A new open-source, artificially intelligent prosthetic leg designed by researchers at the University of Michigan and Shirley Ryan AbilityLab is now available to the scientific community.
The leg’s free-to-copy design and programming are intended to improve the quality of life of patients and accelerate scientific advances by offering a unified platform to fragmented research efforts across the field of bionics.
When Elon Musk and DARPA both hop aboard the cyborg hypetrain, you know brain-machine interfaces (BMIs) are about to achieve the impossible.
BMIs, already the stuff of science fiction, facilitate crosstalk between biological wetware with external computers, turning human users into literal cyborgs. Yet mind-controlled robotic arms, microelectrode “nerve patches”, or “memory Band-AIDS” are still purely experimental medical treatments for those with nervous system impairments.
With the Next-Generation Nonsurgical Neurotechnology (N3) program, DARPA is looking to expand BMIs to the military. This month, the project tapped six academic teams to engineer radically different BMIs to hook up machines to the brains of able-bodied soldiers. The goal is to ditch surgery altogether—while minimizing any biological interventions—to link up brain and machine.
Wearing a sensor-packed glove while handling a variety of objects, MIT researchers have compiled a massive dataset that enables an AI system to recognize objects through touch alone. The information could be leveraged to help robots identify and manipulate objects, and may aid in prosthetics design.
The researchers developed a low-cost knitted glove, called “scalable tactile glove” (STAG), equipped with about 550 tiny sensors across nearly the entire hand. Each sensor captures pressure signals as humans interact with objects in various ways. A neural network processes the signals to “learn” a dataset of pressure-signal patterns related to specific objects. Then, the system uses that dataset to classify the objects and predict their weights by feel alone, with no visual input needed.
In a paper published in Nature, the researchers describe a dataset they compiled using STAG for 26 common objects—including a soda can, scissors, tennis ball, spoon, pen, and mug. Using the dataset, the system predicted the objects’ identities with up to 76 percent accuracy. The system can also predict the correct weights of most objects within about 60 grams.
The Cyborg and Transhumanist Forum at the Nevada Legislature on May 15, 2019, marked a milestone for the U.S. Transhumanist Party and the Nevada Transhumanist Party. This was the first time that an official transhumanist event was held within the halls of a State Legislature, in one of the busiest areas of the building, within sight of the rooms where legislative committees met. The presenters were approached by tens of individuals – a few legislators and many lobbyists and staff members. The reaction was predominantly either positive or at least curious; there was no hostility and only mild disagreement from a few individuals. Generally, the outlook within the Legislative Building seems to be in favor of individual autonomy to pursue truly voluntary microchip implants. The testimony of Anastasia Synn at the Senate Judiciary Committee on April 26, 2019, in opposition to Assembly Bill 226 — https://www.youtube.com/watch?v=kXGessk5c24 — is one of the most memorable episodes of the 2019 Legislative Session for many who heard it. It has certainly affected the outcome for Assembly Bill 226, which was subsequently further amended to restore the original scope of the bill and only apply the prohibition to coercive microchip implants, while specifically exempting microchip implants voluntarily received by an individual from the prohibition. The scope of the prohibition was also narrowed by removing the reference to “any other person” and applying the prohibition to an enumerated list of entities who may not require others to be microchipped: state officers and employees, employers as a condition of employment, and persons in the business of insurance or bail. These changes alleviated the vast majority of the concerns within the transhumanist and cyborg communities about Assembly Bill 226.
This Cyborg and Transhumanist Forum comes at the beginning of an era of transhumanist political engagement with policymakers and those who advise them. It was widely accepted by the visitors to the demonstration tables that technological advances are accelerating, and that policy decisions regarding technology should only be made with adequate knowledge about the technology itself – working on the basis of facts and not fears or misconceptions that arise from popular culture and dystopian fiction. Ryan Starr shared his expertise on the workings and limitations of both NFC/RFID microchips and GPS technology and who explained that cell phones are already far more trackable than microchips ever could be (based on their technical specifications and how those specifications could potentially be improved in the future). U.S. Transhumanist Party Chairman Gennady Stolyarov II introduced visitors to the world of transhumanist literature by bringing books for display – including writings by Aubrey de Grey, Bill Andrews, Ray Kurzweil, Jose Cordeiro, Ben Goertzel, Phil Bowermaster, and Mr. Stolyarov’s own book “Death is Wrong” in five languages. It appears that there is more sympathy for transhumanism within contemporary political circles than might appear at first glance; it is often transhumanists themselves who overestimate the negativity of the reaction they expect to receive. But nobody picketed the event or even called the presenters names; transhumanist ideas, expressed in a civil and engaging way – with an emphasis on practical applications that are here today or due to arrive in the near future – will be taken seriously when there is an opening to articulate them.
Researchers have developed a brain-computer interface the size of a baby aspirin that can restore mobility to people with paralysis or amputated limbs.
How does it work? It rewires neural messages from the brain’s motor cortex to a robotic arm, or reroutes it to the person’s own muscles. In this video, Big Think contributor Susan Hockfield, president emerita of MIT, explains further.
DARPA has awarded funding to six organizations to support the Next-Generation Nonsurgical Neurotechnology (N) program, first announced in March 2018. Battelle Memorial Institute, Carnegie Mellon University, Johns Hopkins University Applied Physics Laboratory, Palo Alto Research Center (PARC), Rice University, and Teledyne Scientific are leading multidisciplinary teams to develop high-resolution, bidirectional brain-machine interfaces for use by able-bodied service members. These wearable interfaces could ultimately enable diverse national security applications such as control of active cyber defense systems and swarms of unmanned aerial vehicles, or teaming with computer systems to multitask during complex missions.
“DARPA is preparing for a future in which a combination of unmanned systems, artificial intelligence, and cyber operations may cause conflicts to play out on timelines that are too short for humans to effectively manage with current technology alone,” said Al Emondi, the N program manager. “By creating a more accessible brain-machine interface that doesn’t require surgery to use, DARPA could deliver tools that allow mission commanders to remain meaningfully involved in dynamic operations that unfold at rapid speed.”
At least not optimally. As scientists and companies are increasingly exploring ways to interface your brain with computers, fashioning new hardware that conforms to and compliments our biological wetware becomes increasingly important.
To be fair, silicon transistors, when made into electrode arrays, can perform the basics: record neural signals, process and analyze them with increasingly sophisticated programs that detect patterns, which in turn can be used to stimulate the brain or control smart prosthetics.
