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El. knyga: Fundamentals of Radiation Thermometers

(National Physical Laboratory, UK), (Formerly of the National Physical Laboratory, UK)
  • Formatas: 262 pages
  • Išleidimo metai: 03-Nov-2016
  • Leidėjas: CRC Press Inc
  • Kalba: eng
  • ISBN-13: 9781498778220
Kitos knygos pagal šią temą:
Fundamentals of Radiation ThermometersDidesnis paveikslėlis
  • Formatas: 262 pages
  • Išleidimo metai: 03-Nov-2016
  • Leidėjas: CRC Press Inc
  • Kalba: eng
  • ISBN-13: 9781498778220
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Authored by two highly respected experts in this specialist area, The Fundamentals of Radiation Thermometers is an essential resource for anyone intending to measure the temperature of an object using the radiated energy from that object. This readable, user-friendly book gives important background knowledge for anyone working in the field of non-contact thermometry.

The book begins with an accessible account of how temperature scales are set up and defined, and explores the historic development of temperature scales and Plancks radiation law. Through explaining the reliability of both emissivity values and extrapolation to different wavelengths and temperatures, the book provides a foundation for understanding when a valid measurement with realistic uncertainties has been made, or if an inappropriate emissivity value has been used with consequent unknown errors.



The book also presents the hardware of radiation thermometers, allowing the reader to specify an appropriate design for a particular measurement problem. It explores multi-wavelength radiation thermometry and its associated pitfalls, and a final chapter suggests strategies to minimise the uncertainties from unreliable emissivity data.

Recenzijos

"The Fundamentals of Radiation Thermometers starts by giving a thorough introduction to the basics of thermometry and the fundamental thermal radiation laws, providing clear explanations that will be useful for any undergraduate studying thermodynamics. Having established a solid set of foundations, the book then describes what is needed to make world-leading temperature measurements, providing design considerations when building radiation thermometers and reminding the reader of techniques that will help to attain optimum performance. Clearly written and meticulous, this book provides a wealth of information that can be utilised by any radiation thermometrist - from new scientists taking their first steps in this field to those with more experience. This is a great book that I wish had been available when I first started!" Martin Dury, National Physical Laboratory

"Coates and Lowe aim to provide a firm theoretical background for radiation thermometry and radiation thermometer design and they manage to perform this task successfully and to a very high standard. Diverse areas of physics and engineering are pulled together cohesively, in addition to the authors own contributions which are specific to radiation thermometry. Assembling this information would otherwise be a huge task even for the most experienced of radiation thermometer users, designers or researchers to do themselves. Providing a theoretical basis for radiation thermometers and thermometry, this book explores the link between the local measurements and traceability back to the SI in addition to a survey of the techniques for reducing measurement uncertainty and dealing with the variety of challenges found when using these devices to make measurements outside the controlled conditions of a lab. This text will be of great use to many professionals and academics. In particular, workers at the National Measurement Institutes will find this book provides suf

