SIR-based multiple access with cascade yielding avoidance for distributed device-to-device communications
2
Citation
16
Reference
10
Related Paper
Citation Trend
Basis (linear algebra)
Separation (statistics)
Cite
Citations (12)
Component (thermodynamics)
Cite
Citations (1)
A simulation of a cascade system, during which the problem of determining the transfer function of a cascade system for analytical reception of the transient response occurred, is performed. It is proven that the equivalent object used in many modelling works and the cascade system are not the same. Transients obtained by using an equivalent object are different from real transients in a cascade control system. The analytical expression of the description of cascade system is received as a result of researches.
Transient (computer programming)
Cite
Citations (2)
Cite
Citations (1)
Component (thermodynamics)
Cite
Citations (9)
ABSTRACTA nonconventional gas centrifuge cascade, called the NFSW (no feed and single withdrawal) cascade, is studied in the separation of middle components by means of numerical simulation. The cascade has no feed and only a single withdrawal at either end of the cascade, different from conventional cascades, which usually have two withdrawals at the two ends of the cascade and one feed in between. The material to be separated is loaded in a reservoir at either end, and the desired component is enriched in either the reservoir or the withdrawal at the other end. The effects of the unit separation factor (equivalently, the cascade length) and the ratio of the upstreaming flow rate to the withdrawal rate are investigated on separation. The separation performance is evaluated in terms of the material recovery and the operation time efficiency, and is compared with those of the corresponding conventional cascades and another type of nonconventional cascade, the SW (single withdrawal) cascade. It is found that the NFSW cascade is superior to the conventional cascade and comparable in the material recovery with, but advantageous in the operation time efficiency over the SW cascade.Key Words:: Multicomponent isotope separationGas centrifuge cascadeNonstationary cascadeNumerical simulation
Centrifuge
Cite
Citations (8)
A linear turbine cascade experimental apparatus often consists of only a few cascade blades. Advantages to this arrangement are increased from using larger cascade blades and easier optical access. However, fewer cascade blades in the cascade row make it difficult to establish periodic flow conditions between blades. In this study, a 160% pitch passage for cascade experiments with a single blade is designed to satisfy infinite cascade flow conditions without any flow control or tailboards. Fourteen geometric design variables are applied to the design of a 160% pitch passage by using a gradient-based optimization method and a genetic algorithm. Flow structures within a passage designed with a genetic algorithm are closer to the infinite cascade flow conditions than those obtained with a gradient-based method. The results show that infinite cascade flow conditions can be obtained by modifying only the passage walls of the cascade experimental apparatus.
Cite
Citations (2)
Adaptive IIR filters implemented in cascade-form are attractive due to the ease with which their stability may be monitored. Four cascade-form structures are compared for use in adaptive filtering with respect to complexity of implementation, error surface geometry, and adaptation speed. The four structures include a cascade of second order pole/zero sections, a cascade of second order all-pole sections followed by a tapped delay line, and two new structures. The latter pair includes a tapped cascade, which is a cascade of second order all-pole sections whose output is constructed as a weighted combination of signals tapped from the cascade. The second new structure is a modification of the tapped cascade that yields orthogonal signals at the taps of the cascade. It is shown that the tapped cascade provides the best overall performance in the respects noted above.
Cite
Citations (5)
Cite
Citations (25)