What is the difference between mass moment of inertia and area moment of inertia?

Mass moment of inertia (rotational inertia) measures resistance to angular acceleration and has units of kg·m². Its formula is I = Smr² and it is used in rotation dynamics with Newton's second law for rotation: t = I×a. Area moment of inertia (second moment of area) measures a cross-section's resistance to bending and has units of m4 or mm4. Its formula is I = ?y²dA and it is used in structural engineering with the flexure formula: s = M×y/I. Both use the symbol I but they are completely different quantities.

How does the moment of inertia affect rotation?

Moment of inertia (rotational inertia) is the rotational equivalent of mass. Newton's second law for rotation is t = I×a, where t is torque (N·m), I is moment of inertia (kg·m²), and a is angular acceleration (rad/s²). A higher I means more torque is needed to produce the same angular acceleration. Rotational kinetic energy is KE = (1/2)I?². Angular momentum is L = I×?. Distributing mass farther from the rotation axis increases I — this is why flywheels have mass concentrated at the rim.

📐 Engineering Calculator

Moment of Inertia Calculator

Q: What is the moment of inertia formula for a rectangle?

The area moment of inertia of a rectangle about its centroidal x-axis is I = bh³/12, where b is the width and h is the height. About the centroidal y-axis: I = hb³/12. About the base: I = bh³/3. The section modulus is S = bh²/6. For a 100×200mm rectangle: I_x = 100×200³/12 = 66,666,667 mm4.

Q: What is the moment of inertia of a rod about its center?

The moment of inertia of a thin rod about a perpendicular axis through its center is I = mL²/12, where m is the mass and L is the length. For a rod about one end: I = mL²/3. The parallel axis theorem connects them: I_end = I_center + m(L/2)² = mL²/12 + mL²/4 = mL²/3. Example: m=0.8kg, L=1.2m ? I_center = 0.8×1.44/12 = 0.096 kg·m².

Q: What is the moment of inertia of a solid sphere?

The moment of inertia (rotational inertia) of a solid sphere about any diameter axis is I = (2/5)mR² = 0.4mR², where m is mass and R is radius. For m=1kg, R=0.05m: I = 0.4×1×0.0025 = 0.001 kg·m². A hollow spherical shell has I = (2/3)mR², which is higher because mass is concentrated at the outer radius.

Q: How do you find the moment of inertia of a disk about its edge?

Use the parallel axis theorem: I_edge = I_center + m×d². For a disk, I_center = (1/2)mR² and d = R (distance from center to edge). Therefore I_edge = (1/2)mR² + mR² = (3/2)mR². Example: m=2kg, R=0.1m ? I_edge = 1.5×2×0.01 = 0.03 kg·m².

Q: What is the parallel axis theorem?

The parallel axis theorem states that I = I_cm + m×d² for mass moment of inertia, where I_cm is the moment of inertia about the center of mass axis, m is mass, and d is the perpendicular distance between the two parallel axes. For area moment of inertia: I = I_centroid + A×d². This theorem lets you find I about any axis if you know I about the centroidal parallel axis.

Q: What is section modulus and how is it calculated?

Section modulus S = I/y_max, where I is the area moment of inertia and y_max is the distance from the centroid to the extreme fibre. Units are mm³ or m³. It is used in beam design: s_max = M/S (maximum bending stress = bending moment divided by section modulus). For a rectangle: S = bh²/6. For a circle: S = pd³/32. A larger section modulus means less bending stress for the same moment.

Q: What is the moment of inertia of a thin hoop?

For a thin hoop (ring) about its central axis (perpendicular to the plane): I = mR² = mR². All mass is at radius R so this gives the maximum possible I for a given mass and radius. About a diameter axis: I = (1/2)mR². For a thick ring (annulus) with inner radius r and outer radius R about central axis: I = (1/2)m(R²+r²). Example: m=0.5kg, R=0.2m ? I_central = 0.5×0.04 = 0.02 kg·m².

Q: What is the polar moment of inertia?

The polar moment of inertia J is the area moment of inertia about an axis perpendicular to the cross-section (the z-axis through the centroid). J = I_x + I_y. For a circle: J = pR4/2 = pd4/32. For a rectangle: J = bh(h²+b²)/12. It is used in torsion calculations: t_max = T×R/J, where T is torque. A larger J means less shear stress for the same torque.

