Orion’s 1st European Service Module Unveiled at KSC for NASA’s 1st Moon Test Flight on SLS: Photos

ESA’s first European Service Module for NASA Orion crew capsule is unveiled at welcoming ceremony at Neil Armstrong Operations and Checkout building at NASA’s Kennedy Space Center on Nov. 16, 2018 including remarks by ESA Director General Jan Wörner.  Credit: Ken Kremer/kenkremer.com/spaceupclose.com

Ken Kremer  --SpaceUpClose.com & RocketSTEM --28 November 2018

KENNEDY SPACE CENTER, FL - The first European-built Service Module built to power NASA’s Orion crew spacecraft for human voyages to deep space was unveiled at a welcoming ceremony held at NASA’s Kennedy Space Center (KSC) in Florida - where it is now being processed for the 1^st integrated test flight launch to the Moon atop the mammoth Space Launch System (SLS) megarocket on the Exploration Mission-1 (EM-1) in 2020. 

NASA hosted the welcoming event for this first European Service Module - dubbed ESM-1 - inside the cavernous Neil Armstrong Operations and Checkout building at KSC on Nov. 16 - and attended by a big crowd of dignitaries from NASA, the European Space Agency (ESA) who funded its development, the main European and US industrial contractors and the news media including Space UpClose.

“We will not go back to the moon … We will go forward to the moon,” said ESA Director General Jan Wörner at the “Powering EM-1” KSC media event. 

“We will go in a totally different way to the moon. Not in competitive manner but in a very cooperative manner ... to motivate the future.”

“Today we celebrate the delivery of the European Service Module, said  NASA Administrator Jim Bridenstine.

"The USA is very grateful for our partners at the European Space Agency and all its member nations.”

“This is a momentous occasion where we will have the opportunity to fly into deep space. And the European Service Module is a huge element of this architecture.” 

Enjoy our exclusive ESM event photos at KSC’s Neil Armstrong Operations and Checkout building. 

ESA’s first European Service Module for NASA Orion crew capsule is unveiled at welcoming ceremony at Neil Armstrong Operations and Checkout building at NASA’s Kennedy Space Center on Nov. 16, 2018 including remarks by ESA Director General Jan Wörner.  Credit: Ken Kremer/kenkremer.com/spaceupclose.com

The cylindrically-shaped European Service Module ESM-1 is the critical ‘powerhouse’ element that will supply NASA’s human-rated Orion spacecraft with electricity, propulsion, thermal control, air and water and propel it on its first voyage to the the Moon and 40,000 miles (64,000 km) beyond atop SLS-1 during EM-1 from KSC pad 39B.

Graphic outlining European Service Module for NASA’s Exploration Mission-1 with Orion human-rated spacecraft and Space Launch System rocket launch to the Moon in 2020. Credit: ESA/Airbus  

“This powerhouse element is what we need to go farther than ever before,” said Mark Kirasich, NASA’s Orion program manager.

“In space the two halves must operate flawlessly.”

“It’s a great day @NASAKennedy with our @esaspaceflight @AirbusSpace @LockheedMartin partners with the delivery of the #OrionESM !” tweeted Kirasich.

ESA’s first European Service Module for NASA Orion crew capsule is unveiled at welcoming ceremony at Neil Armstrong Operations and Checkout building at NASA’s Kennedy Space Center on Nov. 16, 2018 including remarks by ESA Director General Jan Wörner.  Credit: Ken Kremer/kenkremer.com/spaceupclose.com

ESM-1 was funded and developed by the European Space Agency (ESA) and manufactured by prime contractor Airbus in Bremen, Germany and Turin, Italy with components supplied by companies all over Europe.

After years of separate development the two main components are finally together in the same place for mating and more!

“Finally together! @NASA_Orion's service and crew modules are both at @NASAKennedy, and this is just the beginning – the first leg of an exciting #JourneyToTheMoon,” tweeted ESA. 

