bigpictureone

Using photos, video & words to explore the Big Picture WordPress.com site

GONE IN 30 SECONDS…

Posted on November 6, 2014 by bigpictureone

It’s estimated that an average of 8 percent of all commercial rocket launches end in failure.

Multimedia eLearning program by: David A. Johanson © All Rights

David Johanson is a multimedia specialist, CTE instructor and a former Boeing scientific photographer. All content, including photography, graphics and text (unless otherwise noted) was created by the author. To see an alternative graphic format of this program, click on: www.ScienceTechTablet.wordpress.com

Learning Objectives Of This Program Includes:

≥ Definition and meaning of space law

≥ History and development of space law

≥ History and development of 20TH and 21ST Century Rocket and Launch disasters

≥ How, where and why rocket launch sites and space portals are located on the globe

≥ Potentially life threatening activities and components of rocket launches ———————————————————————————————

The Antares 110 rocket engines roared as they illuminated their departure from Earth — seconds later, appearing as if mortally wounded, the multi-staged rocket suddenly lost momentum and sank downward, creating an explosive tower of flames. Over the launch site’s PA system an urgent command required all media personnel to leave their equipment and evacuate immediately. It was reported no deaths had occurred — however the total environmental damage, the launch site cleanup and insurance liability issues are yet to be assessed.

Here’s NASA video of the unexpected Antares rocket launch disaster. ⇒http://www.youtube.com/watch?v=aL5eddt-iAo

The referenced video below shows, press journalist and photographers ordered to evacuate as the Antares rocket explodes and unleashes toxic clouds of vaporized solid rocket propellant. Winds should be blowing to the east, so that burning propellant dissipates over the Atlantic Ocean — not heading west towards potentially populated areas, as is indicated happening in this video. ⇒ http://www.youtube.com/watch?v=IclTka711xo

Photograph: Kenneth Brown/Reuters

On October 31ST, just three days after Orbital Sciences’, Antares rocket launch explosion, Virgin Galactic’s SpaceShipTwo (SS2) disintegrates in an upper altitude reentry over California’s Mojave Desert. Unfortunately the space plane’s pilot was killed, as the remaining components of the craft slammed into an unpopulated area. ⇒http://www.youtube.com/watch?v=dy1k5s7Fbl0 ⇒http://www.theguardian.com/science/2014/nov/02/virgin-galactic-spaceshiptwo-crash-investigators-fuel-warnings

What Goes Up, Must Come Down

Rocket launch projects have always had to contend with laws of physics, in particular, Newton’s law of gravity. Today, these multimillion dollar programs are governed by another set of laws, involving multinational, liability space laws. These binding laws are for protecting individuals, communities and the environment from impacts caused by, man-made objects launched into space or subsequent damage of corporate or national operations in space.

Case Study: The first record of a space law liability incident occurring was in 1962, on a street within Manitowoc, Wisconsin. Apparently, a three-kilogram metal artifact from the Russian’s 1960, Sputnik 4 satellite launch, reentered the atmosphere unannounced, over an unsuspecting Midwest. The Russian’s denied it was theirs, fearing liability under international law. This event, helped set in motion, the 1963 Declaration on Legal Principals Governing the Activities of State in the Exploration and Use of Outer Space. As an international agreement, it puts forth the responsibility to the State which launches or engages in sending objects into space as internationally responsible for damages caused on Earth. In 1967, the agreement was slightly modified and was titled “Outer Space Treaty 1967.”

Earth has water covering 70% of its surface — when attempts fail to guide space debris towards open oceans, the chance for these falling objects to hit a populated area increase. Space Law assesses the liability for damages caused by space debris to the nation or agency responsible for its original rocket launch.

By 1984, the United Nations General Assembly, had adopted five sets of legal principles governing international law and cooperation in space activities. The principles include the following agreements and conventions.”Outer Space Treaty” – the use of Outer Space, including the Moon and other Celestial Bodies (1967 – resolution 2222.) “Rescue Agreement” – the agreement to rescue Astronauts/Cosmonauts, the Return of Astronauts/Cosmonauts and the Return of Objects Launched into Space (1968 – resolution 2345.) “Liability Convention” – the Convention on International Liability for Damaged Caused by Space Objects (1972 – resolution 2777.) “Registration Convention” – the registration of Objects Launched into Outer Space (1975 – resolution 3235.) “Moon Agreement” – the agreement Governing the Activities of States on the Moon and Other Celestial Bodies (1979 – resolution 34/68.)

Because so many international languages are used for creating these technical agreements — terms and meanings are often misinterpreted. There are linguistic limitations and a general lack of definitions to adequately cover all the specific space concepts and activities using Space Law. Each Nation has its own agenda and vision concerning the development of space, including corporate, cultural and religious interest, adding to the complexity of governing space.

Although most large “space debris” is monitored with top priority for enabling reentry over uninhabited areas such as oceans and deserts — satellites or sections of rockets still have potential for an unexpected re-entry over an inhabited area.

Cuba Gives A New Meaning To A Cash Cow

Case Study: In November of 1960, the second stage of a U.S. – Thor rocket fell back to Earth and killed a cow grazing in Eastern Cuba. The final settlement required the U.S. Government to pay Cuba $2 million dollars in compensation — creating the world’s first “Cuban Cash Cow.”

Dramatic Rocket Launch Failures Associated With Space Exploration

American physicist, Dr. Robert H. Goddard is the father of modern rocket propulsion. Goddard’s published rocket research during the1920s and 1930s, is what German military scientist used to help develop the liquid fueled V2 rocket, which terrorized Europe towards the end of WWll. The V2 (technical name Aggregat-4 or A4) rocket was the first human made artifact to leave the Earth’s atmosphere and reach into space. This basic design of modern rockets has changed little in the 100 years since Goddard was awarded a U.S. patent in 1914 for a rocket using liquid fuel.

It’s estimated since the 1950s, of the nearly 8,000 rockets launched into space related missions, 8 percent of rocket launches ended in some-type of failure (2012 spacelaunchreport.com.) The resulting anomalies have cost the lives of hundreds of individuals, including; astronauts, cosmonauts and civilians, along with billions of dollars of property and payload losses.

Here’s an abbreviated list of eventful, dramatic and tragic events associated with rocket launches.

