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27.10.2021

Japanese H-2A rocket ready for launch with navigation satellite

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A Japanese H-2A rocket rolls out to its launch pad at the Tanegashima Space Center with the QZS 1R satellite. Credit: MHI

Japan is set to launch a replacement satellite Monday for a navigation spacecraft that has been in space since 2010, augmenting the U.S. military’s GPS network to provide more precise positioning and timing services over the Asia-Pacific region.

The new satellite will join Japan’s Quasi-Zenith Satellite System, or QZSS, which helps give users better estimates of their position, especially in cities and remote regions, where skyscrapers, trees and mountains can block signals from GPS satellites.

A Japanese H-2A rocket is set to deploy the new satellite, named QZS 1R or Michibiki 1R, to replace the first Michibiki spacecraft launched on a previous H-2A flight in September 2010. The QZS 1 satellite is beyond its original 10-year design life.

Liftoff of the 174-foot-tall (53-meter) H-2A rocket from Tanegashima Space Center in southwestern Japan is scheduled for a 15-minute window opening at 10:19:37 p.m. EDT Monday (0219 GMT; 11:19 a.m. Japan Standard Time on Tuesday).

The flight was delayed 24 hours because of a poor weather forecast for the mission’s first launch opportunity.

Japanese teams from Mitsubishi Heavy Industries, the H-2A’s prime contractor and operator, rolled the rocket from its assembly building to the launch pad around 15 hours before liftoff. The 1,600-foot (500-meter) journey on a mobile launch table took about 30 minutes to complete.

Once at the launch pad, the rocket was connected to ground electrical and propellant systems, allowing the H-2A team to start loading liquid hydrogen and liquid oxygen into the launcher’s first and second stage tanks.

QZS 1R, built by Mitsubishi Electric Corp., weighs about 4 metric tons (4.4 tons) fully fueled on top of the H-2A rocket.

The H-2A rocket is fitted with two strap-on solid rocket boosters, providing the majority of the 1.4 million pounds of thrust to push the launcher off the pad.

A cryogenic hydrogen-fueled LE-7A main engine powers the core stage, and another cryogenic engine — the LE-5B — is mounted to the rocket’s second stage.

Heading east after liftoff from Tanegashima, the rocket’s strap-on boosters will consume their propellant in about two minutes before jettisoning to fall into the Pacific Ocean. The core stage, covered in a blanket of orange insulating foam, will burn for about six-and-a-half minutes.

Then the upper stage’s LE-5B engine will ignite for two maneuvers to inject the QZS 1R satellite into an elliptical transfer orbit stretching more than 22,000 miles (about 36,000 kilometers) above Earth. Deployment of the spacecraft is scheduled about 28 minutes after liftoff.

The QZS 1R satellite during pre-launch testing. Credit: Japan’s Cabinet Office

Designed for a 15-year lifetime, the spacecraft will use its own propulsion system to reach a near-circular geosynchronous orbit with an average altitude of about 22,000 miles. The QZS 1R satellite will settle into an operational orbit tilted between 40 and 45 degrees to the equator, where it will circle the planet once every 24 hours.

The four-satellite QZSS fleet, entirely compatible with the GPS network, is positioned in orbits that loiter over Japan. GPS satellites, operated by the U.S. Space Force, circle Earth in lower orbits, meaning different spacecraft are visible in the sky at different times.

Projected against Earth’s surface, the QZS 1R satellite’s ground track will chart an asymmetric figure-eight pattern stretching from Japan to Australia as it alternates north and south of the equator. Three of the active quasi-zenith satellites are positioned in similar inclined geosynchronous orbits, and another one is parked in geostationary orbit over the equator, remaining in a fixed position over the planet.

Like the satellite it’s replacing, QZS 1R will be near-zenith, or almost straight up, in the Japanese sky for about eight hours each day. With a full complement of satellites, the constellation permits continuous coverage of Japan.

Michibiki means “guiding” or “showing the way” in Japanese.

It takes four GPS satellites to calculate a precise position on Earth, but a Michibiki satellite broadcasting the same L-band signals will give a receiver an estimate if there are not enough GPS satellites visible, or it can help produce a more accurate position calculation even with full GPS service.

Japan is developing three more quasi-zenith navigation satellites for launch by the end of 2023. The expanded fleet of seven spacecraft will give Japan complete navigation coverage over Japanese territory, independent of any GPS signals.

Quelle: SN

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Japan successfully launches replacement for decade-old navigation satellite

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A Japanese H-2A rocket blasts off from Tanegashima Space Center with the QZS 1R navigation satellite. Credit: MHI

A replacement for an aging satellite in Japan’s regional navigation network successfully launched Monday from Tanegashima Space Center aboard an H-2A rocket, heading to an orbit more than 20,000 miles above Earth.

The launch keeps Japan on track to establish an independent seven-satellite navigation network to provide continuous coverage over the country’s territory.

