Latest revision as of 08:02, 27 July 2015

This report presents a brief introduction to OLED (organic light emitting diode) and technologies available for top emission OLED. A detailed taxonomy for OLED is presented covering parts of the type of OLED, material used, manufacturing, applications among others. A detailed landscape analysis of patent and non-patent literature is done with a focus on Top Emission OLED (TEOLED). The product information of major players in the market is also captured for OLED. The final section of the report covers the existing and future market predictions for OLED.

OLED Working Principle

Introduction

OLED technology was firstly developed in 1987 at Eastman Kodak Company by Tang and Van Slyke using small-molecule (sm-OLED). In 1990 Richard Friend, Jeremy Burroughes and Donal Bradley discovered electroluminescence capabilities from conjugated polymers so laying down the foundations for a new generation of flat panel displays.
The growing number of electronic devices using organic light emitting diode displays shows that after years of promise, the technology is increasingly finding place in many products. But while OLED displays might challenge LCDs as the screens of choice for smaller gadgets, the technology may not become mainstream for notebook PCs or TVs within this decade.
OLED displays use organic compounds that emit light when exposed to an electric current. They are brighter, have better contrast, offer wider viewing angles, use less power, and provide faster response times than liquid crystal displays. OLED screens' thickness is a third of that of LCDs, since they don't need a back-light, and that makes them a good fit for portable electronics devices.

Top Emission OLED: Search Strategy

The present study on the IP activity in the area of OLED with focus on Top Emission OLED (TEOLED) is based on a search conducted on Micropat.

Control Patents

S. No.	Patent/Publication No.	Publication Date(mm/dd/yyyy)	Assignee/Applicant	Title
1	US7791271B2	7/9/2010	Global OLED Technology LLC	Top-Emitting OLED Device With Light-Scattering Layer and Color-Conversion.
2	US7781961B2	08/24/2010	Novaled AG	Top Emitting, Electroluminescent Component With Frequency Conversion Centres.
3	US7002293B2	02/21/2006	Eastman Kodak Company	Organic Light Emitting Diode With Improved Light Emission Through The Cathode.
4	US6770502B2	3/8/2004	Eastman Kodak Company	Method Of Manufacturing a Top-emitting OLED display Device with Desiccant Structures.
5	US20080169757A1	07/17/2008	TPO Displays Corp.	Top-Emitting Organic Electroluminescent Display
6	US20060043373A1	2/3/2006	Industrial Technology Research Institute	Method for Manufacturing a Pixel Array of Top Emitting OLED.
7	US20050236629A1	10/27/2005	Samsung Corp.	Top Emission Organic Light Emitting Diode Display Using Auxiliary Electrode to Prevent Voltage Drop of Upper Electrode and Method of Fabricating the Same.
8	EP1489671A2	12/22/2004	Global OLED Technology LLC	Method of Making a Top-Emitting OLED device having Improved Power Distribution
9	EP1029336A1	08/23/2000	Fed Corp.	Top Emitting OLED with Refractory Metal Compounds as Bottom Cathode .
10	WO2001057904A1	9/8/2001	Emagin Corp.	Low Absorption Sputter Protection Layer for OLED Structure.

Patent Classes

S. No.

Class No.

Class Type

Definition

1

257/40

USPC

Active solid-state devices (e.g., transistors, solid-state diodes) /Organic semiconductor material

2

257/E51.018

USPC

Active solid-state devices (e.g., transistors, solid-state diodes) / organic solid state devices, processes or apparatus peculiar to manufacture or treatment of such devices or of parts thereof / structural detail of device / light-emitting organic solid-state device with potential or surface barrier

3

257/E51.019

USPC

Active solid-state devices (e.g., transistors, solid-state diodes) / organic solid state devices, processes or apparatus peculiar to manufacture or treatment of such devices or of parts thereof / structural detail of device / light-emitting organic solid-state device with potential or surface barrier / Electrode

4

257/E51.02

USPC

Active solid-state devices (e.g., transistors, solid-state diodes) / organic solid state devices, processes or apparatus peculiar to manufacture or treatment of such devices or of parts thereof / structural detail of device / light-emitting organic solid-state device with potential or surface barrier / Electrode / Encapsulation

5

257/E51.021

USPC

Active solid-state devices (e.g., transistors, solid-state diodes) / organic solid state devices, processes or apparatus peculiar to manufacture or treatment of such devices or of parts thereof / structural detail of device / light-emitting organic solid-state device with potential or surface barrier / Electrode / Arrangements for extracting light from device (e.g., Bragg reflector pair)

6

257/E51.022

USPC

Active solid-state devices (e.g., transistors, solid-state diodes) / organic solid state devices, processes or apparatus peculiar to manufacture or treatment of such devices or of parts thereof / structural detail of device / light-emitting organic solid-state device with potential or surface barrier / Multicolor organic light-emitting device (OLED)

7

313/504

USPC

Electric lamp and discharge devices/solid-state type/ with particular phosphor or electrode material / Organic phosphor

8

H01L 27/28

IPC

Semiconductor devices; electric solid state devices not otherwise provided for / devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate / including components using organic materials as the active part, or using a combination of organic materials with other materials as the active part

9

H01L 27/32

IPC

Semiconductor devices; electric solid state devices not otherwise provided for / devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate / including components using organic materials as the active part, or using a combination of organic materials with other materials as the active part / with components specially adapted for light emission, e.g. flat-panel displays using organic light-emitting diodes

10

H01L 51/50

IPC

Semiconductor devices; electric solid state devices not otherwise provided for / solid state devices using organic materials as the active part, or using a combination of organic materials with other materials as the active part; processes or apparatus specially adapted for the manufacture or treatment of such devices, or of parts thereof / specially adapted for light emission, e.g. organic light emitting diodes (oled) or polymer light emitting devices (pled)

11

H01L 51/52

IPC

Semiconductor devices; electric solid state devices not otherwise provided for / solid state devices using organic materials as the active part, or using a combination of organic materials with other materials as the active part; processes or apparatus specially adapted for the manufacture or treatment of such devices, or of parts thereof / Details of devices

12

H01L 51/56

IPC

Semiconductor devices; electric solid state devices not otherwise provided for/specially adapted for sensing infra-red radiation, light, electromagnetic radiation of shorter wavelength, or corpuscular radiation; specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation / Processes or apparatus specially adapted for the manufacture or treatment of such devices or of parts thereo

Concept Table

S. No.	Concept 1	Concept 2
S. No.	Top emission	Organic Light Emitting Diode
1	top emitting	oled
2	top emissive	polymer led
3	top emission	light emitting polymer diode
4	toled	organic led
5	teoled	organic electroluminescent diode
6		foled
7		sm-oled
8		small molecule oled
9		amoled
10		pmoled

Micropatent Search Strategy

Database: Micropat
Patent coverage: US, EP, WO, JP, DE, GB, FR
Time line: 1836/01/01 to 2011/02/20

S. No.	Concept	Scope	Search String	No. of Hits
1	Classes - OLED	Any Classification	H01L005150* OR H01L005152* OR H01L005156 OR H05B003308P OR 257E51.022	63152
2	Classes - Organic Semiconductor Devices	Any Classification	313504 OR 257040 OR 257E51.018 OR 257E51.019 OR 257E51.020 OR 257E51.021 OR H01L002728 OR H01L002732	27601
3	Top Emission keywords	Claims, Title or Abstract	((top emitting) OR (toled) OR (teoled) OR (te-oled) OR (top ADJ2 emitting) OR (top ADJ2 emissive) OR (top ADJ2 emission)) ADJ ((light ADJ emitting ADJ polymer) OR (organic ADJ electro-luminescence ADJ diode) OR (ORganic ADJ electroluminescent ADJ diode) OR (ploymer ADJ light ADJ emitting ADJ diode) OR (ORganic ADJ light ADJ emitting ADJ device) OR (self-luminous ADJ diode) OR (oled) OR (organic led arrays) OR (organic ADJ light ADJ emitting ADJ diode) OR (organic ADJ light ADJ emission ADJ diode) OR (polymer ADJ light ADJ emission ADJ device) OR (organic ADJ electroluminescent device) OR (oel) OR (oleds))	1141
4	OLED keywords	Claims, Title or Abstract	((organic OR (small adj molecule1) OR polymer1) adj (lightemitting OR (light adj (emitting OR emission)) OR electroluminescen2 OR (electro adj luminescen2))) NEAR3 diode1) OR oled2 OR smled2 OR pled2 OR (light adj (emitting OR emission) adj polymer1) OR ((organic OR (small adj molecule1) OR polymer1) NEAR3 led2)	39392
5	Top emissioin OLED keywords	Claims, Title or Abstract	(((((organic OR (small ADJ molecule1) OR polymer1) ADJ (lightemitting OR (light ADJ (emitting OR emission)) OR electroluminescen2 OR (electro ADJ luminescen2))) NEAR3 diode1) OR oled2 OR smled2 OR pled2 OR (light ADJ (emitting OR emission) ADJ polymer1) OR ((ORganic OR (small ADJ molecule1) OR polymer1) NEAR3 led2)) AND ((top ADJ3 (emissi2 OR emitting)))) OR (te ADJ oled2)	429
6	Top Emission keywords AND OLED classes	Combined query	1 AND 3	809
7	LED Keywords	Claims, Title or Abstract	((lightemitting OR (light ADJ (emitting OR emission)) OR electroluminescen2 OR (electro ADJ luminescen2)) NEAR3 diode1) OR led2 OR oled2 OR smled2 OR pled*2	1617014
8	Top emission keywords AND Organic semiconductor devices classes AND Top emission keywords	Combined query	2 AND 7 AND 3	224
9	Top emissioin OLED keywords	Full patent spec.	(((((organic OR (small ADJ molecule1) OR polymer1) ADJ (lightemitting OR (light ADJ (emitting OR emission)) OR electroluminescen2 OR (electro ADJ luminescen2))) near3 diode1) OR oled2 OR smled2 OR pled2 OR (light ADJ (emitting OR emission) ADJ polymer1) OR ((organic OR (small ADJ molecule1) OR polymer1) near3 LED2)) near3 ((top ADJ3 (emissi2 OR emitting)))) OR (te ADJ oled2)	1506
10	German Keywords	Full patent spec.	((top adj3 (emissi2 OR emitting)) OR (Top NEAR2 emittierende1)) NEAR3 ((organische NEAR2 (led1 OR Leuchtdiode1)) OR (Licht adj emittierende adj Polymer1) OR oled1)	1430
11	French Keywords	Full patent spec.	((top ADJ3 (émissive OR émettant)) OR (démission ADJ top) OR (top ADJ3 (emissi2 OR emitting))) NEAR3 ((diode1 NEAR3 électroluminescente NEAR3 organique1) OR ((Polymère1 OR organiques) ADJ2 led1) OR (polymère1 NEAR3 émettant NEAR3 lumière) OR oled*1)	1412
12		Combined query	5 OR 6 OR 8 OR 9 OR 10 OR 11	2113 (1132 unique)
13	Control Patents	Patent/Publication No.	WO2001057904A1 OR EP1029336A1 OR EP1489671A2 OR US20050236629A1 OR US20060043373A1 OR US20080169757A1 OR US6770502B2 OR US7002293B2 OR US7781961B2 OR US7791271B2	10
14		Combined query	12 AND 13	10

Scientific Literature Search

S.No	Database	Query	Limits by Date	No.Of Hit
1	Google scholar	(Top emitting or top emission or top emissive) and ((organic light emitting diode) or (polymer led) or (light emitting polymer led) or (OLED))	1990-2011	1840

Search in Japanese database

Database: IPDL (Industrial property digital library), Japan

Date of search: 1900/01/01 to 2011/02/15

S.No.	Issue/Publication date	F-Term Theme	FI/F-term/Facet	Hits
1	1900/01/01 to 2011/03/02	3K107	DD03*[AA01+BB01+BB02+BB03+BB04+BB05+BB06+BB07+BB08+DD01+DD04+DD42+DD50+CC01+CC02+CC04+CC06+CC07+ CC08+CC09+EE02+EE03+EE06+EE22+GG01+GG02+GG03+GG04+GG05+GG06+GG07+GG08+GG08]	1596

F-Terms and theme used in search

Japanese F-term search			Definition
Sr. No.	F- Term theme	3K107	Electroluminescent light sources
1	F- Term	AA01	Organic electroluminescent element.
2	F- Term	BB01	Used in displays.
3	F- Term	BB02	Used in Lights or light sources
4	F- Term	BB03	Used in Backlights or the like for liquid crystals
5	F- Term	BB04	Used in printer heads
6	F- Term	BB05	Used in lasers
7	F- Term	BB06	Used in designs or advertisements
8	F- Term	BB07	Used in timepieces
9	F- Term	BB08	Used in on-board use
10	F- Term	DD01	Having feature of all direction of light emission.
11	F- Term	DD03	Having top emission.
12	F- Term	DD04	Having double sided emission.
13	F- Term	DD42	Having Organic materials.
14	F- Term	DD50	Structured with Light emitting layers
15	F- Term	CC01	Having Light emitting layers
16	F- Term	CC02	Light emission characteristics were improved.
17	F- Term	CC04	Has an effect on brightness.
18	F- Term	CC06	Has an effect on efficiency
19	F- Term	CC07	Has an effect on colours.
20	F- Term	CC08	Has an effect on Colour purity; Colour temperatures; Light emission wavelengths, including UV
21	F- Term	CC09	Has colour balance feature
22	F- Term	EE02	Has white light emission.
23	F- Term	EE03	Display having Passive matrices
24	F- Term	EE06	Display having Active matrices
25	F- Term	EE22	Display having with RGB picture elements having different areas
26	F- Term	GG01	Dispaly having color filters.
27	F- Term	GG02	Apparatus for deposition
28	F- Term	GG03	Apparatus for dry methods
29	F- Term	GG04	Apparatus for chemical vapour deposition
30	F- Term	GG05	Apparatus for evaporation
31	F- Term	GG06	Apparatus for sputtering
32	F- Term	GG07	Apparatus for wet methods
33	F- Term	GG08	Apparatus for printing
34	F- Term	GG08	Apparatus for Inkjet

Taxonomy

Sample Analysis

Patent Analysis

A sample of 200 patents from the search is analyzed based on the taxonomy. Provided a link below for sample spread sheet analysis for Top Emission OLED.

S.No

Patent/Publication No.

Date of Publication

Assignee / Applicant

Title

Problem

Solution

1

US7692191B2

04/06/2010

Samsung Mobile Display Co., Ltd.

Top-emitting organic light emitting device

In the conventional top-emitting organic light emitting device, each pixel electrode is designed to have a minimum width, and neighboring pixel electrodes are designed to be widely spaced apart from each other by as much as 17 .mu.m. Therefore, the wide space between the pixel electrodes leaks emitted light, thereby deteriorating the voltage-current characteristics of the thin film transistors i.e., increasing photo-leakage.

In this patent the top-emitting organic light emitting device has maximized the width of a pixel electrode , thereby enhancing aperture ratio. Furthermore, the pixel electrode is arranged to overlap all thin film transistors, so that light is prevented from leaking through a space between neighboring pixel electrodes, thereby reducing photo-leakage of the thin film transistor.

2

US7554259B2

06/30/2009

Sanyo Electric Co., Ltd.

Light emitting display apparatus having excellent color reproducibility

Organic electroluminescence panel obtains white light by synthesizing two lights each having complementary color to the other, and the three primary colors differ in luminous intensity. Therefore it is difficult to set chromaticity of white light to desired level. And even after color-filter transmission, red light and blue light will have stronger luminous intensity than green light.

The present invention objective provide a light emitting display apparatus having excellent color reproducibility. Organic light emitting layer that synthesizes two or more complementary colors of light that are complementary to each other thereby producing white light. It has a resonant structure by which a resonant wavelength is set to a predetermined wavelength, and outputs the white light via the resonant structure where the predetermined wavelength substantially coincides with a wavelength corresponding to a primary color whose luminous intensity is uniform.With the stated construction, non-uniformity in luminous intensity among three primary colors is alleviated by means of amplified luminous intensity due to resonance. This will help obtain white light in which the primary colors are balanced well.

3

US7332859B2

02/19/2008

Canon Kabushiki Kaisha

Organic luminescence device with anti-reflection layer and organic luminescence device package

In organic luminescence device, the transparent electrode is formed by a material of a refractive index higher than that of air or nitrogen, constituting the external environment of the organic luminescence device. Therefore, the light emitted from the light emitting layer is reflected at a light emitting surface of the transparent electrode , namely at the interface between the transparent electrode and the air constituting the external environment in FIG. 1. For this reason, such organic luminescence device has been associated with a low efficiency of light emission to the exterior.

The present invention is to provide an organic luminescence device of a high light-emitting efficiency to the exterior and an organic luminescence device of a satisfactory contrast. A case holding the organic luminescence device in an internal holding space, in which a light emitted from the organic luminescence device, is emitted to the exterior through a light emitting side of the case; wherein anti-reflection means is provided on a light-emitting face on the light-emitting side among faces constituting the internal holding space of the case

4

US6885157B1

04/26/2005

Eastman Kodak Company

Integrated touch screen and OLED flat-panel display

It has the problem of multiple external electrical connections by employing a flat-panel display having a substrate that extends beyond the substrate of the resistive touch screen.

The present invention has the advantage that it reduces the costs and improves the reliability and performance of a touch screen that is used with an OLED flat-panel display by integrating cable connections on a single substrate and providing touch screen signal processing on the display substrate.

5

US6069443A

05/30/2000

FED Corporation

Passive matrix OLED display

The disadvantage of oxygen and moisture penetration into the interior of the organic light emitting device is the potential to form metal oxides at the metal-organic interface. These metal oxide impurities may allow separation of the cathode or anode and the organic in a matrix . This can result in the formation of dark non-emitting spots (i.e., no illumination).Edge shorting between the cathode and anode layers is a current problem affecting most conventional organic light emitting display devices. This edge shorting reduces the illuminating potential of the display devices.

The present invention to provide an insulator layer to minimize edge shorts between lines by separating the OLED layer and the electrode elements. It also provides a sealing structure to isolate the OLED layer from moisture and other contaminants.

6

US20110031511A1

02/10/2011

None

ORGANIC LIGHT EMITTING DIODE DISPLAY AND METHOD OF MANUFACTURING THE SAME

In the organic light emitting layer, as it is easy to transfer energy in an interface between a light emitting layer and a hole transfer layer, a light emitting efficiency and lifetime of the OLED display are reduced because of an energy loss of triplet inside the OLED display.

An interface of the light emitting layer can be improved by forming the inorganic oxide layer between the hole transport layer and the light emitting layer. Further, an energy loss of triplet can be prevented, and the emission efficiency and lifetime can be improved.

7

US20070153051A1

07/05/2007

Samsung Electronics Co., Ltd.

Manufacturing flat panel displays with inkjet printing systems

For manufacture of certain flat panel display devices, such as LCDs or OLED displays, various thin film patterns are formed on panel substrates of the devices, typically using photolithography processes. However, as displays become larger, the amount of material that must be deposited on substrates to form the thin film patterns also becomes larger, inturn increases the manufacturing costs of the panels.

Inkjet printing systems have been developed for forming the thin film patterns on the substrates by depositing them on the substrates in the form of special inks. These systems deposit the ink on the substrate through an inkjet head. However, the inkjet head includes a plurality of nozzles, and if only one of these nozzles becomes dysfunctional, the number of passes that the inkjet printing head must make increases. As a result, processing time and costs are substantially increased.

8

US6911671B2

06/28/2005

Eastman Kodak Company

Device for depositing patterned layers in OLED displays

To achieve color pixelation in OLED imaging panels, fabrication of a multicolor OLED imaging panel using a shadow masking method is used. A multicolor organic electroluminescent ("EL") medium is vapor deposited and patterned by controlling an angular position of a substrate with respect to a deposition vapor stream. The positioning an element in direct contact with a surface of a substrate can invite problems of abrasion, distortion, or partial lifting, this may cause abrasion, distortion, or partial lifting of the first-color pattern.

The present invention is that a pattern of vaporized material, such as organic material, can be deposited without the use of shadow mask.Another feature is that a plurality of devices can be used for simultaneously depositing different organic materials. Such organic materials can emit light in different ranges of the spectrum.

9

US7218295B2

05/15/2007

AU Optronics Corp.

Driving method for active matrix OLED display

In one display frame, the current received by the OLED is fixed.The driving method used previously accumulates carriers inside the OLED which reduce the life of the OLEDs. Moreover, the voltage across the OLED gradually increases over timewhich inturn increases power. This effects the OLED over time.

The present invention uses a driving method to neutralize carrier accumulation in the OLED, thereby reducing the increase in voltage and minimizing the increase in power consumption across both ends of the OLED over time, further increasing the life of the OLED.

10

US7067170B2

06/27/2006

Eastman Kodak Company

Depositing layers in OLED devices using viscous flow

To achieve color pixelation in OLED imaging panels, fabrication of a multicolor OLED imaging panel using a shadow masking method is used. A multicolor organic electroluminescent ("EL") medium is vapor deposited and patterned by controlling an angular position of a substrate with respect to a deposition vapor stream. The positioning an element in direct contact with a surface of a substrate can invite problems of abrasion, distortion, or partial lifting, this may cause abrasion, distortion, or partial lifting of the first-color pattern.

The present invention is that the method of color pixelating an organic layer includes providing a plurality of vapor sources disposed outside of a deposition chamber for generating vapors of organic materials, and connecting such vapor sources to a manifold disposed in the chamber. By using vapor deposition method, we can eliminate precision shadow masks.

Click here to view the detailed analysis sheet for doubly-fed induction generators patent analysis.

