Microwave Component Mechanics

الغلاف الأمامي
Artech House, 2003 - 368 من الصفحات
HereOCOs a first-of-its-kind resource that offers you detailed guidance in the mechanical aspects of designing and manufacturing microwave components. The book takes an interdisciplinary approach that combines design and manufacturing, mechanical and electrical design, and microwave component performance and productivity. By exploring the immediate connection between electrical and mechanical quality, you more easily arrive at cost-effective solutions and reduce the unnecessary use of OC double-tolerancingOCO."

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الصفحات المحددة

المحتوى

References
200
Other Joining Technologies
203
82 Glued Joints
205
822 CyanoacrylateBased Adhesives
206
825 Adhesives for HighStrength Applications
208
826 HighTemperature Ceramic Adhesives
209
References
210
Machined Components
211

14 Connection Philosophies
26
15 Typical User and Application Profiles
27
Systematic Flowchart Model
29
211 Some Assisting Tools
31
212 List of Requirements
33
22 Advanced Methodology for Designing Microwave Mechanics
34
221 Basic Elements of the Advanced Methodology
35
222 Flowchart Presentation of the Tuned Methodology
39
References
42
Material Selection for Microwave Mechanics
45
32 Effects of the Products Operating Frequency
47
322 Definition of the Penetration Depth
48
33 Effects of the Operating Environment
51
34 Metallic Components
54
341 OxygenFree Copper
55
343 Beryllium Copper Alloy
56
344 Phosphorus Bronze
57
345 Brass
58
347 Aluminum Alloys
60
348 Invar
62
35 Use of Plastics
64
353 Other Fluorine Plastics
65
355 Polyphenylene Oxide
66
361 PowderMetallurgically Manufactured Materials for Microwave Mechanics
69
362 Application Areas of Ceramic Materials in Microwave Mechanics
73
363 Low Temperature Cofired Ceramics
75
References
77
ComputerAided Environment for Design Work
79
41 Integration of Basic CAD Tools
80
411 Interaction Between Virtual Engineering and Hypermedia Applications in Controlling Heat Input During Welding of Microwave Components
86
412 Integration of ComputerAssisted Engineering and Microwave Mechanics Simulation in Welded Stripline Filter Design
94
42 Typical Simulation Software Solutions for Microwaves
96
43 Integration Problems of Current CAD Applications
102
432 Problems in CAD Applications Developed for Microwave Design
103
References
108
Instructions for Technical Documentation and Dimensioning
111
51 The Relationship Between RF Parameters and Mechanical Parameters
112
52 Differences Between DFMAand PerformanceOriented Approaches
114
53 On the Suitability of General Manufacturing Tolerances for MW Mechanics
116
References
118
Effects of Production Volume and Related Topics
119
612 Material Costs
120
62 Relationship Between Manufacturing Costs and Surface Finish
121
63 Relationship Between Manufacturing Costs and Dimensional Tolerance
122
641 Goals of DFMDFMA
123
643 Putting DFM in Practice
125
644 Additional Tools for DFM
127
645 More Effective Use of DFM
128
65 A CrossTechnological Approach
129
66 Concurrent Engineering Design
131
661 The Design Process for CE
132
662 Manufacturability for CE Design
133
67 Manufacturing Costs of Prototypes
134
68 Quality Aspects
135
610 Cost Accumulation in Laser Processed Components
136
611 Manufacturing Costs of Other Manufacturing Processes
141
References
148
Manufacturing Technologies for Some Passive Microwave Components
151
Welded Components
153
72 Laser Welding in General
154
721 Parameters of Laser Welding
156
73 LaserWelded Stripline Filter
157
74 Utilizing Ultrasonic Welding in Filter Constructions
164
75 Welded Joint Geometries of Microwave Cavity Resonators and Waveguides
170
751 Practical Welding Instructions for Cavity Resonators and Waveguides
174
76 Welded Radiating Elements of Patch Antennas
177
77 A Comparison of Welding Processes for Encapsulating Electronics
192
771 Advantages of Laser Welded Sealing
193
772 Projection Welding Application
197
92 Milled Low Loss Filters
215
93 Ring Hybrids and Other Milled Power Dividers
218
94 General Enclosures for Encapsulating Electronics
224
95 Connector Mounting Considerations
229
96 Rotary Joints
231
961 Basic Waveguide Rotary Joints
233
962 Swivel Joints
234
963 Coaxial Rotary Joints
235
97 Case Examples of Precision Machined Microwave Components
237
971 HighQ SiO Whispering Gallery Mode Resonator
238
972 Center Conductor for a Tubular Coaxial Filter
239
References
