integrate the fields of information and communication technologies (ICT), social sciences and complexity science, to develop a new kind of participatory science and technology that will help us to understand, explore and manage the complex, global, socially interactive systems that make up our world today, while at the same time paving the way for a new paradigm of  ICT systems that will leverage socio-inspired self-organisation, self-regulation, and collective awareness.

The project could provide us with profound insights into societal behaviour and improve policymaking. The project echoes the Large Hadron Collider at CERN in its scope and vision, only here we are trying to understand the state of the world. The FutureICT project combines the creation of a ‘Planetary Nervous System’ (PNS) where Big Data will be collated and organised, a ‘Living Earth Simulator’ (LES), and the ‘Global Participatory Platform’ (GPP). The LES will simulate the data and provide models for analysis, while the GPP will provide the data, models and methods to everyone. People wil be able to collaborate and research in a very different way. The availability of Big Data to participants will both strengthen our ability to understand complex socio-economic systems, and it could help build a new dialogue between nations in how we solve complex global societal challenges.

FutureICT aim to develop a ‘Global Systems Science’, which will

lay the theoretical foundations for these platforms, while the focus on socio-inspired ICT will use the insights gained to identify suitable designs for socially interactive systems and the use of mechanism that have proven effective in society as operational principles for ICT systems.

It is exciting to think about the possible breakthroughs that could be made. What new insights and scientific discoveries could be made? What new technologies could emerge? The Innovation Accelerator (IA) is one feature of the venture that could create both disruptive technology and politics. Next year will open up a new world of possibilities. A possible project for the Lifeboat Foundation to be involved in.

In this post I discuss the third and final part, Concepts and Logical Flow, of how to read or write a journal paper, that is not taught in colleges.

A paper consists of a series of evolving concepts expressed as paragraphs. If a concept is too complex to be detailed in a single paragraph, then break it down into several sub-concept paragraphs. Make sure there is logical evolution of thought across these sub-concepts, and across the paper.

As a general rule your sentences should be short(er). Try very hard not to exceed two lines of Letter or A4 size paper at font size 11. Use commas judicially. Commas are not meant to extend sentences or divide the sentence into several points!!! They are used to break up a sentence into sub-sentences to indicate a pause when reading aloud. How you use commas can alter the meaning of a sentence. Here is an example.

“And this I know with confidence, I remain and continue …”

Changing the position of the commas, changes the meaning to

“And this I know, with confidence I remain and continue …”

We see how ‘confidence’ changes from the speaker’s assessment of his state of knowledge, to the speaker’s reason for being. So take care.

When including mathematical formulae, always wrap. Wrap them with an opening paragraph and a closing paragraph. Why? This enhances the clarity of the paper. The opening paragraph introduce the salient features of the equation(s), i.e. what the reader needs to be aware of in the equation(s), or an explanation of the symbols, or why the equation is being introduced.

The closing paragraph explains what the author found by stating the equations, and what the reader should expect to look for in subsequent discussions, or even why the equation(s) is or is not relevant to subsequent discussions.

Many of these concept-paragraphs are logically combined into sections, and each section has a purpose for its inclusion. Though this purpose may not always be stated in the section, it is important to identify what it is and why it fits in with the overall schema of the paper.

The basic schema of a paper consists of an introduction, body and conclusion. Of course there are variations to this basic schema, and you need to ask the question, why does the author include other types of sections.

In the introduction section(s) you summarize your case, what is your paper about, and what others have reported. In the body sections you present your work. In the conclusion section you summarize your findings and future direction of the research. Why? Because a busy researcher can read your introduction and conclusion and then decide whether your paper is relevant to his or her work. Remember we are working within a community of researchers in an asynchronous manner, an asynchronous team, if you would. As more and more papers are published every year, we don’t have the time to read all of them, completely. So we need a method of eliminating papers we are not going to read.

An abstract is usually a summary of the body of the paper. It is difficult to do well and should only be written after you have completed your paper. That means you are planning ahead and have your paper written and abstracts completed when you receive the call for papers.

An abstract tells us if the paper could be relevant, to include in our list of papers to be considered for the shortlist of papers to be read. The introduction and conclusion tells if the paper should be removed from our short list. If the conclusion fits in with what we want to achieve, then don’t remove the paper from the short list.

I follow a rule when writing the introduction section. If I am writing to add to the body of consensus, I state my case and then write a review of what others have reported. If I am negating the body of consensus, then I write a review of what others have reported, and then only do I state my case of why not.