This moment of inertia calculator covers both mass moment of inertia (rotational inertia, kg·m²) for rotation dynamics and area moment of inertia (second moment of area, mm4) for beam bending and structural engineering — for all common shapes including rectangle, circle, rod, sphere, cylinder, ring, cone, and hollow sections. Every result includes the formula and full step-by-step working with numbers substituted.

🌀 Mass Moment of Inertia Rotation • Physics • Dynamics • Flywheels • Shafts kg·m² I = Σmr²

📐 Area Moment of Inertia Beams • Bending • Structural • Section Modulus mm4 / m4 I = ∫y²dA

🌀 Mass Moment of Inertia (Rotational Inertia) — kg·m²

Select a shape to calculate its rotational inertia. Formula: I = Σmr². Results shown in kg·m², kg·cm², g·cm², lb·ft², lb·in².

I_axis = ½mR² | I_diam = ¼mR² + &frac{1}{12}mL² | I_edge = &frac32;mR²

axis = spinning like a wheel | diam = end-to-end | edge = parallel axis theorem

Mass m

Radius R

Length L

Output Units

I = ⅖mR² = 0.4 × m × R²

About any diameter axis — rotational inertia of a sphere

Mass m

Radius R

I = ⅔mR²

Hollow sphere / spherical shell — compare: solid = 2/5 mR²

Mass m

Outer Radius R

I_central = mR² (thin hoop) | I_diam = ½mR² | I_annulus = ½m(R²+r²)

Set inner radius r = 0 for thin hoop. The formula I = mR² applies when all mass is at radius R.

Mass m

Outer Radius R

Inner Radius r (0 = thin hoop)

I_center = &frac{1}{12}mL² | I_end = ⅓mL²

Perpendicular axis through midpoint or one end — moment of inertia of a rod

Mass m

Length L

I_z = &frac{1}{12}m(a²+b²) | I_x = &frac{1}{12}m(b²+c²) | I_y = &frac{1}{12}m(a²+c²)

a = length | b = width | c = height | all axes through center of mass

Mass m

Length a

Width b

Height c

I_axis = &frac{3}{10}mR²

About central axis through apex and centre of base — moment of inertia of cone

Mass m

Base Radius R

Height h

I = I_cm + m × d²

I_cm = MOI about centre of mass | d = distance between parallel axes | Also: I_cm = I − md²

I_cm (kg·m²)

Mass m (kg)

Distance d (m)

📐 Area Moment of Inertia (Second Moment of Area) — mm4 / m4

Select a cross-section shape. I = ∫y²dA. Used in beam bending: σ = M×y/I. Section modulus S = I/y_max.

I_x = bh³/12 | I_y = hb³/12 | I_base = bh³/3 | S = bh²/6

b = width | h = height | I_x about centroidal horizontal axis | area moment of inertia of a rectangle

Width b

Height h

Output Units

I = πR4/4 = πd4/64 | J = πR4/2 | S = πR³/4 | k = R/2

Solid circle: set inner radius = 0. Hollow circle (pipe): I = π(R4−r4)/4

Outer Radius R (or Diameter d/2)

Inner Radius r (0 = solid circle)

Output Units

I_x = (BH³ − bh³)/12 | I_y = (HB³ − hb³)/12

B,H = outer dims | b = B−2t | h = H−2t | t = wall thickness

Outer Width B

Outer Height H

Wall Thickness t

Output Units

I_base = πR4/8 | ŷ = 4R/(3π) | I_centroid = R4(π/8 − 8/(9π))

Centroid measured from base (diameter) — second moment of area of half circle

Radius R

Output Units

Mass Moment of Inertia vs Area Moment of Inertia — What is the Difference?

The symbol I is used for two completely different quantities in engineering. The mass moment of inertia (also called rotational inertia) measures how difficult it is to angularly accelerate a rotating body — it depends on how mass is distributed relative to the rotation axis. The area moment of inertia (also called second moment of area) measures how a cross-section resists bending — it depends on how the cross-sectional area is distributed relative to the bending axis. Always check units: kg·m² means rotational inertia; mm4 or m4 means second moment of area.

