OPTICAL MODULATORS GLOBAL MARKET FORECAST & ANALYSIS

1. Executive Summary

• 1.1 Optical Modulator Market Forecast
• 1.2 Broadband and FTTx Trends
• 1.3 Fiber Optics Industry Overview
  • 1.3.1 Boom, Bust and the Recovery
  • 1.3.2 Fiber Optics Industry: Decade-to-Decade

2. Optical Modulator Technology

• 2.1 Overview
• 2.2 Modulator Definition

3. 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 & 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. Competitive Analysis

• 4.1 Overview
• 4.2 Market Share Estimates for Selected Competitors (2007)

5. Methodology

• 5.1 Research and Analysis Methodology
• 5.2 Assumptions of Fiber Optic Component Global Market Forecast

6. Definitions

• 6.1 Acronyms, Abbreviations, and General Terms

7. Market Forecast Data Base - Overview and Tutorial

• 7.1 Overview
• 7.2 Tutorial

• Global
• America
• Europe
• APAC

• 1.1.1 Full-band tunable high-dynamic-range transmitter engine, Source JDS Uniphase Corporation
• 1.1.2 Next Generation' s UDWDM 2500 Channel Filter Module
• 1.2.1 Access Network Elements
• 1.2.2 Fiber-to-the-Office Forecast Structure
• 1.2.3 Cogent Communication' s Multi-National IP Network
• 1.2.4 Broadband-to-the-Premise Architecture
• 1.2.5 Fully Reconfigurable OADM
• 1.2.6 B-PON Optical Line Terminal
• 1.2.7 Alcatel 7340 FTTU-PON System
• 1.2.8 Free Space Optics (FSO) Illustration
• 1.3.1.1 LH/SLH/Submarine Global Fiber Optic Component Shipments
• 1.3.1.2 Regulated Telco Metro/Access Global Fiber Optic Component Shipments
• 1.3.1.3 Enterprise LAN/WAN, SAN, BBTH, SOHO Global Fiber Optic Component Shipments
• 1.3.1.4 Price Trends of a Typical Maturing Component, 1997-2007
• 1.3.2.1 Evolution of Research Emphasis during Technology Life Cycle
• 1.3.2.2 Evolving to the All-Optical Network
• 1.3.2.3 AON - Technology Demonstration Roadmap, Source: CRC
• 1.3.2.4 AON - Test-bed Network Platform, Source: CRC
• 2.1.1 10-Gbit/s directly modulated DFB laser and scope to network system (Source: NTT)
• 2.1.2 Structures of a LN Modulator (Source: Sumitomo Osaka Cement Opto-Electronics Group)
• 2.1.3 “ZERO” and “ONE” Driving Voltage of the LN Modulator (Source: Sumitomo)
• 2.1.4 Electrical Digital Signals are Transformed into Optical Digital Signal (Source: Sumitomo)
• 2.1.5 Changes in the “phase” of optical signals by applying voltage (Source: Sumitomo)
• 2.1.6 Reducing DC Drift (Source: Sumitomo Osaka Cement Opto-Electronics Group)
• 2.1.7 Reducing DC Drift, Continued (Source: Sumitomo Osaka Cement Opto-Electronics Group)
• 2.1.8 Bias Control Configuration by TAP Coupler and PD Integrated Modulator (Source: Sumitomo)
• 2.1.9 Y-Combiner Junction (Source: Sumitomo Osaka Cement Opto-Electronics Group)
• 2.1.10 Main Optical output and Monitor signal (Source: Sumitomo)
• 2.1.11 10 Gbps LN Optical Modulator CODEON' s Mach-10TM (source: COVEGA: CODEON)
• 2.1.12 40Gbps LN optical modulator with 1.8V drive voltage (Source: Fujitsu Limited)
• 2.1.13 Package Size (Hermetically-sealed) Drawings - 40Gbit DQPSK Modulator (Source: Sumitomo)
• 2.1.14 40 Gbps DQPSK Optical Transceiver (Source: Fujitsu Limited)
• 2.1.15 Transmission Reach as Limited by PMD (Source: Fujitsu Limited)
• 2.1.16 Electroabsorption Modulator Structure Illustration
• 2.1.17 The OL5157M EML (Source OKI Electric Europe GmbH)
• 2.1.18 EML Line Drawing (Source: Agere Systems: Acquired by LSI Corporation)
• 2.1.19 Configuration Using a PEM for Measurement Application (Source: University of Wisconsin)
• 2.2.1 High-Speed Laser Diode Modules (Source: NEC Compound Semiconductor Devices)
• 2.2.2 Injection Laser with EA modulator (Source: RPI)
• 2.2.3 External Modulation, General Circuit
• 3.2.1 Network Bandwidth Expansion Alternatives
• 3.2.2 Xanoptix Multifiber Transmitters
• 3.2.3 Flexible Optical Backplane
• 3.4.3.1 Genealogy of VCSELs
• 3.4.3.2 New Focus 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 Transceiver 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 Corona Optical Systems 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
• 3.3.3.15 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 Bookham Integrated Transceiver; Silicon Waveguides
• 5.1.1 Market Research & Forecasting Methodology

