Lifeboat Foundation

Year 2018 😗

State-of-the-art software tools for neuronal network simulations scale to the largest computing systems available today and enable investigations of large-scale networks of up to 10% of the human cortex at a resolution of individual neurons and synapses. Due to an upper limit on the number of incoming connections of a single neuron, network connectivity becomes extremely sparse at this scale. To manage computational costs, simulation software ultimately targeting the brain scale needs to fully exploit this sparsity. Here we present a two-tier connection infrastructure and a framework for directed communication among compute nodes accounting for the sparsity of brain-scale networks. We demonstrate the feasibility of this approach by implementing the technology in the NEST simulation code and we investigate its performance in different scaling scenarios of typical network simulations. Our results show that the new data structures and communication scheme prepare the simulation kernel for post-petascale high-performance computing facilities without sacrificing performance in smaller systems.

Modern neuroscience has established numerical simulation as a third pillar supporting the investigation of the dynamics and function of neuronal networks, next to experimental and theoretical approaches. Simulation software reflects the diversity of modern neuroscientific research with tools ranging from the molecular scale to investigate processes at individual synapses (Wils and De Schutter, 2009) to whole-brain simulations at the population level that can be directly related to clinical measures (Sanz Leon et al., 2013). Most neuronal network simulation software, however, is based on the hypothesis that the main processes of brain function can be captured at the level of individual nerve cells and their interactions through electrical pulses. Since these pulses show little variation in shape, it is generally believed that they convey information only through their timing or rate of occurrence.

Japan wants to get back into the leading-edge semiconductor business and very recently a new company was formed to reboot its semiconductor industry. The company is named Rapidus, referring to rapid production of new chips, a clear reference to how the company plans to differentiate its business from other foundries such as TSMC, Samsung, and Intel. The company has announced a partnership with IBM Research to develop IBM’s 2nm technology in fabs that Rapidus plans to build in Japan during the second part of this decade. Previously, Rapidus announced a collaboration with the Belgium-based microelectronics research hub IMEC on advanced semiconductor technologies. Imec is collaborative semiconductor research organization working the world’s major foundries, IDMs, fabless and fablite companies, material and tool suppliers, EDA companies and application developers.

The IBM process uses gate-all-around transistors — IBM refers to them as nano sheet FETs — which is the next generation of transistor design that enables device scaling beyond today’s FinFETs. The 2nm structures will require Rapidus to use ASML’s EUV manufacturing equipment. Business details with IBM were not disclosed, but there’s likely two parts to the deal: a cross-licensing agreement for the intellectual property necessary to build the product and a joint development agreement. While the announcement is nominally for IBM’s 2nm process, it likely includes a long-term commitment to build advanced semiconductor chips going beyond the 2nm process node.

Rapidus was formed by semiconductor veterans such as Rapidus President Atsuyoshi Koike, with backing by leading Japanese technology and financial firms, including Denso, Kioxia, Mitsubishi UFJ Bank, NEC, NTT, Softbank, Sony, and Toyota Motor. The Japanese government is also subsidizing Rapidus. The big change for Japan compared to prior national efforts is the collaboration with international organizations. It’s a recognition Japan cannot go it alone. This appears to be a fundamental change in Japanese attitudes. Building a fab in Japan will be helped by Japan’s strong manufacturing ecosystem of materials, equipment, and engineering talent.

The two American allies are signing on to the U.S. offensive against China’s flagging chip industry.

Christopher Nolan revealed to Total Film magazine that he recreated the first nuclear weapon detonation without CGI effects as part of the production for his new movie “Oppenehimer.” The film stars longtime Nolan collaborator Cillian Murphy as J. Robert Oppenheimer, a leading figure of the Manhattan Project and the creation the atomic bomb during World War II. Nolan has always favored practical effects over VFX (he even blew up a real Boeing 747 for “Tenet”), so it’s no surprise he went the practical route when it came time to film a nuclear weapon explosion.

“I think recreating the Trinity test [the first nuclear weapon detonation, in New Mexico] without the use of computer graphics was a huge challenge to take on,” Nolan said. “Andrew Jackson — my visual effects supervisor, I got him on board early on — was looking at how we could do a lot of the visual elements of the film practically, from representing quantum dynamics and quantum physics to the Trinity test itself, to recreating, with my team, Los Alamos up on a mesa in New Mexico in extraordinary weather, a lot of which was needed for the film, in terms of the very harsh conditions out there — there were huge practical challenges.”

Using a chip-based optical frequency comb, researchers transmitted almost double the global internet traffic in a single second.

Such a device could help address climate change and food scarcity, or break the Internet. Will the U.S. or China get there first?

A pair of microspheres can convert microwave signals over a wide frequency range into optical signals, which will be essential for future quantum technologies.

Future quantum communication systems will likely use microwaves to transfer information into and out of storage and processing devices but will use lasers to carry information from point to point within an extended network. Now researchers have demonstrated an improved method for converting microwaves to visible light signals by exploiting the way that electromagnetic waves can set up vibrations within microspheres [1]. Two microspheres in contact—one sensitive to microwaves and the other sensitive to optical signals—serve as the core of the converter. The work should give researchers a wider range of technological options as they develop advanced communications and computing networks.

Researchers are pursuing a variety of ways to store quantum information, or “qubits,” in microscopic, typically superconducting, structures. One common feature of such technologies is that reading or writing information relies on interactions with microwaves rather than on higher-frequency visible or infrared light from lasers. But lasers offer the best way to move information around, so extended networks of such devices will need ways to convert signals from one form to the other.

Elon Musk’s Neuralink is under federal investigation for potential animal-welfare violations after staff complaints about rushed animal testing. Ana Kasparian discusses on The Young Turks. Watch TYT LIVE on weekdays 6–8 pm ET. http://youtube.com/theyoungturks/live.

“Elon Musk’s Neuralink, a medical device company, is under federal investigation for potential animal-welfare violations amid internal staff complaints that its animal testing is being rushed, causing needless suffering and deaths, according to documents reviewed by Reuters and sources familiar with the investigation and company operations.

Continue reading “Neuralink NIGHTMARE: Elon’s Brain Chip Trials Are A Total Horror Show” »

Microsoft today announced that it acquired Lumenisity, a U.K.-based startup developing “hollow core fiber (HCF)” technologies primarily for data centers and ISPs. Microsoft says that the purchase, the terms of which weren’t disclosed, will “expand [its] ability to further optimize its global cloud infrastructure” and “serve Microsoft’s cloud platform and services customers with strict latency and security requirements.”

HCF cables fundamentally combine optical fiber and coaxial cable. They’ve been around since the ’90s, but what Lumenisity brings to the table is a proprietary design with an air-filled center channel surrounded by a ring of glass tubes. The idea is that light can travel faster through air than glass; in a trial with Comcast in April, a single strand of Lumenisity HCF was reportedly able to deliver traffic rates ranging from 10 Gbps to 400 Gbps.

“HCF can provide benefits across a broad range of industries including healthcare, financial services, manufacturing, retail and government,” Girish Bablani, CVP of Microsoft’s Azure Core business, wrote in a blog post. “For the public sector, HCF could provide enhanced security and intrusion detection for federal and local governments across the globe. In healthcare, because HCF can accommodate the size and volume of large data sets, it could help accelerate medical image retrieval, facilitating providers’ ability to ingest, persist and share medical imaging data in the cloud. And with the rise of the digital economy, HCF could help international financial institutions seeking fast, secure transactions across a broad geographic region.”