Sunday, July 15, 2012
DARPA is developing brain-control capability (6)
http://www.smartplanet.com/blog/smart-takes/darpa-aims-to-control-prosthetic-limbs-with-brain-implants/4890
DARPA aims to control prosthetic limbs with brain implants
By Andrew Nusca | March 10, 2010, 6:28 AM PST
As the use of prosthetic limbs increases in military veterans,
the Pentagon is investigating prostheses that are more durable, reliable and
directly controlled using brain implants.
DARPA, the military’s research arm, said it will launch the
next phase of its decade-old Revolutionizing Prosthetics program, which
had an original goal to create a fully-functioning, neurally-controlled human
limb within five years.
Though the agency has made considerable progress —human
trials of the DEKA Arm are underway, and a neurally-controlled arm is
under development at Johns Hopkins University — it hasn’t yet
achieved its goal.
The hurdles:
It has proved difficult to fully integrate human neural
pathways with artificial platforms.
Neural-recording interfaces have short life spans of just
two years.
Neural-recording interfaces don’t extract adequate
information to yield seamless movement from brain to neurons to limbs.
Current prototypes can’t move fast enough: even at 500
events per second, it’s not enough for fluid motion.
To face the challenge, DARPA is launching its Histology
for Interface Stability Over Time program.
The goal: create a neurally-controlled limb that lasts for
70 years and has complete integration with the human body.
Here’s what the agency says (.pdf):
DARPA is soliciting innovative research proposals in the
area of neural-recording interface failure analysis. The HIST program seeks to
develop the technology needed to reliably extract information from the nervous
system, and to do so at a scale and rate necessary to control many
degree-of-freedom (DOF) machines, such as high-performance prosthetic limbs.
Technologies and techniques emerging from this program will enable the construction
of reliable neural-recording interfaces, which will be suitable for clinical
use over the lifetime of an injured soldier (~70 years). Additionally, an
objective understanding of the failure mechanisms will lead to high-throughput
biological testing, due to the discovery of predictive markers linked to a high
probability of failure and other accelerated-testing techniques. Proposed
research should investigate innovative approaches that enable revolutionary
advances in science, devices, or systems. Specifically excluded is research
that primarily results in evolutionary improvements to the existing state of
practice.
In other words: DARPA wants to understand why
neural-recording interfaces are so unreliable, and how failure can be predicted
before an amputee is left without the use of an artificial limb.
The program is structures in three phases over three years.
It’s basically like a hacker contest for prosthetic limbs — DARPA wants
researchers to overload neural systems to find vulnerabilities.
Of particular concern are “implanted cortical microelectrodes,”
or brain implants, which DARPA believes may be the best system for the job.
DARPA is developing brain-control capability (5)
http://www.popsci.com/technology/article/2010-09/darpa-wants-mind-control-keep-soldiers-sharp-smart-and-safe
DARPA has been trying to crawl inside the minds of soldiers
for a while now, but a new ultrasound technology could let them get deeper
inside than ever. Working under a DARPA grant, a researcher at Arizona State is
developing transcranial pulsed ultrasound technology that could be
implanted in troops’ battle helmets, allowing soldiers to manipulate brain
functions to boost alertness, relieve stress, or even reduce the effects of
traumatic brain injury.
Manipulating the brain to enhance warfighting capabilities
and maintain mental acuity on the battlefield has long been a topic of interest
for DARPA and various military research labs, but the technology to do so
remains limited. Deep brain stimulation (DBS), for instance, requires
surgically implanted electrodes to stimulate neural tissues, while
less-invasive methods like transcranial magnetic stimulation (TMS) possess
limited reach and low spatial resolution.
But Dr. William J. Tyler, an assistant professor of life
sciences at ASU, writes on the DoD’s “Armed With Science” blog: “To overcome
the above limitations, my laboratory has engineered a novel technology which
implements transcranial pulsed ultrasound to remotely and directly stimulate
brain circuits without requiring surgery. Further, we have shown this
ultrasonic neuromodulation approach confers a spatial resolution approximately
five times greater than TMS and can exert its effects upon subcortical brain circuits
deep within the brain.”
Tyler’s technology, packaged in a warfighter’s helmet, would
allow soldiers to flip a switch to stimulate different regions of their brains,
helping them relieve battle stress when it’s time to get some rest, or to boost
alertness during long periods without sleep. Grunts could even relieve pain
from injuries or wounds without resorting to pharmaceutical drugs. More
importantly, in the periods after brain trauma ultrasound technology could
reduce swelling and metabolic damage that is often the root cause of lasting
brain damage.
