Your search keyword '"Jalen Johnson"' showing total 5 results

1. A GaN Switched Tank Converter with Partial Power Voltage Regulation for Electric Vehicle Applications

Author

Xiaofeng Lyu, Mengxuan Wei, Dong Cao, Jalen Johnson, Ze Ni, Chengkun Liu, and Yanchao Li

Subjects

business.product_category, Buck converter, business.industry, Computer science, 020208 electrical & electronic engineering, Electrical engineering, 02 engineering and technology, 021001 nanoscience & nanotechnology, Switched capacitor, Power (physics), law.invention, Capacitor, law, Boost converter, Electric vehicle, 0202 electrical engineering, electronic engineering, information engineering, Voltage regulation, 0210 nano-technology, business, Voltage

Abstract

A new Switched Tank Converter (STC) with Partial Power Voltage Regulation (PPVR) is introduced for electric vehicle applications. It offers a flexibly adjustable conversion ratio for a wide-range battery voltage. The unregulated stage is modularized with resonant switched capacitor converters. All device voltage stresses are equal to the input voltage. The efficient unregulated stage processes the bulk of system power and the less efficient regulated stage processes a small amount of power. Thus, high overall efficiency can be achieved. A new index called Semiconductor Loss Index (SLI) is defined as a function of semiconductor die area to evaluate different power topologies. It is helpful to analyze the impact of each switch die area, different operated output power, switching frequency, and conversion ratio on the total device power loss. With the same total semiconductor die area, the proposed converter can achieve less than 1/3 device total power loss compared with boost converter. A 4-kW 1200V output converter prototype with 200V~400V input voltage range is developed, which combines a 6 times conversion ratio STC with a PPVR buck converter. The overall full-load efficiency of designed 4-kW converter can reach to 97.71%. Simulation, prototype and experiment results are presented to verify the validity of the proposed converter.

Published

2019

2. An Isolated Composite Resonant Multilevel Converter with Partial Power Voltage Regulation for Telecom Application

Author

Xiaofeng Lyu, Yanchao Li, Dong Cao, Ze Ni, and Jalen Johnson

Subjects

Operating point, Computer science, 020208 electrical & electronic engineering, 05 social sciences, 02 engineering and technology, Voltage regulator, Power (physics), Stress (mechanics), 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, 0501 psychology and cognitive sciences, Point (geometry), State (computer science), Voltage regulation, 050107 human factors, Voltage

Abstract

In this paper, an new converter that includes isolated composite resonant multilevel converter (ICRMC) that uses composite converter concept and partial power voltage regulator (PPVR) has been proposed for telecommunication application. The proposed converter can achieve high efficiency at nominal operating point since it takes minimum effort to regulate the output voltage at this point. A comparative study shows that with the proposed two operation modes of ICRMC, the proposed converter has the best capability to maintain lowest total semiconductor power stress among the existing state of the art solutions when the input voltage varies from 36V to 60V. Furthermore, zero current switching (ZCS) can be always achieved on the switching devices in ICRMC under different operating points. A 600W converter has been simulated to validate the theoretical analysis. The estimated peak efficiency can be as high as 97.65%. Fully debugged prototype and experimental results are provided in this paper.

Published

2018

3. Composite Modular Power Delivery Architecture for Next-Gen 48V Data Center Applications

Author

Dong Cao, Chenhao Nan, Jalen Johnson, Yanchao Li, Xiaofeng Lyu, Ze Ni, and Shuai Jiang

Subjects

Computer science, business.industry, Electrical engineering, High voltage, Modular design, Inductor, law.invention, Power (physics), Capacitor, Power rating, law, business, Power density, Voltage

Abstract

This paper presents a smart Composite Modular Power Delivery Architecture (COMPDA). One example for this architecture is applied in DC-DC 48V to 12V data center circuit shown here. COMPDA has many good features, such as voltage clamping for all devices, low total device stress under wide range ratio. It also has good modular characteristics. Each device has the same voltage and current stress. The principle operation is that all modular cells are connected in-series to share input high voltage and in-parallel to pump output high current, which can easily achieve ultra-high power density and high efficiency. Zero current switching (ZCS) can be applied in the proposed converter. A 4X unregulated DC-DC COMPDA with ZCS is studied for data center application. Finally, a GaN based prototype is built and tested to verify the theoretical analysis. The proposed converter can achieve the peak efficiency at 98.55% under ultra-high switching frequency 253 kHz. Furthermore, another GaN based high-density 6X boost COMPDA based prototype is also presented here. The peak efficiency can achieve 98.9% at 4kW power rating.