Property	Mass Moment of Inertia	Area Moment of Inertia
Also called	Rotational inertia	Second moment of area
Symbol	I (kg·m²)	I (m4 or mm4)
Formula	I = Σmr²	I = ∫y²dA
Units	kg·m²	m4 or mm4
Used in	Rotation dynamics, angular acceleration	Beam bending, deflection, stress
Relevant equation	τ = I × α	σ = M × y / I
Example use	Spinning flywheel, rotating shaft	Steel beam deflection, column buckling
Depends on	Mass distribution and axis location	Cross-section shape and axis location

The polar moment of inertia J = I_x + I_y is the sum of the two area moments of inertia and is used in torsion calculations: τ_max = T×R/J. Both area moment of inertia and polar moment of inertia are second moments of area — different axes, same concept.

Mass Moment of Inertia Formulas — Reference Table

All formulas below give rotational inertia I in kg·m² when mass is in kg and dimensions in metres. The fundamental formula is I = Σmr² — each element of mass multiplied by the square of its distance from the axis. Note that I = mR² appears for the thin hoop, I = mR² is the baseline maximum for a given mass and radius.

Shape	Axis	Formula	Notes
Solid cylinder / disk	Central (spinning)	I = ½mR²	Wheel-like spin
Solid cylinder	Diameter (end-to-end)	I = ¼mR² + &frac{1}{12}mL²	Tumbling axis
Disk about edge	Tangent to rim	I = &frac32;mR²	Parallel axis theorem
Solid sphere	Any diameter	I = ⅖mR²	Rotational inertia of a sphere
Hollow sphere (shell)	Any diameter	I = ⅔mR²	Higher than solid sphere
Thin hoop / ring	Central axis (⊥ to plane)	I = mR²	All mass at radius R; thin hoop moment of inertia
Thin hoop	Diameter axis	I = ½mR²	In-plane axis
Thick ring / annulus	Central axis	I = ½m(R²+r²)	Inertia of a ring with wall thickness
Thin rod	Through center (⊥)	I = &frac{1}{12}mL²	Moment of inertia of a rod about center
Thin rod	Through end (⊥)	I = ⅓mL²	Moment of inertia of a rod about end
Rectangular box	z-axis through center	I = &frac{1}{12}m(a²+b²)	Moment of inertia of a box
Rectangular box	x-axis through center	I = &frac{1}{12}m(b²+c²)	Rotational inertia of a cube when a=b=c
Solid cone	Central axis	I = &frac{3}{10}mR²	Moment of inertia of cone; about base axis
Thin plate (a×b)	Through center parallel to b	I = &frac{1}{12}ma²	Moment of inertia of a plate

Area Moment of Inertia Formulas — Reference Table

These formulas give the second moment of area I in mm4 when dimensions are in mm. The formula I = bh³/12 is fundamental — it appears for rectangles about their centroidal axis. The section modulus S = I / y_max is used in beam design to find maximum bending stress: σ_max = M/S.

Cross-section	Axis	Formula	Section Modulus S
Rectangle (b×h)	Centroidal x (horiz)	I = bh³/12	S = bh²/6
Rectangle (b×h)	Base	I = bh³/3	—
Rectangle (b×h)	Centroidal y (vert)	I = hb³/12	S = hb²/6
Square (a×a)	Centroidal	I = a4/12	S = a³/6
Hollow rectangle	Centroidal x	I = (BH³−bh³)/12	S = I/(H/2)
Circle (radius R)	Any diameter	I = πR4/4	S = πR³/4
Circle (diameter d)	Any diameter	I = πd4/64	S = πd³/32
Hollow circle / pipe	Any diameter	I = π(R4−r4)/4	S = I/R
Semicircle (radius R)	Base (diameter)	I = πR4/8	—
Semicircle	Centroidal (∥ to base)	I = R4(π/8−8/(9π))	S = I/(R−ŷ)
Triangle (b×h)	Base	I = bh³/12	—
Triangle (b×h)	Centroidal	I = bh³/36	—

Parallel Axis Theorem — How to Find Moment of Inertia About Any Axis

The parallel axis theorem allows you to find the moment of inertia about any axis if you know the moment of inertia about a parallel axis through the centroid (or centre of mass for mass MOI). Both the mass and area versions follow the same principle.

