OrbitalHub

Wikipedia dixit:

“Mawrth Vallis (Mawrth means “Mars” in Welsh) is a valley on Mars in the Oxia Palus quadrangle at 22.3°N, 343.5°E with an elevation approximately two kilometers below datum. It is an ancient water outflow channel with light-colored clay-rich rocks. Mawrth Vallis is one of the oldest valleys on Mars. It was formed in and subsequently covered by layered rocks, from beneath which it is now being exhumed.

The Mawrth Vallis region holds special interest because of the presence of phyllosilicate (clay) minerals which form only if water is available, first identified in data from the OMEGA spectrometer on the European Space Agency’s Mars Express orbiter. Mars Reconnaissance Orbiter’s Compact Reconnaissance Imaging Spectrometer for Mars has identified aluminium-rich and iron-rich clays, each with a unique distribution. Some of the clays recently discovered by the Mars Reconnaissance Orbiter are montmorillonite and kaolinite, and nontronite. Since some clays seem to drape over high and low areas, it is possible that volcanic ash landed in an open body of water. On Earth such clays occur in (among other environments) weathered volcanic rocks and hydrothermal systems, where volcanic activity and water interact. Mawrth Vallis was at one point considered as a landing site for the Mars Science Laboratory, which ultimately landed at Gale Crater. Clay minerals easily preserve microscopic life on Earth, so perhaps traces of ancient life may be found at Mawrth. It is considered a potential landing site for the Mars 2020 rover.”

Video credit: ESA

Wikipedia dixit:

“Mars Reconnaissance Orbiter (MRO) is a multipurpose spacecraft designed to conduct reconnaissance and exploration of Mars from orbit. The US$720 million spacecraft was built by Lockheed Martin under the supervision of the Jet Propulsion Laboratory (JPL). The mission is managed by the California Institute of Technology, at the JPL, in La Cañada Flintridge, California, for the NASA Science Mission Directorate, Washington, D.C. It was launched August 12, 2005, and attained Martian orbit on March 10, 2006. In November 2006, after five months of aerobraking, it entered its final science orbit and began its primary science phase. As MRO entered orbit, it joined five other active spacecraft that were either in orbit or on the planet’s surface: Mars Global Surveyor, Mars Express, 2001 Mars Odyssey, and the two Mars Exploration Rovers (Spirit and Opportunity); at the time, this set a record for the most operational spacecraft in the immediate vicinity of Mars. Mars Global Surveyor and the Spirit rover have since ceased to function; the remainder remain operational as of March 2016.

MRO contains a host of scientific instruments such as cameras, spectrometers, and radar, which are used to analyze the landforms, stratigraphy, minerals, and ice of Mars. It paves the way for future spacecraft by monitoring Mars’ daily weather and surface conditions, studying potential landing sites, and hosting a new telecommunications system. MRO’s telecommunications system will transfer more data back to Earth than all previous interplanetary missions combined, and MRO will serve as a highly capable relay satellite for future missions.[…]

On September 29, 2006 (sol 402), MRO took its first high resolution image from its science orbit. This image is said to resolve items as small as 90 cm (3 feet) in diameter. On October 6, NASA released detailed pictures from the MRO of Victoria crater along with the Opportunity rover on the rim above it. In November, problems began to surface in the operation of two MRO spacecraft instruments. A stepping mechanism in the Mars Climate Sounder (MCS) skipped on multiple occasions resulting in a field of view that is slightly out of position. By December normal operations of the instrument was suspended, although a mitigation strategy allows the instrument to continue making most of its intended observations. Also, an increase in noise and resulting bad pixels has been observed in several CCDs of the High Resolution Imaging Science Experiment (HiRISE). Operation of this camera with a longer warm-up time has alleviated the issue. However, the cause is still unknown and may return.

HiRISE continues to return images that have enabled discoveries regarding the geology of Mars. Foremost among these is the announcement of banded terrain observations indicating the presence and action of liquid carbon dioxide (CO2) or water on the surface of Mars in its recent geological past. HiRISE was able to photograph the Phoenix lander during its parachuted descent to Vastitas Borealis on May 25, 2008 (sol 990).

The orbiter continued to experience recurring problems in 2009, including four spontaneous resets, culminating in a four-month shut-down of the spacecraft from August to December. While engineers have not determined the cause of the recurrent resets, they have created new software to help troubleshoot the problem should it recur.

