AssembleAR from Adam Pickard on Vimeo.
Making an instruction in AR is amazing. no paper is needed, no language barrier as long as you can see.Â
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AssembleAR from Adam Pickard on Vimeo.
Making an instruction in AR is amazing. no paper is needed, no language barrier as long as you can see.Â
After years of doing pop-up events, Two Bit Circus is setting up a permanent, micro-amusement park in Los Angeles.
Love the idea, play and learn. I wish my classes are like this park
Nike announced today that itâs now using augmented reality features through its iOS app to make exclusive sneaker releases a more interactive experience. Using its Nike+ SNKRS app popular amoâŠ
While VR needs certain requirements to enjoy it, thus it seems to take a slow move, AR is coming faster, closer to mass users. It is not only an intersting way to introduce the product but also a great way of advertising. Also, it allows pinpoint marketing, - precisely. For instance, exclusive products/services for exclusive customers. -in a very intrguing, engaging way.
Bring back the feels.
oldies but goodies. While people look for newer gadgets, how fresh these items are!
Artists Ai Weiwei and Olafur Eliasson's collaborative art project, Moon, creates a shared online canvas, allowing a global audience to leave their individual...
http://www.moonmoonmoonmoon.com/#sphere
Art meets Technology. - Leave our marks or messages on the virtual moon. Stories are shining through the moon.Â
Communication Arts' projects in a filterable, scrollable page.
Neither a pre-recorded animation nor on loop, the work is being rendered in real time by a computer program. The flowers spring up, grow, bud and blossom bef...
This artwork uses accumulated light points to create a sculptural body, similar to the way distinct dots of color form an image in a pointillist painting. In...
Hyper-Reality presents a provocative and kaleidoscopic new vision of the future, where physical and virtual realities have merged, and the city is saturated ...
What does a cultural Big Bang look like? For Amit Sood, director of Google's Cultural Institute and Art Project, it's an online platform where anyone can explore the world's greatest collections of art and artifacts in vivid, lifelike detail. Join Sood and Google artist in residence Cyril Diagne in a mind-bending demo of experiments from the Cultural Institute and glimpse the exciting future of accessibility to arts and culture.
Two UW undergraduate students won $10,000 for building a gadget-loaded glove that translates sign language gestures into audio.
From the interview.Â
âIt is not about helping people; they donât need help. It is about how technology can be accessible and inclusive. Itâs a means of building bridges and breaking down barriers.â
When memories age
For our brain it makes a great difference whether we remember experiences from long ago, or if we recollect recent events. RUB-neuroscientists were able to show that distinct brain-networks are involved.
Results are published in âeLIFEâ
When we remember events which occurred recently, the hippocampus is activated. This area in the temporal lobe of the brain is a hub for learning and memory. But what happens, if we try to remember things that took place years or decades ago? Neuroscientists at the Ruhr-University Bochum and the Osaka University have been able to give some answers to this question. They reveal that the neural networks involved in retrieving very old memories are quite distinct from those used to remember recent events. The results of the study have now been published in the open source science journal eLIFE.
Hippocampus is a hub for memory
Neuroscientists agree that the hippocampus, which contains the cornu ammonis regions 1 and 3 (CA1 and CA3), plays a major role in retrieving recent memories. However, a major controversy in memory research resides on whether the hippocampus is also engaged when experiences date back half a life-time or whether this is the role of the parahippocampal region of the brain: the cortical areas directly adjacent to the hippocampus. Prof. Dr. Magdalena Sauvage and her team of neuroscientists have monitored brain activity in mice during the retrieval of memories that are one day to one year old â e.g. up to the mouse-equivalent of 40 human years. For their study they applied a high-resolution molecular imaging technique, which detects the expression of a particular gene tied to plasticity processes and this way sheds light on cognitive processes.
