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China Space Military:Recon, Satcom, Navi, ASAT/BMD, Orbital Vehicle, SLV, etc.

Hey do you know anything about the atomic clock on the Beidou 3? And how does it compare with the current generation clocks on GPS and Galileo?

http://news.xinhuanet.com/english/2017-11/06/c_136731697.htm
http://gpsworld.com/china-launches-20th-beidou-satellite-with-hydrogen-clock/
http://www.fyjs.casic.cn/n355677/n661085/c5471157/content.html

It is hard to compare that because I do not have accurate data of atomic clocks on GPS and Galileo. I only know that part of Beidou 2 and all Beidou 3 satellites installed the Chinese Rubidium standard. And Beidou 3 satellites also installed the Chinese Hydrogen masers clock.

I believe we can find many valuable information from IEEE, but the journals on that are too expensive.
http://ieeexplore.ieee.org/document/7546720/
 
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Hey do you know anything about the atomic clock on the Beidou 3? And how does it compare with the current generation clocks on GPS and Galileo?

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The above data was collected in 2015.

The clocks installed on Beidou 3 has a day stability reaches the order of magnitude of E-15, which is comparable to the stability of Rb clocks installed on GPS Block IIF as well as the forthcoming GLONASS-K2, better than the clocks installed on Galileo.
 
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China launches remote sensing satellites SuperView-1 03/04
Source: Xinhua| 2018-01-09 12:32:25|Editor: Yang Yi

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China launches SuperView-1 03/04, a pair of 0.5-meter high-resolution remote sensing satellites, from the Taiyuan Satellite Launch Center in north China's Shanxi Province, Jan. 9, 2018. The satellites blasted off Tuesday on the back of a Long March 2D rocket. The mission aims to promote the country's commercial use of high-resolution remote sensing satellites. The satellites, which are able to provide commercial images at 0.5-meter resolution, are expected to offer remote sensing data to customers worldwide and provide services to land and resource surveys, mapping, environmental monitoring, finance and insurance as well as the Internet industry. (Xinhua/Cao Yang)

TAIYUAN, Jan. 9 (Xinhua) -- China launched a pair of 0.5-meter high-resolution remote sensing satellites Tuesday from the Taiyuan Satellite Launch Center in north China's Shanxi Province.

The satellites, SuperView-1 03/04, blasted off at 11:24 a.m. Beijing time on the back of a Long March 2D rocket, according to the center.

The mission aims to promote the country's commercial use of high-resolution remote sensing satellites.

The satellites, which are able to provide commercial images at 0.5-meter resolution, are expected to offer remote sensing data to customers worldwide and provide services to land and resource surveys, mapping, environmental monitoring, finance and insurance as well as the Internet industry.

The satellites were developed by China Aerospace Science and Technology Corporation.

It is the second launch of the corporation's commercial remote sensing satellites, followed by the launching of SuperView-1 01/02 in December 2016.

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According to CASC report the temperature is -20 celsius. This is what happen when the reporter splash warm water at Taiyuan Launch Center.

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China pitching for buyers of high-res satellite imagery
A state-owned aerospace conglomerate is wooing customers at trade shows for photos at reportedly 1-meter spatial resolution or even higher

By Asia Times staff | January 9, 2018 2:46 PM (UTC+8)

The state-owned aerospace conglomerate China Aerospace Science and Technology Corporation (CASC) has started wooing overseas buyers of satellite photos at reportedly 1-meter spatial resolution or even higher at a number of trade shows and exhibitions, such as the Army-2017 Defense Exhibition held in Moscow.

These commercially available photos were all shot with China’s various indigenous imaging satellites that are tailor-made to suit the needs of civil and commercial use, such as the CASC-made VRSS-2 remote sensing satellite launched last October for Venezuela.

Hong Kong-based Kanwa Defense Review reports that CASC will soon start marketing the SuperView-1 internationally, the first generation of an ultra-mobile, lightweight (560 kilograms) imaging satellite family with improved sensor resolution as high as 0.5 meter in panchromatic format and 2 meters in multispectral format.

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A collage of images taken by the SuperView-1 satellite. Photo: CASC

One satellite can churn out and store data of a total of 700,000 square kilometers per day, and a network of 16 such satellites can collect images of any given location on the planet at least once daily throughout their designed service life of no less than eight years, according to CASC.