DARPA is developing brain-control capability (4)
IBM produces first 'brain chips'
http://www.bbc.co.uk/news/technology-14574747
IBM has developed a microprocessor which it claims comes
closer than ever to replicating the human brain.
The system is capable of "rewiring" its
connections as it encounters new information, similar to the way biological
synapses work.
Researchers believe that by replicating that feature, the
technology could start to learn.
Cognitive computers may eventually be used for understanding
human behaviour as well as environmental monitoring.
Dharmendra Modha, IBM's project leader, explained that they
were trying to recreate aspects of the mind such as emotion, perception,
sensation and cognition by "reverse engineering the brain."
The SyNAPSE system uses two prototype "neurosynaptic
computing chips". Both have 256 computational cores, which the scientists
described as the electronic equivalent of neurons.
One chip has 262,144 programmable synapses, while the other
contains 65,536 learning synapses.
Man machine
In humans and animals, synaptic connections between brain
cells physically connect themselves depending on our experience of the world.
The process of learning is essentially the forming and strengthening of
connections.
A machine cannot solder and de-solder its electrical tracks.
However, it can simulate such a system by "turning up the volume" on
important input signals, and paying less attention to others.
IBM has not released exact details of how its SyNAPSE
processor works, but Dr Richard Cooper, a reader in cognitive science at
Birkbeck, University of London said that it likely replicated physical
connections using a "virtual machine".
Instead of stronger and weaker links, such a system would
simply remember how much "attention" to pay to each signal and alter
that depending on new experiences.
"Part of the trick is the learning algorithm - how
should you turn those volumes up and down," said Dr Cooper.
"There's a a whole bunch of tasks that can be done just
with a relatively simple system like that such as associative memory. When we
see a cat we might think of a mouse."
Some future-gazers in the cognitive computing world have
speculated that the technology will reach a tipping point where machine
consciousness is possible.
However, Dr Mark Bishop, professor of cognitive computing at
Goldsmiths, was more cautious.
"[I] understand cognition to be something over and
above a process simulated by the execution of mere computations, [and] see such
claims as verging on the magical," he said.
IBM's work on the SyNAPSE project continues and the company,
along with its academic partners, has just been awarded $21m (£12.7m) by the US
Defense Advanced Research Projects Agency (DARPA).
DARPA is developing brain-control capability (3)
DARPA takes new look at electrical brain stimulation to aid
in learning April 21, 2011
by Bob Yirka in Neuroscience
http://medicalxpress.com/news/2011-04-darpa-electrical-brain-aid.html
New research going on in Albequerque, NM by a team of
neuroscientists working for the Defense Advanced Research Projects Agency
(DARPA) indicates that mild brain stimulation with electrical shocks, might in
fact cause people to learn more easily.
The team, led by Vincent Clark, of the University of New
Mexico, has been applying electrodes to the scalps of volunteers, and then
giving them very mild electrical shocks while they play a battle simulation
video game designed to teach soldiers to react properly in stressful
conditions. Called transcranial direct-current stimulation (tDCS), the
procedure employs a nine volt battery and electrodes connected to wet sponges
affixed to the temples of game players to send just a few milliamps of current
through the skull and into the brain as they attempt to differentiate between
friend and foe in dilapidated, potentially dangerous environmental conditions.
Two groups were tested, one received 2 milliamps while they
played, the other just 0.1. The volunteers receiving the larger amount showed
twice as much improvement as those that did not, which Clark says shows quite
clearly how effective tDCS can be. Pilot video for tDCS informed consent.
Applying electricity to the brain has a long and at times dark history.
Doctors, psychiatrists and other researchers have known for
hundreds of years that applying electrical current to the brain can cause
changes; some good, some not so much. Electrical stimulation has been used to
keep executed prisoners from twitching after death, to “help” patients overcome
depression and more recently to help people with injuries or brain impairments to
regain functionality. This history now colors any new research as fear and
skepticism tend to get in the way of serious work.
This is likely the
reason that this new research is being done by DARPA, rather than an
independent organization; it doesn’t have to answer to anyone except the DoD.
Because the amount of current is so small, volunteers report no pain, just a
slight tingling sensation during the procedure, and afterwards can offer no
real explanations as to why they performed better than they might have
otherwise.
