2009 Picoprojector Report

2009 Picoprojector Report published by Insight Media in October, 2009. This report consists of Pages 301 and the price starts from US $ 2000.

Introduction

Abstract

The Need:

After several years of development, picoprojector products arrived on the market in 2008. This new product category has had modest sales in 2008 and to date in 2009. There is a need to examine this emerging market carefully to see how it is likely to develop further, who is likely to buy these projectors, how the picoprojectors will be used and what prices end-users are likely to pay. This information is needed for product planning by component vendors, the picoprojector manufacturers and organizations like mobile data service providers that will be selling picoprojectors.

Report Objective:

This report attempts to give product planners and technologists a view of the current and forecast status of all aspects of the picoprojector ecosystem. This includes components such as light sources and image generators, picoprojector modules, additional sub-systems needed to build a picoprojector, current picoprojector markets and applications and future picoprojector progress. The report also covers the business models, economics and structure of the picoprojector industry. Since picoprojectors are not the only technology addressing some key markets, the report gives an overview of competitive technologies that may take away some of the picoprojector market share.

The study period of this report covers the time period from the present through 2014.

This 301 page 2009 Picoprojector Report is not just an update of the 108-page 2008 report, it is a complete rewrite and reflects the many changes and advancements in the picoprojector industry. The key advancement, of course, was the introduction of picoprojector products into the marketplace.

• Descriptions of the key sub-markets within the expected pico-projector market.
• Presentation of an end user survey to determine how picoprojectors are actually used and what improvements end users would like to see.
• Analysis of the human factors of picoprojectors, including resolution, colorimetry and other factors.
• Guidance on the choice of LED and laser wavelengths.
• Discussion and forecasts of RGB LED, white LED and laser technology as it applies to picoprojectors.
• Description of the technologies used to generate the image in a picoprojector, including several emerging technologies. Key technologies, including color sequential and color filter LCoS, DLP and scanning mirror approaches are discussed in special detail.
• Evaluation and forecasts of battery technology for picoprojectors.
• Evaluation of the connectivity requirements for picoprojectors and what connection technologies and standards can meet these requirements.
• Discussion and forecasts for other markets that can use picoprojector-type technology.
• Forecast performance and BOM cost estimates for both laser and LED-based picoprojectors using all major image source technologies, including validation examples of currently available products.
• Estimated unit sales to date of all picoprojectors.
• Forecasts through 2014 of the total picoprojector unit sales.
• Forecasts through 2014 of the revenue generated by picoprojector module sale.
• Forecasts through 2014 for the total picoprojector industry revenues.
• List of most picoprojector models introduced in the March 2008 - October 2009 time frame in order of introduction date, with a comment on each.
• Identification of the key players in the picoprojector field.
• Evaluation of competitive technologies that could cut into the expected picoprojector market.
• SWOT analysis of key picoprojector technologies and components.

Methodology:

The technical and marketing information in this report are based on multiple sources, including:

• Discussions with key people in the picoprojector, microdisplay, laser and LED industries.
• Trade show visits
• Company visits
• News reports and company press releases
• Information and forecasts from other Analysts

Information on Lasers and LEDs used in this report has been updated since the 2007 Insight Media Laser Projection Report and the 2008 Insight Media LED Report were issued. These updates were based on news reports (many of which were published in Insight Media newsletters) and discussions with key players in the laser, LED and picoprojector industries.

Forecasts for picoprojectors going forward were based on a number of inputs including:

• Estimated 2008 and 2009 unit sales and retail prices of picoprojectors
• Estimates and forecasts of the Total Available Market (TAM) for picoprojectors
• Historical yearly sales rates for consumer electronics into the TAM
• Market Acceptance Evaluation for the years 2008, 2010, 2012 and 2014. This was done to compare to the forecast penetration rate into the TAM and to validate the observed penetration rate.

