Signal Frequency: Are Frequencies Always Present?

In summary, the concept of frequency is meaningless for intervals of zero time, so it is not accurate to say that all frequencies are present at all times. Instead, the best approach is to study the signal over a specific interval of time and describe the frequency content present in that interval. The amplitude of the signal may vary over time, but this does not necessarily mean that the frequency of the signal changes. It is important to clarify whether the amplitude variation occurs over the period of the waveform or over the time the signal is produced.
  • #1
Blade_Runner
8
0
signal frequency!

suppose we have a signal varying randomly in amplitude with time...when we plot the frequency responce of this signal , we get a bandwidth of frequencies...My question is ' are all these frequencies present at all times??', or 'at any time , say t=to , only one of these frequencies is present??'...
 
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  • #2


I'm not sure how you would quantify the randomness of the amplitude. You can't really throw random numbers in for amplitude or you would get junk. You would need to increase or decrease the amplitude with a "random walk" like process to have anything that looks remotely periodic.
 
  • #3


Blade_Runner said:
My question is ' are all these frequencies present at all times??', or 'at any time , say t=to , only one of these frequencies is present??'...

Well, the very concept of frequency is meaningless for intervals of zero time. If all you're considering is a single point in time, an infinity of different signals (with different frequency content) could result in the point you're seeing.

The best you can do is to study a signal over some interval of time, and describe what frequency content is present in that interval. The next interval of time, however, could include totally different frequencies.

- Warren
 
  • #4


In my area we deal with discrete functions. Applying the same thinking, I would say that the signal or function can be thought of as an infinite series of sine waves with varying frequencies and amplitudes. While the direct contribution of low or high order sine functions may not be directly prevalent at a specific point in time, t; the function does exist from t0 to t_inf.

Do you have additional information regarding a specific problem?
 
  • #5


If your signal is a constant-frequency signal with varying amplitudes (AM modulation), the observed bandwidth is sidebands due to the amplitude modulation. The frequency spread of the sidebands is due to the frequency of the amplitude modulation.
 
  • #6


It doesn't seem clear whether the time-varying amplitude varies over the period of the waveform or over the time the signal is produced. If it's over the period of the waveform, the signal can be expressed as a sum of sinusoidal signals, each having amplitudes that do not change with time. If the main signal varies over the time the signal is produced, all of the sinusoidal components will likely all still be present but their amplitudes will change over time.
 

1. What is signal frequency?

Signal frequency refers to the number of times a signal repeats per second. It is usually measured in Hertz (Hz).

2. Are frequencies always present in signals?

Yes, frequencies are always present in signals. Every signal, whether it is sound, light, or electricity, has a frequency associated with it. However, the frequency may vary depending on the type of signal. For example, an audio signal may have a lower frequency than a radio signal.

3. How does frequency affect signals?

The frequency of a signal affects its characteristics, such as its wavelength, amplitude, and energy. Higher frequencies have shorter wavelengths and carry more energy, while lower frequencies have longer wavelengths and carry less energy. The frequency also determines the type of information that can be transmitted through a signal.

4. Can frequencies be changed or manipulated?

Yes, frequencies can be changed or manipulated through a process called modulation. This is commonly used in communication systems to transmit information through different frequencies and to prevent interference between different signals. Frequencies can also be changed by using filters or other electronic components.

5. What is the relationship between frequency and bandwidth?

Frequency and bandwidth are closely related. Bandwidth refers to the range of frequencies that a signal occupies. The higher the frequency of a signal, the wider its bandwidth. This means that signals with higher frequencies can carry more information than signals with lower frequencies.

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