As a general rule, you write several iterations of the body first, then introduction and finally the conclusion. You’d be surprised by how your thinking changes if you do it this way, This is because you have left yourself open to other inferences that had not crossed your mind from the time you completed your work, to the time you started writing your paper.

If someone else has theoretical or experimental results that apparently contradicts your thesis, then discuss why and why not, and you might end up changing your mind. It is not a ‘sin’ to include contradictory results, but make sure you discuss this intelligently and impartially.

Your work is the sowing and growing period. Writing the paper is the harvesting period. What are you harvesting? Wheat, weeds or both? Clearly the more wheat you harvest the better your paper. The first test for this is the logical flow of your paper. If it does not flow very well, something is amiss! You the author, and you the reader beware! There is no substitute but to rethink your paper.

The second test is, if you have tangential discussions in your paper that seem interesting but are not directly relevant. Prune, prune & prune. If necessary split into multiple concise papers. A concise & sharp paper that everyone remembers is more valuable than a long one that you have to plough through.

Go forth, read well and write more.

Previous post in the Kline Directive series.

Next post in the Kline Directive series.

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Benjamin T Solomon is the author & principal investigator of the 12-year study into the theoretical & technological feasibility of gravitation modification, titled An Introduction to Gravity Modification, to achieve interstellar travel in our lifetimes. For more information visit iSETI LLC, Interstellar Space Exploration Technology Initiative.

Solomon is inviting all serious participants to his LinkedIn Group Interstellar Travel & Gravity Modification.

In this post I discuss part 2 of 3, Mathematical Construction versus Mathematical Conjecture, of how to read or write a journal paper that is not taught in colleges.

I did my Master of Arts in Operations Research (OR) at the best OR school in the United Kingdom, University of Lancaster, in the 1980s. We were always reminded that models have limits to their use. There is an operating range within which a model will provide good and reliable results. But outside that operating range, a model will provide unreliable, incorrect and even strange results.

Doesn’t that sound a lot like what the late Prof. Morris Kline was saying? We can extrapolate this further, and ask our community of theoretical physicists the question, what is the operating range of your theoretical model? We can turn the question around and require our community of theoretical physicists to inform us or suggest boundaries of where their models fail “ … to provide reasonability in guidance and correctness in answers to our questions in the sciences …”

A theoretical physics model is a mathematical construction that is not necessarily connected to the real world until it is empirically verified or falsified, until then these mathematical constructions are in limbo. Search the term ‘retrocausality’ for example. The Wikipedia article Retrocausality says a lot about how and why of the origins of theoretical physics models that are not within the range of our informed common sense. Let me quote,

“The Wheeler–Feynman absorber theory, proposed by John Archibald Wheeler and Richard Feynman, uses retrocausality and a temporal form of destructive interference to explain the absence of a type of converging concentric wave suggested by certain solutions to Maxwell’s equations. These advanced waves don’t have anything to do with cause and effect, they are just a different mathematical way to describe normal waves. The reason they were proposed is so that a charged particle would not have to act on itself, which, in normal classical electromagnetism leads to an infinite self-force.”

John Archibald Wheeler and Richard Feynman are giants in the physics community, and these esteemed physicists used retrocausality to solve a mathematical construction problem. Could they not have asked the different questions? What is the operating range of this model? How do we rethink this model so as not to require retrocausality?

This unfortunate leadership in retrocausality has led to a whole body of ‘knowledge’ by the name of ‘retrocausality’ that is in a state of empirical limbo and thus, the term mathematical conjecture applies.

Now, do you get an idea of how mathematical construction leads to mathematical conjecture? Someone wants to solve a problem, which is a legitimate quest because that is how science progresses, but the solution causes more problems (not questions) than previously, which leads to more physicists trying to answer those new problems, and so forth .… and so forth .… and so forth .…

In Hong Kong, the Cantonese have an expression “chasing the dragon”.

Disclaimer: I am originally from that part of the world, and enjoyed tremendously watching how the Indian and Chinese cultures collided, merged, and separated, repeatedly. Sometimes like water and oil, and sometimes like water and alcohol. These two nations share a common heritage, the Buddhist monks, and if they could put aside their nationalistic and cultural pride, who knows what could happen?

Chasing the dragon in the Chinese cultural context “refers to inhaling the vapor from heated morphine, heroin, oxycodone or opium that has been placed on a piece of foil. The ‘chasing’ occurs as the user gingerly keeps the liquid moving in order to keep it from coalescing into a single, unmanageable mass. Another more metaphorical use of the term ‘chasing the dragon’ refers to the elusive pursuit of the ultimate high in the usage of some particular drug.”