Article Analysis

S.No.	Title	Authors	Publication date	Journal/Conference	Dolcera summery.
1	Application of Screen Printing in the Fabricationof Organic Light-Emitting Devices	Dino A. Pardo, Ghassan E. Jabbour,* andNasser Peyghambarian	01/27/2000	Optical Sciences Center, University of Arizona.IEEE 27 Jan 2000	This article explains the screen printing technique which deposits organic active layer having a thickness of several tens of nanometers and acting as a hole-transport layer (HTL) in multilayer OLEDs. The resulting devices emitlight at low voltage (<5 V) and have a peak external quantum efficiency of 0.91 %.
2	Multicolor Organic Light-Emitting DiodesProcessed by Hybrid Inkjet Printing	Shun-Chi Chang, Jie Liu, Jayesh Bharathan,Yang Yang,* Jun Onohara and Junji Kido	08/07/1999	Department of Materials Science and EngineeringUniversity of California at Los Angeles. willey 8 Jul 1999	This article presents a multicolor patterning technique to produce controllable patterning of red-green-blue OLEDs with fine pixel displays. The LEDs comprise bilayer structures of red and green dopants with inkjet-printed onto a film of the blue-emitting semiconducting polymer, the latter serving as the hole-transport layer.
3	Organic light-emitting diode (OLED)technology: materials, devices and displaytechnologies	Bernard Geffroy, Philippe le Roy and Christophe Prat	06/02/2006	Laboratoire Cellules et Composants. willey 6 Feb 2006	This article presents an overview of OLED's over LCD's. OLED'S have a thickness, currently less than 2 mm. Having high contrast ratio is also a strong point of OLED and also in fast response time.OLEDs for flat-panel display applications are their self-emitting property, high luminous efficiency, full-colour capability, wide viewing angle, high contrast,low power consumption, low weight, potentially large area colour displays and flexibility.
4	Organic/polymeric electroluminescent devices processed by hybrid ink-jet printing	Yang Yang, Shun-Chi Chang, Jayesh Bharathan and Jie Liu	04/05/1999	Journal of Materials Science: Materials in Electronics Volume 11, Number 2,	The HIJP concept is a unique approach for fabricating polymer and organic electronic devices. One is able to apply this technology for the deposition of various functional materials such as charge-injection layers, charge-blocking layers, and multicolor polymer/organic emissive layers. It can be used for the fabrication of logos, indicator lights, multicolor displays and also in bio-medical applications such as biosensors for low cost diagnostics.
5	White Organic Light-Emitting Devices for Solid-State Lighting	B. W. D'Andrade, S. R. Forrest	14/10/2004	Department of Electrical Engineering, Princeton University Willey 14 OCT 2004	This article presents the WOLEDs increasing display applications for use primarily as liquid-crystal display backlights. They have achieved high material purity, low cost, high brightness,color quality and long operational life-times.
6	White organic light-emitting diodes with fluorescent tube efficiency	Sebastian Reineke, Frank Lindner, Gregor Schwartz, Nico Seidler, Karsten Walzer	14/05/2009	Institute of Applied Photophysics. Vol 459 Macmillan Pub	This article presents an WOLED havinh high internal quantum efficiencies for the con-version of electrical energy to light have been realized by focussing on reducing energetic and ohmic losses that occur during electron–photon conversion.This can be achieved by improved OLED structure which reaches fluorescent tube efficiency. By combining a care-fully chosen emitter layer with high-refractive-index substrates and using a periodic outcoupling structure
7	Precision ink jet printing of polymer light emitting displays	J. F. Dijksman, P. C. Duineveld, M. J. J. Hack, A. Pierik, J. Rensen, J.-E. Rubingh, I. Schram andM. M. Vernhou	09/11/2006	Philips Research Laboratories RSC	Precision ink jet printing of organic polymer light emitting diodes relies strongly on the accuracy of the droplet generation process.Image capturing using one image at a time for image processing delivers sharper images and can be used for optically measuring droplet volumes.
8	High-efficiency microcavity top-emitting organic light-emittingdiodes using silver anode	Huajun Peng, Jiaxin Sun, Xiuling Zhu, Xiaoming Yu, Man Wong, and Hoi-Sing Kwok	17/02/2006	Hong Kong Universityof Science and Technology. AIP	High efficient top-emitting OLEDs have been fabricated using highly reflective Ag as the anode. Surfacemodification of the Ag anode by CF4 plasma substantially enhances the hole injection efficiency. The color variation isalmost eliminated in the TOLED. The optimized microcav- ity TOLED has a current efficiency enhancement of 65% and a total outcoupling efficiency enhancement of 35%, as compared with a conventional OLED.
9	Inverted top-emitting organic light-emitting diodes using transparent conductive NiO electrode	Se-W. Park, Jeong-M. Choi, Eugene Kim and Seongil Im	09/01/2005	Institute of Physics and Applied Physics, Applied Surface Science 244 (2005) 439–443	TE-OLED device uses a thermally evaporated and semi-transparent NiO film as a top-electrode. Since the sheet resistance of our NiO was very high and its transmittance was only about 50%, the resulting luminance and injection current of our TE-OLED were much inferior to those of the BE-OLED device.
10	Self-assembled monolayer-modified Ag anode for top-emitting polymerlight-emitting diodes	Lai-Wan Chong, Yuh-Lang Lee,a͒ and Ten-Chin Wenb͒	07/12/2006	Department of Chemical Engineering, National Cheng Kung University	Self-assembled monolayer is a method to modify the Ag anodes for application in T-PLED. The Ag electrode can be utilized as an effective anode to improve the emitting characteristic of a T-PLED. The Ag anode enhances the hole injection, reduce the op-eration voltage, and significantly increase the current inten-sity and luminous efficiency of the device, without decreasing the reflectivity of the Ag anode.

Click here to view the detailed analysis sheet for Top Emission OLED for non patent literature

Top Cited Patents

S. No.	Patent/Publication No.	Publication Date (mm/dd/yyyy)	Assignee/Applicant	Title	Citation Count
1	US6096496A	8/1/2000	Frankel; Robert D	Supports incorporating vertical cavity emitting lasers and tracking apparatus for use in combinatorial synthesis	130
2	US6069443A	5/30/2000	Fed Corporation	Passive matrix OLED display	97
3	US6366017B1	4/2/2002	Agilent Technologies	Organic light emitting diodes with distributed bragg reflector	80
4	US20020197511A1	12/26/2002	United Of America As Respresented By The Secretary Of The Air Force	High efficiency multi-color electro-phosphorescent OLEDS	51
5	US6265820B1	7/24/2001	Emagin Corporation,De	Heat removal system for use in organic light emitting diode displays having high brightness	50
6	US20020195968A1	12/26/2002	IBM	Oled current drive pixel circuit	44
7	US20020186209A1	12/12/2002	Eastman Kodak Company	Touch screen for use with an OLED display	42
8	US20030127973A1	7/10/2003	Universal Display Corporation	OLEDs having increased external electroluminescence quantum efficiencies	41
9	US6844673B1	1/18/2005	Alien Technology Corporation	Split-fabrication for light emitting display structures	38
10	US20040174116A1	9/9/2004	Universal Display Corporation	Transparent electrodes	36
11	US20050194896A1	9/8/2005	Hitachi Displays Ltd.	Light emitting element and display device and illumination device using the light emitting element	35
12	US20020074935A1	6/20/2002	Universal Display Corporation	Highly stable and efficient OLEDs with a phosphorescent-doped mixed layer architecture	35
13	US20040217702A1	11/4/2004	Corning Incorporated	Light extraction designs for organic light emitting diodes	33
14	US20020030647A1	3/14/2002	Universal Display Corporation	Uniform active matrix oled displays	32
15	US20050248270A1	11/10/2005	Eastman Kodak Company	Encapsulating OLED devices	31
16	US20040113875A1	6/17/2004	Eastman Kodak Company	Color oled display with improved power efficiency	29
17	US20030230972A1	12/18/2003	Eastman Kodak Company	Oled display having color filters for improving contrast	28
18	US20050040756A1	2/24/2005	Eastman Kodak Company	OLED device having microcavity gamut subpixels and a within gamut subpixel	27
19	US6670772B1	12/30/2003	Eastman Kodak Company	Organic light emitting diode display with surface plasmon outcoupling	26
20	US20040061136A1	4/1/2004	Eastman Kodak Company	Organic light-emitting device having enhanced light extraction efficiency	26

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Products

S. No.

Company

Product

Specifications

1

Sony

BVME250

Digital Inputs Specifications

Detail:

HDMI

HDMI (x1) (HDCP correspondence, Deep Color correspondence)

SDI (SMPTE 259M)

BNC (x2)

Display Specifications

Detail:

Image Aspect Ratio

16:09

Resolution

1920 x 1080 pixels (Full HD)

Screen Size

24 5/8 inches (623.4 mm)

Viewing Angle

89°/89°/89°/89°

General Specifications Specifications

Detail:

Dimensions (W x H x D)

22 3/4 x 16 3/4 x 5 7/8 inches

Weight

28 lb 11 oz

Power Requirements Specifications

Detail:

Power Consumption

Approx. 145 W

Power Requirements

AC 100 V to 240 V, 1.6 A to 0.8 A, 50/60 Hz

2

Sony

BVM-E170

Digital Inputs Specifications

Detail:

HDMI

HDMI (x1) (HDCP correspondence, deep colour correspondence)

SDI

BNC (x2)

Display Specifications

Detail:

Image Aspect Ratio

16:09

Resolution

1920 x 1080 pixels (Full HD)

Screen Size

365.8 x 205.7 mm (14 1/2 x 8 1/8 inches)

Viewing Angle

89°/89°/89°/89° (typical) (up/down/left/right contrast >10:1)

General Specifications Specifications

Detail:

Dimensions (W x H x D)

436.0 x 282.4 (266.4)* x 214.7 mm (17 1/4 x 11 1/4 (10 1/2)* x 8 1/2 inches) * Height without legs

Weight

8.5 kg (18 lb 11 oz)

Power Requirements Specifications

Detail:

Power Consumption

Approx. 65 W normally with input from a standard HDMI input. Approx. 115 W at maximum load, with four option slots in use and maximum luminance compensation for any deterioration due to aging.

Power Requirements

AC 100 V to 240 V, 1.4 A to 0.7 A, 50/60 Hz DC 24 V to 28 V, 4.7 A to 4.0 A

3

Sony

PVM-740

Digital Inputs Specifications

Detail:

HDMI

Yes

HDSDI (SMPTE 292M)

3G/SDI/HDSDI

SDI (SMPTE 259M)

Included

Display Specifications

Detail:

Back Light Technology

OLED

Native Aspect Ratio

16:09

Resolution

960 x 540

Screen Size

Approx 7.4 inches

Viewing Angle

85°/85°/85°/85° (typical) (up/down/left/right contrast>10:1)

General Specifications Specifications

Detail:

Dimensions (W x H x D)

8 7/8 x 7 1/4 x 6 3/8 inches Approx. 222.4 x 183.5 x 161.8 mm

On-Screen Display

Yes

Rack Mount

MB531

Weight

Approx. 5 lb 12 oz Approx. 2.6 kg

Power Requirements Specifications

Detail:

Power Consumption

Max. approx. 27W

Power Requirements

AC 100 to 240 V 50/60 Hz 0.5A to 0.3A DC 12 V 1.9 A Rechargeable Battery Pack

Market Research

Major Players

Major types of player	USA	EU	Japan	Korea	Taiwan	China
Original IPR for devices and for manufacture process + material supply / verification	UDC; Kodak; Add-Vision; Magin; Plextronics; Organic Lighting Technologies; GE;3M Innovation	CDT (Sumitomo Chemical) (UK); Novaled (G); Fraunhofer IPMS (G); OLED-T (UK); OTB (ND); MicroEmissive Displays (UK)	Seiko-Epson; Matsushita; Sony; Sumitomo Chemical; Sharp; TM Display; Konica –Minolta; Sanyo; Toppoly; Lumiotec; Canon; Toshiba	Samsung; LG Phillips LCD; Neo View; Doosan DND	AU Optoelectronics (AUO); Univision; Toppoly; Tetrahedron; Chi Mei Optoelectronics
Bulk materials and glass suppliers	PPG; 3M; Dow Corning	Merck Materials (G); BASF (G); CDT (UK); Degussa/ Evonik (G); HC Starck (G); Sensient Imaging Technologies (G); Goodfellow Metals (UK); Novaled (G)	Sumitomo Chemical; Mitsubishi Chemical			Syndychem (Shenyang Syndy Chemistry Institute)
Components – driver ccts., packaging etc	Corning; Rockwell Collins	ST Microelectronics (It, Fr); Infineon (G)	Maekawa; Matsushita; Toppoly	Dae Joo Electrncs	AUO; Richtek Technologies; Lightsonic; Univision; Wintek	Innocom Technologies Shenzen; RIT Display
OEM OLED FPD screen manufacturer & resellers	eMagin; US Micro Products	Densitron Technologies (UK); MicroEmissive Displays (MED) (UK); Pacer International Distributors (UK reseller)	Seiko-Epson; Sharp; Sumitomo Chemical; Lumiotec; TMDisplay; Sanyo	Samsung SDI; Orion OLED; NeoView KOLON; Hyundai LCD	AUO; Chi Mei EL (CMEL); Univision Technology; Evervision Electronics; RiTDisplay; TPO Display	Visionix; Smartdisplays; Universal Display Technologoes (Jilin); Varitronix (HK); Blaze Display Technologies
Branded application device or/and FPD screen manufacturer with retail device sales	OSD	Nokia; Sony-Ericsson	Sony; Matsushita; Hitachi; Toshiba; Imase	Samsung; LG Philips
OLED lighting branded suppliers and R&D	GE	Thorn EMI (UK); OSRAM (G); Siemens (G)	Sumitomo Chemica

source: Major players

SWOT analysis

Strengths	Weaknesses
• Capability for innovation • Production of base materials for OLED manufacture • Process equipment manufacture is easy.	• Lack of industrial productive capacity or eco-system to support low-cost volume production • Capability to bring innovations to market – i.e. probability of export market success • Lack of branded consumer goods suppliers apart from mobile handsets – e.g. Nokia
Opportunities	Threats
• Possible renaissance in manufacturing at low-cost • Use of IPR – with mitigations through agreements • Expansion in base materials supply and process equipment manufacture for low temperatures	• Older technologies – TFT-LCDs which improve technically – become cheaper, flexible, lower power demands and better colour/contrast, scale up larger, etc, make existing (LCD) players far stronger • Strong competitive position and behaviour of current major players globally and market make market entry difficult or increasingly impossible

Market Forecast

OLED Lighting Market Forecast

OLED lighting will pick up in 2011, and reach $6.3B by 2018.
The OLED lighting market will reach $1.5B by 2015, and $6.3B by 2018.
Large investments have been made in OLED lighting in the EU, US, Japan and Korea.
There are about 20 OLED lighting organizations worldwide. Europe is currently the leading participant in OLED lighting in terms of projects numbers, government funding, and participating companies.
Over 100 companies and universities are currently working on OLED lighting.

OLED Lighting Market Forecast

OLED TV Market Forecast

OLED TV sets will account for around half of all revenue for OLED panels in 2012, growing rapidly from just $150 million in 2011 to $1.5 billion in 2013.
iSuppli’s similarly forecasts the global OLED TV market will reach 2.8 million units by 2013, managing a compound annual growth rate (CAGR) of 212.3% from just 3,000 units in 2007.
In terms of global revenue, OLED TV will hit $1.4 billion by 2013, increasing at a CAGR of 206.8% from $2 million in 2007.

OLED TV Market Forecast

OLED Dispaly Market Forecast

OLED display market will grow to $5.5 billion by 2015, from $0.6 billion in 2008, with a CAGR of 37%. Currently, this growth is being driven by the adoption of active matrix OLED (AMOLED) displays for the primary display in mobile phones and portable media players.

OLED Display Market Forecast

Recent Licensing Activities in OLED Segment

Licensor	Licensee	Date	Details
Global OLED Technology LLC	OLEDWorks	6th Dec 2011	Under the terms of the royalty-bearing license, OLEDWorks is granted the right to use certain GOT patents in connection with OLEDWorks’ commercialization of specified OLED lighting-related products.
Universal Display	Moser Baer	8th Feb 2011	Moser Baer agreed to license Universal’s OLED technology and purchase UniversalPHOLED (phosphorescent OLED) materials for white OLED panel manufacturing. The companies have agreed to work together for five years in the development of Moser Baer’s US-based OLED panel manufacturing project.
Universal Display	Pioneer Corp	29th Sep 2011	Pioneer is supposed to use Universal Display’s highly efficient, high-performance UniversalPHOLED® technology and materials for the manufacture and sale of OLED lighting products
DuPont	Samsung	3rd Nov 2011	Samsung needed new technology for its larger models for televisions and hoped to benefit from DuPont’s recent innovations.

Landscape Analysis Of Top-Emmission OLED

Competitor Landscape

Top Assignee

Filing trends over the publication years

IP activity based on publication years

Filing trends over the priority years

IP activity based on priority years

Geographical Distribution based on family members

The geographical distribution is based on 10 sample patent numbers along with all their family members.

Geographical Distribution based on Family members of OLED

Key Inventor Mapping

S.No	Inventor	2000	2001	2002	2003	2004	2005	2006	2007	2008	2009	2010	Total Result
1	Cok, Ronald			1	3	22	18	17	14	15	4	2	96
2	Park, Jin Woo								18	2			20
3	Choi, Beohm Rock						1	6	7	2			16
4	Kim, Nam Deog							7	6	3			16
5	Tyan, Yuan Sheng					2	7	3	1	1	1		15
6	Winters, Dustin					2	5	5	2	1			15
7	Choi, Dong Soo								13	1			14
8	Choi, Joon Hoo						2	3	4	5			14
9	Kwak, Won Kyu						1	1	9	1	1	1	14
10	Miller, Michael					4	4	2	1	1	1	1	14
11	Park, Jae Yong				2	8	4						14
12	Shore, Joel					2	2	5	3	1	1		14
13	Arnold, Andrew					4	5	1	1	1	1		13
14	Boroson, Michael				1		4	3	1		4		13
15	Goh, Joon Chul						1	4	5	3			13
16	Tanaka, Masahiro						1	1	1	5	4	1	13
17	Choong, Vi En						5	5	2				12
18	Ghosh, Amalkumar	2	1			1	3	5					12
19	Kim, Eun Ah						1	2				9	12
20	Kobayashi Hidekazu						1	2	2	5	1	1	12
21	Total Result	2	1	1	6	45	67	72	90	47	18	15	362

Most Cited Patents

S.No	Publication Number	Assignee/Applicant	Title	Publication Date	Count of Citing Patents
1	US6069443A	Fed Corporation	Passive matrix OLED display	30/05/2000	97
2	US6366017B1	Agilent Technologies	Organic light emitting diodes with distributed bragg reflector	02/04/2002	80
3	US20020197511A1	United Of America As Respresented By The Secretary Of The Air Force	High efficiency multi-color electro-phosphorescent OLEDS	26/12/2002	51
4	US6265820B1	Emagin Corporation,De	Heat removal system for use in organic light emitting diode displays having high brightness	24/07/2001	50
5	US20020195968A1	IBM	Oled current drive pixel circuit	26/12/2002	44
6	US20020186209A1	Eastman Kodak Company	Touch screen for use with an OLED display	12/12/2002	42
7	US20030127973A1	Universal Display Corporation	OLEDs having increased external electroluminescence quantum efficiencies	10/07/2003	41
8	US6844673B1	Alien Technology Corporation	Split-fabrication for light emitting display structures	18/01/2005	38
9	US20040174116A1	Universal Display Corporation	Transparent electrodes	09/09/2004	36
10	US20050194896A1	Hitachi Displays Ltd.	Light emitting element and display device and illumination device using the light emitting element	08/09/2005	35
11	US20020074935A1	Universal Display Corporation	Highly stable and efficient OLEDs with a phosphorescent-doped mixed layer architecture	20/06/2002	35
12	US20040217702A1	Corning Incorporated	Light extraction designs for organic light emitting diodes	04/11/2004	33
13	US20020030647A1	Universal Display Corporation	Uniform active matrix oled displays	14/03/2002	32
14	US20050248270A1	Eastman Kodak Company	Encapsulating OLED devices	10/11/2005	31
15	US20040113875A1	Eastman Kodak Company	Color oled display with improved power efficiency	17/06/2004	29
16	US20030230972A1	Eastman Kodak Company	Oled display having color filters for improving contrast	18/12/2003	28
17	US20050040756A1	Eastman Kodak Company	OLED device having microcavity gamut subpixels and a within gamut subpixel	24/02/2005	27
18	US6670772B1	Eastman Kodak Company	Organic light emitting diode display with surface plasmon outcoupling	30/12/2003	26
19	US20040061136A1	Eastman Kodak Company	Organic light-emitting device having enhanced light extraction efficiency	01/04/2004	26

Most Cited Patents Mapping

Most Cited Patents

Technology Mapping

In OLED devices not all internally generated light is coupled out of the device (only 20%-50%), which reduces the device efficiency and lifetime.
Modification in structures are applied to improve outcouple efficiency in order to enhance the efficiency and lifetime of top emission OLEDs.
Below is a snapshot of how various organizations are using different design structures, using the same principle of internal reflection, to achieve higher out-coupling efficiencies.

Comparison of out coupling of waveguiding light in top-emission polyLED stack

Some light is reflected out of the OLED at stray angles in typical cases. By using a barrier material (form of microparticles) in the cathode layer, this light at stray angles hits the barrier material, and some of it is reflected back and guided out at the right angles, reducing light loss.

Microparticles are incorporated in the substrate, which prevents light loss by reflecting light emitted at stray angles.

A highly reflective anode is provided made of Aluminium or Silver, with a mirror like finish, to reflect light.

A shielding layer is provided below the anode, across its entire surface, thus increasing the surface area from which light can be reflected outside.

The reflective layer, anode, is made of a highly reflective surface like Aluminium alloy or silver.

Conclusion

The innovation is towards:

Incorporating micro-particles structure over the substrate that provide a reflective surface.
Highly reflective materials using metals like Molybdenum etc.

