光ファイバーセンサーの世界市場：将来予測

Fiber Optic Sensors Global Market Forecast Service

発行	ElectroniCast
発行回数	4 回/年	商品コード	8682
ページ情報	英文
価格	こちらの商品の販売は終了いたしました。

概要
原文目次
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当商品の販売は、2011年07月19日を持ちまして終了しました。

原文目次

Abstract

Overview

$ 621.62 Million Consumption Value by 2010

The global consumption value of Fiber Optic Sensors Devices (component-level/module-level) will rise steadily from $304.1 Million in 2005 to $621.62 Million by 2010, as shown in Table 1.1.1. Fiber-optic sensors offer numerous advantages over conventional electrical and/or electromechanical-based devices, since fibers are made of a dielectric material such as plastic or glass. Other advantages include: the fact that the signal transfer is provided as photons instead of the convention approach of dealing with electrons. Sensor devices based on semiconductor photo detectors and laser diode sources are not only smaller and lighter in weight, the dielectric immunity to electromagnetic interference (EMI) is extremely important is several applications. For example, fiber optic sensors may be placed very close to large EMI sources such as power generators, electrical motors, or on structures prone to lightning strikes (bridges, towers, aircraft). In addition, the geometric versatility offered by a flexible fiber allows unobtrusive sensing along with an environmental ruggedness.

FOGs Dominate Fiber Optic Sensor Market Value

The wide range of applications (uses) for fiber-optic sensors is facilitated by the various measurands (types of measurements). Because of the relative average price per unit, Fiber Optic Gyros (FOGs) sensors, which are used in Military/Aerospace as well as commercial guidance control applications, led in global consumption value with $201.9 Million in 2005; by 2010, the value will increase to $440.11 Million or 70.8 percent of the total worldwide market.

Total Number of Pages: 179

1. Fiber Optic Sensors Market Forecast and Analysis

1.1 Overview
- Measurement Explanation: Sensor Types
- Position, Proximity, and Displacement Sensors
- Strain Sensors
- Pressure Sensors
- Temperature Sensors
- Rotation Sensors
- Acoustic and Vibration Sensors
- Chemical Species
- Electrical and Magnetic Sensors
- Miscellaneous Sensors

2. Competitive Analysis

2.1 Overview
2.2 Market Share Estimates
2.3 List of Selected Fiber Optic Sensor Suppliers, By Sensor-Type

3. High Speed Optical Communication Trends

3.1 Overview
3.2 Fiber Network Technology Trends
3.3 Components
- 3.3.1 Overview
- 3.3.2 Transmitters and Receivers
- 3.3.3 Optical Amplifiers
- 3.3.4 Dispersion Compensators
- 3.3.5 Fiber Cable
3.4 Devices and Parts
- 3.4.1 Overview
- 3.4.2 Emitters and Detectors
- 3.4.3 VCSEL and Transceiver Technology Review
- 3.4.4 Optoelectronic Application-Specific Integrated Circuits
- 3.4.5 Modulators
- 3.4.6 Packages
- 3.4.7 Optoelectronic Integrated Circuits

4. Fiber Optics Industry Overview

4.1 Boom, Bust and Recovery

5. Fiber Optics Industry

5.1 Decade-to-Decade
5.2 Broadband and Fiber to the Premise

6. Definitions

Acronyms, Abbreviations and General Terms

7. Methodology

7.1 Research and Analysis Methodology
7.2 Assumptions of the 2005-2010 Market Forecast

List of Figures

1.1.1 Block Diagram: Sensor Relationships - Principals, Measurement, Applications
3.2.1 Network Bandwidth Expansion Alternatives
3.2.2 Multifiber Transmitters
3.2.3 Flexible Optical Backplane
3.4.3.1 Genealogy of VCSELs
3.4.3.2 10 Gbps VCSEL Optical Subassembly
3.4.3.3 4 x 3.125 Gbps WWDM SFF Transceiver Concept
3.4.3.4 Assembled Non-Functional 4 x 3.125 Gbps WWDM SFF Concept Module
3.4.3.5 WWDM Transceiver, Transmit Side Optical Combiner
3.4.3.6 WWDM Demultiplexing Subassembly
3.4.3.7 CWDM VCSEL Transceiver (8-wavelength diagram)
3.4.3.8 4-Channel VCSEL Transceiver
3.4.3.9 OptoCube 40
3.4.3.10 Array VCSEL Interconnects between Cabinets or Racks
3.4.3.11 12 x 2.5 Gbps VCSEL Transceiver Package
3.4.3.12 Pre-terminated Ribbon Cable Assembly
3.4.3.13 Optical Backplane Implementation
3.4.3.14 Typical Intra-Office Interconnections
3.4.3.15 12 Fiber VSR Architecture
3.4.3.16 Converter ASIC Function
3.4.3.17 12-Fiber VSR Module vs. OC-192 SONET Line Card
3.4.3.18 4 Fiber VSR Architecture
3.4.3.19 OC-192 and OC-768 VSR Module Pricing
3.4.7.1 Trend of Transceiver Packaging Density, Gigabits/Cubic Inch
3.4.7.2 Xanoptix 32x32 Datacom Transceiver
3.4.7.3 Integrated Transceiver/Silicon Waveguides
4.1.1 LH/SLH Submarine Global Fiber Optic Component Shipment Trends, 1990-2006
4.1.2 Regulated Telco Metro/Access Global Fiber Optic Component Trends, 1990-2006
4.1.3 Enterprise LAN/WAN/SAN/BBTH Global Fiber Optic Component Trends, 1990-2006
4.1.4 Price Trends of a Typical Maturing Component, 1997-2007
4.1.5 Contrasting Trends During the Business Cycle
5.1.1 Evolution of research Emphasis During Technology Life Cycle
5.1.2 Evolution to the All Optical Network
5.2.1 Access Network Elements
5.2.2 Multi-National IP Network
5.2.3 Broadband-to-the-Premise
5.2.4 Fully ROADM
5.2.5 B-PON OLT
5.2.6 FTTU - PON System
5.2.7 FSO Illustration

List of Tables

1.1.1 Global Fiber Optic Sensor Consumption Forecast, by Type ($, Million)
1.1.2 Global Fiber Optic Sensor Consumption Forecast, by Type (Quantity, Number of Units)
1.1.3 Applications of Fiber Optic Sensors addressing specific measurands
1.1.4 Operating Principles that make it possible to address specific measurands
1.1.5 Global Fiber Optic Sensor Consumption Forecast, by Application ($, Million)
1.1.6 Global Fiber Optic Sensor Consumption Forecast, by Application (Quantity, Number of Units)
2.2.1 Fiber Optic Sensors Competitive Market Share Estimate, 2005
2.3 List of Fiber Optic Sensor Suppliers, By Sensor-Type 2-4 to
3.3.3.1.5 OIF Proposals
5.2.1 Number of Subscribers- Broadband
5.2.2 Ideal/Minimum Speeds for Popular Applications
5.2.3 Passive Optical Network (PON) Comparisons