Rocketing away from Tanegashima on a 174-foot-tall (53-meter) H-2A rocket, the new navigation station streaked into space to join three other spacecraft in Japan’s Quasi-Zenith Satellite System, which augments positioning and timing signals from the U.S. military’s GPS network over the Asia-Pacific region.

The new satellite, named QZS 1R, took off at 10:19:37 p.m. EDT Monday (0219:37 GMT Tuesday) from Japan’s primary spaceport, located on Tanegashima Island in the southwestern part of the country.

The H-2A rocket carrying the QZS 1R, or Michibiki 1R, satellite into space lifted off with 1.4 million pounds of thrust from two strap-on solid rocket boosters and a hydrogen-burning core stage engine.

Heading east over the Pacific Ocean, the H-2A shed its spent booster casings nearly two minutes into the mission. The rocket’s aerodynamic payload shroud jettisoned more than four minutes into the flight, once the launcher soared above dense, lower layers of the atmosphere.

The QZS 1R satellite during pre-launch testing. Credit: Japan’s Cabinet Office

The core stage shut down and jettisoned about six-and-a-half minutes after liftoff, and the engine on the H-2A’s second stage ignited for two burns to inject the 4-metric ton (4.4-ton) QZS 1R spacecraft into an elliptical, or oval-shaped, transfer orbit.

The rocket’s guidance computer targeted an orbit with an apogee, or high point, more than 22,000 miles (about 36,000 kilometers) above Earth.

The launcher hit its marks and deployed the QZS 1R spacecraft into its intended orbit, according to Mitsubishi Heavy Industries, the H-2A rocket’s prime contractor.

The mission marked the 44th launch of an H-2A rocket, Japan’s most-used launch vehicle, since its debut in 2001. It was the 47th consecutive successful launch by the H-2 rocket family, which includes the more powerful H-2B launcher used for International Space Station resupply missions.

The flight was delayed 24 hours because of a poor weather forecast for the mission’s first launch opportunity.

Designed for a 15-year lifetime, the QZS 1R spacecraft will use its own propulsion system to reach a near-circular geosynchronous orbit with an average altitude of about 22,000 miles. The satellite will settle into an operational orbit tilted between 40 and 45 degrees to the equator, where it will circle the planet once every 24 hours.

QZS 1R will replace the QZS 1, or Michibiki 1, navigation satellite launched on a previous H-2A flight in 2010. Three other quasi-zenith navigation satellites launched in 2017.

The four-satellite QZSS fleet, entirely compatible with the GPS network, is positioned in orbits that loiter over Japan. GPS satellites, operated by the U.S. Space Force, circle Earth in lower orbits, meaning different spacecraft are visible in the sky at different times.

Projected against Earth’s surface, the QZS 1R satellite’s ground track will chart an asymmetric figure-eight pattern stretching from Japan to Australia as it alternates north and south of the equator. Three of the active quasi-zenith satellites are positioned in similar inclined geosynchronous orbits, and another one is parked in geostationary orbit over the equator, remaining in a fixed position over the planet.

Artist’s illustration of a driver using navigation signals from a Quasi-Zenith Satellite in an area where GPS satellite signals are partially blocked. Credit: National Space Policy Secretariat

Like the satellite it’s replacing, QZS 1R will be near-zenith, or almost straight up, in the Japanese sky for about eight hours each day. With a full complement of satellites, the constellation permits continuous coverage of Japan.

Michibiki means “guiding” or “showing the way” in Japanese.

It takes four GPS satellites to calculate a precise position on Earth, but a Michibiki satellite broadcasting the same L-band signals will give a receiver an estimate if there are not enough GPS satellites visible, or it can help produce a more accurate position calculation even with full GPS service.

Japan is developing three more quasi-zenith navigation satellites for launch by the end of 2023. The expanded fleet of seven spacecraft will give Japan complete navigation coverage over Japanese territory, independent of any GPS signals.

The launch of the H-2A rocket Monday from Tanegashima cleared the way for Japan’s space agency to resume preparations to launch a smaller Epsilon rocket from Uchinoura Space Center on the nearby Japanese island of Kyushu.

The Epsilon rocket was supposed to launch earlier this month with a batch of small technology demonstration satellites, but managers scrubbed two launch attempts due to a ground radar problem and unfavorable high-altitude winds.

After the delays, Japanese officials decided to ground the Epsilon rocket at Uchinoura and press ahead with the launch of the H-2A rocket from Tanegashima. Although the rockets take off from different spaceports, they share some ground support infrastructure, requiring spacing between the missions to reconfigure for the next launch.

Officials have not set a new target launch date for the Epsilon mission.

The next H-2A rocket is scheduled to launch in December with a commercial communications satellite for Inmarsat, a London-based provider of voice, video, and data relay services for ships, airplanes, and other mobile customers.

Quelle: SN

 

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