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White Swan Graphics, Countermeassuring Every Unthinkable Black Swan, By Mr. Andres Agostini — Question: In Corporate Settings, Is There An Outright Countermeassuring White Swan To The Black Swan? Read at http://lifeboat.com/blog/2014/04/White-Swan

Posted in automation, big data, biological, business, complex systems, computing, disruptive technology, economics, education, engineering, existential risks, finance, futurism, information science, innovation, law, law enforcement, lifeboat, science, scientific freedom, security, singularity, sustainability | Leave a Comment on White Swan Graphics, Countermeassuring Every Unthinkable Black Swan, By Mr. Andres Agostini — Question: In Corporate Settings, Is There An Outright Countermeassuring White Swan To The Black Swan? Read at http://lifeboat.com/blog/2014/04/White-Swan

WHITE SWAN GRAPHICS BY MR. ANDRES AGOSTINI. — QUESTION: IN CORPORATE SETTINGS, IS THERE AN OUTRIGHT COUNTERMEASSURING WHITE SWAN TO THE BLACK SWAN? READ at https://lifeboat.com/blog/2014/04/White-Swan

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WHITE SWAN GRAPHICS BY MR. ANDRES AGOSTINI. — QUESTION: IN CORPORATE SETTINGS, IS THERE AN OUTRIGHT COUNTERMEASSURING WHITE SWAN TO THE BLACK SWAN? READ at https://lifeboat.com/blog/2014/04/White-Swan

Mr. Andres Agostini

Lifeboat Foundation Worldwide Ambassador: https://lifeboat.com/ex/bios.andres.agostini

The White Swan Treatise at https://lifeboat.com/blog/2014/04/white-swan

The « … The Human Race to the Future … » Worldwide Ambassador at http://amzn.to/19H3qf0 POINT OF CONTACT AND QUERY: www.linkedin.com/in/andresagostini PROFESSIONAL SERVICE: http://ThisSuccess.wordpress.com

Yesterday’s program, The Next Space Race, on Bloomberg TV was an excellent introduction to the commercial aerospace companies, SpaceX, the Sierra Nevada Company (SNC), and Boeing. The following are important points, at the stated times, in the program:

0.33 mins: The cost of space travel has clipped our wings.
5:18 mins: How many people knew Google before they started?
7:40 mins: SpaceX costs, full compliment, 4x per year at $20 million per astronaut.
11:59 mins: Noisy rocket launch, notice also the length of the hot exhaust is several times the length of the rocket.
12:31 mins: One small step for man, one giant leap for mankind.
12:37 mins: Noisy shuttle launch, notice also the length of the hot exhaust is several times the length of the rocket.
13:47 mins: OPF-3, at one time the largest building in the world at 129 million cubic feet.
16:04 mins: States are luring private companies to start up in their states.
16:32 mins: NASA should be spending its money on exploration and missions and not maintenance and operations.
17:12 mins: The fair market value of OPF-3 is about $13.5 million.
17:19 mins: Maintenance cost is $100,000 per month
17:47 mins: Why Florida?
18:55 mins: International Space Station (ISS) cost $60B and if including the Shuttle program, it cost $150B.
19:17 mins: The size of the commercial space launch business.
21:04 mins: Elon Musk has put $100 million of his own money into SpaceX.
21:23 mins: The goals of NASA and private space do not conflict.

Summary:
1. Cost of ISS is $60B, total cost including the Shuttle program is $150B.

2. SpaceX cost is $20M per astronaut (for 7 astronauts) or a launch cost of $140 million per launch at $560 million per year for 4 launches per year.

3. The next space race is about money.

4. NASA will give a multi billion dollar contract to private space companies to ferry humans & cargo into space and back.

5. Orbiter Processing Facility 3 (OPF-3) valued at $13.5million, and an estimated area of 207,000 sq ft gives a value of $65.22/sq ft.

