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(3 September 2020 – cosine) This morning at 03:51 CEST, a Vega launch vehicle carried two FSSCat nanosatellites into orbit, one of which houses the brand new HyperScout 2 instrument.

This advanced remote sensing system has two unique aspects. Firstly, it is equipped with both a spectral channel operating at visible wavelengths and a multispectral channel operating in the thermal infrared. Secondly, it incorporates an ultra-low-power artificial intelligence accelerator to perform processing tasks that were previously only possible on the ground.

The Small Spacecraft Mission Service Proof of Concept was launched into low Earth orbit this morning from the Guiana Space Center in Kourou on board an Arianespace Vega launcher. Together with 51 other small satellites, the rocket carried two 6U nanosatellites for the Federated Satellite System tandem mission (FSSCat) of the Nano-Satellite and Payload Laboratory (UPC NanoSat Lab) at the Technical University of Catalonia-BarcelonaTech (Universitat Politècnica de Catalunya).

HyperScout 2 (courtesy: cosine)

Poised to monitor sea ice and soil moisture in support of the Copernicus Land and Marine Environment Services, one of the nanosatellites is carrying the first instance of the HyperScout 2 instrument, developed and built by Dutch company cosine and its partners.

Extending FSSCat with a new version of cosine’s HyperScout instrument was made possible by support from the Earth Observation Directorate of the European Space Agency (ESA) and the Netherlands Space Office. For the first time, the already powerful onboard processing capabilities of HyperScout have been extended with multiband thermal infrared imaging, as well as the Myriad 2 Vision Processing Unit (VPU) from Intel. This allows artificial intelligence to run on the spacecraft much more efficiently than before, enabling in-orbit analyses that previously had to be executed on Earth.

Ф-sat-1

cosine led the development for the first artificial intelligence in-orbit experiment, Ф-sat-1, developed as part of ESA’s Ф-lab program, which is intended to drive space technology innovations using small satellites. The Ф-sat-1 experiment on the FSSCat mission demonstrates these combined capabilities for the first time, on board a small satellite.

For this demonstration, the Ф-sat-1 project consortium developed and trained a neural network to detect clouds in Earth observation data. Onboard differentiation between clouded and unobscured areas of the observations will significantly reduce the amount of data that needs to be sent to Earth. The University of Pisa (IT) developed the cloud detection algorithm, Sinergise (SI) developed the training dataset, and Ubotica (IE) provided the VPU and software testing.

cosine extended HyperScout’s spectral range with three thermal infrared bands, modified the electronics and software for the integration of the Myriad 2 VPU, and developed a new method for the onboard processing of the spectral data, which has resulted in the new HyperScout 2 instrument.

hyperscout 2

(courtesy: cosine)

After commissioning, HyperScout 2 will support FSSCat applications related to soil moisture, ice extent, ice thickness, as well as the detection of melting ponds over ice, and will demonstrate the Ф-sat-1 capabilities in orbit.

What will HyperScout 2 contribute?

“The HyperScout 2 data is going to be paired with the first HyperScout, which has been in orbit since early 2018. This will allow experimental programs to investigate the use of artificial intelligence on distributed platforms and on imagery acquired with shorter revisit times and which contains additional spectral information. This greatly increases the number and variety of scientific, operational and commercial applications that can be implemented using HyperScout,” explains Marco Esposito, Business Unit Manager Remote Sensing at cosine.

What’s next?

Additional HyperScout instruments are scheduled for launch in 2020 and 2021. The development of these new systems has been made possible by cosine’s 20 years of experience in designing advanced miniaturized space instrumentation and is based on strong collaborations with the partners involved.

The launch of HyperScout 2 showcases the intelligent solutions devised by cosine and its partners to overcome many of the volume, mass and power constraints resulting from the use of small satellite platforms. cosine makes these technologies accessible not only for space applications, but also for terrestrial ones, such as land surveillance, agriculture and air and water quality monitoring.

Our partners

The FSSCat consortium consists of DEIMOS Engenharia (PT), Universitat Politècnica de Catalunya (ES), Golbriak Space (ET), Tyvak International (IT) and cosine Remote Sensing (NL). The Ф-sat-1 consortium comprises cosine Remote Sensing (NL), University of Pisa (IT), Sinergise (SI) and Ubotica (IE). HyperScout was developed by cosine with consortium partners S&T, TU Delft, VDL and VITO with funding through the ESA GSTP program with contributions from the Dutch, Belgian and Norwegian national space organizations: Netherlands Space Office, BELSPO and Norsk Romsenter.

