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9780471958703

Display Systems Design and Applications

by ;
  • ISBN13:

    9780471958703

  • ISBN10:

    0471958700

  • Edition: 1st
  • Format: Hardcover
  • Copyright: 1997-07-07
  • Publisher: Wiley
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Summary

A current overview of Display Systems, written by recognised experts in the field. This book gives practical guidance on the latest technological developments and new application areas of displays which will enable the reader to gain an understanding of the current state of the art as well as the major trends that will shape future applications of displays and display systems. Display Systems offers an insight into display technology with a view to defining its best potential, by focusing on performance assessment and optimum utilisation. It brings together complimentary disciplines of design, hardware and usage, covering a wide range of developments, and is written by leading international experts. The book is divided into three sections: (1) requirements for display systems, covering topics such as applications and evaluation; (2) display technology, covering developments in flat panel displays as well as CRTs; and (3) display characterisation, including measurement techniques and colour specification. Also covered are ergonomic requirements for display systems and their mutual dependence on standards. The book will be welcomed by scientists, technologists and engineers active in the field and also by the developers of a wide range of systems and applications for displays. Its technical content is suitable for final year undergraduate or postgraduate study. The Society for Information Display (SID) is an international society which has the aim of encouraging the development of all aspects of the field of information display. Indeed, it is the only international society dedicated solely to this field, which is broad and interdisciplinary, not only in the scientific sense, but through development and manufacturing to marketing. Wiley SID Series in Display Technology This volume is the first in the series which aims to present a comprehensive technical discussion of the many disciplines which must be combined in the development of display systems. Further volumes will be announced in due course and more information on SID, its aims and activities can be found from its home page.

Author Biography

Lindsay MacDonald is Professor of Multimedia Imaging at the Colour & Imaging Institute, University of Derby. For 18 years he was with Crosfield Electronics Ltd, where he designed and wrote the software for the world's first computer-based page composition system in 1977. Professor MacDonald is a Fellow of the British Computer Society, the Institution of Electrical Engineers, the Royal Photographic Society, and the Royal Society of Arts. He is co-author or co-editor of a number of books, including Computer Generated Colour, Display Systems: Design and Applications, Colour Imaging: Vision and Technology and Colour Image Science: Exploiting Digital Media.