6. With a maintenance costs of $100,000 gives a per sq ft maintenance costs of $0.48/sq ft/month or $5.80/sq ft/year.

7. Another reason for the Cape Canaveral NASA launch site is the mandatory no/low population down range for rocket launches. At Cape Canaveral this down range is the Atlantic Ocean.

Although I have already mentioned a recent technical note on the application of Astronomical Observation to LHC/Collider Safety in comments to other posts here and there, I have not posted specifically about it until now. So finally, a short mention:

The technical note follows on from a modest paper I wrote in 2012 (Discussions on the Hypothesis that Cosmic Ray Exposure on Sirius B Negates Terrestrial MBH Concerns from Colliders), which concerned micro-black hole (MBH) production and the white dwarf safety assurance. There I demonstrated that not only are most white dwarf stars not suitable as a safety assurance, but that those hand-picked for the 2008 safety report had magnetic field strength measured to just 99% confidence within the range for safety assurance. That is not to say that the LHC safety argument was only 99% reliable — just that one of the cornerstone assurances was. The affirmation of these measurements was needed for a safety assurance to LHC p-p collisions based on astronomical observations – as a safety assurance that is not based on Hawking Radiation theory — but based on verifiable measurement. The technical note captures the official LSAG (CERN) response on the matter after internal review at CERN in late 2012, which had remained archived from email discussions until recently, when those conclusions were formalised into this technical note:

Link to the technical note: http://environmental-safety.webs.com/TechnicalNote-EnvSA01.pdf

mostly harmless

That conclusion was fortunately, as expected, one of safety: significant progress had been made on the accuracy of B field measurement technology since the original 2008 safety report — and after a survey of latest literature, one finds that there are now extensive examples of WD with fields measured with uncertainty ranges within the 1–100 kG range required for assurance. However — despite an eventual conclusion of safety on this one matter (MBH concerns from p-p collisions) I would like to reiterate a point that I made back in 2008, that there is an obligation on industry to keep safety debate open and honest. We are not likely to see credible argument on any of the other concerns to LHC operations (strangelet production, magnetic monopoles, de sitter space transitions and vacuum bubbles, and so on), but these discussions do illustrate that re-visitations can be necessary.

Whilst onwards we strive to find new understandings to the universe, and to engineer new ways of being, we need to stand back and take a look at where we are, lest we get lost.

The future propulsion community are those who believe in or are actively researching rocketry, gravity modification & interstellar propulsion engineering & physics.

In this video I discuss the 3 groups within the future propulsion community. These groups are the Nay Sayers — they don’t believe that it is in the near future, Advanced Rocket — that only rockets can do this, & New Physics — that a new physics will solve this soon.

I also discuss briefly the European/French and Chinese interest in my work.

Jason Dorrier — Singularity Hub

While traditional sports only grudgingly accept technological augmentation, the 2016 Cybathlon, a kind of hybrid between the XPRIZE and Olympics, embraces it with both robotic arms. Disabled competitors (or pilots) will compete using assistance devices like powered exoskeletons, robotic prostheses, and brain-control interfaces.

We’ve chronicled the continuous evolution of such technologies over the years, but they’re still largely out of reach for most folks.

Read more

Book Review: The Human Race to the Future by Daniel Berleant (2013) (A Lifeboat Foundation publication)

Posted in alien life, asteroid/comet impacts, biotech/medical, business, climatology, disruptive technology, driverless cars, drones, economics, education, energy, engineering, ethics, evolution, existential risks, food, futurism, genetics, government, habitats, hardware, health, homo sapiens, human trajectories, information science, innovation, life extension, lifeboat, nanotechnology, neuroscience, nuclear weapons, philosophy, policy, posthumanism, robotics/AI, science, scientific freedom, security, singularity, space, space travel, sustainability, transhumanismTagged , , , , , , | Leave a Comment on Book Review: The Human Race to the Future by Daniel Berleant (2013) (A Lifeboat Foundation publication)

From CLUBOF.INFO

The Human Race to the Future (2014 Edition) is the scientific Lifeboat Foundation think tank’s publication first made available in 2013, covering a number of dilemmas fundamental to the human future and of great interest to all readers. Daniel Berleant’s approach to popularizing science is more entertaining than a lot of other science writers, and this book contains many surprises and useful knowledge.

