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Japan Army Hovercraft in Action - LCAC of the Japan Self-Defense Forces



I want our servicemen to learn from each other , at the level it was several years ago.

Japanese Ground Self Defense Soldiers can learn so much from the expertise of Pakistan Army Soldiers --- in urban warfare, mountain fighting skills, desert warfare, everything.

Samurai and Mughal Warrior....

2fe8507f-bcbd-4c4f-803c-125784b68956HiRes.JPG
 
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I long someday to see Pakistani F-16s in joint patrols with the JASDF's F-2s.

Is it wrong to dream of this ? I think not.

Such beautiful birds....

Very Interesting point :tup:

On another note, while I was studying the F2 vs the F16 Blk40 /52 /61. I noted that the F2 has a bigger engine intake, like the Blk 61. The engine is also a GE, which only requires a "kit" to increase the thrust from 29,000 lb thrust to 32,500 lb thrust.

Secondly, there isn't much available on the J/APG2 radar, so I can't comment whether it's better than the latest SABR or not.

Thirdly, Weapons integration. SDB would definitely be a good addition.

Conclusion, given it's engine larger size and the capabilities of the Japanese domestic defense industries, there is a lot of room for improvement!

What do you think?
 
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I long someday to see Pakistani F-16s in joint patrols with the JASDF's F-2s.

Is it wrong to dream of this ? I think not.

Such beautiful birds....

The dream would be to see Mirage 2000's and F-2s patrolling over Djibouti :yay:

mirage-2000-en-reconnaissance.jpg

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The F-2 support fighter aircraft is a multi role single engine fighter aircraft principally designed for the Japan Air Self Defence Force (JASDF), the result of a joint Japan and USA development programme. Mitsubishi Heavy Industries (MHI) is the prime contractor and Lockheed Martin Aeronautics Company serves as the principal US subcontractor. The F-2A is the single-seat version and F-2B is the two-seat version.

The Japanese Defence Agency originally planned to procure a total of 130 F-2 aircraft (83 single-seat and 47 two-seat aircraft) with deliveries to beyond 2010, but, in early 2007, this number was reduced to 94.

The initial order was for 81 aircraft. A further five were ordered in March 2007 in a $150m contract. MHI awarded a further $250m contract to Lockheed Martin in April 2008 to manufacture components for eight more F-2 aircraft. The contract was the 12th annual contract awarded by MHI to Lockheed Martin.

F-2 fighter programme and development
In 1987, the JASDF selected a variant of the F-16C as the Japanese FS-X aircraft to replace the Mitsubishi F-1 aircraft, and in 1988 Mitsubishi was selected as prime contractor for the aircraft, which became known as the F-2. The programme involved technology transfer from the USA to Japan, and responsibility for cost sharing was split 60% by Japan and 40% by USA.

Four flying prototypes were developed, along with two static prototypes for static testing and for fatigue tests. Flight trials of the prototypes were successfully completed by 1997, and the aircraft entered production in 1998.

The first production aircraft was delivered to the Japanese Defence Agency in by March 2005 61 F-2 fighters had been delivered. The aircraft are being assembled at Mitsubishi's Komaki South Plant in Nagoya. MHI expects to complete deliveries of 76 aircraft in the near future.

AIR_F-2s.jpg

In June 2007, the F-2 made its first overseas deployment to Andersen AFB in Guam for joint US / Japan exercises. The F-2 dropped live weapons for the first time during the exercises.

F-2 fighter design
Kawasaki is responsible for the construction of the midsection of the fuselage, and also the doors to the main wheel and the engine. Mitsubishi builds the forward section of the fuselage and the wings.

Mitsubishi has also designed the lower-wing box structure, which includes lower skin, spars, ribs and cap, and is made from graphite-epoxy composite and co-cured together in an autoclave. This is the first application of co-cured technology to a production tactical fighter.

Fuji manufactures the upper-wing surface skin, the wing fairings, the radome, flaperons and the engine air-intake units and the tail section. Lockheed Martin Aeronautics Company supplies the rear section of the fuselage, the port-side wing boxes and the leading-edge flaps.


Cockpit
The cockpit is equipped with three multifunction displays, including a liquid crystal display from Yokogawa. The pilot's head-up display was developed by Shimadzu.

Integrated weapons system
The aircraft's integrated electronic warfare system, mission computer and active phased array radar were developed by Mitsubishi Electric.

An M61A1 Vulcan 20mm multi-barrel gun is installed in the wing root of the port wing. There are 13 hardpoints for carrying weapon systems and stores: one on the fuselage centreline, one on each wing-tip and five under each wing. The stores management system is supplied by Lockheed Martin.

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There are two Frazer Nash common rail launchers manufactured by Nippi. The aircraft is capable of deploying the Raytheon AIM-7F/M medium-range Sparrow air-to-air missile, the Raytheon AIM-9L short-range Sidewinder and the Mitsubishi Heavy Industries AAM-3 short-range air-to-air missile.

mitsubishi_f2_l1.jpg

The F-2 is armed with the ASM-1 and ASM-2 anti-ship missiles. Mitsubishi started developing the Type 80 series anti-ship missiles, ASM-1 and ASM-2, in 1980, originally for the F-1 fighter.

The fighter aircraft can also carry 500lb bombs, CBU-87/B cluster bombs and rocket launchers. The centreline and the inner-wing hardpoints can carry drop tanks with a 4,400kg fuel capacity.
asm-3-a.jpg



Avionics and flight controls
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Lockheed Martin is responsible for the avionics systems. The aircraft's digital fly-by-wire system has been developed by Japan Aviation Electric and Honeywell (formerly Allied Signal) under a joint development agreement.

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The fly-by-wire modes include control augmentation, static stabilisation and load control during manoeuvres.

Communications
The communications systems fitted in the F-2 are the AN/ARC-164 transceiver, operating at UHF band and supplied by Raytheon, a V/UHF transceiver supplied by NEC, a Hazeltine information friend or foe interrogator, and an HF radio, developed and supplied by Kokusai Electric.

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Turbofan engine
The aircraft is equipped with a General Electric F110-GE-129 afterburning turbofan engine. The engine develops 131.7kN and the speed of the aircraft is Mach 2. The F-2 produces 17,000lb of thrust, with 29,000lb generated when the burners are switched on
http://www.airforce-technology.com/projects/f2
 
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Japan Hosts First Global Arms Fair
Agence France-Presse
May 13, 2015

TOKYO — Japan on Wednesday began its first ever military trade fair, with a particular focus on maritime security at a time of rising regional tensions over territorial squabbles.

The three-day fair, organized by a private British company with the backing of Japan's defense and trade ministries, comes as Prime Minister Shinzo Abe pushes to boost the role and capability of his well-equipped military.

