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Todo lo que tiene que ver con lo que es la modulacion digital, en ambito de la electrocnica digital
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SISTEMAS DE COMUNICACIN 2
Universidad de CuencaIngeniera Electrnica y Telecomunicaciones
Ciclo Marzo 2015 a Agosto 2015
SISTEMAS DE COMUNICACIN 2TEMA 8: MODULACIN DIGITAL
Sub-Tema 1 :Conmutador de desplazamiento de amplitud (ASK)Sub-Tema 2 :Conmutador de desplazamiento de frecuencia (FSK)Sub-Tema 3 :Conmutador de desplazamiento de fase (PSK)Sub-Tema 4 :Comparacin de sistemas de modulacin binaria digitalSub-Tema 5 :AM de cuadratura (QAM) y PSK cuaternaria (QPSK)Sub-Tema 6 :FSK ortogonal M-nariaSub-Tema 7 :PSK M-ariaSub-Tema 8 :Comparacin de mtodos de modulacin digital
TEMA 8: MODULACIN DIGITAL
MODULACIN DIGITAL
MODULACIN DIGITAL
MODULACIN DIGITAL
MODULACIN DIGITAL
MODULACIN DIGITAL
MODULACIN DIGITAL
MODULACIN DIGITAL
MODULACIN DIGITAL
MODULACIN DIGITAL
MODULACIN DIGITAL
TEMA 8: MODULACIN DIGITAL
Sub-Tema 1 :Conmutador de desplazamiento deamplitud (ASK)
AMPLITUDE-SHIFT KEYING (ASK)Sub-Tema 1 :Conmutador de desplazamiento de amplitud (ASK)
In amplitude-shift keying, the amplitude of a high-frequency carrier signal isswitched between two or more values in response lo the PCM code. For thebinary case, the usual choice is on-off keying (sometimes abbreviated as OOK).
AMPLITUDE-SHIFT KEYING (ASK)Sub-Tema 1 :Conmutador de desplazamiento de amplitud (ASK)
In amplitude-shift keying, the amplitude of a high-frequency carrier signal isswitched between two or more values in response lo the PCM code. For thebinary case, the usual choice is on-off keying (sometimes abbreviated as OOK).
Time-autocorrelation function
Optimum decision time is for t = T
Optimum decision threshold E/2
AMPLITUDE-SHIFT KEYING (ASK)Sub-Tema 1 :Conmutador de desplazamiento de amplitud (ASK)
ASK system is equivalent to an on-offbase band system in terms of theaverage signal-to-noise ratio requiredfor a given probability of error.
AMPLITUDE-SHIFT KEYING (ASK)Sub-Tema 1 :Conmutador de desplazamiento de amplitud (ASK)
TEMA 8: MODULACIN DIGITAL
Sub-Tema 2 :Conmutador de desplazamiento defrecuencia (FSK)
FREQUENCY-SHIFT KEYING (FSK)Sub-Tema 2 :Conmutador de desplazamiento de frecuencia (FSK)
In frequency-shift keying, the instantaneous frequency of the carrier signal isswitched between two (or more) values in response to the PCM code
FREQUENCY-SHIFT KEYING (FSK)Sub-Tema 2 :Conmutador de desplazamiento de frecuencia (FSK)
On an average bit energy-to-noise basis, for the same peak-power requirements FSK has a3-dB advantage over ASKbecause the latter is offapproximately one-half of thetime
FREQUENCY-SHIFT KEYING (FSK)Sub-Tema 2 :Conmutador de desplazamiento de frecuencia (FSK)
FREQUENCY-SHIFT KEYING (FSK)Sub-Tema 2 :Conmutador de desplazamiento de frecuencia (FSK)
What is the optimum frequency separation for the detection of FSK?
Orthogonality condition
FREQUENCY-SHIFT KEYING (FSK)Sub-Tema 2 :Conmutador de desplazamiento de frecuencia (FSK)
TEMA 8: MODULACIN DIGITAL
Sub-Tema 3 :Conmutador de desplazamiento defase (PSK)
PHASE-SHIFT KEYING (PSK)Sub-Tema 3 :Conmutador de desplazamiento de fase (PSK)
In phase-shift keying, the phase of the carrier signal is switched between two(or more) values in response to the PCM code.
For binary PCM, a 180 phase shift is a convenient choice because it simplifiesthe modulator design and is often used. This particular choice is known asphase-reversal keying (PRK)
The maximum peak signal-to-noise ratio for a givensignal energy is then obtained for the condition
Antipodal
PHASE-SHIFT KEYING (PSK)Sub-Tema 3 :Conmutador de desplazamiento de fase (PSK)
PRK has the same probability of-errorperformance as polar-baseband systems.
To attain a given error probability theaverage power required for FSK and ASK istwice that required for PRK.
