Transmitting on all frequencies?

In summary, it is possible to broadcast on several frequencies at once by generating harmonics or using "ultra wideband" modulation techniques. This is achieved by passing a radio signal through a nonlinear device or by adding together the waveforms of each transmission. However, it is not possible to achieve an ideal pulse with infinite frequencies, and practical limitations exist in creating a spread of frequencies for transmission.
  • #1
ice109
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i know you've heard this in a movie or something, usually when a ship is sinking or the last survivor of the human race is looking for other survivors. considering a transmitter is just a driven LRC circuit oscillating at a certain frequency, is this possible? obviously you could have a bunch of different transmitters going at the same time or broadcast, change the frequency of oscillations and retransmit but could you broadcast on several freqs at once?
 
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  • #2
An ideal pulse such as described by the dirac delta function is composed of infinite frequencies. You can check that by taking its Fourier transform.

But practically it's impossible to achieve an ideal pulse with infinite amplitude, and 0 period, but you can get a bit close.

Another way is to generate harmonics. By passing a radio signal through a nonlinear device such as a transistor amplifier, the output will be composed of the fundamental frequency and its multiples. Its possible to mess around with the nonlinear device to produce all kinds of subharmonics, and mixing products.
 
  • #3
You can broadcast on several frequencies at once,
there's the Fourier transform relationship between a waveform and the frequencies that make up the waveform.

So in fact anything that isn't an infinite duration pure
sine wave occupies a spread of frequencies.

If you transmit very sharp impulses they'll cover a wide
range of frequencies, and the old "spark gap" transmitters
worked in just such a way to generate RF at some useful
frequency range without very precise control of oscillator
tuning in the transmitter.

To really cover a wide range of frequencies there are
"ultra wideband" modulation techniques. To cover
several sets of individual frequencies at once you can
just generate the waveform of each of those transmissions
and add them together coming out of one broadband
antenna.
 

1. What does it mean to "transmit on all frequencies"?

Transmitting on all frequencies refers to the process of sending out a signal or message on all available frequency channels. This can allow for a wider range of receivers to pick up the transmission and increase the chances of successful communication.

2. Why is it important to transmit on all frequencies?

Transmitting on all frequencies is important because it allows for better communication and coverage. Different devices may operate on different frequencies, so by transmitting on all frequencies, the chances of reaching all devices and receivers is increased. It also helps to reduce interference and improve signal strength.

3. How does transmitting on all frequencies work?

Transmitting on all frequencies can be achieved through the use of a multi-band transmitter, which is able to send out signals on multiple frequencies simultaneously. It can also be achieved by using a frequency hopping technique, where the transmitter switches between different frequencies at regular intervals.

4. Are there any drawbacks to transmitting on all frequencies?

One potential drawback of transmitting on all frequencies is that it can lead to congestion and interference, especially in areas with high levels of radio frequency activity. This can affect the quality of the transmission and make it difficult for receivers to pick up the signal. It can also consume more power and increase the risk of signal jamming.

5. In what situations is it necessary to transmit on all frequencies?

Transmitting on all frequencies is particularly useful in situations where there is a need for reliable and widespread communication, such as in emergency response situations. It can also be beneficial in military operations, where secure and uninterrupted communication is crucial. Additionally, it can be used in everyday communication devices to ensure better coverage and connectivity.

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