Figure
Correlation between the component of the average velocity vave on the s1 -axis and the self-propulsion force Fsd .
Source publication
Relationship between matter and energy transport has always been one of the key issues that researchers have been searching for in statistical physics and complexity science. In many transport phenomena, the active transport with zero or even no external force in life activities has attracted extensive attention of scholars. As a special kind of ac...
Citations
In this paper, a mixer-first receiver frontend with dual-feedback baseband is proposed. The negative resistive and positive capacitive feedback paths are both applied to single-stage inverter-based operational transconductance amplifier (OTA) with fewer poles, to cover a wide BB frequency range. The [Formula: see text]-path filtering at the RF side and second-order filtering at the BB side inhibit out-of-band blocker interferences. The receiver frontend is designed in 65 nm CMOS. Simulation results display an NF of 2.1 dB across 306 MHz IF bandwidth, and a maximum gain of 33 dB from 1 to 3 GHz LO frequency range. The in-band and out-of-band IIP3 are −13 and 16 dBm, respectively. The receiver core draws 40 mW at 1 GHz LO frequency.
In this paper, we present a quantum group signature (QGS) scheme based on orthogonal product states (OPSs) that cannot be perfectly distinguished by local operations and classical communication. Our scheme has all the properties of QGS, including unforgeability, undeniability, traceability, verifiability and anonymity. These properties can guarantee the security of the scheme. More importantly, different particles of a product state that comes from a nonlocal set are transmitted separately, thus the information that is encoded in the product state will not be leaked. Security and efficiency analysis of the scheme show that our scheme is secure and efficient.
In this paper, a receiver front-end in 180 nm CMOS operating at 28 GHz is presented. The receiver front-end consists of a cascade low-noise amplifier (LNA) with two gain stages and a current-bleeding active mixer with tunable loads. By embedding a quadrature coupler into the mixer, the circuit delivers in-phase and quadrature outputs. The proposed architecture avoids the traditional I/Q implementation by process-sensitive quadrature voltage control oscillators (VCOs) with larger power consumption at high frequencies. The adopted transformers and inductors are optimized by a momentum tool. The simulated results show that the receiver front-end provides an NF of 5.48 dB, a conversion gain of 18.1 dB, and an IIP3 around −8.5 dBm at 28 GHz. The circuit dissipates 17.3 mW under a 1.8 V supply.
Abstract: Non-equilibrium phase transition is always one of the most important issue for complexity science, since it can reveal physical mechanisms of abundant physical phenomena. Exploring applications of non-equilibrium phase transitions in basic paradigm models of complexity science is vital for better comprehending essences of real physical processes. Among these processes, totally asymmetric simple exclusion process (TASEP) stands out owing to important theoretical significances and practical value, whose importance is regarded as being equivalent to Ising model. In this paper, a heterogeneous interacting particle system constituted by three-lane TASEPs with binding and unbinding processes affected by interacting energies among adjacent subsystems is proposed. Nonlinear equations about all particle configuration states of boundaries and bulk are established. We find and analyze numerical local densities and currents by performing simple and cluster mean-field analyses. Nine species of phases including homogeneous phases and mixed ones are discovered. Specifically, as for mixed phases, densities of middle channel are much larger and smaller than those of neighboring ones when specific interacting energy is positive and negative, respectively. All triple points are found to move to upper left corner of phase space with increasing interacting energy. Current phase diagrams mapped into density phase ones are explored, which reveal currents in homogenous phases rely on just one critical governing parameter (namely, injecting rate or escaping one) while those in mixed phases are controlled by the coupling effects of these two critical governing rates. Theoretical results from mean-field analyses are confirmed by simulations, which yield to fine coincidences. This work will improve understanding of non-equilibrium phase transition mechanisms in such basic paradigm models and stochastic dynamics in corresponding critical phenomena to a certain extent, especially cluster effects and related dynamic processes of self-driven particles in such systems in the area of complex system science and statistical physics at mesoscopic scale.
Keywords: Non-equilibrium phase transitions; TASEP; Binding and unbinding process; Density phase diagrams; Current phase diagrams
(Accepted Article)