I = I_cm + m × d² (Mass MOI)

I_cm = MOI about centre of mass | m = total mass | d = perpendicular distance between axes

I = I_centroid + A × d² (Area MOI)

I_centroid = second moment about centroidal axis | A = cross-sectional area | d = distance between axes

Worked Example 1 — Rod About End From Center

I about center: I_cm = (1/12)mL²
Distance from center to end: d = L/2
I_end = (1/12)mL² + m(L/2)² = (1/12)mL² + (1/4)mL²
I_end = mL²(1/12 + 3/12) = mL²(4/12) = (1/3)mL² ✓

Worked Example 2 — Disk About Edge

I about center (spinning): I_cm = (1/2)mR²
Distance from center to rim: d = R
I_edge = (1/2)mR² + mR² = (3/2)mR² ✓
Example: m=2kg, R=0.1m → I_edge = 1.5×2×0.01 = 0.03 kg·m²

Worked Example 3 — Rectangle About Base From Centroid

I about centroid: I_x = bh³/12
Area A = b×h, distance from centroid to base: d = h/2
I_base = bh³/12 + (bh)(h/2)² = bh³/12 + bh³/4 = bh³/12 + 3bh³/12 = bh³/3 ✓

Section Modulus Calculator — Rectangle Circle and Hollow Sections

Section modulus S = I / y_max, where I is the area moment of inertia and y_max is the distance from the centroid to the extreme (outermost) fibre. Units are mm³ or m³ — one order of dimension lower than I (mm4). The section modulus is the single most important property for beam design because maximum bending stress equals σ_max = M / S, where M is the applied bending moment.

Section Modulus Formulas — Common Cross-Sections

Rectangle: S_x = bh²/6 | S_y = hb²/6
Circle (diameter d): S = πd³/32
Hollow circle: S = π(D4−d4)/(32D)
Square tube (outer B×H, inner b×h): S = (BH³−bh³)/(6H)

Elastic vs Plastic section modulus: The elastic section modulus S_e = I/y_max assumes linear stress distribution (used for serviceability). The plastic section modulus S_p assumes full yielding across the section (used for ultimate strength design). S_p > S_e always.

Worked Example — Maximum Bending Stress in Rectangular Beam

Rectangular beam: b=50mm, h=100mm, M=5 kN·m

I_x = bh³/12 = 50×100³/12 = 4,166,667 mm4
y_max = h/2 = 50 mm
S_x = I/y_max = 4,166,667/50 = 83,333 mm³
σ_max = M/S = 5,000,000 N·mm / 83,333 mm³ = 60 N/mm² = 60 MPa

Moment of Inertia of a Rod

The moment of inertia of a rod describes the rotational inertia of a thin uniform rod rotating about an axis perpendicular to its length. There are two standard cases, and the parallel axis theorem connects them. Note that rotation about the rod's own length axis gives I ≈ 0 for a thin rod (negligible radius).

Case 1 — Axis Through Centre (Perpendicular)

I_center = &frac{1}{12}mL²

Perpendicular axis through the midpoint of the rod

This is the minimum moment of inertia for a rod rotating perpendicular to its length. The mass is distributed symmetrically about the centre, so distances range from 0 (at center) to L/2 (at ends), giving I = (1/12)mL².

Case 2 — Axis Through One End (Perpendicular)

I_end = ⅓mL²

Perpendicular axis through one end — exactly 4× the center case (not 3×)

The moment of inertia of a rod about one end is exactly 4 times larger than (1/12)mL² — wait, (1/3)/(1/12) = 4. Yes: rotating about the end is 4× harder than rotating about the center because all mass is now at distances from 0 to L. Via parallel axis theorem: I_end = (1/12)mL² + m(L/2)² = (1/12)mL² + (3/12)mL² = (4/12)mL² = (1/3)mL².

