chapter 12, Infrared Focal Plane Arrays

In Part III Applications from: Analysis and Evaluation of Sampled Imaging Systems

Author(s): Richard H. Vollmerhausen, Donald A. Reago, Jr., Ronald G. Driggers

Published: 08 March 2010

Chapter DOI: http://dx.doi.org/10.1117/3.853462.ch12

Chapter Page Count: 36 pages

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Frontmatter

Part I Analysis of Sampled Imaging Systems
1. The Sampling Process

2. Fourier Integral Representation of an Optical Image

3. Sampled Imager Response Function

4. Sampled Imager Optimization

5. Interlace and Dither

Part II Evaluating the Performance of Electro-Optical Imagers
6. Quantifying Visual Task Performance

7. Evaluating Imager Resolution

8. Quantifying the Effect of Aliasing on Visual Task Performance

9. Thermal Imager Topics

10. Imagers of Reflected Light

Part III Applications
11. Computer Programs and Application Data

12. Infrared Focal Plane Arrays

13. Appendix

14. Backmatter

15. Supplemental Programs: Thermal and Reflective

Preview

Chapter Contents

12.1 Photon Detector Infrared Focal Plane Arrays
12.1.1 Photon detector basic principles
12.1.2 Readout integrated circuit
12.1.3 Photon detector dark current
12.2 IR FPA Performance Characterization
12.2.1 Responsivity and detectivity background-limit performance
12.2.2 Flux-based signal-to-noise ratio
12.3.1 Indium antimonide (InSb) detectors
12.3.2 Quantum well infrared photoconductor (QWIP) detectors
12.3.3 Mercury cadmium telluride (HgCdTe) detectors
12.4 Uncooled Detectors
12.4.1 Introduction
12.4.2 Signal-to-noise ratio and performance limits
12.4.3 Typical uncooled detectors
References

Excerpt

The purpose of this chapter is to provide an understanding of infrared (IR) detector focal plane arrays (FPAs) and to describe the important parameters that contribute to overall system performance. The emphasis here is on building an intuitive view of how IR FPAs work and less on a detailed treatment of the semiconductor physics of the detector materials. There are many excellent books that treat detector physics and materials in much greater depth. A partial list used in preparing this chapter includes Singh, Henini and Razeghi, and Kinch. Section 12.1 is an overview of the basic principles of photon detector/FPA operation. Section 12.2 describes the development of the background-limited photoconductor (BLIP) and flux-based expressions for signal-to-noise ratio. Section 12.3 summarizes the capabilities, limitations, and typical performance parameters for cooled FPAs. Section 12.4 discusses uncooled (bolometer) FPAs.

12.1 Photon Detector Infrared Focal Plane Arrays

12.1.1 Photon detector basic principles

Figure 12.1 shows an abstracted cross-sectional view of a few pixels of a photon detector IR FPA. This particular detector structure is a double-layer heterojunction (DLHJ) photovoltaic (PV) detector with an n-type absorber region. There are many other detector structures possible, but their general properties are similar. The DLHJ is a widely used structure for HgCdTe FPAs; it is of considerable practical importance and is easy to understand in cross section. The end-to-end signal chain involves a number of steps:

(1) IR radiation (i.e. light) impinges from the top.

(2) The first layer is an antireflection coating that reduces first surface reflection from 20-30% to 2-3%.

(3) The light passes through a transparent but electrically inactive substrate. This detector is “backside” illuminated. Some detectors have no substrate or have the substrate removed.

(4) Photons of sufficient energy to overcome the detector's bandgap are absorbed in the n-type absorber region generating electron-hole pairs.

http://dx.doi.org/10.1117/3.853462.ch12

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