# Does mass affect wave frequency?

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Video answer: Edexcel a-level physics: core practical 7

## Top best answers to the question «Does mass affect wave frequency»

Bowing a different string (of the same length, generally) means you use a string of a different tension and/or linear mass density; the higher the tension the higher the wave speed and thus frequency, but the higher the linear mass density the lower the frequency.

FAQ

Those who are looking for an answer to the question «Does mass affect wave frequency?» often ask the following questions:

### 👋 How does mass affect wave frequency?

lower mass = higher frequency

- Does frequency affect wave energy?
- Does frequency affect wave height?
- Does frequency affect wave speed?

### 👋 How does mass affect wave speed?

Since the speed of a wave on a string is **inversely proportional to the square root of the linear mass density**, the speed would be higher in the low linear mass density of the string. Shown below are three waves that were sent down a string at different times.

- Does wave frequency affect color?
- Does wave frequency affect diffraction?
- Why does square wave frequency affect triangle wave frequency?

### 👋 Does wave frequency affect wave speed?

- The data convincingly show that
**wave**frequency**does**not**affect wave speed**. An increase in wave frequency caused a decrease in**wavelength**while the**wave speed**remained constant. The last three trials involved the same procedure with a different rope tension.

- Does frequency affect energy of wave?
- How does frequency affect wave energy?
- How does sampling frequency affect sine wave?

Video answer: Tension, linear density, wave speed on a string introduction to linear density wave speed problem.

We've handpicked 27 related questions for you, similar to «Does mass affect wave frequency?» so you can surely find the answer!

How does tension affect transverse wave frequency?- On increasing the tension in a string, the speed of the
**wave**increases, which in turn, increases the wave frequency, i.e., the number of waves in a given length. 4. What Are Some Properties of a Transverse Wave? The crests and troughs of transverse waves are like peaks of a mountain.

- The data convincingly show that wave frequency
**does not affect wave speed**. An increase in wave frequency caused a decrease in wavelength while the wave speed remained constant. The last three trials involved the same procedure with a different rope tension.

#### How does wave frequency affect the speed of a wave?

- The data convincingly show that
**wave frequency does**not**affect wave speed**. An increase in**wave frequency**caused a decrease in wavelength while the**wave speed**remained constant. The last three trials involved the same procedure with a different rope tension.

**The**data convincingly show that**wave**frequency does not affect**wave**speed. An increase in wave frequency caused**a decrease**in**wavelength**while**the wave**speed remained constant. Rather,**the**speed**of the wave**is dependent upon**the**properties**of the**medium such as the tension of the rope.

**The**data convincingly show that**wave**frequency**does**not**affect wave speed**. An increase in wave frequency caused a decrease in wavelength while**the wave speed**remained constant. Complete answer to this is here.

### Video answer: Simple harmonic motion, mass spring system - amplitude, frequency, velocity - physics problems

How to find wave frequency with mass?The frequency, f, is 1/T, so the equation relating wave speed, frequency, and wavelength is **v = f λ** . where µ = m / L is the string's mass per unit length.

- In a standing wave, we have the equation: where T is string tension and μ is linear mass density. By this, if we increase linear mass density, wave velocity will decrease. But how does this affect wavelength?

### Video answer: Wave speed on a string - tension force, intensity, power, amplitude, frequency - inverse square law

How does mass density affect wave velocity and wavelength?- In a standing wave, we have the equation: where T is string tension and μ is linear mass density. By this, if we increase linear mass density, wave velocity will decrease. But how does this affect wavelength?

FALSE! The speed of a wave **is unaffected by changes in the frequency**.

- The small variations in the values for the
**speed**were the result of experimental error, rather than a demonstration of some physical law. The data convincingly show that**wave**frequency**does**not**affect wave speed**. An increase in wave frequency caused a decrease in wavelength while the**wave speed**remained constant.

### Video answer: All you need to know about ir and how to analyze the spectra with with 9 examples

Does wave speed affect wavelength if frequency increases?**The**data convincingly show that**wave**frequency**does**not affect**wave speed**. An increase in wave frequency caused**a**decrease in**wavelength**while**the wave speed**remained constant. See full answer. Besides,**does wave speed**affect wavelength?

- Frequency is
**inversely proportional to wavelength**, since speed is fixed. Amplitude is independent of both. Another key difference is that amplitude is related to wavelength.

- In our example
**slow wave**structure below, at the Bragg frequency, Z 0 of the line becomes purely imaginary, propagation stops and the slow-**wave**structure ceases to function. The smaller the line segments, the higher the Bragg frequency. We have another Bragg frequency example, on an artificial transmission line, located here.

**Damping**of a**wave**lowers**the**amplitude of a wave, PE and KE decrease but frequency remains**the**same. I don't understand**how**frequency can stay**the**same if overall energy decreases? Frequency is set by**the**source of**the wave**. It never changes due to the medium. but wavelength and wavespeed do? If you think about it in kinematics.

**The amplitude**decreases with an increase in**the**frequency**of a wave**. The amplitude increases with an increase in the frequency of a wave. Is wavelength directly proportional to energy?

The data convincingly show that **wave frequency does not affect wave speed**. An increase in wave frequency caused a decrease in wavelength while the wave speed remained constant.

- The small variations in the values for the speed were the result of experimental error, rather than a demonstration of some physical law. The data convincingly show that
**wave**frequency**does**not**affect wave**speed. An increase in**wave**frequency caused a decrease in wavelength while the wave speed remained constant.

The data convincingly show that wave frequency does not affect wave speed. An increase in wave frequency caused a decrease in wavelength while the wave speed remained constant… Rather, the speed of the wave is dependent upon the properties of the medium such as the tension of the rope.

### Video answer: The wave equation - why speed = frequency x wavelength

Does frequency affect sound intensity?Are Intensity and Frequency of Sound the Same? The answer to this question is clearly no. You might suspect, that the higher the frequency, the louder we perceive a noise, but **frequency does not tell us how loud a sound is**. Intensity or loudness is the amount of energy of a vibration and is measured in decibels (dB).

To summarise, waves carry energy. The amount of energy they carry is related to their frequency and their amplitude. **The higher the frequency, the more energy**, and the higher the amplitude, the more energy.

#### What is the relationship between wavelength and frequency?

- Wavelength and frequency are two such characteristics. The relationship between wavelength and frequency is that the
**frequency of a wave multiplied by its wavelength gives the speed of the wave**, as we will see below.

The speed of a wave doesn't depend on its frequency.

#### How does frequency affect energy of a wave?

- Wave frequency is related to wave energy. Since all that waves really are is traveling energy, the more energy in a wave, the higher its frequency. The lower the frequency is, the less energy in the wave. Following the above examples, gamma rays have very high energy and radio waves are low-energy.