College Physics II – Mechanics, Sound, Oscillations, and Waves
Definition
Hertz (Hz) is the unit of frequency, representing the number of cycles per second of a periodic phenomenon. This term is crucial in understanding wave phenomena, such as how fast a wave oscillates or how sound waves change due to motion. In practical terms, Hertz helps quantify the rate at which events occur in various physical contexts, linking frequency to wave behavior and sound perception.
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1 Hz equals one cycle per second, indicating how frequently a wave oscillates.
In wave mechanics, higher frequencies correspond to shorter wavelengths, following the relationship $$v = f \lambda$$, where v is wave speed, f is frequency in Hz, and \lambda is wavelength.
Sound waves are often measured in Hertz, with audible frequencies ranging from about 20 Hz to 20,000 Hz for humans.
The Doppler Effect describes how the frequency of a wave changes based on the relative motion of the source and observer, affecting perceived pitch.
When analyzing wave speed on a string, increasing tension or decreasing mass per unit length alters the frequency at which standing waves can be produced.
Review Questions
How does increasing the tension in a stretched string affect its frequency measured in Hertz?
Increasing the tension in a stretched string raises its frequency because a tighter string allows waves to travel faster. According to the wave equation $$v = f \lambda$$, if wave speed (v) increases due to greater tension while wavelength (\lambda) remains constant, the frequency (f) must increase. This means that as tension rises, the string vibrates more rapidly, producing higher frequency tones measured in Hertz.
Discuss how the concept of Hertz is essential for understanding the Doppler Effect and its applications.
The concept of Hertz is vital for understanding the Doppler Effect because it quantifies how frequencies change based on relative motion. When a sound source moves toward an observer, the waves compress, increasing the frequency (measured in Hz), leading to a higher perceived pitch. Conversely, as the source moves away, the waves stretch out, decreasing the frequency. This principle is widely applied in various fields like astronomy to determine the movement of stars and galaxies based on their spectral lines' shifts.
Evaluate the relationship between frequency measured in Hertz and its practical implications in real-world applications such as sound and communication technology.
The relationship between frequency measured in Hertz and its applications is profound. In sound technology, different frequencies correspond to different pitches; for instance, musical notes are defined by specific Hz values. In communication technology, radio frequencies (often measured in kilohertz or megahertz) determine how signals are transmitted over distances. Understanding these frequencies enables engineers to design better audio systems and optimize transmission channels for clearer communication. As such, mastering Hertz not only aids theoretical physics but also has tangible impacts on technology and daily life.