Mixed Electronic and Optical Computing Platforms for Portable Surface Plasmon Resonance Sensors

用于便携式表面等离子共振传感器的混合电子和光学计算平台

基本信息

批准号：
0086947
负责人：
Karl Booksh
金额：
$ 13万
依托单位：
Arizona State University
依托单位国家：
美国
项目类别：
Standard Grant
财政年份：
2000
资助国家：
美国
起止时间：
2000-09-15 至 2002-06-30
项目状态：
已结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=0086947&HistoricalAwards=false
关键词：
Mixed Electronic Optical Computing Platforms

项目摘要

0086947BookshThe environmental sensing goal of this project is to develop and demonstrate new engineering capabilities associated with optical computational methods for improving the design and performance of optical sensors for convenient, user-friendly, and field-portable environmental analyses. Optical computational methods and novel systems integration approaches promise reduction in power requirements for field portable sensors, simplification of electronics and optical train of field portable sensors, optimization of signal collection and processing for field portable sensors, and adaptation to changing calibration models by updating the programmable memory in the sensor controller. Thus, compared to traditional sensors that rely in discrete digitization of optical signals, smaller, lighter, and less power-hungry sensors with superior detection limits are to be developed using these new engineering technologies. The proposed novel optical computational methods will be incorporated in the design and construction of hand held surface plasmon resonance (SPR) sensors for determination of a range of environmental pollutants at superior detection limits and sensitivities. In Phase 1, application of the sensor will be limited to quantitation of polycyclic aromatic hydrocarbons (PAHs) in ground water. PAHs are carcinogenic EPA priority pollutants that largely enter the environment through fuel and oil spills or as a byproduct of incomplete combustion. In Phase 2, this sensor will be expanded to a massively parallel array of SPR sensors designed for multi-analyte detection. The scope of target analytes will be expanded to other (EPA) priority pollutants. One key area of progress to the sensors designed for both Phase 1 and Phase 2, will be the increasing ability of the system to account for environmental changes that affect the SPR spectrum.In Phase 1 of the proposed research, these optical computations will be integrated into a novel, fiber optic, surface plasmon resonance sensor design. The goals of Phase 1 are to demonstrate the improvements in sensitivity, power, space, and signal-to-noise ratio achievable with integrated optical computation in the SPR sensor, to improve system concentration sensitivity in isolated but integrated photodetectors, to demonstrate programmability for ease of calibration and referencing to environmental changes, and to increase greater than 12 hours of battery life capable of determining to +/- 1% PAH concentration down to ppb levels in a changing environment. The fiber optic SPR sensor will have two sensing areas: one responsive to the target analyte and any environmental changes, the other responsive to only environmental changes.

0086947Booksh 该项目的环境传感目标是开发和展示与光学计算方法相关的新工程能力，以改进光学传感器的设计和性能，以实现方便、用户友好和现场便携式环境分析。光学计算方法和新颖的系统集成方法有望降低现场便携式传感器的功率要求，简化现场便携式传感器的电子和光学系列，优化现场便携式传感器的信号收集和处理，并通过更新可编程来适应不断变化的校准模型传感器控制器中的存储器。因此，与依赖于光信号离散数字化的传统传感器相比，使用这些新的工程技术可以开发出更小、更轻、功耗更低、检测限更高的传感器。所提出的新型光学计算方法将被纳入手持式表面等离子共振（SPR）传感器的设计和构造中，以优异的检测限和灵敏度测定一系列环境污染物。在第一阶段，传感器的应用将仅限于地下水中多环芳烃（PAH）的定量。 PAH 是 EPA 优先考虑的致癌污染物，主要通过燃料和石油泄漏或作为不完全燃烧的副产品进入环境。在第二阶段，该传感器将扩展到专为多分析物检测而设计的大规模并行 SPR 传感器阵列。目标分析物的范围将扩大到其他 (EPA) 优先污染物。为第一阶段和第二阶段设计的传感器的一个关键进展领域将是提高系统解释影响 SPR 光谱的环境变化的能力。在拟议研究的第一阶段，这些光学计算将被集成一种新颖的光纤表面等离子体共振传感器设计。第一阶段的目标是展示通过 SPR 传感器中的集成光学计算可实现的灵敏度、功率、空间和信噪比方面的改进，以提高隔离但集成的光电探测器中的系统浓度灵敏度，以轻松演示可编程性校准和参考环境变化，并增加超过 12 小时的电池寿命，能够在变化的环境中确定 +/- 1% 的 PAH 浓度，低至 ppb 水平。光纤 SPR 传感器将具有两个传感区域：一个响应目标分析物和任何环境变化，另一个仅响应环境变化。