Tag Archives: PaperPhone

Graphene dreams of the Morph

For anyone who’s not familiar with the Morph, it’s an idea that Nokia and the University of Cambridge’s Nanoscience Centre have been working on for the last few years. Originally announced as a type of flexible phone that you could wrap around your wrist, the Morph is now called a concept.  Here’s an animation illustrating some of the concepts which include flexibility and self-cleaning,

There have been very few announcements of any kind about the Morph or the technology that will support this concept. A few months ago, they did make an announcement about researching graphene as a means of actualizing the concept (noted in my May 6, 2011 posting [scroll down about 1/2 way]).

Interestingly the latest research published  on graphene and the flexible, transparent screens that are necessary to making something like the Morph a reality has come from a lab at Rice University. From the August 1, 2011 news item on Nanowerk,

The lab of Rice chemist James Tour lab has created thin films that could revolutionize touch-screen displays, solar panels and LED lighting. The research was reported in the online edition of ACS Nano (“Rational Design of Hybrid Graphene Films for High-Performance Transparent Electrodes”).

Flexible, see-through video screens may be the “killer app” that finally puts graphene — the highly touted single-atom-thick form of carbon — into the commercial spotlight once and for all, Tour said. Combined with other flexible, transparent electronic components being developed at Rice and elsewhere, the breakthrough could lead to computers that wrap around the wrist and solar cells that wrap around just about anything. [emphasis mine]

The lab’s hybrid graphene film is a strong candidate to replace indium tin oxide (ITO), a commercial product widely used as a transparent, conductive coating. It’s the essential element in virtually all flat-panel displays, including touch screens on smart phones and iPads, and is part of organic light-emitting diodes (OLEDs) and solar cells.

Here’s James Tour and Yu Zhu, the paper’s lead author, explaining how the flexible screen was developed,

There are other flexible screens and competitors to the Morph notably the PaperPhone mentioned in my May 6,2011 posting (scroll down about 2/3 of the way) and in my May 12, 2011 posting featuring an interview with Roel Vertegaal of Queen’s University, Ontario, Canada, about the PaperPhone. (We did not discuss the role that graphene might or might not play in the development of the Paperphone’s screens.)

I wonder what impact this work at Rice will have not only for the Morph and the PaperPhone but on the European Union’s pathfinder research competition (the prize is $1B Euros), mentioned in my June 13, 2011 posting about graphene (scroll down about 1/3 of the way). Graphene is one of the research areas being considered for the prize.

ETA Aug. 5, 2011: Tour’s team just published another paper on graphene, one that proves you can make it from anything containing carbon according the Aug. 4, 2011 news item, One Box of Girl Scout Cookies Worth $15 Billion: Lab Shows Troop How Any Carbon Source Can Become Valuable Graphene, on Science Daily,

The cookie gambit started on a dare when Tour mentioned at a meeting that his lab had produced graphene from table sugar.

“I said we could grow it from any carbon source — for example, a Girl Scout cookie, because Girl Scout Cookies were being served at the time,” Tour recalled. “So one of the people in the room said, ‘Yes, please do it. … Let’s see that happen.'”

Members of Girl Scouts of America Troop 25080 came to Rice’s Smalley Institute for Nanoscale Science and Technology to see the process. Rice graduate students Gedeng Ruan, lead author of the paper, and Zhengzong Sun calculated that at the then-commercial rate for pristine graphene — $250 for a two-inch square — a box of traditional Girl Scout shortbread cookies could turn a $15 billion profit.

Here’s the full reference for this second paper,

Gedeng Ruan, Zhengzong Sun, Zhiwei Peng, James M. Tour. Growth of Graphene from Food, Insects and Waste. ACS Nano, 2011; 110729113834087 DOI: 10.1021/nn202625c

The article is behind a paywall.

From the bleeding edge to the cutting edge to ubiquitous? The PaperPhone, an innovation case study in progress

This story has it all: military, patents, international competition and cooperation, sex (well, not according to the academics but I think it’s possible), and a bizarre device – the PaperPhone (last mentioned in my May 6, 2011 posting on Human-Computer Interfaces).

“If you want to know what technologies people will be using 10 years in the future, talk to the people who’ve been working on a lab project for 10 years,” said Dr. Roel Vertegaal, Director of the Human Media Lab at Queen’s University in Kingston, Ontario. By the way, 10 years is roughly the length of time Vertegaal and his team have been working on a flexible/bendable phone/computer and he believes that it will be another five to 10 years before the device is available commercially.