Solving a mathematical equation always gives a high, and discovering a new equation gives a greater high. So when we write a paper, we have to ask ourselves, are we chasing the dragon of mathematical conjecture or chasing the dragon of mathematical construction? I hope it is the latter.

Previous post in the Kline Directive series.

—————————————————————————————————

Benjamin T Solomon is the author & principal investigator of the 12-year study into the theoretical & technological feasibility of gravitation modification, titled An Introduction to Gravity Modification, to achieve interstellar travel in our lifetimes. For more information visit iSETI LLC, Interstellar Space Exploration Technology Initiative.

Solomon is inviting all serious participants to his LinkedIn Group Interstellar Travel & Gravity Modification.

References

Bhatt MA, Lohrenz TM, Camerer CF, Montague PR. (2012). Distinct contributions of the amygdala and parahippocampal gyrus to suspicion in a repeated bargaining game. Proc. Nat’l Acad. Sci. USA, 109(22):8728–8733. Retrieved October 15, 2012, from http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3365181/pdf/pnas.201200738.pdf.

Birhard, K. (1999). The science of haptics gets in touch with prosthetics. The Lancet, 354(9172), 52–52. Retrieved from http://search.proquest.com/docview/199023500

Bostrom, N. (2009). When Will Computers Be Smarter Than Us? Forbes Magazine. Retrieved October 19, 2012, from http://www.forbes.com/2009/06/18/superintelligence-humanity-oxford-opinions-contributors-artificial-intelligence-09-bostrom.html.

BrainGate. (2012). BrainGate — Clinical Trials. Retrieved October 15, 2012, from http://www.braingate2.org/clinicalTrials.asp.

Chapin, J. (2008). Robo Rat — The Brain/Machine Interface [Video]. Retrieved October 19, 2012, from https://www.youtube.com/watch?v=-EvOlJp5KIY.

Cotton, I. (1997, 96). Dr. persinger’s god machine. Free Inquiry, 17, 47–51. Retrieved from http://search.proquest.com/docview/230100330.

de Garis, H. (2009, June 22). The Coming Artilect War. Forbes Magazine. Retrieved October 19, 2012, from http://www.forbes.com/2009/06/18/cosmist–terran-cyborgist-opinions-contributors-artificial-intelligence-09-hugo-de-garis.html.

deCODE genetics. (2012). deCODE genetics – Products. Retrieved October 26, 2012, from http://www.decode.com/products.

Feynman, R. (1959, December 29). There’s Plenty of Room at the Bottom, An Invitation to Enter a New Field of Physics. Caltech Engineering and Science. 23(5)22–36. Retrieved October 17, 2012, from http://calteches.library.caltech.edu/47/2/1960Bottom.pdf.

Foresight Institute. (2012). FI sponsored prizes & awards. Retrieved October 17, 2012, from http://www.foresight.org/FI/fi_spons.html.

Foster, D. J., & Wilson, M. A. (2006). Reverse replay of behavioural sequences in hippocampal place cells during the awake state. Nature, 440(7084), 680–3. doi: 10.1038/nature04587.

Freitas, R. (1998). Exploratory Design in Medical Nanotechnology: A Mechanical Artificial Red Cell, Artificial Cells, Blood Substitutes, and Immobil. Biotech.26(1998):411–430. Retrieved October 15, 2012, from http://www.foresight.org/Nanomedicine/Respirocytes.html.

Freitas, R. (2000, June 30). Clottocytes: Artificial Mechanical Platelets,” Foresight Update (41)9–11. Retrieved October 15, 2012, from http://www.imm.org/publications/reports/rep018.

Freitas, R. (2005. April). Microbivores: Artificial Mechanical Phagocytes using Digest and Discharge Protocol. J. Evol. Technol. (14)55–106. Retrieved October 15, 2012, from http://www.jetpress.org/volume14/freitas.pdf.

Freitas, R. (2006. September). Pharmacytes: An Ideal Vehicle for Targeted Drug Delivery. J. Nanosci. Nanotechnol. (6)2769–2775. Retrieved October 15, 2012, from http://www.nanomedicine.com/Papers/JNNPharm06.pdf.

Gao, R., Strehle, S., Tian, B., Cohen-Karni, T. Xie, P., Duan, X., Qing, Q., & Lieber, C.M. (2012). “Outside looking in: Nanotube transistor intracellular sensors” Nano Letters. 12(3329–3333). Retrieved September 7, 2012, from http://cmliris.harvard.edu/assets/NanoLet12-3329_RGao.pdf.