Amongst other things, that means re-thinking their rules of engagement to allow them to fight to defend an ally — something most administrations have said was impossible under Japan's pacifist constitution.

The government has also moved to lessen restrictions on the home-grown weapons industry, allowing it to sell more hardware abroad in an effort to boost the sector.

The new rules could allow Tokyo to supply weaponry to nations that sit along important sea lanes to help them fight piracy — an important strategic consideration for resource-poor Japan.

"This is a great opportunity for us as a small company to promote our name and products," said Susumu Kasai, an official with ShinMaywa Industries Ltd. which manufactures US2 Amphibious Planes for Japan's Marine Self-Defense Force.

Reports have said US2 is likely to become the first export of Japanese-made military equipment under the new rules.

"Currently the governments of Japan and India are negotiating the issue and if the governments agree, we will be able to export our products," Kasai said.

"This is a maritime security fair and as maritime security is important for Japan, which is surrounded by seas, the government supports the event," said defense ministry official Toru Hotchi.

Under Japan's new arms export rules, weapon sales are still banned to conflict-plagued countries that could undermine international peace and security. Any sale must contribute to international peace and boost pacifist Japan's security.

Abe is readying to submit new security bills to parliament that will underwrite last year's cabinet decision on broadening the scope of so-called collective defense, which gives the military freer rein to protect Japan's allies.

While Washington, which has long called for Japan to take on more of the burden of its own defense, has warmly welcomed the moves, Abe faces considerable domestic opposition from a public deeply wedded to the country's pacifist constitution.

He also faces regular rebukes from China, which hints ominously at what it says is a deep-seated desire on Japan's nationalist right to up-end the post-World War II settlement and return to the militarism of last century.

Abe and his supporters deny the charge.

Japan Hosts First Global Arms Fair
 
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I want our servicemen to learn from each other , at the level it was several years ago.

Japanese Ground Self Defense Soldiers can learn so much from the expertise of Pakistan Army Soldiers --- in urban warfare, mountain fighting skills, desert warfare, everything.

Samurai and Mughal Warrior....

2fe8507f-bcbd-4c4f-803c-125784b68956HiRes.JPG

It's a brilliant idea :tup:

Why don't you recommend it to Gen Nakatani? :-)
 
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Japan Boosts ISR Abilities Across Domains
By Paul Kallender-Umezu
May 11, 2015


TOKYO — Japan's defense budget for 2015 prioritizes intelligence, surveillance and reconnaissance (ISR) improvements as the Ministry of Defense attempts to bolster, in particular, its ability to protect Japan's far-flung southwestern island chain, Nansei Shoto.

New ISR programs — some announced, some in planning — show Japan is extending its ISR reach not only in air- and space-based systems, but also in new maritime applications.

"The focus on improved ISR is useful and reflects a few things — not least, Japan's current ISR capabilities don't provide a useful operating picture of what's going on in the region," said Grant Newsham, a senior research fellow at the Japan Forum for Strategic Studies.

Japan's approach to ISR changed radically in 1998 when a North Korean Taepodong missile overflew the nation, shocking it and spurring leaders to develop a small constellation of information-gathering reconnaissance satellites.

But a 2007 direct-ascent Chinese anti-satellite test and the surge in probing and incursions into Japanese air and maritime domains have alarmed planners and the public alike. For example, from January to April, the Air Self-Defense Force scrambled fighters 943 times against Russian and Chinese aircraft, the second highest on record since 944 times in 1984. Incidents steadily dropped through the 1990s and early 2000s, with totals typically in the 140s to 160s. By 2005 it was up to 229, in 2010 it was 386, surging to 943 five years later, according to MoD figures.

"Given an increasingly assertive PRC [People's Republic of China] in recent years and North Korean movement toward better missile and nuclear capabilities, the region has never seemed more dangerous from a Japanese perspective," Newsham said. "Having a clear intelligence picture is obviously of fundamental importance."

To keep watch over the Nansei Shoto, the MoD announced that it will acquire Global Hawk UAVs and is researching the use of ship-based UAVs. To support these moves, the MoD will also deploy a new coastal observation unit on Yonaguni Island, which abuts Taiwan.

"There is concern in some quarters that Japan is overly dependent on the US' ISR capabilities and needs more of its own proprietary resources, particularly in terms of PRC and North Korean activities," Newsham said. "The … surveillance unit on Yonaguni is going to need assistance from Maritime and Air Self-Defense Force assets to really be effective."

Japan is also making a major push in space-based ISR following a new military and national security-oriented space strategy released in January. The nation's current constellation of four information-gathering satellites could double within 10 years, and a series of new dual-use satellites for ISR purposes is being considered.

For example, the Japan Aerospace Exploration Agency (JAXA) is cooperating with the MoD to host a ballistic missile early warning sensor on a new JAXA-built reconnaissance satellite called ALOS-3
, and may go ahead and develop a space-based early warning architecture to support the US. JAXA is also investing in a slew of new dual-use ISR satellite programs, including tactical satellites, and Japan is considering whether it wants to build space-based signals intelligence and electronic intelligence assets.

"Space-based ISR is certainly an important issue for the US due to its global defense obligations," said Scott Pace, director of the Space Policy Institute at the George Washington University's Elliott School of International Affairs.

In addition, space situational awareness and maritime domain awareness are key priorities for space-based ISR, following a series of agreements with the US, which is keen for Japan to play a greater role in these areas, Pace said.

Japan also wants to bolster its maritime ISR, most notably through the acquisition of 20 Kawasaki P-1 patrol aircraft, with improved detection/discernment capabilities, flight performance, information-processing capabilities, and attack capabilities to succeed existing P-3C fixed-wing patrol aircraft, which are also receiving upgrades.

Japan plans to refocus on "close-in" ISR to protect ports, harbors and other critical infrastructure, said Bob Nugent, affiliate consultant at AMI International. At least five MoD research projects cover a variety of unmanned maritime ISR systems and technologies, including long-range "sea gliders," cooperative networks of surface and underwater unmanned vehicles.

Some of these systems will be featured at the MAST Asia maritime security exhibition to be held mid-May in Yokohama. For example, NEC Corp. will outline a proposed system of underwater wireless electric charging stations for UUVs.

"Japan is keenly looking at advanced long-range acoustic hydrophones using optical fiber rather than traditional electro-acoustic listening devices," Nugent said. "Additional MoD research includes projects to improve performance of underwater passive sonar arrays. All these highlight Japan's need to improve ISR in the underwater domain."

Nugent said improved energy storage and charge/recharge technologies will be a key enabler for many of the advanced ISR platforms. Several Japanese and international companies are researching power and energy technologies "beyond the battery."

Japan's next-generation system requirements are already creating new opportunities for suppliers, said Eric Johnson, president of JSR Micro, the US subsidiary of JSR, a major Japanese semiconductor materials company.