Old and recent memories are retrieved differently
âFor the very first time we were able to show that the retrieval of old and recent memories are supported by distinct brain networksâ, Prof. Dr. Magdalena Sauvage reports. The CA3 region, believed to be the place of memory storage in the hippocampus, no longer plays a role when we remember very old memories. Rather, the involvement of the CA1 region persists and the cortical areas adjacent to the hippocampus become involved. The reason for the differential involvement of the hippocampal subregions could lie in the mechanisms supported by CA3, explains Prof. Sauvage: âIn CA3, memories can be retrieved on the basis of single features of an original memory, which are used as cues. Since the memory for single features degrades over time, we speculate that they might ultimately be of no more use as cues, hence retrieving memory would then essentially rely on CA1 and other processes taking place in the parahippocampal region of the brainâ.
resource for future
Wearable sensors provide continuous, real-time analysis of biochemicals in perspiration
resource for future project
Believe or not, during the process, (yet, still far from completion), Every time, I felt stuck, or overwhelmed. I looked at the photo of a boy, closing his eyes and his subtle smile.- regardless of whether he is a blind or not, it put me into ..: thinking about what he imagines..? the warmth of light? what he wants to do? where he wants to go? I closed my eyes and tried to feel what if I cantâ see.?the photo makes me smile and happy. happy enough to continue.Â
Going back to the project, in reality,
For the final, it includes,
visual design: logo & other graphic designs, materials
publication: a design book
product design: drawing, modeling, mockups
web design.Â
Since it is still in process, not much to say, but the final result will be updated the end of next week and will keep continuing until it comes true.
IBM Wants to Implant Fake Brains in Real Brains to Prevent Seizures
TALK ABOUT NEURAL networking.
In Melbourne, Australia, Stefan Harrer is running an artificial software brain atop an artificial hardware brain in an effort to analyze a brain that isnât artificial at all. Ultimately, he and his colleagues envision merging these three brains together so that the artificial can augment the real.
Harrer is an IBM researcher stationed at the companyâs Australian research lab. Together with neurologists at the University of Melbourne, heâs developing a computing system that can analyze your brain waves in an effort to predict epileptic seizures.
The trick is that Harrer and his colleagues are building the system using a neural network, computer software that mimics the web of neurons in the human brain. This is the same breed of neural network that identifies photos you post to Facebook, recognizes the commands you speak into your Android phone, and more. If you feed a photo of your mother into a neural network, it can learn to recognize your mother. And now, Harrer is feeding scans of brain waves into a neural network, in the hopes that it can learn to recognize epilepsy.
âWeâre trying to extract all the meaningful information from all the background noise,â Harrer says. âWe want to be able to detect a specific seizure for a specific patient.â
But thereâs also another trick. Harrer and team are running this neural network on an experimental IBM chip called TrueNorth, which, like the neural network theyâre using, is built in the image of the human brain. Because it uses a similar architecture, TrueNorth is rather adept at running neural networks. And because it consumes very little power, Harrer and team hope to one day use the chip to build a wearable device that, working in tandem with a brain implant, monitors for seizures around the clock and notifies patients before they happen.
âWe want to do this on a wearable system that you put on a subjectâon a patientâand have it do analysis in real-time, 24/7,â Harrer says. âThatâs the only way this technology will have an impact beyond cool research papers.â
Science Non-Fiction
That may sound like science fiction. But at the University of Melbourne, neurologists have already run a study in which a less complex implant gathered EEG readings from epilepsy patients over the course of about three years. This data, in fact, is what Harrer and team are using to train their neural network.
Weâre still a long way from a time when we can attach an (artificial) neural network to a human bodyâHarrerâs work is still in the preliminary stagesâbut thatâs the ultimate aim here. And thatâs certainly doable, according to Kimford Meador, a neurologist at Stanford University Medical Center who has no connection to the work in Australia. âIf you have an implant near the seizureâs origin,â Meador says, âyou can detect them quite reliably.â
Harrerâs project, which is described in a peer-reviewed paper being presented at the ACM Computing Frontiers conference in May, is part of sweeping movement among companies and researchers to develop so-called deep neural networks. Along with the widespread use of deep neural nets at Facebook and Google, Twitter is using them to identify pornography on its social network. Microsoft is using them to translate Skype calls from one language to another. And academics at the University of California at Berkeley are using them to teach robots to screw on bottle caps. The difference is that Harrer is using fake brains to analyze real brain wavesâand that heâs experimenting with TrueNorth, a chip thatâs not yet available on the open market.
Herrarâs work is particularly intriguing because itâs difficult for todayâs machines to automatically predict seizures on the fly, in part because they arenât using the latest in AI. âNo one has really applied machine learning to this kind of task,â Meador says. But there is a clear path using such machine learning. As Meador explains, manually detecting a seizure just before it happens isnât that difficultâat least where some patients are concerned. So, if you have data from seizures, you should be able to teach a neural network to detect on its own. Thanks to that earlier study from the University of Melbourne, Harrer and team have the data.