Table of Contents

Colour plates
xv(2)
About the editors xvii(2)
Contributors xix(4)
Preface xxiii(2)
Abbreviations xxv
PART 1 APPLICATIONS -- What drives the requirements for displays? 3(132)
1 How applications have driven display requirements
3(14)
Carl Machover
1.1 Introduction
3(1)
1.2 Applications of displays
4(4)
1.3 Resolution and addressability
8(3)
1.4 Brightness and colour
11(1)
1.5 Flicker and image motion
12(1)
1.6 Field of view and display size
12(2)
1.7 Other factors
14(1)
1.8 Conclusion
14(1)
Bibliography
15(2)
2 Display requirements for desktop electronic imaging
17(26)
Lindsay MacDonald
2.1 Introduction
17(1)
2.2 Quality in product design
18(3)
2.2.1 Quality Function Deployment
18(1)
2.2.2 Voice of the customer
19(2)
2.3 Gathering user requirements for displays
21(3)
2.3.1 Focus Group of experts
21(1)
2.3.2 Constructing a PST tree
22(1)
2.3.3 Analysis of the PST tree for displays
23(1)
2.4 EASI analysis
24(6)
2.4.1 The EASI groups
24(1)
2.4.2 The Quality Game
25(3)
2.4.3 Analysis of EASI results
28(2)
2.5 Results of the study
30(3)
2.6 Conclusions
33(1)
References
33(1)
Appendix A: PST tree of requirements for desktop displays
34(5)
Appendix B: Results of EASI classification of secondaries
39(4)
3 Application requirements and the evolution of displays
43(18)
Philip Robertson
3.1 Introduction
43(2)
3.2 The needs of advanced applications
45(7)
3.2.1 Achieving interaction -- performance requirements
46(2)
3.2.2 Working context or `paradigm' -- generic architecture requirements
48(2)
3.2.3 Display surface -- GUI and geometry requirements
50(1)
3.2.4 Overall implications of application requirements
51(1)
3.3 Display support for perceptual colour addressing
52(3)
3.3.1 Requirements for perceptual colour control
52(1)
3.3.2 Perceptual colour gamut representations
53(1)
3.3.3 Implications for display design -- perceptual colour control
54(1)
3.4 Perceptual sound control
55(1)
3.5 Perceptual texture control
56(2)
3.6 Summary and broader issues
58(1)
Acknowledgements
58(1)
References
59(2)
4 Head-mounted display technology in virtual reality systems
61(22)
Richard Holmes
4.1 Introduction
61(2)
4.2 Overview of VR display requirements
63(1)
4.3 Review of HMD options
64(3)
4.3.1 Cathode ray tubes
64(1)
4.3.2 Flat panel displays
65(1)
4.3.3 Advanced alternative display technologies
66(1)
4.4 Human factors of head-mounted displays
67(4)
4.4.1 Photosensitive epilepsy
67(1)
4.4.2 Accommodation and convergence disassociation
68(1)
4.4.3 Motion sickness
68(1)
4.4.4 Image quality
69(1)
4.4.5 Colour
70(1)
4.4.6 Brightness
70(1)
4.4.7 Contrast
71(1)
4.5 Technical issues in head-mounted displays
71(10)
4.5.1 Backlights
71(1)
4.5.2 Resolution
72(1)
4.5.3 Transmittance
73(1)
4.5.4 Pixel shape
74(1)
4.5.5 Screen aspect ratio
74(1)
4.5.6 Display size
75(5)
4.5.7 Viewing angle
80(1)
4.5.8 Screen refresh rate
80(1)
4.5.9 Video format
80(1)
4.5.10 Screen geometry
81(1)
4.6 Conclusion
81(1)
References
82(1)
5 Evaluating the spatial and textual style of displays
83(14)
Ben Shneiderman
Richard Chimera
Ninad Jog
Ren Stimart
David White
5.1 Introduction
83(2)
5.2 GUI design metrics
85(1)
5.3 Dialogue evaluation methods
86(6)
5.3.1 Dialogue box summary table
87(5)
5.4 Testing our methods
92(1)
5.5 Conclusions
93(2)
Acknowledgements
95(1)
References
95(2)
6 Estimation of the visibility of small image features on a VDU
97(20)
Dick Bosman
6.1 Introduction
97(2)
6.2 Response to symbol structure
99(4)
6.2.1 Analysis in the opto-spatial distance domain
99(3)
6.2.2 Analysis in the opto-spatial frequency domain
102(1)
6.3 Comfortably seeing detail
103(6)
6.3.1 Visibility in terms of just noticeable differences (JNDs)
103(2)
6.3.2 Average brightness resulting from local modulation within the symbol
105(2)
6.3.3 Effects of stroke width and character height
107(2)
6.4 Effect of blur
109(2)
6.5 Effect of active area of the display element on local brightness modulation
111(1)
6.6 Effect of colour
112(2)
6.7 Concluding remarks
114(1)
References
115(2)
7 Colour matrix displays: a paradigm shift for the future of electronic colour imaging
117(18)
Louis Silverstein
7.1 Introduction
117(3)
7.2 Empirical studies of CMD image quality
120(4)
7.3 Display modelling and optimisation
124(5)
7.4 The future of electronic colour displays
129(2)
Acknowledgements
131(1)
References
131(4)
PART 2 TECHNOLOGY -- What can current displays deliver? 135(126)
8 Matching display technology to the application
135(22)
Anthony Lowe