Published

2018

4. An ultra efficient composite modular power delivery architecture for solar farm and data center

Author

Dong Cao, Chenhao Nan, Shuai Jiang, Xiaofeng Lyu, Jalen Johnson, Ze Ni, and Yanchao Li

Subjects

business.industry, Computer science, 020208 electrical & electronic engineering, 05 social sciences, Electrical engineering, High voltage, 02 engineering and technology, Voltage regulator, Modular design, law.invention, Power (physics), Rectifier, Capacitor, law, 0202 electrical engineering, electronic engineering, information engineering, 0501 psychology and cognitive sciences, business, Low voltage, 050107 human factors, Voltage

Abstract

This paper presents an ultra-efficient composite modular power delivery architecture (COMPDA) that is able to be used for DC-DC, DC-AC, AC-DC, and AC-AC applications. The proposed architecture has very good module structure, the devices in each module have the same voltage and current stress. When it is used for high conversion ratio dc-dc applications, the device voltage stress is the same with the low voltage side, and the device current stress is the same with the low current side. Compared with the buck, flying capacitor multilevel or modular multilevel dc-dc converters, the proposed architecture has much lower total device power or current stress, which means a significant semiconductor chip area reduction. During the operation, the modules are connected in-series to sustain the high voltage and connected in-parallel to pump the high current. By properly design the resonant tank in the COMPDA, all the switching devices could achieve zero current switching or zero voltage switching. A partial power regulator could be integrated in the proposed architecture, where only a minimum amount of power needs to be processed in order to achieve the output voltage fine regulation. By properly control the operation of modules, the COMPDA can also be used as a high boost ratio DC-AC inverter or high step-down ratio AC-DC rectifier while keeping the soft-switching features, which are specially suitable for solar farm and data-center application. When apply the COMPDA to single-phase DC-AC or AC-DC applications, only a minimum amount dc-link capacitor is needed since the needs of energy storage is minimized, and there is no high voltage dc-link requirement anymore. In order to show the benefits of the COMPDA, one special unregulated case derived from the proposed architecture has been used for 48 V–8 V DC-DC data center application, which is also named switched-tank converter. Finally, a GaN based prototype is built and tested to verify the theoretical analysis. The proposed converter can achieve the peak efficiency at 98.55% under switching frequency 253 kHz and power density is ∼750W/inch3.

Published

2018

5. GaN based inverter with high conversion ratio and sinusoidal output for motor drive applications stress analysis

Author

Jalen Johnson, Xiaofeng Lyu, Dong Cao, and Ze Ni

Subjects

Computer science, business.industry, 020208 electrical & electronic engineering, 05 social sciences, Electrical engineering, Topology (electrical circuits), 02 engineering and technology, Electromagnetic interference, Motor drive, Modulation, Boost converter, 0202 electrical engineering, electronic engineering, information engineering, Inverter, 0501 psychology and cognitive sciences, Voltage source, business, 050107 human factors, Voltage

Abstract

This paper discusses a GaN based motor drive topology with a high conversion ratio and sinusoidal output voltage. This inverter topology is based on the z-source inverter and provides many benefits over the traditional three-phase inverter or traditional inverter with a DC-DC boost converter input. The semi-quasi-z-source inverter allows the input voltage source and the load to share a ground so the problem of handling leakage current is eliminated. Thanks to the high conversion ratio with the semi-quasi-z-source topology, a lower input voltage can be used to generate a desired output. The proposed topology can also take advantage of many popular modulation strategies of traditional inverters. The output of this inverter is sinusoidal so it is perfect for motor drive applications. This paper also compares the voltage and current stress of the semi-quasi-z-source inverter against a traditional inverter with a DC-DC boost converter. Simulations for a 10 kW semi-quasi-z-source inverter are also discussed at the end of this paper.

Published

2017