Single-Flux-Quantum Bipolar Digital-to-Analog Converter Comprising Polarity-Switchable Double-Flux-Quantum Amplifier

We present a single-flux-quantum (SFQ)-based digital-to-analog converter (DAC) generating bipolar output voltages, in which the key component is a polarity-switchable double-flux-quantum amplifier (PS-DFQA). The DAC comprised a dc/SFQ converter, an 8-bit variable pulse-number-multiplier (PNM), and a 8-fold PS-DFQA integrated on a single chip. SFQ pulse-frequency modulation was employed to realize variable output voltage amplitude, for which the multiplication factor of the variable-PNM was controlled by a commercial data generator situated at room temperature. The variable-PNM realized 8-bit resolution with a multiplication factor between 0 and 255. Bias currents fed to the 8-fold PS-DFQA were polarity-switched in synchronization with the digital code for the variable-PNM. The whole circuits including I/O elements were designed using SFQ cell libraries, and fabricated using a niobium integration process. Sinusoidal bipolar voltage waveform of 0.38 mVpp was demonstrated using a reference signal source of 43.94 MHz

Numerical Simulation of Single-Electron Tunneling in Random Arrays of Small Tunnel Junctions Formed by Percolation of Conductive Nanoparticles

We numerically simulated electrical properties, i.e., the resistance and Coulomb blockade threshold, of randomly-placed conductive nanoparticles. In simulation, tunnel junctions were assumed to be formed between neighboring particle-particle and particle-electrode connections. On a plane of triangle 100×100 grids, three electrodes, the drain, source, and gate, were defined. After random placements of conductive particles, the connection between the drain and source electrodes were evaluated with keeping the gate electrode disconnected. The resistance was obtained by use of a SPICE-like simulator, whereas the Coulomb blockade threshold was determined from the current-voltage characteristics simulated using a Monte-Carlo simulator. Strong linear correlation between the resistance and threshold voltage was confirmed, which agreed with results for uniform one-dimensional arrays

Comparison of Wind and Wave Fields between High-Resolution Simulations and Operational Forecast Products : A Case of Wave Development under Easterly Wind Jets in the West of the Tsugaru Strait

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Basic Study on Sediment Behavior in the Chiyoda Experimental Channel

Source: ICHE Conference Archive - https://mdi-de.baw.de/icheArchiv

A MODEL FOR ANALYSIS OF THE IMPACT BETWEEN A TENNIS RACKET AND A BALL

The purpose of this study is to determine the validity of a vibration model designed to elucidate the impact between tennis rackets and balls. Generally, a vibration model consists of elasticity and viscosity. A rod was added to the existing model to indicate the contact point on the racket face because vibration changes depend on the position of impact. Comparing the results of the model‟s simulation and the physical experiment that was performed, it was found that the model was appropriate with regards to amplitude and frequency of vibrations. Using such a model, it should be possible to modify the characteristics of rackets. This will be beneficial, not only for racket selection, but also for new design

SIMULATION OF BALL HANDLING IN OVERHEAD PASSING IN VOLLEYBALL

The purpose of this study was to obtain basic data to be used for teaching ball handling in overhead passing in volleyball. The method used was simulation of a mass-elasticity-viscosity model consisting of arms, hands and ball. First, the acceleration of the ball was calculated during contact with the hands through means of VTR images. As a result of comparing this acceleration with that of the simulation of the model, it was found to be appropriate, and the coefficients of elasticity and viscosity were sufficient. The coefficients indicated that a skilled player changes hand elasticity depending on the height of set up. This is the reason that skilled players can control the ball with a greater degree of accuracy. On the other hand, unskilled players can not change hand elasticity as easily, which affects their control of the ball

1000-Fold Double-Flux-Quantum Voltage Multiplier Employing Directional Propagation of Flux Quanta Through Asymmetrically Damped Junction Branches

Precise voltage generation is a unique feature of single-flux-quantum (SFQ) circuits, in addition to their high-speed digital signal processing with low power consumption. We investigated SFQ pulse-frequency modulation D/A converters for metrological applications. In our SFQ-based D/A converters, the maximum output voltage is determined by the maximum SFQ pulse-frequency at the pulse number multiplier, and by the voltage multiplication factor at the voltage multiplier. In this study, we present our new design for a double-flux-quantum amplifier (DFQA) that works as a quantum voltage multiplier. In the new parameter set, we tuned the damping parameters of the Josephson junctions to realize proper propagation of SFQ pulses. A 1000-fold DFQA designed with the new parameter set was fabricated using a 25-μ A/μ m 2 Nb/AlOx/Nb integration technology. A 1000-fold voltage multiplication was confirmed for the input voltage up to 43 μV, with a corresponding SFQ repetition frequency of 21 GHz. That is, the output voltage reached 43 mV