8.1 Introduction
135(1)
8.2 Comparing technologies and visualizing comparisons
136(1)
8.3 Head-mounted displays
137(6)
8.3.1 General considerations
137(1)
8.3.2 Pixel size
137(3)
8.3.3 Display module weight
140(1)
8.3.4 Display power and operating voltage
141(1)
8.3.5 Summary and conclusion
142(1)
8.4 Displays greater than 0.5 m diagonal
143(2)
8.5 Direct view display technologies less than 0.5 m diagonal
145(8)
8.5.1 Introduction
145(1)
8.5.2 Low power reflective displays
145(5)
8.5.3 Light emitting direct view displays with wide viewing angle
150(1)
8.5.4 Notebook computer displays
151(2)
8.6 Conclusion
153(1)
References
153(4)
9 Active matrix addressing of LCDs: merits and shortcomings
157(16)
Ernst Luder
9.1 Introduction
157(1)
9.2 Operation of TFTs and MIMs
158(4)
9.3 Fabrication of TFTs and MIMs
162(4)
9.4 Brightness of AMLCDs
168(2)
9.5 Conclusions, applications and future trends
170(1)
References
171(2)
10 The structure, performance and future of passive matrix LCDs
173(18)
Alan Mosley
10.1 Introduction
173(1)
10.2 Structure and fabrication
174(2)
10.3 Supertwist liquid crystal displays
176(5)
10.3.1 Operation and performance
176(3)
10.3.2 Recent developments
179(1)
10.3.3 Future potential
179(2)
10.4 Ferroelectric LCDs
181(5)
10.4.1 History and operating principles
181(3)
10.4.2 Future potential
184(2)
10.5 Polymer stabilised cholesteric texture LCDs
186(2)
10.5.1 History and operating principles
186(2)
10.5.2 Future Potential
188(1)
10.6 Conclusion
188(1)
References
189(2)
11 Emissive displays: the relative merits of ACTFEL, plasma and FEDs
191(32)
Jean-Pierre Budin
11.1 Introduction
191(1)
11.2 Alternating current thin film electroluminescent displays (ACTFEL)
192(10)
11.2.1 Operating principles, specificities and panel construction
192(8)
11.2.2 Performance of ACTFEL panels, present and future
200(2)
11.3 Plasma display panels (PDPs)
202(12)
11.3.1 Operating principles, specificities and panel construction
202(10)
11.3.2 Plasma display performance, present and future
212(2)
11.4 Field emission displays (FEDs)
214(4)
11.4.1 Operating principles, specificity and panel construction
214(3)
11.4.2 Performance of FEDs, present and future
217(1)
11.5 Conclusion
218(1)
Acknowledgements
219(1)
References
219(4)
12 The CRT as the display of the future
223(14)
Seyno Sluyterman
12.1 Introduction
223(1)
12.2 CRT basics
224(1)
12.3 The electron gun
224(3)
12.4 The yoke
227(3)
12.5 The shadowmask
230(3)
12.6 The phosphors
233(1)
12.7 The screen glass
234(2)
12.8 Conclusion
236(1)
References
236(1)
13 Projection systems
237(24)
Patrick Candry
13.1 Light valve projector system design
237(1)
13.2 CRT Projector system design
238(2)
13.3 Light valve technologies
240(4)
13.4 CRT technology
244(1)
13.5 Light source and illumination system for light valve projectors
245(4)
13.6 Projection optics for light valve and CRT Projection
249(4)
13.7 Conclusion
253(3)
References
256(5)
PART 3 METROLOGY -- How can display performance be evaluated? 261(152)
14 Principles of display measurement and calibration
261(28)
Jean Glasser
14.1 Introduction
261(1)
14.2 Overview of display characterisation parameters
262(3)
14.3 Standardised characterisation methods
265(2)
14.3.1 Function and benefit of the standards
265(1)
14.3.2 The players in display measurement standards and the current state-of-the-art
265(2)
14.4 Characterizing the visual stimulus: photo-colorimetric measuring instruments and their practical use
267(8)
14.4.1 Using measuring instruments to obtain photo-colorimetric data
267(6)
14.4.2 Electro-optical transfer
273(2)
14.5 Characterisation parameters
275(11)
14.5.1 Spatial parameters
275(4)
14.5.2 Temporal parameters
279(1)
14.5.3 Parameters depending on ambient illuminance
280(1)
14.5.4 Parameters depending on the viewing direction
281(5)
14.6 Conclusion
286(1)
Acknowledgements
286(1)
References
286(3)
15 Optical characterisation of LCDs: pitfalls and solutions
289(20)
Ludwig Selhuber
Amboise Parker
15.1 Introduction
289(1)
15.2 Characterisation tools
290(7)
15.2.1 Luminance and contrast measurements
292(4)
15.2.2 Colour measurements
296(1)
15.3 Characterisation methods
297(3)
15.3.1 Goniometric method
297(2)
15.3.2 Conoscopic method
299(1)
15.4 Obtaining reliable measurements
300(7)
15.4.1 Goniometric features
301(4)
15.4.2 Conoscopic features
305(1)
15.4.3 Monitor calibration
306(1)
15.5 Conclusion
307(1)
References
307(2)
16 Measurement and standardisation in the colorimetry of CRT displays