A modified V-2 rocket being launch on July 24, 1950. General Electric Company was prime contractor for the launch, Douglas Aircraft Company manufactured the second

A modified V-2 rocket being launch on July 24, 1950. General Electric Company was prime contractor for the launch, Douglas Aircraft Company manufactured the second stage of the rocket & the Jet Propulsion Laboratory (JPL) had major rocket design roles & test instrumentation. This was the first launch from Cape Canaveral, Florida.

stage of the rocket & the Jet Propulsion Laboratory (JPL) had major rocket design roles & test instrumentation. This was the first launch from Cape Canaveral, Florida. → http://www.youtube.com/watch?v=zVeFkakURXM

Vanguard TV3, December 6, 1957 launched from Cape Canaveral, Florida (U.S.) was the first U.S. attempt at sending a satellite into orbit. A first event of its kind to use a live televised broadcast, which ended with stunned viewers witnessing Vanguard’s explosive failure. Unfortunately, this launch mission was not ready for prime-time and occurred as a reflex reaction to the Soviet Union’s surprise aerospace success of launching the world’s first satellite, Sputnik, on October 23, 1957. → http://www.youtube.com/watch?v=zVeFkakURXM

Vostok rocket, March 18, 1980, launched from Plesetsk, Russia (formerly the world’s busiest spaceport). While being refueled the rocket exploded on the launch pad, killing 50, mostly young soldiers. (Source: New York Times article, published September 28, 1989) ⇒ http://www.nytimes.com/1989/09/28/world/1980-soviet-rocket-accident-killed-50.html

Challenger STS-51-L Space Shuttle disaster, January 28, 1986, launched from Kennedy Space Center (U.S.) marked the first U.S. in-flight fatalities. After only 73 seconds from lift-off, faulty O-ring seals failed, releasing hot gases from the solid propellant rocket booster (SRB), which led to a catastrophic failure. Seven crew members were lost, including Christy McAullife, selected by NASA’s Teacher in Space Program. McAullife was the first civilian to be trained as an astronaut — she would have been the first civilian to enter space, but tragically, the flight ended a short distance before reaching the edge of space. Recovery efforts for Challenger were the most expensive of any rocket launch disaster to date. ⇒ http://www.history.com/topics/challenger-disaster/videos/engineering-disasters—challenger

Long Mark 3B rocket launch, payload: American communication satellite, built by Space Systems Loral – February 14, 1996 in Xichang (China) – two seconds into launch, rocket pitched over just after clearing the launch tower and accelerated horizontally a few hundred feet off the ground, before hitting a hill 22 seconds into its flight. The rocket slammed into a hillside exploding in a fireball above a nearby town, it’s estimated at least 100 people died in the resulting aftermath. This event was most likely the worst rocket launch disaster to date, due to the massive loss of human life. Disaster at Xichang | History of Flight | Air & Space Magazine ⇒ http://www.airspacemag.com/history-of-flight/disaster-at-xichang-2873673/?c=y%3Fno-ist video of the rocket launch disaster ⇒ https://www.youtube.com/watch?v=8_EnrVf9u8s

Antares rocket launch explosion with ‘firebrands’ cascading from solid propellant — NASA photo

Delta 2, rocket launch – January 1997, Cape Canaveral (U.S.) – this rocket carried a new GPS satellite and ends in a spectacular explosion. Video link included to show examples of worst case scenario of a rocket exploding only seconds after launch (note brightly burning rocket propellant cascading to the ground is known as “firebrand”.) The short video has an interview with Chester Whitehair, former VP of Space Launch Operations Aerospace Corporation, who describes how the burning debris and toxic hydrochloric gas cloud fell into the Atlantic Ocean from the rocket explosion. Rocket launch sites and Spaceports are geographically chosen to mitigate rocket launch accidents. US rocket disasters ⇒ http://www.youtube.com/watch?v=Y4-Idv6HnH8

Titan 4, rocket launch – August 1998, Cape Canaveral (U.S.) the last launch of a Titan rocket – with a military, top-secret satellite payload, was the most expensive rocket disaster to date – estimated loss of $ 1.3 Billion dollars. ⇒ http://www.military.com/video/explosions/blast/titan-iv-explosion-at-cape-canaveral/1137853205001/

VLS-3 rocket, launch – August 2003, Alcantara (Brazil) – rocket exploded on the launch pad when the rocket booster was accidentally initiated during test 72 hours before its scheduled launch. Reports of at least 21 people were killed at the site. ⇒ http://usatoday30.usatoday.com/news/world/2003-08-22-brazil-rocket_x.htmvideo of the rocket launch disaster ⇒ https://www.youtube.com/watch?v=8_EnrVf9u8s

Rocket launch debris fields are color keyed in red & Links to space port’s web sites included. (CLICK ON MAP TO ENLARGE) Quiz ??? – 1.) Do you see any similarities in the geographic locations used for these launch sites? 2.) What advantages do these locations have regarding “Space Law?” 3.) For most rocket launches, which site has the greatest geographic advantage & why? 4.) Which has the least advantage & why?

Rocket launch debris fields are color keyed in red & Links to space port’s web sites included. (CLICK ON MAP TO ENLARGE) Quiz ??? – 1.) Do you see any similarities in the geographic locations used for these launch sites? 2.) What advantages do these locations have regarding “Space Law?” 3.) For most rocket launches, which site has the greatest geographic advantage & why? 4.) Which has the least advantage & why?
Location, location, location is a huge benefit for rocket launch sites.

If you zoom into the above World map with its rocket launch sites, you’ll notice they’re located in remote, uninhabited areas. Another feature most space ports share is their proximity to large bodies of water, which are located in an easterly direction (with the exception of the U.S. Vandenberg site.) Rockets are launched over oceans to minimize the risk to people or property from catastrophic accidents, which includes falling launch debris and toxic clouds of burnt fuel propellant. Liability from a launch vehicle is the main reason why all ships and aircraft are restricted from being in water anywhere near or underneath a rocket’s flight path. Rocket’s debris can contain highly toxic forms of unspent fuel and oxidizer, especially from solid propellant fuels.

The majority of rockets are launched in an easterly direction, due to the Earth’s easterly rotation. This procedure gives the rocket extra momentum to help escape the Earth’s gravitational pull. An exception for an east directional launch is a Vandenberg site in California. This site launches most of its rockets south for polar orbits, which is used by a majority of communication and mapping satellites.

Launching rockets closer to the equator gives a launch vehicle one more advantage — extra velocity is gained from the Earth’s rotation near its equator. At the equator, our planet spins at a speed of 1675 kph (1040 mph,) compared to a spot near the Arctic Circle, which moves at a slower, 736 kph (457 mph.) Even the smallest advantage gained in velocity means a rocket requires less fuel (13 percent less fuel required for equatorial launches) to reach “escape velocity.” This fuel savings translates to a lighter launch vehicle, making the critical transition of leaving Earth’s gravitational field quicker.

