Abstract
In this paper, we focus on Orthogonal Frequency Division Multiplexing (OFDM) transceivers where undersampling is employed by the receiver Analog/Digital Converter (ADC) when sparse information is exchanged. Several Fast Fourier Transform (FFT) symmetry properties are exploited to allow the substitution of specific input values by others that have already been sampled by the ADC. Several architectures have been proposed in the literature for efficient FFT implementations in terms of power, speed and hardware resources. The FFT input/output values, twiddle factors, etc., are complex numbers with their real and imaginary parts being represented using fixed point format. A tradeoff has to be made between rounding error and complexity. The optimal minimum FFT word length is investigated by combining the undersampling and the rounding error. A configurable new FFT architecture has been developed in hardware description language to test the error model with various FFT sizes, word lengths and Quadrature Amplitude Modulations (QAM). A system designer can take into account the sparseness of the input data and define the desired rounding and undersampling error relation. Τhe developed error model would then predict the required word length and ADC resolution with average Root Mean Square Error (RMSE) less than 1.
Highlights
Recovering information from fewer samples is possible if data are sparse or compressible.In this case, an Analog/Digital Converter (ADC) can operate in a sampling rate closer to the actual information rate rather than the Nyquist one [1]
Groups of log2 q bits are mapped to q-Quadrature Amplitude Modulations (QAM) constellation symbols Xk (0≤k
We focus on the error modelling of DIT Fast Fourier Transform (FFT) in this paper
Summary
Recovering information from fewer samples is possible if data are sparse or compressible. The simulation results show that full information recovery can be achieved if 50% of the time the ADC operates in 7/8 of its normal rate and the sparseness s in input data is less than 2% i.e., less than 2% of the input bits are non-trivial. Selecting the desired modulation scheme and FFT size the developed error model will estimate the minimum word length to achieve the specified relation between RE and UE for a particular sparseness level of the input data. The OFDM configuration in terms of FFT size, modulation and word length cannot change dynamically in real time They are statically defined in order to measure the error for various sparseness levels.
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