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SPAINSAT NG programme successfully passes Preliminary Design Review (PDR)

SPAINSAT NG programme successfully passes Preliminary Design Review PDR

(22 October 2020 – Thales) The SPAINSAT NG programme, owned and operated by Hisdesat, has successfully passed the preliminary design review (PDR) of the payloads and the full satellite, including PDR of Pacis 3 elements.

SPAINSAT NG is being manufactured by a consortium of four co-primes from Airbus in Spain and France, and Thales Alenia Space in Spain and France.

(courtesy: Hisdesat)

This important milestone confirms the soundness of the preliminary design and technical capabilities of the SPAINSAT NG satellite system.

It was achieved in the expected timeframe despite the difficulties caused by the Covid-19 health crisis, thanks to the commitment of all project teams who have continued to work at full capacity, combining remote work with face-to-face activity in the workplace.

“Successfully passing the satellite and payloads PDR, including Pacis 3, in the planned schedule shows the outstanding commitment and performances of all the teams working in this challenging program. I really much appreciate the efforts of anyone, from our main end customer and partner in the SPAINSAT NG PPP the Spanish Ministry of Defense and the Spanish Ministry of Industry, Trade and Tourism as lender of the program, till CDTI, ESA, Hisdesat, Airbus DS, Thales Alenia Space and the rest of the industry working in the program”, said Miguel A. García Primo, Hisdesat CEO.

The SPAINSAT NG programme comprises two satellites, SPAINSAT NG I and II which will be situated in different geostationary positions to operate in X, military Ka and UHF bands.

The communication payloads of both satellites are provided by Spanish industry, including integration of the Communications Module in Spain, a major step forward for Spanish industry. Airbus in Spain is responsible for the X band payload, while Thales Alenia Space in Spain is responsible for the UHF and Ka band payloads. Other companies from Spanish space industry are also involved. The UHF payload is a new development in Spain, positioning the country at the forefront of the few countries in the world with national systems in the military UHF band.

The satellites are based on the Eurostar Neo platform, Airbus’ new geostationary telecommunications satellite product, a significant evolution of the highly reliable and successful Eurostar series with an entire range of major innovations. SPAINSAT NG includes an X band fully flexible payload, employing active antennas with in orbit reconfiguration capability, an onboarddigital processor that will interconnect the X and Ka band payloads for cross-banding, and a dedicated high speed service link enabling fast re-configuration.

“The successful PDR is an important milestone for the development of the SPAINSAT NG programme, which is on-track and on-schedule thanks to the huge professionalism and commitment of the project team,” said Eduardo Bellido, CEO of Thales Alenia Space in Spain. “For the first time we lead in Spain the development and integration of the payloads for a programme like SPAINSAT NG, which positions us at the forefront of space technology with the capacity to integrate large space systems. This will allow us to take the lead of new payloads and instruments in future missions.”

“Spain has always been at the centre of Airbus’ space activities. This milestone represents an extraordinary achievement as it clearly validates we have succeeded in further developing our expertise and capabilities on new technologies,” said Fernando Varela, Head of Airbus Space in Spain. “We are now ready for the next stage and on track with the integration of the communication modules in our clean rooms.”

The development of SPAINSAT NG is supported by the Spanish Centre for the Development of Industrial Technology (CDTI) in the framework of a Partnership Project (PP) between the European Space Agency (ESA) and the satellite operator Hisdesat, called Pacis 3.

ESA Partnership Project supports the development and integration of innovative satellite payload elements, such as the reconfigurable transmit and receive X-band active antennas, and the deployable pallet with individually steerable Ka-band antennas. The Partnership Project will de-risk the partner’s investments to answer market needs through the development of sustainable end-to-end system up to in-orbit validation. It will also demonstrate novel pooling and sharing concepts to ultimately provide more affordable, flexible and secure communications services for governmental users in Europe.

“The Pacis 3 Partnership Project with Hisdesat is an important step within the Govsatcom Precursor project, part of ESA’s Space Systems for Safety and Security Program” stated Elodie Viau, ESA’s Director of Telecommunications and Integrated Applications. “Pacis 3 shows how the European space industry can respond to a globally emerging market of secure satellite communications. Partnership Projects, provide an effective and collaborative environment to introduce innovative systems and services, up to in-orbit validation.”

spainsat 2

(courtesy: Thales Alenis Space)

New AIT facility

The construction of a new clean room in Thales Alenia Space site in Madrid is progressing on-schedule to be ready for the SPAINSAT NG payload assembly, integration and test activities. This unique, cutting-edge facility in Spain will add more than 600 m2 clean area to the existing 2000 m2. With a free height of 12.5 meters in the inside, the facility is equipped with bridge cranes with lifting capacity up to 12 tons each, prepared for the integration of payloads and instruments of large dimensions for all type of space missions, spanning telecommunications, navigation, Earth observation and science.