The implications here are huge because this marks the first time that NASA “will use a European-built system as a critical element to power an American spacecraft, extending the international cooperation of the International Space Station into deep space.”

Up Close look at ESA’s first European Service Module mated on top to Crew Module Adapter with 192 bolts - for eventual connection to NASA Orion crew capsule was unveiled at Neil Armstrong Operations and Checkout building at NASA’s Kennedy Space Center on Nov. 16, 2018  Credit: Ken Kremer/kenkremer.com/spaceupclose.com

Eventually future ESMs will power Orion astronauts to the Moon and beyond on mission to deep space starting with Exploration Mission-2 (EM-2) as soon as 2022 after life support and other systems are incorporated. 

ESM serves the same role as the Apollo Service Module (SM) during NASA’s Apollo Moon landing missions in the 1960s and 1970s. 

Orion and SLS  are under development by NASA to lead humanity back to a permanent presence at the Moon together with partners including Europe and potentially Russia, Canada and Japan.  

NASA’s Gateway human tended lunar orbiting outpost is key to NASA human ‘Return to the Moon’ architecture says NASA Administrator Jim Bridenstine.

“We are in a good place to be a partner for the lunar Gateway,” says Jan Wörner. r

ESM-1 aerived stateside at the Kennedy Space Center, FL, on Nov. 6, from its manufacturing facility in Bremen, German after flying here aboard a huge Antanov An-124 cargo jet touching down gracefully at approximately 11:34 a.m. EST at the Shuttle Landing Facility – as witnessed by Space UpClose with photos taken from Titusville, FL.

First European-built Orion Service Module (ESM) arrives at NASA’s Kennedy Space Center aboard Antonov An-124 cargo jet flying from Bremen, Germany on Nov. 6, 2018. The module was provided by the European Space Agency to propel NASA’s first Orion mission to the Moon in 2020 on the Space Launch System rocket.   Credit: Ken Kremer/kenkremer.com/spaceupclose.com

Credit: Ken Kremer/kenkremer.com/spaceupclose.com

Orion’s first mission launches to the Moon on the uncrewed EM-1 test flight in 2020 on NASA’s Space Launch System (SLS) mammoth rocket.

Graphic outlining NASA’s Exploration Mission-1 with Orion human-rated spacecraft and Space Launch System rocket launch to the Moon in 2020. Credit: NASA  

The next step is to test, connect and integrate the two hardware components together with NASA’s Orion Crew Module stacked atop ESA’s Orion Service Module -  just like the  Apollo Command and Service modules. 

That effort begins now inside the Neil Armstrong Operations & Checkout (O & C) high bay at KSC where the crew module is being manufactured by prime contractor Lockheed Martin. 

The cylindrically shaped ESM arrived at the entrance to the O & C later the same day in flew here aboard the Antonov.  

“Come on in; we’ve been waiting for you! The @esa @AirbusSpace European Service Module is at the door of the @NASAKennedy Neil Armstrong Operations and Checkout Building!” tweeted Mark Kirasich, NASA’s Orion program manager.

“Engineers will complete functional checkouts to ensure all elements are working properly before it is connected to the Orion crew module. Teams will weld together fluid lines to route gases and fuel and make electrical wiring connections,” NASA reported.

The team is already hard at work and had already connected the Orion Crew Module Adapter to the top of ESM-1 by the day of the event using 192 bolts that “are needed to keep the structure together and withstand the immense forces of launch and spaceflight.”

The work by technicians to attach the Crew Adapter to ESM-1 with the 192 bolts was arduous and excruciating at the complex interfaces between them, explained Philippe Berthe, ESA’s ESM program manager for Orion. 

Laser measurements are used to continuously check that everything is perfectly aligned as required. 

This enables them to start working on connections for power, data and welding the pipes for the fluids such as water and fuel between the two main modules.

The Orion EM-1 crew module will be connected next to the Adapter and ESM-1. 