The Expected, Optimistic and Conservative forecasts were further categorized by:

• Module total power consumption
• Embedded vs. Accessory picoprojector
• Light source technology
• Microdisplay or other image source technology.

Who Should Buy:

• This report should be purchased by anyone designing or manufacturing picoprojectors or modules or components for picoprojectors.
• Companies expecting to sell or use pico-projectors. This includes all companies involved in mobile data services.
• The report is of value to people planning research, development or products utilizing laser or LED illumination for picoprojectors or other small projectors.
• Engineers and researchers involved in laser or LED projection systems.
• Investors looking for information to support due diligence

Report Statistics

• Date of Release: October 2009
• Author: Matthew Brennesholtz
• Number of Pages: 301
• Number of Figures: 163 (Many with attached data tables)
• Number of Tables: 73
• Deliverable: PDF file

About the Author:

The principal author of the 2009 Pico-Projector Market Segment Analysis is Matthew Brennesholtz.

Matthew Brennesholtz has worked in the display field since receiving his Masters of Engineering degree from Cornell University in 1978. He has worked on direct view CRT systems and projection systems based on CRTs, oil-film light valves, DMDs, LCDs and LCoS. In addition to system level work, he was involved in the design and testing of optical components for these systems. Currently he is at Insight Media providing consulting and other services to the display industry. He has followed the picoprojector industry since the emergence of the first proposals for the technology in 2005.

Table of Contents

1. Introduction & Executive Summary

• 1.1. Introduction: What is a Picoprojector?
• 1.2. Executive Summary
  • 1.2.1. Markets
  • 1.2.2. Human Factors
  • 1.2.3. Technology
    • 1.2.3.1. Image Sources
    • 1.2.3.2. Light Sources
    • 1.2.3.3. Other Picoprojector Technologies
  • 1.2.4. Forecasts
• 1.3. Conclusions

2. Description of the Current Market

• 2.1. What is a Picoprojector?
• 2.2. Key R&D Issues
• 2.3. Who Is Buying Picoprojectors and Why?
  • 2.3.1. Expected Picoprojector Markets
  • 2.3.2. Survey of Picoprojector End-Users
    • 2.3.2.1. Survey Demographics
    • 2.3.2.2. About the Picoprojectors Used by Responders
    • 2.3.2.3. Picoprojector Application and Use
    • 2.3.2.4. User Satisfaction and Desired Improvements
  • 2.3.3. Key Take-Aways From the Survey
• 2.4. Picoprojectors Currently on the Market
• 2.5. Key Market Trends
  • 2.5.1. Handheld Devices
  • 2.5.2. Picoprojectors with Portable and Desktop Systems
  • 2.5.3. Other Markets for Picoprojector Modules
    • 2.5.3.1. Industrial Applications
    • 2.5.3.2. Medical Applications
    • 2.5.3.3. Automotive Applications
    • 2.5.3.4. Aviation
    • 2.5.3.5. Toy Projectors
  • 2.5.4. Likely Picoprojector Enhancements
    • 2.5.4.1. Ultimate Integration
• 2.6. Market Pull vs Technology Push
• 2.7. Shortcomings of Current Displays
• 2.8. Shape of the Industry
• 2.9. Technologies In Competition with Picoprojectors
  • 2.9.1. Direct View Displays
  • 2.9.2. Mobile Companions
  • 2.9.3. Low-lumen Ultraportable Projectors
  • 2.9.4. Rollable, e-Paper and Reflective Displays
  • 2.9.5. Head Mounted Displays

3. Picoprojector Requirements

• 3.1. Key Picoprojector Requirements
  • 3.1.1. Integrated Projectors
  • 3.1.2. Accessory Projectors
• 3.2. Picoprojector Human Factors
  • 3.2.1. Resolution
  • 3.2.2. Picoprojector Colorimetry
  • 3.2.3. Projector Luminance, Image Brightness, Image Size and Contrast
    • 3.2.3.1. Helmholtz-Kohlrausch Effect
    • 3.2.3.2. Portable Projection Screens