International space law is emerging from its infancy, attempting to clearly define itself from a nebulous amalgam of; agreements, amendments, codes, rules, regulations, jurisdictions,

Photo-illustration: David A Johanson — of space debris using a NASA photo of Skylab

treaties and non-binding measures. There exists today, enough legal framework for commercial interest to move cautiously towards developing outer space. However, with the unforeseen variables and dynamics of space activities, exceptions will be made & rules will be stretched, if not broken to accommodate necessity, justification or exculpation. ~

Part 1 of 2 editions – please check back soon for the conclusion of this essay.

The next edition of the Space Law series includes:

Potential Minefield Effects From Space Debris And The Regulatory Laws To Help Clean It Up.

Will Asteroid Mining Become The Next Big Gold Rush And What Laws Will Keep The Frontier Order?

Music video portal of rocket launches (nostalgia enriched content):

Boards of Canada – Dawn Chorus ⇒ http://www.youtube.com/watch?v=rfVfRWv7igg

Boards of Canada – Gemini – ⇒ http://vimeo.com/68087306

Boards of Canada – Music is Math ⇒http://www.youtube.com/watch?v=F7bKe_Zgk4o

Links And Resources, For Space Law And Related Issues

http://definitions.uslegal.com/s/space-law/

http://www.thespacereview.com/article/2588/1

https://www.gwu.edu/~spi/assets/docs/AGuidetoSpaceLawTerms.pdf

http://digitalcommons.unl.edu/spacelaw/38/

The Space Review: International space law and commercial space activities: the rules do apply Outlook on Space Law Over the Next 30 Years: Essays Published for the 30th … – Google Books “SPACE FOR DISPUTE SETTLEMENT MECHANISMS – DISPUTE RESOLUTION MECHANISM” by Frans G. von der Dunk Asteroid mining: US company looks to space for precious metal | Science | The Guardian Planetary Resources – The Asteroid Mining Company – News 5 of the Worst Space Launch Failures | Wired Science | Wired.com Orbital Debris: A Technical Assessment NASA Orbital Debris FAQs ‎orbitaldebris.jsc.nasa.gov/library/IAR_95_Document.pdf A Minefield in Earth Orbit: How Space Debris Is Spinning Out of Control [Interactive]: Scientific American SpaceX signs lease agreement at spaceport to test reusable rocket – latimes.com Earth’s rotation – Wikipedia, the free encyclopedia The Space Review: Spacecraft stats and insights Space Launch Report V-2 rocket – Wikipedia, the free encyclopedia Billionaire Paul Allen gets V-2 rocket for aviation museum near Seattle – Science Germany conducts first successful V-2 rocket test — History.com This Day in History — 10/3/1942

http://www.nbcnews.com/science/billionaire-paul-allen-gets-v-2-rocket-aviation-museum-near-1C9990063

[contact-form][contact-field label="Name" type="name" class="GINGER_SOFATWARE_correct">/][contact-field label="Email" type="email" class="GINGER_SOFATWARE_correct">/][contact-field label="Website" class="GINGER_SOFATWARE_correct">/][contact-field label="Comment" type="textarea" class="GINGER_SOFATWARE_correct">/][/contact-form]

Will The Next Jet Airliner You Fly Be Obsolete, And Ready for Early Retirement?

Posted on October 15, 2014 by bigpictureone

 Multimedia eLearning program authored by: David Anthony Johanson © – All written & graphic content on this site (unless noted) was produced by the author. Add: 2.0 For an alternative graphic format presentation, please visit: https://sciencetechtablet.wordpress.com/tag/commercial-jet-airliner-obsolescence/

This multimedia essay includes an eLearning program for secondary/post secondary education and community learning. Assessment tool: A quiz and answer key is located at the end of the program. Learning content covered: aerospace/airliner— aerospace engineering, avionics, economics & business, environmental footprint, financing, manufacturing, marketing, obsolescence management, technology. Learning concepts used: Applied Learning, Adult Learning, Competency-based Learning, Critical Thinking, Integrative Learning.Key: Words or phrases italicized are used to focus on essential concepts or terms for enhanced learning and retention.

[ Disclaimer: David Johanson is a former Boeing scientific photographer and currently has no stock holdings or a financial interest in: Boeing, Airbus or any other companies referenced in this program. Research in this article has been cross referenced using at least three sources, however, all perspectives and opinions represent only the viewpoints of the author.]

.
Like seeing a mirage in the distance, shimmering sunlight reflects off rows of metal fuselages densely packed in the summer light. A surreal scene of Boeing jet airliners dominates the view, while forming a metallic wall around sections of a regional airport.

Billions of dollars worth of jet airliners are now double parked around Paine Field, Snohomish County Airport, in Everett, Washington. “This development indicates the current success, Boeing is having at landing airliner orders and the result you’re seeing represents a record amount of aircraft production,”said Terrance Scott, a spokesman for Boeing Commercial Airplanes.

He said the Company is leasing this space from Paine Field so that planes can have the remaining work completed and be ready for delivery to their customers — also, this isn’t unique to Everett, but is happening at Boeing manufacturing facilities at Renton Field and at Boeing Field in Seattle.

“Boeing has always been a good neighbor and a fine customer for the airport, they are currently leasing areas to park their aircraft and the revenue generated is appreciated.” said Dave Waggoner, Airport Director at Snohomish County Airport — Paine Field.

The global economy’s steady growth has increased passenger traffic, which puts pressure on the airlines to purchase new aircraft for satisfying demand. Continued drops in jet fuel prices benefits air travel industry profits, giving further incentives for fleet investments. Additionally, with historically low-interest rates, lending institutions find new opportunities in aviation financing, enabling expansion of corporate sales. However, financing for used planes is another matter. Cash is drying up for previously owned jetliners — which puts pressure to part-out, then scrap relatively newer-used aircraft.

Could The New Normal Be Shorter Aircraft Service-Life For Airliner Fleets?

Recently, published reports noted a shift towards an assumed obsolescence and accelerated scraping of newer airliners — well before structural integrity or air worthiness becomes a problem, middle-aged aircraft are experiencing vulnerability to an early end-of-life. Clearly, accelerated scraping of newer aircraft is not due to any structural concerns, but rather, cyclical conditions of the industry. To appreciate these concerns a review of an airliner’s operational lifespan may help clarify some of the issues.

