Signal processing hardware and software applied to the development of a real-time infrared mission simulation test capability

ICIASF '95 Record. International Congress on Instrumentation in Aerospace Simulation Facilities Pub Date : 1995-05-30 DOI:10.1109/ICIASF.1995.519473

R. H. Fugerer, H. Lowry, D. J. Hervig, L. Holt

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引用次数: 4

Abstract

The Arnold Engineering Development Center (AEDC) Scene Generation Test Capability (SCTC) program has completed the development of a laser based Direct Write Scene Generation (DWSG) facility that provides dynamic mission simulation testing for infrared (IR) Focal Plane Arrays (FPAs) and their associated signal processing electronics. The AEDC DWSG Focal Plane Array Test Capability (FPATC) includes lasers operating at 0.514, 1.06, 5.4, or 10.6 /spl mu/m, and Acousto-Optic Deflectors (AODs) which modulate the laser beam position and amplitude. Complex Radio Frequency (RF) electronics control each AOD by providing multi-frequency inputs. These inputs produce a highly accurate and independent multi-beam deflection, or "rake", that is swept across the FPA sensor under test. Each RF amplitude input to an AOD translates into an accurate and independent beam intensity in the rake. Issues such as scene fidelity, sensor frame rates, scenario length, and real-time laser beam position adjustments require RF control electronics that employ the use of advanced analog and digital signal processing techniques and designs. By implementing flexible system architectures in the electronics, the overall capability of the DWSG to adapt to emerging test requirements is greatly enhanced. Presented in this paper is an overview of the signal processing methodology and designs required to handle the DWSG requirement. Further, electronic design techniques that enabled the system to be implemented within program cost constraints will also be presented. These electronic designs include a broad range of disciplines including digital signal processing hardware and software, programmable logic implementations, and advanced techniques for high fidelity RF synthesis, switching, and amplitude control. Techniques for validating electronic performance will also be presented along with data acquired using those techniques.

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信号处理硬件和软件应用于红外任务的实时仿真测试能力的开发

阿诺德工程开发中心(AEDC)场景生成测试能力(SCTC)项目已经完成了基于激光的直写场景生成(DWSG)设备的开发，该设备为红外(IR)焦平面阵列(fpa)及其相关信号处理电子设备提供动态任务模拟测试。AEDC DWSG焦平面阵列测试能力(FPATC)包括工作在0.514,1.06,5.4或10.6 /spl mu/m的激光器，以及调制激光束位置和振幅的声光偏转器(aod)。复杂射频(RF)电子设备通过提供多频率输入来控制每个AOD。这些输入产生一个高度精确和独立的多波束偏转，或“耙”，扫过测试中的FPA传感器。每个输入到AOD的射频振幅转换成rake中精确且独立的波束强度。场景保真度、传感器帧速率、场景长度和实时激光束位置调整等问题需要采用先进的模拟和数字信号处理技术和设计的射频控制电子设备。通过在电子器件中实现灵活的系统架构，DWSG适应新出现的测试需求的整体能力大大增强。本文概述了处理DWSG要求所需的信号处理方法和设计。此外，电子设计技术，使系统能够在程序成本限制内实施也将被提出。这些电子设计包括广泛的学科，包括数字信号处理硬件和软件，可编程逻辑实现，以及高保真射频合成，开关和幅度控制的先进技术。验证电子性能的技术也将与使用这些技术获得的数据一起提出。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ICIASF '95 Record. International Congress on Instrumentation in Aerospace Simulation Facilities

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