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AM Noise Analysis. Professor Z Ghassemlooy Electronics and IT Division School of Engineering Sheffield Hallam University U.K. Contents. DSBC (AM) Receiver model Envelope detection Synchronous Detection Signal-to-noise ratio DSB-SC - Signal-to-noise ratio
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AM Noise Analysis Professor Z Ghassemlooy Electronics and IT Division School of Engineering Sheffield Hallam University U.K. Z. Ghassemlooy
Contents • DSBC (AM) • Receiver model • Envelope detection • Synchronous Detection • Signal-to-noise ratio • DSB-SC - Signal-to-noise ratio • SSB-SC - Signal-to-noise ratio Z. Ghassemlooy
SNRo SNRi Message signal + noise + DSB-C White noise w(t) vi(t) = cr(t) + vn(t) vo(t) = m(t) + vn(t) AM Receiver - Envelope Detector Receiver Demodulator Diode + LPF (B) BPF (B) Received modulated signal power R = 1 Band-limited noise power Input signal-to-noise ratio Z. Ghassemlooy
Recovered signal AM Receiver - Envelope Detector - cont. The vector diagram of AM + noise at the input of the demodulator is RT(t) y(t) R(t) x(t) The envelope of AM + noise is Assuming SNRi >> 1, thus [….]2 >> y2(t), therefore: DC blocked by a capacitor Recovered message signal power Output noise power Z. Ghassemlooy
SNRo Threshold SNRi SNRi AM Receiver - Envelope Detector -cont. Thus the output signal-to-noise ratio Modulation noise improvement factor For M = 1 (i.e 100%) MNI = 1.75 dB The demodulator exhibits a threshold effect where below certain SNRi the SNRo deteriorate rapidly. Z. Ghassemlooy
AM Receiver - Envelope Detector - cont. For the case where SNRi << 1 the vector diagram is R(t) RT(t) The envelope of AM + noise is Dominant term Note: output containes no term proportional to the information m(t) = ECMcos wmt. The last term is the signal multiplied by time-varying noise, therefore is of no use in recovering m(t). Z. Ghassemlooy
SNRi SNRo Message signal + noise LPF (B) BPF (B) + X DSB-C White noise w(t) cos ct vo(t) = m(t) + vn(t) AM Receiver - Synchronous Detector Receiver Demodulator z(t) vi(t) = cr(t) + vn(t) Note that Z. Ghassemlooy
AM Receiver - Synchronous Detector - cont. DC Output signals High frequency High frequency Information High frequency Information Low frequency noise High frequency High frequency Z. Ghassemlooy
SNRo Threshold SNRi SNRi AM Receiver - Synchronous Detector - cont. SNRiis the same as in envelope detector Recovered message signal power Output noise power Synch. detection Envelope detection For M =1, MNI = -1.76 dB, i.e. degradation in SNR. Z. Ghassemlooy
Receiver Demodulator SNRi SNRo z(t) Message signal + noise LPF (B) BPF (B) + X DSB-C C White noise w(t) LO Sw(f) Ec 0.5MEc o/2 f c c-m c+m o m -m 0 -c+m c-m -(c+m) c+m B c c AM Receiver - Synchronous Detector - cont. PT B 0.5PT o/2 Z. Ghassemlooy
SNRi SNRo Message signal + noise LPF (B) BPF (B) X cos ct vo(t) = m(t) + vn(t) DSB-SC Noise Analysis Receiver Demodulator z(t) + DSB-SC White noise w(t) vi(t) = cr(t) + vn(t) Substituting for Z. Ghassemlooy
DSB-SC Noise Analysis - cont. Information Output signals Noise High frequency • Power analysis R = 1 Received modulated signal power Band-limited noise power Z. Ghassemlooy
DSB-SC Noise Analysis - cont. Recovered message signal power Output noise power This improvement is due to presence of two sidebands in the received signal which is translated down to the baseband and added coherently. Noise power on the other hand does not add coherently (quadrature component is reject by the detector). Z. Ghassemlooy
SNRi SNRo Message signal + noise LPF (B) BPF (B) X cos ct vo(t) = m(t) + vn(t) SSB-SC Noise Analysis Receiver Demodulator z(t) + SSB-SC White noise w(t) vi(t) = cr(t) + vn(t) Z. Ghassemlooy
SNRo SNRi SSB-SC Noise Analysis - cont. • Power analysis R = 1 Input signal power Output signal power Output noise power Noise power Z. Ghassemlooy