Orion EM-1 under construction at KSC. Credit: Ken Kremer/kenkremer.com/spaceupclose.com

For the thousands of miles (km) journey across the Atlantic Ocean the ESM “was packed in a custom-built container that keeps the environment inside within acceptable limits for transportation,” said ESA.

Prime contractor Airbus Defence & Space designed and manufactured the ESM at facilities in Bremen, Germany and Turin, Italy with over 20,000 parts provided by companies across ESA’s partner nations. The design builds on heritage from ESA’s now retired Automated Transfer Vehicle (ATV) which served as a cargo freighter for the ISS.

The 4-meter tall ESM provides power, propulsion, life support and consumables for the Orion crew capsule and the astronauts – including oxygen, nitrogen and water – on the first integrated flight with the SLS heavy lift booster on EM-1.  

Orion Spacecraft modules. Credits: ESA

The service module is equipped with four giant solar array wings that span 19 meters when deployed and provide enough electricity to power two three-bedroom homes, as well as the orbital maneuvering system. 

Each solar wing measures 2 m wide by 7 m in length. The four wings contain 15,000 solar cells to convert light into the electricity that powers Orion. 

Radiators and heat exchangers help maintain comfortable temperatures, “while the module’s structure is the backbone of the entire vehicle, like a car chassis,” according to ESA.

One of the key challenges was keeping the ESM spacecraft mass within tight limits.

“If you want to go far, you must go light,” explained Philippe Berthe.

"We have been on a 7-year diet to get everything included. So we took some short cuts for EM-1 because of the schedule.  But we have plans for the future modules to be compliant.”

“We still need to lose some weight for EM-2 and beyond."

"EM-2 is mass constrained. EM-1 was not.”

ESA is under contract with NASA to provide the service modules for EM-1 and EM-2 to fulfil their budgetary obligations to the International Space Station through 2024. 

The main engine ignites to provide the powerful burns to propel insert Orion into and out of lunar orbit and return to Earth.  The module is equipped with 33 engines altogether.

For this first service module the engine is a repurposed Space Shuttle Orbital Maneuvering System (OMS) engine.  It has flown 19 times in space before on three shuttle orbiters including Challenger, Discovery and Atlantis from 1984 to its last flight in space in 2002 on the STS-112 mission and provides 25.7 kN thrust.

What type main engines will power ESM in the future.

“Six more shuttle era OMSs engine are available for upcoming Orion mission,” Oliver Juckenhöefel, Airbus VP Bremen told Space UpClose in an interview at the KSC event.

We will continue using these OMS as its a lot of money to develop something new and they are available to use now.”

After the Orion crew module and service module are combined and mated the usit will be shipped to NASA’s Plum Brook facility for rigorous acoustic and vacuum testing in the world’s largest thermal vacuum chamber.

“NASA Glenn is looking forward to welcoming Orion for testing when it arrives at Plum Brook Station next summer,” says Janet Kavandi, Director of NASA's Glenn Research Center in Cleveland, Ohio and three-time shuttle astronaut.

Watch for Ken’s continuing onsite coverage of NASA, SpaceX, ULA, Boeing, Lockheed Martin, Northrop Grumman and more space and mission reports direct from the Kennedy Space Center, Cape Canaveral Air Force Station, Florida and Wallops Flight Facility, Virginia.

Stay tuned here for Ken's continuing Earth and Planetary science and human spaceflight news: www.kenkremer.com –www.spaceupclose.com – twitter @ken_kremer – email: ken at kenkremer.com

Dr. Kremer is a research scientist, journalist and photographer based in the KSC area.

………….