Worked Example 1: m=0.8kg, L=1.2m

L² = 1.2² = 1.44 m²
I_center = (1/12) × 0.8 × 1.44 = 0.096 kg·m²
I_end = (1/3) × 0.8 × 1.44 = 0.384 kg·m²
Check: 0.096 + 0.8×(0.6)² = 0.096 + 0.288 = 0.384 ✓

Worked Example 2: Baton (m=0.2kg, L=0.5m)

I_center = (1/12) × 0.2 × 0.25 = 0.00417 kg·m²
I_end = (1/3) × 0.2 × 0.25 = 0.01667 kg·m²
Torque needed for α = 10 rad/s² about center: τ = 0.00417×10 = 0.0417 N·m

Moment of Inertia of a Rectangle

The moment of inertia of a rectangle is an area moment of inertia (second moment of area) used in structural engineering to quantify a rectangular beam's resistance to bending. The formula is I = bh³/12 about the centroidal horizontal axis, where b is width and h is height (depth). Note that height h appears cubed — this means doubling the depth multiplies bending resistance by 8×, while doubling the width only doubles it. This is why beams are always oriented with their greater dimension vertical.

I_x = bh³/12 | I_y = hb³/12 | I_base = bh³/3

b = width | h = height (depth) | x = centroidal horizontal axis | y = centroidal vertical axis

Example 1: 200×400mm Beam (b=200mm, h=400mm)

I_x = 200×400³/12 = 200×64,000,000/12 = 1,066,666,667 mm4 = 1.067×10? mm4
S_x = I_x/(h/2) = 1,066,666,667/200 = 5,333,333 mm³
A = 200×400 = 80,000 mm²
k_x = √(I/A) = √(1,066,666,667/80,000) = 115.5 mm

Example 2: Square 150×150mm

I_x = I_y = 150×150³/12 = 1504/12 = 42,187,500 mm4
S = I/(h/2) = 42,187,500/75 = 562,500 mm³

Example 3: I about base (b=100mm, h=200mm)

I_centroid = bh³/12 = 100×200³/12 = 66,666,667 mm4
I_base = bh³/3 = 100×200³/3 = 266,666,667 mm4 (= 4 × I_centroid)
Check via parallel axis: 66,666,667 + (100×200)×100² = 66,666,667 + 200,000,000 = 266,666,667 ✓

Worked Examples

1. Moment of Inertia of a Solid Cylinder About Its Axis

A solid cylinder spinning like a wheel uses I = (1/2)mR². For m=5kg, R=0.15m: I = 0.5×5×0.15² = 0.5×5×0.0225 = 0.05625 kg·m². Angular acceleration with 2 N·m torque: α = τ/I = 2/0.05625 = 35.6 rad/s².

2. Moment of Inertia of a Disk About Its Edge

Disk about its edge uses the parallel axis theorem: I_edge = I_center + mR² = (1/2)mR² + mR² = (3/2)mR². For m=2kg, R=0.1m: I_edge = 1.5×2×0.01 = 0.03 kg·m². This is exactly 3× the spinning (central axis) value of 0.01 kg·m².

3. Moment of Inertia of a Rod — Center and End

m=0.8kg, L=1.2m: I_center = (1/12)×0.8×1.44 = 0.096 kg·m². I_end = (1/3)×0.8×1.44 = 0.384 kg·m². Verification: 0.096 + 0.8×0.36 = 0.096 + 0.288 = 0.384 ✓. The end value is 4× the center value.

4. Rotational Inertia of a Sphere

Solid sphere: I = (2/5)mR². For m=3kg, R=0.08m: I = 0.4×3×0.0064 = 0.00768 kg·m². Hollow sphere same mass and radius: I = (2/3)×3×0.0064 = 0.01280 kg·m² — 67% higher because all mass is at the outer surface.

5. Moment of Inertia of a Rectangle for Beam Bending

b=100mm, h=200mm: I_x = 100×200³/12 = 66,666,667 mm4. S_x = bh²/6 = 100×40,000/6 = 666,667 mm³. For M=10 kN·m: σ_max = 10×106/666,667 = 15 MPa.

6. Area Moment of Inertia of a Circular Cross Section

Solid circle d=50mm (R=25mm): I = π×254/4 = π×390,625/4 = 306,796 mm4. J = 2I = 613,592 mm4. S = I/R = 306,796/25 = 12,272 mm³. Radius of gyration k = R/2 = 12.5mm.