4. Picoprojector Technology

• 4.1. Etendue and Power Limited Picoprojector Systems
  • 4.1.1. Etendue Limitations
  • 4.1.2. Power Limitations
• 4.2. Image Sources
  • 4.2.1. Single Scanning Mirror
  • 4.2.2. Two Scanning Mirrors
  • 4.2.3. Color Sequential Transmissive LCD
  • 4.2.4. DLP
  • 4.2.5. LCoS CFA
  • 4.2.6. Color Sequential LCoS
    • 4.2.6.1. Micron (Formerly Displaytech)
    • 4.2.6.2. Syndiant
    • 4.2.6.3. Aurora
    • 4.2.6.4. Himax
    • 4.2.6.5. Phase Modulation Projection
  • 4.2.7. Transmissive LCD
• 4.3. Illumination Sources for Picoprojectors
  • 4.3.1. Polarization and Collection Efficiency
  • 4.3.2. RGB LED Illumination
  • 4.3.3. White LED Illumination
  • 4.3.4. Laser Illumination
• 4.4. Power for Picoprojectors
  • 4.4.1. General Power Requirements
  • 4.4.2. Batteries for Picoprojectors
• 4.5. Picoprojector/Source Connectivity
  • 4.5.1. Wired Connections
  • 4.5.2. Wireless Connections
  • 4.5.3. Internal Connections

5. SWOT Analysis

• 5.1. Image Sources
• 5.2. Illumination Sources
• 5.3. Imaging Arrangements

6. BOM Costs

• 6.1. BOM Methodology
  • 6.1.1. Production Volume and Existing vs Optimized Components
  • 6.1.2. BOM Estimates for Modules Intended to be Embedded in Systems
  • 6.1.3. BOM Estimates for Accessory Picoprojectors
  • 6.1.4. Integrating a Picoprojector Module into Other Systems
• 6.2. BOMs For Validation
• 6.3. Viable Technology Combinations
• 6.4. DLP BOMs
• 6.5. Color Sequential LCoS BOMs
• 6.6. Holographic Color Sequential LCoS BOMs
• 6.7. LCoS Color Filter Array BOMs
• 6.8. Raster Scanned Mirror BOMs
• 6.9. Spatial LCD (Display Photonic) BOMs
• 6.10. BOM Summary
• 6.11. BOM Conclusions

7. Forecasts

• 7.1. Forecast Methodology
• 7.2. Yearly Sales Rates
• 7.3. Total Available Market (TAM)
• 7.4. Roadmap for Forecast
• 7.5. Market Acceptance Evaluation
• 7.6. Expected, Optimistic and Conservative Forecasts
  • 7.6.1. Forecast Drivers and Assumptions
  • 7.6.2. Starting Sales Basis
  • 7.6.3. Sales Level Evolution
  • 7.6.4. Expected Picoprojector Module Forecast
  • 7.6.5. Optimistic and Conservative Forecasts
• 7.7. Forecast Breakdown by Sub-Categories
  • 7.7.1. Forecast Breakdown by Embedded vs Accessory
  • 7.7.2. Forecast Breakdown by Power Consumption
  • 7.7.3. Forecast Breakdown by Imager Technology
  • 7.7.4. Forecast Breakdown by Light Source Technology
• 7.8. Picoprojector Industry Revenue Forecasts
  • 7.8.1. Picoprojector Price Forecasts
  • 7.8.2. Module Revenue Forecast
  • 7.8.3. Industry Revenue Forecast
• 7.9. Forecasts for Other Applications of Picoprojector Technology
  • 7.9.1. Unit Forecasts for Other Applications
  • 7.9.2. Revenue Forecasts for Other Applications
• 7.10. Forecast Summary and Conclusions

8. Appendix

• 8.1. Picoprojectors on the Market
• 8.2. Players in the Picoprojector Market
  • 8.2.1. Other Likely Players