"We're developing advanced energy storage technologies using supercapacitors that deliver very high bursts of energy and recharge quickly … needed for remote maritime sensors; unmanned vehicles operating over, on or under the water; and even space satellites … areas of particular interest in Japan and beyond for future maritime ISR systems," Johnson said.

Newsham said Japan needs to go beyond its traditional focus on systems and technology and focus on better integration between the services and between Japan and the US, particularly since the alliance partners have just updated their defense guidelines touting "seamless" cooperation.

"More effective ISR allows Japan to make more of a contribution to the overall US-Japan defense effort. … Japan has some good ISR hardware, but it hasn't created a coherent national ISR network that collects intelligence from all sources, properly assesses and classifies it, and disseminates it to the right end users — both in Japan and elsewhere," Newsham said.

Japan Boosts ISR Abilities Across Domains
 
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Philippines, Japan To Hold Joint Naval Exercise In S. China Sea
Agence France-Presse
May 10, 2015

MANILA, Philippines — The Philippines' navy chief said Sunday it would hold a joint exercise with Japan in the South China Sea, but emphasized the collaboration was unrelated to China's land reclamation efforts in the disputed waters.

Two warships from the Japan Maritime Self-Defense Force (JMSDF) will take part in the exercise with a single Philippine ship after making a port call in the Philippines this month, said Vice Adm. Jesus Millan.

"This is a port call, a regular port call of the Japanese navy and while they are here, it would be good if we can practice this code of unplanned encounters at sea," he said.

The exercise will take place just outside the former US naval base of Subic, off the archipelago's west coast, he added.

The Japanese vessels would be leaving Subic while a Philippine ship was heading there under the training scenario, he said.

Millan said Japanese and Philippine sailors would have an opportunity to "compare notes" during the exercise, but stressed it had nothing to do with the Philippines' territorial dispute with China over conflicting claims to large parts of the sea.
http://www.defensenews.com/story/de...ge-south-china-sea-land-reclamation/27083039/
The Philippines has been seeking closer ties with regional allies amid what it sees as Chinese aggression in pressing its territorial claims.

The regional giant claims most of the resource-rich waters, even reefs, shoals and cays close to the shores of its neighbors. The claims overlap those of Brunei, Malaysia, the Philippines, Vietnam and Taiwan.

Millan said that practicing with the Japanese force would help with modernizing the poorly-equipped Philippine military, one of the weakest in the region.

China and Japan have their own festering territorial row over the East China Sea including ownership of the Senkaku Islands, which Beijing also claims and calls the Diaoyus.

There have been regular standoffs in the sea and air around the contested territory.

Earlier this month, Japanese and Philippine coast guards held anti-piracy drills in the Philippines, the first such joint exercise between the two countries following a brutal occupation by Japanese forces during World War II.

US officials said on Friday that China's rapid construction of artificial islands in the strategic waters amounted to 2,000 acres (800 hectares), with 75 percent of the total built in the last five months.

The US report said that at four reclamation sites China had moved from dredging operations to "infrastructure development" that could include harbors, communications and surveillance systems, logistics support and "at least one airfield."

The Philippine military has also cited escalating Chinese efforts to drive off Philippine aircraft from a disputed island garrisoned by Manila, which have sparked dangerous confrontations.

Japan in turn has called for international law to be observed in the South China Sea dispute and has previously promised to help in the modernizing the Philippines' maritime assets.

Philippines, Japan To Hold Joint Naval Exercise In S. China Sea


@Nihonjin1051 @JayMandan Any details?
 
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Japan cabinet agrees military expansion rules
By Kyoko Hasegawa - AFP
15/05/2015

Japan's cabinet on Thursday approved a set of bills bolstering the role and scope of the military, as the pacifist country redefines its position in the increasingly roiled Asia-Pacific region.

The bills are a pet project of nationalist Prime Minister Shinzo Abe, who says Japan can no longer shy away from its responsibility to help safeguard regional stability, and must step out from under the shade of the security umbrella provided by the United States.

The draft legislation, which will go before lawmakers in the coming months, formalises a decision made by the cabinet last year to broaden the remit of Japan's well-equipped and well-trained armed forces.

It would allow them to go into battle to protect allies -- so-called "collective defence" -- something currently banned by a strict reading of Japan's pacifist constitution.

"We live in an era when no country can any longer protect itself alone," Abe told a televised press conference.

"In the past two years, Japanese nationals have fallen victim to terrorism in Algeria, Syria and Tunisia; Japan is within range of hundreds of North Korea's ballistic missiles and the number of (fighter jet) scrambles has risen seven-fold in a decade.

Prime Minister Shinzo Abe says Japan can no longer ignore the threat of terrorism and the military m …
"This is the reality. We should not try to ignore it."

Washington -- which imposed the never-altered constitution on a defeated Japan during its post-World War II occupation -- has long called for Tokyo to take on a more active role in their mutual security pact.

- Opposition -

But the Japanese public is suspicious of anything that seems to lessen the commitment to pacificism, and insists its armed forces should only ever be used in a narrowly-defined defence of Japan.

Critics of the security moves say eroding this principle could see Tokyo pulled into American military adventures in the Middle East, a claim Abe rejected Thursday.

"The conventional principle that (the military) shall not be deployed overseas will stay. They will not take part in conflicts like the Gulf War or Iraq War in the future. I want to make that clear," he said.

He said the last 70 years had proved that Japan was committed to peace and the country should be confident in its ability to stick to that path, without fearing these legal changes would drag it into conflict.

"Not a single Japanese person wants to see a war," he said.

Hundreds of people rallied in front of Abe's office Thursday, holding banners condemning the proposed legal changes.

"The bills will eventually serve as a green light to join an American war. It is clearly a violation of the constitution," said 66-year-old Akemi Kitajima.

Abe also faces Chinese charges that he is re-militarising Japan by stealth in an effort to return to its warring ways of the 20th century. The prime minister and his supporters deny this.

In Beijing, foreign ministry spokeswoman Hua Chunying said the world was watching Tokyo for "historical reasons".

"We hope that Japan will draw lessons from history, pursue the path of peaceful development, and make more positive efforts for the peace, stability and development of the Asia-Pacific region where we live together," she said.

The legislation, which would overhaul 10 security related laws and create a new one, would pave the way for the military to deploy abroad on non-combat assignments such as disaster relief and UN peacekeeping missions.

Revisions include removing geographical constraints on logistical support for friendly forces in "situations that would significantly affect Japan's security".

They also say Japan can defend allies "in situations where there is a clear risk that Japan's existence is threatened and its people's rights...are compromised through an attack on a country which has a close relationship with Japan".

The cabinet decision comes as Japan hosts its first ever global arms fair, the result of relaxation in rules banning the sale of weapons abroad, as part of a bid to shore up the domestic arms industry.


