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SpaceX’s super sized Falcon Heavy rocket has a new launch date: spring 2016. That’s according to remarks given by Lee Rosen, SpaceX’s vice president of mission and launch operations, at a conference in Pasadena this week. Space News reports the executive as saying, “It’s going to be a great day when we launch [the Falcon Heavy], some time in the late April – early May timeframe.”

We’ve been hearing about the Falcon Heavy for some time, but it has seen its share of delays. It will be the world’s most powerful operational rocket, capable of launching 115,000 pounds (53,000 kg) into low-Earth orbit. In history, it only comes short of the Saturn V rocket, which powered NASA’s Apollo missions to the moon. SpaceX originally promised to launch the rocket for the first time in 2013. It was then pushed back to this year, but the project was put on ice following the failure of a Falcon 9 rocket on June 28th.

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A year ahead of the 2016 U.S. presidential election, it’s amazing at how small a role the American space program has played during this tempestuous summer of early primary campaigning.

It’s certain that NASA will live long and prosper no matter who’s ultimately elected as our 45th president; the American space agency has done so for 50-plus years. But even in this burgeoning age of commercial space development, political catchphrases such as “Back to the Moon and on to Mars;” “Capture an asteroid and on to Mars;” or even bypass the Moon and “Go directly to Mars” somehow still ring hollow.

On the morning of the recent booster test launch of NASA’s Space Launch System (SLS), I watched NASA Administrator Charles Bolden enthusiastically describe the new launch system. He noted NASA’s goal of using the new system to capture a large boulder from a near Earth asteroid and bring it back to a stable lunar orbit. This planned Asteroid Redirect Mission (ARM) as it’s now called would happen by the middle of the next decade. Then by the 2030s, NASA would re-purpose SLS for a manned mission to Mars. But such massive undertakings still need political will and the funding that goes with it.

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Our interstellar challenge is, how do we as a planet confined humans, become an interstellar species? This encompasses all human endeavors, and is vitally dependent upon interstellar propulsion physics to realize our coming of age as an interstellar species.

There are so many competing ideas on how to realize interstellar propulsion. These include chemical rockets, ion propulsion, nuclear engines, solar sails, atomic bomb pulse detonation, antimatter drives, small black holes, warp drives and much more.

How do we sift through all these competing ideas?

For his objectivity and courage in stating that mathematics has become so sophisticated that it can now be used to prove anything, I have named the approach to solving this interstellar challenge the Kline Directive, in honor of the late Prof. Morris Kline.

To achieve interstellar travel, the Kline Directive instructs us to be bold, to explore what others have not, to seek what others will not, and to change what others dare not. To extend the boundaries of our knowledge, to advocate new methods, techniques and research, to sponsor change not status quo, on 5 fronts, (1) Legal Standing, (2) Safety Awareness, (3) Economic Viability, (4) Theoretical-Empirical Relationship and (5) Technological Feasibility.

Legal Standing: Do we have the protection of the law?

Mr. Gregory W. Nemitz of The Eros Project is the first person I know, who pushed the limits of the law. As a US taxpayer, Nemitz claimed ownership of Asteroid 433, Eros, and invoiced NASA $20,000 for parking and storage of the NEAR Shoemaker spacecraft. Citing faulty interpretation of the Outer Space Treaty of 1967, NASA refused to pay. On April 26, 2004 U.S. District Court Judge Howard McKibben dismissed the case. We have to address this. What is to stop other governments from imposing taxes on our outer space commercial activities that is “for the benefit and in the interests of all countries”?

Safety Awareness: Can we protect our crew and our planet?

In the heady rush to propose ideas for new propulsions systems or star drives it is very easy to overlook safety considerations. Quoting E.J. Opik, “Is Interstellar Travel Possible?” Irish Astronomical Journal, Vol 6, page 299. “The exhaust power of the antimatter rocket would equal the solar energy power received by the earth — all in gamma rays”. And Opik quotes the eminent Carl Sagan, Planet. Space Sci., pp. 485–498, 1963, “So the problem is not to shield the payload, the problem is to shield the earth”.

Economic Viability: Can realistic commercial viability be determined?

Space exploration economic viability is not an accounting problem that can be solved by CFOs and accountants. This economic viability is a physics and engineering problem. For example, chemical rocket propulsion to Alpha Centauri, our nearest star, would cost about $1.19x10^14 or 23x 2011 world GDP.

Theoretical-Empirical Relationship: Is the hypothesis empirically sustainable?

String theories are a good example of a theoretical-empirical relationship that is yet to be proved. Let’s remember Prof. Morris Kline’s words when theorist claim a velocity of 1032 x c (velocity of light) is achievable. Don’t get me wrong. Mathematics is vital to the progress of the sciences, but it needs to be tempered with real world experimental evidence, otherwise it is just conjecture, and ties up our search for interstellar propulsion technologies.

The reverse is equally valid. Without the theoretical underpinnings, there will not be much experimental progress. Podkletnov’s gravity shielding experiments are a good example. In 2 decades since Podkletnov published his experiments, there has not been any experimental progress. My inference is that none of the proposed theoretical explanations addressed all the observations and therefore, could not guide future experiments.

Technological Feasibility: Does it work?

Technological feasibility in a realistic and finite time frame is vital. Technological feasibility quickly leads back to the question of commercial viability. Developing future feasible technologies is an iterative process between technological feasibility and commercial viability, until we can reach the stars without having to ask the question, whom do we select to leave Earth?

