We appreciate your visit to A string with both ends held fixed is vibrating in its third harmonic The waves have a speed of 186 m s and a frequency. This page offers clear insights and highlights the essential aspects of the topic. Our goal is to provide a helpful and engaging learning experience. Explore the content and find the answers you need!
Answer :
Final answer:
The maximum transverse velocity of the string at an antinode can be calculated using the formula 2 \\pi \\cdot frequency \\cdot amplitude, resulting in approximately 5.68 m/s.
Explanation:
The question asks how to calculate the maximum transverse velocity of a string vibrating in its third harmonic when the amplitude at an antinode is given.
The wave speed and frequency are also provided. The maximum transverse velocity at an antinode in a standing wave can be obtained using the formula:
velocity (v) = 2 \\pi \\cdot frequency (f) \\cdot amplitude (A)
Given that the frequency is 205 Hz and the amplitude is 0.440 cm (or 0.0044 meters), we can calculate the velocity as follows:
v = 2 \\pi \\cdot 205 Hz \\cdot 0.0044 m
v = approximately 5.68 m/s
Thanks for taking the time to read A string with both ends held fixed is vibrating in its third harmonic The waves have a speed of 186 m s and a frequency. We hope the insights shared have been valuable and enhanced your understanding of the topic. Don�t hesitate to browse our website for more informative and engaging content!
- Why do Businesses Exist Why does Starbucks Exist What Service does Starbucks Provide Really what is their product.
- The pattern of numbers below is an arithmetic sequence tex 14 24 34 44 54 ldots tex Which statement describes the recursive function used to..
- Morgan felt the need to streamline Edison Electric What changes did Morgan make.
Rewritten by : Barada
