Calculating Fractional Change in Frequency of Whistling Sound

How can we calculate the fractional change in the frequency of the whistling sound heard by a person as a bullet passes by?

The fractional change in the frequency of the whistling sound heard by the person as the bullet crosses is a decrease from the actual frequency to approximately 391.13 Hz.The fractional change in the frequency of the whistling sound heard by the person as the bullet passes by can be determined using the Doppler effect formula. The formula for the apparent frequency, or the frequency heard by the person, is: f' = f x (v + v_observer) / (v + v_source) Where: - f\' is the apparent frequency - f is the actual frequency of the whistling sound - v_observer is the velocity of the observer (person) - v_source is the velocity of the source (bullet) - v is the speed of sound in air In this case, the bullet is passing by the person, so the observer's velocity (v_observer) is zero. The speed of sound in air (v) is typically around 343 m/s. Using the given information: - The bullet's speed (v_source) is 220 m/s - The speed of sound in air (v) is 343 m/s We can substitute these values into the formula: f' = f x (0 + 220) / (220 + 343) Simplifying further: f' = f x 220 / 563 Now, let's assume the actual frequency of the whistling sound is f = 1000 Hz. Substituting this value: f' = 1000 x 220 / 563 Simplifying further: f' ≈ 391.13 Hz So, the apparent frequency of the whistling sound heard by the person as the bullet crosses is approximately 391.13 Hz. In conclusion, the fractional change in the frequency of the whistling sound heard by the person as the bullet crosses is a decrease from the actual frequency to approximately 391.13 Hz.

Understanding the Doppler Effect Formula for Frequency Change

The Doppler effect is a phenomenon where the frequency of a wave changes for an observer moving relative to the source of the wave. In this case, as the bullet moves past the person, the frequency of the whistling sound heard by the person changes due to their relative motion. The formula for the apparent frequency incorporates the velocities of the source, observer, and the speed of sound in air. By plugging in the values for these velocities into the formula, we can calculate the apparent frequency of the whistling sound as heard by the person. In the given scenario, where the bullet is passing by the person at a speed of 220 m/s and the speed of sound in air is 343 m/s, we can determine the fractional change in the frequency of the whistling sound. By understanding and applying the Doppler effect formula, we can calculate how the frequency of the whistling sound changes for the person as the bullet crosses them. This calculation allows us to quantify the change in the perceived frequency and understand the physics behind sound wave propagation in relative motion scenarios.
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