Collision Energy Calculator

Calculator Inputs

Mass m1

Positive value.

Mass m2

Positive value.

Mass unit kg g mg lb

Converted to kg internally.

Velocity v1 (initial)

Use negative for opposite direction.

Velocity v2 (initial)

Use negative for opposite direction.

Velocity unit m/s km/h mph ft/s

Converted to m/s internally.

Coefficient of restitution (e)

1 = elastic, 0 = perfectly inelastic limit.

Compute Reset Tip: try e=1, then reduce e to see energy loss.

Formula Used

This calculator assumes a one-dimensional collision along a line. The coefficient of restitution e models elasticity: e = (v2' − v1') / (v1 − v2), with 0 ≤ e ≤ 1.

• v1' = (m1 v1 + m2 v2 − m2 e (v1 − v2)) / (m1 + m2)
• v2' = (m1 v1 + m2 v2 + m1 e (v1 − v2)) / (m1 + m2)
• K = ½ m1 v1² + ½ m2 v2²
• E_diss = K_i − K_f (energy converted to heat, sound, deformation)
• v_cm = (m1 v1 + m2 v2) / (m1 + m2)
• E_cm = ½ μ (v1 − v2)², where μ = m1 m2 / (m1 + m2)

Notes: In perfectly elastic collisions, E_diss ≈ 0. For inelastic collisions, E_diss ≥ 0, while total momentum remains conserved.

How to Use This Calculator

1. Enter both masses and choose the mass unit.
2. Enter initial velocities (use negative for opposite direction) and pick a velocity unit.
3. Set restitution e: 1 for elastic, smaller for more energy loss.
4. Click Compute to see results above the form.
5. Use the CSV/PDF buttons to export the latest computed results.

Example Data Table

Units shown in the table are kg for mass and m/s for velocity.

Professional Notes on Collision Energy

1) What this calculator measures

The tool evaluates kinetic energy before and after a one‑dimensional impact and reports both the laboratory energies and the center‑of‑mass relative‑motion energy. It is useful for carts, air‑track gliders, bumper tests, and any setup where motion is mainly along one line.

2) Why kinetic energy can change

Momentum is conserved for an isolated system, but kinetic energy can decrease when deformation, vibration, heat, and sound are produced. The calculator reports this as E_diss = K_i − K_f. For nearly elastic steel‑on‑steel taps, E_diss can be close to zero; for soft bumpers it can be large.

3) Restitution data you can compare

The coefficient of restitution e summarizes how “bouncy” the collision is. Values near e≈0.9 are typical for hard, well‑aligned impacts; rubber‑like contacts may fall around e≈0.5; and the perfectly inelastic limit is e=0. Because e is sensitive to alignment, surface condition, and speed, measuring it across several trials improves reliability.

4) Lab frame vs center‑of‑mass frame

In the lab, one object might be at rest while the other moves. In the center‑of‑mass frame the system’s bulk motion is removed, revealing the energy available for deformation. The calculator provides v_cm and E_cm so you can compare collisions performed at different overall speeds.

5) Reduced mass and relative speed

The center‑frame collision energy is computed as E_cm = ½ μ (v1 − v2)², where μ = m1 m2 / (m1 + m2). This highlights two controls: the reduced mass and the closing speed. Doubling the relative speed quadruples E_cm.

6) Practical experiment workflow

Record masses, then measure pre‑impact velocities with photogates, video tracking, or motion sensors. Run the calculator, then verify that the reported momentum p is consistent across trials. For classroom carts, a closing speed of 2–6 m/s commonly yields energies from a few joules to tens of joules, depending on mass.

7) Uncertainty and common pitfalls

The largest errors usually come from velocity measurement and sign conventions. Use negative velocities for opposite directions, and keep units consistent. If results appear unphysical, check that both masses are positive and that 0 ≤ e ≤ 1. Repeat trials to estimate uncertainty bands.

8) Interpreting the outputs

Compare K_i and K_f to quantify losses, and use E_cm to compare different setups fairly. Export CSV for lab reports, and use the PDF summary when documenting test conditions and results.

FAQs

1) What does collision energy mean here?

It refers to kinetic energy before and after impact, plus the center‑of‑mass relative‑motion energy that represents energy available for deformation during contact.

2) Can I use this for perfectly elastic collisions?

Yes. Set e = 1. The calculator will typically show E_diss near zero, with any tiny difference due to rounding.

3) What if one object is initially at rest?

Enter v2 = 0 for the stationary object. The formulas remain valid and the results will show final velocities and the energy change.

4) Why is E_diss sometimes large?

Energy can convert into heat, sound, and deformation. Softer materials, misalignment, and higher closing speed usually increase dissipation.

5) How do I choose the coefficient of restitution?

If you measured pre‑ and post‑impact speeds, compute e from relative speeds along the collision line. Otherwise, use literature values as a starting point and adjust to match tests.

6) Does this handle two‑dimensional impacts?

No. It models one‑dimensional motion along a line. For angled impacts, project velocities onto the collision normal or use a full 2D/3D collision model.

7) What is the purpose of E_cm?

It removes the system’s bulk motion and isolates relative‑motion energy. This helps compare collisions performed with different overall speeds or different lab frames.