Table of Figures

• Figure 1: Picoprojectors at Amazon.com
• Figure 2: Picoprojector Integration
• Figure 3: Conservative, Expected and Optimistic Sales of Picoprojectors
• Figure 4: Expected Unit Sales of Picoprojectors by Power
• Figure 5: Projector Categories Based on Lumen Output
• Figure 6: Publicity Photo of Integrated Picoprojectors
• Figure 7: Respondents by Region
• Figure 8: Respondents by Age
• Figure 9: Respondents by Working Environment
• Figure 10: Use of Other Projector Types
• Figure 11: Other Projector Types Used
• Figure 12: Where Picoprojectors Were Purchased
• Figure 13: Who Purchased the Picoprojectors
• Figure 14: Price Paid for the Picoprojectors
• Figure 15: Picoprojector Power Source
• Figure 16: Picoprojector Resolution
• Figure 17: Picoprojector Use Category
• Figure 18: Picoprojector Use Frequency
• Figure 19: Picoprojector Use Duration
• Figure 20: Picoprojector Use Location
• Figure 21: Type of Projection Surface
• Figure 22: Expected Content Type
• Figure 23: Actual Content Type
• Figure 24: Satisfaction with Lumen Output
• Figure 25: Satisfaction with Resolution
• Figure 26: Features Liked Best by Respondents
• Figure 27: Desired Improvements
• Figure 28: Photos of a Working Companion Picoprojector with Generated Image
• Figure 29: Photos of Integrated Projector/Cell Phones
• Figure 30: Photo of Picoprojectors from BeamBox and AAXA
• Figure 31: Apple iPhone Handheld Device
• Figure 32: $70 Projector Clock from Oregon Scientific
• Figure 33: Structured Light For Shape Determination
• Figure 34: Luminetx VeinViewer
• Figure 35: Automotive Applications for Picoprojector Modules
• Figure 36: LED-Based Avionic Display (after salt spray test) from Scram Technologies
• Figure 37: Toy Projector from Jakks Pacific
• Figure 38: Two $70 Digital Cameras
• Figure 39: Image Produced by an MPro-110
• Figure 40: Virtual Keyboard from I-Tech
• Figure 41: Virtual Touchpad from Funai
• Figure 42: Golden-i Gen 2 Demonstration Unit from Kopin
• Figure 43: Advertisement for a Knock-off iPhone
• Figure 44: Chocolate Handset (LG-BL40) from LG
• Figure 45: Red Fly CN8 Mobile Companion
• Figure 46: Dell M109s Low-Lumen Ultraportable Projector
• Figure 47: Polymer Vision Readius Rollable Display
• Figure 48: Sony Concept Laptop with OLED Display
• Figure 49: Plastic Logic e-Book Reader
• Figure 50: Sunlight Readable Netbook Display from Pixel Qi
• Figure 51: Myvu Personal Eyewear with Video iPod
• Figure 52: Personal Display Glasses from Mobintech
• Figure 53: Nikon Coolpix S1000pj
• Figure 54: Example Pixel Layouts
• Figure 55: Raster Types
• Figure 56: Colorimetry of LED Projectors
• Figure 57: LED Power Required as Red Wavelength Varies
• Figure 58: LED Power Required as Green Wavelength Varies
• Figure 59: LED Power Required as Blue Wavelength Varies
• Figure 60: Laser Power Required as Red Wavelength Varies
• Figure 61: Laser Power Required as Green Wavelength Varies
• Figure 62: Laser Power Required as Blue Wavelength Varies
• Figure 63: Brightness Enhancement of LED vs Lamp Projectors
• Figure 64: Portable Screen Used with an Ultraportable Projector
