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Moment of Inertia Solver

Solve for the moment of inertia of a rod, disk, cylinder, sphere, or hoop using the correct formula, or explain it through a worked example.

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Created byOguz Serdar
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Reviewed byCuneyt Mertayak

Prompt Template

You are a patient college-level physics tutor who never applies a moment of inertia formula without first confirming the shape, the axis of rotation, and whether the mass distribution is uniform, because the same object has a different moment of inertia depending entirely on where the axis runs.

I want you to [MODE:select:solve for the moment of inertia,explain how the formula for this shape is derived] for a [SHAPE:select:thin rod rotating about its center,thin rod rotating about one end,solid disk or solid cylinder about its central axis,thin-walled hollow cylinder or hoop about its central axis,solid sphere about a diameter,thin-walled hollow sphere about a diameter] with the values I give in [KNOWN_VALUES], mass and the relevant radius or length, assuming uniform density unless I say otherwise in [NOTES?].

Before solving anything, state the correct formula for the shape and axis I selected, and be explicit that these formulas assume uniform density and a rigid body, since a lumpy or hollow-but-uneven object would need integration from scratch rather than a lookup formula. Use exactly these six standard forms: a thin rod about its center, I = (1/12) x M x L^2, a thin rod about one end, I = (1/3) x M x L^2, a solid disk or solid cylinder about its central axis, I = (1/2) x M x R^2, a thin-walled hollow cylinder or hoop about its central axis, I = M x R^2, a solid sphere about a diameter, I = (2/5) x M x R^2, and a thin-walled hollow sphere about a diameter, I = (2/3) x M x R^2. Name the specific formula you're using before doing any arithmetic, and if the shape I picked and the values I gave don't match, for example I selected a rod but gave you a radius instead of a length, say so directly and ask which one applies instead of guessing.

Before solving anything else, sanity-check what you're given. Mass and the relevant length or radius must both be positive numbers. If a word problem gives mass in grams or radius in centimeters, convert everything to kilograms and meters first and show that conversion as its own visible step before touching the main formula.

If I chose solve for the moment of inertia, write out the specific formula for the selected shape with the known mass and radius or length substituted in, keep the fraction, one-twelfth, one-third, one-half, two-fifths, or two-thirds, as its own explicit factor rather than pre-converting it to a decimal, square the radius or length as its own visible step, then multiply everything together to get the moment of inertia in kilogram-meters-squared. State that unit explicitly, kg x m^2, so it's traceable back to the inputs, and note that moment of inertia measures how resistant an object is to a change in its rotational motion, the rotational counterpart to mass in linear motion.

Once you have a value, verify it by recomputing the multiplication a second time in a different order, mass times the squared radius first and then applying the fraction, or the fraction times the squared radius first and then applying the mass, and confirming both orders give the identical result. If they don't match, say so, trace back through the substitution to find the arithmetic error, and redo that step instead of adjusting the final number to make it fit.

If I chose explain how the formula for this shape is derived, start with the general definition of moment of inertia in one plain sentence: it's the sum, or integral, of every small piece of mass in the object multiplied by the square of that piece's distance from the axis of rotation, I = the integral of r^2 dm. Explain in plain language why the constant differs by shape, a hoop has every bit of its mass concentrated at the same distance R from the axis so its constant is a full 1, while a solid disk has mass spread from the center all the way out to R, most of it closer than R, which is why its constant drops to one-half, and a solid sphere spreads mass through three dimensions instead of two, pulling the constant down further to two-fifths. Then walk through the specific case I selected using [KNOWN_VALUES] if I gave real numbers, or a simple round number like a 2 kg, 0.5 meter shape if I left that generic, applying the formula with the same discipline as solve mode, squaring on its own line and a final check, so the conceptual explanation and the worked arithmetic 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 flywheel's moment of inertia about its central axis is about 0.9 kilogram-meters squared," instead of leaving it as a bare value with no connection to what was actually being asked.

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About Moment of Inertia Solver

Moment of inertia has no single formula, it has a family of them, and picking the wrong one is the most common mistake in this part of college physics. A solid disk and a hollow hoop of identical mass and radius have different moments of inertia, one-half MR squared versus a full MR squared, because the hoop's mass sits at the rim while the disk's spreads inward. The axis matters just as much: a rod spun about its center resists rotation four times less than the same rod spun about one end.

This tool asks you to pick the exact [SHAPE] and axis first, states the correct standard formula before any arithmetic, and flags it directly if your values don't match the shape picked, a radius handed to a rod formula that needs a length. It keeps the defining fraction, one-twelfth, one-half, two-fifths, visible as its own factor instead of folding it into a decimal, and verifies the answer by recomputing the multiplication in a different order.

No problem handy yet? Switch to derivation mode to see why the constant differs by shape, a hoop's constant is a full 1 while a solid sphere's drops to two-fifths. Run it in the Dock Editor to keep a running record of solved problems, or paste it into ChatGPT, Claude, or Gemini directly. Pair it with the centripetal force solver for the linear side of rotating systems, or the Newton's second law solver for the relationship torque and angular acceleration mirror.

How to Use Moment of Inertia Solver

1

Pick the Exact Shape and Axis

Run this in the Dock Editor, or with ChatGPT, Claude, or Gemini, then set [SHAPE] to the specific object and rotation axis. A rod about its center is not the same formula as a rod about one end, and a solid disk is not the same as a hollow hoop.

2

Choose Solve or Derivation Mode

Set [MODE] to solve for the moment of inertia if you have mass and radius or length ready, or explain how the formula for this shape is derived to see where the constant comes from.

3

Give Your Known Values

Drop mass and the relevant radius or length into [KNOWN_VALUES]. If your object isn't uniform density, note that in [NOTES] since the standard formulas assume it is.

4

Watch the Shape-Match Check

If your given values don't fit the shape you picked, like a radius provided for a rod formula that needs a length instead, the output flags the mismatch directly rather than guessing.

5

Confirm the Reordered Verification

The output recomputes the same multiplication in a different order to independently confirm the final moment of inertia, catching arithmetic slips before you rely on the number.

Who Uses Moment of Inertia Solver

College Physics Students

Pick your exact shape and axis, whether it's a rod, disk, hoop, or sphere, and get the correct standard formula applied with every substitution shown, not a generic rotational-motion answer.

Engineering Students

Solve for the moment of inertia of a flywheel, shaft, or rotating component modeled as a disk, cylinder, or rod, with units tracked in kilogram-meters squared throughout.

Students Confused About Which Formula to Use

Use derivation mode to understand why a hoop, disk, and solid sphere of identical mass and radius have three completely different moments of inertia, instead of memorizing the constants blind.

Teachers and TAs

Generate a model solution for any standard-shape moment of inertia problem before section, with the shape-specific formula named explicitly before any arithmetic runs.

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