Image from Human Media Lab press kit

As you can see in the image, the prototype device looks like a thin piece of plastic that displays a menu. In real life that black bit to the left of the image is the head of a cable with many wires connecting it to a computer. Here’s a physical description of the device copied from the paper (PaperPhone: Understanding the Use of Bend Gestures in Mobile Devices with Flexible Electronic Paper Displays) written by Byron Lahey, Audrey Girouard, Winslow Burleson and Vertegaal,

PaperPhone consists of an Arizona State University Flexible Display Center 3.7” Bloodhound flexible electrophoretic display, augmented with a layer of 5 Flexpoint 2” bidirectional bend sensors. The prototype is driven by an E Ink Broadsheet AM 300 Kit featuring a Gumstix processor. The prototype has a refresh rate of 780 ms for a typical full screen gray scale image.

An Arduino microcontroller obtains data from the Flexpoint bend sensors at a frequency of 20 Hz. Figure 2 shows the back of the display, with the bend sensor configuration mounted on a flexible printed circuit (FPC) of our own design. We built the FPC by printing its design on DuPont Pyralux flexible circuit material with a solid ink printer, then etching the result to obtain a fully functional flexible circuit substrate. PaperPhone is not fully wireless. This is because of the supporting rigid electronics that are required to drive the display. A single, thin cable bundle connects the AM300 and Arduino hardware to the display and sensors. This design maximizes the flexibility and mobility of the display, while keeping its weight to a minimum. The AM300 and Arduino are connected to a laptop running a Max 5 patch that processes sensor data, performs bend gesture recognition and sends images to the display. p. 3

It may look ungainly but it represents a significant step forward for the technology as this team (composed of researchers from Queen’s University, Arizona State University, and E Ink Corporation) appears to have produced the only working prototype in the world for a personal portable flexible device that will let you make phone calls, play music, read a book, and more by bending it. As they continue to develop the product, the device will become wireless.

The PaperPhone and the research about ‘bending’, i.e., the kinds of bending gestures people would find easiest and most intuitive to use when activating the device, were presented in Vancouver in an early session at the CHI 2011 Conference where I got a chance to speak to Dr. Vertegaal and his team.

Amongst other nuggets, I found out the US Department of Defense (not DARPA [Defense Advanced Research Projects Agency] oddly enough) has provided funding for the project. Military interest is focused on the device’s low energy requirements, lowlight screen, and light weight in addition to its potential ability to be folded up and carried like a piece of paper (i. e., it could mould itself to fit a number of tight spaces) as opposed to the rigid, ungiving borders of a standard mobile device. Of course, all of these factors are quite attractive to consumers too.

As is imperative these days, the ‘bends’ that activate the device have been patented and Vertegaal is in the process of developing a startup company that will bring this device and others to market. Queen’s University has an ‘industrial transfer’ office (they probably call it something else) which is assisting him with the startup.

There is international interest in the PaperPhone that is collaborative and competitive. Vertegaal’s team at Queen’s is partnered with a team at Arizona State University led by Dr. Winslow Burleson, professor in the Computer Systems Engineering and the Arts, Media, and Engineering graduate program and with Michael McCreary, Vice President Research & Development of E Ink Corporation representing an industry partner.

On the competitive side of things, the UK’s University of Cambridge and the Finnish Nokia Research Centre have been working on the Morph which as I noted in my May 6, 2011 posting still seems to be more concept than project.

Vertegaal noted that the idea of a flexible screen is not new and that North American companies have gone bankrupt trying to bring the screens to market. These days, you have to go to Taiwan for industrial production of flexible screens such as the PaperPhone’s.

One of my last questions to the team was about pornography. (In the early days of the Internet [which had its origins in military research], there were only two industries that made money online, pornography and gambling. The gambling opportunities seem pretty similar to what we already enjoy.) After an amused response, the consensus was that like gambling it’s highly unlikely a flexible phone could lend itself to anything new in the field of pornography. Personally, I’m not convinced about that one.

So there you have a case study for innovation. Work considered bleeding edge 10 years ago is now cutting edge and, in the next five to 10 years, that work will be become a consumer product. Along the way you have military investment, international collaboration and competition, failure and success, and, possibly, sex.

Human-Computer interfaces: flying with thoughtpower, reading minds, and wrapping a telephone around your wrist

This time I’ve decided to explore a few of the human/computer interface stories I’ve run across lately. So this posting is largely speculative and rambling as I’m not driving towards a conclusion.

My first item is a May 3, 2011 news item on physorg.com. It concerns an art installation at Rensselaer Polytechnic Institute, The Ascent. From the news item,

A team of Rensselaer Polytechnic Institute students has created a system that pairs an EEG headset with a 3-D theatrical flying harness, allowing users to “fly” by controlling their thoughts. The “Infinity Simulator” will make its debut with an art installation [The Ascent] in which participants rise into the air – and trigger light, sound, and video effects – by calming their thoughts.