Some of the science covered in The Human Race to the Future, such as future ice ages and predictions of where natural evolution will take us next, is not immediately relevant in our lives and politics, but it is still presented to make fascinating reading. The rest of the science in the book is very linked to society’s immediate future, and deserves great consideration by commentators, activists and policymakers because it is only going to get more important as the world moves forward.

The book makes many warnings and calls for caution, but also makes an optimistic forecast about how society might look in the future. For example, It is “economically possible” to have a society where all the basics are free and all work is essentially optional (a way for people to turn their hobbies into a way of earning more possessions) (p. 6–7).

A transhumanist possibility of interest in The Human Race to the Future is the change in how people communicate, including closing the gap between thought and action to create instruments (maybe even mechanical bodies) that respond to thought alone. The world may be projected to move away from keyboards and touchscreens towards mind-reading interfaces (p. 13–18). This would be necessary for people suffering from physical disabilities, and for soldiers in the arms race to improve response times in lethal situations.

To critique the above point made in the book, it is likely that drone operators and power-armor wearers in future armies would be very keen to link their brains directly to their hardware, and the emerging mind-reading technology would make it possible. However, there is reason to doubt the possibility of effective teamwork while relying on such interfaces. Verbal or visual interfaces are actually more attuned to people as a social animal, letting us hear or see our colleagues’ thoughts and review their actions as they happen, which allows for better teamwork. A soldier, for example, may be happy with his own improved reaction times when controlling equipment directly with his brain, but his fellow soldiers and officers may only be irritated by the lack of an intermediate phase to see his intent and rescind his actions before he completes them. Some helicopter and vehicle accidents are averted only by one crewman seeing another’s error, and correcting him in time. If vehicles were controlled by mind-reading, these errors would increasingly start to become fatal.

Reading and research is also an area that could develop in a radical new direction unlike anything before in the history of communication. The Human Race to the Future speculates that beyond articles as they exist now (e.g. Wikipedia articles) there could be custom-generated articles specific to the user’s research goal or browsing. One’s own query could shape the layout and content of each article, as it is generated. This way, reams of irrelevant information will not need to be waded through to answer a very specific query (p. 19–24).

Greatly similar to the same view I have written works expressing, the book sees industrial civilization as being burdened above all by too much centralization, e.g. oil refineries. This endangers civilization, and threatens collapse if something should later go wrong (p. 32, 33). For example, an electromagnetic pulse (EMP) resulting from a solar storm could cause serious damage as a result of the centralization of electrical infrastructure. Digital sabotage could also threaten such infrastructure (p. 34, 35).

The solution to this problem is decentralization, as “where centralization creates vulnerability, decentralization alleviates it” (p. 37). Solar cells are one example of decentralized power production (p. 37–40), but there is also much promise in home fuel production using such things as ethanol and biogas (p. 40–42). Beyond fuel, there is also much benefit that could come from decentralized, highly localized food production, even “labor-free”, and “using robots” (p. 42–45). These possibilities deserve maximum attention for the sake of world welfare, considering the increasing UN concerns about getting adequate food and energy supplies to the growing global population. There should not need to be a food vs. fuel debate, as the only acceptable solution can be to engineer solutions to both problems. An additional option for increasing food production is artificial meat, which should aim to replace the reliance on livestock. Reliance on livestock has an “intrinsic wastefulness” that artificial meat does not have, so it makes sense for artificial meat to become the cheapest option in the long run (p. 62–65). Perhaps stranger and more profound is the option of genetically enhancing humans to make better use of food and other resources (p. 271–274).

On a related topic, sequencing our own genome may be able to have “major impacts, from medicine to self-knowledge” (p. 46–51). However, the book does not contain mention of synthetic biology and the potential impacts of J. Craig Venter’s work, as explained in such works as Life at the Speed of Light. This could certainly be something worth adding to the story, if future editions of the book aim to include some additional detail.

