Your search keyword '"Large signal equivalent circuit model"' showing total 6 results

1. Improved and Reduced-Order I/O Devices Behavioral Modeling Solutions for SI Simulation

Author

Dghais, Wael, Kacprzyk, Janusz, Series editor, Alam, Muhammad, editor, Dghais, Wael, editor, and Chen, Yuanfang, editor

Published

2018

2. A compact D-band monolithic APDP-based sub-harmonic mixer.

Author

Zhang, Shengzhou, Sun, Lingling, Wang, Xiang, Wen, Jincai, and Liu, Jun

Subjects

*REACTION mechanisms (Chemistry), *INTERMEDIATES (Chemistry), *COUPLING reactions (Chemistry)

Abstract

The paper presents a compact D-band monolithic sub-harmonic mixer (SHM) with 3 μm planar hyperabrupt schottky-varactor diodes offered by 70 nm GaAs mHEMT technology. According to empirical equivalent-circuit models, a wide-band large signal equivalent circuit model of the diode is proposed. Based on the extracted model, the mixer is implemented and optimized with a shunt-mounted anti-parallel diode pair (APDP) to fulfill the sub-harmonic mixing mechanism. Furthermore, a modified asymmetric three-transmission-line coupler is devised to achieve high-level coupling and minimize the chip size. The measured results show that the conversion gain varies between −13.9 dB and −17.5 dB from 110 GHz to 145 GHz, with a local oscillator (LO) power level of 14 dBm and an intermediate frequency (IF) of 1 GHz. The total chip size including probe GSG pads is 0.57 × 0.68mm 2 . In conclusion, the mixer exhibits outstanding figure-of-merits. [ABSTRACT FROM AUTHOR]

Published

2017

3. Using electrical analogy to describe mass and charge transport in lithium-ion batteries

Author

Raël, S. and Hinaje, M.

Subjects

*LITHIUM-ion batteries, *MASS transfer, *CHARGE transfer, *DIFFUSION, *ELECTROLYTES, *COMPUTER software, *SIMULATION methods & models, *FINITE element method

Abstract

Abstract: This article deals with an electrical model of lithium-ion battery, based on a 1D analog representation of mass and charge transport phenomena. By using an electrical analogy to describe migration and diffusion of species and charges in electrodes and electrolyte, the model can be directly implemented in standard simulation software used in electrical engineering (such as Saber, in our case), so that it can be easily employed for the simulation of electrical systems involving lithium-ion batteries. The paper explains how the analog model is obtained from mass and charge transport equations, then it presents a comparison with results obtained by means of a finite element method. At last, some electrical power systems are simulated in order to show advantages of our modeling method. [Copyright &y& Elsevier]

Published

2013

4. Using electrical analogy to describe mass and charge transport in PEM fuel cell

Author

Noiying, P., Hinaje, M., Thounthong, P., Raël, S., and Davat, B.

Subjects

*PROTON exchange membrane fuel cells, *CHARGE transfer, *MASS transfer, *ELECTRIC power production, *DIFFUSION, *ELECTRIC potential, *MATHEMATICAL models, *UNSTEADY flow

Abstract

Abstract: This article deals with a PEMFC (proton exchange membrane fuel cell) electrical model based on a 1D analog representation of mass transport phenomena, and taking into account the influence of gas supply conditions on fuel cell voltage. By using an electrical analogy to describe transport of gaseous species in GDLs (gas diffusion layers), and water distribution in the membrane, the model can be directly implemented in standard simulation softwares used in electrical engineering (such as Saber, in our case), so that it can be easily employed for the simulation of fuel cell electrical systems. The paper explains how the analog model is obtained from mass transport equations, then it presents validation tests carried out in both steady-state and transient regimes on a PEM single cell bench. [Copyright &y& Elsevier]

Published

2012

5. Design, Fabrication and Operation of a Very High Intensity CMUT Transmit Array for Beam Steering Applications

Author

Khan, Talha Masood and Köymen, Hayrettin

Subjects

CMUT, Array, Airborne ultrasound, Large signal equivalent circuit model, High Intensity, Half frequency driven, Lumped element model, MEMS, Transducer array, Beam steering, Capacitive micromachined ultrasonic transducers, Unbiased operation, Microfabrication, Mutual radiation impedance

