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LEDs in Medical/Science Devices Global Market Forecast & Analysis February 2015

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This report by ElectroniCast Consultants provides the research findings of our study of the worldwide consumption of packaged Light Emitting Diodes (LEDs), in Scientific and Medical Devices. This report provides global market data covering the years 2014-2024.

The market data are segmented into the following geographic regions, plus a Global summary:

• North, Central and South America (America)
• Europe, plus Middle Eastern and African countries (EMEA)
• Asia Pacific (APAC)

The LED market is segmented into the following sub-application categories:

• Sensing/Detection and Analytical/Monitoring
• Photo-therapy/Sanitation/Cell Regeneration/Curing
• Instrumentation Light Source and Imaging

The market data for are also segmented by the following colors (type):

• Red
• Green
• Blue
• White
• Multiple Color/Multiple Chip
• UV and Other

The term biophotonics denotes a combination of biology and photonics, with photonics being the science and technology of generation, manipulation, and detection of photons, quantum units of light.

Biophotonics has become the established general term for all techniques that deal with the interaction between biological items and photons. This refers to emission, detection, absorption, reflection, modification, and creation of radiation from biomolecular, cells, tissues, organisms and biomaterials. Areas of application are life science, medicine, agriculture, and environmental science.

Similar to the differentiation between "electric" and "electronics" a difference can be made between applications, which use light mainly to transfer energy via light (such as therapy or surgery) and applications which excite matter via light and transfer information back to the operator (like diagnostics). In most cases the term biophotonics is only referred to the second case; however, in this ElectroniCast study, we cover both uses of the LED packaged chips in medical, biophotonics and other related science:

• Use light mainly to transfer energy via light (such as therapy or surgery)

• Applications which excite matter via light and transfer information back to the operator, such as diagnostics

LED Level Quantified in the ElectroniCast Study Below, are five levels (or “food chain”) of LEDs. For the purposes of THIS ElectroniCast study, we quantify and provide a market forecast for “Level 2”

Level 1 - The chip or die
Level 2 - The Packaged LED
Level 3 - LED array; may include optics, heat sink, other components
Level 4 - Lamp (consumer-level bulb)
Level 5 - LED luminaire (light fixture/light fitting)

This report provides the market data by the following functions:

• Consumption Value (US$, million)
• Quantity (number/units)
• Average Selling Prices (ASP $, each)

The value is determined by multiplying the number of units by the average selling price (ASP). The ASPs are based on the price of the packaged LED at the initial factory level. The value is then based on the end-use application and the end-use region.

Information Base for the Market Forecast

Primary Research

This study is based on analysis of information obtained continually over the past several years, but updated through the beginning of February 2015. During this period, ElectroniCast analysts performed interviews with authoritative and representative individuals in the following sectors relative to the use of LEDs: medical, science, bio-photonic, display industry, test/measurement, instrumentation, R&D, university, military defense and government. The interviews were conducted principally with:

• Engineers, marketing personnel and management at manufacturers of LED test/measurement & medical science equipment/devices and related equipment, as well as other technologies

• Design group leaders, engineers, marketing personnel and market planners at major users and potential users of LEDs and test/measurement & medical science equipment/devices

• Other industry experts, including those focused on standards activities, trade associations, and investments.

The interviews covered issues of technology, R&D support, pricing, contract size, reliability, documentation, installation/maintenance crafts, standards, supplier competition and other topics.

Analysis

The analyst then considered customer expectations of near term growth in their application, plus forecasted economic payback of investment, technology trends and changes in government regulations in each geographical region, to derive estimated growth rates of quantity and price of each product subset in each application. These forecasted growth rates are combined with the estimated baseline data to obtain the long-range forecasts at the lowest detailed level of each product and application.

Secondary Research

A full review of published information was also performed to supplement information obtained through interviews. The following sources were reviewed:

• Professional technical journals, papers and conference proceedings
• Trade press articles
• Company profile and financial information; Product literature
• Additional information based on previous ElectroniCast market studies
• Personal knowledge of the research team

In analyzing and forecasting the complexities of geographical regional markets, it is essential that the market research team have a good and a deep understanding of the technology and of the industry. ElectroniCast members who participated in this report were qualified.

