Digital filter: Difference between revisions
en>Monkbot |
|||
| Line 1: | Line 1: | ||
'''Double-sideband suppressed-carrier transmission''' ('''DSB-SC''') is [[transmission (telecommunications)|transmission]] in which frequencies produced by [[amplitude modulation]] (AM) are symmetrically spaced above and below the [[Carrier wave|carrier frequency]] and the [[Carrier wave|carrier level]] is reduced to the lowest practical level, ideally being completely suppressed. | |||
In the DSB-SC modulation, unlike in AM, the wave carrier is not transmitted; thus, much of the power is distributed between the sidebands, which implies an increase of the cover in DSB-SC, compared to AM, for the same power used. | |||
DSB-SC transmission is a special case of [[double-sideband reduced carrier transmission]]. It is used for [[Radio Data System|radio data system]]s. | |||
==Spectrum== | |||
DSB-SC is basically an [[amplitude modulation]] wave without the carrier, therefore reducing power waste, giving it a 50% efficiency. This is an increase compared to normal AM transmission (DSB), which has a maximum efficiency of 33.333%, since 2/3 of the Power is in the Carrier which carries NO intelligence, and each Sideband carries the SAME Information. Single_Side_Band (SSB) Suppressed_Carrier is 100% efficient. | |||
Spectrum plot of an DSB-SC signal: | |||
[[Image:Spectrum DSBSC.svg]] | |||
==Generation== | |||
DSB-SC is generated by a mixer. This consists of a message signal combined with the frequency carrier. | |||
< | <math> | ||
\underbrace{V_m \cos \left( \omega_m t \right)}_{\mbox{Audio}} \times | |||
\underbrace{V_c \cos \left( \omega_c t \right)}_{\mbox{Carrier}} = | |||
\frac{V_m V_c}{2} \left[ | |||
\underbrace{\cos\left(\left( \omega_c + \omega_m \right)t\right)}_{\mbox{USB}} + | |||
\underbrace{\cos\left(\left( \omega_c - \omega_m \right)t\right)}_{\mbox{LSB}} | |||
\right] | |||
</math> | |||
[[Image:DSBSC Modulation.svg]] | |||
==Demodulation== | |||
For demodulation, the audio frequency and the carrier frequency must be exact. Otherwise, distortion will occur. DSB-SC can be demodulated if [[modulation index]] is less than unity. | |||
[[File:Demodulation distortion diagram.png]] | |||
== How it works == | |||
This is best shown graphically. Below is a message signal that one may wish to modulate onto a carrier, consisting of a couple of sinusoidal components. | |||
[[Image:DSBSC Message Signal.png]] | |||
The equation for this message signal is <math>s(t) = \frac{1}{2}\cos\left(2\pi 800 t\right) - \frac{1}{2}\cos\left( 2\pi 1200 t\right)</math>. | |||
The carrier, in this case, is a plain 5 kHz (<math>c(t) = \cos\left( 2\pi 5000 t \right)</math>) sinusoid—pictured below. | |||
[[Image:DSBSC Carrier Signal.png]] | |||
The modulation is performed by multiplication in the time domain, which yields a 5 kHz carrier signal, whose amplitude varies in the same manner as the message signal. | |||
[[Image:DSBSC Modulated Output.png]] | |||
< | <math>x(t) = \underbrace{\cos\left( 2\pi 5000 t \right)}_\mbox{Carrier} \times \underbrace{\left[\frac{1}{2}\cos\left(2\pi 800 t\right) - \frac{1}{2}\cos\left( 2\pi 1200 t\right)\right]}_\mbox{Message Signal}</math> | ||
The name "suppressed carrier" comes about because the carrier signal component is suppressed—it does not appear in the output signal. This is apparent when the spectrum of the output signal is viewed: | |||
[[Image:DSBSC Spectrum.png]] | |||
==References== | |||
{{FS1037C MS188}} | |||
{{DEFAULTSORT:Double-Sideband Suppressed-Carrier Transmission}} | |||
[[Category:Radio modulation modes]] | |||
Revision as of 21:27, 16 January 2014
Double-sideband suppressed-carrier transmission (DSB-SC) is transmission in which frequencies produced by amplitude modulation (AM) are symmetrically spaced above and below the carrier frequency and the carrier level is reduced to the lowest practical level, ideally being completely suppressed.
In the DSB-SC modulation, unlike in AM, the wave carrier is not transmitted; thus, much of the power is distributed between the sidebands, which implies an increase of the cover in DSB-SC, compared to AM, for the same power used.
DSB-SC transmission is a special case of double-sideband reduced carrier transmission. It is used for radio data systems.
Spectrum
DSB-SC is basically an amplitude modulation wave without the carrier, therefore reducing power waste, giving it a 50% efficiency. This is an increase compared to normal AM transmission (DSB), which has a maximum efficiency of 33.333%, since 2/3 of the Power is in the Carrier which carries NO intelligence, and each Sideband carries the SAME Information. Single_Side_Band (SSB) Suppressed_Carrier is 100% efficient.
Spectrum plot of an DSB-SC signal:
Generation
DSB-SC is generated by a mixer. This consists of a message signal combined with the frequency carrier.
![\underbrace {V_{m}\cos \left(\omega _{m}t\right)}_{{{\mbox{Audio}}}}\times \underbrace {V_{c}\cos \left(\omega _{c}t\right)}_{{{\mbox{Carrier}}}}={\frac {V_{m}V_{c}}{2}}\left[\underbrace {\cos \left(\left(\omega _{c}+\omega _{m}\right)t\right)}_{{{\mbox{USB}}}}+\underbrace {\cos \left(\left(\omega _{c}-\omega _{m}\right)t\right)}_{{{\mbox{LSB}}}}\right]](https://wikimedia.org/api/rest_v1/media/math/render/svg/802acb0ca94b7acbfb575aa0290e4f1b04a50625)
Demodulation
For demodulation, the audio frequency and the carrier frequency must be exact. Otherwise, distortion will occur. DSB-SC can be demodulated if modulation index is less than unity.
How it works
This is best shown graphically. Below is a message signal that one may wish to modulate onto a carrier, consisting of a couple of sinusoidal components.
The equation for this message signal is .
The carrier, in this case, is a plain 5 kHz () sinusoid—pictured below.
The modulation is performed by multiplication in the time domain, which yields a 5 kHz carrier signal, whose amplitude varies in the same manner as the message signal.
![x(t)=\underbrace {\cos \left(2\pi 5000t\right)}_{{\mbox{Carrier}}}\times \underbrace {\left[{\frac {1}{2}}\cos \left(2\pi 800t\right)-{\frac {1}{2}}\cos \left(2\pi 1200t\right)\right]}_{{\mbox{Message Signal}}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/c908bd48c94a484e5cb06c3bf2fa72a3c3e473f3)
The name "suppressed carrier" comes about because the carrier signal component is suppressed—it does not appear in the output signal. This is apparent when the spectrum of the output signal is viewed:
