| Summary: | In this paper, two real-time architectures of medium access techniques useful for future generation of wireline and wireless communication systems are presented. One architecture is based on discrete cosine transform (DCT), while the second approach implements a filter-bank multi-carrier (FBMC) system. A comparative analysis, in terms of resource consumption, performance, and precision, is shown. The comparison considers a floating-point model, a fixed-point model, and experimental tests. These models make it possible to evaluate the effect of the fixed-point precision in the implementation and, in turn, to verify the correctness of the developed architecture. The simulation models and the experimental tests have been carried out in different practical environments in order to achieve a further analysis. The two proposed architectures have been implemented on a field-programmable gate array (FPGA) device. Furthermore, the architectures have been included as advanced peripherals in a system-on-chip, which also integrates a soft microprocessor to monitor the whole system and manage the data transfers. As a communication scenario, the proposed architectures have been particularized to operate in real time while meeting all timing requirements defined by a broadband power line communications standard. For that case, the system has achieved a desired transmission rate of 62.5 Ms/s at the converters, providing mean squared errors, at the output for an ideal channel, below 3·10<sup>-5</sup> for both the DCT and FBMC approaches, whereas each transmitter/receiver requires around 50% of the DSP cells available in the Xilinx XC6VLX240T FPGA, the most demanded resource in the device.
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