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S. No.	Title	Publication Date	Journal/Conference	Citations Count
1	Electroluminescence from single monolayers of nanocrystals in molecular organic devices	Oct 2002	Nature, Internatinal journal of science.	736
2	Spin-dependent exciton formation in π-conjugated compounds	Aug 2001	Nature, Internatinal journal of science.	220
3	Highly Efficient Organic Devices Based on Electrically Doped Transport Layers	Mar 2007	American Chemical Society Pub.	211
4	Phosphorescent top-emitting organic light-emitting devices with improved light outcoupling	Nov 2002	Applied Physics Letters / Volume 82	111
5	Thin-film permeation-barrier technology for flexible organic light-emitting devices	Jan 2004	IEEE Photonics Society	104
6	Design of flat-panel displays based on organic light-emitting devices	Feb 1998	IEEE Photonics Society	100
7	A new a-Si:H thin-film transistor pixel circuit for active-matrix organic light-emitting diodes	Aug 2003	IEEE Electron Devices Society	86
8	The road to high efficiency organic light emitting devices	Sep 2003	ScienceDirect	87
9	Amorphous silicon thin film transistor circuit integration for organic LED displays on glass and plastic	Sep 2004	IEEE Photonics Society	73
10	Transparent-cathode for top-emission organic light-emitting diodes	Feb 2003	Applied Physics Letters	72