Ken’s photos are for sale and he is available for lectures and outreach events

Artists concept of NASA’s Orion spacecraft mission to the Moon. Credit: NASA

ESA Director General Jan Wörner and Ken Kremer (l) Space UpClose chat about the European Service Module unveiled at NASA’s Kennedy Space Center on Nov. 16, 2018

NASA’s InSight Lander Deploys Solar Panels after Surviving ‘7 Minutes of Terror’ Descent to Mars, Snaps 2nd Beautiful Photo

The Instrument Deployment Camera (IDC), located on the robotic arm of NASA's InSight lander, took this picture of the Martian surface on Nov. 26, 2018, the same day the spacecraft touched down on the Red Planet. The camera's transparent dust cover is still on in this image, to prevent particulates kicked up during landing from settling on the camera's lens. This image was relayed from InSight to Earth via NASA's Odyssey spacecraft, currently orbiting Mars. Credits: NASA/JPL-Caltech

Ken Kremer  --SpaceUpClose.com & RocketSTEM --27 November 2018

CAPE CANAVERAL, FL –  Mars newest resident, NASA’s InSight Lander, successfully deployed her twin solar arrays after surviving the harrowing ‘7 minutes of Terror’ descent through the planets thin atmosphere and safely soft landing on the smooth, vast expanse of the alien Red Planet locale named ‘Elysium Planitia’ – and snapped a second picture proving she was 'stayin alive'! 

“There’s a quiet beauty here. Looking forward to exploring my new home. #MarsLanding,” the InSight team tweeted along with that 2^nd incredibly clear and beautiful photo shown above - late Monday evening, Nov. 26 on landing day. 

Thus far the mission has been a complete 100% success!!

The new photo - taken  by the robotic arm camera - shows the robotic arm and other instruments on the landers deck.  Unlike the first photo (see below) it’s not obscured by lots of dust thrown up during the landing despite also being protected by a transparent lens cap.

InSight’s mission is to study the deep interior of the fourth rock from the sun and unravel Mars and Earth evolution since they formed 4.5 Billion years ago.  

“Our Mars Odyssey orbiter phoned home, relaying news from @NASAInSight indicating its solar panels are open & collecting sunlight on the Martian surface. Also in the dispatch: this snapshot from the lander's arm showing the instruments in their new home,” NASA tweeted. 

Unfurling the power generating and life-giving solar wings was the next critical required step towards ensuring her survival for a planned 2 year mission - after completing the harrowing entry, descent and landing propulsive touchdown at 2:54  p.m. EDT, 11:54 a.m. PST, Monday, Nov 26. Thereby concluding a 7 month, 301 million mile (484 million km) interplanetary journey from Earth.

“Aaah...soaking up the Sun with my solar panels. After a long flight, and thrilling #MarsLanding, it feels great to get a good stretch and recharge my batteries. (Like, literally.) It’s just what I’ll need to really start getting in tune with #Mars.”

Confirmation that the solar panels deployed and were ‘catching the suns rays’ finally came some five and a half hour after touchdown via signals relayed by NASA's Mars Odyssey orbiter at about 8:30 p.m. EST  5:30 p.m. PST Monday, Nov. 26, 0130 Nov. 27 GMT, after it overflew InSight’s landing site.

“NASA's InSight has sent signals to Earth indicating that its solar panels are open and collecting sunlight on the Martian surface,” NASA reported.

“NASA's Mars Odyssey orbiter relayed the signals, which were received on Earth at about 5:30 p.m. PST (8:30 p.m. EST). Solar array deployment ensures the spacecraft can recharge its batteries each day. Odyssey also relayed a pair of images showing InSight's landing site.”

"The InSight team can rest a little easier tonight now that we know the spacecraft solar arrays are deployed and recharging the batteries," said Tom Hoffman, InSight's project manager at NASA's Jet Propulsion Laboratory in Pasadena, California, which leads the mission, in a statement.

"It's been a long day for the team. But tomorrow begins an exciting new chapter for InSight: surface operations and the beginning of the instrument deployment phase."

NASA's InSight Mars lander acquired this image of the area in front of the lander using its lander-mounted, Instrument Context Camera (ICC). This annotated image was acquired on Nov. 26, 2018, Sol 0 of the InSight mission where the local mean solar time for the image exposures was 13:34:21. Each ICC image has a field of view of 124 x 124 degrees.  Credits: NASA/JPL-CalTech

InSight sports a wingspan of 19 feet 8 inches (6 meters) with solar panels deployed and a width of 5 feet 1 inch (1.56 meters) (lander deck diameter).

