394 research outputs found
Carrier Sense Random Packet CDMA Protocol in Dual-Channel Networks
Code resource wastage is caused by the reason that many hopping frequency (FH) sequences are unused, which occurs under the condition that the number of the actual subnets needed for the tactical network is far smaller than the networking capacity of code division net¬working. Dual-channel network (DCN), consisting of one single control channel and multiple data channels, can solve the code resource wastage effectively. To improve the anti-jamming capability of the control channel of DCN, code division multiple access (CDMA) technology was introduced, and a carrier sense random packet (CSRP) CDMA protocol based on random packet CDMA (RP-CDMA) was proposed. In CSRP-CDMA, we provide a carrier sensing random packet mechanism and a packet-segment acknowledgement policy. Furthermore, an analytical model was developed to evaluate the performance of CSRP-CDMA networks. In this model, the impacts of multi-access interference from both inter-clusters and intra-clusters were analyzed, and the mathematical expressions of packet transmission success probability, normalized network throughput and signal interference to noise ratio, were also derived. Analytical and simulation results demonstrate that the normalized network throughput of CSRP-CDMA outperforms traditional RP-CDMA by 10%, which can guarantee the resource utilization efficiency of the control channel in DCNs
Superconducting transmon qubit-resonator quantum baterry
Quantum battery (QB) is the miniature energy storage and release device and
plays a crucial role in future quantum technology. Here, an implementation
scheme of a QB is proposed on a superconducting circuit which is composed by
coupled transmon qubits and a one-dimensional transmission line resonator.
We derive the Hamiltonian of the QB system and investigate its charging
performance by considering three decay channels. We find that the presence of
the decay channels suppresses the high oscillation of the energy storage
process, thereby realizing a stable and powerful QB. In particular, compared
with the resonator decay and the qubit relaxation, the qubit dephasing shows a
counterintuitive advantage in our QB. We show that the nearest neighbor
interaction always have a positive impact on the stable energy and the coupling
only significantly influences the maximum charging power in the fully
nondegenerate ground state region. We also demonstrate the feasibility of our
approach by evaluating the QB performance under experimental parameters.Comment: 8 pages, 6 figure
Cavity-Heisenberg spin chain quantum battery
We propose a cavity-Heisenberg spin chain (CHS) quantum battery (QB) with the
long-range interactions and investigate its charging process. The performance
of the CHS QB is substantially improved compared to the Heisenberg spin chain
(HS) QB. When the number of spins , the quantum advantage of
the QB's maximum charging power can be obtained, which approximately satisfies
a superlinear scaling relation . For the CHS QB,
can reach and even exceed , while the HS QB can only reach about
. We find that the maximum stored energy of the CHS QB has a
critical phenomenon. By analyzing the Wigner function, von Neumann entropy, and
logarithmic negativity, we demonstrate that entanglement can be a necessary
ingredient for QB to store more energy, but not sufficient
Numerical Investigation of Flow and Heat Transfer Characteristics in Plate with Multiple Incline Stage Holes
In this paper, the effects of impingement and film composite cooling on the design of combustion chamber cooling structure are simulated by numerical simulation. The focus of the investigation was on increased film cooling efficiency and enhanced heat transfer between the coolant and the hole wall. The five-stage shaped hole model and one cylindrical hole design have the same equivalent flow area. The flow and heat transfer characteristics of cylindrical hole and stage-shaped hole were numerically investigated under same blowing ratio, and compared at the same blowing ratio. The results showed the stage-shaped hole resulted in higher cooling effectiveness, especially in rear part, and the mechanisms of which were studied in details. The consequences of the phase parameters in the flow have very clearly dependedt on the internal shape of the corresponding hole. Stage-shaped holes formed impact inside the wall, tapped the coolant potential in cooling, and increased the heat transfer inside the solid wall. Further, stage-shaped hole resulted in unstabilized flow inside hole, gave an enhancement of lateral spreading ability, and brought a significant increase of the film lateral effectiveness. Further, the affection of area ratio and height ratio has been studied by five models. The results show that the increasing of area ratio leads to an increase in cooling efficiency, which also indicates the increasing of height ratio showed slight affection
Three-level Dicke quantum battery
Quantum battery (QB) is the energy storage and extraction device that is
governed by the principles of quantum mechanics. Here we propose a three-level
Dicke QB and investigate its charging process by considering three quantum
optical states: a Fock state, a coherent state, and a squeezed state. The
performance of the QB in a coherent state is substantially improved compared to
a Fock and squeezed states. We find that the locked energy is positively
related to the entanglement between the charger and the battery, and
diminishing the entanglement leads to the enhancement of the ergotropy. We
demonstrate the QB system is asymptotically free as . The
stored energy becomes fully extractable when , and the charging power
follows the consistent behavior as the stored energy, independent of the
initial state of the charger.Comment: 9 Pages, 9 Figure
Closed-loop three-level charged quantum battery
Quantum batteries are energy storage or extract devices in a quantum system.
Here, we present a closed-loop quantum battery by utilizing a closed-loop
three-state quantum system in which the population dynamics depends on the
three control fields and associated phases. We investigate the charging process
of the closed-loop three-level quantum battery. The charging performance is
greatly improved due to existence of the third field in the system to form a
closed-contour interaction. Through selecting an appropriate the third control
field, the maximum average power can be increased, even far beyond the most
ideal maximum power value of non-closed-loop three-level quantum battery
(corresponding to the most powerful charging obtainable with minimum quantum
speed limit time and the maximum charging energy). We study the effect of
global driving-field phase on the charging process and find the maximum
extractable work (`ergotropy') and charging power vary periodically under
different control field, with a period of . Possible experimental
implementation in nitrogen-vacancy spin is discussed
Analytically solvable many-body Rosen-Zener quantum battery
Quantum batteries are energy storage devices that satisfy quantum mechanical
principles. How to obtain analytical solutions for quantum battery systems and
achieve a full charging is a crucial element of the quantum battery. Here, we
investigate the Rosen-Zener quantum battery with two-level systems, which
includes atomic interactions and external driving field. The analytical
solutions of the stored energy, changing power, energy quantum fluctuations,
and von Neumann entropy are derived by employing the gauge transformation. We
demonstrate that full charging process can be achieved when the external
driving field strength and scanning period conforms to a quantitative
relationship. The local maximum value of the final stored energy corresponds to
the local minimum values of the final energy fluctuations and von Neumann
entropy. Moreover, we find that the atomic interaction induces the quantum
phase transition and the maximum stored energy of the quantum battery reaches
the maximum value near the quantum phase transition point. Our result provides
an insightful theoretical scheme to realize the efficient quantum battery.Comment: 9 pages,7 figure
Adiabatic light propagation in nonlinear waveguide couplers with longitudinally varying detunings via resonance-locked inverse engineering
We investigate the adiabatic evolution of light in nonlinear waveguide
couplers via resonance-locked inverse engineering based on stimulated Raman
adiabatic passage (STIRAP). The longitudinal varying detunings of the
propagation coefficients are designed to eliminate dynamically the nonlinear
effect, which induce the non-adiabatic oscillations. We show that different
light evolutions such as complete light transfer, light split and light return
can be realized adiabatically with appropriate choices of the detunings even in
the nonlinear regime. The features open new opportunities for the realization
of all-optical nonlinear devices with high fidelity in integrated optics.Comment: 8 pages,6 figure
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