The harder part, Meador says, is trying to predict the probability of seizure well ahead of time. That takes some much deeper analysis. But itâs also more useful, and indeed, this is part of what Harrer and his colleagues at the University are striving for. Because of new insights that have arisen since that original implant study, says Mark Cook, the neurologist at the University of Melbourne who led the study, they âshould be able to see deeper into the structure underlying the seizure activity.â
Fixing Broken Systems
But the tech that makes all this practical is the TrueNorth chip. Nowadays, companies like Google, Facebook, and Microsoft typically run their neural networks across myriad machines inside massive computer data centers. They train the neural network inside the data center. When you allow Facebook to identify people in your photos, for instance, your laptop, tablet, or phone is communicating with those neural nets via the Internet. With TrueNorth, IBM aims to make it easier to run neural networks on the laptop, tablet, or phone itselfâand maybe on a wearable that talks to an implant in your head.
The idea is that, after detecting brain wave patterns that indicate a seizure, the device would notify you by sending a wireless signal to your smartphone. And even just a little bit of notice before a seizure happens can be beneficial to patients, says Dean Robert Freestone, a senior research fellow at the University of Melbourne who is working closely with Harrer. âIt can give them a new sense of freedom and eliminate a lot of risk in their lives,â he says. The device could provide enough notice to, say, pull your car to the side of the road before a seizure happens.
Harrer acknowledges that this full-blown warning system is still years off. But modern AI technology keeps getting smarter. He and his collaborators even think that their implants could one day be used to prevent seizures entirely: the system would detect a seizure coming on and send out electrical impulses in order to stop it. In essence, an artificial brain could end up augmenting and improving a real brain. âOur aim is to replace broken neural systems with machinesâmachines that can interact with the brain in a very natural way,â says Freestone.
This too is entirely doable, says Stanfordâs Meador. At least one Silicon Valley company is already offer a device that will stimulate the brain in an effort to curb seizures, he says. But itâs not nearly as sophisticated as the device that Harrer envisions. âThis could let us to something that we canât do at the moment,â Cook says. âIt provides us with a better way.â
Image Credit: GETTY IMAGES
Source: WIRED Magazine (CADE METZ)
Which neuron is more mature? Single cell transcriptome knows!
The human brain is extremely complex, containing billions of neurons forming trillions of synapses where thoughts, behavior and emotion arise. However, when an individual is performing a particular task, not many but only a few neural circuits are in action. The enormous cellular heterogeneity of the brain structure has made dissections of the molecular basis for neural circuitry function particularly challenging, because previous studies on genetic and epigenetic profiling using a block of brain tissues simply do not have the sufficient precision and accuracy to correspond to the activities of a few activated circuitries in the brain.
In the March issue of Springerâs journal Protein & Cell, Chen et al. reported, for the first time, molecular gene expression signatures underlying human neuronal maturation judged by electrophysiological characteristics. The authors successfully employed âPatch-seqâ technology whereby patch-clamp recording and single neuron transcriptome profiling were performed on the same human neurons derived from more primitive stem cells. The authors also implemented powerful bioinformatics analyses, including Weighted Gene Coexpression Network Analyses (WGCNA), to extrapolate important signature genes corresponding to immature and mature human neurons, which is unprecedented.
By cross-referencing published data to single neuron transcriptome profiled from fetal and adult human brains (though without electrophysiological analyses), 39 neuronal genes were identified, which could serve as generic biomarkers for human neuronal maturation. The precise role of these 39 genes in the neuronal maturation process remains to be determined in the future. On the other hand, a number of calcium signaling, mitochondrial function, and ubiquitination-related genes are consistently elevated when human neurons mature, underscoring the critical importance of these biological processes relating to neuronal function. It is expected that dysregulation of these processes might be core elements leading to neurodegeneration.
The technology of coupling electrophysiological recording and single cell transcriptome analysis plus the powerful WGCNA should, in the future, be widely used to delineate the molecular logic for neural circuitry wiring, function and plasticity, to ultimately understand the human brain, the mind, and major human neurological disorders.
sadly, I wasnât good at science, biology(wasnât bad, my favorite among physics, chemistry, biology and..what is it? the last one?) when i was in high school.But now, I am more interested in all these and it sounds making sense (in other word,it understandable/i find it interesting.Â
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Another interesting history and unknown (to many) historical fact.
while men are dominant in computer science, engineering..., programming,,these days, another interesting, but not-so-well known women in computer science. Â