@@ Line 1: / Line 1: @@
-{{TOCrightEx}}
+This report presents a brief introduction to OLED (organic light emitting diode) and technologies available for top emission OLED. A detailed taxonomy for OLED is presented covering parts of the type of OLED, material used, manufacturing, applications among others. A detailed landscape analysis of patent and non-patent literature is done with a focus on Top Emission OLED (TEOLED). The product information of major players in the market is also captured for OLED. The final section of the report covers the existing and future market predictions for OLED.
+[[Image:OLED.png|right|thumb|800px| '''[http://electronics.howstuffworks.com/oled2.htm OLED Working Principle]]]
+=Introduction=
+*OLED technology was firstly developed in 1987 at Eastman Kodak Company by Tang and Van Slyke using small-molecule (sm-OLED). In 1990 Richard Friend, Jeremy Burroughes and Donal Bradley discovered electroluminescence capabilities from conjugated polymers so laying down the foundations for a new generation of flat panel displays.
+*The growing number of electronic devices using organic light emitting diode displays shows that after years of promise, the technology is increasingly finding place in many products. But while OLED displays might challenge LCDs as the screens of choice for smaller gadgets, the technology may not become mainstream for notebook PCs or TVs within this decade.
+*OLED displays use organic compounds that emit light when exposed to an electric current. They are brighter, have better contrast, offer wider viewing angles, use less power, and provide faster response times than liquid crystal displays. OLED screens' thickness is a third of that of LCDs, since they don't need a back-light, and that makes them a good fit for portable electronics devices.
+==Read More? ==
+Click on [[OLED Background]] to read more about OLED.
+Traditional light bulbs were invented more than 130 years ago. Since then the basic principle of creating light remains the same, although the design has been tweaked.An electric current passing through a tungsten wire causes it to heat up and glow white hot.Today, more than 20% of electricity used in US buildings is eaten up by lights and nearly half that amount is used by traditional, incandescent light bulbs. It has been a long-term goal of scientists to come up with something that would reduce this mammoth energy demand.
-==[[Diabetes Overview]]==
+The OLEDs do not heat up like today's light bulbs and so are far more energy efficient and last longer.They also produce a light that is more akin to natural daylight than traditional bulbs. The new polymer uses a fluorescent blue material instead which lasts much longer and uses less energy.
-=== News stories ===
+=Top Emission OLED: Search Strategy=
-* [http://health.msn.com/dietfitness/articlepage.aspx?cp-documentid=100144067 One of the top stories on Reddit - Dec 26, 2006]
+The present study on the IP activity in the area of OLED with focus on '''''Top Emission OLED (TEOLED)''''' is based on a search conducted on Micropat.
-* [http://www.nytimes.com/2006/12/26/health/26workplace.html?hp&ex=1167195600&en=79c108081b2bd0e3&ei=5094&partner=homepage Home page story on New York Times - Dec 26, 2006]
-* "Today nearly one out of every 10 adults in the US has diabetes. Among people over 60, that figure is even higher - one in five. But what's most alarming is that many people don't know they have diabetes until they develop one of its terrible complications - like heart disease, blindness or stroke.": University of California, San Francisco Diabetes Center
-===Total Prevalence of Diabetes & Pre-diabetes (US)===
+==Control Patents==
-* '''Total''': 20.8 million children and adults -- 7.0% of the population -- have diabetes.
+{|border="2" cellspacing="0" cellpadding="4" width="100%"
-* '''Diagnosed''': 14.6 million people
+| style="background-color:#4f81bd;padding:0.079cm;"| <center>'''S. No. '''</center>
-* '''Undiagnosed''': 6.2 million people
+| style="background-color:#4f81bd;padding:0.079cm;"| <center>'''Patent/Publication No. '''</center>
-* '''Pre-diabetes''': 54 million people
+| style="background-color:#4f81bd;padding:0.079cm;"| <center>'''Publication Date(mm/dd/yyyy) '''</center>
-* 1.5 million new cases of diabetes were diagnosed in people aged 20 years or older in 2005. ([http://www.diabetes.org/diabetes-statistics/prevalence.jsp Source])
+| style="background-color:#4f81bd;padding:0.079cm;"| <center>'''Assignee/Applicant '''</center>
+| style="background-color:#4f81bd;padding:0.079cm;"| <center>'''Title '''</center>
-===Calories and food consumption - US===
+|-
-<table>
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>1</center>
-  <tr>
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>[http://patft.uspto.gov/netacgi/nph-Parser?Sect1=PTO1&Sect2=HITOFF&d=PALL&p=1&u=%2Fnetahtml%2FPTO%2Fsrchnum.htm&r=1&f=G&l=50&s1=7791271.PN.&OS=PN/7791271&RS=PN/7791271 US7791271B2]</center>
-    <td>[[image:calories consumption.jpeg|thumb|center|380 px]]
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>7/9/2010</center>
-    </td>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Global OLED Technology LLC
-    <td>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Top-Emitting OLED Device With Light-Scattering Layer and Color-Conversion.
-    </td>
-  </tr>
-   <tr>
-    <td>[[image:food consumption.jpeg|thumb|center|400 px]]
-    </td>
-    <td>
-    </td>
-  </tr>
-  <tr>
-    <td>[[image:Milk.jpeg|thumb|center|380 px]]
-    </td>
-    <td>[[image:Fat consumption.jpeg|thumb|center|400 px]]
-    </td>
-  </tr>
-  <tr>
-    <td>[[image:Vegetables.jpeg|thumb|center|380 px]]
-    </td>
-    <td>[[image:Fruits.jpeg|thumb|center|400 px]]
-    </td>
-  </tr>
-  <tr>
-    <td>[[image:Meat products.jpeg|thumb|center|380 px]]
-    </td>
-    <td>[[image:Sweetener consumption.jpeg|thumb|center|400 px]]
-    </td>
-  </tr>
-</table>
-* Drinking Coffee Helps Lower the Chance of Getting of Type 2 Diabetes [http://www.diabetes.org/diabetes-research/summaries/Smith-drinking-coffee-lowers-risk.jsp Source]
+|-
-* Coffee and Green Tea May Help Prevent Type 2 Diabetes [http://www.diabetes.org/diabetes-research/summaries/iso-coffee-green-tea.jsp Source]
+| style="padding:0.079cm;"| <center>2</center>
+| style="padding:0.079cm;"| <center>[http://patft.uspto.gov/netacgi/nph-Parser?Sect1=PTO1&Sect2=HITOFF&d=PALL&p=1&u=%2Fnetahtml%2FPTO%2Fsrchnum.htm&r=1&f=G&l=50&s1=7781961.PN.&OS=PN/7781961&RS=PN/7781961 US7781961B2]</center>
+| style="padding:0.079cm;"| <center>08/24/2010</center>
+| style="padding:0.079cm;"| Novaled AG
+| style="padding:0.079cm;"| Top Emitting, Electroluminescent Component With Frequency Conversion Centres.
-===Maintaining a healthy weight is a challenge for most Americans===
+|-
-*66.3% of the adult population in the US weigh more than is healthy Where you carry your fat is important. Fat in the mid-section – visceral fat – is worse, as this fat surrounds and invades vital organs. Few Americans add muscle and bone after their early twenties so nearly all added weight is fat
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>3</center>
-* Daily caloric intake is the number of calories needed per day to maintain your current weight. Maintaining a healthy weight is a balancing act of calories consumed versus calories burned
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>[http://patft.uspto.gov/netacgi/nph-Parser?Sect1=PTO1&Sect2=HITOFF&d=PALL&p=1&u=%2Fnetahtml%2FPTO%2Fsrchnum.htm&r=1&f=G&l=50&s1=7002293.PN.&OS=PN/7002293&RS=PN/7002293 US7002293B2]</center>
-Weight change = calories in – calories out
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>02/21/2006</center>
-* Small increases in daily caloric intake cause increases in body fat mass (Figure 1)
+| style="background-color:#DCE6F1;padding:0.079cm;"| Eastman Kodak Company
-[[Image:Maintaining_a_healthy_weight_is_a_challenge_for_most_Americans_01.png|Figure 1. Cumulative effect of small daily imbalances in energy intake on body fat mass]]
+| style="background-color:#DCE6F1;padding:0.079cm;"| Organic Light Emitting Diode With Improved Light Emission Through The Cathode.
-* From 1971-2000 there was a statistically significant increase in average caloric intake—2,450 kcals to 2,618 kcals in men (''P ''<nowiki><</nowiki> 0.01) and 1,541 kcals to 1,877 kcals in women (''P ''<nowiki><</nowiki> 0.01) (Figure 2)
+|-
-[[Image:Maintaining_a_healthy_weight_is_a_challenge_for_most_Americans_02.png|Figure 2. Caloric intake from 1971-2000]]
+| style="padding:0.079cm;"| <center>4</center>
+| style="padding:0.079cm;"| <center>[http://patft.uspto.gov/netacgi/nph-Parser?Sect1=PTO1&Sect2=HITOFF&d=PALL&p=1&u=%2Fnetahtml%2FPTO%2Fsrchnum.htm&r=1&f=G&l=50&s1=6770502.PN.&OS=PN/6770502&RS=PN/6770502 US6770502B2]</center>
+| style="padding:0.079cm;"| <center>3/8/2004</center>
+| style="padding:0.079cm;"| Eastman Kodak Company
+| style="padding:0.079cm;"| Method Of Manufacturing a Top-emitting OLED display Device with Desiccant Structures.
-* Today, adult men and adult women are almost 25 pounds heavier than 40 years ago (Figure 2). Children aged 6-11 are almost 9 pounds heavier. Teen boys and girls are 15 and 12 pounds heavier respectively, topping the scales in 2002 at 141 pounds and 130 pounds
+|-
-* Obesity ranks low on the list of serious health problems. Only 9% of respondents to a national survey indicated their own weight was a problem, despite more than 50% were overweight
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>5</center>
-[[Image:Maintaining_a_healthy_weight_is_a_challenge_for_most_Americans_03.png|Figure 3. Mean weight for men and women over the last 40 years]]
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>[http://appft1.uspto.gov/netacgi/nph-Parser?Sect1=PTO1&Sect2=HITOFF&d=PG01&p=1&u=%2Fnetahtml%2FPTO%2Fsrchnum.html&r=1&f=G&l=50&s1=%2220080169757%22.PGNR.&OS=DN/20080169757&RS=DN/20080169757 US20080169757A1]</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>07/17/2008</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| TPO Displays Corp.
+| style="background-color:#DCE6F1;padding:0.079cm;"| Top-Emitting Organic Electroluminescent Display
-* As the average daily caloric intake has increased, the percentage of caloric intake from fat decreased, and the percentage from carbohydrates increased significantly for both men and women (Figures 4 and 5)
+|-
+| style="padding:0.079cm;"| <center>6</center>
+| style="padding:0.079cm;"| <center>[http://appft1.uspto.gov/netacgi/nph-Parser?Sect1=PTO1&Sect2=HITOFF&d=PG01&p=1&u=%2Fnetahtml%2FPTO%2Fsrchnum.html&r=1&f=G&l=50&s1=%2220060043373%22.PGNR.&OS=DN/20060043373&RS=DN/20060043373 US20060043373A1]</center>
+| style="padding:0.079cm;"| <center>2/3/2006</center>
+| style="padding:0.079cm;"| Industrial Technology Research Institute
+| style="padding:0.079cm;"| Method for Manufacturing a Pixel Array of Top Emitting OLED.
-[[Image:Maintaining_a_healthy_weight_is_a_challenge_for_most_Americans_04.png|Figure 4. Percentage of caloric intake from fat from 1971-2000]]
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>7</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>[http://appft1.uspto.gov/netacgi/nph-Parser?Sect1=PTO1&Sect2=HITOFF&d=PG01&p=1&u=%2Fnetahtml%2FPTO%2Fsrchnum.html&r=1&f=G&l=50&s1=%2220050236629%22.PGNR.&OS=DN/20050236629&RS=DN/20050236629 US20050236629A1]</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>10/27/2005</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Samsung Corp.
+| style="background-color:#DCE6F1;padding:0.079cm;"| Top Emission Organic Light Emitting Diode Display Using Auxiliary Electrode to Prevent Voltage Drop of Upper Electrode and Method of Fabricating the Same.
-[[Image:Maintaining_a_healthy_weight_is_a_challenge_for_most_Americans_05.png|Figure 5. Percentage of caloric intake from carbohydrates from 1971-2000]]
+|-
+| style="padding:0.079cm;"| <center>8</center>
+| style="padding:0.079cm;"| <center>[http://v3.espacenet.com/searchResults?NUM=EP1489671A2&DB=EPODOC&submitted=true&locale=en_V3&ST=number&compact=false EP1489671A2]</center>
+| style="padding:0.079cm;"| <center>12/22/2004</center>
+| style="padding:0.079cm;"| Global OLED Technology LLC
+| style="padding:0.079cm;"| Method of Making a Top-Emitting OLED device having Improved Power Distribution
-'''Dietary habits can help pile on the pounds'''
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>9</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>[http://v3.espacenet.com/searchResults?NUM=EP1029336A1&DB=EPODOC&submitted=true&locale=en_V3&ST=number&compact=false EP1029336A1]</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>08/23/2000</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Fed Corp.
+| style="background-color:#DCE6F1;padding:0.079cm;"| Top Emitting OLED with Refractory Metal Compounds as Bottom Cathode .
-* Consumption of food away from home, increased consumption of salty snacks, soft drinks and pizza, and increased portion sizes have contributed to increased caloric intake
+|-
-* Over the last 20 years portions have grown significantly
+| style="padding:0.079cm;"| <center>10</center>
-** With the exception of white bread, the sizes of marketplace portions exceed federal standards by at least a factor of 2 and sometime 8<sup><nowiki>[</nowiki></sup>
+| style="padding:0.079cm;"| <center>[http://www.wipo.int/pctdb/en/wo.jsp?WO=2001057904 WO2001057904A1]</center>
-o Items in fast food restaurants are 2 to 5 times larger than 2 decades ago due to the increased variety of available portion sizes
+| style="padding:0.079cm;"| <center>9/8/2001</center>
-[[Image:Maintaining_a_healthy_weight_is_a_challenge_for_most_Americans_06.png|Figure 6. Increase in portion size from 1977-1996]]
+| style="padding:0.079cm;"| Emagin Corp.
-* The increases in portion size are significant and result in more calories consumed. An added 10 kcal/day of unexpended energy is equivalent to an extra pound of weight per year (Figure 6)
+| style="padding:0.079cm;"| Low Absorption Sputter Protection Layer for OLED Structure.
-'''Americans need to pay more attention to what we eat and our activity levels'''
+|}
-* Recent guidelines from the American Heart Association focus on both a healthy diet and healthy lifestyle to reduce the risk of developing cardiovascular disease
-* Recommended calorie intake will differ for individuals based on age, gender, and activity level, as seen in the Dietary Guidelines for Americans 2005, available at: [http://www.healthierus.gov/dietaryguidelines www.healthierus.gov/dietaryguidelines].
-* Lifestyle activity levels are directly tied to calorie consumption in the body. Lifestyle activity levels have been defined as:
-** Sedentary means a lifestyle that includes only the light physical activity associated with typical day-to-day life
-** Moderately active means a lifestyle that includes physical activity (consuming 3.5 to 7 calories/min) equivalent to walking about 1.5 to 3 miles per day at 3 to 4 miles per hour, in addition to the light physical activity associated with typical day-to-day life
-** Active means a lifestyle that includes physical activity (consuming <nowiki>></nowiki> 7 calories/minute) equivalent to walking more than 3 miles per day at 3 to 4 miles per hour, in addition to the light physical activity associated with typical day-to-day life
-* The recent Dietary Reference Intakes publication recommends
+==Patent Classes==
-** Fat intake:
-*** 30% to 40% kcal in children 1 to 3 years
-*** 25% to 35% kcal in children 4 to 18 years
-*** 20% to 35% kcal in adults
-** Protein intake:
-*** 5% to 20% kcal in children 1 to 3 years old
-*** 10% to 30% kcal in children 4 to 18 years old
-*** 10% to 35% kcal in adults
-** Carbohydrate intake:
-*** 45% to 65% kcal in all children and adults
-'''Diet and exercise can make a difference in your overall health'''
+{|border="2" cellspacing="0" cellpadding="4" width="100%"
-* Weight reduction requires a careful balance of fat, protein and carbohydrate intake (Figure 7)
+| style="background-color:#4f81bd;padding:0.079cm;"| <center>'''S. No.'''</center>
-[[Image:Maintaining_a_healthy_weight_is_a_challenge_for_most_Americans_07.png|Figure 7. Nutrient content of a weight-reducing diet]]
+| style="background-color:#4f81bd;padding:0.079cm;"| <center>'''Class No.'''</center>
-* The Nurse<nowiki>’</nowiki>s Health Study and the Health Professionals Follow-up Study demonstrated that middle-aged women and men who gained 11-22 pounds after age 20 were up to 3 times more likely to develop heart disease, high blood pressure, type 2 diabetes, and gallstones than those who gained 5 pounds or fewer
+| style="background-color:#4f81bd;padding:0.079cm;"| <center>'''Class Type'''</center>
-* Weight loss of 5% to 15% of total body weight can lower an individual<nowiki>’</nowiki>s chance of heart disease or having a stroke, as weight loss may improve blood pressure, triglycerides, cholesterol levels, decrease inflammation throughout the body, and improve mental health and quality of life. Moderate intentional weight loss sustained over time may be associated with reduced mortality
+| style="background-color:#4f81bd;padding:0.079cm;"| <center>'''Definition'''</center>
-* Only 8% of American adults are aware of the link between overweight and cancer.<br>Overweight leads to insulin resistance and may be linked to breast cancer, aggressive prostate cancer, colorectal cancer and endometrial, kidney, pancreatic and esophagus cancer as well as lymphomas
-* Higher levels of physical activity promote long-term weight loss better than conventional recommendations for low to moderate activity (Figure 8)
-[[Image:Maintaining_a_healthy_weight_is_a_challenge_for_most_Americans_08.png|Figure 8. Effect of physical activity on body weight]]
-* People who exercise regularly achieve better maintenance of weight loss and have beneficial effects on their cardiovascular, physical and psychological well-being
-* Compared to a low-fat diet or conventional weight loss diet, a low-carbohydrate diet program had better participant retention and greater weight loss—there were beneficial effects on serum triglyceride levels and high density lipoprotein as well as improved glycemic control
-* Diet and exercise may prevent or delay the onset of diabetes
-** Modest weight loss and changes in lifestyle reduced the 3-year incidence of type 2 diabetes by 58%
-** Weight loss strategies using dietary, physical activity or behavioral interventions produced significant improvements in weight among person with pre-diabetes, and a significant decrease in diabetes incidence
-* Dietary guidelines encourage eating fewer calories, being more active and making wise food choices. Making wise food choices involves a careful look at nutrition labels and calories consumed. Carbohydrates and protein each contain 4 calories/gram while alcohol and fat contain 7 calories and 9 calories per gram, respectively. Don<nowiki>’</nowiki>t waste the daily allotment with empty calories – calories do count
-===The Universe for Reducing Calories is Expanding===
+|-
-'''Prevalence of overweight and obese adults is increasing'''
+| style="padding:0.079cm;"| <center>1</center>
-* Obesity among all ages, races, educational levels, and smoking levels is increasing
+| style="padding:0.079cm;"| [http://www.uspto.gov/web/patents/classification/uspc257/sched257.htm#C257S040000 257/40]
-* Between 1991 and 2001 prevalence of obesity increased by 74% – 21.4 million obese men and 22.9 million obese women
+| style="padding:0.079cm;"| USPC
-* During this same time period the percentage of overweight adults increased from 45% to 58%
+| style="padding:0.079cm;"| Active solid-state devices (e.g., transistors, solid-state diodes) /'''Organic semiconductor material '''
-* In 2004, obese adults represented ≥ 25% of the adult population in 9 of the 50 states (Figure 1)
-[[Image:Maintaining_a_healthy_weight_is_a_challenge_for_most_Americans_09.png|Figure 1. Prevalence of obesity among US adults, 1991, 1996 and 2004.]]
-* In 2003, more than 136,000,000 American adults were overweight, and this number continues to grow
+|-
-* Recent evidence suggests that increases in body weight in women may be leveling off, though no specific reason for the trend was given
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>2</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| [http://www.uspto.gov/web/patents/classification/uspc257/sched257.htm#C257SE51018 257/E51.018 ]
+| style="background-color:#DCE6F1;padding:0.079cm;"| USPC
+| style="background-color:#DCE6F1;padding:0.079cm;"| Active solid-state devices (e.g., transistors, solid-state diodes) / organic solid state devices, processes or apparatus peculiar to manufacture or treatment of such devices or of parts thereof / structural detail of device / '''light-emitting organic solid-state device with potential or surface barrier '''
-'''Prevalence of overweight among children has tripled'''
+|-
-* Figure 2 shows the change in percent of overweight children, 6-12 and 12-19 years of age, from data analyzed in the mid 1960s and at the turn of the century
+| style="padding:0.079cm;"| <center>3</center>
-* In 2003-2004, '''''17.1% of children and adolescents 2-19 years of age (over 12.5 million) were overweight'''''
+| style="padding:0.079cm;"| [http://www.uspto.gov/web/patents/classification/uspc257/sched257.htm#C257SE51019 257/E51.019 ]
-* Prevalence of overweight among girls increased from 13.8% in 1999 to 16.0% in 2004
+| style="padding:0.079cm;"| USPC
-* Prevalence of overweight among boys increased from 14.0% to 18.2% during the same time frame
+| style="padding:0.079cm;"| Active solid-state devices (e.g., transistors, solid-state diodes) / organic solid state devices, processes or apparatus peculiar to manufacture or treatment of such devices or of parts thereof / structural detail of device / light-emitting organic solid-state device with potential or surface barrier / '''Electrode '''
-* Overweight is associated with a number of comorbidities in children
-* Metabolic, orthopedic, cardiovascular, psychological, neurological, hepatic, pulmonary and renal comorbid conditions can exist
-[[Image:Maintaining_a_healthy_weight_is_a_challenge_for_most_Americans_10.png|Figure 2. Prevalence of pediatric obesity]]
-'''Body mass index (BMI), calculated with height and weight, is used to define overweight and obesity'''
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>4</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| [http://www.uspto.gov/web/patents/classification/uspc257/sched257.htm#C257SE5102 257/E51.02 ]
+| style="background-color:#DCE6F1;padding:0.079cm;"| USPC
+| style="background-color:#DCE6F1;padding:0.079cm;"| Active solid-state devices (e.g., transistors, solid-state diodes) / organic solid state devices, processes or apparatus peculiar to manufacture or treatment of such devices or of parts thereof / structural detail of device / light-emitting organic solid-state device with potential or surface barrier / Electrode '''/ Encapsulation '''
-* The NHLBI defines underweight, normal weight, overweight and 3 classes of obesity based on BMI (Table 1)
+|-
-* BMI = kg/m<sup>2</sup> <nowiki>{</nowiki>BMI = weight (pounds) x 703 ÷ height squared (inches)<nowiki>}</nowiki>
+| style="padding:0.079cm;"| <center>5</center>
-* BMI and waist circumference correlate with the amount of body fat; both are surrogate markers of body fat
+| style="padding:0.079cm;"| [http://www.uspto.gov/web/patents/classification/uspc257/sched257.htm#C257SE51021 257/E51.021 ]
+| style="padding:0.079cm;"| USPC
+| style="padding:0.079cm;"| Active solid-state devices (e.g., transistors, solid-state diodes) / organic solid state devices, processes or apparatus peculiar to manufacture or treatment of such devices or of parts thereof / structural detail of device / light-emitting organic solid-state device with potential or surface barrier / Electrode '''/ Arrangements for extracting light from device (e.g., Bragg reflector pair) '''
-'''Table 1. Defining overweight and obesity.'''
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>6</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| [http://www.uspto.gov/web/patents/classification/uspc257/sched257.htm#C257SE51018 257/E51.022 ]
+| style="background-color:#DCE6F1;padding:0.079cm;"| USPC
+| style="background-color:#DCE6F1;padding:0.079cm;"| Active solid-state devices (e.g., transistors, solid-state diodes) / organic solid state devices, processes or apparatus peculiar to manufacture or treatment of such devices or of parts thereof / structural detail of device / light-emitting organic solid-state device with potential or surface barrier / '''Multicolor organic light-emitting device (OLED) '''
+|-
+| style="padding:0.079cm;"| <center>7</center>
+| style="padding:0.079cm;"| [http://www.uspto.gov/web/patents/classification/uspc313/sched313.htm#C313S504000 313/504]
+| style="padding:0.079cm;"| USPC
+| colspan="12"  style="padding:0.079cm;"| Electric lamp and discharge devices/solid-state type/ with particular phosphor or electrode material / '''Organic phosphor '''
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>8</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| [http://www.wipo.int/ipcpub/#refresh=page¬ion=scheme&version=20110101&symbol=H01L0027280000 H01L 27/28 ]
+| style="background-color:#DCE6F1;padding:0.079cm;"| IPC
+| style="background-color:#DCE6F1;padding:0.079cm;"| Semiconductor devices; electric solid state devices not otherwise provided for / devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate / '''including components using organic materials as the active part, or using a combination of organic materials with other materials as the active part'''
+|-
+| style="padding:0.079cm;"| <center>9</center>
+| style="padding:0.079cm;"| [http://www.wipo.int/ipcpub/#refresh=page¬ion=scheme&version=20110101&symbol=H01L0027320000 H01L 27/32 ]
+| style="padding:0.079cm;"| IPC
+| style="padding:0.079cm;"| Semiconductor devices; electric solid state devices not otherwise provided for / devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate / including components using organic materials as the active part, or using a combination of organic materials with other materials as the active part / '''with components specially adapted for light emission, e.g. flat-panel displays using organic light-emitting diodes'''
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>10</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| [http://www.wipo.int/ipcpub/#refresh=page¬ion=scheme&version=20110101&symbol=H01L0051500000 H01L 51/50 ]
+| style="background-color:#DCE6F1;padding:0.079cm;"| IPC
+| style="background-color:#DCE6F1;padding:0.079cm;"| Semiconductor devices; electric solid state devices not otherwise provided for / solid state devices using organic materials as the active part, or using a combination of organic materials with other materials as the active part; processes or apparatus specially adapted for the manufacture or treatment of such devices, or of parts thereof / '''specially adapted for light emission, e.g. organic light emitting diodes (oled) or polymer light emitting devices (pled)'''
+|-
+| style="padding:0.079cm;"| <center>11</center>
+| style="padding:0.079cm;"| [http://www.wipo.int/ipcpub/#refresh=page¬ion=scheme&version=20110101&symbol=H01L0051520000 H01L 51/52 ]
+| style="padding:0.079cm;"| IPC
+| style="padding:0.079cm;"| Semiconductor devices; electric solid state devices not otherwise provided for / solid state devices using organic materials as the active part, or using a combination of organic materials with other materials as the active part; processes or apparatus specially adapted for the manufacture or treatment of such devices, or of parts thereof / '''Details of devices'''
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>12</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| [http://www.wipo.int/ipcpub/#refresh=page¬ion=scheme&version=20110101&symbol=H01L0051560000 H01L ][http://www.wipo.int/ipcpub/#refresh=page¬ion=scheme&version=20110101&symbol=H01L0051560000 51/56 ]
+| style="background-color:#DCE6F1;padding:0.079cm;"| IPC
+| style="background-color:#DCE6F1;padding:0.079cm;"| Semiconductor devices; electric solid state devices not otherwise provided for/specially adapted for sensing infra-red radiation, light, electromagnetic radiation of shorter wavelength, or corpuscular radiation; specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation / '''Processes or apparatus specially adapted for the manufacture or treatment of such devices or of parts thereo'''
+|}
+==Concept Table==
+{|border="2" cellspacing="0" cellpadding="4" width="55%"
+| rowspan="2" align = "center" bgcolor = "#4F81BD" width="38"|<font color="#FFFFFF">'''S. No.'''</font>
+|align = "center" bgcolor = "#4F81BD"|<font color="#FFFFFF">'''Concept 1'''</font>
+|align = "center" bgcolor = "#4F81BD"|<font color="#FFFFFF">'''Concept 2'''</font>
+|-
+| style="background-color:#4f81bd;padding:0.079cm;"| <center>'''Top emission'''</center>
+| colspan="3"  style="background-color:#4f81bd;padding:0.079cm;"| <center>'''Organic Light Emitting Diode'''</center>
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>1</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| top emitting
+| style="background-color:#DCE6F1;padding:0.079cm;"| oled
+|-
+| style="padding:0.079cm;"| <center>2</center>
+| style="padding:0.079cm;"| top emissive
+| colspan="2"  style="padding:0.079cm;"| polymer led
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>3</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| top emission
+| colspan="2"  style="background-color:#DCE6F1;padding:0.079cm;"| light emitting polymer diode
+|-
+| style="padding:0.079cm;"| <center>4</center>
+| style="padding:0.079cm;"| toled
+| colspan="2"  style="padding:0.079cm;"| organic led
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>5</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| teoled
+| colspan="2"  style="background-color:#DCE6F1;padding:0.079cm;"| organic electroluminescent diode
+|-
+| style="padding:0.079cm;"| <center>6</center>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| foled
