4×288 readouts and FPAs properties

• Autorzy: Sizov F. F. , Reva V. P. , Golenkov A. G. , Vasiliev V. V. , Suslyakov A. O.
• Konferencja: Infrared Photodetectors (IPH) ; (30-31.08.2005, Warsaw, Poland)
• Języki publikacji: EN

Abstrakty

EN

Analysis of four types 4×288 designed and manufactured readouts is presented. All the readouts have the direct injection input circuit with the circuits incorporated that allows testing procedure of readouts without the photodiodes attached to readout circuits. TDI registers have three delay elements between neighbouring inputs. Some characteristics of 4×288 FPAs with mercury-cadmium-telluride (MCT) arrays are presented too. Analysis have shown that in spite of different constructions of four readout types, different numbers of outputs and external service, rather similar parameters of FPAs have been obtained. Detectivity values measured for all 4×288 FPAs at operation temperature T ≈ 78 K with skimming mode included and background temperature T_b ≈ 295 K were in the range D*_λ ≅ (1.2–1.7)×10¹¹ cmHz¹/²/W.

Słowa kluczowe

EN

MCT; readouts; FPAs

• Wydawca: Stowarzyszenie Elektryków Polskich ; Polska Akademia Nauk ; Wojskowa Akademia Techniczna im. Jarosława Dąbrowskiego
• Czasopismo: Opto-Electronics Review
• Rocznik: 2006
• Tom: Vol. 14, No. 1
• Strony: 79--86
• Opis fizyczny: Bibliogr. 12 poz., wykr.

Twórcy

autor

Sizov F. F.

autor

Reva V. P.

autor

Golenkov A. G.

autor

Vasiliev V. V.

autor

Suslyakov A. O.

• Institute of Semiconductor Physics, 41 Nauki Ave., 03028 Kiev, Ukraine,

Bibliografia

• 1. A. Rogalski, Infrared Detector, Gordon and Breach Science Publishers, Amsterdam, 2000.
• 2. J.P. Chamonal, E. Mottin, P. Audebert, M. Ravetto, M. Caes, and J.P. Chatard, "Long linear MWIR and LWIR HgCdTe arrays for high-resolution imaging", Proc. SPIE 4130, 452-462 (2000).
• 3. P. Tribolet, P. Chorier, A. Manissadjian, P. Costa, and J.P. Chatard, "High performance infrared detectors at Sofradir", Proc. SPIE 4028, 438-456 (2000).
• 4. H.M. Runciman, "Influence of technology on FLIR waveband selection", Proc. SPIE 2470, 156-167 (1995).
• 5. J.C. Holst, Electro-Optical Imaging System Performance, SPIE Optical Engineering Press, Bellingham, 2003.
• 6. A.B. Utenkov, Y.I. Belousov, and A.L. Smirnov, "Influence of matrix detector filling coefficient on the quality of thermovision image", Optical Journal 68, 75-80 (2001). (in Russian).
• 7. F.F. Sizov, Y.P. Derkach, V.P. Reva., and Y.G. Kononenko, "MCT sensor readout devices with charge current injection and preliminary signal treatment", Opto-Electron. Rev. 7, 327-338 (1999).
• 8. L.J. Kozlowski, K. Vural, W.E. Tennant, W.E. Kleinhaus, and I.S. Gergis, "Progress toward high-performance infrared imaging systems-on-a-chip", Proc. SPIE 4130, 245-253 (2000).
• 9. L.J. Kozlowski and W.F. Kosonocky, "Infrared detector arrays", in Handbook of Optics, edited by M. Boss, W. Van Stryland, D.R. Williams, and W.L. Wolfe, McGraw-Hill, New York, 1995.
• 10. F.F. Sizov, Y.P. Derkach, S.A. Dvoretski, A.G. Golenkov, J.V. Gumenyuk-Sichevska, V.P. Reva, V.N. Ovsyuk, Yu.G. Sidorov, N.Kh. Talipov, V.V. Vasiliev, and V.V. Zabudsky, "MCT linear arrays and associated silicon readouts", Proc. SPIE 5251, 16-25 (2004).
• 11. E.L. Dereniak and G.D. Boreman, Infrared Detectors and Systems. Wiley-Interscience N.Y., 1996.
• 12. SOFRADIR data sheet, 2000.