Grill, W., McDonald, J., Peckham, P., Heetderks, W., Kocsis, J., & Weinrich, M. (2001). At the interface: convergence of neural regeneration and neural prostheses for restoration of function. Journal Of Rehabilitation Research & Development, 38(6), 633–639.

Hochberg, L. R., Bacher, D., Jarosiewicz, B., Masse, N. Y., Simeral, J. D., Vogel, J., Donoghue, J. P. (2012). Reach and grasp by people with tetraplegia using a neurally controlled robotic arm. Nature, 485(7398), 372–5. Retrieved from http://search.proquest.com/docview/1017604144.

Kessel, A. (2009, June 8). Proteus Ingestible Microchip Hits Clinical Trials. Retrieved October 15, 2012, from http://singularityhub.com/2009/06/08/proteus–ingestible-microchip-hits-clinical-trials.

Koene, R.A. (2010). Whole Brain Emulation: Issues of scope and resolution, and the need for new methods of in-vivo recording. Presented at the Third Conference on Artificial General Intelligence (AGI2010). March, 2010. Lugano, Switzerland. Retrieved August 29, 2010, from http://rak.minduploading.org/publications/publications/koene…=0&d=1.

Kraemer, W. (2011, December).  To Interface the Future: Interacting More Intimately with Information. Journal of Geoethical Nanotechnology. 6(2). Retrieved December 27, 2011, from http://www.terasemjournals.com/GNJournal/GN0602/kraemer.html.

Montague, R. (2012, June). What we’re learning from 5,000 brains. Retrieved October 15, 2012, from http://video.ted.com/talk/podcast/2012G/None/ReadMontague_2012G-480p.mp4.

Nature Publishing Group (NPG). (2010, December). A critical look at connectomics. Nature Neuroscience. p. 1441. doi:10.1038/nn1210-1441.

Nickell, J. (2005, September). Mystical experiences: Magnetic fields or suggestibility? The Skeptical Inquirer, 29, 14–15. Retrieved from http://search.proquest.com/docview/219355830

Panksepp, J. (1992). A Critical Role for “Affective Neuroscience” in Resolving What Is Basic About Basic Emotions. 99(3)554–560. Retrieved October 14, 2012, from http://www.communicationcache.com/uploads/1/0/8/8/10887248/a…otions.pdf.

Park, K. I., Teng, Y. D., & Snyder, E. Y. (2002). The injured brain interacts reciprocally with neural stem cells supported by scaffolds to reconstitute lost tissue. Nature Biotechnology, 20(11), 1111–7. doi: 10.1038/nbt751.

Persinger, M. (2003). The Sensed Presence Within Experimental Settings: Implications for the Male and Female Concept of Self. Journal of Psychology. (137)1.5–16. Retrieved October ‎October ‎14, ‎2012, from http://search.proquest.com/docview/213833884.

Persinger, M. (2012). Dr. Michael A. Persinger. Retrieved October 27, 2012, from http://142.51.14.12/Laurentian/Home/Departments/Behavioural+Neuroscience/People/Persinger.htm?Laurentian_Lang=en-CA

Ptolemy, R. (Producer & Director). (2009). Transcendent Man [Film]. Los Angeles: Ptolemaic Productions, Therapy Studios.

Solovey, E., Schermerhorn, P., Scheutz, M., Sassaroli, A., Fantini, S. & Jacob, R. (2012). Brainput: Enhancing Interactive Systems with Streaming fNIRS Brain Input. Retrieved August 5, 2012, from http://web.mit.edu/erinsol/www/papers/Solovey.CHI.2012.Final.pdf.

Tran, F. (Director). (2012). Dream Life of Rats [Video]. Retrieved ?September ?21, ?2012, from http://www.hulu.com/watch/388493.

UPI. (2012, May 31). People with paralysis control robotic arms to reach and grasp using brain computer interface. UPI Space Daily. Retrieved from http://search.proquest.com/docview/1018542919

Weber, J. L. (2002). The iceland map. Nature Genetics, 31(3), 225–6. doi: http://dx.doi.org/10.1038/ng920

Wolpaw, J. (2010, November). Brain-computer interface research comes of age: traditional assumptions meet emerging realities. Journal of Motor Behavior. 42(6)351–353. Retrieved September 10, 2012, from http://www.tandfonline.com/doi/pdf/10.1080/00222895.2010.526471.

I was not intending to write Part 5, but judging from the responses I thought it was necessary to explain how to read a journal paper – and a good read cannot be done without a pen and paper. If you are writing a paper, when you have completed it, I would suggest you set it aside for at least a week. Don’t think about your paper or the topic during this shmita period. Then come back to your paper with a pen & paper and read it afresh. You’d be surprised by the number of changes you make, which means you have to start well before your deadline.

