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1. Two-Stage 48V-1V Hybrid Switched-Capacitor Point-of-Load Converter with 24V Intermediate Bus

   https://doi.org/10.1109/COMPEL49091.2020.9265715  

   Chen, Yenan; Giuliano, David M.; Chen, Minjie (November 2020, 2020 IEEE 21st Workshop on Control and Modeling for Power Electronics)

   null (Ed.)

   This paper presents a 90.6% 48 V-1 V/150 A two-stage hybrid switched-capacitor point-of-load (PoL) converter with a 24 V intermediate bus. The first stage of the converter is a 2:1 resonant charge pump which converts the 48 V input voltage to 24 V. The second stage of the converter is a 24:1 four-phase series capacitor buck converter which is capable of delivering 150 A with two customized four-phase coupled inductor for vertical power delivery. The two-stage architecture combines the resonant switched-capacitor structure and the series capacitor buck configuration to achieve high efficiency, high power density, and voltage regulation. The effectiveness of the topology is verified by a 48 V-1 V/150 A prototype with a peak efficiency of 90.6% at 60 A and a full load efficiency of 86.2% at 150 A. The power density of the prototype is 283 W/in 3 . 

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2. Multiphase Control for Robust and Complete Soft-charging Operation of Dual Inductor Hybrid Converter

   Xie, Tianshi; Das, Ratul; Seo, Gab-Su; Maksimovic, Dragan; and Le, Hanh-Phuc (March 2019, 2019 IEEE Applied Power Electronics Conference and Exposition (APEC))

   This paper presents a new Multiphase Dual Inductor Hybrid (MP-DIH) Converter for application in data center and telecommunication systems. The converter is based on addition of two output filter inductors to a Dickson switched-capacitor converter. The inductors are operated in multiple phases that are non-overlapped and evenly distributed over one switching cycle, completely soft-charging all flying capacitors even in the presence of practical capacitor mismatches and voltage ripples. In this converter operation, each branch of the switched-capacitor network is activated individually in one charging phase, and two interleaved inductors are employed to softly charge and discharge the capacitors to achieve high efficiency without any complex capacitor sizing or split phase operation. To verify the topology and its soft-charging advantages, a 48V-to-1.8V 20W experimental converter prototype is constructed. The converter achieves 92.4% peak efficiency for 40V-to-1.8V conversion and 92.1% peak efficiency for 48V-to-1.8V conversion at 4A load, and with 20% capacitance variations. 

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3. Low-Ripple High-Voltage DC Generation Using a Serially Segmented Multiphase Voltage Multiplier

   https://doi.org/10.1109/ECCE44975.2020.9235707  

   Park, Sanghyeon; Rivas-Davila, Juan (October 2020, 2020 IEEE Energy Conversion Congress and Exposition (ECCE))

   null (Ed.)

   This paper presents a voltage multiplier topology that is suitable for a low-ripple high-voltage dc generation. The topology has a number of voltage multipliers connected in series and driven at different phases. Compared to a single-phase multiplier, an n-phase voltage multiplier has an output ripple that is smaller by n times. Since the ripple frequency is simultaneously increased by n times, a simple RC lowpass filter further reduces the ripple amplitude by n times, resulting in ripple reduction of n^2 times. We demonstrate the ripple reduction of the proposed topology using a 6 V-to-800 V power supply with a 16-stage four-phase bipolar voltage multiplier. The output ripple frequency is eight times the converter's switching frequency and the ripple amplitude is significantly smaller than the conventional single-phase voltage multiplier. 

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4. A Comprehensive Analysis of Charge-Pump-Based Multi-Stage Multi-Output DC-DC Converters

   https://doi.org/10.1109/ISCAS51556.2021.9401129  

   Danesh, Ahmad Reza; Heydari, Payam (May 2021, IEEE International Symposium on Circuits and Systems)

   null (Ed.)

   This paper presents an analytical model for calculating the output voltage and the power efficiency of multi-stage multi-output (MSMO) DC-DC converters (DDC) that use charge pump cells for boosting the voltage. Various cases such as multi-output current consumption and its effects on the output voltage and the power efficiency are studied. Based on the model, a tapered design approach is proposed that can bolster the power efficiency and lower the output voltage drop of MSMO DDCs. Moreover, a charge-pump-based DDC is introduced and designed to verify the proposed model. Simulation results using a standard high-voltage 180-nm CMOS technology affirms the accuracy of the presented model. 

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5. Analysis of Dual-Inductor Hybrid Converters for Extreme Conversion Ratios

   https://doi.org/10.1109/JESTPE.2020.2985116  

   Das, Ratul; Seo, Gab-Su; Le, Hanh-Phuc (June 2020, IEEE Journal of Emerging and Selected Topics in Power Electronics)

   This paper presents a dual-inductor hybrid (DIH) converter that is capable of efficient non-isolated DC-DC con- versions with extremely large voltage conversion ratios. The converter topology combines a switched-capacitor network and two interleaved inductors, that supports simple duty-cycle control for output regulation. In order to achieve complete soft charging for all flying capacitors, a method to optimally size the capacitors has been proposed and verified. A detailed analysis on the two inductor currents revealing a new and simple method to modulate them and its impacts on output regulation and efficiency are also provided and demonstrated in experiments. Employing the converter topology and design methods, a DIH converter prototype is implemented and measured for a wide range of operating voltages, providing a 1V-2V output from a 48-V input and a 1V-5V output from a 150V input with output currents up to 20A. The converter achieves 94.3% peak efficiency at 48V- to-2V/7A conversion and 93.7% at 150V-to-5V/18A conversion. 

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