Key focus: Complex Baseband Equivalent Models are behavioral models that simplify the simulation, saves computation memory requirements and run time.
This article is part of the book Digital Modulations using Matlab : Build Simulation Models from Scratch
Introduction
The passband model and equivalent baseband model are fundamental models for simulating a communication system. In the passband model, also called as waveform simulation model, the transmitted signal, channel noise and the received signal are all represented by samples of waveforms. Since every detail of the RF carrier gets simulated, it consumes more memory and time. In the case of discrete-time equivalent baseband model, only the value of a symbol at the symbol-sampling time instant is considered. Therefore, it consumes less memory and yields results in a very short span of time when compared to the passband models. Such models operate near zero frequency, suppressing the RF carrier and hence the number of samples required for simulation is greatly reduced. They are more suitable for performance analysis simulations. If the behavior of the system is well understood, the model can be simplified further.
Complex baseband representation of a modulated signal
By definition, a passband signal is a signal whose one-sided energy spectrum is centered on non-zero carrier frequency
![\tilde{s}(t) = a(t) cos \left[ 2 \pi f_c t + \phi(t) \right] = s_I(t) cos(2 \pi f_c t) - s_Q(t) sin(2 \pi f_c t) \quad (1)](https://s0.wp.com/latex.php?latex=%5Ctilde%7Bs%7D%28t%29+%3D+a%28t%29+cos+%5Cleft%5B+2+%5Cpi+f_c+t+%2B+%5Cphi%28t%29+%5Cright%5D+%3D+s_I%28t%29+cos%282+%5Cpi+f_c+t%29+-+s_Q%28t%29+sin%282+%5Cpi+f_c+t%29+%5Cquad+%281%29+&bg=ffffff&fg=000&s=2&c=20201002)
where,
Recognizing that the sine and cosine terms in the equation (1) are orthogonal components with respect to each other, the signal can be represented in complex form as
When represented in this form, the signal
Complex baseband representation of channel response
In the typical communication system model shown in Figure 2(a), the signals represented are real passband signals. The digitally modulated signal
The corresponding complex baseband equivalent (Figure 2(b)) is expressed as
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Reference:
[Proakis] Proakis J.G, Digital Communications, fifth edition, New York, McGraw–Hill, 2008
Books by the author
 Wireless Communication Systems in Matlab Second Edition(PDF)    |  Digital Modulations using Python (PDF ebook) |  Digital Modulations using Matlab (PDF ebook) |
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Topics in this chapter
| Digital Modulators and Demodulators - Passband Simulation Models ● Introduction ● Binary Phase Shift Keying (BPSK) □ BPSK transmitter □ BPSK receiver □ End-to-end simulation ● Coherent detection of Differentially Encoded BPSK (DEBPSK) ● Differential BPSK (D-BPSK) □ Sub-optimum receiver for DBPSK □ Optimum noncoherent receiver for DBPSK ● Quadrature Phase Shift Keying (QPSK) □ QPSK transmitter □ QPSK receiver □ Performance simulation over AWGN ● Offset QPSK (O-QPSK) ● π/p=4-DQPSK ● Continuous Phase Modulation (CPM) □ Motivation behind CPM □ Continuous Phase Frequency Shift Keying (CPFSK) modulation □ Minimum Shift Keying (MSK) ● Investigating phase transition properties ● Power Spectral Density (PSD) plots ● Gaussian Minimum Shift Keying (GMSK) □ Pre-modulation Gaussian Low Pass Filter □ Quadrature implementation of GMSK modulator □ GMSK spectra □ GMSK demodulator □ Performance ● Frequency Shift Keying (FSK) □ Binary-FSK (BFSK) □ Orthogonality condition for non-coherent BFSK detection □ Orthogonality condition for coherent BFSK □ Modulator □ Coherent Demodulator □ Non-coherent Demodulator □ Performance simulation □ Power spectral density |