List of Figures
xi
List of Tables
xv
Foreword xvii
Preface xix
Authors xxi
Chapter 1 The quantity `temperature'
1(18)
1.1 Introduction
1(1)
1.2 The Concept Of A Scale
1(2)
1.3 Thermometry -- The Measurement Of Temperature
3(2)
1.4 Thermodynamic Temperature
5(2)
1.5 International Temperature Scales
7(7)
1.5.1 The origin of internationally agreed scales
7(4)
1.5.2 Wire scales
11(1)
1.5.3 The International Temperature Scale of 1990, ITS-90
11(3)
1.6 The Definition Of Temperature Units
14(1)
1.7 The Mise En Pratique Of The Definition Of The Kelvin
15(4)
Chapter 2 Fundamental laws
19(32)
2.1 Introduction
19(1)
2.2 The Concept Of A Black-Body Radiator
20(8)
2.2.1 The radiation quantities
23(1)
2.2.2 Properties of the cavity radiation field
24(4)
2.3 The Stefan-Boltzmann Law
28(1)
2.4 The Development Of Planck's Law
29(9)
2.4.1 Boltzmann statistics
33(2)
2.4.2 Quantum Statistics
35(3)
2.5 Einstein's Derivation Of Planck's Law
38(3)
2.6 The Modern Theory Of The Radiation Field
41(2)
2.7 Zero-Point Fluctuations Of The Radiation Field
43(1)
2.8 Deviations From Planck's Law
44(1)
2.9 Coherence Properties Of Thermal Radiation
45(1)
2.10 Spectral Radiance
46(5)
Chapter 3 Characteristics of surfaces
51(24)
3.1 General Characteristics Of Surfaces
51(8)
3.1.1 Definition of optical properties
52(4)
3.1.2 Kirchhoff's law
56(3)
3.2 Calculated Emissivity Values
59(12)
3.2.1 Equations for strongly absorbing materials
62(3)
3.2.2 The Drude free-electron theory
65(6)
3.3 Complicating Factors
71(4)
3.3.1 Surface layers
71(1)
3.3.2 Surface roughness
72(1)
3.3.2.1 Angular dependence
73(1)
3.3.2.2 Translucent materials
73(2)
Chapter 4 Radiation thermometer design considerations
75(28)
4.1 Classification Of Radiation Thermometer Types
75(2)
4.2 The General Measurement Equation
77(15)
4.2.1 The throughput of the optical system
79(5)
4.2.2 Noise-limited performance
84(5)
4.2.3 Noise limits and examples of behaviour
89(2)
4.2.4 Additional noise sources
91(1)
4.2.4.1 Mechanical noise
91(1)
4.2.4.2 Electromagnetic interference
91(1)
4.2.5 a.c. effects
92(1)
4.3 Radiation Thermometer Design Process
92(4)
4.3.1 General radiation thermometer design considerations
92(2)
4.3.2 Choice of wavelength and design procedure
94(2)
4.4 Optical System Design
96(7)
4.4.1 Refracting optics
97(1)
4.4.1.1 General principle
97(1)
4.4.1.2 Refracting optics -- simple design
97(1)
4.4.1.3 Refracting optics -- Lyot stop design
97(1)
4.4.1.4 Optical materials
98(1)
4.4.2 Reflecting optics
99(1)
4.4.2.1 Catadioptric
99(1)
4.4.2.2 Off-axis
99(1)
4.4.3 Wavelength selection
100(1)
4.4.4 Stray light reduction
101(2)
Chapter 5 Detectors
103(32)
5.1 Introduction
103(2)
5.2 Classification Of Detectors
105(1)
5.3 Photoemissive Devices
106(13)
5.3.1 Vacuum photodiodes
110(1)
5.3.2 Photomultipliers
111(8)
5.4 Photoconductive Devices
119(2)
5.5 Semiconductor Photodiodes
121(6)
5.6 Avalanche Photodiodes
127(1)
5.7 Thermal Detectors
128(1)
5.7.1 Thermopile
128(1)
5.7.2 Bolometer
128(1)
5.7.3 Pyroelectric detector
129(1)
5.8 Detector Linearity
129(6)
5.8.1 Sectored discs
131(1)
5.8.2 Neutral density niters
132(1)
5.8.3 Multiple aperture techniques
133(1)
5.8.4 Beam conjoiners
134(1)
Chapter 6 Series expansion analytical technique
135(20)
6.1 Introduction
135(4)
6.2 The Series Expansion Technique
139(6)
6.2.1 Extent of applications of the technique
143(2)
6.3 Examples Of Applications
145(10)
6.3.1 Calculation of temperatures from signal ratios
145(1)
6.3.2 Generalised effective wavelengths
146(3)
6.3.3 Calculation of second-order terms
149(2)
6.3.4 Uncertainties from changes in the spectral response
151(2)
6.3.5 Dependence of radiance temperature upon bandwidth
153(2)
Chapter 7 Multi-wavelength radiation thermometry
155(20)
7.1 Introduction
155(8)
7.1.1 Effect of measurement errors
161(2)
7.2 The Least Squares Approach
163(5)
7.2.1 Overall assessment of the technique
166(2)
7.3 Two-Colour Radiation Thermometry
168(5)