Each of the twin solar arrays are 7 feet (2.2 meters) wide. 

NASA's InSight Mars Lander in fully landed configuration in the clean room at Lockheed Martin Space in Littleton, Colorado. Once the solar arrays are fully deployed on Mars, they can provide 600-700 watts on a clear day, or just enough to power a household blender.  Credits: Lockheed Martin

On a clear Martian day the panels are estimates to provide about 600 to 700 -  enough to power a household blender and plenty to keep its instruments conducting science on the Red Planet, says the team.

“Even when dust covers the panels — what is likely to be a common occurrence on Mars — they should be able to provide at least 200 to 300 watts.”

Soon the team will unstow the robotic arm in preparation for placing the 2 international science instruments from Germany and France – HP³ and SEIS - onto the surface after using camera images to select the best spots for safety and science gathering.  

Artist's concept depicts NASA's InSight lander after it has deployed its instruments on the Martian surface in the Elysium Planitia region of Mars with smooth, flat ground that dominates InSight's landing ellipse.  Credits: NASA/JPL-Caltech

InSight in an international science mission. Loaded aboard are the two primary science instruments provided by European partners from France and Germany: The SEIS seismometer and  HP³ heat flow measuring instrument.

The SEIS seismometer instrument is equipped with a trio of incredibly precise seismometers to detect marsquakes and was provided by the Centre National d'Études Spatiales (CNES) - the French national space agency equivalent to NASA.  

The other instrument measuring heat flow from the Martian interior is provided by the German Aerospace Center (DLR) and is named Heat Flow and Physical Properties Package (HP³).  

The HP³ hammering mole will pound about 5 meters (16 feet) deep into Mars pulling the science heat flow cable tether along to make heat flow and temperature measurements.   It will pause multiple times along the way down to make detailed measurements at different depths of heat flow from the planets core. 

Meanwhile one of the briefcase sized Mars Cube One (MarCO) minisatellites which transmitted all the real time EDL data on landing day Monday, also snapped a farewell photo- see below from MarCO-B.

MarCO-B, one of the experimental Mars Cube One (MarCO) CubeSats, took this image of Mars from about 4,700 miles (6,000 kilometers) away during its flyby of the Red Planet on Nov. 26, 2018. MarCO-B was flying by Mars with its twin, MarCO-A, to attempt to serve as communications relays for NASA’s InSight spacecraft as it landed on Mars.  Credits: NASA/JPL-Caltech

Instead of over 5 hours from Mars Odyssey, it took only 8.1 minutes from MarCO, the time it takes for radio signals traveling at light speed from Mars to Earth across a distance of 91 million miles (146 million kilometers).

The pair traveled to Mars along with but separately from InSight following launch from Earth on a ULA Atlas V rocket 7 months ago.

InSight is NASA’s first mission to Mars surface in 6 years since the Curiosity rover safely touched down by the skycrane maneuver in 2012 - to begin a minimum 2 year long mission to study the heart of Mars and elucidate the deep interior of the Red Planet like never before. 

The landing location at Elysium Planitia just north of the equator is about 340 miles (550 kilometers) away from Gale Crater - where NASA's Curiosity rover landed in 2012. 

Elysium Planitia, a flat-smooth plain just north of the equator makes for the perfect location from which to study the deep Martian interior.  The landing site is centered at about 4.5 degrees north latitude and 135.9 degrees east longitude. The locations of other Mars landers and rovers are labeled.  Credit: NASA/JPL-Caltech

InSight, which stands for Interior Exploration using Seismic Investigations, Geodesy and Heat Transport,  is designed to study the deep interior of Mars.  

The $850 million seeks the fingerprints of the processes that formed the rocky planets of the solar system. 

InSight is funded by NASA’s Discovery Program of low cost, focused science missions along with the science instrument funding contributions from France and Germany.