• 1.1.1 Optical Communication Modulator Global Forecast, By Region ($, Million)
• 1.1.2 Optical Communication Modulator Global Forecast, By Region (Quantity, K)
• 1.1.3 Global Forecast of Optical Communication Modulators, by Type ($, Million)
• 1.1.4 Global Forecast of Optical Communication Modulators, by Type (Quantity, K)
• 1.1.5 North American Forecast of Optical Communication Modulators, by Type ($, Million)
• 1.1.6 North American Forecast of Optical Communication Modulators, by Type (Quantity, K)
• 1.1.7 European Forecast of Optical Communication Modulators, by Type ($, Million)
• 1.1.8 European Forecast of Optical Communication Modulators, by Type (Quantity, K)
• 1.1.9 Japan/Pacific Rim Forecast of Optical Communication Modulators, by Type ($, Million)
• 1.1.10 Japan/Pacific Rim Forecast of Optical Communication Modulators, by Type (Quantity, K)
• 1.1.11 Global Forecast of Optical Communication Modulators, by Data Rate ($, Million)
• 1.1.12 Global Forecast of Optical Communication Modulators, by Data Rate (Quantity, K)
• 1.1.13 North American Forecast of Optical Communication Modulators, by Data Rate ($, Million)
• 1.1.14 North American Forecast of Optical Communication Modulators, by Data Rate (Quantity, K)
• 1.1.15 European Forecast of Optical Communication Modulators, by Data Rate ($, Million)
• 1.1.16 European Forecast of Optical Communication Modulators, by Data Rate (Quantity, K)
• 1.1.17 Japan/Pacific Rim Forecast of Optical Communication Modulators, by Data Rate ($, Million)
• 1.1.18 Japan/Pacific Rim Forecast of Optical Communication Modulators, by Data Rate (Quantity, K)
• 1.2.1 Leaders (Countries) in Broadband, Based on Total Subscribers at >200Kbps (one-way)
• 1.2.2 Minimum & Ideal Speeds Necessary for Popular Applications
• 1.2.3 Selected PON Comparison
• 1.2.4 Canadian Broadband Statistical Data (2007)
• 1.2.5 Summary Information - Bell Canada (2007)
• 1.2.6 Summary Information - Cogeco Cable - Canada (2007)
• 1.2.7 Summary Information - Rogers Cable - Canada (2007)
• 1.2.8 Summary Information - Shaw Communications - Canada (2007)
• 1.2.9 Summary Information - Telus - Canada (2007)
• 1.2.10 Summary Information - Videotron - Canada (2007)
• 1.2.11 Latin American Demographic Trends
• 1.3.1 Contrasting Trends during the Business Cycle
• 2.1.1 Specifications - 40Gbit DQPSK Modulator (Source: Sumitomo)
• 2.2.1 Sample AOM specifications
• 4.2.1 Competitive Global Market Share Estimates, Optical Modulators, 2006
• 7.1.1 Optical Modulator Data Base Categories, by Technology Type
• 7.1.2 Optical Modulator Data Base Categories, by Associated Transmitter Data Rate