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A satellite image of a stadium in Vienna. Photo: CASC

Two such satellites have been circling the Earth in a Sun-synchronous orbit 530km above the ground since December 2016.

Previously this market was dominated by a handful of US and European imagery and geospatial content vendors such as DigitalGlobe, Planet Labs and Spot Image. which because of their stranglehold on the market, could sell their products with a fat markup.

CASC has not disclosed a specific price regime but it’s believed that the Chinese company will seek to undercut existing rivals to build up market share, and prices will depend on resolution and purchase quantity. It’s also said that discounted subscription fees are on offer for long-term customers such as governmental agencies, academic institutions and private entities such as energy firms.

Meanwhile, military analyst Andrei Chang has said that Beijing has been able to keep a close eye on military installations and deployments in Taiwan, Japan, India and the Korean Peninsula on the strength of the legion of satellites it has launched throughout the years.

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A 30cm class satellite image of Shanghai’s Lujiazui financial district released by DigitalGlobe.

DigitalGlobe has been selling 30cm resolution imagery since 2015.


China pitching for buyers of high-res satellite imagery | Asia Times
 
BeiDou map to be accurate within one meter
China Plus Published: 2018-01-10 13:59:50

The BeiDou Navigation Satellite System is touting the accuracy of its new system, suggesting its precise enough to have food delivered directly to your table.

Opening the BeiDou laboratory in Chongqing, BeiDou claims its system is now accurate within one meter, reports the Chongqing Evening News.

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Undated photo shows a model of the BeiDou Satellite Navigation system on exhibition in Zhuhai, Guangdong Province. [File photo: Xinhua]

The new laboratory focuses on improving the accuracy of navigation and setting up database for smart city building, according to a head of the lab who refused to divulge his name.

The BeiDou map will be available on smartphones from May 1st.

"The high accuracy of BeiDou map navigation also lays foundation for the future development of unmanned driving," said the lab chief.

First launched in 2000, BeiDou is considered China's alternative to US-based GPS. Since 2012, BeiDou has been able to provide navigation, time and text messaging services across the Asia and Pacific region.
 
"X-51" :D:tup:

中航透露成都所某天地往返高超音速型号于2017年底定型成功!

2018-01-11 10:03:02

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天地往返高超音速飞行器,中国X-51

中航透露成都所天地往返高超音速无人飞行器某型号于2017年底定型,4次试飞,外界推测应该是中国版X-51。美军X-51试飞四次以上均未能实现以6倍音速飞行300秒的初始计划而前途难料,没想到中国只试飞4次即定型,这标志着中国一超级平台超越美国进入实战部署,具有划时代的意义。。

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中国X-51

根据中国航空报的新闻报道说,这架飞行器2015年已经交付试飞中心,在2017年底已经在部队批量装备并组织定型,文章还透露了50天里才组织了4次试飞,这肯定不是普通有歼20之类四代机,绝对是天地往返的亚轨道飞行器。因为战斗机要进行上千次的测试,只有亚轨道飞行器才可能试验次数这么少。

根据1月9日航空报消息,2017年年初就定下的年内必须定型的目标,最终定型目标完成。

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中国X-51

2017年年底,某型号定型审查顺利通过。官文说,项目历经数年,经此一役,总算尘埃落定。

领军人物来自成都飞机设计研究所,根据航空报的人物简历,总负责人现为空天技术与无人机设计研究部临近空间飞行器总体研究室主任,高级工程师。

官方称,成都所在“十一五”全面承担了某试验样机的总体设计工作,在短短4年内完成了总体设计、总体装配,并进行了样机外场飞行试验。

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外界猜测效果图

成都所设计的亚轨道无人飞机,具有概念新、布局新和空天结合的特点,突破了总体、结构、环控防热一体化设计技术,急剧变化的重心与大范围变化的焦点匹配设计技术,严酷热环境下的全机多波段保形天线综合设计技术,全机有效载荷综合设计技术,填补了国内空白。这也说明中国紧随美国X-51的研究步伐。