The first of these New Generation SPAINSAT satellites will be launched at the end of 2023 and the second one a year later, guaranteeing the continuity of secure communications services.

The SPAINSAT NG satellites will have an operational lifetime of 15 years, remaining in service up to 2039.

About Airbus

Airbus is a global leader in aeronautics, space and related services. In 2019, it generated revenues of € 70 billion and employed a workforce of around 135,000. Airbus offers the most comprehensive range of passenger airliners. Airbus is also a European leader providing tanker, combat, transport and mission aircraft, as well as one of the world’s leading space companies. In helicopters, Airbus provides the most efficient civil and military rotorcraft solutions worldwide.

About Hisdesat

Hisdesat was born in 2001 as an operator of satellite government services to act fundamentally in the areas of defense, security, intelligence and external services. Since 2005, the company provides secure satellite communications services to government agencies in different countries and since September 2018, it provides Earth observation services with radar technology through the PAZ satellite, successfully launched on February 22nd. At present, the company is developing new constellations of maritime Satellite Traffic Information Satellites (AIS).

About Thales Alenia Space

Drawing on over 40 years of experience and a unique combination of skills, expertise and cultures, Thales Alenia Space delivers cost-effective solutions for telecommunications, navigation, Earth observation, environmental management, exploration, science and orbital infrastructures. Governments and private industry alike count on Thales Alenia Space to design satellite-based systems that provide anytime, anywhere connections and positioning, monitor our planet, enhance management of its resources, and explore our Solar System and beyond. Thales Alenia Space sees space as a new horizon, helping to build a better, more sustainable life on Earth. A joint venture between Thales (67%) and Leonardo (33%), Thales Alenia Space also teams up with Telespazio to form the parent companies’ Space Alliance, which offers a complete range of services. Thales Alenia Space posted consolidated revenues of approximately 2.15 billion euros in 2019 and has around 7,700 employees in nine countries.

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Orbcomm’s new, versatile communication device enables solution providers to easily add satellite connectivity to IOT applications

Orbcomms new versatile communication device enables solution providers to easily

(20 October 2020 – Orbcomm) Orbcomm today announced that it has launched the ST 2100, a state-of-the-art satellite communications device that enables solution providers to easily add satellite connectivity to their IoT applications and expand to dual-mode connectivity in remote areas with limited cellular coverage.

Orbcomm’s rugged and environmentally sealed ST 2100 is targeted for a number of vertical markets, such as fleet management, maritime and utilities, including fixed and mobile assets.

Orbcomm’s state-of-the-art satellite communications device enables solution providers to easily add satellite connectivity to their IoT applications. (courtesy: Orbcomm)

Orbcomm’s ST 2100 can be quickly and easily integrated into a variety of IoT applications with minimal development. Solution providers can leverage the versatile ST 2100 to provide backup satellite connectivity or serve as the sole communications device where cellular networks are unavailable or unreliable, including areas with high network congestion. The power-efficient device offers maximum reliability and security by allowing messages to be sent during temporary power loss. The device also includes a built-in navigation module that enables global reporting of location data to provide complete visibility for industrial IoT solutions. In addition, over-the-air satellite updates allow the ST 2100 to receive updated firmware versions without having to send a technician to the site, saving time and money to enable new features. With Orbcomm’s new device, solution providers can deliver ubiquitous and affordable dual-mode connectivity to customers, along with enhanced communication reliability, improved asset visibility and access to new markets and geographies.

“Orbcomm is continuing to focus on dual-mode innovation as a key driver to growth, and we’re pleased to launch our new ST 2100 for solution providers to cost-effectively add satellite connectivity to their IoT applications and quickly expand their market reach,” said Craig Malone, Orbcomm’s Executive Vice President of Product Development. “By leveraging Orbcomm’s strength in satellite IoT, we’ve created a robust, satellite communications device that enhances the reliability, performance and longevity of asset tracking and monitoring solutions nearly anywhere in the world.”