Bottom-up Methodology

ElectroniCast forecasts, as illustrated in the forecast data structure, are developed initially at the lowest detail level, then summed to successively higher levels. The background market research focuses on the amount of each type of product used in each application in the base year (2014), and the prices paid at the first transaction from the manufacturer. This forms the base year data. ElectroniCast analysts then forecast the growth rates in component quantity use in each application, along with price trends, based on competitive, economic and technology forecast trends, and apply these to derive long term forecasts at the lowest application levels. The usage growth rate forecasts depend heavily on analysis of overall end user trends applicable products/applications and equipment usage and economic payback.

Cross-Correlation Increases Accuracy

The quantities of packaged LEDs, LED Driver ICs, LED materials/wafer/die/chips, LED Lamps and LED fixtures (luminaries) and other LED-based components, manufacturing processes/quality control/yields, and end-use products used in a particular application are interrelated. Since ElectroniCast conducts annual analysis and forecast updates in each LED component field, accurate current quantity estimates are part of the corporate database. These quantities are cross-correlated as a "sanity check".

ElectroniCast, each year since 2002, has conducted extensive research and updated their forecasts of several LED lighting categories. As technology and applications have advanced, the number of component subsets covered by the forecasts has expanded impressively.

The calculation and analysis data spreadsheet technique is based upon input/output analysis, leveraging the quantitative consumption quantity, price and value of each item in each application at all levels to achieve reasonable quantitative conclusions; this interactive analysis concept, first applied on a major scale by Leonteff, of the US Department of Commerce, in the mid 1950s, was then adopted successfully by analyst/forecasting firms Quantum Science, Gnostic Concepts and (in 1981) by ElectroniCast.

1. LEDs Used in Biophotonic and Medical Devices Executive Summary 1-1
 1.1 Overview 1-1
 1.2 Bare (Unpackaged) LED Chips – Overview 1-11
 2. LEDs – Technology Overview 2-1
 3. LEDs Used in Biophotonic and Medical Devices Market Forecast 3-1
 3.1 Overview 3-1
 3.2 Sensing/Detection and Analytical/Monitoring 3-9 3-
 3.3 Photo-therapy/Sanitation/Cell Regeneration/Curing 3-114
 3.4 Instrumentation Light Source and Imaging 3-159
 4. Fiber Optic Sensor Technology 4-1
 4.1 Overview 4-1
 4.2 Interferometric Fiber Optic Sensors 4-6
 4.3 Intensity Fiber Optic Sensors 4-28
 4.4 Polarization Fiber Optic Sensors 4-31
 4.5 Fiber Bragg Grating (FBG) Fiber Optic Sensors 4-35
 4.6 Raman Scattering Fiber Optic Sensors 4-59
 4.7 Fluorescence Fiber Optic Sensors 4-66
 4.8 Brillouin Scattering Fiber Optic Sensors 4-78
 4.9 Doppler Anemometry 4-81
 4.10 Spectroscopy 4-85
 4.11 Waveguides Fiber Optic Sensors 4-95
 4.12 Optrode 4-131
 4.13 List of Fiber Optic Sensor and Related Companies (over 130 companies listed with web-links) 4-144 4-144
 5. Company Profiles of Pulse Oximeter Suppliers (47-companies) 5-1 5-1
 6. Market Research Methodology 6-1
 7. Definitions and Standards (LEDs) 7-1
 7.1 Acronyms, Abbreviations, and General Terms 7-1
 7.2 Lighting Standards and Protocols 7-73
 8. Market Forecast Data Base 8-1
 8.1 Overview 8-1
 8.2 Tutorial 8-3
 
 Addendum
 Excel Data Base Spreadsheets (Global Market Forecast)
 Detailed Data: ASP ($, each); Quantity (Million); Value ($, Million) for all Regions
 Power Point Market Data Figures (Global Market Forecast) 