7. Using the Parallel Axis Theorem Step by Step

Find I of rectangle (100×200mm) about its base: I_centroid = 100×200³/12 = 66,666,667 mm4. Area A = 20,000 mm². Distance centroid to base d = 100mm. I_base = 66,666,667 + 20,000×100² = 66,666,667 + 200,000,000 = 266,666,667 mm4.

8. Section Modulus for a Rectangular Beam

b=50mm, h=150mm: S_x = bh²/6 = 50×150²/6 = 50×22,500/6 = 187,500 mm³. Maximum allowable moment for σ_allow=120MPa: M = S×σ = 187,500×120 = 22,500,000 N·mm = 22.5 kN·m.

9. Moment of Inertia of a Hollow Sphere

Hollow sphere (spherical shell): I = (2/3)mR². For m=2kg, R=0.1m: I = (2/3)×2×0.01 = 0.01333 kg·m². Compare solid sphere same mass/radius: I = (2/5)×2×0.01 = 0.008 kg·m². The hollow sphere has 67% more rotational inertia — its mass is all at maximum radius.

10. Moment of Inertia of a Thin Hoop About Its Diameter

Thin hoop about diameter axis: I = (1/2)mR². For m=0.5kg, R=0.2m: I = 0.5×0.5×0.04 = 0.01 kg·m². Compare central axis (perpendicular to plane): I = mR² = 0.5×0.04 = 0.02 kg·m². The in-plane (diameter) rotation is half as resistant as the out-of-plane (central axis) rotation.

Frequently Asked Questions

What is the moment of inertia formula for a rectangle? ▼

The area moment of inertia of a rectangle: I_x = bh³/12 (about centroidal x-axis), I_y = hb³/12 (about centroidal y-axis), I_base = bh³/3 (about base). Section modulus S = bh²/6. For b=100mm, h=200mm: I_x = 100×200³/12 = 66,666,667 mm4 = 66.67×106 mm4.

What is the difference between mass and area moment of inertia? ▼

Mass moment of inertia (rotational inertia, kg·m², I=Σmr²) resists angular acceleration in rotating systems (τ=I×α). Area moment of inertia (second moment of area, mm4, I=∫y²dA) resists bending in beams (σ=M×y/I). Same symbol I, completely different physical quantities — always check units.

What is the moment of inertia of a rod about its center? ▼

I = mL²/12. For m=1kg, L=1m: I = 1/12 = 0.0833 kg·m². About one end: I = mL²/3 = 4 times larger. These are perpendicular axes — about the rod's own length axis, I≈0 for a thin rod.

What is the moment of inertia of a solid sphere? ▼

I = (2/5)mR² = 0.4mR² about any diameter axis. For m=1kg, R=0.1m: I = 0.4×1×0.01 = 0.004 kg·m². Hollow sphere (spherical shell): I = (2/3)mR² — 67% higher because all mass is at the maximum radius R.

How do you find the moment of inertia of a disk about its edge? ▼

Use the parallel axis theorem: I_edge = I_center + mR² = (1/2)mR² + mR² = (3/2)mR². For m=2kg, R=0.1m: I_edge = 1.5×2×0.01 = 0.03 kg·m². The disk-about-edge moment of inertia is 3 times the spinning (central axis) value.

What is the parallel axis theorem? ▼

I = I_cm + md² (mass MOI) or I = I_centroid + Ad² (area MOI). It lets you find I about any axis parallel to a centroidal axis. The centroidal I must be known first, then add md² or Ad² for the offset. Example: rod about end = I_center + m(L/2)² = (1/12)mL² + (1/4)mL² = (1/3)mL².

What is section modulus and how is it calculated? ▼

S = I/y_max (mm³). Maximum bending stress σ = M/S. Rectangle: S = bh²/6. Circle: S = πd³/32. For b=100mm, h=200mm: S = 100×200²/6 = 666,667 mm³. With M=10 kN·m: σ_max = 10×106/666,667 = 15 MPa.

What is the moment of inertia of a thin hoop? ▼

Thin hoop central axis (perpendicular to plane): I = mR². This is the maximum possible I for given mass and radius — all mass is at the maximum distance R. About diameter axis: I = (1/2)mR². Thick ring (annulus): I = (1/2)m(R²+r²) about central axis. For m=0.5kg, R=0.2m: I = 0.5×0.04 = 0.02 kg·m².

