--- name: mfe-waves description: "Periodic phenomena and frequency analysis. How repetition creates structure — from simple oscillation to Fourier decomposition." user-invocable: false allowed-tools: Read Grep Glob metadata: extensions: gsd-skill-creator: version: 1 createdAt: "2026-02-26" triggers: intents: - "wave" - "frequency" - "harmonic" - "oscillation" - "period" - "amplitude" - "resonance" - "standing wave" - "Fourier" - "spectrum" contexts: - "mathematical problem solving" - "math reasoning" --- # Waves ## Summary **Waves** (Part II: Hearing) Chapters: 4, 5, 6, 7 Plane Position: (-0.4, 0) radius 0.4 Primitives: 50 Periodic phenomena and frequency analysis. How repetition creates structure — from simple oscillation to Fourier decomposition. **Key Concepts:** Simple Harmonic Motion, Frequency, Wave Function, Superposition Principle, Wave Equation ## Key Primitives **Simple Harmonic Motion** (definition): Simple harmonic motion (SHM) is periodic motion where the restoring force is proportional to displacement: F = -kx. The solution is x(t) = A*cos(omega*t + phi) where omega = sqrt(k/m). - modeling back-and-forth motion of a pendulum or spring - any system with a linear restoring force proportional to displacement **Frequency** (definition): The frequency f of a periodic phenomenon is the number of complete cycles per unit time. f = 1/T where T is the period. Measured in hertz (Hz = cycles/second). - determining how many oscillations occur per second - relating pitch of a sound to its physical frequency **Wave Function** (definition): The general sinusoidal wave function is y(x,t) = A*sin(kx - omega*t + phi), describing a traveling wave with amplitude A, wave number k, angular frequency omega, and phase offset phi. - describing a sinusoidal disturbance propagating through a medium - modeling light, sound, or any traveling periodic signal **Superposition Principle** (theorem): For linear systems, the net response at a given point caused by two or more stimuli is the sum of the responses that would have been caused by each stimulus individually. For waves: y_total(x,t) = y_1(x,t) + y_2(x,t) + ... - adding together multiple wave sources to find the combined effect - analyzing interference patterns from multiple coherent sources **Wave Equation** (definition): The one-dimensional wave equation is the second-order partial differential equation: d^2u/dt^2 = c^2 * d^2u/dx^2, where c is the wave propagation speed and u(x,t) is the displacement field. - modeling wave propagation in strings, air columns, or electromagnetic fields - predicting how disturbances travel through a medium **Harmonic Series** (definition): The harmonic series of a fundamental frequency f_1 consists of integer multiples: f_n = n * f_1 for n = 1, 2, 3, ... The nth harmonic has frequency n times the fundamental. - determining the frequency content of a vibrating string or air column - understanding why different instruments sound different even playing the same note **Fundamental Frequency** (definition): The fundamental frequency f_1 is the lowest resonant frequency of a vibrating system. For a string of length L with wave speed v: f_1 = v/(2L). All higher harmonics are integer multiples of f_1. - finding the lowest pitch produced by a vibrating string or air column - tuning musical instruments to a specific pitch **Separation of Variables for Waves** (technique): Separation of variables assumes the solution to a PDE is a product of functions of individual variables: u(x,t) = X(x)*T(t). Substituting into the wave equation and dividing by X*T yields two ODEs: X''/X = T''/(c^2*T) = -lambda (separation constant). - solving the wave equation on a bounded domain with fixed or free boundary conditions - finding the natural vibration modes of a physical system **Standing Wave** (definition): A standing wave is a wave pattern that does not propagate through space but oscillates in place. It is formed by the superposition of two identical waves traveling in opposite directions: 2A*sin(kx)*cos(omega*t). - analyzing vibration patterns on strings, membranes, or in cavities - determining where resonant systems have maximum and minimum displacement **Period** (definition): The period T of a periodic function f is the smallest positive value such that f(t + T) = f(t) for all t. T is the duration of one complete cycle. - measuring the time for one complete oscillation cycle - determining how long before a periodic system returns to its initial state ## Composition Patterns - Simple Harmonic Motion + waves-frequency -> Complete SHM description with temporal period and spatial amplitude (parallel) - Frequency + waves-wavelength -> Wave speed: v = f * lambda, connecting temporal and spatial periodicity (parallel) - Period + waves-frequency -> Complete temporal characterization: T = 1/f, f = 1/T (parallel) - Angular Frequency + perception-radian-measure -> Natural sinusoidal parameterization: sin(omega*t) cycles at frequency f = omega/(2*pi) (nested) - Wave Function + waves-wave-number -> Complete space-time wave description: y(x,t) = A*sin(kx - omega*t) (parallel) - Wavelength + waves-frequency -> Wave speed relation: v = lambda * f (parallel) - Sum-to-Product Formulas + waves-superposition-principle -> Analysis of combined waves: sum of two sinusoids reveals beat and carrier frequencies (sequential) - Product-to-Sum Formulas + waves-sum-to-product -> Complete toolkit for converting between product and sum forms of trigonometric expressions (parallel) - Superposition Principle + waves-constructive-destructive-interference -> Complete interference analysis: constructive when in-phase, destructive when out-of-phase (sequential) - Phasor Representation + waves-superposition-principle -> Adding sinusoids by vector addition of their phasors (sequential) ## Cross-Domain Links - **perception**: Compatible domain for composition and cross-referencing - **change**: Compatible domain for composition and cross-referencing - **reality**: Compatible domain for composition and cross-referencing - **mapping**: Compatible domain for composition and cross-referencing - **synthesis**: Compatible domain for composition and cross-referencing ## Activation Patterns - wave - frequency - harmonic - oscillation - period - amplitude - resonance - standing wave - Fourier - spectrum