This research, and other studies like it, have set off both
alarms and intrigue in certain quarters. Some worry people, such as college
students will jump on the procedure as a means to help cram for exams, others
wonder if electronic devices such as blue-tooth phones are emitting electricity
that might help them learn; while others yet point out, very soberly, that no
one really knows just yet what long-term effects people might have from
exposure to something as simple as tCDS.
Read more at: http://medicalxpress.com/news/2011-04-darpa-electrical-brain-aid.html#jCp
Read more at: http://medicalxpress.com/news/2011-04-darpa-electrical-brain-aid.html#jCp
DARPA is developing brain-control capability (2)
http://www.theregister.co.uk/2011/08/18/ibm_darpa_synapse_project/
DARPA shells out $21m for IBM cat brain chip
By Timothy Prickett Morgan
Posted in Rise of the Machines, 18th August 2011
16:27 GMT
The US Defense Advanced Research Projects Agency is moving
ahead with IBM in the third leg of its Synapse cat brain chip. That leaves one
more leg, a tail, and nine lives to go.
Because this is the military, the third leg of the Systems
of Neuromorphic Adaptive Plastic Scalable Electronics (Synapse) project at
DARPA is called phase 2, and IBM's techies have already completed phases 0 and
1. The initial phase of the project simulated the cortex of a cat brain on
an IBM BlueGene massively parallel supercomputer with 147,456 cores and 144TB
of memory and developing the basic synaptic circuits for the brain chip.
[…]
Phase one, which brought in $16.1m in funding spread across
IBM and researchers at Stanford University, the University of
Wisconsin-Madison, Cornell University, Columbia University Medical Center, and
the University of California-Merced, focused on simulating and building
prototype brain chips that have electronic synapses and memory circuits instead
of simulating them using sequentially processing von Neumann-style processors
like the ones on our desktops and in the data centers of the world.
IBM is unveiling the fruits of the phase 1 work today and
the fact that its cognitive computer dream team, headed up by Dharmendra Modha,
the Synapse project leader at IBM Research, as well as announcing that DARPA
has allocated another $21m in funding to begin the phase 2 work.
Like most DARPA projects, Synapse has some impressive goals
and ones that may not pan out. There is a lot of talk about "dawn of a new
paradigm" and "dawn of a new age" as researchers try to create
brain-like systems. The problem, according to DARPA, is that von Neumann
machines, while great for playing Angry Birds and wasting time at work, are
less efficient than biological computers – the ripply, fat-encrusted gray stuff
between your ears – by between a factor of 1 million to 1 billion. It takes an
increasingly complex von Neumann machine to handle increasingly complex data
streaming in from the environment:
[…]
The IBM team is working for DARPA to create a chip that is
designed to chew on streams telemetry and rewire itself, much as your brain
does as it learns, as it learns about the world from that telemetry.
"This is a major initiative to move beyond the von
Neumann paradigm that has been ruling computer architecture for more than half
a century," said Modha in a statement. "Future applications of
computing will increasingly demand functionality that is not efficiently delivered
by the traditional architecture. These chips are another significant step in
the evolution of computers from calculators to learning systems, signaling the
beginning of a new generation of computers and their applications in business,
science and government."
[…]
IBM is not using wetware biological components to make its
neurosynaptic chips, but rather plain old 45 nanometer CMOS with
silicon-on-oxide doping, exactly the same process that IBM is using to etch its
Power7 processors. The neurosynaptic cores replicating the function of
synapses, neurons, and axons in the brain to provide memory, computation, and
communication. IBM has created two prototype neurosynaptic chips thus far,
which have 256 simulated neurons. One design has 262,144 programmable synapses
and the other has 65,536 learning synapses.
IBM has already put these relatively small-brained chips
through the paces performing navigation, machine vision, pattern recognition,
associative memory, and other tasks. The long-term goal of the Synapse project
is to create a system based on the neurosynaptic chips that has 10 billion
electronic neurons and 100 trillion synapses, all packed up in a two-liter
volume and burning only one kilowatt.
[…]
At this point, we humans can tell the Internet to go read
and write itself and get back to goofing off. Or, we'll be working the gas
chambers for Skynet.
In phase 3 of the Synapse project, IBM plans to cook up a
chip with 10 million neurons and work on simulation and design of a fake brain
with 100 million neurons using a multi-chip. In phase 4 of the project, IBM
Research's team hopes to build a robot using this multi-chip fake brain and do
the emulation and simulation of a fake brain with around 10 billion neurons,
what IBM and DARPA call a "human level design". ®
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