Introducing the OSA Display Technology Technical Group

Presented by:

Dr. Daniel Smalley

Chair of the OSA Display Technology Technical Group

Turkey Farming

Elroy Pearson

MIT

Mark II

Origin Story

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Polarization RotationPolarization Rotation

High Angular Deflection

Frequency Division Color

Holographic Stereograms

Low cost

Success!

Sadness

Bigger!

ILLUMINATI-CON

Advanced 3D and World Domination

Clandestine meeting to be held during Heidelberg DH 2016. Admittance by password only.

Dr. T.C. Poon

Mentor of the OSA Display Technology Technical Group

Precision optoelectronic metrology and Information Display Technologies

Research Center Shanghai University

Holographic 3D Display

–One of Future Ultimate Display

Outlines

1. Holographic 3D TV

2. Holographic 3D Projection

3. Analog Hologram

4. Digital Hologram Print

Holographic 3D Display

Holography is a true 3D technique

Intensity Information

Phase InformationHolographic reconstruction

Coherent light Object

Holographic material

Reference beam

Object beam

Holographic

material

Readout Light

Reconstructed 3D image

Hologram

Hologram

Holographic recording

Experimental setup for R/G/B holographic display R/G/B holographic display videos

Real-time dynamic holographic 3D display

Refresh time：~2 ms

Holographic 3D

display in materials

Real time dynamic display

Full-parallax 3D display

Large size and high definition display

3D video display

applications

Real-time dynamic holographic 3D display

Society for Information Display Symposium

2012 Technical Highlights

Invited Talk at OSA Digital Holography and

3D Imaging 2013 in USA

Real-time dynamic holographic 3D display

20 Plenary and Invited Talks at International Conferences in USA, Russia, Japan, Singapore,

Taiwan, and China

Real-time dynamic holographic 3D display

Top 5 download OSA Digital Holography and 3D

Imaging Meeting PapersCover Paper in SID Information Display

Holographic 3D TV

3D model

Hologram

Holographic 3D display

without pixelation

Images from different angles Computer generated holograms

Holographic 3D projection

Holographic 3D projection

Holographic 3D projection

Static analog hologram of real object

Analog hologram

Holographic print

Hologram print system

3D model

Holographic print

Reconstructed 3D image

from printed hologram

CGH

Future holographic 3D display

Future holographic 3D display

Precision optoelectronic metrology and Information Display Technologies

Research Center

Thank you for your attention!

Edward Buckley

March 2016

Webinar presentation

About me

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• Dr. Edward Buckley

• Born London, England

• Education

– University College London (1997-2001)

• MEng. Electrical and Electronic Engineering

• First class with Honours

– Cambridge University (2003-2006)

• Ph.D. Computer Generated Holography for Displays and Sensors

• Sponsored by BAE Systems

• Arsenal season ticket holder

Career highlights

56

• Have taken two novel display technologies from lab bench to product revenue

• Recognized expert in display technologies, optics and image processing with

50 publications and 17 patents

• Invented Light Blue Optics’ holographic projection technology and span out

business from the University of Cambridge, raising $45m VC funding

• Created ecosystem and supply chain to support laser projection business;

created automotive, defense and aerospace business from scratch

• Architected Pixtronix’ ground-breaking DMS display (entire architecture

including color processing, backlight, backplane and power saving techniques)

• Drove DMS technology through $175m acquisition by Qualcomm and eventual

production and use in a 7” tablet PC

Light Blue Optics (LBO) – phase-only projector

57

LBO – technical highlights

58

• Novel architecture and hologram generation algorithm to exploit HVS properties

and hence reduce required calculation by six orders of magnitude

• Highly novel optical system and projection lens assembly– At the time, delivered lowest speckle contrast of all laser projectors

• Developed custom FLCOS microdisplay– 5m pixels, high tilt FLC material, binary modulation

• Laser development programs– Green laser (808nm pump diode)

– Green laser (1064nm pump DBR)

– 642nm red laser development

• 8 million gate 90nm ASIC

• Two Asian ODMs making complete subsystems

Pixtronix / Qualcomm – 7” MEMS / IGZO panel

59

Pixtronix – technical highlights (1)

60

• DMS RGB field-sequential technology was extremely constrained– Critical image and power consumption quality problems, all counter-opposing

– Yield issues made these problems even worse (achievable bit depth was low, for example)