About Orbcomm

Orbcomm (Nasdaq: ORBC) is a global leader and innovator in the industrial Internet of Things, providing solutions that connect businesses to their assets to deliver increased visibility and operational efficiency. The company offers a broad set of asset monitoring and control solutions, including seamless satellite and cellular connectivity, unique hardware and powerful applications, all backed by end-to-end customer support, from installation to deployment to customer care. Orbcomm has a diverse customer base including premier OEMs, solutions customers and channel partners spanning transportation, supply chain, warehousing and inventory, heavy equipment, maritime, natural resources, and government.

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OSIRIS-REx spacecraft successfully touches asteroid

OSIRIS REx spacecraft successfully touches asteroid

(20 October 2020 – NASA) NASA’s Origins, Spectral Interpretation, Resource Identification, Security, Regolith Explorer (OSIRIS-REx) spacecraft unfurled its robotic arm Tuesday, and in a first for the agency, briefly touched an asteroid to collect dust and pebbles from the surface for delivery to Earth in 2023.

This well-preserved, ancient asteroid, known as Bennu, is currently more than 200 million miles (321 million kilometers) from Earth. Bennu offers scientists a window into the early solar system as it was first taking shape billions of years ago and flinging ingredients that could have helped seed life on Earth. If Tuesday’s sample collection event, known as “Touch-And-Go” (TAG), provided enough of a sample, mission teams will command the spacecraft to begin stowing the precious primordial cargo to begin its journey back to Earth in March 2021. Otherwise, they will prepare for another attempt in January.

NASA’s OSIRIS-REx mission readies itself to touch the surface of asteroid Bennu. (courtesy: NASA/Goddard/University of Arizona)

“This amazing first for NASA demonstrates how an incredible team from across the country came together and persevered through incredible challenges to expand the boundaries of knowledge,” said NASA Administrator Jim Bridenstine. “Our industry, academic, and international partners have made it possible to hold a piece of the most ancient solar system in our hands.”

At 1:50 p.m. EDT, OSIRIS-REx fired its thrusters to nudge itself out of orbit around Bennu. It extended the shoulder, then elbow, then wrist of its 11-foot (3.35-meter) sampling arm, known as the Touch-And-Go Sample Acquisition Mechanism (TAGSAM), and transited across Bennu while descending about a half-mile (805 meters) toward the surface. After a four-hour descent, at an altitude of approximately 410 feet (125 meters), the spacecraft executed the “Checkpoint” burn, the first of two maneuvers to allow it to precisely target the sample collection site, known as “Nightingale.”

Ten minutes later, the spacecraft fired its thrusters for the second “Matchpoint” burn to slow its descent and match the asteroid’s rotation at the time of contact. It then continued a treacherous, 11-minute coast past a boulder the size of a two-story building, nicknamed “Mount Doom,” to touch down in a clear spot in a crater on Bennu’s northern hemisphere. The size of a small parking lot, the site Nightingale site is one of the few relatively clear spots on this unexpectedly boulder-covered space rock.

“This was an incredible feat – and today we’ve advanced both science and engineering and our prospects for future missions to study these mysterious ancient storytellers of the solar system,” said Thomas Zurbuchen, associate administrator for NASA’s Science Mission Directorate at the agency’s headquarters in Washington. “A piece of primordial rock that has witnessed our solar system’s entire history may now be ready to come home for generations of scientific discovery, and we can’t wait to see what comes next.”

“After over a decade of planning, the team is overjoyed at the success of today’s sampling attempt,” said Dante Lauretta, OSIRIS-REx principal investigator at the University of Arizona in Tucson. “Even though we have some work ahead of us to determine the outcome of the event – the successful contact, the TAGSAM gas firing, and back-away from Bennu are major accomplishments for the team. I look forward to analyzing the data to determine the mass of sample collected.”

All spacecraft telemetry data indicates the TAG event executed as expected. However, it will take about a week for the OSIRIS-REx team to confirm how much sample the spacecraft collected.

Real-time data indicates the TAGSAM successfully contacted the surface and fired a burst of nitrogen gas. The gas should have stirred up dust and pebbles on Bennu’s surface, some of which should have been captured in the TAGSAM sample collection head. OSIRIS-REx engineers also confirmed that shortly after the spacecraft made contact with the surface, it fired its thrusters and safely backed away from Bennu.

“Today’s TAG maneuver was historic,” said Lori Glaze, Planetary Science Division director at NASA Headquarters in Washington. “The fact that we safely and successfully touched the surface of Bennu, in addition to all the other milestones this mission has already achieved, is a testament to the living spirit of exploration that continues to uncover the secrets of the solar system.”