成都所除了在歼20研制上大放异彩外,近年在空天技术特别是临近空间领域的创新开拓作出了突出贡献。

根据相关资料,成都所这种飞行器是一种临近空间高速巡航飞行器,可重复使用的复合结构。

首飞2015年09月18日,当时航空报称试飞中心某型机首次试飞圆满成功,就是指的这架亚轨道飞行器。

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X-51

X-51A高超音速无人飞行器是美国空军研制的超燃冲压发动机验证机--乘波者。它由波音公司与普惠公司共同开发,由一台JP-7碳氢燃料超燃冲压发动机推动,设计飞行马赫数在6~6.5之间。

X-51的第一次试飞是在2010年5月,成功飞行了200秒;而之后在2011年6月进行的第二次试飞则以失败告终。2013年5月1日,第4次试飞成功,以5.1倍音速飞行了约3分半钟。

X-51计划的终极目标就是要发展一种比美国原武器库中任何一种导弹的速度都要快5倍以上,可以在1小时内攻击地球任意位置目标的新武器。

早就相传成飞在搞空天项目,没想到2018年初航空报就侧面证实了,而且已经初步定型。

这种高超音速飞行器反应速度快,只需要10几分钟就可飞临一千公里外的目标,突防能力相当强,再加上亚轨道飞行,超过现有防空武器射高,现有的防空武器对它基本无计可施。

21世纪是乘波体与战略核潜艇的天下,其他都是次要的。人类的未来最厉害的攻击性武器就是它,乘波体可以飞行于大气边缘。2018年,成飞的乘波体已经可以亮剑了!

Amongst China's most significant military achievement in 2017 :partay:

http://www.cannews.com.cn/2018/0109/170270.shtml
 
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China sends twin BeiDou-3 navigation satellites into space
Source: Xinhua| 2018-01-12 11:49:25|Editor: Mengjie



XICHANG, Sichuan Province, Jan. 12 (Xinhua) -- China on Friday sent twin satellites into space on a single carrier rocket, as part of efforts to enable its BeiDou system to provide navigation and positioning services to countries along the Belt and Road by the end of 2018.

The Long March-3B carrier rocket took off from Xichang Satellite Launch Center in the southwestern province of Sichuan at 7:18 a.m.

This is the first launch of the BeiDou satellites in 2018, which will see intensive launches throughout the year.

The twin satellites are coded the 26th and 27th satellites in the BeiDou Navigation Satellite System (BDS).

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China launches land exploration satellite
Source: Xinhua| 2017-12-23 12:48:51|Editor: Lifang



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China launches a land exploration satellite into a preset orbit from the Jiuquan Satellite Launch Center in the Gobi desert, northwest China's Gansu Province, Dec. 23, 2017. The satellite is mainly used for remote sensing exploration of land resources. A Long March-2D rocket carried the satellite into space. (Xinhua/Zhen Zhe)

JIUQUAN, Dec. 23 (Xinhua) -- China launched a land exploration satellite into a preset orbit from the Jiuquan Satellite Launch Center in the Gobi desert at 12:14 p.m. Saturday Beijing Time.

The satellite is mainly used for remote sensing exploration of land resources.

A Long March-2D rocket carried the satellite into space.

The launch was the 259th mission of the Long March rocket series.

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1月13日15点10分,长征二号丁运载火箭在我国酒泉卫星发射中心发射升空,成功将陆地勘查卫星三号送入预定轨道。
At 15:10 on January 13, the Long March 2D carrier rocket at the Jiuquan Satellite Launch Center in China successfully sent the Land Survey Satellite No. 3 into its orbit.

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A figure from the letter shows how the Micius satellite transfers quantum keys across vast distances.

China has the quantum technology to perfectly encrypt useful signals over distances far vaster than anyone has ever accomplished, spanning Europe and Asia, according to a stunning new research letter.

Bits of information, or signals, pass through people's houses, the skies overhead and the flesh of human bodies every second of every day. They're television signals and radio, as well as private phone calls and data files.

Some of these signals are public, but most are private — encrypted with long strings of numbers known (presumably) only to the senders and receivers. Those keys are powerful enough to keep the secrets of modern society: flirty text messages, bank-account numbers and the passwords to covert databases. But they're brittle. A sufficiently determined person, wielding a sufficiently powerful computer, could break them.

"Historically, every advance in cryptography has been defeated by advances in cracking technology," Jian-Wei Pan, a researcher at the University of Science and Technology of China and author on this research letter, wrote in an email. "Quantum key distribution ends this battle."

