D
Doron Shmilovitz
Researcher at Tel Aviv University
Publications - 134
Citations - 2450
Doron Shmilovitz is an academic researcher from Tel Aviv University. The author has contributed to research in topics: Switched-mode power supply & Topology (electrical circuits). The author has an hindex of 23, co-authored 130 publications receiving 2183 citations. Previous affiliations of Doron Shmilovitz include National Sun Yat-sen University.
Papers
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On the control of photovoltaic maximum power point tracker via output parameters
TL;DR: In this article, the maximum power point tracker output voltage and current are used for control purposes, rather than for its input voltage or current, and it is shown that using the output parameters simplifies the MPPT controller.
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Ultrasonic transcutaneous energy transfer for powering implanted devices
Shaul Ozeri,Doron Shmilovitz +1 more
TL;DR: This paper investigates ultrasonic transcutaneous energy transfer as a method for energizing implanted devices at power level up to a few 100 mW by proposing a continuous wave 673 kHz single frequency operation to power devices implanted up to 40 mm deep subcutaneously.
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On the definition of total harmonic distortion and its effect on measurement interpretation
TL;DR: In this article, it is suggested that total harmonic distortion measurements in the context of power systems should always adopt the first definition and never the second definition and the difference between those definitions is stressed out in this letter.
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Maximum Power Point Tracking Employing Sliding Mode Control
Yoash Levron,Doron Shmilovitz +1 more
TL;DR: A fast and unconditionally stable maximum power point tracking scheme with high tracking efficiency and all range stability is proposed for photovoltaic generators and a typical convergence time of 15 ms is shown.
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Ultrasonic transcutaneous energy transfer using a continuous wave 650 kHz Gaussian shaded transmitter.
TL;DR: Pressure and power transfer measurements within a test tank further confirm the effectiveness of the proposed UTET, which showed a peak power transfer efficiency of 39.1% at a power level of 100 mW.