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>7</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"|
+| style="background-color:#DCE6F1;padding:0.079cm;"| sm-oled
+|-
+| style="padding:0.079cm;"| <center>8</center>
+| style="padding:0.079cm;"|
+| colspan="2"  style="padding:0.079cm;"| small molecule oled
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>9</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"|
+| style="background-color:#DCE6F1;padding:0.079cm;"| amoled
+|-
+| style="padding:0.079cm;"| <center>10</center>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| pmoled
+|}
+==Micropatent Search Strategy==
+'''Database:''' Micropat<br>
+'''Patent coverage:''' US, EP, WO, JP, DE, GB, FR<br>
+'''Time line:''' 1836/01/01 to 2011/02/20
+{|border="2" cellspacing="0" cellpadding="4" width="100%"
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''S. No.'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Concept'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Scope'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Search String'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''No. of Hits'''</center>
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>1</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Classes - OLED
+| style="background-color:#DCE6F1;padding:0.079cm;"| Any Classification
+| style="background-color:#DCE6F1;padding:0.079cm;"| H01L005150* OR H01L005152* OR H01L005156 OR H05B003308P OR 257E51.022
+| style="background-color:#DCE6F1;padding:0.079cm;"| 63152
+|-
+| style="padding:0.079cm;"| <center>2</center>
+| style="padding:0.079cm;"| Classes - Organic Semiconductor Devices
+| style="padding:0.079cm;"| Any Classification
+| style="padding:0.079cm;"| 313504 OR 257040 OR 257E51.018 OR 257E51.019 OR 257E51.020 OR 257E51.021 OR H01L002728 OR H01L002732
+| style="padding:0.079cm;"| 27601
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>3</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Top Emission keywords
+| style="background-color:#DCE6F1;padding:0.079cm;"| Claims, Title or Abstract
+| style="background-color:#DCE6F1;padding:0.079cm;"| ((top emitting) OR (toled) OR (teoled) OR (te-oled) OR (top ADJ2 emitting) OR (top ADJ2 emissive) OR (top ADJ2 emission)) ADJ ((light ADJ emitting ADJ polymer) OR (organic ADJ electro-luminescence ADJ diode) OR (ORganic ADJ electroluminescent ADJ diode) OR (ploymer ADJ light ADJ emitting ADJ diode) OR (ORganic ADJ light ADJ emitting ADJ device) OR (self-luminous ADJ diode) OR (oled) OR (organic led arrays) OR (organic ADJ light ADJ emitting ADJ diode) OR (organic ADJ light ADJ emission ADJ diode) OR (polymer ADJ light ADJ emission ADJ device) OR (organic ADJ electroluminescent device) OR (oel) OR (oleds))
+| style="background-color:#DCE6F1;padding:0.079cm;"| 1141
+|-
+| style="padding:0.079cm;"| <center>4</center>
+| style="padding:0.079cm;"| OLED keywords
+| style="padding:0.079cm;"| Claims, Title or Abstract
+| style="padding:0.079cm;"| ((organic OR (small adj molecule*1) OR polymer*1) adj (lightemitting OR (light adj (emitting OR emission)) OR electroluminescen*2 OR (electro adj luminescen*2))) NEAR3 diode*1) OR oled*2 OR smled*2 OR pled*2 OR (light adj (emitting OR emission) adj polymer*1) OR ((organic OR (small adj molecule*1) OR polymer*1) NEAR3 led*2)
+| style="padding:0.079cm;"| 39392
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>5</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Top emissioin OLED keywords
+| style="background-color:#DCE6F1;padding:0.079cm;"| Claims, Title or Abstract
+| style="background-color:#DCE6F1;padding:0.079cm;"| (((((organic OR (small ADJ molecule*1) OR polymer*1) ADJ (lightemitting OR (light ADJ (emitting OR emission)) OR electroluminescen*2 OR (electro ADJ luminescen*2))) NEAR3 diode*1) OR oled*2 OR smled*2 OR pled*2 OR (light ADJ (emitting OR emission) ADJ polymer*1) OR ((ORganic OR (small ADJ molecule*1) OR polymer*1) NEAR3 led*2)) AND ((top ADJ3 (emissi*2 OR emitting)))) OR (te ADJ oled*2)
+| style="background-color:#DCE6F1;padding:0.079cm;"| 429
+|-
+| style="padding:0.079cm;"| <center>6</center>
+| style="padding:0.079cm;"| Top Emission keywords AND OLED classes
+| style="padding:0.079cm;"| Combined query
+| style="padding:0.079cm;"| 1 AND 3
+| style="padding:0.079cm;"| 809
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>7</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| LED Keywords
+| style="background-color:#DCE6F1;padding:0.079cm;"| Claims, Title or Abstract
+| style="background-color:#DCE6F1;padding:0.079cm;"| ((lightemitting OR (light ADJ (emitting OR emission)) OR electroluminescen*2 OR (electro ADJ luminescen*2)) NEAR3 diode*1) OR led*2 OR oled*2 OR smled*2 OR pled*2
+| style="background-color:#DCE6F1;padding:0.079cm;"| 1617014
+|-
+| style="padding:0.079cm;"| <center>8</center>
+| style="padding:0.079cm;"| Top emission keywords AND Organic semiconductor devices classes AND Top emission keywords
+| style="padding:0.079cm;"| Combined query
+| style="padding:0.079cm;"| 2 AND 7 AND 3
+| style="padding:0.079cm;"| 224
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>9</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Top emissioin OLED keywords
+| style="background-color:#DCE6F1;padding:0.079cm;"| Full patent spec.
+| style="background-color:#DCE6F1;padding:0.079cm;"| (((((organic OR (small ADJ molecule*1) OR polymer*1) ADJ (lightemitting OR (light ADJ (emitting OR emission)) OR electroluminescen*2 OR (electro ADJ luminescen*2))) near3 diode*1) OR oled*2 OR smled*2 OR pled*2 OR (light ADJ (emitting OR emission) ADJ polymer*1) OR ((organic OR (small ADJ molecule*1) OR polymer*1) near3 LED*2)) near3 ((top ADJ3 (emissi*2 OR emitting)))) OR (te ADJ oled*2)
+| style="background-color:#DCE6F1;padding:0.079cm;"| 1506
+|-
+| style="padding:0.079cm;"| <center>10</center>
+| style="padding:0.079cm;"| German Keywords
+| style="padding:0.079cm;"| Full patent spec.
+| style="padding:0.079cm;"| ((top adj3 (emissi*2 OR emitting)) OR (Top NEAR2 emittierende*1)) NEAR3 ((organische NEAR2 (led*1 OR Leuchtdiode*1)) OR (Licht adj emittierende adj Polymer*1) OR oled*1)
+| style="padding:0.079cm;"| 1430
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>11</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| French Keywords
+| style="background-color:#DCE6F1;padding:0.079cm;"| Full patent spec.
+| style="background-color:#DCE6F1;padding:0.079cm;"| ((top ADJ3 (émissive OR émettant)) OR (démission ADJ top) OR (top ADJ3 (emissi*2 OR emitting))) NEAR3 ((diode*1 NEAR3 électroluminescente NEAR3 organique*1) OR ((Polymère*1 OR organiques) ADJ2 led*1) OR (polymère*1 NEAR3 émettant NEAR3 lumière) OR oled*1)
+| style="background-color:#DCE6F1;padding:0.079cm;"| 1412
+|-
+| style="padding:0.079cm;"| <center>12</center>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| Combined query
+| style="padding:0.079cm;"| 5 OR 6 OR 8 OR 9 OR 10 OR 11
+| style="padding:0.079cm;"| 2113 ('''1132''' unique)
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>13</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Control Patents
+| style="background-color:#DCE6F1;padding:0.079cm;"| Patent/Publication No.
+| style="background-color:#DCE6F1;padding:0.079cm;"| WO2001057904A1 OR EP1029336A1 OR EP1489671A2 OR US20050236629A1 OR US20060043373A1 OR US20080169757A1 OR US6770502B2 OR US7002293B2 OR US7781961B2 OR US7791271B2
+| style="background-color:#DCE6F1;padding:0.079cm;"| 10
+|-
+| style="padding:0.079cm;"| <center>14</center>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| Combined query
+| style="padding:0.079cm;"| 12 AND 13
+| style="padding:0.079cm;"| 10
+|}
+==Scientific Literature Search==
+{|border="2" cellspacing="0" cellpadding="4" width="100%"
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''S.No'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Database'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Query'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Limits by Date'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''No.Of Hit'''</center>
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''1'''</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Google scholar
+| style="background-color:#DCE6F1;padding:0.079cm;"| (Top emitting or top emission or top emissive) and ((organic light emitting diode) or (polymer led) or (light emitting polymer led) or (OLED))
+| style="background-color:#DCE6F1;padding:0.079cm;"| 1990-2011
+| style="background-color:#DCE6F1;padding:0.079cm;"| 1840
+|}
+==Search in Japanese database==
+Database: IPDL (Industrial property digital library), Japan
+Date of search: 1900/01/01 to 2011/02/15
 {|border="2" cellspacing="0" cellpadding="4" width="50%"
-|align = "center"|'''Classifications of BMI'''
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''S.No.'''</center>
-|align = "center"|'''BMI'''
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Issue/Publication date'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''F-Term Theme'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''FI/F-term/Facet'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Hits'''</center>
 |-
-|align = "center"|Underweight
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''1'''</center>
-|align = "center"|<nowiki><</nowiki> 18.5 kg/m<sup>2</sup>
+| style="background-color:#DCE6F1;padding:0.079cm;"| 1900/01/01 to 2011/03/02
+| style="background-color:#DCE6F1;padding:0.079cm;"| 3K107
+| style="background-color:#DCE6F1;padding:0.079cm;"| DD03*[AA01+BB01+BB02+BB03+BB04+BB05+BB06+BB07+BB08+DD01+DD04+DD42+DD50+CC01+CC02+CC04+CC06+CC07+ <br>CC08+CC09+EE02+EE03+EE06+EE22+GG01+GG02+GG03+GG04+GG05+GG06+GG07+GG08+GG08]
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''1596'''
+|}
+*F-Terms and theme used in search
+{|border="2" cellspacing="0" cellpadding="4" width="50%"
+| colspan="3"  style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Japanese F-term search'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Definition'''</center>
 |-
-|align = "center"|Normal weight
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Sr. No.'''</center>
-|align = "center"|18.5-24.5 kg/m<sup>2</sup>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term theme'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| 3K107
+| style="background-color:#DCE6F1;padding:0.079cm;"| Electroluminescent light sources
 |-
-|align = "center"|Overweight
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>1</center>
-|align = "center"|25-29.9 kg/m<sup>2</sup>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| AA01
+| style="background-color:#DCE6F1;padding:0.079cm;"| Organic electroluminescent element.
 |-
-|align = "center"|Obesity (Class 1)
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>2</center>
-|align = "center"|30-30.4 kg/m<sup>2</sup>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| BB01
+| style="background-color:#DCE6F1;padding:0.079cm;"| Used in displays.
 |-
-|align = "center"|Obesity (Class 2)
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>3</center>
-|align = "center"|35-39.9 kg/m<sup>2</sup>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| BB02
+| style="background-color:#DCE6F1;padding:0.079cm;"| Used in Lights or light sources
 |-
-|align = "center"|Extreme obesity (Class 3)
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>4</center>
-|align = "center"|<nowiki>></nowiki> 40 kg/m<sup>2</sup>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| BB03
+| style="background-color:#DCE6F1;padding:0.079cm;"| Used in Backlights or the like for liquid crystals
 |-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>5</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| BB04
+| style="background-color:#DCE6F1;padding:0.079cm;"| Used in printer heads
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>6</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| BB05
+| style="background-color:#DCE6F1;padding:0.079cm;"| Used in lasers
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>7</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| BB06
+| style="background-color:#DCE6F1;padding:0.079cm;"| Used in designs or advertisements
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>8</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| BB07
+| style="background-color:#DCE6F1;padding:0.079cm;"| Used in timepieces
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>9</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| BB08
+| style="background-color:#DCE6F1;padding:0.079cm;"| Used in on-board use
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>10</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| DD01
+| style="background-color:#DCE6F1;padding:0.079cm;"| Having feature of all direction of light emission.
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>11</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| DD03
+| style="background-color:#DCE6F1;padding:0.079cm;"| Having top emission.
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>12</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| DD04
+| style="background-color:#DCE6F1;padding:0.079cm;"| Having double sided emission.
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>13</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| DD42
+| style="background-color:#DCE6F1;padding:0.079cm;"| Having Organic materials.
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>14</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| DD50
+| style="background-color:#DCE6F1;padding:0.079cm;"| Structured with Light emitting layers
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>15</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| CC01
+| style="background-color:#DCE6F1;padding:0.079cm;"| Having Light emitting layers
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>16</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| CC02
+| style="background-color:#DCE6F1;padding:0.079cm;"| Light emission characteristics were improved.
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>17</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| CC04
+| style="background-color:#DCE6F1;padding:0.079cm;"| Has an effect on brightness.
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>18</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| CC06
+| style="background-color:#DCE6F1;padding:0.079cm;"| Has an effect on efficiency
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>19</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| CC07
+| style="background-color:#DCE6F1;padding:0.079cm;"| Has an effect on colours.
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>20</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| CC08
+| style="background-color:#DCE6F1;padding:0.079cm;"| Has an effect on Colour purity; Colour temperatures; Light emission wavelengths, including UV
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>21</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| CC09
+| style="background-color:#DCE6F1;padding:0.079cm;"| Has colour balance feature
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>22</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| EE02
+| style="background-color:#DCE6F1;padding:0.079cm;"| Has white light emission.
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>23</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| EE03
+| style="background-color:#DCE6F1;padding:0.079cm;"| Display having Passive matrices
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>24</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| EE06
+| style="background-color:#DCE6F1;padding:0.079cm;"| Display having Active matrices
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>25</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| EE22
+| style="background-color:#DCE6F1;padding:0.079cm;"| Display having with RGB picture elements having different areas
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>26</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| GG01
+| style="background-color:#DCE6F1;padding:0.079cm;"| Dispaly having color filters.
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>27</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| GG02
+| style="background-color:#DCE6F1;padding:0.079cm;"| Apparatus for deposition
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>28</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| GG03
+| style="background-color:#DCE6F1;padding:0.079cm;"| Apparatus for dry methods
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>29</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| GG04
+| style="background-color:#DCE6F1;padding:0.079cm;"| Apparatus for chemical vapour deposition
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>30</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| GG05
+| style="background-color:#DCE6F1;padding:0.079cm;"| Apparatus for evaporation
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>31</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| GG06
+| style="background-color:#DCE6F1;padding:0.079cm;"| Apparatus for sputtering
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>32</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| GG07
+| style="background-color:#DCE6F1;padding:0.079cm;"| Apparatus for wet methods
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>33</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| GG08
+| style="background-color:#DCE6F1;padding:0.079cm;"| Apparatus for printing
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>34</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''F- Term'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| GG08
+| style="background-color:#DCE6F1;padding:0.079cm;"| Apparatus for Inkjet
 |}
+=Taxonomy=
+<mm>[[OLED Taxonomy.mm]]</mm>
-'''Obesity and weight gain are associated with an increased risk of diabetes'''
+=Sample Analysis=
-* Prevalence of obesity from 1991 to 2001 correlates with the increased prevalence of diabetes<sup> </sup>(Figure 4)
+==Patent Analysis==
-* Between 1990 and 2001 the prevalence of diabetes increased 61%
+A sample of 200 patents from the search is analyzed based on the taxonomy. Provided a link below for sample spread sheet analysis for Top Emission OLED.
-[[Image:Maintaining_a_healthy_weight_is_a_challenge_for_most_Americans_12.png|Figure 4. Prevalence of obesity and diabetes among US adults, 1991 and 2001.]]
-* In 2003, 14,100,000 Americans had been diagnosed with diabetes
+{|border="2" cellspacing="0" cellpadding="4" width="100%"
-* More than 80% of type 2 diabetes patients are either overweight or obese
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''S.No'''</center>
-* Diabetic women are at increased risk of major cardiovascular disease and represent the only group where cardiovascular mortality is increasing
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Patent/Publication No.'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Date of Publication'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Assignee / Applicant'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Title'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Problem'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Solution'''</center>
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>'''1'''</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>US7692191B2</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>04/06/2010</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Samsung Mobile Display Co., Ltd.
+| style="background-color:#DCE6F1;padding:0.079cm;"| Top-emitting organic light emitting device
+| style="background-color:#DCE6F1;padding:0.079cm;"| In the conventional top-emitting organic light emitting device, each pixel electrode is designed to have a minimum width, and neighboring pixel electrodes are designed to be widely spaced apart from each other by as much as 17 .mu.m. Therefore, the wide space between the pixel electrodes leaks emitted light, thereby deteriorating the voltage-current characteristics of the thin film transistors i.e., increasing photo-leakage.
+| style="background-color:#DCE6F1;padding:0.079cm;"| In this patent the top-emitting organic light emitting device has maximized the width of a pixel electrode , thereby enhancing aperture ratio. Furthermore, the pixel electrode is arranged to overlap all thin film transistors, so that light is prevented from leaking through a space between neighboring pixel electrodes, thereby reducing photo-leakage of the thin film transistor.
-'''There is a progression from normal blood sugar to type 2 diabetes'''
+|-
+| style="padding:0.079cm;"| <center>'''2'''</center>
+| style="padding:0.079cm;"| <center>US7554259B2</center>
+| style="padding:0.079cm;"| <center>06/30/2009</center>
+| style="padding:0.079cm;"| Sanyo Electric Co., Ltd.
+| style="padding:0.079cm;"| Light emitting display apparatus having excellent color reproducibility
+| style="padding:0.079cm;"| Organic electroluminescence panel obtains white light by synthesizing two lights each having complementary color to the other, and the three primary colors differ in luminous intensity. Therefore it is difficult to set chromaticity of white light to desired level. And even after color-filter transmission, red light and blue light will have stronger luminous intensity than green light.
+| style="padding:0.079cm;"| The present invention objective provide a light emitting display apparatus having excellent color reproducibility. Organic light emitting layer that synthesizes two or more complementary colors of light that are complementary to each other thereby producing white light. It has a resonant structure by which a resonant wavelength is set to a predetermined wavelength, and outputs the white light via the resonant structure where the predetermined wavelength substantially coincides with a wavelength corresponding to a primary color whose luminous intensity is uniform.With the stated construction, non-uniformity in luminous intensity among three primary colors is alleviated by means of amplified luminous intensity due to resonance. This will help obtain white light in which the primary colors are balanced well.
-* Prediabetes is a new term for a condition found in adults before they are diagnosed with diabetes
+|-
-* Prediabetes is characterized by higher than normal blood glucose levels, either impaired fasting glucose or impaired glucose tolerance not yet high enough to be classified as diabetes
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>'''3'''</center>
-* Almost all diabetic patients go through a phase called impaired glucose tolerance (IGT) or impaired fasting glucose (IFG) (Figure 5)
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>US7332859B2</center>
-[[Image:Maintaining_a_healthy_weight_is_a_challenge_for_most_Americans_13.png|Figure 5. Progression to diabetes]]
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>02/19/2008</center>
-* Based on projected NHANES III data, the number of prediabetic individuals was almost 12 million in 2000 among overweight individuals (Figure 6)
+| style="background-color:#DCE6F1;padding:0.079cm;"| Canon Kabushiki Kaisha
-*• Patients with prediabetes have the potential to develop diabetes within a decade if no modifications to their diet and level of physical activity are made
+| style="background-color:#DCE6F1;padding:0.079cm;"| Organic luminescence device with anti-reflection layer and organic luminescence device package
-* Over 50 million adults ages 40-74 have prediabetes, of which 1 in 4 will develop type 2 diabetes
+| style="background-color:#DCE6F1;padding:0.079cm;"| In organic luminescence device, the transparent electrode is formed by a material of a refractive index higher than that of air or nitrogen, constituting the external environment of the organic luminescence device. Therefore, the light emitted from the light emitting layer is reflected at a light emitting surface of the transparent electrode , namely at the interface between the transparent electrode and the air constituting the external environment in FIG. 1. For this reason, such organic luminescence device has been associated with a low efficiency of light emission to the exterior.
-[[Image:Maintaining_a_healthy_weight_is_a_challenge_for_most_Americans_14.png|Figure 6. Proportion of overweight adults with IFG only, IFG and IGT, and IGT only]]
+| style="background-color:#DCE6F1;padding:0.079cm;"| The present invention is to provide an organic luminescence device of a high light-emitting efficiency to the exterior and an organic luminescence device of a satisfactory contrast. A case holding the organic luminescence device in an internal holding space, in which a light emitted from the organic luminescence device, is emitted to the exterior through a light emitting side of the case; wherein anti-reflection means is provided on a light-emitting face on the light-emitting side among faces constituting the internal holding space of the case
+| colspan="7"  style="padding:0.079cm;"|
-* Prevalence of cardiovascular disease risk factors is high among patients with prediabetes:
+|-
-** 94.9% had dyslipidemia
+| style="padding:0.079cm;"| <center>'''4'''</center>
-** 56.5% had hypertension
+| style="padding:0.079cm;"| <center>US6885157B1</center>
-** 13.9% had microalbuminuria
+| style="padding:0.079cm;"| <center>04/26/2005</center>
-** 16.6% were current smokers
+| style="padding:0.079cm;"| Eastman Kodak Company
-* Prediabetes increases a person<nowiki>’</nowiki>s risk for an MI or stroke by 50%
+| style="padding:0.079cm;"| Integrated touch screen and OLED flat-panel display
+| style="padding:0.079cm;"| It has the problem of multiple external electrical connections by employing a flat-panel display having a substrate that extends beyond the substrate of the resistive touch screen.
+| style="padding:0.079cm;"| The present invention has the advantage that it reduces the costs and improves the reliability and performance of a touch screen that is used with an OLED flat-panel display by integrating cable connections on a single substrate and providing touch screen signal processing on the display substrate.
+| colspan="7"  style="padding:0.079cm;"|
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>'''5'''</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>US6069443A</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>05/30/2000</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| FED Corporation
+| style="background-color:#DCE6F1;padding:0.079cm;"| Passive matrix OLED display
+| style="background-color:#DCE6F1;padding:0.079cm;"| The disadvantage of oxygen and moisture penetration into the interior of the organic light emitting device is the potential to form metal oxides at the metal-organic interface. These metal oxide impurities may allow separation of the cathode or anode and the organic in a matrix . This can result in the formation of dark non-emitting spots (i.e., no illumination).Edge shorting between the cathode and anode layers is a current problem affecting most conventional organic light emitting display devices. This edge shorting reduces the illuminating potential of the display devices.
+| style="background-color:#DCE6F1;padding:0.079cm;"| The present invention to provide an insulator layer to minimize edge shorts between lines by separating the OLED layer and the electrode elements. It also provides a sealing structure to isolate the OLED layer from moisture and other contaminants.
+| colspan="7"  style="padding:0.079cm;"|
-'''Obesity and diabetes can be prevented'''
+|-
+| style="padding:0.079cm;"| <center>'''6'''</center>
+| style="padding:0.079cm;"| <center>US20110031511A1</center>
+| style="padding:0.079cm;"| <center>02/10/2011</center>
+| style="padding:0.079cm;"| None
+| style="padding:0.079cm;"| ORGANIC LIGHT EMITTING DIODE DISPLAY AND METHOD OF MANUFACTURING THE SAME
+| style="padding:0.079cm;"| In the organic light emitting layer, as it is easy to transfer energy in an interface between a light emitting layer and a hole transfer layer, a light emitting efficiency and lifetime of the OLED display are reduced because of an energy loss of triplet inside the OLED display.
+| style="padding:0.079cm;"| An interface of the light emitting layer can be improved by forming the inorganic oxide layer between the hole transport layer and the light emitting layer. Further, an energy loss of triplet can be prevented, and the emission efficiency and lifetime can be improved.
+| colspan="7"  style="padding:0.079cm;"|
-* The 1979 Surgeon General<nowiki>’</nowiki>s Report, ''Healthy People'', laid the foundation for a national prevention agenda to ensure that good health, as well as long life, are enjoyed by all
+|-
-* The Healthy People 2010 objective is to reduce the prevalence of '''''obesity among adults to <nowiki><</nowiki> 15%, and to have <nowiki>></nowiki> 60% of the adult population in the normal weight range'''''
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>'''7'''</center>
-* Another Healthy People 2010 objective is to reduce the number of '''''overweight or obese children and adolescents aged 6-19 years to 5%'''''
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>US20070153051A1</center>
-* The American Diabetes Association recommends that all overweight people 45 years of age or older with impaired glucose tolerance or impaired fasting glucose should be classified as having prediabetes and that they are potential candidates for diabetes prevention interventions
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>07/05/2007</center>
-* The Diabetes Prevention Program (DPP) showed that diet and exercise resulting in a 5 to 7 percent weight loss lowered the incidence of type 2 diabetes by 58%
+| style="background-color:#DCE6F1;padding:0.079cm;"| Samsung Electronics Co., Ltd.
-**Participants lost weight by cutting fat and calories in their diet and by exercising at least 30 minutes per day, 5 days per week
+| style="background-color:#DCE6F1;padding:0.079cm;"| Manufacturing flat panel displays with inkjet printing systems
-== The Essential Elements of Diet Menus for Diabetes==