At least related to synthetic biology is the book’s discussion of genetic engineering of plants to produce healthier or more abundant food. Alternatively, plants could be genetically programmed to extract metal compounds from the soil (p. 213–215). However, we must be aware that this could similarly lead to threats, such as “superweeds that overrun the world” similar to the flora in John Wyndam’s Day of the Triffids (p. 197–219). Synthetic biology products could also accidentally expose civilization to microorganisms with unknown consequences, perhaps even as dangerous as alien contagions depicted in fiction. On the other hand, they could lead to potentially unlimited resources, with strange vats of bacteria capable of manufacturing oil from simple chemical feedstocks. Indeed, “genetic engineering could be used to create organic prairies that are useful to humans” (p. 265), literally redesigning and upgrading our own environment to give us more resources.

The book advocates that politics should focus on long-term thinking, e.g. to deal with global warming, and should involve “synergistic cooperation” rather than “narrow national self-interest” (p. 66–75). This is a very important point, and may coincide with the complex prediction that nation states in their present form are flawed and too slow-moving. Nation-states may be increasingly incapable of meeting the challenges of an interconnected world in which national narratives produce less and less legitimate security thinking and transnational identities become more important.

Close to issues of security, The Human Race to the Future considers nuclear proliferation, and sees that the reasons for nuclear proliferation need to be investigated in more depth for the sake of simply by reducing incentives. To avoid further research, due to thinking that it has already been sufficiently completed, is “downright dangerous” (p. 89–94). Such a call is certainly necessary at a time when there is still hostility against developing countries with nuclear programs, and this hostility is simply inflammatory and making the world more dangerous. To a large extent, nuclear proliferation is inevitable in a world where countries are permitted to bomb one another because of little more than suspicions and fears.

Another area covered in this book that is worth celebrating is the AI singularity, which is described here as meaning the point at which a computer is sophisticated enough to design a more powerful computer than itself. While it could mean unlimited engineering and innovation without the need for human imagination, there are also great risks. For example, a “corporbot” or “robosoldier,” determined to promote the interests of an organization or defeat enemies, respectively. These, as repeatedly warned through science fiction, could become runaway entities that no longer listen to human orders (p. 83–88, 122–127).

A more distant possibility explored in Berleant’s book is the colonization of other planets in the solar system (p. 97–121, 169–174). There is the well-taken point that technological pioneers should already be trying to settle remote and inhospitable locations on Earth, to perfect the technology and society of self-sustaining settlements (Antarctica?) (p.106). Disaster scenarios considered in the book that may necessitate us moving off-world in the long term include a hydrogen sulfide poisoning apocalypse (p. 142–146) and a giant asteroid impact (p. 231–236)

The Human Race to the Future is a realistic and practical guide to the dilemmas fundamental to the human future. Of particular interest to general readers, policymakers and activists should be the issues that concern the near future, such as genetic engineering aimed at conservation of resources and the achievement of abundance.

By Harry J. Bentham - More articles by Harry J. Bentham

Originally published on April 22 in h+ Magazine

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The crisis in super symmetry physics is causing physicist to search for a new physics. Could this new physics be non-particle based? A physics closer to General Relativity than to either Quantum or String theories?

The video blog shows 2 of the 400 experiments I conducted between September 1999 and at least April 2001, maybe later. I used various weight measuring scales, battery packs and power supplies. These experiments convinced me that something was a miss with contemporary physics, thus leading to my 12-year study into gravity modification.

This study has been published under the title “An Introduction to Gravity Modification, 2nd Edition”. It documents the new massless formula g=(tau)c^2, for gravitational, mechanical & electromagnetic accelerations; the discovery of Non Inertia (Ni) Fields and non-Gaussian photon probability, and the subsequent unification of photon shielding, transmission/cloaking, invisibility and resolution into a single phenomenon.