Collaborative: 3D Integrated Imaging Receivers for 10-Gb/s Free Space Optical MIMO

协作：用于 10 Gb/s 自由空间光学 MIMO 的 3D 集成成像接收器

• 批准号: 0824068
• 负责人: Zhaoran Rena Huang
• 金额: $ 24.9万
• 依托单位: Rensselaer Polytechnic Institute
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2008
• 资助国家: 美国
• 起止时间: 2008-09-01 至 2012-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0824068&HistoricalAwards=false
• 关键词: Collaborative; 3D; Integrated; Imaging; Receivers

The objective of this research is to create a new class of power-efficient imaging photoreceivers to reach an aggregated data rate of 50 gigabits per second and beyond for broadband wireless optical communication. The approach is to develop a large array of planar tessellated photodetectors with a rate of 10 gigabits per second per pixel. The array includes diversity selection circuits, which are implemented using an optical multi-input/multi-output configuration.With respect to intellectual merit, this project addresses two well-known challenges in optical wireless communication, channel scintillation and optical beam alignment. The research explores power-efficient InGaAs metal-semiconductor-metal photodetectors that are integrated with silicon integrated circuits for multifunctional operation (decision, amplification, and computing), and the implementation of multi-input/multi-output architectures for signal processing of massive amounts of data. This research is expected to augment the body of knowledge on carrier drift characteristics in the photodetectors at low voltage bias and the physics of complex three-dimensional optoelectronic device structures. This research also explores heterogeneous integration of compound semiconductor device on silicon circuits using three-dimensional wafer bonding for photoreceiver applications.With respect to broader impacts, the research has the potential to benefit a variety of applications, including wireless networks with reduced security vulnerabilities, networks able to transfer high-resolution digital images in the midst of equipment sensitive to electromagnetic interference in healthcare settings; and optical interconnects in large-scale data centers. A cross-university curriculum is addressed, covering multi-disciplinary topics in information theory, system-level design, analog circuits, device physics, fabrication and integration. Various programs are used to recruit students from underrepresented groups. K-12 outreach efforts are coordinated through the Tufts Center for Engineering Educational Outreach.

本研究的目标是创建一种新型的节能成像光接收器，以达到每秒50千兆比特的聚合数据速率，并超过宽带无线光通信。 该方法是开发一个大阵列的平面镶嵌的光电探测器的速度为10千兆比特每秒每像素。 该阵列包括分集选择电路，这是使用光多输入/多输出configuration.With方面的智力价值，该项目解决了两个众所周知的挑战，在光无线通信，信道闪烁和光束对准。 该研究探索了与硅集成电路集成的高能效InGaAs金属-半导体-金属光电探测器，用于多功能操作（决策，放大和计算），以及用于大量数据信号处理的多输入/多输出架构的实现。 这项研究预计将增加在低电压偏置的光电探测器和复杂的三维光电器件结构的物理载流子漂移特性的知识体系。 本研究还探索了使用三维晶片键合在硅电路上异质集成化合物半导体器件以用于光接收器应用。就更广泛的影响而言，本研究有可能使各种应用受益，包括减少安全漏洞的无线网络，能够在医疗保健环境中对电磁干扰敏感的设备中传输高分辨率数字图像的网络;以及大规模数据中心中的光学互连。 一个跨大学的课程是解决，涵盖信息理论，系统级设计，模拟电路，器件物理，制造和集成的多学科课题。 各种方案被用来从代表性不足的群体中招收学生。 K-12外展工作通过塔夫茨工程教育外展中心进行协调。