+| style="background-color:#DCE6F1;padding:0.079cm;"| For manufacture of certain flat panel display devices, such as LCDs or OLED displays, various thin film patterns are formed on panel substrates of the devices, typically using photolithography processes. However, as displays become larger, the amount of material that must be deposited on substrates to form the thin film patterns also becomes larger, inturn increases the manufacturing costs of the panels.
-Diet menus for diabetes need to be
+| style="background-color:#DCE6F1;padding:0.079cm;"| Inkjet printing systems have been developed for forming the thin film patterns on the substrates by depositing them on the substrates in the form of special inks. These systems deposit the ink on the substrate through an inkjet head. However, the inkjet head includes a plurality of nozzles, and if only one of these nozzles becomes dysfunctional, the number of passes that the inkjet printing head must make increases. As a result, processing time and costs are substantially increased.
-* Low
+| colspan="7"  style="padding:0.079cm;"|
-** in fats, particularly saturated or animal fats
-**in white, refined flour
-**in cholesterol
-**in calories, since obesity dramatically increases the risk of heart disease
-**in simple or refined sugars
-**in sodium, particularly if elevated blood pressure has already been identified
-* High
+|-
-**in complex carbohydrates, particularly those containing raw fiber.  For example: brown bread, brown rice
+| style="padding:0.079cm;"| <center>'''8'''</center>
-**in fresh fruits and vegetables
+| style="padding:0.079cm;"| <center>US6911671B2</center>
-[http://weightlossinternational.com/newsletter/diet-menus-for-diabetes.html Source]
+| style="padding:0.079cm;"| <center>06/28/2005</center>
+| style="padding:0.079cm;"| Eastman Kodak Company
+| style="padding:0.079cm;"| Device for depositing patterned layers in OLED displays
+| style="padding:0.079cm;"| To achieve color pixelation in OLED imaging panels, fabrication of a multicolor OLED imaging panel using a shadow masking method is used. A multicolor organic electroluminescent ("EL") medium is vapor deposited and patterned by controlling an angular position of a substrate with respect to a deposition vapor stream. The positioning an element in direct contact with a surface of a substrate can invite problems of abrasion, distortion, or partial lifting, this may cause abrasion, distortion, or partial lifting of the first-color pattern.
+| style="padding:0.079cm;"| The present invention is that a pattern of vaporized material, such as organic material, can be deposited without the use of shadow mask.Another feature is that a plurality of devices can be used for simultaneously depositing different organic materials. Such organic materials can emit light in different ranges of the spectrum.
+| colspan="7"  style="padding:0.079cm;"|
-==Food constituents==
+|-
-===Carbohydrates===
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>'''9'''</center>
-Carbohydrates come from a wide array of foods - bread, beans, milk, popcorn, potatoes, cookies, spaghetti, corn, and cherry pie. The most common and abundant are sugars, fibers, and starches. The basic building block of a carbohydrate is a sugar molecule, a simple union of carbon, hydrogen, and oxygen. Starches and fibers are essentially chains of sugar molecules.
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>US7218295B2</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>05/15/2007</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| AU Optronics Corp.
+| style="background-color:#DCE6F1;padding:0.079cm;"| Driving method for active matrix OLED display
+| style="background-color:#DCE6F1;padding:0.079cm;"| In one display frame, the current received by the OLED is fixed.The driving method used previously accumulates carriers inside the OLED which reduce the life of the OLEDs. Moreover, the voltage across the OLED gradually increases over timewhich inturn increases power. This effects the OLED over time.
+| style="background-color:#DCE6F1;padding:0.079cm;"| The present invention uses a driving method to neutralize carrier accumulation in the OLED, thereby reducing the increase in voltage and minimizing the increase in power consumption across both ends of the OLED over time, further increasing the life of the OLED.
+| colspan="7"  style="padding:0.079cm;"|
-Carbohydrates were grouped into two main categories:
+|-
-* Simple carbohydrates included sugars such as fruit sugar (fructose), corn or grape sugar (dextrose or glucose), and table sugar (sucrose).
+| style="padding:0.079cm;"| <center>'''10'''</center>
-* Complex carbohydrates included everything made of three or more linked sugars.
+| style="padding:0.079cm;"| <center>US7067170B2</center>
+| style="padding:0.079cm;"| <center>06/27/2006</center>
+| style="padding:0.079cm;"| Eastman Kodak Company
+| style="padding:0.079cm;"| Depositing layers in OLED devices using viscous flow
+| style="padding:0.079cm;"| To achieve color pixelation in OLED imaging panels, fabrication of a multicolor OLED imaging panel using a shadow masking method is used. A multicolor organic electroluminescent ("EL") medium is vapor deposited and patterned by controlling an angular position of a substrate with respect to a deposition vapor stream. The positioning an element in direct contact with a surface of a substrate can invite problems of abrasion, distortion, or partial lifting, this may cause abrasion, distortion, or partial lifting of the first-color pattern.
+| style="padding:0.079cm;"| The present invention is that the method of color pixelating an organic layer includes providing a plurality of vapor sources disposed outside of a deposition chamber for generating vapors of organic materials, and connecting such vapor sources to a manifold disposed in the chamber. By using vapor deposition method, we can eliminate precision shadow masks.
+| colspan="7"  style="padding:0.079cm;"|
-[[image:diabetes food pyramid.jpeg|center|600 px|thumb|Diabetes Food Pyramid ([http://www.diabetes.org/nutrition-and-recipes/nutrition/foodpyramid.jsp Source])]]
+|}
-'''Examples'''
+Click '''[[media:sample analysis sheet oled.xls|here]]''' to view the detailed analysis sheet for doubly-fed induction generators patent analysis.
-* Simple Carbohydrates
-** Fruit juices
-** Jams, jellies
-** Candy
-** Sugar, maple syrup, honey
-** Sweeteners in food: dextrose, high fructose, corn syrup
-** Kool-Aid
-** Cakes, pies, cookies, ice cream, pudding
-* Complex Carbohydrates
-** Whole grain breads, crackers
-** Rice
-** Pasta
-** Tortillas
-** Beans
-** Corn, peas, lima beans
-Foods contain three major types of nutrients: carbohydrates (carbs), proteins and fats. Carbohydrate foods most often come from plants, such as fruits, vegetables and grains. Carbohydrates are chains of sugar molecules; thus, they have the greatest effect on blood-sugar levels when these chains are digested (broken down).
+==Article Analysis==
+{|border="2" cellspacing="0" cellpadding="4" width="100%"
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''S.No.'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Title'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Authors'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Publication date'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Journal/Conference'''</center>
+| colspan="2"  style="background-color:#4F81BD;padding:0.079cm;"| <center>Dolcera summery.</center>
-Complex carbohydrates are longer chains of sugars. They are absorbed more slowly into the blood and cause a slower change in blood sugar than simple carbohydrates. 90-100% of the carbohydrate (CHO) eaten converts to sugar (glucose) within 15 minutes to 1.5 hours. Only 58% of the ingested protein, and less than 10% of fat, are converted into sugar within several hours after consumption. [http://www.mfm-evms.org/dm6acarbsdiabetes.html Source]
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>'''1'''</center>
-[[image:carbohydrates types.jpeg|center|thumbs|800 px]]
+| style="background-color:#DCE6F1;padding:0.079cm;"| [http://ieeexplore.ieee.org/xpl/freeabs_all.jsp?arnumber=979337 Application of Screen Printing in the Fabricationof Organic Light-Emitting Devices]
+| style="background-color:#DCE6F1;padding:0.079cm;"| Dino A. Pardo, Ghassan E. Jabbour,* andNasser Peyghambarian
+| style="background-color:#DCE6F1;padding:0.079cm;"| 01/27/2000
+| style="background-color:#DCE6F1;padding:0.079cm;"| Optical Sciences Center, University of Arizona.IEEE 27 Jan 2000
+| style="background-color:#DCE6F1;padding:0.079cm;"| This article explains the screen printing technique which deposits organic active layer having a thickness of several tens of nanometers and acting as a hole-transport layer (HTL) in multilayer OLEDs. The resulting devices emit<nowiki>light at low voltage (<5 V) and have a peak external quantum efficiency of 0.91 %.</nowiki>
-====Carbohydrates and the Glycemic Index====
+|-
-A new system for classifying carbohydrates known as the glycemic index, measures how fast and how far blood sugar rises after you eat a food that contains carbohydrates
+| style="padding:0.079cm;"| <center>'''2'''</center>
+| style="padding:0.079cm;"| [http://onlinelibrary.wiley.com/doi/10.1002/(SICI)1521-4095(199906)11:9%3C734::AID-ADMA734%3E3.0.CO;2-D/abstract Multicolor Organic Light-Emitting DiodesProcessed by Hybrid Inkjet Printing]
+| style="padding:0.079cm;"| Shun-Chi Chang, Jie Liu, Jayesh Bharathan,Yang Yang,* Jun Onohara and Junji Kido
+| style="padding:0.079cm;"| 08/07/1999
+| style="padding:0.079cm;"| Department of Materials Science and EngineeringUniversity of California at Los Angeles. willey 8 Jul 1999
+| style="padding:0.079cm;"| This article presents a multicolor patterning technique to produce controllable patterning of red-green-blue OLEDs with fine pixel displays. The LEDs comprise bilayer structures of red and green dopants with inkjet-printed onto a film of the blue-emitting semiconducting polymer, the latter serving as the hole-transport layer.
-White bread, for example, is converted almost immediately to blood sugar, causing it to spike rapidly. It's classified as having a high glycemic index. Brown rice, in contrast, is digested more slowly, causing a lower and more gentle change in blood sugar. It has a low glycemic index.
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>'''3'''</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| [http://onlinelibrary.wiley.com/doi/10.1002/pi.1974/abstract Organic light-emitting diode (OLED)technology: materials, devices and displaytechnologies]
+| style="background-color:#DCE6F1;padding:0.079cm;"| Bernard Geffroy, Philippe le Roy and Christophe Prat
+| style="background-color:#DCE6F1;padding:0.079cm;"| 06/02/2006
+| style="background-color:#DCE6F1;padding:0.079cm;"| Laboratoire Cellules et Composants. willey 6 Feb 2006
+| style="background-color:#DCE6F1;padding:0.079cm;"| This article presents an overview of OLED's over LCD's. OLED'S have a thickness, currently less than 2 mm. Having high contrast ratio is also a strong point of OLED and also in fast response time.OLEDs for flat-panel display applications are their self-emitting property, high luminous efficiency, full-colour capability, wide viewing angle, high contrast,low power consumption, low weight, potentially large area colour displays and flexibility.
-Diets filled with high-glycemic-index foods, which cause quick and strong increases in blood sugar levels, have been linked to an increased risk for both diabetes and heart disease. [http://www.hsph.harvard.edu/nutritionsource/carbohydrates.html Source]
+|-
+| style="padding:0.079cm;"| <center>'''4'''</center>
+| style="padding:0.079cm;"| [http://www.springerlink.com/content/q34n0017t30373q6/ Organic/polymeric electroluminescent devices processed by hybrid ink-jet printing]
+| style="padding:0.079cm;"| Yang Yang, Shun-Chi Chang, Jayesh Bharathan and Jie Liu
+| style="padding:0.079cm;"| 04/05/1999
+| style="padding:0.079cm;"| Journal of Materials Science: Materials in Electronics Volume 11, Number 2,
+| style="padding:0.079cm;"| The HIJP concept is a unique approach for fabricating polymer and organic electronic devices. One is able to apply this technology for the deposition of various functional materials such as charge-injection layers, charge-blocking layers, and multicolor polymer/organic emissive layers. It can be used for the fabrication of logos, indicator lights, multicolor displays and also in bio-medical applications such as biosensors for low cost diagnostics.
-'''Glycemic Index'''
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>'''5'''</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| [http://onlinelibrary.wiley.com/doi/10.1002/adma.200400684/abstract White Organic Light-Emitting Devices for Solid-State Lighting]
+| style="background-color:#DCE6F1;padding:0.079cm;"| B. W. D'Andrade, S. R. Forrest
+| style="background-color:#DCE6F1;padding:0.079cm;"| 14/10/2004
+| style="background-color:#DCE6F1;padding:0.079cm;"| Department of Electrical Engineering, Princeton University Willey 14 OCT 2004
+| style="background-color:#DCE6F1;padding:0.079cm;"| This article presents the WOLEDs increasing display applications for use primarily as liquid-crystal display backlights. They have achieved high material purity, low cost, high brightness,color quality and long operational life-times.
-The glycemic index measures how fast a food is likely to raise your blood sugar. This can be helpfu. For example, if your blood sugar is low and continuing to drop during exercise, you would prefer to eat a carb that will raise your blood sugar quickly. On the other hand, if you would like to keep your blood sugar from dropping during a few hours of mild activity, you may prefer to eat a carb that has a lower glycemic index and longer action time. If your blood sugar tends to spike after breakfast, you may want to select a cereal that has a lower glycemic index.
+|-
+| style="padding:0.079cm;"| <center>'''6'''</center>
+| style="padding:0.079cm;"| [http://www.nature.com/nature/journal/v459/n7244/full/nature08003.html White organic light-emitting diodes with fluorescent tube efficiency]
+| style="padding:0.079cm;"| Sebastian Reineke, Frank Lindner, Gregor Schwartz, Nico Seidler, Karsten Walzer
+| style="padding:0.079cm;"| 14/05/2009
+| style="padding:0.079cm;"| Institute of Applied Photophysics. Vol 459 Macmillan Pub
+| style="padding:0.079cm;"| This article presents an WOLED havinh high internal quantum efficiencies for the con-version of electrical energy to light have been realized by focussing on reducing energetic and ohmic losses that occur during electron–photon conversion.This can be achieved by improved OLED structure which reaches fluorescent tube efficiency. By combining a care-fully chosen emitter layer with high-refractive-index substrates and using a periodic outcoupling structure
-'''Factors that influence how quickly the carbohydrates in food raise blood sugar include:'''
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>'''7'''</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| [http://pubs.rsc.org/en/Content/ArticleLanding/2007/JM/b609204g Precision ink jet printing of polymer light emitting displays]
+| style="background-color:#DCE6F1;padding:0.079cm;"| J. F. Dijksman, P. C. Duineveld, M. J. J. Hack, A. Pierik, J. Rensen, J.-E. Rubingh, I. Schram andM. M. Vernhou
+| style="background-color:#DCE6F1;padding:0.079cm;"| 09/11/2006
+| style="background-color:#DCE6F1;padding:0.079cm;"| Philips Research Laboratories RSC
+| style="background-color:#DCE6F1;padding:0.079cm;"| Precision ink jet printing of organic polymer light emitting diodes relies strongly on the accuracy of the droplet generation process.Image capturing using one image at a time for image processing delivers sharper images and can be used for optically measuring droplet volumes.
-* Fiber content. Fiber shields the starchy carbohydrates in food immediate and rapid attack by digestive enzymes. This slows the release of sugar molecules into the bloodstream.
+|-
-* Ripeness. Ripe fruits and vegetables tend to have more sugar than unripe ones, and so tend to have a higher glycemic index.
+| style="padding:0.079cm;"| <center>'''8'''</center>
-* Type of starch. Starch comes in many different configurations. Some are easier to break into sugar molecules than others. The starch in potatoes, for example, is digested and absorbed into the bloodstream relatively quickly.
+| style="padding:0.079cm;"| [http://apl.aip.org/resource/1/applab/v88/i7/p073517_s1?isAuthorized=no High-efficiency microcavity top-emitting organic light-emittingdiodes using silver anode]
-* Fat content and acid content. The more fat or acid a food contains, the slower its carbohydrates are converted to sugar and absorbed into the bloodstream.
+| style="padding:0.079cm;"| Huajun Peng, Jiaxin Sun, Xiuling Zhu, Xiaoming Yu, Man Wong, and Hoi-Sing Kwok
-* Physical form. Finely ground grain is more rapidly digested, and so has a higher glycemic index, than more coarsely ground grain.
+| style="padding:0.079cm;"| 17/02/2006
+| style="padding:0.079cm;"| Hong Kong Universityof Science and Technology. AIP
+| style="padding:0.079cm;"| High efficient top-emitting OLEDs have been fabricated using highly reflective Ag as the anode. Surfacemodification of the Ag anode by CF4 plasma substantially enhances the hole injection efficiency. The color variation isalmost eliminated in the TOLED. The optimized microcav- ity TOLED has a current efficiency enhancement of 65% and a total outcoupling efficiency enhancement of 35%, as compared with a conventional OLED.
-'''Carbohydrates and the Glycemic Load'''
+|-
-* Low Glycemic Load
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>'''9'''</center>
-** High-fiber fruits and vegetables (not including potatoes)
+| style="background-color:#DCE6F1;padding:0.079cm;"| [http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6THY-4F70JMT-5&_user=10&_coverDate=05%2F15%2F2005&_rdoc=1&_fmt=high&_orig=gateway&_origin=gateway&_sort=d&_docanchor=&view=c&_searchStrId=1660089209&_rerunOrigin=scholar.google&_acct=C000050221&_version=1&_urlVersion=0&_userid=10&md5=f4dc4db9a6e736e6994a9ffa868e34b8&searchtype=a Inverted top-emitting organic light-emitting diodes using transparent conductive NiO electrode ]
-** Bran cereals (1 oz)
+| style="background-color:#DCE6F1;padding:0.079cm;"| Se-W. Park, Jeong-M. Choi, Eugene Kim and Seongil Im
-** Many legumes, including chick peas, kidney beans, black beans, lentils, pinto beans (5 oz cooked, approx. 3/4 cup)
+| style="background-color:#DCE6F1;padding:0.079cm;"| 09/01/2005
-* Medium Glycemic Load
+| style="background-color:#DCE6F1;padding:0.079cm;"| Institute of Physics and Applied Physics, Applied Surface Science 244 (2005) 439–443
-** Pearled barley: 1 cup cooked
+| style="background-color:#DCE6F1;padding:0.079cm;"| TE-OLED device uses a thermally evaporated and semi-transparent NiO film as a top-electrode. Since the sheet resistance of our NiO was very high and its transmittance was only about 50%, the resulting luminance and injection current of our TE-OLED were much inferior to those of the BE-OLED device.
-** Brown rice: 3/4 cup cooked
-** Oatmeal: 1 cup cooked
-** Bulgur: 3/4 cup cooked
-** Rice cakes: 3 cakes
-** Whole grain breads: 1 slice
-** Whole-grain pasta: 1 ¼ cup cooked
-** No-sugar added fruit juices: 8 oz
-* High Glycemic Load
-** Baked potato
-** French fries
-** Refined cereal products: 1 oz
-** Sugar-sweetened beverages: 12 oz
-** Jelly beans: 10 large or 30 small
-** Candy bars: 1 2-oz bar or 3 mini bars
-** Couscous: 1 cup cooked
-** Cranberry juice cocktail: 8 oz
-** White basmati rice: 1 cup cooked
-** White-flour pasta: 1¼ cup cooked
-====Carbohydrates and Diabetes====
+|-
+| style="padding:0.079cm;"| <center>'''10'''</center>
+| style="padding:0.079cm;"| [http://apl.aip.org/resource/1/applab/v89/i23/p233513_s1?isAuthorized=no Self-assembled monolayer-modified Ag anode for top-emitting polymerlight-emitting diodes]
+| style="padding:0.079cm;"| Lai-Wan Chong, Yuh-Lang Lee,a͒ and Ten-Chin Wenb͒
+| style="padding:0.079cm;"| 07/12/2006
+| style="padding:0.079cm;"| Department of Chemical Engineering, National Cheng Kung University
+| style="padding:0.079cm;"| Self-assembled monolayer is a method to modify the Ag anodes for application in T-PLED. The Ag electrode can be utilized as an effective anode to improve the emitting characteristic of a T-PLED. The Ag anode enhances the hole injection, reduce the op-eration voltage, and significantly increase the current inten-sity and luminous efficiency of the device, without decreasing the reflectivity of the Ag anode.
-The long-held belief that eating foods containing "sugar" (sweets) will cause your blood glucose levels to rise higher and more quickly than starchy foods (bread, rice, pasta, etc.) has not been supported by scientific evidence. Both are forms of carbohydrates and both cause blood glucose to increase.
+|}
-Research has shown that your total daily amount of carbohydrate intake affects your blood glucose levels. Carbohydrates have the most immediate effect on blood glucose levels, since carbohydrates are broken down into glucose (sugar) early during digestion. It is important to eat the suggested amount of carbohydrate at each meal, along with some protein, and fat.
+Click '''[[media:Non patent literature.xls|here]]''' to view the detailed analysis sheet for Top Emission OLED for non patent literature
-Carbohydrates are mainly found in three food groups: Fruit; Milk and Yogurt; and Bread, Cereal, Rice, Pasta and Starchy Vegetables. You will need to consider the total amount of carbohydrates when working out your daily meal plan.
+== Top Cited Patents==
+{|border="2" cellspacing="0" cellpadding="4" width="100%"
+| style="background-color:#4f81bd;padding:0.079cm;"| <center>'''S. No.'''</center>
+| style="background-color:#4f81bd;padding:0.079cm;"| <center>'''Patent/Publication No.'''</center>
+| style="background-color:#4f81bd;padding:0.079cm;"| <center>'''Publication Date (mm/dd/yyyy)'''</center>
+| style="background-color:#4f81bd;padding:0.079cm;"| <center>'''Assignee/Applicant'''</center>
+| style="background-color:#4f81bd;padding:0.079cm;"| <center>'''Title'''</center>
+| style="background-color:#4f81bd;padding:0.079cm;"| <center>'''Citation Count'''</center>
-'''Carbohydrate counting'''
+|-
-Counting grams of carbohydrate and evenly distributing them at meals will help you manage your blood glucose. Carbohydrate counting is a method of meal planning that is a simple way to keep track of the amount of total carbohydrate you eat each day. Instead of following an exchange list, you monitor how much carbohydrate (sugars and starches) you eat daily. One carbohydrate choice is equal to 15 grams of carbohydrate. Note: your consumption of protein and fat still counts as calories.
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>1</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| US6096496A
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>8/1/2000</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Frankel; Robert D
+| style="background-color:#DCE6F1;padding:0.079cm;"| Supports incorporating vertical cavity emitting lasers and tracking apparatus for use in combinatorial synthesis
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>130</center>
-With carbohydrate counting, you can pick up almost any food product off the shelf, read the label, and use the information about grams of carbohydrate to fit the food into your meal plan.
+|-
+| style="padding:0.079cm;"| <center>2</center>
+| style="padding:0.079cm;"| US6069443A
+| style="padding:0.079cm;"| <center>5/30/2000</center>
+| style="padding:0.079cm;"| Fed Corporation
+| style="padding:0.079cm;"| Passive matrix OLED display
+| style="padding:0.079cm;"| <center>97</center>
-Carbohydrate counting is most useful for people who take multiple daily injections of insulin, use an insulin pump, or who want more flexibility and variety in their food choices. The amount and type of insulin you are prescribed may affect the flexibility of your meal plan.
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>3</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| US6366017B1
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>4/2/2002</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Agilent Technologies
+| style="background-color:#DCE6F1;padding:0.079cm;"| Organic light emitting diodes with distributed bragg reflector
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>80</center>
-A registered dietitian can help you determine how much carbohydrate, as well as other foods, you should include in your daily meal plan.
+|-
+| style="padding:0.079cm;"| <center>4</center>
+| style="padding:0.079cm;"| US20020197511A1
+| style="padding:0.079cm;"| <center>12/26/2002</center>
+| style="padding:0.079cm;"| United Of America As Respresented By The Secretary Of The Air Force
+| style="padding:0.079cm;"| High efficiency multi-color electro-phosphorescent OLEDS
+| style="padding:0.079cm;"| <center>51</center>
-Carbohydrate counting may not be for everyone, and the traditional method of following food exchange lists may be used instead.
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>5</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| US6265820B1
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>7/24/2001</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Emagin Corporation,De
+| style="background-color:#DCE6F1;padding:0.079cm;"| Heat removal system for use in organic light emitting diode displays having high brightness
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>50</center>
-===Fiber===
+|-
-Fiber is the indigestible part of plant foods that plays an important role in the digestive process. Fiber helps move foods along the digestive tract and adds bulk to stool to speed its passage through the bowel and promote regular bowel movements. Fiber also delays sugar absorption, helping to better control blood glucose levels. In addition, fiber binds with cholesterol and may reduce the level of cholesterol in the blood. Lastly, fiber helps prevent constipation and reduces the risk of certain intestinal disorders.
+| style="padding:0.079cm;"| <center>6</center>
+| style="padding:0.079cm;"| US20020195968A1
+| style="padding:0.079cm;"| <center>12/26/2002</center>
+| style="padding:0.079cm;"| IBM
+| style="padding:0.079cm;"| Oled current drive pixel circuit
+| style="padding:0.079cm;"| <center>44</center>
-The goal for all Americans is to consume 25 to 35 grams of fiber per day. The best way to increase your fiber intake is to eat more of these fiber-rich foods:
+|-
-* Fresh fruits and vegetables
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>7</center>
-* Cooked dried beans and peas
+| style="background-color:#DCE6F1;padding:0.079cm;"| US20020186209A1
-* Whole grain breads, cereals, and crackers
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>12/12/2002</center>
-* Brown rice
+| style="background-color:#DCE6F1;padding:0.079cm;"| Eastman Kodak Company
-* Bran products
+| style="background-color:#DCE6F1;padding:0.079cm;"| Touch screen for use with an OLED display
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>42</center>
-[http://www.clevelandclinic.org/health/health-info/docs/2600/2619.asp?index=9825 Source]
+|-
-===Cheese===
+| style="padding:0.079cm;"| <center>8</center>
-* Glycemic Index: 60
+| style="padding:0.079cm;"| US20030127973A1
-* Glycemic Index Rating: Medium
+| style="padding:0.079cm;"| <center>7/10/2003</center>
-* Glycemic Response to Cheese Pizza: Carbs in Cheese Pizza have a medium effect on blood sugar levels.
+| style="padding:0.079cm;"| Universal Display Corporation
-* Constituents: protein, calcium, riboflavin and fat (as a cup of whole milk - Lactose sugar)
+| style="padding:0.079cm;"| OLEDs having increased external electroluminescence quantum efficiencies
+| style="padding:0.079cm;"| <center>41</center>
-===Proteins===
+|-
-Beans and legumes are another excellent source of protein for humans. Beans do not contain all the essential amino acids when cooked in their usual manner, but through sprouting (link to sprouting) them you can enjoy a full spectrum of amino acids in an alkaline forming low glycemic index food. [http://www.ortogo.com/php/learning/build_art.php?67 Source]
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>9</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| US6844673B1
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>1/18/2005</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Alien Technology Corporation
+| style="background-color:#DCE6F1;padding:0.079cm;"| Split-fabrication for light emitting display structures
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>38</center>
-===Vegetables===
+|-
-Vegetables contain low glycemic, often considered “free food” carbohydrate sources. [http://www.ortogo.com/php/learning/build_art.php?67 Source]
+| style="padding:0.079cm;"| <center>10</center>
+| style="padding:0.079cm;"| US20040174116A1
+| style="padding:0.079cm;"| <center>9/9/2004</center>
+| style="padding:0.079cm;"| Universal Display Corporation
+| style="padding:0.079cm;"| Transparent electrodes
+| style="padding:0.079cm;"| <center>36</center>
-===Legumes===
+|-
-Legumes are a dense source of carbohydrate and certain amino acids. They are rich in fiber which helps to keep you clean on the inside. Low on the glycemic index legumes are a great source of energy for an active body. Legumes: Almost all legumes have a moderate glycemic index. They also provide a source of water-soluble fiber that is valuable for lowering cholesterol. They also provide phytoestrogens, which may provide health benefits. [http://www.findarticles.com/p/articles/mi_nhi4446/is_10/ai_n16083623/pg_6 Source]
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>11</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| US20050194896A1
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>9/8/2005</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Hitachi Displays Ltd.
