Efficient FPGA implementation of high-throughput mixed radix multipath delay commutator FFT processor for MIMO-OFDM

This article presents and evaluates pipelined architecture designs for an improved high-frequency Fast Fourier Transform (FFT) processor implemented on Field Programmable Gate Arrays (FPGA) for Multiple Input Multiple Output Orthogonal Frequency Division Multiplexing (MIMO-OFDM). The architecture presented is a Mixed-Radix Multipath Delay Commutator. The presented parallel architecture utilizes fewer hardware resources compared to Radix-2 architecture, while maintaining simple control and butterfly structures inherent to Radix-2 implementations. The high-frequency design presented allows enhancing system throughput without requiring additional parallel data paths common in other current approaches, the presented design can process two and four independent data streams in parallel and is suitable for scaling to any power of two FFT size N. FPGA implementation of the architecture demonstrated significant resource efficiency and high-throughput in comparison to relevant current approaches within literature. The proposed architecture designs were realized with Xilinx System Generator (XSG) and evaluated on both Virtex-5 and Virtex-7 FPGA devices. Post place and route results demonstrated maximum frequency values over 400 MHz and 470 MHz for Virtex-5 and Virtex-7 FPGA devices respectively

Properties and customization of sensor materials for biomedical applications.

Low-power chemo- and biosensing devices capable of monitoring clinically important parameters in real time represent a great challenge in the analytical field as the issue of sensor calibration pertaining to keeping the response within an accurate calibration domain is particularly significant (1–4). Diagnostics, personal health, and related costs will also benefit from the introduction of sensors technology (5–7). In addition, with the introduction of Registration, Evaluation, Authorization, and Restriction of Chemical Substances (REACH) regulation, unraveling the cause–effect relationships in epidemiology studies will be of outmost importance to help establish reliable environmental policies aimed at protecting the health of individuals and communities (8–10). For instance, the effect of low concentration of toxic elements is seldom investigated as physicians do not have means to access the data (11)

An Accuracy-Improved Fixed-Width Booth Multiplier Enabling Bit-Width Adaptive Truncation Error Compensation

Fixed-width Booth multipliers (FWBMs) generate a product with the same bit width as the operand and have been extensively employed in many digital systems. Various truncation error compensation (TEC) schemes have been presented for FWBM designs, aiming to reduce hardware costs while preserving operation accuracy. In general, the existing TEC methods function adequately for an exact bit width of the operand but fail to consider the TEC effect for FWBM inputs with various bit-width levels. To address this issue, we propose a bit-width adaptive TEC (BWATEC) scheme for providing high-accuracy TEC functions that are adaptive to the multiple L′-bit numerical ranges of input data for an L-bit FWBM (L′ ≤ L). We also present adjustable architecture for a 16-bit FWBM to enable the proposed BWATEC scheme and evaluate the hardware performance, using the TSMC 40 nm standard cell library. Relative to the contrast 16-bit FWBM approaches that use state-of-the-art TEC methods, the proposed BWATEC-enabled FWBM design can achieve reductions in the area-delay-error product of 7.9–50.9%, 17.1–69.5%, 29.9–82.2%, and 100% for the 14-bit, 12-bit, 10-bit, and 8-bit inputs, respectively. Moreover, the resultant 16-bit FWBM with BWATEC was verified by using the field-programmable gate array for convolutional neural network acceleration

Simple and Fast Method To Fabricate Single-Nanoparticle-Terminated Atomic Force Microscope Tips

This paper introduces a simple, yet controllable scheme to pick up a single 13 nm Au nanoparticle (Au-NP) using the tip of an atomic force microscope (AFM) probe through the application of electrical biases between the tip and the Au-NP. Transmission electron microscope (TEM) images were acquired to verify that a single Au-NP was attached to the AFM probe. We postulate that the mechanism underlying the ability to manipulate individual Au-NPs at the apex of the AFM probe tip is Coulomb interaction induced by tip bias. The AFM tip with the attached Au-NP was then used to study the interaction between a single quantum dot (QD) and the Au-NP. The blinking behavior of single colloidal CdSe/ZnS core/shell QD was significantly suppressed with the approach of the 13 nm Au-NP attached to the AFM tip