• Developed two generations of display architecture:– Generation 1: RGB, scalar dither, multiple display modes

– Generation 2: RGBW multi-primary, vector dither, local tone correction, 50% power of Gen. 1

• Solved critical image quality problems – Rigorous modeling, simulation and optimization program

– Color breakup, false contouring, dither artifacts, 30 Hz / 60 Hz flicker

– Completely novel panel drive and image processing chain

• Solved critical power problems– Novel FSC dimming algorithms (Generation 1)

– Artifact-free RGBW mode, real-time gamut mapping (Generation 2)

Pixtronix – technical highlights (2)

61

• Designed display architecture to provide maximum flexibility– MEMS and TFT reliability issues were never fully solved

– Display architectures anticipated this and provided variable bit depth, display timing, etc. to ease

yield and fabrication constraints

– Accurate LED control over dimming range, even with relatively wide binning

• Designed and implemented two novel color pipelines in 40 nm ASICs– HW and ARM core embedded SW

• Production of 7” “Momiji” tablet– Four different display modes (wide gamut, narrow gamut, monochrome)

– Interface to Android host

• Improved yield by an order of magnitude– Perception-led analysis to determine allowable cluster size of flickering pixels

– Dark pixel correction to hide particulate defects

Nanolumens

Current research interests

63

• Multi-primary displays– Resolving FSC artifacts, enhancing image quality

• Display modeling, simulation and characterization– Perceptually accurate measurements, benchmarking, competitive analysis

• Halftoning and dithering– Aggressively reducing bit depth while maintaining image quality

• Wide dynamic range, backlight control and local tone correction– Focus on efficient chipset implementations

• Novel light sources for lower cost / enhanced efficiency– 405nm blue lasers, phosphors, OLEDs

• Gamut mapping– Techniques for large and small gamuts (RGB LEDs enable both)

• Subpixel rendering

Dr. Joshua Kvavle

Executive Committee Member of OSA Display Technology Technical Group

BioBio

Husband and

Father

US Navy Work

• Engineer at SPAWAR Systems Center Pacific (San Diego) • 2009 to present

• Focus Areas• Photonics

• Non-linear Optics

• Fiber Optic Gyroscopes

• Augmented Reality

• Grassroots S&T Learn Sailor Needs Enhanced Visualization

• Ocean Augmented Reality – Google Glass Project

• Navy Augmented Reality Roadmap

OCEAN AR

N NE

Contact 1(1.3 km).7 k m)

Proof of Concept with Google Glass

Navy AR Roadmap

A Vision for the Future

• “The summation of human experience is being expanded at a prodigious rate, and the means we use for threading through the consequent maze to the momentarily important item is the same as we used in the days of square-rigged ships.”

• “The hope is that, in not too many years, human brains and computing machines will be coupled together very tightly, and that the resulting partnerships will think as no human brain has ever thought and process data in a way not approached by the information-handling machines we know today.”

A Vision for the Future

• “The summation of human experience is being expanded at a prodigious rate, and the means we use for threading through the consequent maze to the momentarily important item is the same as we used in the days of square-rigged ships.”

• “The hope is that, in not too many years, human brains and computing machines will be coupled together very tightly, and that the resulting partnerships will think as no human brain has ever thought and process data in a way not approached by the information-handling machines we know today.”

- Vannevar Bush, 1945

- J.C.R. Licklider, 1960

Role of Displays in the Man + Machine Revolution?

Sheridan & Verplank (1978)

How are Displays different in 2016 vs 1966?

1960 2016Manufacturer RCA RCA

Model Victor LED55G55R120QDipslay Type CRT LCD

Price ($ in 2016) $3,980 400

Diagonal Width 21" 55"Display (in2) 108 1269Pixel Count 214,855 2,073,600aspect ratio 4:3 16:9

Refresh Rate 30 Hz 120 HzWeight 175 lbs 51 lbs

How might Displays improve in the 21st Century?

• Infinite Field of View.

• Ever present, but only when we want them.

• Create depth in a transparent display that is indistinguishable from reality.

• Generate black in a transparent display.

• Image resolution in transparent displays making them indistinguishable from reality.

Next Webinar:

Choose a side.

Nominate a champion now!

Light Field vs.

Holographic Display

Tentatively Scheduled for June 23rd 9am EDT