Japan cabinet agrees military expansion rules - Yahoo News


Abe Cabinet OKs bills to relax limits on SDF operations abroad

by Masaaki Kameda
Staff Writer
  • May 15, 2015
Prime Minister Shinzo Abe’s Cabinet adopted two security bills on Thursday that would, if passed by the Diet, greatly expand the scope of the Self-Defense Forces’ joint operations with foreign forces overseas.

“The Cabinet today approved a package of security bills to ensure peace for Japan and the world,” Abe said at a news conference at his office.

The legislation will be submitted to the current Diet session, where heated debate is expected. If passed, it will effectively usher in a historic shift away from the country’s long-held defensive posture on matters of security.

One of the two bills would amend 10 security-related laws, removing some restrictions on SDF operations. One of the revisions would allow Japan to exercise the right of collective self-defense, or the right to come to the aid of a friendly nation under attack.

Collective self-defense would be allowed only when there is a “clear danger” to Japan’s survival due to an armed attack on a country with which Tokyo has “close ties” and there are “no other appropriate means” to protect Japanese citizens.

Despite those restrictions, the revision would still result in a departure from the country’s postwar pacifism, as the Constitution was long interpreted as allowing Tokyo to attack an enemy country only when Japan itself is under attack.

The second bill would create a permanent law allowing the government to dispatch the SDF overseas to provide logistics support to a foreign force engaged in armed combat.

The government currently needs to enact a temporary law each time it wishes to dispatch the SDF to provide logistics support to a multinational force, such as those in Iraq or Afghanistan.

The Abe administration argues that forging a permanent law would allow the government to dispatch SDF units without any delays caused by having to enact a special law.

However, the government would still need to gain Diet approval “without exception” before deploying SDF units abroad, according to the proposed amendment.

The bills were adopted in line with Abe’s ambition of making Japan “a proactive contributor” to international peace. The bills would also give teeth to the Cabinet’s contentious decision last July to reinterpret the Constitution to allow Japan to exercise the right to collective self-defense.

And it would boost cooperation between the SDF and U.S. forces, in line with the new bilateral defense guidelines, which were revised last month.

Chief Cabinet Secretary Yoshihide Suga said earlier in the day the new bills are designed to enhance the deterrent power of Japan and its military alliance with the United States.

The government’s most important responsibility is “to protect the peaceful lives of the public,” Suga told reporters. “We need legislation that would enable (the country) to address every situation in a seamless manner.”

One of the security-related laws that would be amended allows Japan to provide logistics support to U.S. forces near Japan in the event of a military contingency.

The law was enacted in 1999 to deal with the possibility of a military contingency on the Korean Peninsula, although this was not explicitly written in the text.

The Abe government would like to remove geographical restrictions on Japan’s logistics support for any foreign forces in the event of a situation that would “gravely affect” Japan’speace and security.

Other proposed revisions to the 10 security-related laws include:

Allowing the SDF to defend warships and other hardware of nations working to defend Japan, such as the U.S.

Permitting the SDF to conduct ship inspections abroad in a bid to contribute to international peace and security. Currently, Japanese forces are restricted to inspecting ships and their cargo “in Japanese waters or on the surrounding high seas.”

Enabling SDF personnel in peacekeeping operations abroad to use their weapons to defend foreign forces under armed attack.

Allowing Japan to send SDF personnel abroad to engage in security operations and to extend humanitarian assistance in line with U.N. resolutions or upon request by other international bodies such as the EU.

Letting the SDF rescue Japanese nationals caught up in emergency situations overseas. Currently, the SDF is only allowed to provide transport during evacuation missions.

Abe Cabinet OKs bills to relax limits on SDF operations abroad | The Japan Times
 
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Japan aims to harness space solar energy
Orbiting craft will gather energy of the sun and utilise microwaves to transfer power to Earth
By Julian Ryall in Tokyo
12 May 2015

japan-space_3301773b.jpg

Space Solar-Power Systems (SSPS) are designed to collect solar energy with large-scale solar collectors deployed in outer space and to transmit that energy to earth as either microwave or laser energy Photo: JAXA

Japanese scientists are developing a spacecraft that will have a square screen of solar panels measuring more than 1.2 miles along each side and use microwaves to beam energy down to Earth.

Researchers from the Japan Aerospace Exploration Agency are working with Japan Space Systems to solve one of the enduring problems associated with the most common form of renewable energy; it does not work at night and is inefficient in bad weather.

Solar panels that are not affected by weather and gathered by a Space Solar Power System (SSPS) positioned to constantly face the sun are able to generate an estimated 10 times as much power as Earth-based solar panels.

"We estimate that one SSPS unit will be able to generate around the same amount of energy as one nuclear reactor", Daisuke Goto, an engineer with the JAXA research team, told The Telegraph.

"So while this SSPS will not solve mankind's energy problems entirely, we hope it will contribute as a future energy source."

The concept of a space-based solar energy system emerged in several countries in the 1980s, including the United States, but it faced some daunting technological challenges and was eclipsed by other projects.

According to Mr Goto, one of the largest challenges has been to develop a system to transmit energy from the spacecraft to the Earth.

space-solar_3301878a.jpg


In an experiment in March, Japan Space Systems succeeded in converting 1.8 kilowatts of electricity into microwaves and transmitting it over a distance of more than 180 feet to an antenna where it was converted back into electricity.

The research is focusing on microwaves because they travel in a straight line and can penetrate even thick clouds, Mr Goto said.

Another major consideration is the receiver on Earth that will "capture" the energy, with the scientists' proposals including a receiver as much as one mile in diameter floating on the sea and linked to the power grid.

Equally challenging will be the task of transporting the components for the SSPS into space and assembling them. Maintenance and repairs will need to be carried out by robots and the scientists are hoping that each craft will have an effective lifespan of 40 years.

Despite the recent breakthroughs, experts believe it will be at least 30 years before the first SSPS is ready to go into operation.

Japan aims to harness space solar energy - Telegraph
 
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Russian launch of new ISS crew members delayed until July: reports
May 8, 2015

MOSCOW – The launch of the rocket that was to carry Japan’s Kimiya Yui and two other astronauts to the International Space Station this month has been postponed to July, Russian media reports said Friday.

The Japan Aerospace Exploration Agency (JAXA) said authorities in the countries involved in the Soyuz mission will rearrange the launch schedule next week.

The decision follows Russia’s failure on April 28 to put the cargo ship Progress in its proper orbit. Progress was carrying food and other supplies to the ISS. The Russian space agency is investigating the cause of the malfunction.

Russian news agency Interfax reported that the Russian spacecraft will head to the ISS “in mid-July,” while TASS news agency quoted a rocket and space industry source as saying the launch will be made “in the last 10 days of July,” given the time needed to adjust the flight program and launch another cargo craft before the manned Soyuz blasts off.

