OpenSpace Innovates

02/01/2017

12/10/2016

Never Miss The First Opportunity!

A young man wished to marry the farmer's beautiful daughter. He went to the farmer to ask his permission. The farmer looked him over and said,

"Son, go stand out in that field. I'm going to release three bulls, one at a time. If you can catch the tail of any one of the three bulls, you can marry my daughter."

The young man stood in the pasture awaiting the first bull.

The barn door opened and out ran the biggest, meanest-looking bull he had ever seen. He decided that one of the next bulls had to be a better choice than this one, so he ran over to the side and let the bull pass through the pasture out the back gate.


The barn door opened again. Unbelievable. He had never seen anything so big and fierce in his life. It stood pawing the ground, grunting, slinging slobber as it eyed him. Whatever the next bull was like, it had to be a better choice than this one. He ran to the fence and let the bull pass through the pasture, out the back gate.


The door opened a third time. A smile came across his face. This was the weakest, scrawniest little bull he had ever seen. This one was his bull. As the bull came running by, he positioned himself just right and jumped at just the exact moment. He grabbed... But the bull had no tail!


Life is full of opportunities. Some will be easy to take advantage of, some will be difficult. But once we let them pass (often in hopes of something better), those opportunities may never again be available.


So always grab the first opportunity.

22/10/2015

May this Vijaya Dashami, light up for you.
The hope of Happy times,
And dreams for a year full of Smiles!
Wish you a Happy Dussehra...!!

08/06/2015

"What matters is where you want to go. Focus in the right direction!"

-- Donald Trump, Billionaire Real Estate Developer

19/05/2015

What if the touchscreen of your smartphone or tablet could touch you back?

Northwestern University and Carnegie Mellon University researchers now report a fascinating discovery that provides insight into how the brain makes sense of data from fingers.

In a study of people drawing their fingers over a flat surface that has two "virtual bumps," the research team is the first to find that, under certain circumstances, the subjects feel only one bump when there really are two. Better yet, the researchers can explain why the brain comes to this conclusion.

Their new mathematical model and experimental results on "haptic illusions" could one day lead to flat-screen displays featuring active touch-back technology, such as making your touchscreen's keyboard actually feel like a keyboard. Tactile information also could benefit the blind, users of dashboard technology in cars, players of video games and more.

"Touch is so important in our real world, but it is neglected in the digital world," said J. Edward Colgate, an expert in touch-based (haptic) systems. He is the Allen and Johnnie Breed University Professor of Design at Northwestern's McCormick School of Engineering and Applied Science. "We want to create something that will make touch a reality for people interacting with their screens, and this work is a step in that direction."

Forces felt by the fingers as they travel along a flat surface can lead to the illusion that the surface actually contains bumps. This so-called "virtual bump illusion" is well known in the haptics field, Colgate said, and the researchers were able to make use of it.

"By leveraging the virtual bump illusion, we were able to design a meaningful experiment that shed light on the way the brain integrates information from multiple fingers," Colgate said. "Our big finding was 'collapse ' -- the idea that separate bumps felt in separate fingers are nonetheless experienced as one bump if their separation happens to match that of the fingers."

The study, which will be published the week of Feb. 9 by the Proceedings of the National Academy of Sciences (PNAS), is about how the brain makes sense of data from the fingers.

Colgate, the paper's corresponding author, and longtime Northwestern haptics collaborator Michael A. Peshkin joined forces with Carnegie Mellon's Roberta Klatzky to work on filling the digital world's functional gap by enabling flat screens to engage the haptic perceptual system. This is known as "surface haptic" technology.

The research team's experiment presented two virtual bumps, with the distance between them varying across trials, to subjects participating in the study. When bump and finger spacing were identical, subjects reported feeling two bumps as one. In this case, the brain thinks it is too coincidental that there should be two bumps at the same time, so it registers the bumps as one.

"How does your body and mind interpret something flat and 'see' it as having shape and texture?" said Klatzky, an expert in cognitive psychology and haptic perception. "An important step toward effective surface haptics is to understand what kinds of stimulation might lead you to feel something other than uniform flatness when you touch the surface of your device. Our study contributes to this understanding."

Klatzky is the Charles J. Queenan Jr. Professor of Psychology and Human-Computer Interaction at Carnegie Mellon.

"Our findings will help us and other researchers figure out how to design haptic technology to produce certain tactile effects," said Peshkin, a professor of mechanical engineering at the McCormick School. "Haptics -- giving a feel to objects -- just enhances the physicality of a person's experience."