+| style="background-color:#DCE6F1;padding:0.079cm;"| Light emitting element and display device and illumination device using the light emitting element
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>35</center>
-===Dairy products===
+|-
-Most dairy products have a low glycemic index. However, some people do not tolerate dairy very well.
+| style="padding:0.079cm;"| <center>12</center>
-[http://www.findarticles.com/p/articles/mi_nhi4446/is_10/ai_n16083623/pg_6 Source]
+| style="padding:0.079cm;"| US20020074935A1
+| style="padding:0.079cm;"| <center>6/20/2002</center>
+| style="padding:0.079cm;"| Universal Display Corporation
+| style="padding:0.079cm;"| Highly stable and efficient OLEDs with a phosphorescent-doped mixed layer architecture
+| style="padding:0.079cm;"| <center>35</center>
-===Fruits===
+|-
-Fruits are generally in the middle of the road in terms of glycemic index; but dried fruits, which are concentrated, have a higher index. Drinking fruit juices will definitely increase blood sugar release. Therefore, fruit juices should be limited or diluted with three-fourths water. [http://www.findarticles.com/p/articles/mi_nhi4446/is_10/ai_n16083623/pg_6 Source]
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>13</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| US20040217702A1
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>11/4/2004</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Corning Incorporated
+| style="background-color:#DCE6F1;padding:0.079cm;"| Light extraction designs for organic light emitting diodes
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>33</center>
-Most sweeteners such as honey, molasses, sugar, and white grape juice concentrate tend to have a high glycemic index. Rice syrup and granulated rice sweeteners may be used instead. The artificial sweetener aspartame may increase insulin resistance over time. [http://www.findarticles.com/p/articles/mi_nhi4446/is_10/ai_n16083623/pg_6 Source]
+|-
+| style="padding:0.079cm;"| <center>14</center>
+| style="padding:0.079cm;"| US20020030647A1
+| style="padding:0.079cm;"| <center>3/14/2002</center>
+| style="padding:0.079cm;"| Universal Display Corporation
+| style="padding:0.079cm;"| Uniform active matrix oled displays
+| style="padding:0.079cm;"| <center>32</center>
-===Grains===
+|-
-Grains such as rice, wheat, and corn tend to have a high glycemic index, but grains such as buckwheat, millet, barley, rye, and bulgur are actually quite low. For successful weight loss and blood sugar control, this group of foods should be used in moderation. Also, the addition of fats such as olive oil or butter (in moderation) can lower the glycemic index. [http://www.findarticles.com/p/articles/mi_nhi4446/is_10/ai_n16083623/pg_6 Source]
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>15</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| US20050248270A1
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>11/10/2005</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Eastman Kodak Company
+| style="background-color:#DCE6F1;padding:0.079cm;"| Encapsulating OLED devices
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>31</center>
-==Regulation of glycemic index ==
+|-
-Factors Affecting Glycemic Index of Foods are:
+| style="padding:0.079cm;"| <center>16</center>
-===Soluble fiber===
+| style="padding:0.079cm;"| US20040113875A1
-The gel-forming property of soluble fiber sources such as oats and barley has been proposed as the mechanism by which these grains reduce both cholesterol and glucose and insulin responses.
+| style="padding:0.079cm;"| <center>6/17/2004</center>
+| style="padding:0.079cm;"| Eastman Kodak Company
+| style="padding:0.079cm;"| Color oled display with improved power efficiency
+| style="padding:0.079cm;"| <center>29</center>
-The high viscosity of the solution containing oat gum was concluded to be the property which delays gastric emptying and/or intestinal absorption resulting in these lower responses
+|-
-===Starch structure===
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>17</center>
-Starch is composed of long chains of glucose (amylose) and highly branched chains of glucose (amylopectin). Hydrolysis of amylose would therefore result in fewer glucose molecules’ being freed at once than the hydrolysis of the highly branched amylopectin chains. Thus, high amylose content grains result in lower glucose responses than those which have a high content of amylopectin.
+| style="background-color:#DCE6F1;padding:0.079cm;"| US20030230972A1
-=== Particle size===
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>12/18/2003</center>
-Boiled whole kernels and larger particle sizes are associated with lower glucose and insulin responses for a variety of grain sources.
+| style="background-color:#DCE6F1;padding:0.079cm;"| Eastman Kodak Company
+| style="background-color:#DCE6F1;padding:0.079cm;"| Oled display having color filters for improving contrast
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>28</center>
-'''Conclusion'''
+|-
-* The greater the particle size, the lower the glucose and insulin response.
+| style="padding:0.079cm;"| <center>18</center>
-* The greater the level of processing and refining, the higher the response.
+| style="padding:0.079cm;"| US20050040756A1
-* Grains with high levels of soluble beta glucans such as oats, rye and barley are generally more effective in improving insulin sensitivity than wheat, which contains predominantly insoluble dietary fiber.
+| style="padding:0.079cm;"| <center>2/24/2005</center>
-* The high viscosity of these soluble fibers is partially responsible for these beneficial effects.
+| style="padding:0.079cm;"| Eastman Kodak Company
-* Corn and rice can have either high or low glycemic indices because their amylose and amylopectin contents vary.
+| style="padding:0.079cm;"| OLED device having microcavity gamut subpixels and a within gamut subpixel
-* Higher amylose content results in lower glucose and insulin responses.
+| style="padding:0.079cm;"| <center>27</center>
-* Replacing low fiber grain foods such as cornflakes or white bread with whole grain higher fiber or higher amylose content products will reduce risk of developing insulin resistance and obesity and improve the health of the American population.
-'''Potential mechanisms whereby high-glycemic-load diets could increase risk of type 2 diabetes'''
+|-
-[[image:Potential mechanisms whereby high-glycemic-load diets could increase risk of type 2 diabetes.jpeg|thumb|center|800 px]]
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>19</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| US6670772B1
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>12/30/2003</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Eastman Kodak Company
+| style="background-color:#DCE6F1;padding:0.079cm;"| Organic light emitting diode display with surface plasmon outcoupling
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>26</center>
-==Overview of U.S. Food Customs and Terminology ==
+|-
-[http://www.uta.fi/FAST/US1/REF/usfood.html Source]
+| style="padding:0.079cm;"| <center>20</center>
+| style="padding:0.079cm;"| US20040061136A1
+| style="padding:0.079cm;"| <center>4/1/2004</center>
+| style="padding:0.079cm;"| Eastman Kodak Company
+| style="padding:0.079cm;"| Organic light-emitting device having enhanced light extraction efficiency
+| style="padding:0.079cm;"| <center>26</center>
-===Overview: Traditional "typical" meals===
+|}
-* Breakfast: O.J., bacon and eggs, sausage, pancakes, waffles, toast/french toast, cold cereals, oatmeal or cream of wheat, yogurt, applesauce, milk, coffee
-* Brunch: above plus bagels & lox, fruits, Danish rolls
-* Lunch: soup and sandwiches, cottage cheese, fruit
-* Sandwich types: BLT, PBJ, tuna salad, egg salad, hero, submarine, grinder, hoagy, poor-boy, "Dagwood sandwich", Reuben sandwish, corned-beef, pita
-* Dinner: fried chicken, steak, roast beef/pork, 2 vegetables (mashed potatos, corn, beans, peas, carrots, broccoli), tossed salad, cole slaw, jello "salads", dessert (apple pie [á la môde], cobbler, ice cream, cake).
-* Meal drinks: coffee, iced tea, [iced coffee], beer, wine, milk, water, soft drinks
-* Supper: hash, stew, hot sandwiches, leftovers
-===Holiday meals===
+== Top Cited Articles ==
-* Thanksgiving: turkey and dressing, cranberry sauce, sweet potato casserole, corn, beans, peas, pumpkin pie ...
+{|border="2" cellspacing="0" cellpadding="4" width="100%"
-* Christmas: ham, turkey, fruitcake, mincemeat pie, Christmas stollen, egg nog, mulled wine,
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''S. No.'''</center>
-* Independence Day: picnics with hot dogs, hamburgers, potato chips, pickles, roasted marshmallows, potato salad, 3-bean salad, pork & beans, ice cream, pie
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Title'''</center>
-* "Traditional" foods: succotash, squash, yams, sweet potatos, chili, corn bread, corn sticks, spoon bread, strawberry shortcake, fried catfish, sourdough bread
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Publication Date'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Journal/Conference'''</center>
+| colspan="2"  style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Citations Count'''</center>
-=== Food trends in recent years===
+|-
-* More fast-food restaurants, McDonalds, Burger King, Col. Sanders' Kentucky Fried Chicken, Arby's Roast Beef, Long John Silver's seafood, Domino's Pizza, Pizza Hut, Godfather's Pizza, Taco Bell, Roy Rogers, Orange Julius, Subway Shoppe, Au Bon Pain
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>1</center>
-* 24-hour 'convenience' restaurants, such as Denney's, Interstate Pancake House, Howard Johnson's (HoJo)
+| style="background-color:#DCE6F1;padding:0.079cm;"| [http://www.nature.com/nature/journal/v420/n6917/full/nature01217.html?free=2 Electroluminescence from single monolayers of nanocrystals in molecular organic devices]
-* Oriental restarants — take-out or dine-in
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>Oct 2002</center>
-* "Power breakfasts," "brown-bag lunches," no-host bars
+| style="background-color:#DCE6F1;padding:0.079cm;"| Nature, Internatinal journal of science.
-* "De-caf" coffee (and tea), more consumption of fish, grilled swordfish, etc.; rise of Mexican food dishes
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>736</center>
-===Vast differences in U.S. regional & ethnic food cultures===
+|-
-* German, Polish, Scandinavian cultures in Midwest
+| style="padding:0.079cm;"| <center>2</center>
-* French cuisine around New Orleans, Maine
+| style="padding:0.079cm;"| [http://www.nature.com/nature/journal/v413/n6858/abs/413828a0.html Spin-dependent exciton formation in π-conjugated compounds]
-* Mexican/Spanish in Southwest, Florida
+| style="padding:0.079cm;"| <center>Aug 2001</center>
-* Chinese, Japanese, Vietnamese, Thai in West/South
+| style="padding:0.079cm;"| Nature, Internatinal journal of science.
-* Indian, Pakistani, Afghan, Ethiopian, etc. in East
+| style="padding:0.079cm;"| <center>220</center>
-* Native American Indian, etc., throughout U.S.
-* Cuban, Puerto Rican, South American in Florida
-===Selected Main Courses===
+|-
-* Meatloaf, meatballs, creamed chipped beef,
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>3</center>
-* Ham (sugar-cured, "picnic," "rolled," "country", Virginia)
+| style="background-color:#DCE6F1;padding:0.079cm;"| [http://pubs.acs.org/doi/abs/10.1021/cr050156n Highly Efficient Organic Devices Based on Electrically Doped Transport Layers]
-* Spaghetti & meatballs, macaroni & cheese
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>Mar 2007</center>
-* Quiche, Turf & Surf, spareribs
+| style="background-color:#DCE6F1;padding:0.079cm;"| American Chemical Society Pub.
-* Chicken (fried, barbequed, fricasseed, roasted, grilled)
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>211</center>
-* Turkey (Butterball), duck, goose, lamb, pork
-* Caesar salad, Chef's salad, chicken salad, tuna salad
-* Catfish, lobster, salmon, trout, shrimp, swordfish, cod
-===Selected Side Dishes===
+|-
-* Beans (baked, green, lima, string, wax, kidney, shell, fava)
+| style="padding:0.079cm;"| <center>4</center>
-* Peas (green, in-the-pod, black-eyed, lentils, chickpeas)
+| style="padding:0.079cm;"| [http://apl.aip.org/resource/1/applab/v82/i3/p466_s1?isAuthorized=no Phosphorescent top-emitting organic light-emitting devices with improved light outcoupling]
-* Zzucchini, other squashes
+| style="padding:0.079cm;"| <center>Nov 2002</center>
-* Corn (on the cob, whole-kernel, creamed, hominy, grits)
+| style="padding:0.079cm;"| Applied Physics Letters / Volume 82
-* Succotash (corn & lima beans together)
+| style="padding:0.079cm;"| <center>111</center>
-* Rice (white, brown, wild; steamed, creamed, boiled, fried)
-* Broccoli, asparagus, okra, spinach, kohlrabi, turnips, chard
-* Noodles, macaroni, dumplings, potato pancakes
-* Cottage cheese, sliced fruit
-===Selected Soups===
+|-
-* Clam chowder, chicken, chicken-noodle, black bean, pea
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>5</center>
-* Tomato soup, creamed celery/potato soups, onion/cheese soups
+| style="background-color:#DCE6F1;padding:0.079cm;"| [http://ieeexplore.ieee.org/xpl/freeabs_all.jsp?arnumber=1288072 Thin-film permeation-barrier technology for flexible organic light-emitting devices]
-* Gumbos, jambalayas, vichyssoise, Scotch broth, shrimp bisque
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>Jan 2004</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| IEEE Photonics Society
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>104</center>
-===Selected Desserts===
+|-
-* Various pies, cakes, cobblers, cookies, puddings, custards
+| style="padding:0.079cm;"| <center>6</center>
-* ice cream, sherbet, frozen yogurt, brownies, fudge, mousse
+| style="padding:0.079cm;"| [http://ieeexplore.ieee.org/xpl/freeabs_all.jsp?arnumber=669473 Design of flat-panel displays based on organic light-emitting devices]
-* fruit compotes, melons, baked alaska, muffins, crepes, soufflés
+| style="padding:0.079cm;"| <center>Feb 1998 </center>
+| style="padding:0.079cm;"| IEEE Photonics Society
+| style="padding:0.079cm;"| <center>100</center>
-===Party and Reception or other "Occasion" Foods===
+|-
-* Hors d'oeuvres, dips, guacamole, pretzels, bread sticks, (cocktail party 'finger food')
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>7</center>
-* Chicken wings, quiches, meatballs, turkey or ham or chicken 'rolls' or 'logs'
+| style="background-color:#DCE6F1;padding:0.079cm;"| [http://ieeexplore.ieee.org/xpl/freeabs_all.jsp?arnumber=1224525 A new a-Si:H thin-film transistor pixel circuit for active-matrix organic light-emitting diodes]
-* Frankfurters, potato chips & salad, dill pickles, french fries
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>Aug 2003</center>
-* Toasted marshmallows, peanut butter fudge/brittle, popcorn balls, "s'mores"
+| style="background-color:#DCE6F1;padding:0.079cm;"| IEEE Electron Devices Society
-* Frog legs, mountain oysters,
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>86</center>
-===Common Ethnic Foods===
+|-
-* Tortillas, enchiladas, tacos, burritos, tamales, nachos
+| style="padding:0.079cm;"| <center>8</center>
-* Knockwurst, kielbasa, sauerkraut,
+| style="padding:0.079cm;"| [http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6W6J-49KS3CB-1&_user=10&_coverDate=09%2F30%2F2003&_rdoc=1&_fmt=high&_orig=gateway&_origin=gateway&_sort=d&_docanchor=&view=c&_searchStrId=1688490500&_rerunOrigin=scholar.google&_acct=C000050221&_version=1&_urlVersion=0&_userid=10&md5=ea20da18e92aafacab19ac69101f9a3c&searchtype=a The road to high efficiency organic light emitting devices ]
-* Lasagne, canneloni, pastas, manicotti, ravioli, vermicelli
+| style="padding:0.079cm;"| <center>Sep 2003</center>
+| style="padding:0.079cm;"| ScienceDirect
+| style="padding:0.079cm;"| <center>87</center>
-===African-American "Soul" Food Examples===
+|-
-* Black-eyed peas and ham hocks, chitterlings, pork neck bones and sauerkraut, fried catfish, oxtail soup
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>9</center>
-* Biscuits, corn bread
+| style="background-color:#DCE6F1;padding:0.079cm;"| [http://ieeexplore.ieee.org/xpl/freeabs_all.jsp?arnumber=1327745 Amorphous silicon thin film transistor circuit integration for organic LED displays on glass and plastic]
-* Collard greens, fried okra, grits
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>Sep 2004</center>
-* Sweet potato pie
+| style="background-color:#DCE6F1;padding:0.079cm;"| IEEE Photonics Society
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>73</center>
-==Wheat processing==
+|-
-AX-rich fiber was extracted from the byproduct of wheat-flour processing. Arabinoxylan (AX) is a hemicellulose that has a xylose backbone with arabinose side chains. Postprandial glucose and insulin responses were improved by ingestion of AX-rich fiber. Further research is required to determine whether AX-rich fiber is of benefit to people with type 2 diabetes. [http://www.ajcn.org/cgi/content/full/71/5/1123 Source]
+| style="padding:0.079cm;"| <center>10</center>
-==Digestive system==
+| style="padding:0.079cm;"| [http://apl.aip.org/resource/1/applab/v82/i16/p2715_s1?isAuthorized=no Transparent-cathode for top-emission organic light-emitting diodes ]
-<table align=center>
+| style="padding:0.079cm;"| <center>Feb 2003</center>
-   <tr>
+| style="padding:0.079cm;"| Applied Physics Letters
-     <td>[[image:digestion of food.jpeg|thumb|left|center|450 px]] </td>
+| style="padding:0.079cm;"| <center>72</center>
-     <td>[[image:key.gif|thumb|right|center|300 px]] </td>
-   </tr>
-</table>
-[[Detailed information on breakdown of food and fat]]
-==Metabolic pathways==
+|}
-[[image:metabolic pathway1.gif|center|700 px|thumb]]
-[[image:metabolic pathway.gif|center|700 px|thumb]]
-==Glucose regulation==
-[[image:image10.gif|center|700 px|thumb]]
+= Dolcera Dashboard =
+[[Image:dashboard_features.png|center|750px|]]
-==Insulin overview==
+'''Dashboard Link'''<br>
-===Insulin secretion===
+{|border="2" cellspacing="0" cellpadding="4" width="100%"
-Insulin secretion in beta cells is triggered by rising blood glucose levels. Starting with the uptake of glucose by the GLUT2 transporter, the glycolytic phosphorylation of glucose causes a rise in the ATP:ADP ratio. This rise inactivates the potassium channel that depolarizes the membrane, causing the calcium channel to open up allowing calcium ions to flow inward. The ensuing rise in levels of calcium leads to the exocytotic release of insulin from their storage granule.
+|'''[http://www.dolcera.com/auth/dashboard/dashboard.php?workfile_id=913 Top Emission OLED - Dashboard] '''
+|width="100"|[[Image:dashboard_thumb.png|center|100px|]]
+|-
+|}
+*Flash Player is essential to view the Dolcera dashboard
-[[image:image11.jpeg|center|700 px|thumb]]
+=Products=
-===How insulin works===
+{|border="2" cellspacing="0" cellpadding="4" width="100%"
-Insulin molecules circulate throughout the blood stream until they bind to their associated (insulin) receptors. The insulin receptors promote the uptake of glucose into various tissues that contain type 4 glucose transporters (GLUT4). Such tissues include skeletal muscles (which burn glucose for energy) and fat tissues (which convert glucose to triglycerides for storage). The initial binding of insulin to its receptor initiates a signal transduction cascade that communicates the message delivered by insulin: remove glucose from blood plasma (see panel 3). Among the wide array of cellular responses resulting from insulin ‘activation,’ the key step in glucose metabolism is the immediate activation and increased levels of GLUT4 glucose transporters. By the facilitative transport of glucose into the cells, the glucose transporters effectively remove glucose from the blood stream. Insulin binding results in changes in the activities and concentrations of intracellular enzymes such as GLUT4. These changes can last from minutes to hours.
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''S. No.'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Company'''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Product'''</center>
+| colspan="2"  style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Specifications'''</center>
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;" rowspan="14"| <center>1</center>
+| style="background-color:#DCE6F1;padding:0.079cm;" rowspan="14"| <center>[http://pro.sony.com/bbsc/ssr/product-BVME250/ Sony] </center>
+| style="background-color:#DCE6F1;padding:0.079cm;" rowspan="14"| [[Image:oled 2.png]] <center>[http://pro.sony.com/bbsc/ssr/product-BVME250/ BVME250]
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''Digital Inputs Specifications'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''Detail:'''
-As important as insulin is to preventing too high of a blood glucose level, it is just as important that there not be too much insulin and hypoglycemia. As one step in monitoring insulin levels, the enzyme insulinase (found in the liver and kidneys) breaks down blood-circulating insulin resulting in a half-life of about six minutes for the hormone. This degradative process ensures that levels of circulating insulin are modulated and that blood glucose levels do not get dangerously low.
+|-
-[[image:image12.jpeg|center|700 px|thumb]]
+| style="background-color:#DCE6F1;padding:0.079cm;"| HDMI
-Insulin binding to the insulin receptor induces a signal transduction cascade which allows the glucose transporter (GLUT4) to transport glucose into the cell.
+| style="background-color:#DCE6F1;padding:0.079cm;"| HDMI (x1) (HDCP correspondence, Deep Color correspondence)
-== Analysis of Oreo cookies ==
+|-
-===Key ingredient of Oreo cookies===
+| style="background-color:#DCE6F1;padding:0.079cm;"| SDI (SMPTE 259M)
-Identifies the various ingredients of the Oreo cookies. The high fructose corn syrup and wheat flour have high glycemic index and are problematic to the diabetes. Thus we have done further deep dive on high fructose corn syrup and wheat flour
+| style="background-color:#DCE6F1;padding:0.079cm;"| BNC (x2)
-[[image:Key ingredient of Oreo cookies.jpeg|center|thumb|500 px]]
-===Substitutes for High fructose corn syrup===
+|-
-[[image:Substitutes for High fructose corn syrup.jpeg|center|thumb|500 px]]
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''Display Specifications'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''Detail:'''
-===Substitutes for wheat flour===
+|-
-[[image:Substitutes for wheat flour.jpeg|center|thumb|500 px]]
+| style="background-color:#DCE6F1;padding:0.079cm;"| Image Aspect Ratio
+| style="background-color:#DCE6F1;padding:0.079cm;"| 16:09
-===Mitigation - High fructose corn syrup===
+|-
-[[image:Mitigation - High fructose corn syrup.jpeg|center|thumb|500 px]]
+| style="background-color:#DCE6F1;padding:0.079cm;"| Resolution
+| style="background-color:#DCE6F1;padding:0.079cm;"| 1920 x 1080 pixels (Full HD)
-===Mitigation – Wheat flour===
+|-
-[[image:Mitigation–Wheat flour.jpeg|center|thumb|500px]]
+| style="background-color:#DCE6F1;padding:0.079cm;"| Screen Size
+| style="background-color:#DCE6F1;padding:0.079cm;"| 24 5/8 inches (623.4 mm)
-===Products substitute for High fructose corn syrup===
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| Viewing Angle
+| style="background-color:#DCE6F1;padding:0.079cm;"| 89°/89°/89°/89°
-[[image:Products substitute for High fructose corn syrup.jpeg|center|thumb|500px]]
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''General Specifications Specifications'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''Detail:'''
-===Products substitute for wheat flour===
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| Dimensions (W x H x D)
+| style="background-color:#DCE6F1;padding:0.079cm;"| 22 3/4 x 16 3/4 x 5 7/8 inches
-[[image:Products substitute for wheat flour.jpeg|center|thumb|500px]]
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| Weight
+| style="background-color:#DCE6F1;padding:0.079cm;"| 28 lb 11 oz
-==Presentation==
+|-
-* Slideset: [[Media: Diabetes - Oreo Cookies ver3.ppt|Oreo Cookies and the sweeteners used in them]]
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''Power Requirements Specifications'''
-* Slideset: [[Media: Diabetes - first draft.ppt|First draft]]
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''Detail:'''
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| Power Consumption
+| style="background-color:#DCE6F1;padding:0.079cm;"| Approx. 145 W
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| Power Requirements
+| style="background-color:#DCE6F1;padding:0.079cm;"| AC 100 V to 240 V, 1.6 A to 0.8 A, 50/60 Hz
+|-
+| style="padding:0.079cm;" rowspan="14"| 2</center>
+| style="padding:0.079cm;" rowspan="14"| <center>[http://www.sony.co.uk/biz/product/bvm/bvm-e170/overview Sony]</center>
+| style="padding:0.079cm;"  rowspan="14"|[[Image:oled 3.png]]<br> <center>[http://www.sony.co.uk/biz/product/bvm/bvm-e170/overview BVM-E170]</center>
+| style="padding:0.079cm;"| '''Digital Inputs Specifications'''
+| style="padding:0.079cm;"| '''Detail:'''
+|-
+| style="padding:0.079cm;"| HDMI
+| style="padding:0.079cm;"| HDMI (x1) (HDCP correspondence, deep colour correspondence)
+|-
+| style="padding:0.079cm;"| SDI
+| style="padding:0.079cm;"| BNC (x2)
+|-
+| style="padding:0.079cm;"| '''Display Specifications'''
+| style="padding:0.079cm;"| '''Detail:'''
+|-
+| style="padding:0.079cm;"| Image Aspect Ratio
+| style="padding:0.079cm;"| 16:09
+|-
+| style="padding:0.079cm;"| Resolution
+| style="padding:0.079cm;"| 1920 x 1080 pixels (Full HD)
+|-
+| style="padding:0.079cm;"| Screen Size
+| style="padding:0.079cm;"| 365.8 x 205.7 mm (14 1/2 x 8 1/8 inches)
+|-
+| style="padding:0.079cm;"| Viewing Angle
+| style="padding:0.079cm;"| 89°/89°/89°/89° (typical) (up/down/left/right contrast >10:1)
+|-
+| style="padding:0.079cm;"| '''General Specifications Specifications'''
+| style="padding:0.079cm;"| '''Detail:'''
+|-
+| style="padding:0.079cm;"| Dimensions (W x H x D)
+| style="padding:0.079cm;"| 436.0 x 282.4 (266.4)* x 214.7 mm (17 1/4 x 11 1/4 (10 1/2)* x 8 1/2 inches) * Height without legs
+|-
+| style="padding:0.079cm;"| Weight
+| style="padding:0.079cm;"| 8.5 kg (18 lb 11 oz)
+|-
+| style="padding:0.079cm;"| '''Power Requirements Specifications'''
+| style="padding:0.079cm;"| '''Detail:'''
+|-
+| style="padding:0.079cm;"| Power Consumption
+| style="padding:0.079cm;"| Approx. 65 W normally with input from a standard HDMI input. Approx. 115 W at maximum load, with four option slots in use and maximum luminance compensation for any deterioration due to aging.
+|-
+| style="padding:0.079cm;"| Power Requirements
+| style="padding:0.079cm;"| AC 100 V to 240 V, 1.4 A to 0.7 A, 50/60 Hz DC 24 V to 28 V, 4.7 A to 4.0 A
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;" rowspan="18"| <center>3</center>
+| style="background-color:#DCE6F1;padding:0.079cm;" rowspan="18"| <center>[http://pro.sony.com/bbsc/ssr/product-PVM740/ Sony]</center>
+| style="background-color:#DCE6F1;padding:0.079cm;" rowspan="18"| [[Image:oled 1.png]] <center>[http://pro.sony.com/bbsc/ssr/product-PVM740/ PVM-740 ]</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''Digital Inputs Specifications'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''Detail:'''
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| HDMI
+| style="background-color:#DCE6F1;padding:0.079cm;"| Yes
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| HDSDI (SMPTE 292M)
+| colspan="2"  style="background-color:#DCE6F1;padding:0.079cm;"| 3G/SDI/HDSDI
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| SDI (SMPTE 259M)
+| style="background-color:#DCE6F1;padding:0.079cm;"| Included
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''Display Specifications'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''Detail:'''
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| Back Light Technology
+| style="background-color:#DCE6F1;padding:0.079cm;"| OLED
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| Native Aspect Ratio
+| style="background-color:#DCE6F1;padding:0.079cm;"| 16:09
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| Resolution
+| colspan="2"  style="background-color:#DCE6F1;padding:0.079cm;"| 960 x 540
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| Screen Size
+| colspan="2"  style="background-color:#DCE6F1;padding:0.079cm;"| Approx 7.4 inches
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| Viewing Angle
+| colspan="7"  style="background-color:#DCE6F1;padding:0.079cm;"| 85°/85°/85°/85° (typical) (up/down/left/right contrast>10:1)
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''General Specifications Specifications'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''Detail:'''
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| Dimensions (W x H x D)
+| colspan="7"  style="background-color:#DCE6F1;padding:0.079cm;"| 8 7/8 x 7 1/4 x 6 3/8 inches Approx. 222.4 x 183.5 x 161.8 mm
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| On-Screen Display
+| style="background-color:#DCE6F1;padding:0.079cm;"| Yes
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| Rack Mount
+| style="background-color:#DCE6F1;padding:0.079cm;"| MB531
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| Weight
+| colspan="4"  style="background-color:#DCE6F1;padding:0.079cm;"| Approx. 5 lb 12 oz Approx. 2.6 kg
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''Power Requirements Specifications'''
+| style="background-color:#DCE6F1;padding:0.079cm;"| '''Detail:'''
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| Power Consumption
+| colspan="2"  style="background-color:#DCE6F1;padding:0.079cm;"| Max. approx. 27W
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| Power Requirements
+| colspan="9"  style="background-color:#DCE6F1;padding:0.079cm;"| AC 100 to 240 V 50/60 Hz 0.5A to 0.3A DC 12 V 1.9 A Rechargeable Battery Pack
+|}
+=Market Research=
+==Major Players==
+{|border="2" cellspacing="0" cellpadding="4" width="100%"