List Of Tables

1.1.1 LEDs in Medical/Science Devices Global Forecast, By Application ($, Million) 1-4
 2.1 LED Color Variety – Selected Examples 2-11
 2.2 LED Color Chart 2-13
 3.1.1 LEDs in Medical/Science Devices Global Forecast, By Application ($, Million) 3-4
 3.1.2 LEDs in Medical/Science Devices Global Forecast, By Application (Quantity/Units) 3-5
 3.1.3 LEDs in Medical/Science Devices America Forecast, By Application ($, Million) 3-6
 3.1.4 LEDs in Medical/Science Devices America Forecast, By Application (Quantity/Units) 3-6
 3.1.5 LEDs in Medical/Science Devices EMEA Forecast, By Application ($, Million) 3-7
 3.1.6 LEDs in Medical/Science Devices EMEA Forecast, By Application (Quantity/Units) 3-7
 3.1.7 LEDs in Medical/Science Devices APAC Forecast, By Application ($, Million) 3-8
 3.1.8 LEDs in Medical/Science Devices APAC Forecast, By Application (Quantity/Units) 3-8
 3.2.1 LEDs in Sensing/Detection and Analytical/Monitoring Global Forecast, By Application ($, Million) 3-9
 3.2.2 LEDs in Sensing/Detection and Analytical/Monitoring Global Forecast, By Application (Quantity) 3-10
 3.2.3 LEDs in Sensing/Detection and Analytical/Monitoring America Forecast, By Application ($, Million) 3-11
 3.2.4 LEDs in Sensing/Detection and Analytical/Monitoring America Forecast, By Application (Quantity) 3-11
 3.2.5 LEDs in Sensing/Detection and Analytical/Monitoring EMEA Forecast, By Application ($, Million) 3-12
 3.2.6 LEDs in Sensing/Detection and Analytical/Monitoring EMEA Forecast, By Application (Quantity) 3-12
 3.2.7 LEDs in Sensing/Detection and Analytical/Monitoring APAC Forecast, By Application ($, Million) 3-13
 3.2.8 LEDs in Sensing/Detection and Analytical/Monitoring APAC Forecast, By Application (Quantity) 3-13
 3.2.9 Strain Sensing Technology Attributes Summary 3-24
 3.3.1 LEDs in PDT/Sanitation/Cell Regeneration/Curing Global Forecast, By Application ($, Million) 3-115
 3.3.2 LEDs in PDT/Sanitation/Cell Regeneration/Curing Global Forecast, By Application (Quantity) 3-116
 3.3.3 LEDs in PDT/Sanitation/Cell Regeneration/Curing America Forecast, By Application ($, Million) 3-117
 3.3.4 LEDs in PDT/Sanitation/Cell Regeneration/Curing America Forecast, By Application (Quantity) 3-117
 3.3.5 LEDs in PDT/Sanitation/Cell Regeneration/Curing EMEA Forecast, By Application ($, Million) 3-118
 3.3.6 LEDs in PDT/Sanitation/Cell Regeneration/Curing EMEA Forecast, By Application (Quantity) 3-118
 3.3.7 LEDs in PDT/Sanitation/Cell Regeneration/Curing APAC Forecast, By Application ($, Million) 3-119
 3.3.8 LEDs in PDT/Sanitation/Cell Regeneration/Curing APAC Forecast, By Application (Quantity) 3-119
 3.3.9 Therapeutic Visible Light Spectrum 3-132
 3.4.1 LEDs in Instrumentation Light Source and Imaging Global Forecast, By Application ($, Million) 3-161
 3.4.2 LEDs in Instrumentation Light Source and Imaging Global Forecast, By Application (Quantity) 3-162
 3.4.3 LEDs in Instrumentation Light Source and Imaging America Forecast, By Application ($, Million) 3-163
 3.4.4 LEDs in Instrumentation Light Source and Imaging America Forecast, By Application (Quantity) 3-163
 3.4.5 LEDs in Instrumentation Light Source and Imaging EMEA Forecast, By Application ($, Million) 3-164
 3.4.6 LEDs in Instrumentation Light Source and Imaging EMEA Forecast, By Application (Quantity) 3-164
 3.4.7 LEDs in Instrumentation Light Source and Imaging APAC Forecast, By Application ($, Million) 3-165
 3.4.8 LEDs in Instrumentation Light Source and Imaging APAC Forecast, By Application (Quantity) 3-165


