A simple and versatile low-characteristic-impedance lumped-element resonator design based on a superconducting coplanar waveguide strip shunted with a parallel-plate capacitor, enabling tailored impedance and frequency in the sub-gigahertz regime while maintaining a small footprint.
Increasing the number of turns on a single coil electric guitar pickup decreases the resonant frequency exponentially and increases the magnitude of the impedance peak linearly. Using thicker wire (42 AWG) results in higher resonant frequencies and higher impedance magnitudes compared to thinner wire (44 AWG) for the same number of turns.
The energy efficiency of supercapacitors is highly dependent on their operating voltage ranges, with efficiency increasing as the minimum voltage is raised and the maximum voltage is maintained at the device's maximum rating.
This paper presents a novel circuit design that can detect, limit the current, and execute self-power cycling to recover from Single Event Latchup (SEL) in CMOS ICs used in spacecraft systems.
Contingency analysis can provide valuable insights to enhance the reliability and resilience of nuclear power plant electrical systems by identifying potential vulnerabilities and enabling the development of effective Remedial Action Schemes.
The optimal cable layout for the offshore wind farm electrical collector system should balance economic efficiency and reliability, considering post-fault network reconfiguration strategies to enhance system resilience.
Capacitance-based sensors offer a promising method for accurate propellant mass gauging in microgravity environments, overcoming the limitations of conventional techniques. The design of the sensor electrodes is critical to optimize performance in terms of sensitivity distribution, dynamic range, and signal-to-noise ratio.
This paper proposes a novel set of quantitative resilience metrics to assess the operational resilience of DC microgrids in naval applications in real-time.
This work presents the design and implementation of low-loss and broadband chip-to-package transitions for mm-Wave and sub-THz communication systems, addressing the challenges of high-frequency signal transitions between integrated circuits and packaging.
A robust stochastic optimization (RSO) based optimal power flow (OPF) control method is proposed for three-phase, four-wire low-voltage distribution networks to effectively manage uncertainties and optimize performance.