Aircraft manufactures use pressurization cycles to determine an airliner’s operational lifespan. A pressurizing cycle includes three distinct aircraft flight activities — takeoff, climbing until it reaches a cruise altitude and then landing. During this process, air is pumped into the fuselage to pressurize the cabin for passenger comfort. This repeated pressurization flexes or expands the fuselage — consequently stress is put on various connecting components, including fasteners and rivets — which helps to hold the structural integrity of the plane together. After a certain number of landing pressurization cycles, stress or metal fatigue can begin to develop, eventually causing small cracks around the fasteners. Pressurization/landing cycles mainly concern the life of an aircraft’s fuselage, wings and landing gear.

The interior of fuselage section, showing perpendicular rings, which are called frames.

The interior of fuselage section, showing perpendicular rings, which are called frames.

Maintenance schedules and lifespan of jet engines are measured in the number of flight hours. Aircraft engines, followed by landing gear and then avionics are the most valuable components for part-out and dismantling specialist operations. Ultimately, engine condition is the major factor in an owner’s decision to part-out an aircraft.

.
For short flights, single or smaller double aisle craft are used to carry passengers, which may go through many landing or pressurization cycles for everyday operations. The more takeoffs and landings, means a shorter operational lifespan for the plane. On long overseas flights, wide body or jumbo jets such as 747s experience fewer landing cycles. These larger airliners, especially ones use for cargo operations can have longer lifespans of upwards of 20 or 30 years. In the U.S., the FAA requires an initial inspection on Boeing 737s, which have 30,000 takeoffs and landings using electromagnetic testing. Mandatory inspections are required for finding cracks in the fuselage or metal fasteners.

Boeing has a history of ‘over-engineering’ components of its aircraft, which is actually a good thing for ensuring passenger safety and for an extended service-life of the aircraft. Historical evidence of this conservative engineering practice is documented in WWII archival film footage of blown-apart B-17s returning from a mission and safely landing. There are more recent examples of Boeing commercial aircraft surviving dramatic inflight catastrophic failures, with most of the passengers and crew landing safely.

Photo-illustration of an aircraft end-of-life center (aircraft boneyard.)

Compound Forces Working Against Long-Life-Cycle Aircraft

What are the current forces, which hasten the end-of-life of a commercial jet airliner? Recurring cycles or patterns of economic and technological events influences the commercial aircraft industry on a daily basis. Various ripple-effects of these cycles can quickly alter new and used aircraft asset valuation. Airline leasing companies have a major influence, in providing their customers with the aircraft assets they need. Unless the buying customer has solid credit, it’s doubtful they can secure financing for previously-owned airliners. Also, tax incentives exist for Airline companies to use depreciation right-offs by decommissioning all but the most advance aircraft assets.

Maintenance requirements are a long-term, yet fluid, financial concern for a company’s airline fleet. The newer designed aircraft are manufactured with significantly fewer parts than previous models. Consequently, reduction in parts has an impact on reducing maintenance expenditures — including smaller service crews, hours spent on inspection and a reduction of overall repairs. Also, spare parts inventories for maintaining the aircraft’s optimum performance can substantially be reduced compared to an older aircraft. The cost savings benefits are compelling incentives for eliminating older, higher maintenance, aircraft assets.

As mentioned previously, the considerable reduction of parts used in manufacturing newer aircraft provides an immediate benefit of up to 20 percent weight reduction. Without compromising strength or aircraft structural integrity, the cost savings from less weight begins the day an airliner is put into service. Traditionally, fuel-efficiency is the “holy grail” used for selecting an aircraft — the amount of fuel-burn affects the daily operational cost of an airline company. After a decade of service an older airliner reaches mid-life, it may require upgraded and modification conversions to the aircraft’s wings (winglets) or need new fuel-efficient jet engines. However, these conversions reach a threshold of diminishing returns from such investments. As a result, keeping an older aircraft competitive with newer models may not pay off at a certain point. That’s when permanent retirement and parting-out the airliner begins to make economic sense and the aircraft’s end-of-life management begins.

Inevitable Problems Facing Aircraft Electronic Systems (Avionics) Obsolescence

The most perplexing problem facing all commercial aircraft is how to ensure its critical avionics systems continue to evolve and stay up-to-date. Avionics provides the central nervous system or a central processing unit (CPU) framework for a commercial aircraft. It’s a marvelous matrix of advanced electronic systems technology, which constantly communicates with itself, the pilots and the outside world. More so than any other components making up an aircraft’s technological system, its management and functionality duties are beyond comparison. Each year avionics components physically contract in size, yet they expand immensely in functionality and system management.

Here’s an example to help clarify this dichotomy of physical contraction and expansion of technical functionality. Your smartphone can be used as a basic representational model for avionics obsolescence. The phone you’re holding in your hand has a superior mobile graphics processor and sheer number-crunching power advantage over IBM’s Deep Blue supercomputer of the late 1990s. Yet, you can hold your phone in hand, compared to Deep Blue, which was the size of a large refrigerator. However, advanced your smartphone is today, a year from now it’ll be obsolete and two years from now… a quaint antique. If you grabbed your smartphone and considered the example, you just experienced Moore’s law of observation — ‘over the history of computing hardware, the number of transistors in a dense integrated circuit doubles approximately every two years.

Now, imagine trying to update a complex system such as an airliner’s avionics bay, in five-years, 10-years or 15-years. The installation and the majority of electronic systems are not made by the Aircraft’s original equipment manufacturer (OEM) such as Boeing or Airbus. Moreover, the vendors or suppliers 10 or 15-years from now who were the OEM, may be out of business. In the meantime, new replacement components may have to substitute the obsolete equipment. However, the aircraft industry is highly regulated by government agencies, which require strict certification of equipment modifications. As a result of these constraints, aircraft manufacturers such as Boeing, developed obsolescence management strategies to help mitigate these ongoing concerns. But there are always unforeseen obstacles and many moving parts to coordinate before the necessary electronic components are available when needed. Clear, transparent communication is necessary between internal engineering and purchasing departments. Successful collaboration at all levels can present major challenges, especially if the objectives and timetables are not each group’s priority.

So aircraft avionics are the vulnerable underbelly of airliner obsolescence — with financial consequences associated with accelerated, technology — necessitating complex and expensive electronic upgrades.