• Figure 65: High-gain Screen Used with an Ultraportable Projector
• Figure 66: Etendue Definition
• Figure 67: Etendue with uniform cone angle
• Figure 68: Etendue conservation with a simple lens
• Figure 69: Microvision Bi-axial Mirror Scanner
• Figure 70: Two Scanning Mirror System from bTendo
• Figure 71: Citizen Finetech Miyota Transmissive LCoS Microdisplays
• Figure 72: DLP Imagers and ASICs Optimized for Picoprojectors
• Figure 73: Projection Module from Sypro with the nHD Imager
• Figure 74: Picoprojector Module with Himax CFA Panel
• Figure 75: Pulse Width Modulation
• Figure 76: Micron Imagers
• Figure 77: Block Diagrams for Micron Imagers
• Figure 78: Syndiant W/SVGA Compared to TI DLP HVGA Pico Imager
• Figure 79: Syndiant W/SVGA Connectivity Compared to TI DLP HVGA Pico Imager
• Figure 80: Web Page Image Projected by a Syndiant SYL2010 Imager
• Figure 81: "Vienna" Color Sequential LCoS Panel from Aurora
• Figure 82: Himax Color Sequential LCoS Panels
• Figure 83: Driving Himax CS LCoS Panels
• Figure 84: Layout of a Light Blue Optics Projector
• Figure 85: Hologram, Subframe and Frame in a LBO Projector
• Figure 86: Block Diagram of Display Photonic Systems Architecture
• Figure 87: Transmissive LCD Panels for the Display Photonic Systems Architecture
• Figure 88: Display Photonic Systems Demonstration Unit
• Figure 89: Polarization Recycling in the MM200 Module from 3M
• Figure 90: LED Light Collection with a Color-combining Prism from Syndiant
• Figure 91: LED combiner from Optoma PK-101
• Figure 92: Two Channel illumination path
• Figure 93: Typical Non-Linearities of LEDs
• Figure 94: Spectra of the Osram Oslon LX Series
• Figure 95: White LED from 3M MPro 110 Projector
• Figure 96: Red Light Increased by Recycling
• Figure 97: RGB Laser Module from Osram
• Figure 98: Green Laser Package from Spectralus
• Figure 99: Detail of a RGB Laser Combiner from Microvision
• Figure 100: Laser Beam Integrator
• Figure 101: Example Lithium Ion Polymer Batteries
• Figure 102: Batteries for Integrated and Companion Projectors
• Figure 103: Unit Prices of Batteries Suited for Ultraportable Projectors
• Figure 104: Forecast Prices for Lithium Ion Polymer Batteries in 10K/Month Volume
• Figure 105: Estimated weights for Lithium Ion Polymer Batteries
• Figure 106: Block Diagram for a Himax Picoprojector Module
• Figure 107: Block Diagram for an Embedded Picoprojector Module
• Figure 108: Picoprojectors with iPod Docks
• Figure 109: USB 2.0 A/B sockets
• Figure 110: SWOT Analysis
• Figure 111: Yearly Sales Rates for Products with Various Success Levels
• Figure 112: Picoprojector WW Total Available Market (TAM)
• Figure 113: Sample Market Acceptance Evaluation
• Figure 114: Product Assessment Using the Evaluation Chart
• Figure 115: Market Acceptance Evaluation for 2008
• Figure 116: Market Acceptance Evaluation for 2010
• Figure 117: Market Acceptance Evaluation for 2012
• Figure 118: Market Acceptance Evaluation for 2014
• Figure 119: Expected Picoprojector Module Yearly Sales Rates into the TAM