240
Cutting Processes
243
102 Water Jet Cut Striplines and Microstrips
246
1022 A Water Jet Cut Stripline Feeding Network
249
1031 Laser Cutting Process in General
250
1032 A Laser Cut SharpEdged Center Conductor
251
1033 Laser Cut Striplines for LowLoss Interdigital Filters
253
104 Tuning Coaxial Transitions
256
References
259
Forming Processes
261
112 Selected Processes for Shaping Plastics
264
1121 Injection Molding
265
113 Drawing Processes for Wires
266
114 Forming Processes for Sheet Metals
267
115 Electroforming Process for Corrugated Waveguides
268
References
269
Coating
271
122 Requirements for Coating Quality
273
124 Case Examples of Coated Microwave Components
278
References
282
Examples of Requirements for Mechanical Accessories in Microwave Assemblies
283
A Microwave Measuring System for Wood Quality
285
131 Description of the Test Arrangement
286
132 Transducer Arrangements
289
133 Mechanical Requirements for the Measurement System Assembly
291
1331 Serviceability and Easy Access
293
References
294
Antenna Constructions
295
141 Basis for the Design of Antenna Constructions
296
142 Wind and Ice Loads
297
References
300
Test Arrangements and Results of Microwave Components Manufactured with Alternative Technologies
301
Mechanical Measuring Equipment
303
1512 Measuring Geometric Tolerances
304
152 Joint Reliability
310
1531 Oxide Layers
311
1533 Mechanical Composition of the Surface Texture
312
1534 Measuring Surface Roughness
313
1535 Friction Measurement
315
1537 Hardness Tests
317
References
318
Selecting Microwave Test Instrumentation
321
161 Vector Network Analyzers
322
162 Spectrum Analyzers
323
163 Signal Generators
324
164 Cables Connectors and Some Accessories
325
Examples of Practical Test SetUps
327
172 Testing the Shielding Performance of Microwave Enclosures
329
173 Experiments on the Input Impedance of Waveguide to Coax Transitions
330
174 Analyzing the Effects of Mechanical Defects on the Performance of Small Phased Array Antennas
332
References
338
Summary
339
List of Acronyms
343
List of Symbols
349
Requirements for Viewing Appendixes A B and C
353
About the Authors
355
Index
357
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الصفحة 128 - Fuzzy logic is a superset of conventional Boolean logic that has been extended to handle the concept of partial truth — truth values between "completely true
الصفحة 304 - Datum: A theoretically exact point, axis, or plane derived from the true geometric counterpart of a specified datum feature. A datum is the origin from which the location or geometric characteristics of features of a part are established . Datum Feature: An actual feature of a part that is used to establish a datum.
الصفحة 43 - A modelbased method for organizing tasks in product development". Research in Engineering Design, vol. 6, no. 1, pp.
الصفحة 149 - Product life cycle cost analysis: State of the art review.
الصفحة 108 - Integrating Engineering Design and Analysis Using a Multi-Representation Approach," Engineering with Computers, Vol.
الصفحة 128 - A fuzzy expert system is an expert system that uses a collection of fuzzy membership functions and rules, instead of Boolean logic, to reason about data.
الصفحة 43 - Identifying Controlling Features of Engineering Design Iteration," Management Science, Vol. 43, No. 3, March 1997, pp. 276-293. Smith, Robert P., and Steven D. Eppinger, "A Predictive Model of Sequential Iteration in Engineering Design,
الصفحة 43 - Model-Based Approaches to Managing Concurrent Engineering," Journal of Engineering Design, Vol. 2, No. 4, 1991, pp. 283-290. [20] Eppinger, SD, MV Nukala, and DE Whitney, "Generalised Models of Design Iteration Using Signal Flow Graphs," Research in Engineering Design — Theory, Applications and Concurrent Engineering, Vol.

نبذة عن المؤلف (2003)

Harri Eskelinen received his M.Sc.and D.Sc. in mechanical engineering at the Lappeenranta University of Technology, Finland. He is a senior research scientist in the laboratory of manufacturing technology at the Lappeenranta University of Technology, Finland. Pekka Eskelinen received his M.Sc., D.Sc., and Ph.D. in electrical engineering from the Institute of Digital Communications at the Helsinki University of Technology, Helsinki, Finland. He is a professor in the radio laboratory and head of the Institute of Digital Communications at the Helsinki University of Technology, Helsinki, Finland.

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