Watch for Ken’s continuing onsite coverage of NASA, SpaceX, ULA, Boeing, Lockheed Martin, Northrop Grumman and more space and mission reports direct from the Kennedy Space Center, Cape Canaveral Air Force Station, Florida and Wallops Flight Facility, Virginia.

Stay tuned here for Ken's continuing Earth and Planetary science and human spaceflight news: www.kenkremer.com –www.spaceupclose.com – twitter @ken_kremer – email: ken at kenkremer.com

Dr. Kremer is a research scientist, journalist and photographer based in the KSC area.………….

Ken’s photos are for sale and he is available for lectures and outreach events

InSight Sticks Flawless Mars Landing –Transmits Terrific 1st Surface Touchdown Photo

@NASAInSight sent home its first photo after #MarsLanding on Nov. 26, 2018: InSight’s view is a flat, smooth expanse called Elysium Planitia, but its workspace is below the surface, where it will study Mars’ deep interior.

Ken Kremer  --SpaceUpClose.com & RocketSTEM --26 November 2018

CAPE CANAVERAL, FL –  Congratulations InSight !!! NASA’s newest Mars mission the Insight Lander sticks flawless Mars landing just moments ago at 2:54  p.m. EDT, 11:54 a.m. PST, following a 7 month, 301 million mile (484 million km) interplanetary journey from Earth - and now starts a 2-year mission to explore the Red Planet’s mysterious deep interior.

"Touchdown confirmed,” reported Christine Szalia of mission control at NASA’s Jet Propulsion Laboratory, Pasadena, CA, live on NASA TV webcast.

"InSight is on the surface of Mars!!”

Louds cheering and boisterous applause erupted immediately at JPL, throughout NASA and worldwide at the fantastic success and reality of InSight becoming NASA’s 8^th mission to successfully touchdown on Mars.  

“This is really fabulous,” said JPL’s chief engineer Rob Manning offering commentary on the webcast.  He has worked on all of NASA’s Mars landers and rovers for more than 20 years going back to Mars Pathfinder in the 1990s.

"Flawless!Everything we hoped for!”

Now resting safely on the surface of the Red Planet,  InSight can now begin at an alien locale called ‘Elysium Planitia’ InSight can now move forward to start her studies of the heart of Mars and its deep interior for the first time in human history.

InSight is the first mission to drill down deep below the surface and explore Mars deep interior.  All prior missions have scratched the surface of the fourth rock from the Sun by design for rock and soli samples. Now we go deep !! - to listen for Marsquakes and measure heat flow emanating from far below!  

"It was intense. And you could feel the emotion," said NASA Administrator Jim Bridenstine, at the JPL briefing. 

"It was very, very quiet when it was time to be quiet and of course very celebratory with every little new piece of information that was received. It's very different being here than watching it on TV, by far, I can tell you that for sure now that I've experienced both." 

InSight survived all the treachery and blazing temperatures of the ‘7 Minutes of Terror’!!

The $830  million spacecraft slammed into the top of Martian atmosphere at over 12,300 miles per hour (5.5 kilometers per second, 19,800 kph) and approximately 80 miles (about 128 kilometers)  altitude at around 2:47 p.m. EST, 11:47 a.m. PST and experienced blazes temperatures reaching up to 2700 degrees F (1500 C) – enough to melt steel – while protected from melting and utter destruction by the advanced heat shield.  

"We spend most of our time visualizing all these bad things that can happen, but sometimes things work out in your favor," said Manning.  "It certainly looked like it was a very successful and perfect landing."

Ultimately InSight used a preprogrammed series of maneuvers and operated autonomously throughout all of EDL EDL (Entry, Descent and Landing) with the heat shield, a supersonic parachute and 12 landing thrusters in succession to slow her descent to about 5 MPH (8 kph) at touchdown – brilliantly concluding the harrowing ‘7 Minutes of Terror’ at approximately 2:54  p.m. EDT, 11:54 a.m. PST.