Airspace Navigation Service Providers (ANSP), which includes the FAA and the European counterpart EASA — have established new mandate requirements for avionic component upgrades. The purpose of this technology is for enhanced data link digital communication, which interacts instantly with aircraft Flight Management Systems (FMS). These requirements include, Automatic Dependent Surveillance-Broadcast (ADS-B), Controller-Pilot Data Link (CPDLC) and the Future Air Navigation System (FANS) enables text messaging and global position through satellite communications. The new civil aviation mandates are part of the next generation air traffic computer technology called NextGen, which represents air traffic infrastructure’s future for the next 10 to 15 years.

Used Aircraft Components, Harvested For Premium Returns, Is The Retired Airliners Last Call In Service Before Its Final Destination.

Perhaps aircraft boneyards are flying under the radar as virtual gold mines, as refurbished parts are easily sold at market value. The savings of buying used, over new aircraft parts is incentive for expanding the market. Engines, landing gear and avionics are the most expensive components of an aircraft. These prized components are a highly valued commodity and are quickly snapped up. Specialized systems are not manufactured by companies such as Boeing or Airbus, but by outside OEM. Parts sold brand new by the manufacturer are considerably more expensive than buying used.

Next Generation aircraft such as the Boeing 737-600 and even a 737-800, which was reported to have had a hard-landing, reached their end-of-life as scrap. Also, Airbus has had similar, newer single-aisle aircraft models reached their final destination in the aviation boneyard. Aircraft Fleet receivable Association (AFRA) estimates 600 commercial jet airliners are scrapped yearly. By 2023 it’s estimated the number of commercial airliners scrapped will reach 1000 per-year.

Efforts Of The Aviation Industry To Leave A Smaller Environmental Footprint.

In 2008, the Boeing Company reached out to Airbus in collaboration, with the goal to vastly improve aircraft recycling technology. Airbus estimates they are recycling 85 percent of the entire aircraft, the remaining cabin interior amounted to 15 percent and was the only materials added to landfills.

The best takeaway from the issues surrounding accelerated airliner service-life is that less fuel is consumed by the newer fleets. As older, less efficient aircraft are replaced — a 20 percent reduction in fuel emissions will not enter the atmosphere from the next generation aircraft replacements. If the world’s commercial airline manufactures continue to devote more effort towards efficient recycling of past generation aircraft, we can look forward to clearer skies ahead. ~

*
Special thanks to The Future of Flight Museum, for allowing photos to be taken from their excellent observation deck.

http://www.futureofflight.org

Aerial view of Paine Field Airport looking north.

Airliner Obsolescence Quiz (Read the entire question before answering.)

1. ) What three economic incentives are currently influencing airlines to purchase new aircraft for satisfying travel demand? ______________________________________ _________________________________ & _________________________________
2. ) (True or False) Structural integrity or air worthiness of current generation airliners is the main issue why these aircraft are being retired early. _______ If you answered false, give at least one other reason why this is occurring. ____________________________ _____________________________________________________________________
3. ) Aircraft manufactures use, what type of ___________ cycles to determine an airliner’s operational lifespan?
4. ) Name the three distinct aircraft flight activities used to determine an airliner’s operation lifespan? _________________________ __________________________ ____________________________________________
5. ) Maintenance schedules and lifespan of jet engines are measured in the ________________ hours.
6. ) Aircraft _________ followed by ____________ and then ___________ are the most valuable components for the part-out and dismantling specialist operations. Fill in the blanks above by selecting the proper order of component value, using the following list: (bulk heads) (wire bundles) (avionics) (engines) (landing gear)
7. ) Selecting from the choices listed below, which aircraft will typically experience more pressurization cycles and why? A or B ____________ A. Jumbo jet (larger, multi isle aircraft) which is used for longer, overseas flights. B. Smaller, single isle jet airliners, which are used more for shorter, domestic flights. Now explain why? ______________________________________________________________________ ______________________________________________________________________ 8. ) Multi-isle airliners or jumbo jets, used for longer international flights or for cargo operations can have life cycles of upwards of ____ – ____ years. Select the best match from these sets: 5 − 15, 10 − 15, 20 − 30, 30 − 40 years.

9. ) Explain why a larger commercial jet airliner, which flies longer over-sea routes, would have a longer operational life than a smaller aircraft, which is used on much shorter routes? __________________________________________________________________ ________________________________________________________________________
10. ) What procedure is required by the FAA for a Boeing 737 airliner, which completes 30,000 takeoffs and landings? _______________________________________________ ________________________________________________________________________
11. ) The newer designed aircraft are manufactured with significantly fewer parts than previous models, list at least two reasons why this is an advantage and would make older aircraft obsolete? _______________________________________________________ ______________________________________________________________________
12. ) What aircraft component traditionally has been considered the “holy grail” used by the airline industry for selecting an aircraft? _____________________________________
13. ) When permanent retirement and parting-out the of an airliner begins to make economic sense, what form of management begins for that aircraft? ____________________ Select one of the following: end-of-days, end-of-life, retirement cycle, recycle phase.
14. ) What critical system of an airliner is considered its “central nervous system” or CPU for overall control of the aircraft? ________________________________ Give at least two reasons why this system contributes to a jet becoming obsolete? ________________________________________________________________________ ________________________________________________________________________
15. ) Approximately how many aircraft are permanently retired or scrapped in a year? __________________ By 2023, how many aircraft are expected to be scrapped? _____________________
16. ) Regarding commercial aircraft recycling technology, what percentage does Airbus estimate it is recycling of the entire airliner ___ 40 %, 65 %, 75 % or 85 % What percent of the aircraft is not recyclable ___ 60 %, 50 %, 25 %, or 15 % What part of the airliner is not recyclable ____________________ and where does it end up? _______________
Answer key is located at the very bottom, after program sources & related links

*
Sources & Related Subject Matter Links

This link shows live air traffic anywhere in the world. View how congested the sky’s are over the world’s busiest airports.

http://www.flightradar24.com/47.79,-122.31/7

Aircraft Bluebook – Used for aviation asset valuation

http://www.boeing.com/assets/pdf/commercial/aircraft_economic_life_whitepaper.pdf

http://marketline.squarespace.com
http://www.boeing.com/boeing/companyoffices/aboutus/brief/commercial.page

http://www.airbus.com/innovation/eco-efficiency/aircraft-end-of-life/

http://www.airspacemag.com/need-to-know/what-determines-an-airplanes-lifespan-29533465/?no-ist

http://www.faa.gov/aircraft/air_cert/design_approvals/air_software/media/ObsolescenceFinalReport.pdf

http://aviationweek.com/awin/nextgen-obsolescence-driving-avionics-refurbs

http://www.theguardian.com/business/2013/jun/11/boeing-commercial-planes-double-asia-pacific

http://www.airliners.net/aviation-forums/general_aviation/read.main/5740876/

http://avolon.aero/wp/wp-content/uploads/2014/06/Aircraft_Retirement_Trends_Outlook_Sep_2012.pdf