Note, you can find articles on how to review or write papers and here is one, by IOP (Institute of Physics, UK) titled Introduction to refereeing, and is a good guide to read before reading or writing a paper. This is especially true for physics but applies to all the sciences and engineering disciplines.

Note, for those who have been following the comments on my blog posts, IOP explicitly states “Do not just say ‘This result is wrong’ but say why it is wrong…” and “be professional and polite in your report”. So I hope, we as commentators, will be more professional in both our comments and the focus of our comments. Thanks.

In this post I will address what is not taught in colleges. There are three things to look out for when reading or writing a paper, Explicit and Implicit Axioms, Mathematical Construction versus Mathematical Conjecture, and finally, Concepts and Logical Flow. In this first part I discuss Explicit and Implicit Axioms.

This may sound silly but 1+1 = 2 is not an axiom. Alfred North Whitehead and Bertrand Russell proved that 1+1 adds to 2. Therefore, we see, that the immense success of the modern civilization compared to all other previous civilizations, is due to the encroachment of the imperceptible mathematical rigor in our daily lives by nameless, faceless scientist, engineers and technicians. Now that is something to ponder about. If we lose that rigor we lose our society. We can discuss economic and political theory but without this mathematical rigor, nothing else works.

Any theoretical work is based on axioms. For example in Pythagorean geometry, one assumes that surfaces are flat in such a manner the sum of the angles of a triangle adds to 180º.  In Riemann geometry this is not the case. Explicit axioms are those stated in the paper.

Implicit axioms are axioms that are taken for granted to be true and therefore not stated, or considered too trivial to be mentioned. More often than not, the author is not aware he or she is using or stating an implicit axiom.

For example, mass causes a gravitational field is an implicit axiom, as we cannot with our current theoretical foundations nor with our current technologies prove either way that mass is or is not the source of a gravitational field. This axiom is also considered trivial because what else could?

But wait, didn’t Einstein … ? Yes correct, he did .…

Mass is a carryover from Newton. It shows how difficult it is to break from tradition even when we are breaking from tradition! Since Newton figured out that mass was an excellent means (i.e. “proxy” to be technically rigorous) to determining gravitational acceleration in mathematical form, therefore mass had to be the source. All tests pertaining to Einstein’s relativity test the field characteristics, not how the source creates the gravitational field.

But our understanding of the world has changed substantially since both Newton and Einstein. We know that quarks are at the center of matter and exist in the same ‘amount’ as mass. So how does one tell the difference between quark interaction and mass as the gravitational source?

The importance of implicit axioms in particular and axioms in general, is that when we recognize them we can change them and drive fundamental changes in theory and technologies. I asked the questions, what is gravity modification and how can we do it? These questions are at best vague, but they were as good a starting point as any? But life happens backwards. We get the answer and then only do we recognize the precise question we were attempting to ask!

When I started researching gravity modification in 1999, I just had this sense that gravity modification should be possible in our lifetimes, but I did not know what the question was. It was all vague and unclear at that time, but I was very strict about the scope of my investigation. I would only deal with velocity and acceleration.

I spent 8 years searching, examining, discarding, testing and theorizing anomalies, trying to get a handle on what gravity modification could be. Finally in 2007 I started building numerical models of how gravitational acceleration could work in spacetime. In February 2008 I discovered g=τc² and at that moment I knew the question: Can gravitational acceleration be described mathematically without knowing the mass of the planet or star?

So the implicit axiom, mass is required for gravitational acceleration, is no longer valid, and because of that we now have propulsion physics.

If, in the spirit of the Kline Directive, you want to explore what others have not, and seek what others will not, my advice is that when you read a paper ask yourself, what are the implicit and explicit axioms in the paper?

Previous post in the Kline Directive series.

Next post in the Kline Directive series.

—————————————————————————————————

Benjamin T Solomon is the author & principal investigator of the 12-year study into the theoretical & technological feasibility of gravitation modification, titled An Introduction to Gravity Modification, to achieve interstellar travel in our lifetimes. For more information visit iSETI LLC, Interstellar Space Exploration Technology Initiative.

Solomon is inviting all serious participants to his LinkedIn Group Interstellar Travel & Gravity Modification.

…here’s Tom with the Weather.

It’s been in the news a lot of late, but — no way, right?

