Request PDF | Design of on‐chip resonator using distributed capacitors in 0.13‐μm (Bi)‐CMOS technology | A novel methodology for on‐chip resonator design using
AI Customer ServiceIn a system of distributed on-chip decoupling capacitors, each de- coupling capacitor is sized based on the impedance of the intercon- nect segment connecting the capacitor to the current
AI Customer ServiceCapacitor placement decreases network losses, which is in line with the government policy for enhancing the efficiency of distribution systems. In addition to the
AI Customer ServiceThus, this article reveals the influence of integrating distributed decoupling capacitors in power modules on current sharing mechanism. The key parameters for dynamic and static current
AI Customer ServiceIn a system of distributed on-chip decoupling capacitors, each de- coupling capacitor is sized based on the impedance of the intercon- nect segment connecting the capacitor to the current
AI Customer ServiceThus, the optimization of the location and capacity of distributed generation resources and capacitors with the aim of reducing power losses and reducing line congestion in the radia
AI Customer ServiceThis paper proposes a two-stage procedure to enhance the distribution system performance by determining the optimal sizes and locations of distributed generations (DGs)
AI Customer ServiceThus, the optimization of the location and capacity of distributed generation resources and capacitors with the aim of reducing power losses and reducing line congestion in the radia
AI Customer ServiceIn this paper, a new methodology for the optimal investment in distributed generation is presented, based on an optimal allocation of combined DG and capacitor units to
AI Customer ServiceIn order to implement distributed control of an electric power distribution system, typically a feeder is first partitioned into control areas. In this work, an analytical partitioning
AI Customer ServiceA capacitor with a molded frame structure that reduces audible noise, reduces the mounting area for the same capacitance when using a stacked structure, and is more resistant to cracking caused by PCB bending.
AI Customer ServiceThis paper proposes a methodology to design and optimize the footprint of miniaturized 3-dB branch-line hybrid couplers, which consists of high-impedance transmission lines and distributed capacitors. To minimize the
AI Customer ServiceDOI: 10.1109/IAS.2002.1042675 Corpus ID: 16897430; Improved distributed model for capacitors in high-performance packages @article{Sullivan2002ImprovedDM, title={Improved distributed
AI Customer ServiceAs described in Sect.13.2, a system of distributed on-chip decoupling capacitors is an efficient solution for providing the required on-chip decoupling capacitance based on the maximum
AI Customer Servicethe required values for distributed capacitors under the con-dition that they are distributed with a constant increment '' on a conductor loop. C. Load Dependence The properties of a coil
AI Customer ServiceDistributed capacitors: In some cases, capacitors can be distributed along the distribution line to address localized power factor issues and reduce voltage drops. This
AI Customer ServiceIn order to implement distributed control of an electric power distribution system, typically a feeder is first partitioned into control areas. In this work, an analytical partitioning
AI Customer ServiceIn this paper, novel and efficient analytical closed-form expressions are proposed for the optimal allocation of multiple capacitors in distribution systems to maximize the total
AI Customer ServiceA capacitor with a molded frame structure that reduces audible noise, reduces the mounting area for the same capacitance when using a stacked structure, and is more resistant to cracking
AI Customer ServiceThe multiplier consists of stage capacitor bank, rectifiers for rectification, protective components, and shielding guards. It is housed in a grounded tank in 6 kg/cm 2 N 2
AI Customer ServiceThe system of distributed on-chip decoupling capacitors should therefore be carefully designed. Since the distributed on-chip decoupling capacitor network is strongly
AI Customer ServiceThis paper proposes a two-stage procedure to enhance the distribution system performance by determining the optimal sizes and locations of distributed generations (DGs)
AI Customer ServiceInternal and External Actions on Distributed Mass Frame 8 2. Free-Body Diagrams from Distributed Mass Frame 8 3. Deformations and Forces for Typical Member . 8 4. Model to
AI Customer ServiceThis paper proposes and develops a new distributed slack bus (DSB) model, in the sequence-components frame, for power-flow analysis of an islanded active distribution
AI Customer ServiceThis paper proposes a novel approach to determine an optimal location and sizing of shunt capacitors for reactive power compensation in distribution systems with
AI Customer ServiceA capacitor with a molded frame structure that reduces audible noise, reduces the mounting area for the same capacitance when using a stacked structure, and is more resistant to cracking caused by PCB bending. This is Samsung Electro-Mechanics MLCC MFC Introduction Page.
Capacitors have been considered as crucial components in distribution systems. Capacitors, when they are optimally allocated, reduce power losses, correct the power factor, improve the voltage profile, and release system capacity [ 1, 2, 3, 4 ].
Capacitors, when they are optimally allocated, reduce power losses, correct the power factor, improve the voltage profile, and release system capacity [ 1, 2, 3, 4 ]. These units also supply reactive powers locally at their connection points, and so, they strengthen the system against reactive power shortages [ 5, 6 ].
The proposed method is based on efficient analytical closed-form expressions which requires the power flow results only for the base case for solving the allocation problem. Two analytical expressions are driven for the optimal capacitor sizing and the selection of the optimal combination of locations.
However, if two capacitors are installed at buses 2 and 4 (Fig. 1 b), the reactive power flow through some lines will be influenced by their reactive power injections. This injected reactive power for each capacitor will affect only the power flow through its upstream lines.
It is a fact that allocating several capacitors at improper locations with erroneous sizes could worsen the performance of distribution systems. Indeed, the problem of capacitor allocation means determining the best combination of locations for installing capacitors with their optimal capacities so that their benefits are maximized.
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