@NASAInSight team members rejoice @NASAJPL after getting confirmation of a successful landing on Mars. #MarsLanding Images: https://flic.kr/s/aHskMTrajC

And just moments later NASA’s InSight transmitted her first post touchdown photo from the surface of the Red Planet at the landing site named Elysium Planitia – a sandy, flat plain with few rocks and chosen because it offered the best chances for a successful landing and science gathering.

The fisheye camera is covered by a dust cover accounting for the dusty image - that will soon be released to provide a crystal clear view of the landing site. 

“Our @NASAInSight spacecraft stuck the #MarsLanding!" 

"Its new home is Elysium Planitia, a still, flat region where it’s set to study seismic waves and heat deep below the surface of the Red Planet for a planned two-year mission,” NASA tweeted along with the 1^st photo.

“Congratulations to @NASA, @LockheedMartin, @ulalaunch, & all who made today's @NASAInSight #MarsLanding possible! This marks the 8th time the US has landed on Mars & the 1st mission to study its deep interior. Incredible milestone!” tweeted VP Mike Pence who called the team with congratulations seconds after the  successful landing. 

NASA InSight team rejoices at NASA JPL upon confirmation of successful landing and receipt of first photo from Mars surface.  Credit: NASA

NASA Administrator Jim Bridenstine attended the landing events at JPL and spoke and tweeted congratulation to the entire InSight team, all of the NASA family and space enthusiasts: 

"Today, we successfully landed on Mars for the eighth time in human history,” said NASA Administrator Jim Bridenstine. “InSight will study the interior of Mars, and will teach us valuable science as we prepare to send astronauts to the Moon and later to Mars. This accomplishment represents the ingenuity of America and our international partners and it serves as a testament to the dedication and perseverance of our team. The best of NASA is yet to come, and it is coming soon.”

Although NASA’s Mars Odyssey (MO) and Mars Reconnaissance Orbiter (MRO) Red Planet orbiters are the primary communications relays for InSight neither could be in place at the moment of landing to transmit real time data back to anxious engineers on Earth monitoring the health and status of InSight during the descent.

Thus NASA decided to send a pair of tiny experimental cubesats to carry out that critical chore- namely MarCO A and MarCO B.

And they performed marvelously !!  Otherwise we would have had to had more than 5 hours to learn InSights fate. 

Instead it took only 8.1 minutes – the time it takes for radio signals traveling at light speed from Mars to Earth across a distance of 91 million miles (146 million kilometers).

Confirmation of InSight’s successful touchdown and receipt of the terrific 1^st photo came via the1^st ever interplanetary cubesats which relayed the critical data in realtime- namely the pair of briefcase sized Mars Cube One (MarCO) minisatellites which traveled to Mars along with but separately from InSight following launch from Earth on a ULA Atlas V rocket 7 months ago.

Seconds later the two MarCO’s passed out of range as they continued flying past Mars. 

Together they had made an interplanetary trek of 301 million mile (484 million km) from Earth.

The next critical step is solar array deployment to provide life giving power to the planned two year long mission. 

Conformation should come in a few hours. 

Artist's concept depicts NASA's InSight lander after it has deployed its instruments on the Martian surface in the Elysium Planitia region of Mars with smooth, flat ground that dominates InSight's landing ellipse.  Credits: NASA/JPL-Caltech

InSight is NASA’s first mission to Mars surface in 6 years since the Curiosity rover safely touched down by the skycrane maneuver in 2012 - to begin a minimum 2 year long mission to study the heart of Mars and elucidate the deep interior of the Red Planet like never before. 

The landing location at Elysium Planitia just north of the equator is about 340 miles (550 kilometers) away from Gale Crater - where NASA's Curiosity rover landed in 2012. 