Because dude, I’m totally real
Despite being utterly unable to even begin thinking about how to consider what real even means, the everyday average rational person would probably assign this to the sovereign realm of unemployable philosophy majors or under the  Whatever, Who Cares?  or  Oh, That’s Interesting I Gotta Go Now!  categories. Okay fine, but on the other side of the intellectual coin, vis-à-vis recent technological advancement, of late it’s actually being seriously considered by serious people using big words they’ve learned at endless college whilst collecting letters after their names and doin’ research and writin’ and gettin’ association memberships and such.

So… why now?

Well, basically, it’s getting hard to ignore.
It’s not a new topic, it’s been hammered by philosophy and religion since like, thought happened. But now it’s getting some actual real science to stir things up. And it’s complicated, occasionally obtuse stuff — theories are spread out across various disciplines, and no one’s really keeping a decent flowchart.

So, what follows is an effort to encapsulate these ideas, and that’s daunting — it’s incredibly difficult to focus on writing when you’re wondering if you really have fingers or eyes. Along with links to some articles with links to some papers, what follows is Anthrobotic’s CliffsNotes on the intersection of physics, computer science, probability, and evidence for/against reality being real (and how that all brings us back to well, God).
You know, light fare.

First — Maybe we know how the universe works: Fantastically simplified, as our understanding deepens, it appears more and more the case that, in a manner of speaking, the universe sort of “computes” itself based on the principles of quantum mechanics. Right now, humanity’s fastest and sexiest supercomputers can simulate only extremely tiny fractions of the natural universe as we understand it (contrasted to the macro-scale inferential Bolshoi Simulation). But of course we all know the brute power of our computational technology is increasing dramatically like every few seconds, and even awesomer, we are learning how to build quantum computers, machines that calculate based on the underlying principles of existence in our universe — this could thrust the game into superdrive. So, given ever-accelerating computing power, and given than we can already simulate tiny fractions of the universe, you logically have to consider the possibility: If the universe works in a way we can exactly simulate, and we give it a shot, then relatively speaking what we make ceases to be a simulation, i.e., we’ve effectively created a new reality, a new universe (ummm… God?). So, the question is how do we know that we haven’t already done that? Or, otherwise stated: what if our eventual ability to create perfect reality simulations with computers is itself a simulation being created by a computer? Well, we can’t answer this — we can’t know. Unless…
[New Scientist’s Special Reality Issue]
[D-Wave’s Quantum Computer]
[Possible Large-scale Quantum Computing]

Second — Maybe we see it working: The universe seems to be metaphorically “pixelated.” This means that even though it’s a 50 billion trillion gajillion megapixel JPEG, if we juice the zooming-in and drill down farther and farther and farther, we’ll eventually see a bunch of discreet chunks of matter, or quantums, as the kids call them — these are the so-called pixels of the universe. Additionally, a team of lab coats at the University of Bonn think they might have a workable theory describing the underlying lattice, or existential re-bar in the foundation of observable reality (upon which the “pixels” would be arranged). All this implies, in a way, that the universe is both designed and finite (uh-oh, getting closer to the God issue). Even at ferociously complex levels, something finite can be measured and calculated and can, with sufficiently hardcore computers, be simulated very, very well. This guy Rich Terrile, a pretty serious NASA scientist, sites the pixelation thingy and poses a video game analogy: think of any first-person shooter — you cannot immerse your perspective into the entirety of the game, you can only interact with what is in your bubble of perception, and everywhere you go there is an underlying structure to the environment. Kinda sounds like, you know, life — right? So, what if the human brain is really just the greatest virtual reality engine ever conceived, and your character, your life, is merely a program wandering around a massively open game map, playing… well, you?
[Lattice Theory from the U of Bonn]
[NASA guy Rich Terrile at Vice]
[Kurzweil AI’s Technical Take on Terrile]

Thirdly — Turns out there’s a reasonable likelihood: While the above discussions on the physical properties of matter and our ability to one day copy & paste the universe are intriguing, it also turns out there’s a much simpler and straightforward issue to consider: there’s this annoyingly simplistic yet valid thought exercise posited by Swedish philosopher/economist/futurist Nick Bostrum, a dude way smarter that most humans. Basically he says we’ve got three options: 1. Civilizations destroy themselves before reaching a level of technological prowess necessary to simulate the universe; 2. Advanced civilizations couldn’t give two shits about simulating our primitive minds; or 3. Reality is a simulation. Sure, a decent probability, but sounds way oversimplified, right?
Well go read it. Doing so might ruin your day, JSYK.
[Summary of Bostrum’s Simulation Hypothesis]

Lastly — Data against is lacking: Any idea how much evidence or objective justification we have for the standard, accepted-without-question notion that reality is like, you know… real, or whatever? None. Zero. Of course the absence of evidence proves nothing, but given that we do have decent theories on how/why simulation theory is feasible, it follows that blithely accepting that reality is not a simulation is an intrinsically more radical position. Why would a thinking being think that? Just because they know it’s true? Believing 100% without question that you are a verifiably physical, corporeal, technology-wielding carbon-based organic primate is a massive leap of completely unjustified faith.
Oh, Jesus. So to speak.