“It’s hard to put into words how exciting it was to receive confirmation that the spacecraft successfully touched the surface and fired one of the gas bottles,” said Michael Moreau, OSIRIS-REx deputy project manager at NASA’s Goddard Space Flight Center in Greenbelt, Maryland. “The team can’t wait to receive the imagery from the TAG event late tonight and see how the surface of Bennu responded to the TAG event.”

The spacecraft carried out TAG autonomously, with pre-programmed instructions from engineers on Earth. Now, the OSIRIS-REx team will begin to assess whether the spacecraft grabbed any material, and, if so, how much; the goal is at least 60 grams, which is roughly equivalent to a full-size candy bar.

OSIRIS-REx engineers and scientists will use several techniques to identify and measure the sample remotely. First, they’ll compare images of the Nightingale site before and after TAG to see how much surface material moved around in response to the burst of gas.

“Our first indication of whether we were successful in collecting a sample will come on October 21 when we downlink the back-away movie from the spacecraft,” Moreau said. “If TAG made a significant disturbance of the surface, we likely collected a lot of material.”

Next, the team will try to determine the amount of sample collected. One method involves taking pictures of the TAGSAM head with a camera known as SamCam, which is devoted to documenting the sample-collection process and determining whether dust and rocks made it into the collector head. One indirect indication will be the amount of dust found around the sample collector head. OSIRIS-REx engineers also will attempt to snap photos that could, given the right lighting conditions, show the inside of the head so engineers can look for evidence of sample inside of it.

osiris 2

These images show the OSIRIS-REx Touch-and-Go Sample Acquisition Mechanism (TAGSAM) sampling head extended from the spacecraft at the end of the TAGSAM arm. The spacecraft’s SamCam camera captured the images on Nov. 14, 2018 as part of a visual checkout of the TAGSAM system, which was developed by Lockheed Martin Space to acquire a sample of asteroid material in a low-gravity environment. The imaging was a rehearsal for a series of observations that will be taken at Bennu directly after sample collection. (courtesy: NASA/Goddard/University of Arizona)

A couple of days after the SamCam images are analyzed, the spacecraft will attempt yet another method to measure the mass of the sample collected by determining the change in the spacecraft’s “moment of inertia,” a phrase that describes how mass is distributed and how it affects the rotation of the body around a central axis. This maneuver entails extending the TAGSAM arm out to the side of the spacecraft and slowly spinning the spacecraft about an axis perpendicular to the arm. This technique is analogous to a person spinning with one arm extended while holding a string with a ball attached to the end. The person can sense the mass of the ball by the tension in the string. Having performed this maneuver before TAG, and now after, engineers can measure the change in the mass of the collection head as a result of the sample inside.

“We will use the combination of data from TAG and the post-TAG images and mass measurement to assess our confidence that we have collected at least 60 grams of sample,” said Rich Burns, OSIRIS-REx project manager at Goddard. “If our confidence is high, we’ll make the decision to stow the sample on October 30.”

To store the sample, engineers will command the robotic arm to place the sample collector head into the Sample Return Capsule (SRC), located in the body of the spacecraft. The sample arm will then retract to the side of the spacecraft for the final time, the SRC will close, and the spacecraft will prepare for its departure from Bennu in March 2021 — this is the next time Bennu will be properly aligned with Earth for the most fuel-efficient return flight.

If, however, it turns out that the spacecraft did not collect enough sample at Nightingale, it will attempt another TAG maneuver on Jan. 12, 2021. If that occurs, it will touch down at the backup site called “Osprey,” which is another relatively boulder-free area inside a crater near Bennu’s equator.

OSIRIS-REx launched from Cape Canaveral Air Force Station in Florida Sept. 8, 2016. It arrived at Bennu Dec. 3, 2018, and began orbiting the asteroid for the first time on Dec. 31, 2018. The spacecraft is scheduled to return to Earth Sept. 24, 2023, when it will parachute the SRC into Utah’s west desert where scientists will be waiting to collect it.

Goddard provides overall mission management, systems engineering and the safety and mission assurance for OSIRIS-REx. Dante Lauretta of the University of Arizona, Tucson, is the principal investigator, and the University of Arizona also leads the science team and the mission’s science observation planning and data processing. Lockheed Martin Space in Denver built the spacecraft and is providing flight operations. Goddard and KinetX Aerospace are responsible for navigating the OSIRIS-REx spacecraft. OSIRIS-REx is the third mission in NASA’s New Frontiers Program, which is managed by NASA’s Marshall Space Flight Center in Huntsville, Alabama, for the agency’s Science Mission Directorate in Washington.

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