List Of Figures

1.1.1 LEDs in Medical/Science Devices Global Forecast ($, Million) 1-3
1.1.2 LEDs in Medical/Science Devices Global Forecast, By Application ($, Million) 1-5
1.1.3 LEDs in Medical/Science Devices Global Forecast, By Region ($, Million) 1-6
1.1.4 LEDs in Medical/Science Devices Global Forecast, By Color ($, Million) 1-7
1.1.5 LEDs in Medical/Science Devices America Forecast, By Color ($, Million) 1-8
1.1.6 LEDs in Medical/Science Devices EMEA Forecast, By Color ($, Million) 1-9
1.1.7 LEDs in Medical/Science Devices APAC Forecast, By Color ($, Million) 1-10
1.2.1 Diagram of a typical LED chip 1-11
1.2.2 Diagram of a typical LED chip 1-12
1.2.3 LED Chip Cross-Sectional Structure 1-13
1.2.4 Chip On Glass Cross-Sectional Structure 1-14
1.2.5 ESD Protection Diodes 1-15
1.2.6 Electrostatic Discharge Example 1-16
1.2.7 Chip-on-Board LED Technology 1-17
1.2.8 Single-die LED: 1000 lm at 100 lm/W at 3A 1-19
1.2.9 Four-die LED with Primary Optics 1-20
1.2.10 LED Packaged Chip 1-21
1.2.11 LED Packaged Chip 1-22
1.2.12 LED Packaged Chip Surface Mount Variations 1-23
1.2.13 Example of LED Packaged Chip: Flux (Component-Level Bulb) 1-24
1.2.14 Example of High Brightness LED Packaged Chip (Component-Bulb) 1-25
2.1 RPCVD Process Equipment 2-6
2.2 LED Chromatic Chart 2-12
2.3 Evolution of Research Emphasis During Technology Life Cycle 2-14
2.4 LED Chip: Metal Layer (Thin Film Technology) 2-20
2.5 Vertical LED Chip 2-21
2.6 AC LED Technology on a Wafer 2-22
2.7 Ultra High Bright LED Chip 2-23
2.8 LED Chip Design with Copper Alloy Thermal Conductivity 2-24
2.9 LED Chip Design – Sapphire vs. Copper Alloy 2-25
2.10 Ultra-Thin LED 2-27
2.11 Solid-State Lighting LED 2-28
2.12 LED Module with High Light Quality 2-29
2.13 LED Module with Low-Profile Rectangular Shape 2-30
2.14 Lumiramic Phosphor Technology: Thin Film Flip Chip (TFFC) technology 2-33
2.15 Next-Generation Light Emitting Diode Module 2-40
2.16 4-Leaded RGB LED 2-42
2.17 Basic Structure of a Deep-UV Light-Emitting Diode 2-46
2.18 Vertically Conducting Advanced LED Structure 2-47
2.19 AlGaInP LED Efficacy 2-49
2.20 Red Nitride Phosphors 2-51
3.1.1 LEDs in Medical/Science Devices Global Forecast ($, Million) 3-2
3.1.2 LEDs in Medical/ Science Devices Global Forecast (Quantity/Units) 3-3
3.2.1 Fabry-Perot Fiber-Optic Temperature-Sensor 3-26
3.2.2 Fiber Optic Temperature Sensor 3-28
3.2.3 Fiber Optic Cable with Temperature Sensor 3-29
3.2.4 Upgradeable Mulichannel Fibre Optic Thermometer 3-30
3.2.5 Pre-clinical Transducer with Fiber Coating 3-35
3.2.6 Sealed-Gauge Fiber Optic Pressure Sensors 3-36
3.2.7 Fiber Optic Sensor would be implanted through the skin 3-41
3.2.8 Optical Fibers Bundled with a Capillary Tube 3-43
3.2.9 Surgery Fiber Optic Sensor – Probe 3-47