I found a video of someone demonstrating this project:
http://blog.makezine.com/archive/2011/03/eeg-controlled-wire-flight.html

Please do watch:

I’ve seen this a few times and it still absolutely blows me away.

If you should be near Rensselaer on May 12, 2011, you could have a chance to fly using your own thoughtpower, a harness, and an EEG helmet. From the event webpage,

Come ride The Ascent, a playful mash-up of theatrics, gaming and mind-control. The Ascent is a live-action, theatrical ride experience created for almost anyone to try. Individual riders wear an EEG headset, which reads brainwaves, along with a waist harness, and by marshaling their calm, focus, and concentration, try to levitate themselves thirty feet into the air as a small audience watches from below. The experience is full of obstacles-as a rider ascends via the power of concentration, sound and light also respond to brain activity, creating a storm of stimuli that conspires to distract the rider from achieving the goal: levitating into “transcendence.” The paradox is that in order to succeed, you need to release your desire for achievement, and contend with what might be the biggest obstacle: yourself.

Theater Artist and Experience Designer Yehuda Duenyas (XXXY) presents his MFA Thesis project The Ascent, and its operating platform the Infinity System, a new user driven experience created specifically for EMPAC’s automated rigging system.

The Infinity System is a new platform and user interface for 3D flying which combines aspects of thrill-ride, live-action video game, and interactive installation.

Using a unique and intuitive interface, the Infinity System uses 3D rigging to move bodies creatively through space, while employing wearable sensors to manipulate audio and visual content.

Like a live-action stunt-show crossed with a video game, the user is given the superhuman ability to safely and freely fly, leap, bound, flip, run up walls, fall from great heights, swoop, buzz, drop, soar, and otherwise creatively defy gravity.

“The effect is nothing short of movie magic.” – Sean Hollister, Engadget

Here’s a brief description of the technology behind this ‘Ascent’ (from the news item on physorg.com),

Ten computer programs running simultaneously link the commercially available EEG headset to the computer-controlled 3-D flying harness and various theater systems, said Todd. [Michael Todd, a Rensselaer 2010 graduate in computer science]

Within the theater, the rigging – including the harness – is controlled by a Stage Tech NOMAD console; lights are controlled by an ION console running MIDI show control; sound through MAX/MSP; and video through Isadora and Jitter. The “Infinity Simulator,” a series of three C programs written by Todd, acts as intermediary between the headset and the theater systems, connecting and conveying all input and output.

“We’ve built a software system on top of the rigging control board and now have control of it through an iPad, and since we have the iPad control, we can have anything control it,” said Duenyas. “The ‘Infinity Simulator’ is the center; everything talks to the ‘Infinity Simulator.’”

This May 3, 2011 article (Mystery Man Gives Mind-Reading Tech More Early Cash Than Facebook, Google Combined) by Kit Eaton on Fast Company also concerns itself with a brain/computer interface. From the article,

Imagine the money that could be made by a drug company that accurately predicted and treated the onset of Alzheimer’s before any symptoms surfaced. That may give us an idea why NeuroVigil, a company specializing in non-invasive, wireless brain-recording tech, just got a cash injection that puts it at a valuation “twice the combined seed valuations of Google’s and Facebook’s first rounds,” according to a company announcement

NeuroVigil’s key product at the moment is the iBrain, a slim device in a flexible head-cap that’s designed to be worn for continuous EEG monitoring of a patient’s brain function–mainly during sleep. It’s non-invasive, and replaces older technology that could only access these kind of brain functions via critically implanted electrodes actually on the brain itself. The idea is, first, to record how brain function changes over time, perhaps as a particular combination of drugs is administered or to help diagnose particular brain pathologies–such as epilepsy.

But the other half of the potentailly lucrative equation is the ability to analyze the trove of data coming from iBrain. And that’s where NeuroVigil’s SPEARS algorithm enters the picture. Not only is the company simplifying collection of brain data with a device that can be relatively comfortably worn during all sorts of tasks–sleeping, driving, watching advertising–but the combination of iBrain and SPEARS multiplies the efficiency of data analysis [emphasis mine].

I assume it’s the notion of combining the two technologies (iBrian and SPEARS) that spawned the ‘mind-reading’ part of this article’s title. The technology could be used for early detection and diagnosis, as well as, other possibilities as Eaton notes,

It’s also possible it could develop its technology into non-medicinal uses such as human-computer interfaces–in an earlier announcement, NeuroVigil noted, “We plan to make these kinds of devices available to the transportation industry, biofeedback, and defense. Applications regarding pandemics and bioterrorism are being considered but cannot be shared in this format.” And there’s even a popular line of kid’s toys that use an essentially similar technique, powered by NeuroSky sensors–themselves destined for future uses as games console controllers or even input devices for computers.