The Mars Odyssey orbiter took this image of the target landing site for NASA's InSight lander at flat-lying Elysium Planitia, centered at about 4.5 degrees north latitude and 136 degrees east longitude. The landing ellipse covers an area within which the spacecraft has about 99 percent chance of landing when targeted for the center of the ellipse. It is about 81 miles (130 kilometers) long, generally west to east, and about 17 miles (27 kilometers) wide. Credits: NASA/JPL-Caltech/ASU

Engineer’s conducted a final Trajectory Correction Maneuver known as TCM-6 late Sunday afternoon, Nov 25 to aim InSight more precisely to the center of the landing ellipse – hoping to shift it about 10 miles west from what TCM-5 accomplished. 

The spacecraft is on course to study Mars deep interior and Marsquakes for the first time in human history to elucidate how it evolved over 4.5 Billions years.  That history has been erased by natural progression and evolution on and inside Earth including plate tectonics and erosion of our planet's crust.  

InSight in an international science mission. Loaded aboard are the two primary science instruments provided by European partners from France and Germany: The SEIS seismometer and  HP³ heat flow measuring instrument.

The SEIS seismometer instrument is equipped with a trio of incredibly precise seismometers to detect marsquakes and to detect marsquakes was provided by the Centre National d'Études Spatiales (CNES) - the French national space agency equivalent to NASA.  

The other instrument measuring heat flow from the Martian interior is provided by the German Aerospace Center (DLR) and is named Heat Flow and Physical Properties Package (HP³).  

The HP³ hammering mole will pound about 5 meters (16 feet) deep into Mars pulling the science heat flow cable tether along to make heat flow and temperature measurements.   It will pause multiple times along the way down to make detailed measurements at different depths of heat flow from the planets core. 

Other contributions came from Switzerland, Great Brittan and Poland. 

After landing it will take about 2 to 3 months to carefully lift the two science instruments off the robots deck and deploy them onto Mars surface using the robotic arm.

InSight is equipped with two cameras.  One just below the rover deck is a fisheye. The other called IDD  is a color located at the terminus of the robotic arm – similar to Phoenix. 

The team will use the cameras to carefully and methodically selected the best spot for the instruments deployments. 

The instruments deployments will be deployed to the surface with a 7 foot long (2 m) robotic arm. 

There is also a weather station aboard to continuously measure Mars local temperatures, wind speeds and direction and pressures every day 24/7 for the first time on Mars.

The spacecraft is based on the design of NASA’s successful Mars lander which touched down safely back in 2008 which arrived at a slightly faster velocity of 12,500 miles per hour (5.6 kilometers per second).

Insight is also slightly heavier weighing about 1,340 pounds (608 kilograms) vs. 1,263 pounds (573 kilograms) when it slams into the atmosphere.

InSight also will be landing at a slightly higher elevation of “about 4,900 feet (1.5 kilometers) higher than Phoenix did, so it has less atmosphere to use for deceleration.”

The InSight team has been busy for 7 years to get the spacecraft ready – and the fruits of their labor was harvested with today’s spectacularly successful landing.

The landed probe has a mass of 794 pounds (360 kilograms). It sports a ‘wingspan of  19 feet 8 inches (6 meters) with solar panels deployed and a width of 5 feet 1 inch (1.56 meters) (lander deck diameter).

NASA's InSight Mars Lander in fully landed configuration in the clean room at Lockheed Martin Space in Littleton, Colorado. Once the solar arrays are fully deployed on Mars, they can provide 600-700 watts on a clear day, or just enough to power a household blender.  Credits: Lockheed Martin

InSight is funded by NASA’s Discovery Program of low cost, focused science missions along with the science instrument funding contributions from France and Germany.

Watch for Ken’s continuing onsite coverage of NASA, SpaceX, ULA, Boeing, Lockheed Martin, Northrop Grumman and more space and mission reports direct from the Kennedy Space Center, Cape Canaveral Air Force Station, Florida and Wallops Flight Facility, Virginia.

Stay tuned here for Ken's continuing Earth and Planetary science and human spaceflight news: www.kenkremer.com –www.spaceupclose.com – twitter @ken_kremer – email: ken at kenkremer.com

Dr. Kremer is a research scientist, journalist and photographer based in the KSC area.

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Ken’s photos are for sale and he is available for lectures and outreach events