Quantum keys are long strings of numbers — keys for opening encrypted files just like the ones used in modern computers — but they're encoded in the physical states of quantum particles. That means they are protected not only by the limits of computers but the laws of physics.

Quantum keys cannot be copied. They can encrypt transmissions between otherwise classical computers. And no one can steal them — a law of quantum mechanics states that once a subatomic particle is observed, poof, it's altered — without alerting the sender and receiver to the dirty trick. [What's That? Your Physics Questions Answered]

And now, according to a new letter due for publication today (Jan. 19) in the journal Physical Review Letters, quantum keys can travel via satellite, encrypting messages sent between cities thousands of miles apart.

The researchers quantum-encrypted images by encoding them as strings of numbers based on the quantum states of photons and sent them across distances of up to 4,722 miles (7,600 kilometers) between Beijing and Vienna — shattering the previous record of 251 miles (404 km), also set in China. Then, for good measure, on Sept. 29, 2017, they held a 75-minute videoconference between researchers in the two cities, also encrypted via quantum key. (This videoconference was announced previously, but the full details of the experiment were reported in this new letter.)

The satellite
This long-distance quantum-key distribution is yet another achievement of the Chinese satellite Micius, which was responsible for smashing a number of quantum-networking records in 2017. Micius is a powerful photon relay and detector. Launched into low Earth orbit in 2016, it uses its fine lasers and detectors to send and receive packets of quantum information — basically, information about the quantum state of a photon — across vast stretches of space and atmosphere.

"Micius is the brightest star in the sky when it is passing over the station," Pan wrote to Live Science. "The star is [as] green as the beacon laser [that Micius uses to aim photons at the ground]. If there is some dust in the air, you will [also] see a red light line pointing to the satellite. No sound comes from space. Maybe there are some raised by the movement of the ground station."

Just about any time Micius does anything, it blows previous records out of the water. That's because previous quantum networks have relied on passing photons around on the ground, using the air between buildings or fiber optic cables. And there are limits to line-of-sight on the ground, or how far a fiber-optic cable will transfer a photon without losing it.

In June 2017, Micius researchers announced that they had sent two "entangled" photons to ground stations 745 miles (1,200 km) apart. (When a pair of photons gets entangled, they affect each other even when separated by large distances.) A month later, in July, they announced that they had teleported a packet of quantum information 870 miles (1,400 km) from Tibet into orbit, meaning the quantum state of a particle had been beamed directly from a particle on the ground to its twin in space.

Both of these achievements were major steps on the road to real-world quantum-key-encrypted networks.

The new letter announces that the theory has been put into action.

Micius first encrypted two photos, a small image of the Micius satellite itself, then a photo of the early quantum physicist Erwin Schrödinger. Then it encrypted that long video call. No similar act of quantum-key distribution has ever been achieved over that kind of distance.

Already, Pan said, Micius is ready to use to encrypt more important information.

How does a quantum key work?
Quantum-key distribution is essentially a creative application of the so-called Heisenberg's uncertainty principle, one of the foundational principles of quantum mechanics. As Live Science has previously reported, the uncertainty principle states that it's impossible to fully know the quantum state of a particle — and, crucially, that in observing part of that state, a detector forever wipes out the other relevant information that particle contains.

That principle turns out to be very useful for encoding information. As the Belgian cryptographer Gilles Van Assche wrote in his 2006 book "Quantum Cryptography and Secret-Key Distillation," a sender and receiver can use the quantum states of particles to generate strings of numbers. A computer can then use those strings to encrypt some bit of information, like a video or a text, which it then sends over a classical relay like the internet connection you're using to read this article.

But it doesn't send the encryption key over that relay. Instead, it sends those particles across a separate quantum network, Van Assche wrote.

In the case of Micius, that means sending photons, one at a time, through the atmosphere. The receiver can then read the quantum states of those photons to determine the quantum key and use that key to decrypt the classical message. [Album: The World's Most Beautiful Equations]

If anyone else tried to intercept that message, though, they would leave telltale signs — missing packets of the key that never made it to the sender.