The three crew members, who are expected to stay on the ISS for about six months to carry out various experiments, were scheduled to depart May 27 from Baikonur Cosmodrome in Kazakhstan.

“We passed Soyuz final exam! We had a great party last night,” Yui, a 45-year-old flight engineer, said in a Twitter post Friday.

Yui, commander Oleg Kononenko from the Russian Federal Space Agency and flight engineer Kjell Lindgren from NASA took the final exam for the mission on Wednesday and Thursday.

Their scheduled news conference on Friday was canceled.

Russian launch of new ISS crew members delayed until July: reports | The Japan Times

Crew Change Delayed on the International Space Station
Brian WuMay
13, 2015

international-space-station.jpg

(Photo : NASA)

Following the failed launch of a Russian resupply rocket, NASA and its space agency partners have decided to delay the return of three astronauts from the International Space Station.


"The return to Earth for NASA's Terry Virts, ESA (European Space Agency) astronaut Samantha Cristoforetti and Russian cosmonaut Anton Shkaplerov now is targeted for early June. NASA astronaut Scott Kelly and Russian cosmonauts Mikhail Kornienko and Gennady Padalka will remain aboard the station to begin Expedition 44."

The three astronauts originally arrived on the station on November 24, 2014, as a part of Expedition 43.

Their replacements, NASA astronaut Kjell Lindgren, the Russian cosmonaut Oleg Kononenko and Kimiya Yui of the Japan Aerospace Exploration Agency, will also be delayed from late May to late July, according to NASA. They will join Scott Kelly of NASA and two Russians, Mikhail Kornienjo and Gennady Padalka, who are already on board, as part of Expedition 44.

The flight plan changes came after Russian space officials conducted an initial investigation into the loss of control of the unmanned Progress 59 cargo ship on April 28. The craft orbited in low Earth orbit for more than a week before plunging into the atmosphere and disintegrating.

"The partner agencies agreed to adjust the schedule after hearing the Russian Federal Space Agency's (Roscosmos) preliminary findings on the recent loss of the Progress 59 cargo craft. The exact dates have not yet been established, but will be announced in the coming weeks. Roscosmos expects to provide an update about the Progress 59 investigation on Friday, May 22."

This delay shouldn't pose any problem to the astronauts that are currently stranded aboard the space station, said NASA spokeswoman, Stephanie Schierholz. "We keep plenty of supplies on the space station so we can have the flexibility to do something like this," she said in an interview.

The incident has put further launches to the Station on hold pending the results of an investigation into the failure," ESA said in a statement. "The six astronauts living and working on the orbital complex have enough supplies to last for many weeks regardless of the loss, so their wellbeing is unaffected by the change of schedule."

The next cargo launch by Russia, Progress 60, will be moved up to early July from August, she said. In addition, SpaceX will also launch a resupply mission currently scheduled for June 19. Both will deliver several tons of supplies and food to the space station.

Crew Change Delayed on the International Space Station : SPACE : Science Times
 
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Japanese H-IIA Rocket successfully launches IGS Reconnaissance Satellite

March 26, 2015


A Japanese H-IIA launch vehicle lifted off from the country's picturesque launch site on Tanegashima Island at 1:21 UTC on Thursday, embarking on a mission to deliver the classified IGS Optical-5 satellite to a Low Earth Orbit to join Japan's fleet of Information Gathering Satellites.

The Information Gathering Satellites were approved for development in 1998 in response to a North Korean missile test that overflew the Japanese territory. At the time, Japan was relying on foreign satellite imagery that were only available after a certain delay and at significant cost.

The need of an independent capability to monitor activity on foreign territories to identify potential military threats was identified by the Japanese government that decided to press forward with the development of optical and radar reconnaissance satellites. The first launch of a pair of IGS satellites occurred in 2003 and over the years, over a dozen satellites were launched, going through constant improvements in capabilities and imagery resolution.

The IGS program is semi-secret up to a point where the Japanese government acknowledges its existence, however, details on the satellites are only available via secondary sources.

The IGS Optical-5 satellite is an operational fifth generation optical satellite that can achieve a ground resolution of better than 0.5 meters, joining an experimental 5th generation satellite that was launched in early 2013.

426px-Payload_fairing_of_GPM%27s_H-IIA_rocket.jpg


Launch Operations at the Tanegashima Space Center picked up around 11:30 UTC on Wednesday when the H-IIA rocket emerged from the Vehicle Assembly Building to make the 500-meter trip to the second launch pad at the Tanegashima Space Center.

Kicking off an overnight countdown, H-IIA - sitting atop the Mobile Launch Platform - was carefully centered on the pad and teams started the process of connecting the various propellant, pressurant, purge, power and data umbilicals. Next, a series of close out operations were completed at the launch pad before engineers departed the area to comply with the 400-meter safety zone for launch vehicle activation and testing.

With H-IIA on external power, the Launch Team started a series of testing operations looking at the electronics, Flight Control System, propulsion systems, Communication System and Flight Termination System. Engine slews on the first and second stage engines were performed and teams completed the final steps to start propellant loading.

Ahead of the initiation of fueling, the safety zone was widened to 3,000 meters and the Vehicle Assembly Building was cleared for launch. Illuminated on its launch pad, H-IIA headed into propellant loading operations around seven hours and 45 minutes prior to launch, picking up with the pressurization and chilldown of the Liquid Hydrogen and Liquid Oxygen Systems on the ground before transfer lines to the launcher were conditioned and the four propellant tanks on the two stages of the vehicle could enter chilldown.

Over the course of a three-hour sequence, the tanks of the H-IIA first stage were filled with about 100 metric tons of -183°C LOX and -253°C LH2 while the second stage received about 16,600kg of cryogenics. Entering topping, the tanks were kept at flight level as the supercold propellants naturally boiled off.

The fully-fueled launcher was put through another round of tests including a repetition of C- and S-Band comm checks, testing of the Flight Control system and verifications of various ground systems. The countdown entered a quiet period after testing was complete and teams and visitors were treated to a beautiful sunrise that could be seen from the sea-side launch complex.

h2btf1.jpg



The Terminal Countdown started at X-60 minutes marking the start of final reconfigurations of the H-IIA rocket for the Automated Countdown Sequence. A refined version of the flight parameters were loaded into the Flight Computers based on the latest measurements of conditions in the upper atmosphere. Weather was favorable for launch with clear skies, calm winds and warm temperatures.

The IGS Optical 5 satellite was switched to internal power as clocks ticked down, also being placed in flight mode to be ready for its trip into orbit. Teams made the final status check of all stations including the range and spacecraft team reported a GO to head into the Automated Countdown Sequence.