Abstract

Cataloged from PDF version of article. Thesis (Ph.D.): Bilkent University, Department of Materials Science and Nanotechnology, İhsan Doğramacı Bilkent University, 2020. Includes bibliographical references (leaves 61-69) Several studies have reported airborne ultrasound transmission systems focused on achieving beamforming. However, beam steering and beamforming for capacitive micromachined ultrasonic transducers (CMUTs) at high intensity remains to be accomplished. CMUTs, like other ultrasonic transducers, incorporate a loss mechanism to obtain a wide bandwidth. They are restricted to a limited amount of plate swing due to the gap between the radiating plate and the bottom electrode, along with a high dc bias operation. CMUTs can be designed to produce high-intensity ultrasound by employing an unbiased operation. This mode of operation allows the plate to swing the entire gap without collapsing, thus enabling higher intensity. In this study, we use an equivalent circuit-based model to design unbiased CMUT arrays driven at half the mechanical frequency. This model is cross verified using finite element analysis (FEA). CMUT arrays are produced in multiple configurations using a customized microfabrication process that involves anodic wafer bonding, a single lithographic mask, and a shadow mask. We use impedance measurements to characterize the microfabricated devices. We experimentally obtained the highest reported intensity using a microfabricated 2×2 CMUT array driven at resonance in a pulsed configuration. This array is also capable of beam steering and beamforming at a high intensity such that it can steer the entire half-space. The beam obtained from the array is in excellent agreement with the theoretical predictions. The amplitude and phase compensation for the devices remain constant that makes these arrays attractive for applications involving park assist, gesture recognition, and tactile displays. by Talha Masood Khan Ph.D.

Published

2020

6. Beslemesiz ve yarı frekansta sürülen sualtı 16x16-elemanlı 2-B fazlı dizin CMUT

Author

Enhoş, Kerem and Köymen, Hayrettin

Subjects

Waterborne, MEMS, CMUT, Volumetric transmission, Array, Capacitive micromachined ultrasonic transducers, Unbiased operation, Large signal equivalent circuit model, Half frequency driven, Mutual radiation impedance

Abstract

Cataloged from PDF version of article. Thesis (M.S.): Bilkent University, Department of Electrical and Electronics Engineering, İhsan Doğramacı Bilkent University, 2019. Includes bibliographical references (leaves 116-123). Capacitive micromachined ultrasonic transducers (CMUT) are typically used as arrays consisting of separate cells or interconnected sub arrays, and these cells have several operation modes. Design procedure and measurements have been previously presented for an airborne CMUT cell without a DC bias. In unbiased mode, the plate motion spans the entire gap without collapsing. The frequency of sinusoidal electrical input signal is half of the resulting acoustical output signal. A large plate swing can be obtained at low excitation voltages using the entire remaining gap. In this work, a design procedure of arrays with unbiased operation mode is derived. Designs are validated by means of simulations and measurements on fabricated CMUTs. The problems associated with beamforming are resolved. Use of this operation mode in an array configuration enables larger acoustical power output. A better transmitted signal waveform definition is obtained when pulse width modulation (PWM) is employed. In the design process of CMUTs, large-signal equivalent circuit model is used. In order to have volumetric transmission, a 16×16 (256 elements) phased array configuration is chosen. A design procedure is presented considering the radiation pattern, Rayleigh distance and the parameters of the lumped-element model. This procedure is applied for designing two arrays, with resonance frequencies at 7.5 MHz and at 18.5 MHz. Harmonic balance and transient analyses are carried out with Gaussian enveloped tone burst, transient sinusoidal and PWM signals with different duty cycles. Outputs of these simulations are fed in beamforming toolboxes for further verification. Corresponding experimental measurements are conducted on an ultrasound measurement system. The dimensions of the CMUT elements in the array are determined as 80 μm element radius, 15 μm plate thickness, and 171 nm effective gap height at 7.5 MHz, where the center-to-center inter-element pitch is set at 192 μm. The array is designed such that it has maximum Rayleigh distance of 45.3 mm, while having a maximum sidelobe level of −17.4 dB. According to these specifications, CMUT array is manufactured using wafer scale batch compatible production. Only two lithography masks, which require conventional photolithography steps, are used in production. The vibrating plate is constructed with anodic wafer bonding and the fabricated CMUT array chip is integrated to PCB with flip-chip bonding. Measurements are conducted for this novel device by integrating the CMUT array chip manufactured with MEMS techniques and conventional macro scale manufactured PCB by using impedance analyser. by Kerem Enhoş M.S.

Published

2019