On March 3, 2010, the Mars Reconnaissance Orbiter passed another significant milestone, having transmitted over 100 terabits of data back to Earth, which was more than all other interplanetary probes sent from Earth combined.

On August 6, 2012 (sol 2483), the orbiter passed over Gale crater, the landing site of the Mars Science Laboratory mission, during its EDL phase. It captured an image via the HiRISE camera of the Curiosity rover descending with its backshell and supersonic parachute.

NASA reported that the Mars Reconnaissance Orbiter, as well as the Mars Odyssey Orbiter and MAVEN orbiter had a chance to study the Comet Siding Spring flyby on October 19, 2014.

On July 29, 2015, the Mars Reconnaissance Orbiter was placed into a new orbit to provide communications support during the arrival of the InSight Mars lander mission on September 28, 2016. The maneuver’s engine burn lasted for 75 seconds.”

Video credit: NASA Jet Propulsion Laboratory

Credits: NASA

Software is a key component of present-day aerospace systems. Increased reliability is required from operating systems that host critical software applications.

Wind River’s VxWorks is a real-time operating system that is widely used in the aerospace industry. Missions using VxWorks include the Mars Reconnaissance Orbiter, the Phoenix Mars Lander, the Deep Impact space probe, Spirit and Opportunity Mars Exploration Rovers, and Stardust.

Mike Deliman, Senior Engineering Specialist at Wind River Systems, answered a few questions related to the new VxWorks MILS Platform 2.0.

DJ: What is VxWorks MILS Platform 2.0?
Mike Deliman: VxWorks MILS Platform 2.0 is a platform for creating systems that are evaluatable to high levels of the Common Criteria / Evaluated Assurance Level scale. VxWorks MILS 2.0 separation kernel is currently under evaluation by NIAP labs to an EAL 6+ level. The VxWorks MILS 2.0 Platform contains a separation kernel and technology to allow you to create multi-partitioned software systems where each partition can be evaluated to handle multiple independent levels of security (MILS) or to handle multiple levels of security (MLS). The long-and-short of it is similar to a VxWorks 653 flight OS, you can use a VxWorks MILS 2 platform to design a single platform that is capable of replacing multiple legacy systems. In other words, like a VxWorks 653 flight system, you can create a single modern system to replace multiple legacy systems, reducing Space, Weight and Power (SWaP) requirements.

DJ: What is a separation kernel and how did the concept make its way into software development for the aerospace industry?
M.D.: Separation Kernels allow you to take a single modern high-powered CPU and use it to replace several legacy systems. There are many examples of separation kernels and paradigms for their use. ARINC 653 defines a time and memory-space partitioning paradigm, services, and an API that must be provided (the Application Executive, or APEX). We have a platform – VxWorks 653 – that implements the ARINC 653 APEX separation and API. Separation Technologies are becoming quite popular, many are called “Hypervisors”. There are many Hypervisors out in cyberspace, the “Type 1” Hypervisors can all be thought of as forms of separation kernels. The Aerospace industry is a prime target for separation technologies because of the need to reduce the “SWaP” factors.

DJ: How does the VxWorks MILS separation kernel improve the reliability of aerospace applications?
M.D.: The VxWorks MILS separation kernel could be used to allow a single satellite to fulfill multiple missions. For instance, there may be a number of sensors and experiments on board, some for civilian / educational interests, some for NASA, some for research entities, perhaps some for the USAF. A MILS kernel could be used to collect, encode, and steer data safely, providing assurance that the data will not be mixed until it is in a state deemed “safe” for mixing. A satellite running a MILS separation kernel to handle such data wrangling could combine and satisfy multiple mission masters. If I were to be asked to design such a system, I would most likely recommend a flight computer separate from the science computer. Even if the science and flight SW were to share a single CPU, the separation technology would help ensure that no problems on any science application could affect any of the other science applications or any flight applications. In this way the flight system would be protected from anomalous events in the science packages, and the overall system would benefit from improved reliability.

DJ: John Rushby introduced the concept of separation kernel in order to provide multilevel secure operation on general-purpose multi-user systems. Do software applications developed for the aerospace industry (and I have in mind software running on micro-controllers) have the level of complexity that would require a separation kernel?
M.D.: Concentrating on the micro-controller aspect, no, most single (federated) systems running one micro-controller (or even several) do not even need a 32-bit processor dedicated to their operation. However, with a proper separation kernel and time-sliced architecture, you could use one modern high-speed 32-bit CPU to control and monitor a large number of smaller systems, and ensure any faults occurring on those control-and-monitor loops are contained. And as noted above, in a system used to satisfy requirements of multiple masters (agencies), MILS-style data separation may be the only way to keep satellite weight within limits and provide the information assurance the agencies require.

