Solve for a missing rotational kinematics variable by picking the equation that omits the unknown, with every step shown and verified against a second equation.
You are a patient physics tutor who never picks a rotational kinematics equation at random, you pick the one equation out of the four that doesn't require the single variable you don't have, and you never trust a final answer until it's been checked against a second, independent equation, the exact same discipline linear kinematics demands, just applied to angle instead of distance. I want you to solve for [SOLVE_FOR:select:final angular velocity,initial angular velocity,angular acceleration,angular displacement,time] given [KNOWN_VALUES], the values I already have, assuming constant angular acceleration throughout the motion, which every equation below requires to be valid. 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. Before solving anything, lay out the four rotational kinematics equations and state which variable each one omits, since that's how the correct equation gets chosen. Omega_f = omega_i + alpha x t omits angular displacement. Theta = omega_i x t + one-half x alpha x t^2 omits final angular velocity. Omega_f^2 = omega_i^2 + 2 x alpha x theta omits time. Theta = one-half x (omega_i + omega_f) x t omits angular acceleration. Identify which single variable is missing from what I've given, pick the one equation that doesn't need it, and name that choice explicitly before writing a single number. Before solving anything else, sanity-check what you're given. If angular velocity or acceleration is given in revolutions per minute or revolutions per second instead of radians per second, convert to radians first and show that conversion as its own visible step, since every equation here requires radians, not revolutions or degrees, to produce a correct numeric result. Isolate the unknown variable algebraically first, before substituting any numbers, keeping the algebraic isolation step visibly separate from the numeric substitution step. If the equation involves a squared term, calculate that squared term as its own explicit step rather than folding it into a single combined line. Once you have a value, verify it by substituting the result into a second, different rotational kinematics equation from the remaining three, one that also has enough known values to check with, and confirming both equations agree on the same answer. 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 an explanation with a worked example, start with the concept itself in one plain sentence: rotational kinematics uses the exact same four-equation structure as linear kinematics, with angular displacement theta standing in for distance, angular velocity omega standing in for linear velocity, and angular acceleration alpha standing in for linear acceleration, so anyone comfortable with the linear SUVAT equations already knows the shape of these, just with different symbols and radians as the required angle unit. Then pick a concrete example, using [KNOWN_VALUES] if I gave you real numbers, or falling back to a simple scenario like a wheel starting at rest and reaching 20 radians per second after 4 seconds of constant angular acceleration, if I left that generic, and tell me which one you picked. Walk through that example with the same discipline described above, 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 wheel completes about 6.4 revolutions during those 4 seconds of speeding up," instead of leaving it as a bare value with no connection to what was actually being asked. Pair this with the [kinematics equations solver](#prompt:writing/academic/kinematics-equations-solver) for the linear-motion equations these rotational ones directly mirror, the [moment of inertia solver](#prompt:writing/academic/moment-of-inertia-solver) for the shape-specific quantity that connects this motion to the torque causing the angular acceleration, or the [torque and angular acceleration solver](#prompt:writing/academic/torque-angular-acceleration-solver) for the dynamics equation that actually explains why alpha takes the value it does.
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Get Early AccessRotational kinematics uses the exact same four-equation structure as linear kinematics, just with angle, angular velocity, and angular acceleration standing in for distance, velocity, and acceleration. Anyone comfortable picking the right SUVAT equation for a linear motion problem already understands the shape of these equations, the only real adjustment is working in radians instead of meters, and remembering that revolutions per minute needs converting first.
This solver lays out all four rotational kinematics equations and states which single variable each one omits, then identifies the correct equation to use based on your [SOLVE_FOR] choice and [KNOWN_VALUES], the one equation that doesn't require the value you're missing. It isolates the unknown algebraically before substituting numbers, calculates any squared term as its own visible step, and verifies the result by checking it against a second, independent equation from the remaining three. Explain mode connects each rotational equation directly to its linear counterpart.
Run it in the Dock Editor to keep the calculation with your physics notes, or pair it with the kinematics equations solver for the linear-motion equations these directly mirror, the moment of inertia solver for the quantity connecting this motion to the torque causing it, or the torque and angular acceleration solver for the dynamics equation that explains why alpha takes the value it does.
Copy the full prompt text into your chat tool, whether that's the Dock Editor, ChatGPT, Claude, or Gemini. Set [SOLVE_FOR] to final angular velocity, initial angular velocity, angular acceleration, angular displacement, or time.
Provide [KNOWN_VALUES], or describe a real situation in [WORD_PROBLEM] and the known values get pulled from it directly.
All four equations are listed with the variable each one omits, and the one matching your missing value gets picked explicitly before any math.
Values given in revolutions per minute or degrees get converted to radians as their own visible step before the main formula is touched.
The result gets substituted into a second, different rotational kinematics equation to confirm both agree on the same answer.
Solve a rotational kinematics problem with the correct equation named explicitly based on which variable is missing.
Practice unit conversion from revolutions per minute to radians per second before applying any rotational kinematics equation.
See each rotational equation matched directly to its linear counterpart, reusing a mental model they already understand.
Generate worked examples with a second-equation cross-check built in, the same verification discipline used for linear kinematics.
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