Applying the Kline Directive, a quick method of eliminating competing technologies is to construct the Interstellar Challenge Matrix that compares the pros and cons of each competing propulsion technology.

Can we hasten the development of interstellar propulsion technologies? Yes.

Since disproving the validity of Alcubierre-type warp drives, interstellar propulsion physics is currently non-existent. To birth this propulsion physics, in 2012, I classified physical hypotheses/theories into 3 categories (1) Type 1: The Millennium Theories, (2) Type 2: The 100-Year Theories and (3) Type 3: The Engineering Feasible Theories.

Type 1, Millennium Theories require more than a 100 years and maybe up to 1,000 years to prove or disprove. Mathematically correct but inscrutable with physically verifiable experiments, even in the distant future. String and quantum gravity theories fall into this category. Why? If we cannot even figure out how to engineer-modify 4-dimensional spacetime, how are we going to engineer-modify a 5-, 6-, 9-, 11- or 23-dimensional universe?

Type 2, 100-Year Theories show promise of being verified with technologies that would require several decades to engineer, test and validate, and do not lend themselves to an immediate engineering solution. The engineering solution is theoretically feasible but a working experiment or technology is some decades away as the experimental or physical implementation is not fully understood.

Type 3, Engineering Feasible Theories lend themselves to engineering solutions, today. They are falsifiable today, with our current engineering technologies, if one knows what to test for and how to test for these experimental observations.

We as a society need to apply the Kline Directive to invent new propulsion physics theories, that are at best Engineering Feasible and at worst 100-Year theories.

We now have the tools to quickly eliminate both theoretical and experimental proposals that are highly likely to be unproductive, and focus on those that truly have potential of delivering commercial interstellar propulsion technologies. In the US money is no object, as the combined 2015 DARPA and NSF budgets, is $10.26 billion. Allocating a very small slice of these budgets for propulsion physics would be an enormous step forward.

(This article was originally published in the Huffington Post.)

Ten years after the project was conceived, the German Aerospace Centre’s SpaceLiner could soon enter a new design phase with a “mission definition review” planned for 2016.

The idea is to produce a two-stage, reusable hypersonic space vehicle that could transport 50 passengers from Europe to Australia in 90 minutes.

Leonid Bussler of the German Aerospace Centre’s Space Launch Systems Analysis (SART) group says the project is currently in “Phase Zero,” where the range of vehicle concepts are narrowed down to a single, baseline configuration through wind tunnel testing and performance trade-offs.

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Agreeing to state-of-the art theory, a warp drive might cut the travel time between stars from tens of thousands of years to only weeks or months. Harold G. White, a physicist and innovative propulsion engineer at NASA and other NASA engineers are working to regulate whether faster-than-light travel — warp drive — might soon be possible. The group is trying to some extent warp the course of a photon, altering the distance it travels in a definite area, and then detecting the change with a device called an interferometer.

In 1994, a Mexican physicist, Miguel Alcubierre, speculated that faster-than-light speeds were conceivable in a technique that did not deny Einstein by binding the growth and reduction of space itself. Under Dr. Alcubierre’s theory, a ship still couldn’t surpass light speed in a native region of space. But a theoretical thrust system he sketched out operated space-time by producing a so-called “warp bubble” that would inflate space on one side of a spacecraft and contract it on another.

Image source: With thanks to Shutterstock.com.

An Alcubierre Warp Drive expanses spacetime in a wave producing the material of space ahead of a spacecraft to contract and the space behind it to enlarge. The ship can ride the wave to go faster to high speeds and time travel. The Alcubierre drive, also famous as the Alcubierre metric or Warp Drive, is a mathematical model of a spacetime showing features suggestive of the fictional “warp drive” from Star Trek, which can move “faster than light”.

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3045

“It has sold millions of copies, is perhaps the greatest novel in the science-fiction canon and Star Wars wouldn’t have existed without it. Frank Herbert’s Dune should endure as a politically relevant fantasy from the Age of Aquarius.”

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Over half a century after the dawn of the space age, getting to space remains an epic challenge. Twice this year, the first stage of a SpaceX Falcon 9 rocket met a fiery end on the Atlantic Ocean—both attempts to recover and reuse rockets to reduce launch costs. A third rocket never made orbit, exploding on ascent.

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In aviation circles, the talk of the future involves phrases like “space planes” and “hypersonic atmospheric flight vehicles.” A group presently in the spotlight is from Germany; they are carrying a roadmap for low-cost space access which involves calling upon the air passenger market for fast-travel flights.

Welcome to the world of SpaceLiner, which, when fully developed, could have dramatic impact in global aerospace. The DLR Institute of Space Systems said this suborbital, hypersonic, winged passenger transport idea is under investigation at DLR-SART. (DLR is a German aerospace research agency and it evaluates complex systems of space flight. SART is Space Launcher Systems Analysis.)

SpaceLiner is a rocket-propelled intercontinental passenger transport, described by the institute as a two-stage vehicle powered by rocket propulsion.

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Theatrical Trailer for The Martian. During a manned mission to Mars, Astronaut Mark Watney is presumed dead after a fierce storm and left behind by his crew. But Watney has survived and finds himself stranded and alone on the hostile planet. With only meager supplies, he must draw upon his ingenuity, wit and spirit to subsist and find a way to signal to Earth that he is alive.

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