🌀 OSCILLATIONS · Simple Harmonic Motion
SHM • Equations • Energy • Spring-block • Pendulum • Damped & Forced • NEET problems
📐 SIMPLE HARMONIC MOTION (SHM)
Motion where restoring force is proportional to displacement and opposite in direction: F = –kx ⇒ a = –ω²x
Differential equation: d²x/dt² + ω²x = 0
Solution: x = A sin(ωt + φ) or x = A cos(ωt + φ)
A = amplitude, ω = angular frequency, φ = initial phase.
Time period: T = 2π/ω Frequency: f = 1/T = ω/2π
📈 Displacement-time graph for SHM
⚡ VELOCITY & ACCELERATION IN SHM
v = dx/dt = Aω cos(ωt + φ) = ± ω√(A² – x²)
a = d²x/dt² = –Aω² sin(ωt + φ) = –ω²x
Maximum velocity: vmax = Aω (at mean position)
Maximum acceleration: amax = Aω² (at extreme positions)
🔋 ENERGY IN SHM
Total mechanical energy is constant: E = (1/2)kA² = (1/2)mω²A²
KE = (1/2)mv² = (1/2)mω²(A² – x²)
PE = (1/2)kx² = (1/2)mω²x²
At extremes: KE=0, PEmax=E.
📊 Energy variation in SHM
🔧 SPRING-BLOCK OSCILLATOR
For a spring of constant k: ω = √(k/m), T = 2π√(m/k)
Series combination: 1/keff = 1/k₁ + 1/k₂
Parallel combination: keff = k₁ + k₂
🖍️ Spring-block system
⏱️ SIMPLE PENDULUM
For small oscillations (θ < 10°): T = 2π√(L/g)
ω = √(g/L), f = (1/2π)√(g/L)
Restoring force: F = –mg sinθ ≈ –mgθ (for small θ)
Effective g due to acceleration: T = 2π√(L/geff)
🧵 Simple pendulum
📉 DAMPED & FORCED OSCILLATIONS
Damped Oscillations
Amplitude decreases exponentially: A = A₀e–bt
Types: underdamped, critically damped, overdamped.
Forced Oscillations & Resonance
When driving frequency matches natural frequency, amplitude becomes maximum → resonance.
💡 NEET TIPS & SHORTCUTS
- In vertical spring, equilibrium position shifts but ω = √(k/m) remains same.
- For a spring of mass ms, effective mass = m + ms/3 in T formula.
- In compound pendulum, T = 2π√(I/mgd).
- For a body in SHM, average KE = average PE = E/2.
⚠️ COMMON MISTAKES
- Using ω = √(g/L) for spring instead of √(k/m).
- Forgetting to convert angle to radians in pendulum formulas.
- Assuming SHM is only sinusoidal – phase difference matters in superposition.
- Confusing angular frequency ω with angular velocity.
📌 QUICK REVISION CARD
SHM equation: x = A sin(ωt + φ)
ω = 2π/T = 2πf
vmax = Aω, amax = Aω²
Spring T: T = 2π√(m/k)
Pendulum T: T = 2π√(L/g)
Total energy: E = ½kA² = ½mω²A²
🔁 OSCILLATIONS (SHM) • NEET REVISION NOTES
📸 NOTES PREVIEW
Preview of Oscillations (SHM) Notes
📥 DOWNLOAD OSCILLATIONS (SHM) NOTES PDF
Download Oscillations Revision Notes for NEET Physics PDF for quick revision and strong conceptual clarity. This chapter is one of the most important and scoring topics in NEET Physics.
These Oscillations (SHM) handwritten notes PDF free download include simple harmonic motion, time period, frequency, spring-mass system, pendulum, energy in SHM, and all important formulas, tricks, and PYQ-based concepts.
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- Graph-based and formula-based questions
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