PHASE-SHIFT KEYING (PSK)Sub-Tema 3 :Conmutador de desplazamiento de fase (PSK)
PHASE-SHIFT KEYING (PSK)Sub-Tema 3 :Conmutador de desplazamiento de fase (PSK)
PHASE-SHIFT KEYING (PSK)Sub-Tema 3 :Conmutador de desplazamiento de fase (PSK)
TEMA 8: MODULACIN DIGITAL
Sub-Tema 4 :Comparacin de sistemas demodulacin binaria digital
COMPARISON OF BINARY DIGITAL MODULATION SYSTEMSSub-Tema 4 :Comparacin de sistemas de modulacin binaria digital
TEMA 8: MODULACIN DIGITAL
Sub-Tema 5 :AM de cuadratura (QAM) y PSKcuaternaria (QPSK)
QUADRATURE AM (QAM) AND QUATERNARY PSK (QPSK)Sub-Tema 5 :AM de cuadratura (QAM) y PSK cuaternaria (QPSK)
In tbe QAM systemTo restrict the bandwidthand provide the desiredspectral shaping.
I and Q data signals aremodulated using DSB-SCmodulation
QUADRATURE AM (QAM) AND QUATERNARY PSK (QPSK)Sub-Tema 5 :AM de cuadratura (QAM) y PSK cuaternaria (QPSK)
QAM system
Bandwidtb efficiency ofQAM is 2 bps/Hz
QUADRATURE AM (QAM) AND QUATERNARY PSK (QPSK)Sub-Tema 5 :AM de cuadratura (QAM) y PSK cuaternaria (QPSK)
QAM system
QAM can be viewed as phase modulation if the I and Q signals have identical magnitudes.Such systems are popularly known as quadrature PSK (QPSK) systems.
QUADRATURE AM (QAM) AND QUATERNARY PSK (QPSK)Sub-Tema 5 :AM de cuadratura (QAM) y PSK cuaternaria (QPSK)
In the QPSK system, all of the information is conveyed by the phase, and aconstant envelope is desirable. To restrict the bandwidth of the data
stream to less than one-half the carrierfrequency
I and Q data signals aremodulated using DSB-SCmodulation
Spectral shaping
To maintain a constant envelope
QUADRATURE AM (QAM) AND QUATERNARY PSK (QPSK)Sub-Tema 5 :AM de cuadratura (QAM) y PSK cuaternaria (QPSK)
QPSK system
Bandwidtb efficiency ofQPSK is 2 bps/Hz
QUADRATURE AM (QAM) AND QUATERNARY PSK (QPSK)Sub-Tema 5 :AM de cuadratura (QAM) y PSK cuaternaria (QPSK)
Phase shifts of 0, 90, 180, and 270
Sub-Tema 5 :AM de cuadratura (QAM) y PSK cuaternaria (QPSK)
QUADRATURE AM (QAM) AND QUATERNARY PSK (QPSK)Sub-Tema 5 :AM de cuadratura (QAM) y PSK cuaternaria (QPSK)
The probability of error for QPSK is greater than that for BPSK (PRK). If, however, weaccount for the fact that twice as much data is being transmitted, the probability of errorperformance of both systems is the same.
Carrier recoverycircuits must beused in QPSKdemodulators.
QUADRATURE AM (QAM) AND QUATERNARY PSK (QPSK)Sub-Tema 5 :AM de cuadratura (QAM) y PSK cuaternaria (QPSK)
TEMA 8: MODULACIN DIGITAL
Sub-Tema 6 :FSK ortogonal M-naria
M -ARY ORTHOGONAL FSKSub-Tema 6 :FSK ortogonal M-naria
M-ary orthogonal signaling, useful in power-limited channels to conservetransmitted power at the expense of added bandwidth and equipmentcomplexity.
M orthogonal signals
Minimum frequencyseparation
M -ARY ORTHOGONAL FSKSub-Tema 6 :FSK ortogonal M-naria
M -ARY ORTHOGONAL FSKSub-Tema 6 :FSK ortogonal M-naria
Average power in M-ary orthogonal signalingdecrease as M is increased.
Larger values of M tend to increase thecomplexity of the transmitting and receivingequipment
M -ARY ORTHOGONAL FSKSub-Tema 6 :FSK ortogonal M-naria
M -ARY ORTHOGONAL FSKSub-Tema 6 :FSK ortogonal M-naria
TEMA 8: MODULACIN DIGITAL
Sub-Tema 7 :PSK M-aria
MARY PSKSub-Tema 7 :PSK M-aria
A convenient set of signals for M-ary PSK is the set
Bandwidth effciency
MARY PSKSub-Tema 7 :PSK M-aria
Signal constellation
MARY PSKSub-Tema 7 :PSK M-aria
8 PSK constellation
MARY PSKSub-Tema 7 :PSK M-aria
16 PSK constellation
MARY PSKSub-Tema 7 :PSK M-aria
Error Probability
M> 8 are seldom used in M-ary PSK signaling as a resultof the excessive additionalpower requirements.
MARY PSKSub-Tema 7 :PSK M-aria
Error Probability
MARY PSKSub-Tema 7 :PSK M-aria
TEMA 8: MODULACIN DIGITAL
Sub-Tema 8 :Comparacin de mtodos demodulacin digital
COMPARISON OF DIGITAL MODULATION SYSTEMSSub-Tema 8 :Comparacin de mtodos de modulacin digital
Choice of digital modulation methods Bandwidth efficiency (in bps/Hz), Error performance (Pe versus S/N) Equipment complexity (cost).
COMPARISON OF DIGITAL MODULATION SYSTEMSSub-Tema 8 :Comparacin de mtodos de modulacin digital
TEMA 8: MODULACIN DIGITAL
Ejercicios
Ejercicios
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