Inhalt
Vakuumelektronik
|
|
Influence of Field Electron Emission, Gas Adsorption, and Surface Migration on the Voltage Strength of Vacuum Gaps
B. Jüttner, Max-Planck-Institut für Plasmaphysik, Berlin, D. A. Zeitoun-Fakiris, C. E. de Saclay, Dapnia-Sea, Gif-Sur-Yvette, F |
11 |
Recent Advances in Dispenser Cathode Technology
L. R. Falce, G. S. Breeze, Semicon Associates, Lexington, Kentucky, USA |
17 |
Multilayer MM-Cathodes with Specific Additives
F. Bossert, R. Lotthammer, AEG Daimler Benz Industries, Ulm, D |
23 |
A Low Power, Indirectly Heated Oxide Coated Cathode through Miniaturisation by Thin Film Technology
F. M. M. Snijkers, Philips Display Components, Eindhoven, NL W. L. C. Heyboer, Philips Research Laboratories, Eindhoven, NL |
29 |
Emissionseigenschaften von Top-Layer Scandat Kathoden
G. Gärtner, P. Geittner, H. Lydtin, Philips GmbH Forschungslaboratorien, Aachen, D |
35 |
Mechanismen nichtkonventioneller Mikrowellenröhren
H. Döring, RWTH Aachen, D |
41 |
Results of linearised Ku-Band TWTs for Space Application
P. Heumüller, R. Nunn, E. Bosch, H.-P. Rothacker, AEG Daimler Benz Industries, Ulm, D |
49 |
Directed Radiation Cooling of Satellite TWTs via Cone-Collector
E. Bosch, H. Rupp, H. Seidel, AEG Daimler Benz Industries, Ulm, D |
55 |
A Simple Technique for Measuring the Interaction Impedance of the Helical Slow-Wave Structures for TWTs
P. Wang, R. G. Carter, Lancaster University, UK B. N. Basu, Banaras Hindu University, Varanasi, IND A. K. Sinha, Central Electronics Engineering Research Institute, Pilani, IND |
63 |
Computer Modeling of Coupled-Cavity Slow-Wave Structures
R. G. Cater, Lancaster University, UK L. M. Joshi, Mrs. Mradula, CEERI, Pilani, IND Zhang Jin-Lin, Beijing Vacuum Electronics Research Institute, VRC |
69 |
Determination of the Shelf Life of Ku-Band TWTs Using Reliable Estimation Methods
H. Vetter, H. Seidel, AEG Daimler Benz Industries, Ulm, D |
75 |
An Investigation into Frequency Twinning in Magnetrons
E. M. Ball, EEV Ltd., Witham, UK R. G. Carter, Lancaster University, UK M. Brady, EEV Ltd. Cheltwford, UK |
85 |
Chaos in a Plasma-Filled Diode
X. Chen, P. A. Lindsay, King's College, University of London, UK |
91 |
Experimental and Theoretical Investigations of the Output Circuit for a Relativistic Klystron
V. M. Pikunov, K. 0. Garkusha, A. N. Sandalov, A. A. Stogov, Moskau, Russia |
101 |
Gyrotron Installation for Millimeter-Wave Processing of Materials
Yu. Bykov, A. Eremeev, V. Flyagin, V. Kaurov, A. Kuftin, A. Luchinin, 0. Malygin, I. Plotnikov, V. Zapevalov, Russian Academy of Sciences, Nizhny Novgorod, Russia L. Feher, M. Kuntze, G. Link, Forschungszentrum Karlsruhe, D M. Thumm, Universität Karlsruhe, D |
103 |
Operation and Design of Megawatt Gyrotrons at 140 GHz at the Forschungszentrum Karlsruhe
G. Dammertz, E. Borie, C. T. Iatrou, M. Kuntze, A. Möbius, B. Piosczyk, Forschungszentrum Karlsruhe, D O. Höchtl, S. Kern, H.-U. Nickel, C. Semmle, M. Thwmn, A. Wien, University of Karlsruhe, D |
109 |
Advanced Russian Gyrotrons for Plasma Investigations
G. G. Denisov, V. A. Flyagin, A. L. Goldenberg, A. N. Kuftin, A. B. Pavelyev, V. E. Zapevalov, Russian Academy of Sciences and Gycom Ltd., Nizhny Novgoro , Russia |
115 |
Two-Cavity Gyrotron
E. V Sokolov, E. V Zasypkin, I. I. Antakov, Russian Academy of Science, Nizhny Novgorod, Russia |
121 |
A Free-Electron-Maser for Heating of Fusion Plasmas
A. G. A. Verhoeven, A. B. Sierk, W. H. Urbanus, M. J. van der Wiel, FOM-Instituut voor Plasmafysica "Rijnhuizen", Nieuwegein, NL |
127 |
Microstructured Liquid Metal Ion and Electron Sources (MILMIS/MILMES)