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Major types of player '''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''USA''' </center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''EU''' </center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Japan''' </center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Korea''' </center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Taiwan''' </center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''China''' </center>
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>'''Original IPR for devices and for manufacture process + material supply / verification '''</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| UDC; Kodak; Add-Vision; Magin; Plextronics; Organic Lighting Technologies; GE;3M Innovation
+| style="background-color:#DCE6F1;padding:0.079cm;"| CDT (Sumitomo Chemical) (UK); Novaled (G); Fraunhofer IPMS (G); OLED-T (UK); OTB (ND); MicroEmissive Displays (UK)
+| style="background-color:#DCE6F1;padding:0.079cm;"| Seiko-Epson; Matsushita; Sony; Sumitomo Chemical; Sharp; TM Display; Konica –Minolta; Sanyo; Toppoly; Lumiotec; Canon; Toshiba
+| style="background-color:#DCE6F1;padding:0.079cm;"| Samsung; LG Phillips LCD; Neo View; Doosan DND
+| style="background-color:#DCE6F1;padding:0.079cm;"| AU Optoelectronics (AUO); Univision; Toppoly; Tetrahedron; Chi Mei Optoelectronics
+| style="background-color:#DCE6F1;padding:0.079cm;"|
+|-
+| style="padding:0.079cm;"| <center>'''Bulk materials and glass suppliers '''</center>
+| style="padding:0.079cm;"| PPG; 3M; Dow Corning
+| style="padding:0.079cm;"| Merck Materials (G); BASF (G); CDT (UK); Degussa/ Evonik (G); HC Starck (G); Sensient Imaging Technologies (G); Goodfellow Metals (UK); Novaled (G)
+| style="padding:0.079cm;"| Sumitomo Chemical; Mitsubishi Chemical
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| Syndychem (Shenyang Syndy Chemistry Institute)
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>'''Components – driver ccts., packaging etc '''</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| Corning; Rockwell Collins
+| style="background-color:#DCE6F1;padding:0.079cm;"| ST Microelectronics (It, Fr); Infineon (G)
+| style="background-color:#DCE6F1;padding:0.079cm;"| Maekawa; Matsushita; Toppoly
+| style="background-color:#DCE6F1;padding:0.079cm;"| Dae Joo Electrncs
+| style="background-color:#DCE6F1;padding:0.079cm;"| AUO; Richtek Technologies; Lightsonic; Univision; Wintek
+| style="background-color:#DCE6F1;padding:0.079cm;"| Innocom Technologies Shenzen; RIT Display
+|-
+| style="padding:0.079cm;"| <center>'''OEM OLED FPD screen manufacturer & resellers '''</center>
+| style="padding:0.079cm;"| eMagin; US Micro Products
+| style="padding:0.079cm;"| Densitron Technologies (UK); MicroEmissive Displays (MED) (UK); Pacer International Distributors (UK reseller)
+| style="padding:0.079cm;"| Seiko-Epson; Sharp; Sumitomo Chemical; Lumiotec; TMDisplay; Sanyo
+| style="padding:0.079cm;"| Samsung SDI; Orion OLED; NeoView KOLON; Hyundai LCD
+| style="padding:0.079cm;"| AUO; Chi Mei EL (CMEL); Univision Technology; Evervision Electronics; RiTDisplay; TPO Display
+| style="padding:0.079cm;"| Visionix; Smartdisplays; Universal Display Technologoes (Jilin); Varitronix (HK); Blaze Display Technologies
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| <center>'''Branded application device or/and FPD screen manufacturer with retail device sales '''</center>
+| style="background-color:#DCE6F1;padding:0.079cm;"| OSD
+| style="background-color:#DCE6F1;padding:0.079cm;"| Nokia; Sony-Ericsson
+| style="background-color:#DCE6F1;padding:0.079cm;"| Sony; Matsushita; Hitachi; Toshiba; Imase
+| style="background-color:#DCE6F1;padding:0.079cm;"| Samsung; LG Philips
+| style="background-color:#DCE6F1;padding:0.079cm;"|
+| style="background-color:#DCE6F1;padding:0.079cm;"|
+|-
+| style="padding:0.079cm;"| <center>'''OLED lighting branded suppliers and R&D '''</center>
+| style="padding:0.079cm;"| GE
+| style="padding:0.079cm;"| Thorn EMI (UK); OSRAM (G); Siemens (G)
+| style="padding:0.079cm;"| Sumitomo Chemica
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+|}
+source: [[Media:market.pdf|Major players]]
+'''SWOT analysis'''
+{|border="2" cellspacing="0" cellpadding="4" width="100%"
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Strengths '''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Weaknesses '''</center>
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| • Capability for innovation<br>• Production of base materials for OLED manufacture <br>• Process equipment manufacture is easy.
+| style="background-color:#DCE6F1;padding:0.079cm;"| • Lack of industrial productive capacity or eco-system to support low-cost volume production<br> • Capability to bring innovations to market – i.e. probability of export market success<br> • Lack of branded consumer goods suppliers apart from mobile handsets – e.g. Nokia
+|-
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Opportunities '''</center>
+| style="background-color:#4F81BD;padding:0.079cm;"| <center>'''Threats '''</center>
+|-
+| style="background-color:#DCE6F1;padding:0.079cm;"| • Possible renaissance in manufacturing at low-cost<br>• Use of IPR – with mitigations through agreements <br>• Expansion in base materials supply and process equipment manufacture for low temperatures
+| style="background-color:#DCE6F1;padding:0.079cm;"| • Older technologies – TFT-LCDs which improve technically – become cheaper, flexible, lower power demands and better colour/contrast, scale up larger, etc, make existing (LCD) players far stronger <br>• Strong competitive position and behaviour of current major players globally and market make market entry difficult or increasingly impossible
+|}
+==Market Forecast==
+'''OLED Lighting Market Forecast'''
+*OLED lighting will pick up in 2011, and reach $6.3B by 2018.
+*The OLED lighting market will reach $1.5B by 2015, and $6.3B by 2018.
+*Large investments have been made in OLED lighting in the EU, US, Japan and Korea.
+*There are about 20 OLED lighting organizations worldwide. Europe is currently the leading participant in OLED lighting in terms of projects numbers, government funding, and participating companies.
+*Over 100 companies and universities are currently working on OLED lighting.
+[[Image:markets.png|thumb|center|700 px|[[Media:market.pdf|OLED Lighting Market Forecast]]]]
+'''OLED TV Market Forecast'''
+*OLED TV sets will account for around half of all revenue for OLED panels in 2012, growing rapidly from just $150 million in 2011 to $1.5 billion in 2013.
+*iSuppli’s similarly forecasts the global OLED TV market will reach 2.8 million units by 2013, managing a compound annual growth rate (CAGR) of 212.3% from just 3,000 units in 2007.
+*In terms of global revenue, OLED TV will hit $1.4 billion by 2013, increasing at a CAGR of 206.8% from $2 million in 2007.
+[[Image:marketes.png|thumb|center|700 px|[[Media:markets1.pdf|OLED TV Market Forecast]]]]
+'''OLED Dispaly Market Forecast'''
+*OLED display market will grow to $5.5 billion by 2015, from $0.6 billion in 2008, with a CAGR of 37%. Currently, this growth is being driven by the adoption of active matrix OLED (AMOLED) displays for the primary display in mobile phones and portable media players.
+[[Image:marketees.png|thumb|center|700 px|[[Media:market1s.pdf|OLED Display Market Forecast]]]]
+==Recent Licensing Activities in OLED Segment==
+{|border="2" cellspacing="0" cellpadding="4" width="100%" align="center"
+|align = "center" bgcolor = "#4F81BD"|<font color="#FFFFFF">'''Licensor'''</font>
+|align = "center" bgcolor = "#4F81BD"|<font color="#FFFFFF">'''Licensee'''</font>
+|align = "center" bgcolor = "#4F81BD"|<font color="#FFFFFF">'''Date'''</font>
+|align = "center" bgcolor = "#4F81BD"|<font color="#FFFFFF">'''Details'''</font>
+|-
+|align = "center" bgcolor = "#DCE6F1"|<font color="#0000FF"><u>[http://www.globaloledtech.com/press-releases.html Global OLED Technology LLC]</u></font>
+|align = "center" bgcolor = "#DCE6F1"|OLEDWorks
+|align = "center" bgcolor = "#DCE6F1"|6th Dec 2011
+|align = "center" bgcolor = "#DCE6F1"|Under the terms of the royalty-bearing license, OLEDWorks is granted the right to use certain GOT patents in connection with OLEDWorks<nowiki>’</nowiki> commercialization of specified OLED lighting-related products.
+|-
+|align = "center"|<font color="#0000FF"><u>[http://www.ledsmagazine.com/news/8/2/7 Universal Display]</u></font>
+|align = "center"|Moser Baer
+|align = "center"|8th Feb 2011
+|align = "center"|Moser Baer agreed to license Universal<nowiki>’</nowiki>s OLED technology and purchase UniversalPHOLED (phosphorescent OLED) materials for white OLED panel manufacturing. The companies have agreed to work together for five years in the development of Moser Baer<nowiki>’</nowiki>s US-based OLED panel manufacturing project.
+|-
+|align = "center" bgcolor = "#DCE6F1"|<font color="#0000FF"><u>[http://www.reuters.com/article/2011/09/29/idUS217574+29-Sep-2011+BW20110929 Universal Display]</u></font>
+|align = "center" bgcolor = "#DCE6F1"|Pioneer Corp
+|align = "center" bgcolor = "#DCE6F1"|29th Sep 2011
+|align = "center" bgcolor = "#DCE6F1"|Pioneer is supposed to use Universal Display<nowiki>’</nowiki>s highly efficient, high-performance UniversalPHOLED® technology and materials for the manufacture and sale of OLED lighting products
+|-
+|align = "center"|<font color="#0000FF"><u>[http://www.bloomberg.com/news/2011-11-02/dupont-may-have-licensed-technology-to-samsung-consultant-says.html DuPont]</u></font>
+|align = "center"|Samsung
+|align = "center"|3rd Nov 2011
+|align = "center"|Samsung needed new technology for its larger models for televisions and hoped to benefit from DuPont<nowiki>’</nowiki>s recent innovations.
+|-
+|}<br clear="all">
+==Landscape Analysis Of Top-Emmission OLED==
+===Competitor Landscape===
+====Top Assignee====
+[[Image:Assigneenew.png|thumb|center| 1000 px|Top Assignee]]
+====Filing trends over the publication years====
+[[Image:publication12.png|thumb|center| 1000 px|IP activity based on publication years]]
+====Filing trends over the priority years====
+[[Image:priority1.png|thumb|center| 1000 px|IP activity based on priority years]]
+====Geographical Distribution based on family members====
+*The geographical distribution is based on 10 sample patent numbers along with all their family members.
+[[Image:geographical 1.png|thumb|center| 1000 px|Geographical Distribution based on Family members of OLED]]
+===Key Inventor Mapping===
+{|border="2" cellspacing="0" cellpadding="4" width="100%"
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''S.No'''</center>
+| style="background-color:#99ccff;padding:0.079cm;"| '''Inventor'''
+| style="background-color:#99ccff;padding:0.079cm;"| '''2000'''
+| style="background-color:#99ccff;padding:0.079cm;"| '''2001'''
+| style="background-color:#99ccff;padding:0.079cm;"| '''2002'''
+| style="background-color:#99ccff;padding:0.079cm;"| '''2003'''
+| style="background-color:#99ccff;padding:0.079cm;"| '''2004'''
+| style="background-color:#99ccff;padding:0.079cm;"| '''2005'''
+| style="background-color:#99ccff;padding:0.079cm;"| '''2006'''
+| style="background-color:#99ccff;padding:0.079cm;"| '''2007'''
+| style="background-color:#99ccff;padding:0.079cm;"| '''2008'''
+| style="background-color:#99ccff;padding:0.079cm;"| '''2009'''
+| style="background-color:#99ccff;padding:0.079cm;"| '''2010'''
+| colspan="2"  style="background-color:#99ccff;padding:0.079cm;"| '''Total Result'''
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''1'''</center>
+| style="padding:0.079cm;"| Cok, Ronald
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">3</div>
+| style="padding:0.079cm;"| <div align="right">22</div>
+| style="padding:0.079cm;"| <div align="right">18</div>
+| style="padding:0.079cm;"| <div align="right">17</div>
+| style="padding:0.079cm;"| <div align="right">14</div>
+| style="padding:0.079cm;"| <div align="right">15</div>
+| style="padding:0.079cm;"| <div align="right">4</div>
+| style="padding:0.079cm;"| <div align="right">2</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''96'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''2'''</center>
+| style="padding:0.079cm;"| Park, Jin Woo
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">18</div>
+| style="padding:0.079cm;"| <div align="right">2</div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''20'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''3'''</center>
+| style="padding:0.079cm;"| Choi, Beohm Rock
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">6</div>
+| style="padding:0.079cm;"| <div align="right">7</div>
+| style="padding:0.079cm;"| <div align="right">2</div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''16'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''4'''</center>
+| style="padding:0.079cm;"| Kim, Nam Deog
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">7</div>
+| style="padding:0.079cm;"| <div align="right">6</div>
+| style="padding:0.079cm;"| <div align="right">3</div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''16'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''5'''</center>
+| style="padding:0.079cm;"| Tyan, Yuan Sheng
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">2</div>
+| style="padding:0.079cm;"| <div align="right">7</div>
+| style="padding:0.079cm;"| <div align="right">3</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"|
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''15'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''6'''</center>
+| style="padding:0.079cm;"| Winters, Dustin
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">2</div>
+| style="padding:0.079cm;"| <div align="right">5</div>
+| style="padding:0.079cm;"| <div align="right">5</div>
+| style="padding:0.079cm;"| <div align="right">2</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''15'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''7'''</center>
+| style="padding:0.079cm;"| Choi, Dong Soo
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">13</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''14'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''8'''</center>
+| style="padding:0.079cm;"| Choi, Joon Hoo
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">2</div>
+| style="padding:0.079cm;"| <div align="right">3</div>
+| style="padding:0.079cm;"| <div align="right">4</div>
+| style="padding:0.079cm;"| <div align="right">5</div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''14'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''9'''</center>
+| style="padding:0.079cm;"| Kwak, Won Kyu
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">9</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''14'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''10'''</center>
+| style="padding:0.079cm;"| Miller, Michael
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">4</div>
+| style="padding:0.079cm;"| <div align="right">4</div>
+| style="padding:0.079cm;"| <div align="right">2</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''14'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''11'''</center>
+| style="padding:0.079cm;"| Park, Jae Yong
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">2</div>
+| style="padding:0.079cm;"| <div align="right">8</div>
+| style="padding:0.079cm;"| <div align="right">4</div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''14'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''12'''</center>
+| style="padding:0.079cm;"| Shore, Joel
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">2</div>
+| style="padding:0.079cm;"| <div align="right">2</div>
+| style="padding:0.079cm;"| <div align="right">5</div>
+| style="padding:0.079cm;"| <div align="right">3</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"|
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''14'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''13'''</center>
+| style="padding:0.079cm;"| Arnold, Andrew
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">4</div>
+| style="padding:0.079cm;"| <div align="right">5</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"|
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''13'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''14'''</center>
+| style="padding:0.079cm;"| Boroson, Michael
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">4</div>
+| style="padding:0.079cm;"| <div align="right">3</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">4</div>
+| style="padding:0.079cm;"|
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''13'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''15'''</center>
+| style="padding:0.079cm;"| Goh, Joon Chul
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">4</div>
+| style="padding:0.079cm;"| <div align="right">5</div>
+| style="padding:0.079cm;"| <div align="right">3</div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''13'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''16'''</center>
+| style="padding:0.079cm;"| Tanaka, Masahiro
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">5</div>
+| style="padding:0.079cm;"| <div align="right">4</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''13'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''17'''</center>
+| style="padding:0.079cm;"| Choong, Vi En
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">5</div>
+| style="padding:0.079cm;"| <div align="right">5</div>
+| style="padding:0.079cm;"| <div align="right">2</div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''12'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''18'''</center>
+| style="padding:0.079cm;"| Ghosh, Amalkumar
+| style="padding:0.079cm;"| <div align="right">2</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">3</div>
+| style="padding:0.079cm;"| <div align="right">5</div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''12'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''19'''</center>
+| style="padding:0.079cm;"| Kim, Eun Ah
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">2</div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">9</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''12'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''20'''</center>
+| style="padding:0.079cm;"| Kobayashi Hidekazu
+| style="padding:0.079cm;"| <div align="right"></div>
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"|
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">2</div>
+| style="padding:0.079cm;"| <div align="right">2</div>
+| style="padding:0.079cm;"| <div align="right">5</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="padding:0.079cm;"| <div align="right">1</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''12'''</div>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''21'''</center>
+| style="background-color:#99ccff;padding:0.079cm;"| '''Total Result'''
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''2'''</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''1'''</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''1'''</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''6'''</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''45'''</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''67'''</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''72'''</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''90'''</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''47'''</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''18'''</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''15'''</div>
+| style="background-color:#99ccff;padding:0.079cm;"| <div align="right">'''362'''</div>
+|}
+===Most Cited Patents===
+{|border="2" cellspacing="0" cellpadding="4" width="100%"
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''S.No'''</center>
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''Publication Number'''</center>
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''Assignee/Applicant'''</center>
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''Title'''</center>
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''Publication Date'''</center>
+| colspan="3"  style="background-color:#99ccff;padding:0.079cm;"| <center>'''Count of Citing Patents'''</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''1'''</center>
+| style="padding:0.079cm;"| US6069443A
+| style="padding:0.079cm;"| Fed Corporation
+| style="padding:0.079cm;"| Passive matrix OLED display
+| style="padding:0.079cm;"| <div align="right">30/05/2000</div>
+| style="padding:0.079cm;"| <center>97</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''2'''</center>
+| style="padding:0.079cm;"| US6366017B1
+| style="padding:0.079cm;"| Agilent Technologies
+| style="padding:0.079cm;"| Organic light emitting diodes with distributed bragg reflector
+| style="padding:0.079cm;"| <div align="right">02/04/2002</div>
+| style="padding:0.079cm;"| <center>80</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''3'''</center>
+| style="padding:0.079cm;"| US20020197511A1
+| style="padding:0.079cm;"| United Of America As Respresented By The Secretary Of The Air Force
+| style="padding:0.079cm;"| High efficiency multi-color electro-phosphorescent OLEDS
+| style="padding:0.079cm;"| <div align="right">26/12/2002</div>
+| style="padding:0.079cm;"| <center>51</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''4'''</center>
+| style="padding:0.079cm;"| US6265820B1
+| style="padding:0.079cm;"| Emagin Corporation,De
+| style="padding:0.079cm;"| Heat removal system for use in organic light emitting diode displays having high brightness
+| style="padding:0.079cm;"| <div align="right">24/07/2001</div>
+| style="padding:0.079cm;"| <center>50</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''5'''</center>
+| style="padding:0.079cm;"| US20020195968A1
+| style="padding:0.079cm;"| IBM
+| style="padding:0.079cm;"| Oled current drive pixel circuit
+| style="padding:0.079cm;"| <div align="right">26/12/2002</div>
+| style="padding:0.079cm;"| <center>44</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''6'''</center>
+| style="padding:0.079cm;"| US20020186209A1
+| style="padding:0.079cm;"| Eastman Kodak Company
+| style="padding:0.079cm;"| Touch screen for use with an OLED display
+| style="padding:0.079cm;"| <div align="right">12/12/2002</div>
+| style="padding:0.079cm;"| <center>42</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''7'''</center>
+| style="padding:0.079cm;"| US20030127973A1
+| style="padding:0.079cm;"| Universal Display Corporation
+| style="padding:0.079cm;"| OLEDs having increased external electroluminescence quantum efficiencies
+| style="padding:0.079cm;"| <div align="right">10/07/2003</div>
+| style="padding:0.079cm;"| <center>41</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''8'''</center>
+| style="padding:0.079cm;"| US6844673B1
+| style="padding:0.079cm;"| Alien Technology Corporation
+| style="padding:0.079cm;"| Split-fabrication for light emitting display structures
+| style="padding:0.079cm;"| <div align="right">18/01/2005</div>
+| style="padding:0.079cm;"| <center>38</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''9'''</center>
+| style="padding:0.079cm;"| US20040174116A1
+| style="padding:0.079cm;"| Universal Display Corporation
+| style="padding:0.079cm;"| Transparent electrodes
+| style="padding:0.079cm;"| <div align="right">09/09/2004</div>
+| style="padding:0.079cm;"| <center>36</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''10'''</center>
+| style="padding:0.079cm;"| US20050194896A1
+| style="padding:0.079cm;"| Hitachi Displays Ltd.
+| style="padding:0.079cm;"| Light emitting element and display device and illumination device using the light emitting element
+| style="padding:0.079cm;"| <div align="right">08/09/2005</div>
+| style="padding:0.079cm;"| <center>35</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''11'''</center>
+| style="padding:0.079cm;"| US20020074935A1
+| style="padding:0.079cm;"| Universal Display Corporation
+| style="padding:0.079cm;"| Highly stable and efficient OLEDs with a phosphorescent-doped mixed layer architecture
+| style="padding:0.079cm;"| <div align="right">20/06/2002</div>
+| style="padding:0.079cm;"| <center>35</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''12'''</center>
+| style="padding:0.079cm;"| US20040217702A1
+| style="padding:0.079cm;"| Corning Incorporated
+| style="padding:0.079cm;"| Light extraction designs for organic light emitting diodes
+| style="padding:0.079cm;"| <div align="right">04/11/2004</div>
+| style="padding:0.079cm;"| <center>33</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''13'''</center>
+| style="padding:0.079cm;"| US20020030647A1
+| style="padding:0.079cm;"| Universal Display Corporation
+| style="padding:0.079cm;"| Uniform active matrix oled displays
+| style="padding:0.079cm;"| <div align="right">14/03/2002</div>
+| style="padding:0.079cm;"| <center>32</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''14'''</center>
+| style="padding:0.079cm;"| US20050248270A1
+| style="padding:0.079cm;"| Eastman Kodak Company
+| style="padding:0.079cm;"| Encapsulating OLED devices
+| style="padding:0.079cm;"| <div align="right">10/11/2005</div>
+| style="padding:0.079cm;"| <center>31</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''15'''</center>
+| style="padding:0.079cm;"| US20040113875A1
+| style="padding:0.079cm;"| Eastman Kodak Company
+| style="padding:0.079cm;"| Color oled display with improved power efficiency
+| style="padding:0.079cm;"| <div align="right">17/06/2004</div>
+| style="padding:0.079cm;"| <center>29</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''16'''</center>
+| style="padding:0.079cm;"| US20030230972A1
+| style="padding:0.079cm;"| Eastman Kodak Company
+| style="padding:0.079cm;"| Oled display having color filters for improving contrast
+| style="padding:0.079cm;"| <div align="right">18/12/2003</div>
+| style="padding:0.079cm;"| <center>28</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''17'''</center>
+| style="padding:0.079cm;"| US20050040756A1
+| style="padding:0.079cm;"| Eastman Kodak Company
+| style="padding:0.079cm;"| OLED device having microcavity gamut subpixels and a within gamut subpixel
+| style="padding:0.079cm;"| <div align="right">24/02/2005</div>
+| style="padding:0.079cm;"| <center>27</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''18'''</center>
+| style="padding:0.079cm;"| US6670772B1
+| style="padding:0.079cm;"| Eastman Kodak Company
+| style="padding:0.079cm;"| Organic light emitting diode display with surface plasmon outcoupling
+| style="padding:0.079cm;"| <div align="right">30/12/2003</div>
+| style="padding:0.079cm;"| <center>26</center>
+|-
+| style="background-color:#99ccff;padding:0.079cm;"| <center>'''19'''</center>
+| style="padding:0.079cm;"| US20040061136A1
+| style="padding:0.079cm;"| Eastman Kodak Company
+| style="padding:0.079cm;"| Organic light-emitting device having enhanced light extraction efficiency
+| style="padding:0.079cm;"| <div align="right">01/04/2004</div>
+| style="padding:0.079cm;"| <center>26</center>
+|}
+===Most Cited Patents Mapping===
+[[Image:most.png|thumb|center| 1000 px|Most Cited Patents]]
+===Technology Mapping===
+* In OLED devices not all internally generated light is coupled out of the device (only 20%-50%), which reduces the device efficiency and lifetime.
+* Modification in structures are applied to improve outcouple efficiency in order to enhance the efficiency and lifetime of top emission OLEDs.
+* Below is a snapshot of how various organizations are using different design structures, using the same principle of internal reflection, to achieve higher out-coupling efficiencies.
+====Comparison of out coupling of waveguiding light in top-emission polyLED stack====
+[[Image:Slide-oled.jpg|thumb|center| 500 px|]]
+* Some light is reflected out of the OLED at stray angles in typical cases. By using a barrier material (form of microparticles) in the cathode layer, this light at stray angles hits the barrier material, and some of it is reflected back and guided out at the right angles, reducing light loss.
+[[Image:Slide-oled1.jpg|thumb|center| 500 px|]]
+* Microparticles are incorporated in the substrate, which prevents light loss by reflecting light emitted at stray angles.
+[[Image:Slide-oled2.jpg|thumb|center| 500 px|]]
+* A highly reflective anode is provided made of Aluminium or Silver, with a mirror like finish, to reflect light.
+[[Image:Slide-oled3.jpg|thumb|center| 500 px|]]
+* A shielding layer is provided below the anode, across its entire surface, thus increasing the surface area from which light can be reflected outside.
+[[Image:Slide-oled4.jpg|thumb|center| 500 px|]]
+* The reflective layer, anode, is made of a highly reflective surface like Aluminium alloy or silver.
+====Conclusion====
+The innovation is towards:
+* Incorporating micro-particles structure over the substrate that provide a reflective surface.
+* Highly reflective materials using metals like Molybdenum etc.
+==<span style="color:#C41E3A">Like this report?</span>==
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Difference between pages "Diabetes products and services" and "OLED - Organic Light Emitting Diode"

Latest revision as of 08:02, 27 July 2015

Contents

Introduction

Read More?

Top Emission OLED: Search Strategy

Control Patents

Patent Classes

Concept Table

Micropatent Search Strategy

Scientific Literature Search

Search in Japanese database

Taxonomy

Sample Analysis

Patent Analysis

Article Analysis

Top Cited Patents

Top Cited Articles

Dolcera Dashboard

Products

Market Research

Major Players

Market Forecast

Recent Licensing Activities in OLED Segment

Landscape Analysis Of Top-Emmission OLED

Competitor Landscape

Top Assignee

Filing trends over the publication years

Filing trends over the priority years

Geographical Distribution based on family members

Key Inventor Mapping

Most Cited Patents

Most Cited Patents Mapping

Technology Mapping

Comparison of out coupling of waveguiding light in top-emission polyLED stack

Conclusion

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