7.3.1 Sources of uncertainty
170(1)
7.3.1.1 From the variations of emissivity
170(1)
7.3.1.2 Other characteristics of the source
171(1)
7.3.1.3 The measurement accuracy and stability
172(1)
7.4 Other Methods Of Multi-Wavelength Radiation Thermometry
173(2)
Chapter 8 Emissivity correction methods
175(40)
8.1 Introduction
175(2)
8.2 Correction With Emissivity Values
177(3)
8.3 Surface Modification
180(3)
8.4 Reflection Of Radiation From The Surface
183(15)
8.4.1 Extension to hemispherical reflectors
187(7)
8.4.2 Use of cylindrical mirrors
194(4)
8.5 Use Of Auxiliary Sources
198(13)
8.5.1 Methods with near-normal irradiation of the surface
201(1)
8.5.2 Multi-wavelength methods
202(3)
8.5.3 Laser absorption radiation thermometry
205(1)
8.5.4 Illumination at large angles
206(2)
8.5.5 Illumination with heated plates
208(2)
8.5.6 Polarisation techniques
210(1)
8.6 Minimisation Of Errors From Reflected Light
211(4)
Appendix A The meaning of `measurement'
215(8)
A.1 Introduction
215(1)
A.2 Criteria For The Existence Of A Quantity
216(2)
A.3 Empirical Scales
218(1)
A.4 Theoretical Quantities
219(4)
Appendix B Effective Wavelengths
223(6)
B.1 Mean Effective Wavelength
223(4)
B.2 Other Empirical Equations
227(2)
Appendix C Measurement Of Filter Transmission
229(8)
C.1 Introduction
229(2)
C.2 Measurement Procedures
231(2)
C.3 Integration Techniques
233(1)
C.4 Correction For Monochromator Bandwidth
234(3)
Bibliography 237(2)
Index 239
Peter Coates joined NPL in 1966, having gained a BSc at Cambridge and a PhD at Imperial College working with shock tubes. On joining the National Physical Laboratory he initially constructed ultra-fast timing circuits for measuring the time of emission of radiation from atoms, a skill he took with him when he joined the temperature section to measure the emission of photons from poorly radiating surfaces by counting individual photons. He transferred to the Temperature Section in 1972, to apply his expertise in photon counting to the NPL primary photoelectric pyrometer built by T. J. Quinn and M. Ford. He was able to make significant improvements in precision use of photomultipliers in the days before silicon photodiodes became established. He and his colleagues, Terence Chandler and John Andrews, also improved the performance and use of pyrometric lamps, including feedback stabilisation of the radiance, and they made the first and most accurate determination of the freezing temperature of palladium for many years. Peter succeeded Terry Quinn as Section head in 1975, while continuing his work in pyrometry. He was an excellent theorist, and produced two or three seminal papers in pyrometry, notably exposing the weaknesses of multiwavelength methods, which had been much trumpeted as overcoming the difficulty of unknown emissivity, showing that it is fundamentally based on an unjustified extrapolation to zero wavelength and that passive techniques alone could not solve the problem. In the early 1980s, dissatisfied with the frustrations of management, he made a second career change and moved to the NPL Time and Frequency group, where he remained until his retirement. He meanwhile drafted most of an authoritative and muchneeded book on 'Radiation Pyrometry', as he preferred to call it. Since his death in 2013 the book has been completed by Dr David Lowe, a current practitioner at NPL.



David Lowe gained a BSc in Physics at the University of Wales College of Cardiff and a PhD in engineering at Warwick where he developed optical reflectivity techniques to characterise semiconductor super-lattice structures. He started at NPL in 1999 where he built the replacement for the Quinn and Ford photoelectric pyrometer. While at NPL he has worked on high temperature thermometery reference standards, and has built a number of radiation thermometers for use as calibrated transfer standards.
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