J. Mitterauer, Technische Universität Wien, A |
133 |
Simulation of Vacuum Microelectronic Components
P. Kopka, H. Ermert, Ruhr-Universität Bochum, D |
139 |
Cathodes for Vacuum Integrated Circuits - Results and Prospects
A. N. Govyadinov, Belarus Academy of Sciences, Minsk, Russia |
145 |
Materials Processing by Focused Ion Beams
L. Frey, S. Lipp, H. Ryssel, Erlangen, D |
151 |
Gyroton Operation Using three Different Types of Cold Cathode
A. D. R. Phelps,A. W. Gross, M. Garven, K. Ronald, Glasgow, UK |
153 |
Multizone Matrix-Type Cathode-Heating Assemblies for Vacuum Integrated Circuits
I. L. Grigorishin, G. I. Efremov, N. 1. Mukhurov, Belarus Academy of Sciences, Minsk, Russia |
155 |
New Material for Vacuum Electronics and Microtechnology - Anodic Alumina
A. N. Govyadinov, I. L. Grigorishin, P. P. Mardilovich, Belarus Academy of Sciences, Minsk, Russia |
161 |
Promising Thermionic Vacuum Integrated Microcircuits Based on Microrelief-Bearing Dielectric Substrates for Thermoradiation-Resistant Apparatus - Design Concept
I. L. Grigorishin, N. I. Mukhurov, 1. F Kotova, Belarus Academy of Sciences, Minsk, Russia |
167 |
New Developments in the Modelling and Design of Coupled-Cavity Travelling-Wave Tubes
R G. Carter, J. A. Broune, Witham, UK |
173 |
Simulation of MIG Guns for Gyrotrons Using the Particle in Cell Method
E. Borie, C. Grüber, S. Illy, Forschungszentrum Karlsruhe, D T. Westermann, Fachhochschule Karlsruhe, D |
175 |
Numerical Simulation and Experimental Investigation Helical Electron Beams of Gyrotrons
A. N. Kuftin, V K. Lygin, V N. Manuilov, A. S. Postnikova, V E. Zapevalov, Russian Academy of Sciences, Nizhny Novgorod, Russia |
181 |
CW 10 kW Technological Gyrotron in the Range 15-50 GHz
V. A. Flyagin, An. N. Kuftin, V. K. Lygin, A. G. Luchinin, O. V Malygin, V. N. Manuilov, Sh. E. Tsimring, V E. Zapevalov, Russian Academy of Sciences, Nizhny Novgorod, Russia |
187 |
Numerical Simulation and Experimental Study of Non-Adiabatic Collector System of a Powerfull 140 GHz Gyrotron
A. L. Goldenberg, S. A. Malygin, V. N. Manuilov, Russian Academy of Sciences, Nizhny Novgorod, Russia |
193 |
Numerical Simulation of Intense Helical Electron Beams Taking into Account Velocity Distribution Functions
V. K. Lygin, V. N. Manuilov, Russian Academy of Sciences, Nizhny Novgorod, Russia |
197 |
Numerical Simulation of Intense Azimuthal-Asymmetric Helical Electron Beams Taking into Account Velocity Distribution Functions
V. K. Lygin, Russian Academy of Sciences, Nizhny Novgorod, Russia |
201 |
The Semiconductor Materials for Output Windows of High-Power Gyrotrons of MM Wavelength Range
R. Heidinger, Kernforschungszentrum Karlsruhe, D. V. V. Parshin, Applied Physics Institute RAS, Nizhny Novgorod, Russia |
207 |
Displays
|
|
Liquid Crystal Materials for Active Matrix Displays
T. Geelhaar, K. Tarumi, M. Bremer, E. Merck, Darmstadt, D |
213 |
Zero-Field Bisable Reflective Cholesteric Displays
P. Bos, D. Yang, M. Pfeiffer, J. W. Doane, Kent State University, Ohio, USA |
219 |
Display Applications of PDLC
D. Coates, P. Nolan, E. Jolliffe, Merck Ltd. Poole, UK |
225 |
Antiferroelectric Liquid Crystals - Promising Materials for Displays Applications
G. Heppke, Technische Universität Berlin, D |
231 |
Manufacturing AM-LCDs in Europe - A Task of Sisyphus
L. G. van A lphen, Eindhoven, NL |
233 |
Improvements in Microlithography for Flat Panel Color Filters
G. L. Resor, MRS Technology Inc., Chelmford, USA |
235 |
Lithography Tools for Non-Critical Masking Levels in Flat Panel Display Manufacturing
E. Cullmann, Garching, D |
239 |