Of course, no network is perfect, especially not one based on shooting information for individual photos across miles of space. As the Micius researchers wrote, the networks typically loses 1 or 2 percent of their key on a clear day. But that's well within what Micius and the base station can work together to edit out of the key, using some fancy mathematics. Even if an attacker did intercept and wreck a much larger chunk of the transmission, whatever they didn't catch would still be clean — shorter, but perfectly secure enough to encrypt transmissions in a pinch. [How Quantum Entanglement Works (Infographic)]

The connection between Micius and Earth isn't perfectly secure yet, however. As the team of Chinese and Austrian authors wrote, the flaw in the network design is the satellite itself. Right now, base stations in each linked city receive different quantum keys from the satellite, which are multiplied together and then disentangled. That system works fine, as long as the communicators trust that no secret squad of nefarious astronauts has broken into Micius itself to read the quantum key at the source. The next step toward truly perfect security, they wrote, is to distribute quantum keys from satellites via entangled photons — keys the satellites would manufacture and distribute, but never themselves be able to read.

In time, the researchers wrote, they plan to launch more quantum satellites into higher orbits — satellites that will communicate with one another and with researchers on Earth in ever-more-complex webs.

This slowly spreading, ever-more-practical quantum network will first be built for China and Europe, they wrote, "and then on a global scale."

Source: https://www.livescience.com/61474-m...intercontinental.html?utm_source=notification
 
That's the original research and at the very forefront of science...China is taking lead over the west in such areas so the technological gap is not only reducing rather in certain areas, China is leading the world.
 
Remote sensing captures ancient Silk Road cities
Source: Xinhua| 2018-01-23 00:23:10|Editor: Yamei



BEIJING, Jan. 22 (Xinhua) -- Using remote sensing, Chinese archaeologists believe they have located a city of the Protectorate of the Western Regions, a major city on the Silk Road, in Koyuk Shahri of Luntai County in Xinjiang Uygur Autonomous Region.

"Thanks to remote sensing, we can start our excavation of the Protectorate of the Western Regions this year," said Li Wenying, deputy director of the Xinjiang Cultural Relics and Archaeology Research Institute.

The city was established in 60 B.C.to supervise domestic and foreign affairs around Tarim Basin, protecting the Silk Road from military assaults.

However, due to the devastation of the landscape around the area, the precise location of the city was not confirmed. There were three candidates: Kona Shahri, Koyuk Shahri and Drow Kurt.

Last year, archaeologists from the Institute of Remote Sensing and Digital Earth (RADI) under the Chinese Academy of Sciences (CAS) exploited remote sensing technology to find an "abnormal" ring around the Koyuk Shahri, which was later proved to be a moat.

"Based on terrain analysis, the moat can be dated back to 2,200 years ago, which conforms to the written records of the Protectorate of the Western Regions," said Nie Yueping, a researcher from the RADI.

They also found the ancient city site in Koyuk Shahri was constructed with the rectangular facade and the round interior.

In terms of the architectural pattern, while the Western Han Dynasty cities were preeminently rectangular, cities in western regions and kingdoms were round. City site in Koyuk Shahri is a combination of the two, different from the other two candidates.

Archaeologists have restored the original shape of the ancient city through digitization. Its highest point is six meters above the earth, which demonstrates that above the rammed earth, there used to be a "high-rise building with stairs."

Moreover, the side length of the ancient city wall is roughly 230 meters, which matches the Western Han Dynasty standard.

The research program on the Protectorate of the Western Regions is supported by the Joint Laboratory of Remote Sensing Archaeology (JLRSA), co-established by the CAS, the State Administration of Cultural Heritage and the Ministry of Education in China.

Besides, the RADI has participated in the searching for Yangguan, an important pass on the Silk Road fortified more than 2,000 years ago, as well the first Paleolithic cave site found in northwest China' s Xinjiang Uygur Autonomous Region.

"The remote sensing technology can adapt to different landscapes. We hope that in the future, more mature technology can be applied to more archaeological work," said Zhu Jianfeng, a researcher at RADI.

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China launches remote sensing satellites
Source: Xinhua| 2017-12-26 08:24:48|Editor: huaxia



XICHANG, Sichuan, Dec. 26 (Xinhua) -- China launched remote sensing satellites at 3:44 a.m.(Beijing Time) Tuesday on a Long March-2C carrier rocket from Xichang Satellite Launch Center in southwest China's Sichuan Province.

The satellites have entered its preset orbit and the launch was proclaimed a success.

