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    130nm DC-DC SEPIC Design and ,Analysis for Energy Harvesting Applications
    (IEEE, 2020) Guzeltepe, Ismail; Vural, Revna Acar; Batur, Okan Zafer
    SEPIC converters, which are becoming widespread in several areas, including renewable energy; are often preferred due to non-inverted output, non-excessive switch stress and considerably less input current ripple. However, there are not enough studies in the literature on the use of the SEPIC converters in ultra-low voltage applications. In this study; It is aimed to design the effective use of DC-DC SEPIC converters consisting of integrated active components for very low voltage energy harvesting applications. In this context; using UMC 130nm technology; A DC-DC SEPIC converter, capable of providing a constant IV output with an input voltage range of 150mV-1.6V and offering an output power range of 1.3-7.7mW with 80% efficiency, has been designed and analyzed.
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    High accuracy potentiostat with wide dynamic range and linearity
    (Elsevier Gmbh, 2021) Toprak, Serdar; Vural, Revna Acar; Batur, Okan Zafer
    Electrochemical measurement require potentiostat to ensure the operational stability during the sensing and conversion of the sensor signals. This article presents a potentiostat circuit with high linearity and accuracy bidirectional current readout circuit for a wide dynamic current range. A current conveyor circuit with a wide current range from +/- 50 nA to +/- 400 mu A is constructed by combining a low-noise current mirror based OTA and a regulated current mirror employing accurate and linear output characteristics. The potentiostat is designed in 0.18 mu m TSMC technology with +/- 0.9 V nominal power supply, and the results obtained are based on simulation and performed with Cadence (TM) tools. The potentiostat circuit achieves a minimum detectable current of 1 nA within current range of +/- 400 mu A. The detectable current range is 112 dB with R-2 linearity of 0.999999993 and maximum error of 1.3%. The input referred noise of the current conveyor is 24.48 fA/root Hz@1 kHz, and integrated referred noise is 0.912 pA within 0.01 Hz - 1 kHz bandwidth. The static power consumption of the potentiostat circuit is 1.993 mW. The control amplifier and the current readout circuit consume 1.98 mW and 13 mu W, respectively. The proposed circuit is capable of providing low noise and high accuracy current measurement with low power consumption and highly linear output characteristics.