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Applied Optics

Applied Optics


  • Vol. 34, Iss. 21 — Jul. 20, 1995
  • pp: 4437–4452

Signal linearity, gain stability, and gating in photomultipliers: application to differential absorption lidars

Michael P. Bristow, Donald H. Bundy, and Anthony G. Wright  »View Author Affiliations

Applied Optics, Vol. 34, Issue 21, pp. 4437-4452 (1995)

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We present the results of a study that identifies a photomultiplier tube (PMT), divider networks, and gating circuitry for use in the current detection mode, in which the specific objectives were to hold variations in both signal gain over a 25-μs gate period and signal linearity up to 20 mA to less than ±0.1%. The study, aimed at optimizing the performance in a nadir-looking airborne UV differential absorption lidar, is sufficiently general to apply to other critical gated or pulsed PMT applications in which performance at the 0.1% level is required. Signal-induced gain increases peculiar to pulsed or gated signals from PMT’s with BeCu dynodes that can have values between 1 and 10% over 25 μs were reduced to less than 0.1% by the use of a 2-in. (5.08-cm)-diameter PMT (EMI 9214) with CsSb dynodes. Compliance with the linearity requirement was achieved for gated signals up to 8 mA at a current gain of ~107 with the EMI 9214 PMT controlled by a resistive divider network with an inverted taper, in which the linearity data showed no tendency toward overlinearity caused by either space charge effects or induced divider-network voltage changes.

© 1995 Optical Society of America

Original Manuscript: August 22, 1994
Revised Manuscript: February 1, 1995
Published: July 20, 1995

Michael P. Bristow, Donald H. Bundy, and Anthony G. Wright, "Signal linearity, gain stability, and gating in photomultipliers: application to differential absorption lidars," Appl. Opt. 34, 4437-4452 (1995)

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