As the third batch of the Yaogan-30 project, the satellites will conduct electromagnetic environmental probes and other experiments.

The launch is the 260th mission of the Long March rocket family.

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After Yaogan-30 03 above, Yaogan-30 04 is scheduled to be launch 25 Jan 13:01 to 13:51 BJT.

A0262/18 - A TEMPORARY RESTRICTED AREA ESTABLISHED BOUNDED BY:
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2018. CREATED: 22 JAN 14:21 2018
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China Focus: China launches 1st high-throughput communications satellite
Source: Xinhua| 2017-04-12 21:53:08|Editor: An

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A Long March-3B carrier rocket carrying Shijian-13, China's first high-throughput communications satellite, blasts off from the launching pad at the Xichang Satellite Launch Center in Xichang, southwest China's Sichuan Province, April 12, 2017. Shijian-13 has a higher message capacity than all of China's previous communications satellites combined and will provide better Internet access in less-developed regions, as well as on planes and high-speed trains. (Xinhua/Ye Lefeng)

XICHANG, April 12 (Xinhua) -- A Chinese satellite will not only help those at the scene of natural disasters report on emergencies but enable passengers on high-speed trains to watch high-definition videos.

Shijian-13, China's first high-throughput communications satellite, was launched from Xichang Satellite Launch Center in southwest China's Sichuan Province at 7:04 p.m. Wednesday.

The satellite, with a transfer capacity of 20 Gbps and a designed orbital life of 15 years, was carried into orbit by a Long March-3B carrier rocket, the 246th mission for Long March carrier rockets.

Shijian-13 has a higher message capacity than all of China's previous communications satellites combined and will provide better Internet access in less-developed regions, as well as on planes and high-speed trains.

"The launch is a milestone for China's communications satellite technology," said Tian Yulong, chief engineer of the State Administration of Science, Technology and Industry for National Defence.

Shijian-13 is the first Chinese satellite to be powered by electricity, potentially improving efficiency by as much as 10 times compared with those using chemicals as propellant, extending the satellite's life and reducing launch weight, said Zhou Zhicheng, commander-in-chief of Shijian-13.

A large number of domestic components have been used. It also has the first laser communications system installed on a Chinese high orbit satellite with a long lifespan.

The satellite and the rocket were designed by academies affiliated with the China Aerospace Science and Technology Corp., and the China Academy of Launch Vehicle Technology respectively.

China plans to launch six communications satellites this year. Shijian-18 will be put into orbit in June to test the DFH-5 satellite platform.

On April, 24, 1970, the launch of China's first satellite Dongfanghong-1 marked the beginning of the country's space endeavors, which currently feature 16 communication satellites.

By 2025, China will have 22 communication satellites, with five built on brand new designs, according to a medium-long term development plan for civilian space infrastructure released in 2015.
China puts high-throughput communication satellite into service
Source: Xinhua| 2018-01-23 20:43:55|Editor: Xiang Bo



BEIJING, Jan. 23 (Xinhua) -- Shijian-13, China's first high-throughput communication satellite, has been put into service after completing a key laser communication test, China National Space Administration said Tuesday.

The high-orbit satellite has finished a two-way high-speed laser communication test between the satellite and ground, the first of its kind in the world, the administration said in a statement.

Serving users in China, the satellite will connect communication base stations in remote areas and meet the needs of distance education, digital news gathering, and emergency communication, said Li Feng, chief satellite designer at China Aerospace Science and Technology Corporation.

Shijian-13, launched from Xichang Satellite Launch Center in southwest China's Sichuan Province in 2017, has a transfer capacity of 20 Gbps and a designed orbital life of 15 years.

The satellite, named Zhongxing-16 after it was put into service, will provide better Internet access on planes and high-speed trains with a maximum download capacity of 150 Mbps and upload capacity of 12 Mbps, according to the statement.

High-throughput communication satellites can form a communication network with larger transfer capacity and higher transfer speeds compared with ordinary satellites.

With a transfer capacity of 200 Gbps, a communication network covering China and the Asia-Pacific region is expected to be established in 2020 as China will send more high-throughput communication satellites into space, said the statement.

By 2025, China will have 22 communication satellites, with five built based on brand new designs, according to a medium-long term development plan for civilian space infrastructure released in 2015.

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