A Person Stands 7.00 M From One Speaker And 9.00 M From An Identical Speaker. If There Is Constructive Interference Where $n = 2$, What Is The Frequency? F = [ ? ] Hz F = [?] \, \text{Hz} F = [ ?] Hz
Understanding Constructive Interference
Constructive interference occurs when two or more waves overlap in such a way that the peaks of the waves align, resulting in a greater amplitude than the individual waves. This phenomenon is crucial in understanding the behavior of sound waves, particularly in the context of multiple speakers. In this scenario, we are dealing with two identical speakers, and we want to determine the frequency of the sound wave when constructive interference occurs at a specific distance.
The Role of Wavelength and Distance
The wavelength of a sound wave is directly related to its frequency. The wavelength can be calculated using the formula $\lambda = \frac{v}{f}$, where $v$ is the speed of sound and $f$ is the frequency. In this case, we are given two distances from the speakers: 7.00 m and 9.00 m. We know that constructive interference occurs when the difference between these distances is an integer multiple of the wavelength. Mathematically, this can be expressed as $d_2 - d_1 = n\lambda$, where $d_2$ and $d_1$ are the distances from the speakers, $n$ is the order of constructive interference, and $\lambda$ is the wavelength.
Calculating the Wavelength
Given that $n = 2$, we can rewrite the equation as $d_2 - d_1 = 2\lambda$. Substituting the given values, we get $9.00 , \text{m} - 7.00 , \text{m} = 2\lambda$, which simplifies to $2.00 , \text{m} = 2\lambda$. Solving for $\lambda$, we find that $\lambda = 1.00 , \text{m}$.
Relating Wavelength to Frequency
Now that we have the wavelength, we can use the formula $\lambda = \frac{v}{f}$ to relate it to the frequency. The speed of sound in air is approximately $343 , \text{m/s}$ at room temperature and atmospheric pressure. Rearranging the formula to solve for frequency, we get $f = \frac{v}{\lambda}$.
Calculating the Frequency
Substituting the values of $v$ and $\lambda$, we get $f = \frac{343 , \text{m/s}}{1.00 , \text{m}} = 343 , \text{Hz}$.
Conclusion
In this scenario, we have determined the frequency of the sound wave when constructive interference occurs at a specific distance from two identical speakers. By understanding the relationship between wavelength and frequency, we were able to calculate the frequency of the sound wave. This calculation is essential in understanding the behavior of sound waves in real-world applications, such as music and audio engineering.
Additional Considerations
It's worth noting that the frequency calculated in this scenario is for a specific order of constructive interference ($n = 2$). In reality, the frequency of the sound wave may vary depending on the order of constructive interference and the specific distances from the speakers. Additionally, the speed of sound may vary depending on the temperature and atmospheric conditions, which can affect the calculated frequency.
References
- [1] Halliday, D., Resnick, R., & Walker, J. (2013). Fundamentals of physics. John Wiley & Sons.
- [2] Young, H. D., & Freedman, R. A. (2012). University physics. Addison-Wesley.
Further Reading
- [1] "Constructive Interference" by Physics Classroom
- [2] "Wavelength and Frequency" by HyperPhysics
Understanding Constructive Interference
Constructive interference occurs when two or more waves overlap in such a way that the peaks of the waves align, resulting in a greater amplitude than the individual waves. This phenomenon is crucial in understanding the behavior of sound waves, particularly in the context of multiple speakers. In this scenario, we are dealing with two identical speakers, and we want to determine the frequency of the sound wave when constructive interference occurs at a specific distance.
The Role of Wavelength and Distance
The wavelength of a sound wave is directly related to its frequency. The wavelength can be calculated using the formula $\lambda = \frac{v}{f}$, where $v$ is the speed of sound and $f$ is the frequency. In this case, we are given two distances from the speakers: 7.00 m and 9.00 m. We know that constructive interference occurs when the difference between these distances is an integer multiple of the wavelength. Mathematically, this can be expressed as $d_2 - d_1 = n\lambda$, where $d_2$ and $d_1$ are the distances from the speakers, $n$ is the order of constructive interference, and $\lambda$ is the wavelength.
Calculating the Wavelength
Given that $n = 2$, we can rewrite the equation as $d_2 - d_1 = 2\lambda$. Substituting the given values, we get $9.00 , \text{m} - 7.00 , \text{m} = 2\lambda$, which simplifies to $2.00 , \text{m} = 2\lambda$. Solving for $\lambda$, we find that $\lambda = 1.00 , \text{m}$.
Relating Wavelength to Frequency
Now that we have the wavelength, we can use the formula $\lambda = \frac{v}{f}$ to relate it to the frequency. The speed of sound in air is approximately $343 , \text{m/s}$ at room temperature and atmospheric pressure. Rearranging the formula to solve for frequency, we get $f = \frac{v}{\lambda}$.
Calculating the Frequency
Substituting the values of $v$ and $\lambda$, we get $f = \frac{343 , \text{m/s}}{1.00 , \text{m}} = 343 , \text{Hz}$.
Conclusion
In this scenario, we have determined the frequency of the sound wave when constructive interference occurs at a specific distance from two identical speakers. By understanding the relationship between wavelength and frequency, we were able to calculate the frequency of the sound wave. This calculation is essential in understanding the behavior of sound waves in real-world applications, such as music and audio engineering.
Additional Considerations
It's worth noting that the frequency calculated in this scenario is for a specific order of constructive interference ($n = 2$). In reality, the frequency of the sound wave may vary depending on the order of constructive interference and the specific distances from the speakers. Additionally, the speed of sound may vary depending on the temperature and atmospheric conditions, which can affect the calculated frequency.
Q&A
Q: What is constructive interference?
A: Constructive interference occurs when two or more waves overlap in such a way that the peaks of the waves align, resulting in a greater amplitude than the individual waves.
Q: What is the relationship between wavelength and frequency?
A: The wavelength of a sound wave is directly related to its frequency. The wavelength can be calculated using the formula $\lambda = \frac{v}{f}$, where $v$ is the speed of sound and $f$ is the frequency.
Q: How do you calculate the wavelength of a sound wave?
A: To calculate the wavelength, you need to know the speed of sound and the frequency of the sound wave. The formula for wavelength is $\lambda = \frac{v}{f}$.
Q: What is the speed of sound in air?
A: The speed of sound in air is approximately $343 , \text{m/s}$ at room temperature and atmospheric pressure.
Q: How do you calculate the frequency of a sound wave?
A: To calculate the frequency, you need to know the speed of sound and the wavelength of the sound wave. The formula for frequency is $f = \frac{v}{\lambda}$.
Q: What is the frequency of the sound wave in this scenario?
A: The frequency of the sound wave in this scenario is $343 , \text{Hz}$.
Q: What are some real-world applications of understanding sound waves?
A: Understanding sound waves is essential in various real-world applications, such as music and audio engineering, acoustics, and noise reduction.
Q: Can the frequency of a sound wave vary depending on the order of constructive interference?
A: Yes, the frequency of a sound wave may vary depending on the order of constructive interference and the specific distances from the speakers.
Q: Can the speed of sound vary depending on the temperature and atmospheric conditions?
A: Yes, the speed of sound may vary depending on the temperature and atmospheric conditions, which can affect the calculated frequency.
Further Reading
- [1] "Constructive Interference" by Physics Classroom
- [2] "Wavelength and Frequency" by HyperPhysics
- [3] "Speed of Sound" by Wolfram Alpha