The precise launch time was programmed into all sequencers and the Automated Countdown commenced at X-4 minutes and 30 seconds to begin the highly choreographed process of transitioning H-IIA to its launch configuration. All launch vehicle parameters were continuously monitored by computers that were ready to trigger an abort in the event of any off-nominal indications.

The first step was the pressurization of the first stage tanks after the ground propellant feed was terminated at X-4:20. Pressurization took two minutes to complete. At X-3 minutes, the two-stage rocket was transferred from ground facility power to battery power - the Flight Termination System was switched to a fully independent power source to ensure the system could end the flight of H-IIA in the event of an in-flight failure.

f18_cd_03.jpg


With one minute on the countdown clock, the sound suppression system started pouring thousands of liters of water onto the launch pad to suppress the acoustic loads at booster ignition.


Launch vehicle ordnances were armed at X-30 seconds followed 12 seconds later by the Guidance System switching to flight mode. At X-11.5 seconds, the sparklers underneath the LE-7A Main Engine of the Core Stage ignited to burn off any residual Hydrogen that may be released during the Ignition Sequence.

Ignition sequence start was commanded at X-5.2 Seconds and the fuel and oxidizer valves of the main engine were opened and its turbopumps started spinning to flight speed. Engine ignition was carefully monitored by computers to ensure LE-7A reached its full liftoff thrust of 109,300 Kilograms.
When clocks hit zero, and LE-7A was up and running, the two Solid Rocket Boosters ignited and H-IIA blasted off under loud thunder with a total thrust of 575 metric tons. The rocket climbed vertically for a handful of seconds before beginning its pitch and roll maneuver to depart Tanegashima Island. No official broadcast by either JAXA of Mitsubishi Heavy was provided but amateur groups gathered at the launch site to cover the launch, providing live video and photos.

Although no information on the flight profile of H-IIA nor the target orbit of this mission were released, the mission design can very well be deduced from previous H-IIA mission to a polar orbit where IGS Optical 5, like all of its predecessors, is headed.

The satellites operate from orbits inclined 98°, an orbital inclination that can not directly be reached from Tanegashima, requiring H-IIA to use additional performance for a Dogleg maneuver - a powered turn during the ascent inserted into the trajectory to avoid any fragments of the rocket coming down over inhabited land masses.

Heading out to the south-east, H-IIA was to continue on that path throughout the booster-phase of the flight and into the late stages of first stage flight, reaching a downrange distance of over 100 Kilometers.


At that point, the vehicle was to gimbal its engine to turn westward to align itself with a south-westerly path towards a 98° orbit, avoiding the Philippines and frequented fishing areas.

Heading uphill, H-IIA passed Mach 1 about 75 seconds after liftoff followed by Maximum Dynamic Pressure as the launcher flew under the power of its cryogenic main engine and the twin boosters that did most of the work at that point in the flight.

Burning over 65 metric tons of solid propellant, each SRB delivered more than 230 metric ton-force of thrust to deliver the extra kick during the initial flight phase needed to get IGS into its planned orbit.

Thrust on the boosters tailed off after passing the T+100-second mark with computers detecting the pressure drop inside the boosters through onboard instrumentation, triggering the separation of the boosters that employed pyrotechnics and thrust struts that ensure a clean separation of both boosters.

With the boosters gone, only the LE-7A engine was powering the launch vehicle consuming 260 Kilograms of cryogenics per second to deliver 109,000 Kilogram-force of thrust.
Reaching an altitude of around 130 Kilometers, H-IIA separated its protective payload fairing to shed no-longer-needed weight since aerodynamic forces can no longer harm the satellite at this altitude.

Sticking to a standard mission profile, the first stage burned until six and a half minutes into the flight. Shutting down the LE-7A engine, the first stage was to initiate the staging process eight seconds after MECO, firing pyrotechnics that allow the 37-meter long stage to be pushed away from the second stage, clearing the engine.

After another six seconds, the LE-5B engine of the upper stage was to ignite on its only burn in this mission, heading directly for the target orbit which required the stage to fire for up to eight and a half minutes. LE-5B delivers 14,000 Kilogram-force of thrust and was planned to finish the dogleg maneuver.

f17_cd_09.jpg


Main Engine Cutoff was expected around 15 minutes after liftoff in an insertion orbit at an altitude of approximately 500 Kilometers. Spacecraft separation was to occur under 20 minutes into the mission to set the IGS satellite free for its mission dedicated to keeping a close eye on developments on the ground. Confirmation of a successful launch was provided by the Launch Team through nominal call-outs during the flight all the way to separation.

This was the second Japanese launch of the year and the second dedicated to the IGS program. The next IGS satellites will be launched in 2016. Still planned this year is the next flight of Japan's H-II Transfer Vehicle on a resupply mission to the International Space Station expected to launch atop an H-IIB in mid-August while H-IIA is set for its first commercial launch late in the year, carrying the TelStar 12V satellite into orbit and also debuting an upgraded second stage. Towards the end of the year, H-IIA is also planned to launch the New X-ray Telescope (NeXT).

Information Gathering Satellites

Information Gathering Satellites are Japan's primary intelligence satellites operated to deliver reconnaissance for the military and intelligence services in the form of optical imagery and high-resolution radar data. IGS satellites carry an optical reconnaissance payload or a Synthetic Aperture Radar for remote sensing. The main purpose of the satellite program is to provide an early warning capability of missile launches. IGS was initiated in 1998 in response to a North Korean missile test that flew over Japan.

re-entry that occurred on July 26, 2012. IGS 1A has been in a stable orbit until early 2012 when it started dropping, indicating that the spacecraft had depleted its fuel tanks or stopped functioning. It decayed in July 2014.

The second IGS launch in November 2003 ended in failure and never arrived in orbit when a Solid Rocket Booster failed to separate from the H-IIA rocket.

The IGS 1 and IGS 2 satellites were first generation spacecraft achieving a ground resolution for optical images of 5 meters (color) and about 1 meter (panchromatic). Synthetic Aperture Radar resolution is believed to be better than 3 meters.
IGS 3A was launched by H-IIA in September 2006 and represented the second generation of optical satellites that achieve a resolution of one meter. The satellite operated from an orbit of 480 Kilometers.

The IGS 4 satellite pair launched in February 2007 and included an experimental third generation optical satellite with a ground resolution of better than one meter, and a second generation SAR spacecraft also achieving a resolution of one meter. The satellites were found in an orbit of 481 to 494 Kilometers that they maintained until 2010. In the summer months of 2010, IGS 4B became non-operational for reasons that were not disclosed - it re-entered in November 2013. When satellite 4A stopped functioning is unclear, but orbital data suggests a loss of orbit control between mid-2010 to mid-2011 leading up to re-entry in April 2014.