Article & photos on U.S. aircraft boneyards

http://www.johnweeks.com/boneyard/

http://www.dailymail.co.uk/sciencetech/article-2336804/The-great-aviation-graveyard-New-aerial-images-hundreds-planes-left-die-American-deserts.html

Article, photos & interactive map of U.S. aircraft boneyards

http://www.airplaneboneyards.com/commercial-aviation-airplane-boneyards-storage.htm

Excellent aerial video of Airplane Graveyard (Mojave Airport, California)

http://www.youtube.com/watch?v=6RjaoR7Zk2s

Airliner Obsolescence Quiz Answer Key

1. ) Satisfying increased travel demand Fuel cost savings & Historically, low-interest rates for financing new aircraft

2. ) True Newer aircraft are replacing airworthy, older aircraft due to much less operating cost, including fuel savings and maintenance issues.

3. ) Pressurization or Landing cycles

4. ) Takeoff Climbing to cruise altitude Landing

5. ) Number of flight hours

6. ) Engines landing gear avionics

7. ) B Shorter service routes typically involve more landing and takeoffs as the airliner satisfies domestic travel demand

8. ) 20 − 30

9. ) An airliner flying overseas route would most likely have fewer takeoffs and landings, due to the longer flight time required to reach its destination

10.) Electromagnetic testing for finding cracks in the fuselage or related components

11.) Fewer parts can result in an airliner weighing up to 20 percent less than older models, which can correlate to the same percentage of fuel savings. The maintenance cost is substantially lower allowing for more savings over older aircraft with more component parts.

12.) Fuel-efficiency

13.) End-of-life

14.) Avionics electronic components used for avionics may not be available or upgradeable due to obsolescence upgrading obsolete avionics may require expensive redesign

15. ) Up to 600 1000

16. ) 85 % 15 % Cabin interiors Landfills

The Environment, Our Earth’s Lost Frontier?

Posted on April 22, 2014 by bigpictureone

(On the left horizon, hydrocarbons are being released into the air, blemishes an otherwise clear arctic day.)

Multimedia eLearning by: David A. Johanson © All Rights

All Roads Lead to Nowhere

Early in my career as a photographer I received assignments which took me above the Arctic Circle. Construction companies and architects working for oil companies in Alaska’s North Slope hired me to photograph their on going developments. At that time the Prudhoe Bay oil field’s production had peaked due to years of sustained extraction. A new oil field near the Kurparuk River, west of Prudhoe Bay was the site I was sent to. The Kuparuk oil field is the second largest oil field in North America by area, and traveling by aircraft was the way I moved from site to site.

Roads and construction sites above the arctic circle, rely on heaps of gravel placed over the tundra’s surface to prevent them from sinking into the earth when the ground thaws. Traveling less than 100 feet off the tundra, at 150 miles per hour, the pilot of the Hughes 500D helicopter races to horizon. The orange shelters at the edge of the road, is our intended destination. These metallic enclosures are used to pump hot steam down-into the wells, for recovering a thick slurry of oil, locked deep below the frozen tundra.

Alaska, the Last Frontier

Flying above an older oil facility, it can clearly be seen — the years of oil production have left Rorschach-like-ink-blots, splattered on the surrounding tundra. I have not been to the oil fields for many years, but I was told at the time — ‘oil companies were trying to cleaning up their act, while leaving a smaller footprint.’ I pray what I heard was true, but as we know — accidents both large and small continue to happen.

On a clear day while flying above vast stretches of tundra, we viewed a small monument, which marked where Will Rogers and Wiley Post had been killed in a plane crash. I spotted dozens of randomly placed metallic cylinders near the site. My bush pilot brought the airplane down for a closer look and cynically said, those are abandoned, empty 50 gallon oil barrels… known as —“Alaska’s state flower.”

An old barn in the shadow of Anacortes oil refinery.
There’s something charming about old barns as they weather over the years. This one with its organic wood earth tones, is contrasted against the metallic cylinders of an oil refinery in Anacortes, about 70 miles north of Seattle, on the edge of Puget Sound. On April 2, 2010 five workers were killed at this oil refinery as an explosion and fire ripped through part of the refinery.

EARTH Day seems to have more meaning as the impact of global warming, seismic and volcanic activity focuses our attention on the big picture.

Our world is delicately balanced, spinning through space, with us all aboard along for the journey. At least one day, one week, out of a busy calendar year, we’re asked to give homage to our planet by being aware of its’ environment. In honor of this day, I’m sending out photographs and prose that reflect current events affecting our world’s environment.

“One World, One Planet.”
A fascinating, outdoor setting, with an incredibly diverse ecosystems is the Rainforest of the Olympic National Forest. It was a late summer day when I hiked down form Lake Osset, to where the rainforest meets the Pacific Ocean. This area has never been logged, the old growth forest here stands as it has for thousands of years.

After setting up a tent I walked along a trail leading to a lush meadow. A twig snapped a few feet away from me, revealing two unusual looking deer, grassing in the tall grass. Never have I encountered wildlife, where if I desired, could reach out and touch it. The deer could plainly see me; yet they made no effort to scramble away or even conceal themselves. The reason this wildlife seems tame is that they reside within a remote National park, where no hunting is allowed. Slowly, I raised my camera loaded with my favorite Kodachrome transparency film. As I began to take a series of photos, I noticed unusual patterned markings on the deer’s body. Refocusing my lens, amazingly, what appeared was a map of the earth, patterned on the deer. Last year I scanned the transparency, then enhancing it with Photoshop, the world continents clearly revealed themselves in what I’ve themed
– “One Planet, One World.”

“Paradise Lost” –
Have you ever gone back to a place and found what you had once treasured was missing? The longing for beauty, which once was, is a reoccurring theme used to select many photos in this essay.

“Paradise Lost” –
The enchanting scene with a man gazing into the pools of water is from Whatcom Falls. My college roommate sitting on the moss-covered boulders is Mark Nishimura, a fine-art photographer, originally from the state of Hawaii. Mark asked that I photograph him in a place that was reminiscent of the waterfalls back home on Ohau. I used a Hasselblad and slow speed transparency film to help capture the dynamic range of shadows and highlights. This was one of my favorite places to photograph when I attended school at Western Washington University, in Bellingham. Many students would spend summer afternoons cooling off, diving and swimming amongst the deep pools of water. A short walk into Whatcom Park, placed you in a lush environment, under a thick canopy of evergreen trees, moss-covered vegetation with sounds of cascading waterfalls running throughout it.