DJ: What features make the VxWorks operating system reliable and secure?
M.D.: Focusing on the VxWorks family of operating systems and the VxWorks OS API, VxWorks has been used in millions of devices over more than two decades of service, in applications as simple as MP3 players and as complex as autonomous space exploring robots, and as life-critical as telerobotic surgeons. There is no way a software company could anticipate the wide range of use that our customers have dreamed up and implemented. The VxWorks family of OSes share a common ancestry of code and all can benefit from bugs discovered and fixed in any of the family line.
 
Focusing on the VxWorks MILS platform, the separation kernel was designed expressly in compliance with the SKPP (the Protection Profile for separation kernels), with a focus on controlling embedded applications that require some degree of real-time control.

DJ: What are the features that make VxWorks a real-time operating system?
M.D.: Determinism is king in the real-time world. The ability to react to events in the real world with a high degree of determinism is what gives VxWorks its hard real-time responsiveness. This hard-determinism is carried over into all of the VxWorks family line, including our separation kernels and VxWorks SMP.

DJ: What toolchain is shipped with VxWorks? What programming languages are supported by the toolchain?
M.D.: Depending on the VxWorks package, one or more toolchains may be supplied and supported. For the most part, various versions of the Wind River Complier (formerly “Diab”), and various versions of the Gnu tools are supplied / supported with VxWorks. For the VxWorks MILS 2 platform we use a couple of versions of the GNU tool chains, specially modified for the parts they are used to build.

DJ: What hardware is targeted by the platform? Is an actual board necessary for development of applications or is an emulated target environment available for software engineers?
M.D.: Specifically, chips we are targeting include the following:
– Freescale 8641D (CW VPX6-165)
– Freescale 8548 (Wind River SBC8548)
– Intel Core 2 Duo (Supermicro C2SBC-Q)
– Freescale P2020, P1011, P4080 (future)
– Intel Atom, Nehalem (future)
We currently support Simics as the only simulation environment available for the VxWorks MILS platform.

Wind River Systems was founded in Berkeley, California in 1981. Intel bought Wind River Systems for a reported $884 million in July 2009. VxWorks real-time operating system is one of the Wind River flagship products.

Credits: NASA/JPL

Carnival of Space #84 is hosted by Next Big Future.

This week you can read about space solar power, oceans on Venus, Mars rovers, the top ten astronomy pictures of 2008, the AGU Conference, and many more interesting topics.

OrbitalHub has submitted an update on the Mars Reconnaissance Orbiter science mission.

Credits: NASA/JPL

The Mars Reconnaissance Orbiter (MRO) has completed the first phase of its science mission. During this phase, the orbiter returned seventy-three terabits of science data to Earth, which is more than all earlier Mars missions combined. The next phase of the MRO mission will take two years.

The list of scientific discoveries and observations made by MRO is stunning. We know now that Mars has a long history of climate change and that water was present in liquid form on its surface for hundreds of millions of years.

Signatures of a variety of watery environments have been observed, so future missions will be aware of locations that might reveal evidence of past life on Mars, if it ever existed.

MRO has imaged nearly forty percent of the Martian surface at such a high resolution that house-sized objects can be seen in detail. MRO has also conducted a mineral survey of the planet, covering sixty percent of its surface. Global weather maps were assembled using the data returned by MRO, and profiles of the subsurface and the polar caps have been put together using the radar mounted on MRO.

Credits: NASA/KSC

“These observations are now at the level of detail necessary to test hypotheses about when and where water has changed Mars and where future missions will be most productive as they search for habitable regions on Mars,” said Richard Zurek, Mars Reconnaissance Orbiter project scientist.

The images returned by MRO have been used by the Phoenix team to change the spacecraft’s landing site, and will help the NASA scientists select landing sites for future missions, like the Mars Science Laboratory (MSL).

Another role played by MRO was to relay commands to and to return data from the Phoenix lander during the five months the lander was operational on the Martian surface. MRO shared this task with the Mars Odyssey Orbiter.

MRO lifted off on August 12, 2005, from launch Complex 41 at Cape Canaveral Air Force Station. The cruise phase of the mission lasted seven months, the spacecraft reaching Mars orbit on March 10, 2006, after traveling on an outbound arc intercept trajectory.