IGS 5A is another optical satellite of the third generation launched in late 2009 and found in an orbit of about 585 Kilometers. In September 2011, the first fourth generation optical satellite was launched that is believed to achieve image resolutions of about 60 centimeters, operating in an orbit similar to that of IGS 5A. The first satellite in the third generation of SAR spacecraft was launched in December 2011 and operates from a 510-Kilometer orbit.

Another dual-IGS launch occurred in January 2013 when an H-IIA202 rocket delivered IGS 8A and 8B into an orbit of 513 Kilometers. The 8A satellite is a 3rd generation SAR spacecraft and 8B a 5th generation optical satellite that returns imagery at resolutions of under 50 centimeters The. 8A satellite remains in its 513-Kilometer orbit while 8B has entered a lower orbit at an altitude of 427 Kilometers.

6424132_orig.jpg


In January 2015, a satellite known as IGS Radar Spare (IGS 9A) entered orbit after a successful H-IIA launch, likely representing a 3rd generation satellite ordered as reserve for an earlier SAR satellite and being launched to be ready for the end of service of a SAR satellite, likely IGS 7.

Because the IGS Satellites are military intelligence spacecraft, details on their design and operation are not provided. IGS spacecraft are built by Mitsubishi Electric, likely based on a commercial satellite bus.

It is known that the spacecraft have a mass of about 1,000 to 1,400 Kilograms when launched in pairs and that power generation is accomplished by solar arrays. Satellites launched without a companion could be much heavier based on the payload capability of the H-IIA which can deliver up to four metric tons into an IGS-type orbit. Orbital data of IGS spacecraft is not provided regularly, but satellite trackers around the world have been keeping tabs on the constellation.

The IGS Optical 5 Satellite is an operational fifth generation optical satellite that follows in the footsteps of IGS IGS 8B satellite that serves an experimental role to confirm the functionality of the optical payload, clearing the instruments for operational deployment. Resolution of the 5th generation of optical satellites is believed to be better than 50 centimeters possibly as high as 40 centimeters.

8547060_orig.jpg
 
Last edited:
.
Japanese H-IIA Rocket successfully launches IGS Reconnaissance Satellite

A Japanese H-IIA launch vehicle lifted off from the country's picturesque launch site on Tanegashima Island at 1:21 UTC on Thursday, embarking on a mission to deliver the classified IGS Optical-5 satellite to a Low Earth Orbit to join Japan's fleet of Information Gathering Satellites.

The Information Gathering Satellites were approved for development in 1998 in response to a North Korean missile test that overflew the Japanese territory. At the time, Japan was relying on foreign satellite imagery that were only available after a certain delay and at significant cost.

The need of an independent capability to monitor activity on foreign territories to identify potential military threats was identified by the Japanese government that decided to press forward with the development of optical and radar reconnaissance satellites. The first launch of a pair of IGS satellites occurred in 2003 and over the years, over a dozen satellites were launched, going through constant improvements in capabilities and imagery resolution.

The IGS program is semi-secret up to a point where the Japanese government acknowledges its existence, however, details on the satellites are only available via secondary sources.

The IGS Optical-5 satellite is an operational fifth generation optical satellite that can achieve a ground resolution of better than 0.5 meters, joining an experimental 5th generation satellite that was launched in early 2013.

426px-Payload_fairing_of_GPM%27s_H-IIA_rocket.jpg


Launch Operations at the Tanegashima Space Center picked up around 11:30 UTC on Wednesday when the H-IIA rocket emerged from the Vehicle Assembly Building to make the 500-meter trip to the second launch pad at the Tanegashima Space Center.

Kicking off an overnight countdown, H-IIA - sitting atop the Mobile Launch Platform - was carefully centered on the pad and teams started the process of connecting the various propellant, pressurant, purge, power and data umbilicals. Next, a series of close out operations were completed at the launch pad before engineers departed the area to comply with the 400-meter safety zone for launch vehicle activation and testing.

With H-IIA on external power, the Launch Team started a series of testing operations looking at the electronics, Flight Control System, propulsion systems, Communication System and Flight Termination System. Engine slews on the first and second stage engines were performed and teams completed the final steps to start propellant loading.

Ahead of the initiation of fueling, the safety zone was widened to 3,000 meters and the Vehicle Assembly Building was cleared for launch. Illuminated on its launch pad, H-IIA headed into propellant loading operations around seven hours and 45 minutes prior to launch, picking up with the pressurization and chilldown of the Liquid Hydrogen and Liquid Oxygen Systems on the ground before transfer lines to the launcher were conditioned and the four propellant tanks on the two stages of the vehicle could enter chilldown.

Over the course of a three-hour sequence, the tanks of the H-IIA first stage were filled with about 100 metric tons of -183°C LOX and -253°C LH2 while the second stage received about 16,600kg of cryogenics. Entering topping, the tanks were kept at flight level as the supercold propellants naturally boiled off.

The fully-fueled launcher was put through another round of tests including a repetition of C- and S-Band comm checks, testing of the Flight Control system and verifications of various ground systems. The countdown entered a quiet period after testing was complete and teams and visitors were treated to a beautiful sunrise that could be seen from the sea-side launch complex.

h2btf1.jpg



The Terminal Countdown started at X-60 minutes marking the start of final reconfigurations of the H-IIA rocket for the Automated Countdown Sequence. A refined version of the flight parameters were loaded into the Flight Computers based on the latest measurements of conditions in the upper atmosphere. Weather was favorable for launch with clear skies, calm winds and warm temperatures.

The IGS Optical 5 satellite was switched to internal power as clocks ticked down, also being placed in flight mode to be ready for its trip into orbit. Teams made the final status check of all stations including the range and spacecraft team reported a GO to head into the Automated Countdown Sequence.

The precise launch time was programmed into all sequencers and the Automated Countdown commenced at X-4 minutes and 30 seconds to begin the highly choreographed process of transitioning H-IIA to its launch configuration. All launch vehicle parameters were continuously monitored by computers that were ready to trigger an abort in the event of any off-nominal indications.

The first step was the pressurization of the first stage tanks after the ground propellant feed was terminated at X-4:20. Pressurization took two minutes to complete. At X-3 minutes, the two-stage rocket was transferred from ground facility power to battery power - the Flight Termination System was switched to a fully independent power source to ensure the system could end the flight of H-IIA in the event of an in-flight failure.

f18_cd_03.jpg


With one minute on the countdown clock, the sound suppression system started pouring thousands of liters of water onto the launch pad to suppress the acoustic loads at booster ignition.


Launch vehicle ordnances were armed at X-30 seconds followed 12 seconds later by the Guidance System switching to flight mode. At X-11.5 seconds, the sparklers underneath the LE-7A Main Engine of the Core Stage ignited to burn off any residual Hydrogen that may be released during the Ignition Sequence.

