This paper presents architecture of block-level-parallel layered decoder for irregular LDPC code. It can be reconfigured to support various block lengths and code rates of IEEE 802.11n (WiFi) wireless-communication standard. We have proposed efficient comparison techniques for both column and row layered schedule and rejection-based high-speed circuits to compute the two minimum values from multiple inputs required for row layered processing of hardware-friendly min-sum decoding algorithm. The results show good speed with lower area as compared to state-of-the-art circuits. Additionally, this work proposes dynamic multi-frame processing schedule which efficiently utilizes the layered-LDPC decoding with minimum pipeline stages. The suggested LDPC-decoder architecture has been synthesized and post-layout simulated in 90 nm-CMOS process. This decoder occupies 5.19 area and supports multiple code rates like 1/2, 2/3, 3/4 & 5/6 as well as block-lengths of 648, 1296 & 1944. At a clock frequency of 336 MHz, the proposed LDPC-decoder has achieved better throughput of 5.13 Gbps and energy efficiency of 0.01 nJ/bits/iterations, as compared to the similar state-of-the-art works.
Index Terms-Data-rate/throughput, IEEE 802.11n (WiFi) wireless-communication standard and very-large scale-integration (VLSI) design, LDPC codes, LDPC-layered decoding.1549-8328
Surface acoustic wave (SAW) sensors extensively employ mass loading effect of a sensing film coated over the surface of a SAW device. We report experimental and simulation results of mass loading by SU-8 micropillars (in place of sensing film) attached normal to the surface of SAW resonators. For certain size of micropillars, we have observed an increase in the resonance frequency of the resonator, in contrast to the decrease in the resonance frequency normally caused by mass loading. The SAW resonator and the pillars constitute a system of coupled resonators, and for high values of stiffness at the interface of the pillar and substrate the shift in the resonance frequency is positive.
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