If we really consider simulation theory, we must of course ask: who built the first one? And was it even an original? Is it really just turtles all the way down, Professor Hawking?

Okay, okay — that means it’s God time now
Now let’s see, what’s that other thing in human life that, based on a wild leap of faith, gets an equally monumental evidentiary pass? Well, proving or disproving the existence of god is effectively the same quandary posed by simulation theory, but with one caveat: we actually do have some decent scientific observations and theories and probabilities supporting simulation theory. That whole God phenomenon is pretty much hearsay, anecdotal at best. However, very interestingly, rather than negating it, simulation theory actually represents a kind of back-door validation of creationism. Here’s the simple logic:

If humans can simulate a universe, humans are it’s creator.
Accept the fact that linear time is a construct.
The process repeats infinitely.
We’ll build the next one.
The loop is closed.

God is us.

Heretical speculation on iteration
Even wonder why older polytheistic religions involved the gods just kinda setting guidelines for behavior, and they didn’t necessarily demand the love and complete & total devotion of humans? Maybe those universes were 1st-gen or beta products. You know, like it used to take a team of geeks to run the building-sized ENIAC, the first universe simulations required a whole host of creators who could make some general rules but just couldn’t manage every single little detail.

Now, the newer religions tend to be monotheistic, and god wants you to love him and only him and no one else and dedicate your life to him. But just make sure to follow his rules, and take comfort that your’re right and everyone else is completely hosed and going to hell. The modern versions of god, both omnipotent and omniscient, seem more like super-lonely cosmically powerful cat ladies who will delete your ass if you don’t behave yourself and love them in just the right way. So, the newer universes are probably run as a background app on the iPhone 26, and managed by… individuals. Perhaps individuals of questionable character.

The home game:
Latest title for the 2042 XBOX-Watson³ Quantum PlayStation Cube:*
Crappy 1993 graphic design simulation: 100% Effective!

And hey, if true, it’s not exactly bad news
All these ideas are merely hypotheses, and for most humans the practical or theoretical proof or disproof would probably result in the same indifferent shrug. For those of us who like to rub a few brain cells together from time to time, attempting to both to understand the fundamental nature of our reality/simulation, and guess at whether or not we too might someday be capable of simulating ourselves, well — these are some goddamn profound ideas.

So, no need for hand wringing — let’s get on with our character arc and/or real lives. While simulation theory definitely causes reflexive revulsion, “just a simulation” isn’t necessarily pejorative. Sure, if we take a look at the current state of our own computer simulations and A.I. constructs, it is rather insulting. So if we truly are living in a simulation, you gotta give it up to the creator(s), because it’s a goddamn amazing piece of technological achievement.

Addendum: if this still isn’t sinking in, the brilliant
Dinosaur Comics might do a better job explaining:

(This post originally published I think like two days
ago at technosnark hub www.anthrobotic.com.)

One would question if the IAEA is taking a strong enough position on the permitted location of nuclear power stations. It perplexes me that the main objections to Iran attaining nuclear power are strategic/military. Whilst Iran is not at risk to the threat of tsunamis as Japan is, Iran is one of the most seismically active countries in the world, where destructive earthquakes often occur. This is because it is crossed by several major fault lines that cover at least 90% of the country. How robust are nuclear power stations to a major quake? The IAEA needs to expand its role to advise countries on what regions it would be unsuitable to build nuclear power stations — such as Iran and Japan. Otherwise we are risking a lasting environmental impact to eventually occur — it is only a matter of time.

How the Diablo Canyon nuclear plant, which sits just miles away from the notoriously active San Andreas fault was allowed to be located there let alone operate for a year and half with its emergency systems disabled (according to a 2010 safety review by the federal Nuclear Regulatory Commission). It seems as if there’s a missing link worldwide between the IAEA and regional planning authorities. Or perhaps it is simply down to responsible government.

There has been strong information questioning the existence of Hawkins Radiation, which was a major reason most scientists think Black Hole Collider research is safe, without any increase in a call for a safety conference. Once, due to classification keeping it away from the general public, there was a small debate whether the first atomic explosion would set off a chain reaction that would consume the earth. On March 1, 1954 the Lithium that was, for other purposes, put in what was intended to be a small Hydrogen Bomb test, created, by far, the dirtiest atomic explosion ever as the natives on Bikini Island woke up to two suns in the sky that morning. History would be different had the first tests gravely injured people. Eventually people in the future will look back at how humankind dealt with the possibility of instantly destroying itself, as more important, than how it dealt with slowly producing more doomsday-like weapons.

