Abstract
In the current age of advanced technologies, there is an escalating demand for reliable wireless systems, catering to the high data rates of mobile multimedia applications. This article presents a novel approach to the concept of Self-Concatenated Convolutional Coding (SECCC) with Sphere Packing (SP) modulation via Differential Space-Time Spreading- (DSTS-) based smart antennas. The two transmitters provide transmit diversity which is capable of recuperating the signal from the effects of fading, even with a single receiving antenna. The proposed DSTS-SP SECCC scheme is probed for the Rayleigh fading channel. The SECCC structure is developed using the Recursive Systematic Convolutional (RSC) code with the aid of an interleaver. Interleaving generates randomness in exchange for extrinsic information between the constituent decoders. Iterative decoding is invoked at the receiving side to enhance the output performance by attaining fruitful convergence. The convergence behaviour of the proposed system is investigated using EXtrinsic Information Transfer (EXIT) curves. The performance of the proposed system is ascertained with the H.264 standard video codec. The perceived video quality of DSTS-SP SECCC is found to be significantly better than that of the DSTS-SP RSC. To be more precise, the proposed DSTS-SP SECCC system exhibits an E b / N 0 gain of 8 dB at the PSNR degradation point of 1 dB, relative to the equivalent rate DSTS-SP RSC. Similarly, an E b / N 0 gain of 10 dB exists for the DSTS-SP SECCC system at 1 dB degradation point when compared with the SECCC scheme dispensing with the DSTS-SP approach.
Highlights
The recent developments in wireless technologies have resulted in the expansion of higher data rates of cellular systems with diverse applications, severely limiting the available bandwidth [1]
Differential Space-Time Spreading- (DSTS-)Sphere Packing (SP) Self-Concatenated Convolutional Coding (SECCC) Differential Space-Time Spreading (DSTS)-SP Recursive Systematic Convolutional (RSC) SECCC scheme incorporation of DSTS-SP results in significantly lower Bit-Error Rate (BER), achieving higher bandwidth efficiency
For the proposed DSTS-SP SECCC system, the 10−4 value of BER is achieved at a lower Eb/N0 value in comparison with the other similar rate schemes
Summary
The recent developments in wireless technologies have resulted in the expansion of higher data rates of cellular systems with diverse applications, severely limiting the available bandwidth [1]. The fifth-generation (5G) wireless technology has very specific aims of further increasing the data rate and catering for the ascents in wireless services, by efficient utilization of the available bandwidth [3]. The channel offers several impingements, such as addition of noise, interference, and fading, leading to error formation and reduction in the system’s performance. These effects are mitigated at the receiver side, resulting in reliable data transfer to the destination for end users
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