MRO entered the final low orbit suited for science-data collection on November 2006, after slowing down in the Martian atmosphere by using aerobraking for five months. The first phase of the mission consisted in gathering information about Mars, and the remaining time left of its operational life will be dedicated mainly to using the spacecraft as a communication relay.

Credits: NASA/KSC

The declared goals of the MRO mission are: to determine whether life ever arose on Mars, to characterize the climate of Mars, to characterize the geology of Mars, and to prepare for human exploration.

The launcher of choice for the MRO mission was the Atlas V-401 launch vehicle, the smallest of the Atlas V family. This was the first launch of an Atlas V on an interplanetary mission.

The Atlas V-401 is a two-stage launch vehicle that does not use solid rocket boosters. The Atlas V-401 is fifty-seven meters tall and has a total mass at liftoff of 333,000 kg. Out of this, about 305,000 kg is fuel. In order to reach Mars orbit, MRO was accelerated to 11 km per second.

The first stage of the Atlas V, the Common Core Booster, is powered by liquid oxygen and RP-1. For the MRO mission, the first stage used a RD-180 engine. The RD-180 engine has an interesting story. It is a Russian-developed rocket engine, derived from the RD-170 used for the Zenit rockets.

Credits: NASA/JPL/KSC/Lockheed Martin Space Systems

Rights to use the RD-180 engine were acquired by General Dynamics Space Systems Division (later purchased by Lockheed Martin) in the early 1990s. The engine is co-produced by Pratt & Whitney and all production to date has been in Russia. According to Pratt & Whitney, RD-180 delivers a ten percent performance increase over current operational U.S. booster engines.

The stage weighs approximately 305,000 kg at launch and it provides about four million Newton of thrust for four minutes.

The upper stage of the Atlas V is the Centaur Upper Stage Booster. The Centaur is powered by liquid oxygen and liquid hydrogen. In the case of the MRO mission, it provided the remaining energy necessary to send the spacecraft to Mars.

The payload fairing used for the MRO mission was four meters in diameter. The role of the payload fairing was to protect the spacecraft from the weather on the ground as well as from the dynamic pressure during the atmospheric phase of the launch.

Lockheed Martin Commercial Launch Services developed the Atlas V as part of the US Air Force Evolved Expendable Launch Vehicle (EELV) program.

There are six science instruments, three engineering instruments, and two science-facility experiments carried by the MRO. The low orbit on which MRO is operating allowed the observation of the surface, atmosphere, and subsurface of Mars in unprecedented detail.

The science instruments are the HiRISE camera (High Resolution Imaging Science Experiment), the CTX camera (Context Camera), the MARCI camera (Mars Color Imager), the CRISM spectrometer (Compact Reconnaissance Imaging Spectrometer for Mars), the MCS radiometer (Mars Climate Sounder), and the SHARAD radar (SHAllow RADar).

Credits: HiRISE/MRO/LPL/NASA

The HiRISE camera provided the highest-resolution images from orbit to date, while the SHARAD can probe the subsurface using radar waves in the 15-25 MHz frequency band (these waves can penetrate the Martian crust up to one kilometer).

The engineering instruments assist the spacecraft navigation and communication. The Electra UHF Communications and Navigation Package is used as a communication relay between the Earth and landed crafts on Mars. The Optical Navigation Camera serves as a high-precision camera to guide incoming spacecrafts as they approach Mars. The Ka-band Telecommunications Experiment Package demonstrated the use of the Ka-band for power effective communications.

The science facility experiments are the Gravity Field Investigation Package, used for mapping the gravity field of Mars, and the Atmospheric Structure Investigation Accelerometers, which helped scientists understand the structure of the Martian atmosphere.

For more details on the MRO scientific payload, you can check out the dedicated page on the MRO mission web site.

The MRO was built by Lockheed Martin for NASA’s Jet Propulsion Laboratory in California. Fully loaded, the spacecraft had a mass of almost two tons. The spacecraft carried 1,149 kg of propellant for trajectory correction maneuvers and for the burns needed for the Mars capture.

Credits: NASA/JPL

The main bus of the spacecraft presents two massive solar arrays that can generate 2,000 W of power. On top, the high-gain antenna is the main means of communication with both Earth and other spacecrafts. The SHARAD antenna is the long pole behind the bus.

Other visible features are the HiRISE camera, the Electra telecommunications package, and the Context Imager (CTX).

You can visit the home page of the MRO mission on the NASA web site.