With genetic engineering the results are amazing, goats with hair thousands of times stronger than wool would offer some increased protection from its predators. Think what would happen if, 1 foot long, undigestible fibers possibly with some sharp spots gets accidental inbreed in goat meat, or very un-tasty animals spread in the wild throughout the ecosystem. In 2001 Genetic Insecticide intended only to protect corn to be used in animal feed spread by the winds and cross breading to all corn in the northern hemisphere. Bees drinking corn syrup from one discarded soda can can endanger an entire hive. Now there is fear of this gene getting into wheat, rice and all plants that don’t rely on insects in some way. The efforts to require food to be labeled for genetically modified ingredients doesn’t address the issue and may actually distract from warning of the dangers ahead.

There are some who say bad people want to play God and create a god particle, likewise some say evil Monsanto,with bad motives, is trying to prevent us from buying safe food. This attitude doesn’t help create a safer future, or empower those trying to rationally deal with the danger.

The next danger is the attempt to impose Helter Skelter on the world with an Islam baiting movie. To Coptic Christians there was to be a movie on them being mistreated in Egypt. Actors hired to perform in a movie about flying saucers landing 2000 years ago and helped a man who never needed a shave and had a far away look in his eyes who had a donkey who he loved, and didn’t know who his father was. Islam haters fund-raised to create a movie smearing bin Laden but tricking Muslims to see it with movie posters in Arabic.

Somehow despite the false claim of 100 Jewish donors, no one who looked Jewish and rich was attacked in Los Angeles. Prompt expose‘ by Coptic Christian religious leaders, instead of someone else, exposing the claim that the person who pretended to be a Coptic Christian refugee and a rich Jewish businessman was the same person. Quick response prevented attacks on Copts in Egypt. Every relative of the four Americans killed in Benghazi, didn’t want Romney to use their name for campaign purposes. It is amazing that of all the people killed in the riots around the world following this hate trailer none of them were Americans who wanted their relative’s name used to promote anger at Muslims.

It is a bad omen that this was looked upon by many as a free speech issue not a terror attack. When Lebanese Prime Minister Rafik Hariri was killed to cause tit for tat revenge killings by a van that was stolen a year earlier in Japan, the UN took charge of the investigation. When Charles Manson tried to impose a Helter Skelter race war on the earth he didn’t come close enough to warrant being punished for a separate crime. If these two previous terror attacks on the world had been done in a way that no one was killed in the initial attack, is the earth really dumb enough to discuss it as a free speech issue?

Michael Jackson’s sister, before he died, was alarmed claiming that Michael Jackson’s handlers were systematical putting him under stress to put her brother in harm’s way. Comrad Murray this year wants a new trial insisting that he never would have given Michael orally such a badly mixed dose of anesthesia, and as no one seems to remember he had been distracted by a call on his cell phone for an offer of an important business deal. The world is full of incidents where professionals commit a crime in such a complex , convoluted way that it is hard to prosecute as a crime. Perhaps all these incidents could be looked into again.

It would be helpful if those stereotyped as not being concerned speak out like a sky diver warning about the Collider or a atheist leader and/or smut dealer speaking out on the hate religious film attack calling for investigation and prosecution. This Lifeboat site can accomplish more when it joins in where stereotypically one wouldn’t expect it to.

January through October, 2012, hasn’t been a good omen, in humankind’s ability to solve its problems and deal with danger, perhaps doing a year in review in October instead of waiting till January will make next January’s review brighter.

Most blogs expire concerning comments, one can comment below months from now,

http://readersupportednews.org/pm-section/22-22/14022-am…lter-chain

http://richardkanepa.blogspot.com/2012/10/it-is-only-human-t…es_18.html

http://www.aljazeera.com/news/europe/2012/10/20121022151851442575.html

I hope I do not misrepresent other members of staff here at The Lifeboat Foundation, in speaking on behalf of the Foundation in wishing these scientists a successful appeal against a court ruling which has shocked the scientific community, and I stand behind the 5,000 members of the scientific community who sent an open letter to Italy’s President Giorgio Napolitano denouncing the trial. This court ruling was ape-mentality at its worst.

http://environmental-safety.webs.com/apps/blog/

http://environmental-safety.webs.com/nuclear_essays.pdf

Comments welcome.