IB Physics HL Topic 3 — Oscillations & Waves Paper 1 & 2 E = ½mω²x² ~12 min read

Calculating Energy Changes in SHM

You already know the story: in SHM, energy trades between kinetic and potential while the total stays fixed. Now we put numbers on it. Three equations do the whole job — one for potential energy, one for kinetic, and one for the total — and they all share the same building blocks: mass, angular frequency, amplitude and displacement. Once you can find ω, the rest is substitution.

📘 What you need to know

The three energy equations

Every energy question in SHM comes back to these three formulas. They use the mass m, the angular frequency ω, the amplitude x0, and the displacement x at the moment you care about.

Potential energy at displacement x EP = ½ ²x²
Kinetic energy at displacement x EK = ½ ²(x0² − x²)
Total energy ET = ½ ²x0²

Where m is mass (kg), ω is angular frequency (rad s−1), x0 is amplitude (m) and x is displacement (m). All three give energy in joules.

Look closely and you’ll see the three equations are really one idea. The total swaps x for x0 (energy when displacement is maximum). The PE uses the actual x. And the KE is just the total minus the PE: ½²x0² − ½²x² = ½²(x0² − x²). Learn one, and you can rebuild the others.

Where the equations come from

The kinetic energy formula is the key one — the others follow. Start from the ordinary kinetic energy EK = ½mv², then substitute the SHM velocity–displacement relation v = ±ω√(x0² − x²):

🔧 Building the energy equations

  1. Start with EK = ½mv² and the SHM velocity v = ±ω√(x0² − x²).
  2. Squaring v gives v² = ω²(x0² − x²), so EK = ½²(x0² − x²).
  3. At the centre (x = 0), KE is maximum and PE is zero — so this is the total energy: ET = ½²x0².
  4. Potential energy is whatever’s left over: EP = ETEK = ½²x².
WE 1

A 0.30 kg mass oscillates in SHM with frequency 2.0 Hz and amplitude 0.05 m. Calculate the total energy of the oscillation.

Step 1 — find ω ω = 2πf = 2π × 2.0 = 12.57 rad s⁻¹ Step 2 — use E_T = ½mω²x₀² E_T = 0.5 × 0.30 × (12.57)² × (0.05)² E_T = 0.5 × 0.30 × 157.9 × 0.0025 E_T = 0.059 J (59 mJ) Find ω first, then square it and square the amplitude. Both get squared — a common slip.

Total energy depends on amplitude squared

The total-energy formula hides an important rule: because x0 is squared, the energy grows with the square of the amplitude. Give an oscillator twice the amplitude and it carries four times the energy; triple the amplitude and it’s nine times the energy.

Energy scales with amplitude squared ETx0²
Handy consequence: the same rule applies to potential energy, EPx². That’s why, when an oscillator is only halfway out (x = x0/2), it holds just a quarter of its energy as PE — not half.

The energy–displacement picture

Plotting the three energies against displacement shows how the formulas fit together. PE is a parabola (from the x² term), KE is its upside-down partner, and the total is the flat line they always add up to.

Energy vs displacement Energy x +x₀ −x₀ total energy KE PE
PE (blue) is the parabola ½²x²; KE (red) is the total minus PE. They always add up to the flat total line ET.
WE 2

A 0.20 kg mass oscillates with angular frequency 10 rad s⁻¹ and amplitude 0.08 m. Find its kinetic and potential energies when the displacement is 0.04 m.

Step 1 — kinetic energy E_K = ½mω²(x₀² − x²) E_K = 0.5 × 0.20 × 10² × (0.08² − 0.04²) E_K = 0.5 × 0.20 × 100 × (0.0064 − 0.0016) = 10 × 0.0048 E_K = 0.048 J Step 2 — potential energy E_P = ½mω²x² E_P = 0.5 × 0.20 × 100 × 0.04² = 10 × 0.0016 = 0.016 J E_K = 48 mJ, E_P = 16 mJ Check: E_K + E_P = 48 + 16 = 64 mJ = the total ½mω²x₀². Conservation holds.
WE 3

A 35 g ball is held between two springs and oscillates in SHM with frequency 5.0 Hz and amplitude 2.0 cm. Calculate the total energy of the oscillation.

Step 1 — convert units: m = 0.035 kg, x₀ = 0.020 m Step 2 — find ω ω = 2πf = 2π × 5.0 = 31.42 rad s⁻¹ Step 3 — use E_T = ½mω²x₀² E_T = 0.5 × 0.035 × (31.42)² × (0.020)² E_T = 0.5 × 0.035 × 987 × 0.0004 E_T = 6.9 mJ Grams to kg and cm to m first — skip that and the answer is out by a big factor.

Maximum energies

Because energy shuffles fully from one store to the other, all three of these are the same number:

All equal to the total energy ET = EK(max) = EP(max) = ½²x0²

Maximum KE happens at the centre (all energy kinetic); maximum PE happens at the extremes (all energy potential). Each equals the fixed total, so if a question gives you the maximum of either, you already know the total.

At centre
EK = max, EP = 0
EK + EP = ET
(constant)
Halfway out
¾ KE, ¼ PE
EK + EP = ET
(constant)
At extreme
EP = max, EK = 0

The energy equations at a glance

EnergyEquationMaximum where
Potential (EP)½²x²At the extremes (x = x0)
Kinetic (EK)½²(x0² − x²)At the centre (x = 0)
Total (ET)½²x0²Constant everywhere

💡 Top tips

⚠ Common mistakes

Quick recap: Three equations cover all SHM energy calculations: EP = ½²x², EK = ½²(x0² − x²), and ET = ½²x0². They always satisfy ET = EK + EP, the maximum KE and PE both equal the total, and the total energy is proportional to amplitude squared.
You can now describe SHM, find its period for springs and pendulums, write its motion equations and calculate its energy. The last piece of the topic handles oscillators that don’t start neatly at the centre or the edge — they start partway through, described by a phase angle. That’s the next page: phase angles in SHM.

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