3.2.10 Vibration optical fiber sensors classification 3-51
3.2.11 Fiber-optic Vibration & Displacement Sensor 3-57
3.2.12 Fiber Optic Position Sensor (FOPS) 3-58
3.2.13 Fiber Optic Position Sensor (FOPS) 3-63
3.2.14 Magneto-Optic Current Transformer for Protection (MOCT-P) 3-67
3.2.15 Mini-sensor measures magnetic activity in human brain 3-68
3.2.16 Microfiber Knot Resonator 3-71
3.2.17 Seven (7) wavelengths acquire blood constituent data 3-78
3.2.18 Seven (7) wavelengths acquire blood constituent data 3-78
3.2.19 Oximeters - Upgradable Technology Platforms 3-79
3.2.20 Automated Flying-Insect Detection System (AFIDS) 3-86
3.2.21 Non-invasive Sensing 3-88
3.2.22 FLIPPER - light-emitting diode excites fluorescence in the sample flow cell 3-92
3.2.23 Nano-sized "carbon dots" glow brightly when exposed to light 3-95
3.2.24 Variable wavelength HPLC/CE detector 3-101
3.2.25 Led-Based Direct Visualization of Tissue Fluorescence 3-112
3.2.26 LED-Based Cell Phone Sensor for Detection of E. coli 3-113
3.3.1 Handheld LED Light Therapy Rejuvenation Device 3-127
3.3.2 Neonatal Phototherapy Treatment (Blue LEDs) 3-129
3.3.3 Light doses range in LED Phototherapy 3-131
3.3.4 Skin treatment therapies Utilizing LED Photo-modulation: Typical LED array (Red) 3-135
3.3.5 Blue LED Arrays 3-139
3.3.6 Apparatuses Containing Arrays of LEDs 3-145
3.3.7 UV LED Disinfection 3-156
3.4.1 LEDs – Different Colors for Fluorescence Microscopy Applications 3-166
3.4.2 LED versus Tungsten used in Slit Lamps Retina Observation 3-170
3.4.3 Red, Green and Blue LED Light Sources – Biophotonics 3-171
3.4.4 Ring Light 3-173
3.4.5 LED-Based Fiber Optic Illuminator 3-174
3.4.6 LED-Based Fiber Optic Illuminator 3-175
4.2.1 Schematic Drawing: Fiber-optic Fabry-Perot Interferometers 4-10
4.2.2 Schematic Drawing: Fiber-optic Fabry-Perot Interferometers 4-11
4.2.3 All-Fiber Michelson interferometer 4-12
4.2.4 Measurement of Micron-Scale Deflections 4-13
4.2.5 Michelson Type-Interferometer with Improvements 4-18
4.2.6 Traditional Fourier-Transform Spectrometer 4-21
4.2.7 Electro-Optical Imaging Fourier-Transform Spectrometer 4-22
4.5.1 Structure of a Fiber Bragg Grating 4-34
4.5.2 Fabry-Perot Sensor Fabricated by Micro-machining 4-36
4.5.3 Unpackaged FBG Sensor 4-38
4.5.4 Weldable FBG Strain Sensor 4-39
4.5.5 Hydrostatic Pressure and Temperature Measurements FBG Sensor 4-40
4.5.6 Flexible Optical Sensing 4-41
4.5.7 Bridge Scour Monitoring: FBG Sensors 4-43
4.5.8 Real-Time Train Wheel Condition Monitoring Scheme 4-44
4.5.9 Fiber Bragg Grating (FBG) Sensors Used in Sailing 4-45
4.6.1 Hand-Held Raman Scanner 4-52
4.7.1 Fluorescent Long-Line Fiber Optic Position Sensors 4-60
4.7.2 Fluorescent Long-Line Fiber Optic Position Sensors with LED 4-62
4.9.1 Laser Doppler Flowmetry 4-69
