Lifeboat Foundation

According to a mind-bending new theory, a black hole could actually be a tunnel between universes, meaning our universe may be nested inside a black hole that is part of a larger universe. The theory explains that the matter doesn’t collapse into a single point, but rather gushes out a “white hole” at the other end of the black one.

The theory was published in the journal Physics Letters B, by Indiana University physicist Nikodem Poplawski. In his article, he presents new mathematical models of the spiraling motion of matter falling into the black hole. His equations suggest that wormholes are probable alternatives to the “space-time singularities” originally predicted by Albert Einstein.

Einstein’s equations for general relativity suggest singularities are created whenever matter in a given region gets too dense as would happen at the center of a black hole. Singularities are infinitely dense and hot, and take up no space. This idea has been supported by indirect evidence but has never been fully accepted into the scientific community.

Continue reading “The ‘Door’ To Another Universe…Can We Find The Black Hole That Opens It…Physicists Say ‘Yes!’” »

Individuals who mine Bitcoins needn’t be miners. We call them ‘miners’ because they are awarded BTC as they solve mathematical computations. The competition to unearth these reserve coins also serves a vital purpose. They validate the transactions of Bitcoin users all over the world: buyers, loans & debt settlement, exchange transactions, inter-bank transfers, etc. They are not really miners. They are more accurately engaged in transaction validation or ‘bookkeeping’.

There are numerous proposals for how to incentivize miners once all 21 million coins have been mined/awarded in May 2140. Depending upon the network load and the value of each coin, we may need to agree on an alternate incentive earlier than 2140. At the opening of the 2015 MIT Bitcoin Expo, Andreas Antonopolous proposed some validator incentive alternatives. One very novel suggestion was based on game theory and involved competition and status rather than cash payments.

I envision an alternative approach—one that also addresses the problem of miners and users having different goals. In an ideal world the locus of users should intersect more fully with the overseers…

To achieve this, I have proposed that every wallet be capable of also mining, even if the wallet is simply a smartphone app or part of a cloud account at an exchange service. To get uses participating in validating the transactions of peers, any transaction fee could be waived for anyone who completes 1 validation for each n transactions. (Say one validation for every five or ten transactions). In this manner, everyone pitches in a small amount of resources to maintain a robust network.

Continue reading “How to Incentivize Bitcoin miners after all 21M BTC are awarded” »

We have the math locked down. Next, we need the materials.

Physicists have come up with what they claim is a mathematical model of a theoretical “time machine” — a box that can move backwards and forwards through time and space.

The trick, they say, is to use the curvature of space-time in the Universe to bend time into a circle for hypothetical passengers sitting in the box, and that circle allows them to skip into the future and the past.

“People think of time travel as something as fiction. And we tend to think it’s not possible because we don’t actually do it,” says theoretical physicist and mathematician, Ben Tippett, from the University of British Columbia in Canada.

Continue reading “Physicists Just Came Up With a Mathematical Model for a Viable Time Machine” »

2017 begins on Monday in Vancouver, Canada, and will explore the theme “The Future You.” If the future you is anything like the future us, you are likely curled up in a big cushy chair right now, devouring the contents of a book that flips your thinking. Below, some reading suggestions from the speaker program. Read, enjoy and stay tuned to the TED Blog for beat-by-beat coverage of the conference.

TED2017 begins on Monday in Vancouver, Canada, and will explore the theme “The Future You.” If the future you is anything like the future us, you are likely curled up in a big cushy chair right now, devouring the contents of a book that flips your thinking. Below, some reading suggestions from the speaker program. Read, enjoy and stay tuned to the TED Blog for beat-by-beat coverage of the conference.

Weapons of Math Destruction: How Big Data Increases Inequality and Threatens Democracy by Cathy O’Neil. The decisions that affect our lives are no longer made by humans — they’re made by algorithms. This might sound like a great way around bias and discrimination, but these things are often built right into our mathematical models. When it comes to college admissions, decisions on parole, applications to jobs and the affects of a bad credit score, O’Neil explores the unintended consequences of algorithms. (Read an excerpt.)

Continue reading “15 books to browse ahead of TED2017” »

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AIMS contributes to this by having created a network across the continent via its various centres in South Africa (initially founded in Cape Town in 2003), Senegal, Ghana, Cameroon, Tanzania, and now Rwanda. It not only educates but it also actively promotes mathematics and science in Africa in various effective ways, some of which we will cover below. It is essentially creating a pool of excellent African mathematicians and scientists who will (in turn) apply solutions to our continent’s challenges. Yes, many of them actually stay here.

AIMS’ new centre in Rwanda offers a model many of our organisations, and many entrepreneurs, can follow. It’s an exciting endeavour creating a quantum leap for the continent. But it should also make us ask hard questions about what we deem important and what we talk about.

As soon as I touched down at Kigali International Airport, Rwanda, I could feel something phenomenal was in the air. Perhaps it was because people kept telling me that Kigali is a true African city, or perhaps it was the sheer amount of beauty of Rwanda — an African nation with its own, unique African identity — or perhaps it was the amazing innovation and technology I encountered from touchdown (free Wi-Fi on the bus, MTN tap-and-go payments, and more) right to where I was going: The African Institute of Mathematical Sciences (AIMS).

Continue reading “AIMS takes Africa on a quantum leap into science” »

In the past 10 years, the best-performing artificial-intelligence systems—such as the speech recognizers on smartphones or Google’s latest automatic translator—have resulted from a technique called “deep learning.”

Deep learning is in fact a new name for an approach to artificial intelligence called neural networks, which have been going in and out of fashion for more than 70 years. Neural networks were first proposed in 1944 by Warren McCullough and Walter Pitts, two University of Chicago researchers who moved to MIT in 1952 as founding members of what’s sometimes called the first cognitive science department.

Neural nets were a major area of research in both neuroscience and computer science until 1969, when, according to computer science lore, they were killed off by the MIT mathematicians Marvin Minsky and Seymour Papert, who a year later would become co-directors of the new MIT Artificial Intelligence Laboratory.

Continue reading “Neural networks explained” »

Phase 1 work demonstrated Optical Mining in the laboratory and performed mission and systems analysis of the application of Optical Mining to human exploration missions. Their mission analysis showed that the most accessible Near Earth Objects (NEOs) can be used to provide NASA with mission consumables for human exploration in deep space with the potential of saving up to $10 billion per year or $150 billion over the 15 year operational life cycle of a human exploration program. This savings alone would be enough to transform NASA’s vision of human exploration from being unaffordable to being affordable within budgets that Congress can approve. Phase 1 technical work included a full scale (8 kW) Optical Mining demonstration using a high fidelity CI-type asteroid simulant in vacuum using sunlight from a 10 meter diameter solar concentrator without mechanical contact or downforce. This work confirmed our physics based mathematical model of the excavation and volatile extraction process and scalability of results from 36 prior, small scale (≈ 1 cm diameter) demonstrations and tests.

Phase 2 work will complete mission and system analysis of the application of Optical Mining to an exciting program of human exploration and we will mature the technology of Optical Mining to the point at which NASA can baseline this approach for an affordable program of human exploration. Our mission studies will address the production via Optical Mining missions to extract and retrieve resources, consumable processing, storage, and application of consumables to human exploration mission in cislunar, NEO and Martian space. The mission studies will be tightly coupled with our laboratory work. Laboratory work will include the development and integration of a 30 kW Optical Mining test apparatus in our laboratory and integration with our high quality vacuum chamber for a test program involving Optical Mining.