Some years after this photo was taken, tragedy struck, instantly incinerating this charming environment. A refinery’s 16-inch fuel-line running next to the park, ruptured, spewing nearly 300 thousand gallons of gasoline into the creek. In an instant, the fuel ignited, creating a river of fire, which killed three youths fishing in the creek and sending a toxic vapor cloud six miles into the atmosphere. The fireball and plume of smoke was visible from Anacortes to Vancouver, B.C., Canada. Now, ten years after the catastrophe, I plan to return to the falls and photograph the site with hopes that nature’s healing process is transforming it back to the way it use to be.

“Paradise Found” –
I remember a photography teacher I had in college took us to a beach near Chukanut Drive. When he gave out the assignment, most of the class groaned; we were to pick a spot on the beach, stay within a 25-foot diameter and shoot a series of photos to tell a story. Most of us wanted to take our cameras and explore what the entire beach had to offer. Surprisingly, it was one of the best assignments I was ever given in school; because it broke the stereotype about how you were suppose to see. Within that small domain we discovered, a whole universe was waiting to reveal itself before the camera lens. That photography lesson has stuck with me since, although world travel is a passion, I realize that I really didn’t have to go any farther than my backyard to find great images and no matter what, if resourceful, amazing subjects can be found everywhere.

My home’s back yard is like an outdoor studio full of indigenous plants, birds and amphibians. We avoid using pesticides and only use natural fertilizers on the yard and garden. One afternoon I found this charming tree frog sitting on a leaf, warming itself in the sunshine. With a macro lens on my camera, I was able to get within inches of the frog and let the background merge into soft abstract forms. The photo makes me smile whenever I see it because it reminds me, I never have to go far to reconnect with nature.

On a moonlit night, traveling the back-roads of Washington and Oregon —
we found countless sentinels standing guard against the cold breeze of darkening skies.

The Future is Now…
Working tirelessly with the wind, turbines spin against the moon backdrop, producing ‘clean energy’ for the Pacific Northwest. Throughout the Americas and many other places in the world, the tide is turning as we move more towards wind and solar for a clean, renewable energy source.

Web Links For Earth Day

http://abclocal.go.com/wls/story?section=news/local/illinois&id=9511926

http://newyork.cbslocal.com/2014/04/22/tri-state-area-commemorating-earth-day-with-series-of-events/

http://www.earthday.org

http://news.nationalgeographic.com/news/2014/04/140421-earth-day-2014-facts-environment-epa/

http://www.slate.com/blogs/bad_astronomy/2014/04/22/earth_day_2014_a_few_fun_facts_about_our_planet.html

THE MARTIAN PROPHECIES – Earth’s Conquest of the Red Planet.

Posted on March 4, 2014 by bigpictureone

Early Mars terraforming site inspected by an American first-generation colonist.

.

Essay and multimedia content by: David Anthony Johanson ©All writing and photography within this program (unless indicated) was produced by the author.

If you would like to see this essay in an alternative graphic format please visit our Science Tech Tablet site at: ⇒ http://sciencetechtablet.wordpress.com/

Fu-tur-ism noun

1. Concern with events and trends of the future or which anticipate the future.

Any sufficiently advanced technology is indistinguishable from magic. — Arthur C. Clarke

How Earth Conquered Mars And Successfully Colonized The Red Planet

March 2054

.

The Evolutionary Mastery Of Mars

In a forty-year period, the march towards making Mars inhabitable, astonished the most optimistic futurist. A sequence of technological events and economic opportunities (commonly known as the Third Industrial Revolution) converged seamlessly, allowing for safe and efficient journeys to the fourth planet from our Sun. Now, human life has sustained itself and is beginning to thrive on Martian soil.

On Earth, three decades into the third millennium, unstable global weather patterns caused by environmental abuse to our oceans, created extreme ripple effects with appalling famines and droughts. Then, suddenly a horrific rain of fire appeared as a sequence of catastrophic meteorite strikes plagued Earth— hastening humanity’s efforts to reach for the red planet. Of all the planets in our solar system — Mars has proven the best hope as a lifeboat and as a refuge for life taking hold.

Collaboration from the World’s nations, aligned rapidly to expand the colonies beyond Earth’s low-orbit. These outposts are in a stable formation at Sun-Earth Lagrangian Points: L2, L4, L5 and beyond. The various sites are used to support manufacturing, exploration and asteroid mining operations. Once established, they became “stepping-stones” towards Mars. Distant supply and launch stations are currently expanding at Sun-Mars Lagrangian points, circulating Mars.

Triumph Through Large Scale Asteroid Mining

After the first three decades of daring space exploration in the late Twentieth Century, momentum was lost from lack of compelling mission. Chemical propulsion system limitations and lack of aerospace manufacturing beyond Earth’s orbit, slowed space exploration’s progress. Major superpowers lacked funding and political will to achieve great advances beyond low Earth Orbit.

As the Twenty-First Century progressed, collaboration of prime aerospace companies Boeing and Space X, developed, hybrid launch vehicles to accelerate humanity’s expanded presence in space. Private commercial ventures determined a great potential existed for mining valuable resources from near Earth asteroids and the Moon. The first company to successfully begin asteroid mining were Planetary Resources, with funding provided by wealthy technology luminaries.

Three-D Printing In Space – A Bridge To Infinity

Early in the Twenty-first Century, new advanced technological tools were developed for flexible and efficient manufacturing. After revolutionary 3-D printing operations took hold in space, opportunities expanded rapidly to develop massive infrastructure beyond Earth’s orbit. Three-D printing devices made prefabrication of immense living and working sites possible on the Moon and various stationary points well beyond Earth’s gravitational influence.

Three-D printing for manufacturing space-station stepping-stones

.

Beyond Earth’s Orbit — Islands In Space

As the population of human enterprises rapidly expanded into deep space, exploration of Mars became practical and irresistible.

Using a spectrum of cybernetic applications, including artificial intelligences (AI), atomically precise manufacturing (APM) and 3-D printing provided cost-effective infrastructure manufacturing to expand beyond Earth’s low orbit. The network of space station developments offers a growing population of skilled aerospace workers — dynamic living and work environments.