Steven G. Manuel, the study's first author and a Northwestern alumnus, developed the model of where the "illusion of protrusion" comes from. It describes how the brain constructs a mental depiction of the surface using sensory signals from two fingers as they explore a surface over time and space.

A critical feature of the model, and one found in theories of perception more generally, is that it assumes the brain is biased toward inferring causes rather than registering coincidences. In essence, as the fingers encounter forces while they explore a flat surface, the brain creates virtual bumpiness that is most consistent with the physical bumps that would produce the same sensations.

17/05/2015

"Don't worry when you are not recognized, but strive to be worthy of recognition."

-- Abraham Lincoln, 16th U.S. president

08/05/2015

"You can become an even more excellent person by constantly setting higher and higher standards for yourself and then by doing everything possible to live up to those standards."

-- Brian Tracy, Author

06/05/2015

3Doodler is the world’s first and only 3D Printing Pen. Using ABS or PLA plastic (the material used by many 3D printers), 3Doodler draws in the air or on surfaces. It’s compact and easy to use, and requires no software or computers. You just plug it into a power socket and can start drawing anything within minutes.
3Doodler is a brand new way of creating objects and artistic works. Whether you are an artist, hobbyist or 3D printing fanatic, we can’t wait to see what you 3Doodle!
As 3Doodler draws, it extrudes heated plastic, which quickly cools and solidifies into a strong stable structure. This allows you to build an infinite variety of shapes and items with ease! Most people will instantly be able to trace objects on paper, and after only a few hours of practice you will be able to make far more intricate objects.
3Doodler works on almost any surface, including plastic, allowing users to personalize items such as iPhone cases, or anything else they feel like 3Doodling on. 3Doodler can even be used for minor repair work.
There are many ways 3Doodler can be used. 3Doodles can be created as flat forms and peeled off a piece of paper, as freestyle 3D objects, or in separate parts, ready to be joined together using the 3Doodler. The creative opportunities are endless.

3Doodler is not a toy for children (it’s recommended for ages 12+). While the plastic extruded from 3Doodler is safe to touch once it has left the pen, the pen itself has a metal tip that can get as hot as 270C. There is no reason for any user to touch the tip while in use, but safety comes first, and we are creating a video series that will explain how to use the 3Doodler, covering off the different techniques and safety precautions necessary.

04/05/2015

Researchers are always searching for improved technologies, but the most efficient computer possible already exists. It can learn and adapt without needing to be programmed or updated. It has nearly limitless memory, is difficult to crash, and works at extremely fast speeds. It's not a Mac or a PC; it's the human brain. And scientists around the world want to mimic its abilities.
Both academic and industrial laboratories are working to develop computers that operate more like the human brain. Instead of operating like a conventional, digital system, these new devices could potentially function more like a network of neurons.

"Computers are very impressive in many ways, but they're not equal to the mind," said Mark Hersam, the Bette and Neison Harris Chair in Teaching Excellence in Northwestern University's McCormick School of Engineering. "Neurons can achieve very complicated computation with very low power consumption compared to a digital computer."

A team of Northwestern researchers, including Hersam, has accomplished a new step forward in electronics that could bring brain-like computing closer to reality. The team's work advances memory resistors, or "memristors," which are resistors in a circuit that "remember" how much current has flowed through them.

The research is described in the April 6 issue of Nature Nanotechnology. Tobin Marks, the Vladimir N. Ipatieff Professor of Catalytic Chemistry, and Lincoln Lauhon, professor of materials science and engineering, are also authors on the paper. Vinod Sangwan, a postdoctoral fellow co-advised by Hersam, Marks, and Lauhon, served as first author. The remaining co-authors--Deep Jariwala, In Soo Kim, and Kan-Sheng Chen--are members of the Hersam, Marks, and/or Lauhon research groups.

"Memristors could be used as a memory element in an integrated circuit or computer," Hersam said. "Unlike other memories that exist today in modern electronics, memristors are stable and remember their state even if you lose power."

Current computers use random access memory (RAM), which moves very quickly as a user works but does not retain unsaved data if power is lost. Flash drives, on the other hand, store information when they are not powered but work much slower. Memristors could provide a memory that is the best of both worlds: fast and reliable. But there's a problem: memristors are two-terminal electronic devices, which can only control one voltage channel. Hersam wanted to transform it into a three-terminal device, allowing it to be used in more complex electronic circuits and systems.