• Figure 120: Picoprojector Module Expected Forecast
• Figure 121: Optimistic Picoprojector Module Yearly Sales Rates into the TAM
• Figure 122: Conservative Picoprojector Module Yearly Sales Rates into the TAM
• Figure 123: Picoprojector Optimistic, Expected and Conservative Module Forecasts
• Figure 124: Embedded vs Accessory Unit Market Share: Conservative
• Figure 125: Embedded vs Accessory Unit Market Share: Expected
• Figure 126: Embedded vs Accessory Unit Market Share: Optimistic
• Figure 127: Picoprojector Conservative Forecast Embedded vs Accessory
• Figure 128: Picoprojector Expected Forecast Embedded vs Accessory
• Figure 129: Picoprojector Optimistic Forecast Embedded vs Accessory
• Figure 130: Picoprojector Conservative Forecast by Module Power Levels
• Figure 131: Picoprojector Expected Forecast by Module Power Levels
• Figure 132: Picoprojector Optimistic Forecast by Module Power Levels
• Figure 133: Picoprojector Conservative Forecast by Imaging Technology
• Figure 134: Picoprojector Expected Forecast by Imaging Technology
• Figure 135: Picoprojector Optimistic Forecast by Imaging Technology
• Figure 136: Picoprojector Conservative Forecast by Light Source Technology
• Figure 137: Picoprojector Expected Forecast by Light Source Technology
• Figure 138: Picoprojector Optimistic Forecast by Light Source Technology
• Figure 139: Conservative OEM Module Revenue Forecast by Power Level
• Figure 140: Expected OEM Module Revenue Forecast by Power Level
• Figure 141: Optimistic OEM Module Revenue Forecast by Power Level
• Figure 142: Picoprojector Conservative Industry Revenue
• Figure 143: Picoprojector Expected Module Industry Revenue
• Figure 144: Picoprojector Optimistic Industry Revenue
• Figure 145: Expected Forecast of Picoprojector Modules for Other Applications
• Figure 146: Expected Picoprojector Module Transfer Price for Other Applications
• Figure 147: Expected Price Forecast of Picoprojectors for Other Applications
• Figure 148: Expected Module Transfer Revenue Forecast for Other Applications
• Figure 149: Expected Total Industry Revenue Forecast for Other Applications
• Figure 150: Optimistic, Expected and Conservative Unit Forecast for Other Applications
• Figure 151: Optimistic, Expected and Conservative Module Revenue for Other Applications
• Figure 152: Optimistic, Expected and Conservative Industry Revenue for Other Applications
• Figure 153: Total Expected Picoprojector Module Unit Sales
• Figure 154: Total Conservative Picoprojector Module Unit Sales
• Figure 155: Total Optimistic Picoprojector Module Unit Sales
• Figure 156: Total Expected Picoprojector Module Industry Revenue
• Figure 157: Total Conservative Picoprojector Module Industry Revenue
• Figure 158: Total Optimistic Picoprojector Module Industry Revenue
• Figure 159: Total Expected Picoprojector Industry Revenue
• Figure 160: Total Conservative Picoprojector Industry Revenue
• Figure 161: Total Optimistic Picoprojector Industry Revenue
• Figure 162: Four Sample Picoprojectors from CES 2008
• Figure 163: Five Sample Picoprojectors from CES 2009

