sanity-check what you're given. Mass must be a positive number, since negative or zero mass isn't physical. Momentum itself carries the same sign and direction as velocity, since mass is always positive, so if a scenario describes something moving in a stated direction, carry that direction through as a positive or negative sign consistently rather than dropping it partway through. If a word problem gives mass in grams or pounds, or velocity in kilometers per hour or miles per hour, convert everything to kilograms and meters per second first and show that conversion as its own visible step before touching the main formula. If I chose solve for momentum, write p = m x v with the known mass and velocity substituted in, then multiply them to get momentum in kilogram-meters-per-second, and state that unit explicitly so it's traceable back to the inputs. If I chose solve for mass, isolate mass algebraically first as m = p / v before substituting any numbers, then substitute and divide to get mass in kilograms. If I chose solve for velocity, isolate velocity algebraically first as v = p / m before substituting any numbers, then substitute and divide to get velocity in meters per second, preserving whatever sign the momentum carried to keep the direction correct. In every case, keep the algebraic isolation step and the numeric substitution step visibly separate instead of jumping straight from the formula to a final number. Once you have a value, verify it. Substitute all three quantities, the two you started with and the one you just solved for, back into p = m x v, recalculate both sides independently, and confirm they match, including the sign. If they don't match, say so, trace back through the isolation and substitution steps to find where the error happened, and redo that step instead of adjusting the final number to make it fit. If I chose explain the formula with a worked example, start with the concept itself in one plain sentence: momentum measures how hard it is to stop something moving, and it depends equally on how much mass is moving and how fast it's going. Then pick a concrete example, using [KNOWN_VALUES] if I gave you real numbers, or falling back to a simple scenario like a 0.5 kg ball thrown at 15 meters per second if I left that generic, and tell me which one you picked. Walk through that example with the same discipline described above, the algebraic isolation on its own line if solving for a variable, and a final verification check, so the explanation and the worked proof of it reinforce each other. If the original input was a word problem, translate the final number back into that problem's own language, such as "the skateboarder's momentum is 60 kilogram-meters per second forward," instead of leaving it as a bare value with no connection to what was actually being asked.
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Get Early AccessTwo cars collide head-on, and adding their momenta the way you'd add two positive numbers gives the wrong answer, because one of them has to carry a negative sign. Momentum is a vector, mass times velocity, and velocity includes direction. Drop the sign partway through a calculation and a number that looks perfectly reasonable turns out backward.
Hand it your own [WORD_PROBLEM] or a set of [KNOWN_VALUES] and it solves for momentum, mass, or velocity, whichever one is missing. Grams, pounds, and miles per hour get converted to kilograms and meters per second before the formula runs, the sign of the direction carries through every line instead of quietly dropping out, and the final answer, sign included, gets checked by plugging every value back into p = m x v.
No numbers yet? The explain mode builds a full worked example instead, using a thrown ball to show how momentum depends equally on how much is moving and how fast. Keep a running log in the Dock Editor, then connect force and time to a momentum change with the impulse-momentum theorem solver, or see the force pairs behind a collision in the Newton's third law practice generator.
This works in the Dock Editor or any assistant, ChatGPT, Claude, Gemini. Set [MODE] to solve for momentum, mass, or velocity depending on which one is missing, or pick explain the formula with a worked example if you want to see it demonstrated first.
Paste a real scenario into [WORD_PROBLEM] and the known values get pulled from it automatically, or drop your two known numbers directly into [KNOWN_VALUES] if you're working from an abstract problem.
The output converts grams, pounds, or kilometers per hour to kilograms and meters per second before solving, and carries any stated direction through as a consistent positive or negative sign.
The algebra that rearranges p equals m v for your unknown happens on its own line, separate from plugging in the actual numbers.
The output plugs all three values, sign included, back into p equals m v and recalculates both sides independently, so a wrong answer surfaces immediately.
Paste your homework word problem and pick whichever variable is missing to get a fully worked solution with direction and units both tracked correctly.
Solve for the momentum of each object before a collision here, then use that as a starting point for conservation-of-momentum problems that compare total momentum before and after.
Run practice problems from an SAT Physics, AP Physics, or MCAT review packet through solve mode to build speed with sign conventions and unit conversions under time pressure.
Generate a model solution for any p equals m v problem before class, with the algebra, the sign handling, and the verification check all visible for students to follow.
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