What is the polar moment of inertia? ▼

J = I_x + I_y — sum of two area moments of inertia, about the z-axis perpendicular to the cross-section. Units mm4. Circle: J = πR4/2 = πd4/32. Rectangle: J = bh(h²+b²)/12. Used in torsion: τ_max = T×R/J. Higher J means less shear stress for the same torque.

How does moment of inertia affect rotation? ▼

Newton's second law for rotation: τ = I×α. Higher I requires more torque for the same angular acceleration. Rotational KE = (1/2)Iω². Angular momentum L = I×ω. Flywheels and gyroscopes deliberately maximise I by placing mass at large radius. Ice skaters pull arms in to reduce I and spin faster (conservation of angular momentum).

Related Calculators

🌀 Mass MOI Quick Reference

Cyl

I = ½mR² (central axis)

Sph

I = ⅖mR² (solid sphere)

HSp

I = ⅔mR² (hollow sphere)

Hoop

I = mR² (thin hoop central)

Rod

I = mL²/12 (center)

Rod

I = mL²/3 (end)

Box

I = m(a²+b²)/12

PAT

I = I_cm + md²

📐 Area MOI Quick Reference

Rect

I = bh³/12 (centroid)

Rect

I = bh³/3 (base)

Circ

I = πR4/4 = πd4/64

Pol

J = πR4/2 = πd4/32

Sec

S = I / y_max = bh²/6

PAT

I = I_c + Ad²

📏 Unit Conversions

kg·m²

1 kg·m² = 10,000 kg·cm² = 107 g·cm²

lb·ft²

1 kg·m² = 23.730 lb·ft² = 3417 lb·in²

mm4

1 mm4 = 10?4 cm4 = 10?¹² m4

in4

1 in4 = 416,231 mm4 = 41.623 cm4

mm³

1 mm³ = 0.001 cm³ = 10?? m³

⚖ Key Equations

τ = I × α
Torque = MOI × angular accel.

KE = ½ Iω²
Rotational kinetic energy

σ = My/I
Bending stress

σ_max = M/S
Max stress via section modulus

τ = TR/J
Torsional shear stress

Moment of Inertia Calculator – Rectangle, Circle, Rod, Sphere & All Shapes

Moment of Inertia Calculator

Mass Moment of Inertia vs Area Moment of Inertia — What is the Difference?

Mass Moment of Inertia Formulas — Reference Table

Area Moment of Inertia Formulas — Reference Table

Parallel Axis Theorem — How to Find Moment of Inertia About Any Axis

Worked Example 1 — Rod About End From Center

Worked Example 2 — Disk About Edge

Worked Example 3 — Rectangle About Base From Centroid

Section Modulus Calculator — Rectangle Circle and Hollow Sections

Section Modulus Formulas — Common Cross-Sections

Worked Example — Maximum Bending Stress in Rectangular Beam

Rectangular beam: b=50mm, h=100mm, M=5 kN·m

Moment of Inertia of a Rod

Case 1 — Axis Through Centre (Perpendicular)

Case 2 — Axis Through One End (Perpendicular)

Worked Example 1: m=0.8kg, L=1.2m

Worked Example 2: Baton (m=0.2kg, L=0.5m)

Moment of Inertia of a Rectangle

Example 1: 200×400mm Beam (b=200mm, h=400mm)

Example 2: Square 150×150mm

Example 3: I about base (b=100mm, h=200mm)

Worked Examples

1. Moment of Inertia of a Solid Cylinder About Its Axis

2. Moment of Inertia of a Disk About Its Edge

3. Moment of Inertia of a Rod — Center and End

4. Rotational Inertia of a Sphere

5. Moment of Inertia of a Rectangle for Beam Bending

6. Area Moment of Inertia of a Circular Cross Section

7. Using the Parallel Axis Theorem Step by Step

8. Section Modulus for a Rectangular Beam

9. Moment of Inertia of a Hollow Sphere

10. Moment of Inertia of a Thin Hoop About Its Diameter

Frequently Asked Questions

Related Calculators

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