309(20)
Andrew Hanson
16.1 Introduction
309(1)
16.2 Colour specification
310(1)
16.3 Colour CRT technology overview
311(2)
16.4 Potential sources of measurement error for CRTs
313(4)
16.4.1 Spatial colour variability
313(1)
16.4.2 Short term temporal factors
314(1)
16.4.3 Changes over longer periods of time
314(1)
16.4.4 Spectral power distribution
314(1)
16.4.5 Black and white point settings
315(1)
16.4.6 Ambient light
315(1)
16.4.7 Non-additivity of primaries
316(1)
16.4.8 Environmental factors
316(1)
16.5 The spectroradiometer
317(5)
16.5.1 Critical design factors
317(1)
16.5.2 Scanning spectroradiometer
318(1)
16.5.3 Multi-channel spectroradiometer
319(1)
16.5.4 Sources of error for spectroradiometers
320(1)
16.5.5 Traceability for the scales of spectroradiometers
321(1)
16.6 The colorimeter
322(2)
16.6.1 Major sources of error for colorimeters
323(1)
16.6.2 Calibration of a colorimeter
324(1)
16.7 Traceability to national standards
324(3)
16.7.1 The national measurement system (NMS)
324(1)
16.7.2 Spectral radiance and spectroradiometric scales
325(1)
16.7.3 Reflectance and transmittance scales
325(1)
16.7.4 Colour
326(1)
16.7.5 Measurement of colour of displays
326(1)
References
327(2)
17 Techniques for high-quality, low-cost, colour measurement of CRTs
329(24)
Tom Lianza
17.1 The challenges of embedded monitor control
329(4)
17.1.1 The sensor architecture and selection process
330(1)
17.1.2 Product cost
330(1)
17.1.3 Factors affecting measurement speed
330(2)
17.1.4 Minimizing environmental constraints
332(1)
17.2 Spectral emission of the monitor
333(3)
17.3 Spectral response of the instrument
336(1)
17.4 Device calibration and sources of error
337(7)
17.4.1 Spectral response functions
337(2)
17.4.2 Electrical and photo-optical noise
339(3)
17.4.3 Temporal errors in monitor measurement
342(2)
17.5 Control of the monitor
344(2)
17.5.1 Display adjustments
344(1)
17.5.2 Controlling the digital display card
345(1)
17.5.3 Controlling the digital display chassis
346(1)
17.6 Matching monitors
346(4)
17.6.1 Limits and bounds
347(1)
17.6.2 Architectural implementation of monitor matching
347(2)
17.6.3 Operating procedure for monitor matching
349(1)
17.7 Measurement of ambient illumination
350(1)
17.8 Conclusions
351(2)
References
351(2)
18 The dynamic performance of CRT and LC displays
353(12)
David Parker
18.1 Introduction
353(1)
18.2 Subjective Considerations
353(3)
18.2.1 Flicker
354(1)
18.2.2 Dynamic resolution
354(1)
18.2.3 Portrayal of motion
355(1)
18.3 CRT displays
356(1)
18.4 AMLCD displays
357(3)
18.5 Field rate conversions
360(3)
18.6 Conclusions
363(1)
References
364(1)
19 Evaluating stereoscopic displays for 3D imagery
365(24)
Tim Bardsley
Ian Sexton
19.1 Introduction
365(1)
19.2 Application requirements
366(3)
19.2.1 Video imaging
366(1)
19.2.2 Synthetic imaging
367(1)
19.2.3 Hybrid systems
368(1)
19.3 Assessment of display types
369(5)
19.3.1 Image crosstalk
371(1)
19.3.2 Flicker
372(1)
19.3.3 Binocular colour rivalry
373(1)
19.3.4 Image intensity
373(1)
19.3.5 Lateral resolution
373(1)
19.4 Evaluation philosophy
374(1)
19.5 Experimental objectives
375(1)
19.6 Method
375(4)
19.6.1 Target tracking
377(1)
19.6.2 Depth discrimination
378(1)
19.6.3 Experimental procedure
378(1)
19.7 Results
379(5)
19.7.1 Target tracking performance
379(2)
19.7.2 Depth discrimination performance
381(2)
19.7.3 Subjective ranking
383(1)
19.8 Discussion
384(1)
19.9 Conclusions
385(1)
Acknowledgements
386(1)
References
386(3)
20 Evaluating the usability of workstation displays: a `real-world' perspective
389(24)
Nigel Heaton
Jim McKenzie
Andrew Baird
20.1 Introduction
389(2)
20.2 Impact of standards and legislation
391(4)
20.2.1 The DSE regulations
391(2)
20.2.2 The Annex of minimum requirements
393(1)
20.2.3 BS and ISO Standards
394(1)
20.3 Display usability an ergonomics perspective
395(7)
20.3.1 The user
397(1)
20.3.2 Task requirements
398(1)
20.3.3 Software Interface Styles
399(3)
20.4 The working environment
402(4)
20.4.1 The visual environment
402(1)
20.4.2 Lighting and contrast
403(2)
20.4.3 Humidity
405(1)
20.4.4 Workstation constraints
405(1)
20.5 Essential display characteristics
406(1)
20.6 Usability evaluation: techniques and metrics
407(3)
20.6.1 Development of methods
407(1)
20.6.2 Checklists and standards
408(1)
20.6.3 Selecting monitors -- a case study
408(2)
20.7 Conclusions
410(1)
References
411(2)
Index 413

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