4.9.2 Schematic Representation of Zeta Potential 4-71
4.10.1 Schematic of a LIBS system 4-77
4.11.1 Surface Plasmon Sensors 4-80
4.11.2 Polariton fiber sensor configuration 4-83
4.11.3 Polariton Fiber Sensor 4-84
4.11.4 Tapered fiber structure with uniform waist 4-85
4.11.5 Surface Plasmon Resonance Sensing Structure 4-86
4.11.6 Hollow core sensing structure with Bragg grating 4-87
4.11.7 Planar SPP sensor with Bragg grating imprinted into the waveguide layer 4-89
4.11.8 Planar SPP sensor with LPG imprinted into the waveguide layer 4-91
4.11.9 MZI branch with the Bragg grating 4-93
4.11.10 Dependence between the refractive index 4-94
4.11.11 A dual LPG-based SPR sensor 4-95
4.11.12 Tilted grating assisted SPR sensor 4-97
4.11.13 Changes in the Intensities 4-98
4.11.14 PVDF Coated Teflon Fiber SPR Gas Sensor 4-99
4.11.15 Hybrid Mode SPR Sensor 4-100
4.11.16 Thin SPP Waveguide 4-101
4.11.17 Gemini Fiber 4-107
4.11.18 Specialty Optical Fibers with Holes for sensors, lasers and components 4-108
4.11.19 Fiber Sensor: LPG and HiBi Fiber 4-110
4.12.1 Use of an Optrode 4-116
5.1 Pulse Oximeter 5-2
5.2 Fingertip Pulse Oximeter 5-3
5.3 Veterinarian Oximeter 5-5
5.4 Handheld Pulse Oximeter 5-6
5.5 Portable Pulse Oximeter 5-8
5.6 Fingertip Oximeter 5-12
5.7 Pulse Oximeter 5-15
5.8 Finger Pulse Oximeter 5-16
5.9 Fingertip Pulse Oximeter 5-19
5.10 Wrist Pulse Oximeter 5-21
5.11 Portable Digital Oximeter with Probe 5-22
5.12 Pulse Oximeter 5-24
5.13 Handheld Pulse Oximeter with Finger Sensor 5-26
5.14 Finger Pulse Oximeter 5-27
5.15 Finger Pulse Oximeter 5-28
5.16 Hand Held Pulse Oximeter 5-31
5.17 Seven (7) wavelengths acquire blood constituent data 5-34
5.18 Seven (7) wavelengths acquire blood constituent data 5-35
5.19 Oximeters - Upgradable Technology Platforms 5-36
5.20 Handheld and Tabletop Oximeters 5-41
5.21 Multi-Functional Monitor, including Oximeter Probes 5-43
5.22 Hand Held Pulse Oximeter 5-44
5.23 Desktop Pulse Oximeter 5-46
5.24 Portable Capnography Monitor 5-48
5.25 Fingertip Pulse Oximeter 5-50
5.26 Hand-Carry Monitor with Oximeter 5-52
5.27 Fingertip Pulse Oximeter 5-53
5.28 Monitor System with Oximeter 5-54
5.29 Hand Held Pulse Oximeter 5-55
5.30 Hand-Held Capnograph/Oximeter 5-57
5.31 Fingertip Pulse Oximeter 5-61
5.32 Hand Held Pulse Oximeter 5-62
5.33 Hand Held Pulse Oximeter 5-64
5.34 Hand Held Pulse Oximeter 5-66
6.1 Market Research & Forecasting Methodology 6-2 


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Reports Details

Published Date : Feb 2015
No. of Pages :566
Country :Global
Category :Electronics
Publisher :ElectroniCast Consultants
Report Delivery By :Email
Report Delivery Time :12 to 24 hours after placing the order.

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