本文为美国加利福尼亚大学（作者：Eric Francis Mannarino）的硕士论文，共49页。

由于成本下降，可再生能源系统的使用正在世界范围内扩大。这些系统需要将直流电源转换为电网同步的交流电源。目前，实现这项任务的逆变器是用分立晶体管设计制造的。TowerJazz半导体公司（TowerJazz Semiconductor Corp.）创造了一种商业化的CMOS工艺，可以阻断高达700伏的电压，有效地消除了将功率逆变器集成到单个芯片上的障碍。本文使用两种拓扑来研究这个过程。第一种是基于单元的开关电容拓扑，首先由Ke Zou提出。第二种是一种新颖的拓扑结构，探索了使用总线作为输入输出系统的优势，就像在数字电路中一样。在这两种拓扑上运行的仿真结果证实了邹的方法所证明的高效性，以及基于总线的系统在输出电压水平上的优势。

Due to their falling costs, the use of renewable energy systems is expanding around the world. These systems require the conversion of DC power into grid-synchronous AC power. Currently, the inverters that carry out this task are built using discrete transistors. TowerJazz Semiconductor Corp. has created a commercial CMOS process that allows for blocking voltages of up to 700 V, effectively removing the barrier to integrating power inverters onto a single chip. This thesis explores this process using two topologies. The first is a cell-based switched-capacitor topology first presented by Ke Zou. The second is a novel topology that explores the advantage of using a bused input-output system, as in digital electronics. Simulations run on both topologies confirm the high-efficiency demonstrated in Zou’s process as well as the advantage the bus-based system has in output voltage levels.

1.  引言

1.1      可再生能源分配的集成

1.2      电流变换的拓扑结构

1.3      多电平开关电容的DC/AC变换器

1.4      控制方法

2.  CMOS集成

2.1      TS18UHV工艺

2.2      半单元逆变器在TS18UHV工艺中的实现

3.  总线开关电容逆变器

3.1      操作

3.2      仿真设置

3.3      仿真结果

4.  结论

4.1      结果

4.2      未来展望

附录A激励文件

附录B仿真输出图形

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