What these two technologies have in common is that, in some fashion or other, they have (shy of implanting a computer chip) a relatively direct interface with our brains, which means (to me anyway) a very different relationship between humans and computers.

In the next couple of items I’m going to profile a couple of very similar to each other technologies that allow for more traditional human/computer interactions, one of which I’ve posted about previously, the Nokia Morph (most recently in my Sept. 29, 2010 posting).

It was first introduced as a type of flexible phone with other capabilities. Since then, they seem to have elaborated on those capabilities. Here’s a description of what they now call the ‘Morph concept’ in a [ETA May 12, 2011: inserted correct link information] May 4, 2011 news item on Nanowerk,

Morph is a joint nanotechnology concept developed by Nokia Research Center (NRC) and the University of Cambridge (UK). Morph is a concept that demonstrates how future mobile devices might be stretchable and flexible, allowing the user to transform their mobile device into radically different shapes. It demonstrates the ultimate functionality that nanotechnology might be capable of delivering: flexible materials, transparent electronics and self-cleaning surfaces.

Morph, will act as a gateway. It will connect the user to the local environment as well as the global internet. It is an attentive device that adapts to the context – it shapes according to the context. The device can change its form from rigid to flexible and stretchable. Buttons of the user interface can grow up from a flat surface when needed. User will never have to worry about the battery life. It is a device that will help us in our everyday life, to keep our self connected and in shape. It is one significant piece of a system that will help us to look after the environment.

Without the new materials, i.e. new structures enabled by the novel materials and manufacturing methods it would be impossible to build Morph kind of device. Graphene has an important role in different components of the new device and the ecosystem needed to make the gateway and context awareness possible in an energy efficient way.

Graphene will enable evolution of the current technology e.g. continuation of the ever increasing computing power when the performance of the computing would require sub nanometer scale transistors by using conventional materials.

For someone who’s been following news of the Morph for the last few years, this news item doesn’t give you any new information. Still, it’s nice to be reminded of the Morph project. Here’s a video produced by the University of Cambridge that illustrates some of the project’s hopes for the Morph concept,

While the folks at the Nokia Research Centre and University of Cambridge have been working on their project, it appears the team at the Human Media Lab at the School of Computing at Queen’s University (Kingston, Ontario, Canada) in cooperation with a team from Arizona State University and E Ink Corporation have been able to produce a prototype of something remarkably similar, albeit with fewer functions. The PaperPhone is being introduced at the Association of Computing Machinery’s CHI 2011 (Computer Human Interaction) conference in Vancouver, Canada next Tuesday, May 10, 2011.

Here’s more about it from a May 4, 2011 news item on Nanowerk,

The world’s first interactive paper computer is set to revolutionize the world of interactive computing.

“This is the future. Everything is going to look and feel like this within five years,” says creator Roel Vertegaal, the director of Queen’s University Human Media Lab,. “This computer looks, feels and operates like a small sheet of interactive paper. You interact with it by bending it into a cell phone, flipping the corner to turn pages, or writing on it with a pen.”

The smartphone prototype, called PaperPhone is best described as a flexible iPhone – it does everything a smartphone does, like store books, play music or make phone calls. But its display consists of a 9.5 cm diagonal thin film flexible E Ink display. The flexible form of the display makes it much more portable that any current mobile computer: it will shape with your pocket.

For anyone who knows the novel, it’s very Diamond Age (by Neal Stephenson). On a more technical note, I would have liked more information about the display’s technology. What is E Ink using? Graphene? Carbon nanotubes?

(That does not look like to paper to me but I suppose you could call it ‘paperlike’.)

In reviewing all these news items, it seems to me there are two themes, the computer as bodywear and the computer as an extension of our thoughts. Both of these are more intimate relationships, the latter far more so than the former, than we’ve had with the computer till now. If any of you have any thoughts on this, please do leave a comment as I would be delighted to engage on some discussion about this.

You can get more information about the Association of Computing Machinery’s CHI 2011 (Computer Human Interaction) conference where Dr. Vertegaal will be presenting here.

You can find more about Dr. Vertegaal and the Human Media Lab at Queen’s University here.

The academic paper being presented at the Vancouver conference is here.

Also, if you are interested in the hardware end of things, you can check out E Ink Corporation, the company that partnered with the team from Queen’s and Arizona State University to create the PaperPhone. Interestingly, E Ink is a spin off company from the Massachusetts Institute of Technology (MIT).