Molecular nanotechnology (MNT) produces an endless variety of manufactured goods for the inhabitants of interplanetary space. As the initial space stations quickly expanded and connected to one another, they became known as “Island Stations.” Adopting interplanetary codes for infrastructure support commonality is maintained for all inhabitants and guest visits by the National Aeronautics and Space Administration (NASA) and European Space Agency (ESA).

A network of stepping stone islands, which initially were used to extend the reach of asteroid mining operations from stable points beyond a low Earth orbit, is essential for colonizing Mars.

Approximately 10 million miles from Earth, a network of station islands is positioned as a gateway point to Mars. These station networks are mutually protected from solar storms/flares by their own artificial magnetosphere. Earth (blue dot) and its moon can be seen near the upper-center part of the photo.

Revolution — Electro Magnetic Propulsion And Magnetic Shield Protective Fields

Revolutionary, electromagnetic propulsion systems, using super-cooled, conducting magnets and magnetoplasmadynamic (MPD) were developed for vastly superior performance over conventional chemical rockets. The time required to reach destinations such as Mars has been reduced significantly, by a factor of one year to less than two weeks. Initial funding from NASA and ESA, created a collaboration between Boeing, SpaceX and Virgin Galatic to produce these hybrid propulsion space craft. http://www.cbsnews.com/news/boeing-spacex-to-team-with-nasa-on-space-taxi/

The greatest threat to human space travel and colonization is from solar winds of magnetized plasma carrying protons and alpha particles, which can break down DNA and lead to cancer. A magnetic coil shield system allows space craft protection from most harmful radiation by creating its own magnetosphere. This shielding system harnesses for universal applications to protect space station populations, inner planetary travelers and Martian colonies.

A high energy accelerator was developed on Mars using spectrums of solar energy to recreate a magnetic field to help produce a sustainable atmosphere.

An electromagnetic propulsion cargo ship as it begins entering a high energy state.

Electromagnetic propulsion “asteroid lifter” encounters solar wind storm.

NASA illustration.

Genetic Modification Through Astrobiology Provides Essential Benefits For Human Space Travelers

Evolutionary biology has provided advantages to meet the challenges of human travel into deep space.

The first generation of genetically modified humans was created to limit the effects and risk from extended space travel. Microchip circuitry imbedded into tissue, gave humans expanded capabilities to assure space survivability, productivity, and flight operations. To combat muscle degradation from zero gravity-exposure, contractile protein levels were increased in muscle tissue.

Settlements On The Red Planet And Stages Of Terraforming

To survive solar radiation effects, early Mar’s settlers lived bellow the planet’s regolith (soil). Within less than a decade, the colonies developed their own localized magnetosphere, which became encapsulated environments within translucent domes — creating an atmospheric oasis. These aerodynamic structures offer shielding from dust storms and subzero temperatures. Now, an enriched quality of life on Mars includes ever-expanding domains of Earth like atmosphere for expanded development and life above the surface of the red planet.

: Meteor showers streaming above craters and cliffs during a Martian sunrise.

Massive mirrors are fixed in orbit above Mars for reflecting warmth back onto its surface, to provide a more temperate climate. Reflected light directed at Martian polar ice caps and its Carbon dioxide atmosphere of CO2 helps to keep thermal energy near the planet’s surface. As a result, a thermal runaway greenhouse effect is created to help build a thicker atmosphere. Release of microorganisms on the red the planet dramatically accelerates production, for intensifying greenhouse gas expansion.

Directing small asteroids with rich concentrations of ammonia to impact nitrate beds on Mars, releases high volumes of oxygen and nitrogen. These highly controlled asteroid strikes are providing substantial positive results to help develop an enriched atmosphere.

Nanotechnology is now employed on the surface of Mars and is dramatically altering landscape regions within various craters. Genetically modified plant forms are successfully taking hold and surviving some test environments. In conclusion, all of these achievements are creating a more Earth like climate, for efforts to terraform Mars.

Earth’s Sustainable Community On Mars

Self replicating machines using APM manufacturing allow infrastructure to develop at astonishing rates on the red planet. New scientific, engineering and mining communities are establishing themselves rapidly as they descend from orbiting stations and stationary platforms above the planet. The current population on Mars has surpassed 40,000 inhabitants and is projected to double within the next five-years.

The form of governance adopted by the colonies on Mars is based on a nonpolitical and international form of cooperation. Asteroid mining and APM manufacturing are the largest industries associated with the Mars colonies.

Martian colonists celebration party for “Pioneer Days.” Martian sunset seen in the background, behind a massive protective atmospheric shield.

Fossil Bed Enigma Reveals We May Never Have Been Alone

Found only days ago in the Antoniadi Crater region, is evidence of a fossil and what appears to be human like footprints. Although this discovery may revolutionize our view of the red planet — we must wait for the samples to arrive on Earth to confirm what could be one of the greatest discoveries of all time.

Discovery at a Martian archeological dig site — “we have never been alone.”

Perchance, the most fascinating evidence of preexisting intelligence of life on Mars, was discovered near the Antoniadi Crater. Enclosed within a geographic site is a source, which is emitting peculiar magnetic fields. Upon further analysis revealed, distinct patterns of what appears as a mysterious complex digital codex. After extensive review and evaluation using a network of 2020 Enigma Genisus Computing systems interpreted it as audible, instrumental sounds accompanied by visual projections of humanoid syncopated movements.

Most perplexing is the referenced quantitative variables, suggest the site was or is a time capsule or possibly a time-portal. To see audio and visual projection click on the link below. https://www.youtube.com/watch?v=53bCaqz0zZA

Music soundtrack for the Martian Prophecies — Powered by Boards of Canada (you can open another web browser if you like and have the following music play while viewing this essay)

Solar System & Planetary travel, music, dedicated to the “Shield of Achilles” – protector of the inner planets ⇒ http://www.youtube.com/watch?v=3l_IMOweP0E

Martian pioneers’ celebratory music – video chronicle International Space Station development and logistic support leading to permanent Mars colonization ⇒ http://www.youtube.com/watch?v=4jBzl–TN1Q and or ⇒ http://www.youtube.com/watch?v=PYEZueAelKc

Music for terraforming Mars too – video chronicles Mars atmospheric enrichment and the planets terraforming stages ⇒ http://www.youtube.com/watch?v=qthHlLyvplg

Martian moonlight illuminates sculpted cliffs, as “Vesta II” (logistics platform) enters view —piercing the night sky with solar light reflecting off its West-East orbital path.