Photolithography with Lenslet Arrays
R. Dändliker, R. Völkel, H. P. Herzig, University of Neuchatel, CH W. B. Hugle, Hugle Lithography S. A., Brissago, CH |
241 |
The Challenge of AMLCD Mass Manufacturing: The Plasma enhanced CVD Case
J. P. M. Schmitt, Balzers Display Technology, Palaiseau, F |
247 |
Entwicklung und Optimierung eines neuartigen, materialeinsparenden Beschichtungsverfahrens für Flachbildschirme
A. Kübelbeck, D. Schurig, Steag Micro Tech GmbH, Sternenfels, D |
253 |
Equipment for the Production of Flat Panel Displays
J. Pollock, St. Petersburg, USA |
257 |
Requirements on Flat Panel Display Equipment
S. Pongratz, Leybold AG, Alzenau, D |
259 |
Clusterhandling for Large Flat Panel Display Substrates
R. Young, Niedereschach |
267 |
Defect Detection in Flat Panel Arrays Using Electron Beams
M. Brunner, R. Schmid, ICT GmbH, Heimstetten, D |
269 |
Quality Control of Flat Panel Displays by Laser Scanning
H. Örley, C. Schenk, Martinsried, D |
275 |
Sputtering Systems for Production of Flat Panel Displays
K. Michael, W. Radloff, B. Ocker, Leybold AG, Alzenau, D |
285 |
Active Matrix LCD Addressing with Two-Terminal Devices
J. M. Shannon, Philips Research Laboratories, Redhill, UK |
291 |
Addressing of Passive Matrix Displays - known limitations and new methods
W. Fertig, Optrex Europe GmbH, Babenhausen, D |
299 |
The Development of Ferroelectric LCDs for the Marketplace
M. G. Clark, Borehamwood, UK , |
311 |
An A4-Size Reflective PSCT-Display
R. Bunz, W. Sautter, E. Lüder, University of Stuttgart; D M. Pfeiffer, D. K. Yang, J. W Doane, Kent State University, USA; C. Catchpole, Z. Yaniv, Kent Display Systems, USA |
313 |
Amorphous and Super-Multidomain AM-LCDs Exhibiting Uniform and Wide Viewing Angle Characteristics and Excellent Grayscale Capability
S. Kobayashi, Y Iimura, Tokyo University, J T. Sugiyama, T. Hashimoto, Y. Toko, K. Katoh, Stanley Electric Co. Ltd., Yokoharna, J |
319 |
LCD-Projection and Photoinduced Alignment of Liquid Crystals
M. Schadt, F. Hoffman-La Roche Ltd, Basel, CH |
323 |
Considerations for the Design and Production of Dichroic Filters for Liquid Crystals Displays (LCDS)
K. Lenhardt, Jos. Schneider Optische Werke Kreuznach, Bad Kreuznach, D |
331 |
Color Splitting in LCD-Projectors
P. G. Wierer, R. Sperger, Optical Thin Film Components of Balzers Ltd., FL |
339 |
Space Saving Interconnection of LCD
D. Krabe, H. Reichl, Technische Universität Berlin, D |
347 |
Laser-Addressed Bistable Nematics for Projection Displays
M. Kreuzer, Technische Hochschule Darmstadt, D R. Eidenschink, NEMATEL, Mainz, D |
351 |
Laser-Display-Technologie (LDT)
H. Leinauer, Schneider Rundfunkwerke AG, Türkheim, D |
357 |
An LC-Projektor with a Reflective Light Valve and Reinjection of Light Lost During Polarization
J. Glueck, E. Lueder, T. Kallfass, E. Ginter, Universität Stuttgart, D |
363 |
Projectors with PDLC Light Valves
E. Ginter, E. Lueder, T. Kallfass, S. Huttelmeier, R. Baeuerle, Universität Stuttgart, D |
369 |
Graphic LCDs for Automotive Application - Display and Illumination Technologies
P. M. Knoll, R. Fieß, MotoMeter GmbH, Leonberg, D |
375 |
Low-Mux-LCDs für transflektive Anwendungen
A. Casel, O. Bader, AEG AG, Ulm, D |
381 |
Plasma Displays Panels - A Technology for Large Size High Resolution Displays
M. Breil, Thomson CSF, F |
387 |
High Resolution Monitor Tubes with High Brightness for Medical Applications
G. Gassler, AEG Daimler Benz Industries, Ulm, D |
393 |
Recent Developments for Full Colour TFEL-Displays
R. H. Mauch, Heinrich-Hertz-Institut für Nachrichtentechnik Berlin GmbH, D |
399 | |