Table of Tables

• Table 1: Key Specifications of a Picoprojector Module
• Table 2: Projector Categories that Could use Laser and LED Illumination
• Table 3: Products That Could Embed or Connect to Picoprojectors
• Table 4: Top Smart Phone Handset Vendors
• Table 5: User Costs for a iPhone Handheld Device
• Table 6: Picoprojector Human Factors Unknowns
• Table 7: Possible Picoprojector Pixel Counts
• Table 8: Optimum and Acceptable Peak LED Wavelengths for Displays
• Table 9: Optimum and Acceptable Laser Wavelengths for Displays
• Table 10: Illumination from Various Sources
• Table 11: Example Maximum Image Sizes From a Picoprojector
• Table 12: Example Etendues
• Table 13: Comparison of Microdisplay/Scanning Device Suppliers
• Table 14: Imaging Technologies no Longer Considered for Picoprojectors
• Table 15: Imaging Technologies Not Seriously Considered for Picoprojectors
• Table 16: Input Formats for Micron Imagers
• Table 17: Picoprojector Power Consumption Categories
• Table 18: Estimated Prices for 4, 7 and 14 Watt-Hour Batteries
• Table 19: Advantages and Disadvantages of Various Wired Formats
• Table 20: Advantages and Disadvantages of Various Wireless Formats
• Table 21: SWOT Analysis for DLP Microdisplays
• Table 22: SWOT Analysis for Color Sequential LCoS Microdisplays
• Table 23: SWOT Analysis for Color Filter Array LCoS Microdisplays
• Table 24: SWOT Analysis for Scanned Mirror Devices
• Table 25: SWOT Analysis for RGB LEDs
• Table 26: SWOT Analysis for Lasers
• Table 27: SWOT Analysis for White LEDs
• Table 28: SWOT Analysis for Direct Imaging
• Table 29: SWOT Analysis for Phase Control (Holographic) Imaging
• Table 30: SWOT Analysis for Scanning Systems
• Table 31: SWOT Analysis for Spatial LCD Systems
• Table 32: VGA CFA Picoprojector with Himax Panel & White LEDs
• Table 33: HVGA DLP Picoprojector with TI Pico Panel & RGB LEDs
• Table 34: VGA CS Picoprojector with Micron Panel &RGB LEDs
• Table 35: SVGA Picoprojector with Syndiant Panel and Lasers
• Table 36: WVGA Scanned Laser Picoprojector with Microvision Scanner
• Table 37: Technology Combinations for Picoprojectors
• Table 38: BOM for a RGB LED HVGA DLP System at 1.5W
• Table 39: BOM for a RGB LED nHD DLP System at 4.5W
• Table 40: BOM for a RGB LED WVGA DLP System at 9W
• Table 41: BOM for a Laser DLP HVGA System at 1.5W
• Table 42: BOM for a Laser nHD DLP System at 4.5W
• Table 43: BOM for a Laser WVGA DLP System at 9W
• Table 44: BOM for a RGB LED Color Sequential LCoS at 1.5W
• Table 45: BOM for a RGB LED Color Sequential LCoS at 4.5W
• Table 46: BOM for a RGB LED Color Sequential LCoS at 9W
• Table 47: BOM for a Laser Color Sequential LCoS at 1.5W
• Table 48: BOM for a Laser Color Sequential LCoS at 4.5W
• Table 49: BOM for a Laser Color Sequential LCoS at 9W
• Table 50: BOM for a Holographic LCoS system at 1.5W
• Table 51: BOM for a Holographic LCoS system at 4.5W
• Table 52: BOM for a Holographic LCoS system at 9W
• Table 53: BOM for a Color Filter Array LCoS at 1.5W
• Table 54: BOM for a Color Filter Array LCoS at 4.5W
• Table 55: BOM for a Color Filter Array LCoS at 9W
• Table 56: BOM for a 12 Lumen Scanned Mirror System
• Table 57: BOM for a 24 Lumen Scanned Mirror System
• Table 58: BOM for a WLED Spatial LCD System at 1.5W
• Table 59: BOM for a WLED Spatial LCD System at 4.5W
• Table 60: BOM for a WLED Spatial LCD System at 9W
• Table 61: Summary for 1.5W Picoprojector Modules
• Table 62: Summary for 4.5W Picoprojector Modules
• Table 63: Summary for 9W Picoprojector Modules
• Table 64: Roadmap of Events Expected to Affect Picoprojector Yearly Sales Rates
• Table 65: Resolution Roadmap and Forecast
• Table 66: Market Acceptance Evaluation Parameters
• Table 67: Estimates of 2008 and 2009 Picoprojector Sales
• Table 68: Shift Toward "Unconventional" Light Engine Designs
• Table 69: OEM Transfer Price Forecast of Picoprojector Modules
• Table 70: Retail Price Increment Forecast of Picoprojector Modules
• Table 71: Price Forecast of Accessory Picoprojectors
• Table 72: Commercially Available Picoprojectors
• Table 73: Known Players in the Picoprojector Business

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