Pitch is the backbone of music, determining how high or low a note sounds. It's all about frequency—the faster a sound wave vibrates, the higher the pitch. This concept is crucial for creating melodies, harmonies, and the overall structure of musical compositions.

Octaves are the building blocks of pitch organization. They occur when one pitch vibrates twice as fast as another, creating a similar sound. This relationship forms the foundation for musical scales, allowing us to arrange pitches systematically and create the diverse sounds we hear in music.

Pitch in Music Theory

Definition and Role

• Pitch is a perceptual property of sounds that allows their ordering on a frequency-related scale, from low to high
• Determined by the frequency of sound wave vibrations; higher frequency results in higher pitch
• In music theory, pitch describes the highness or lowness of a musical note
• Plays a fundamental role in melody, harmony, and counterpoint
• Composers use pitch to create:
  • Melodic contours
  • Harmonic progressions
  • Overall musical structures
• Relationship between pitches (intervals and chords) forms the basis of musical composition

Frequency and Perception

• Pitch perception is related to the frequency of sound waves
• Human hearing range spans approximately 20 Hz to 20,000 Hz
• Doubling the frequency of a sound wave results in a pitch that is one octave higher
• Pitch perception is logarithmic; equal frequency ratios produce equal pitch intervals
• Examples of frequency and pitch relationship:
  • A440 (standard tuning pitch) vibrates at 440 Hz
  • A880 (one octave higher) vibrates at 880 Hz

Octaves and Pitch Organization

Octave Concept

• An octave is the interval between two pitches with a frequency ratio of 2:1
• Higher pitch in an octave vibrates twice as fast as the lower pitch
• Pitches an octave apart sound similar and have the same chroma or pitch class
• Octave equivalence allows for the organization of pitches into a repeating pattern
• Each octave contains a set of distinct pitch classes

Octaves as a Foundation

• Octaves serve as a foundation for musical scales
• Provide a framework for arranging pitches systematically
• Division of the octave into smaller intervals (semitones and whole tones) forms the basis for different musical scales and tuning systems
• Examples of octave-based scales:
  • C major scale: C, D, E, F, G, A, B, C
  • A minor scale: A, B, C, D, E, F, G, A
• Octave equivalence simplifies the understanding and notation of pitch relationships

Pitch Naming Conventions

Letter Names and Accidentals

• In Western music, pitches within an octave are named using the first seven letters of the alphabet: A, B, C, D, E, F, and G
• Letter names are combined with accidentals (sharps ♯ and flats ♭) to represent the 12 distinct pitches within an octave
• The sequence of pitch names follows a specific pattern: A, A♯/B♭, B, C, C♯/D♭, D, D♯/E♭, E, F, F♯/G♭, G, G♯/A♭, and back to A
• Enharmonic equivalents (C♯ and D♭) allow for flexibility in notation and accommodate different musical contexts

Octave Registers

• Pitch names are associated with specific octave registers
• Octave registers are indicated by numbers or specific designations
  • Middle C (C4) is the C located in the middle of the piano keyboard
  • Scientific pitch notation: C4 (middle C), A4 (440 Hz)
  • Helmholtz pitch notation: c' (middle C), a' (440 Hz)
• Octave registers help differentiate between pitches with the same letter name in different octaves
• Example: C4 (middle C) is one octave higher than C3

Frequency Ratios in Octaves

Simple Whole-Number Ratios

• Frequency ratios between pitches in an octave are based on simple whole-number ratios
• These ratios contribute to the perception of consonance and dissonance
• The octave has a frequency ratio of 2:1
  • Upper pitch vibrates twice as fast as the lower pitch
• Other important frequency ratios within an octave:
  • Perfect fifth (P5): 3:2
  • Perfect fourth (P4): 4:3
  • Major third (M3): 5:4
  • Minor third (m3): 6:5

Harmonic Series and Tonal Music

• Frequency ratios form the basis for intervals and chords in tonal music
• Derived from the harmonic series, a series of frequencies that are integer multiples of a fundamental frequency
• The harmonic series naturally occurs in many musical instruments and the human voice
• Understanding frequency ratios helps in analyzing pitch relationships and the construction of musical scales and tuning systems
• Example: The major triad (root, major third, perfect fifth) is derived from the 4th, 5th, and 6th partials of the harmonic series