Ignition sequence start was commanded at X-5.2 Seconds and the fuel and oxidizer valves of the main engine were opened and its turbopumps started spinning to flight speed. Engine ignition was carefully monitored by computers to ensure LE-7A reached its full liftoff thrust of 109,300 Kilograms.
When clocks hit zero, and LE-7A was up and running, the two Solid Rocket Boosters ignited and H-IIA blasted off under loud thunder with a total thrust of 575 metric tons. The rocket climbed vertically for a handful of seconds before beginning its pitch and roll maneuver to depart Tanegashima Island. No official broadcast by either JAXA of Mitsubishi Heavy was provided but amateur groups gathered at the launch site to cover the launch, providing live video and photos.

Although no information on the flight profile of H-IIA nor the target orbit of this mission were released, the mission design can very well be deduced from previous H-IIA mission to a polar orbit where IGS Optical 5, like all of its predecessors, is headed.

The satellites operate from orbits inclined 98°, an orbital inclination that can not directly be reached from Tanegashima, requiring H-IIA to use additional performance for a Dogleg maneuver - a powered turn during the ascent inserted into the trajectory to avoid any fragments of the rocket coming down over inhabited land masses.

Heading out to the south-east, H-IIA was to continue on that path throughout the booster-phase of the flight and into the late stages of first stage flight, reaching a downrange distance of over 100 Kilometers.


At that point, the vehicle was to gimbal its engine to turn westward to align itself with a south-westerly path towards a 98° orbit, avoiding the Philippines and frequented fishing areas.

Heading uphill, H-IIA passed Mach 1 about 75 seconds after liftoff followed by Maximum Dynamic Pressure as the launcher flew under the power of its cryogenic main engine and the twin boosters that did most of the work at that point in the flight.

Burning over 65 metric tons of solid propellant, each SRB delivered more than 230 metric ton-force of thrust to deliver the extra kick during the initial flight phase needed to get IGS into its planned orbit.

Thrust on the boosters tailed off after passing the T+100-second mark with computers detecting the pressure drop inside the boosters through onboard instrumentation, triggering the separation of the boosters that employed pyrotechnics and thrust struts that ensure a clean separation of both boosters.

With the boosters gone, only the LE-7A engine was powering the launch vehicle consuming 260 Kilograms of cryogenics per second to deliver 109,000 Kilogram-force of thrust.
Reaching an altitude of around 130 Kilometers, H-IIA separated its protective payload fairing to shed no-longer-needed weight since aerodynamic forces can no longer harm the satellite at this altitude.

Sticking to a standard mission profile, the first stage burned until six and a half minutes into the flight. Shutting down the LE-7A engine, the first stage was to initiate the staging process eight seconds after MECO, firing pyrotechnics that allow the 37-meter long stage to be pushed away from the second stage, clearing the engine.

After another six seconds, the LE-5B engine of the upper stage was to ignite on its only burn in this mission, heading directly for the target orbit which required the stage to fire for up to eight and a half minutes. LE-5B delivers 14,000 Kilogram-force of thrust and was planned to finish the dogleg maneuver.

f17_cd_09.jpg


Main Engine Cutoff was expected around 15 minutes after liftoff in an insertion orbit at an altitude of approximately 500 Kilometers. Spacecraft separation was to occur under 20 minutes into the mission to set the IGS satellite free for its mission dedicated to keeping a close eye on developments on the ground. Confirmation of a successful launch was provided by the Launch Team through nominal call-outs during the flight all the way to separation.

This was the second Japanese launch of the year and the second dedicated to the IGS program. The next IGS satellites will be launched in 2016. Still planned this year is the next flight of Japan's H-II Transfer Vehicle on a resupply mission to the International Space Station expected to launch atop an H-IIB in mid-August while H-IIA is set for its first commercial launch late in the year, carrying the TelStar 12V satellite into orbit and also debuting an upgraded second stage. Towards the end of the year, H-IIA is also planned to launch the New X-ray Telescope (NeXT).

Information Gathering Satellites

Information Gathering Satellites are Japan's primary intelligence satellites operated to deliver reconnaissance for the military and intelligence services in the form of optical imagery and high-resolution radar data. IGS satellites carry an optical reconnaissance payload or a Synthetic Aperture Radar for remote sensing. The main purpose of the satellite program is to provide an early warning capability of missile launches. IGS was initiated in 1998 in response to a North Korean missile test that flew over Japan.

re-entry that occurred on July 26, 2012. IGS 1A has been in a stable orbit until early 2012 when it started dropping, indicating that the spacecraft had depleted its fuel tanks or stopped functioning. It decayed in July 2014.

The second IGS launch in November 2003 ended in failure and never arrived in orbit when a Solid Rocket Booster failed to separate from the H-IIA rocket.

The IGS 1 and IGS 2 satellites were first generation spacecraft achieving a ground resolution for optical images of 5 meters (color) and about 1 meter (panchromatic). Synthetic Aperture Radar resolution is believed to be better than 3 meters.
IGS 3A was launched by H-IIA in September 2006 and represented the second generation of optical satellites that achieve a resolution of one meter. The satellite operated from an orbit of 480 Kilometers.

The IGS 4 satellite pair launched in February 2007 and included an experimental third generation optical satellite with a ground resolution of better than one meter, and a second generation SAR spacecraft also achieving a resolution of one meter. The satellites were found in an orbit of 481 to 494 Kilometers that they maintained until 2010. In the summer months of 2010, IGS 4B became non-operational for reasons that were not disclosed - it re-entered in November 2013. When satellite 4A stopped functioning is unclear, but orbital data suggests a loss of orbit control between mid-2010 to mid-2011 leading up to re-entry in April 2014.

IGS 5A is another optical satellite of the third generation launched in late 2009 and found in an orbit of about 585 Kilometers. In September 2011, the first fourth generation optical satellite was launched that is believed to achieve image resolutions of about 60 centimeters, operating in an orbit similar to that of IGS 5A. The first satellite in the third generation of SAR spacecraft was launched in December 2011 and operates from a 510-Kilometer orbit.

Another dual-IGS launch occurred in January 2013 when an H-IIA202 rocket delivered IGS 8A and 8B into an orbit of 513 Kilometers. The 8A satellite is a 3rd generation SAR spacecraft and 8B a 5th generation optical satellite that returns imagery at resolutions of under 50 centimeters The. 8A satellite remains in its 513-Kilometer orbit while 8B has entered a lower orbit at an altitude of 427 Kilometers.

6424132_orig.jpg


In January 2015, a satellite known as IGS Radar Spare (IGS 9A) entered orbit after a successful H-IIA launch, likely representing a 3rd generation satellite ordered as reserve for an earlier SAR satellite and being launched to be ready for the end of service of a SAR satellite, likely IGS 7.

Because the IGS Satellites are military intelligence spacecraft, details on their design and operation are not provided. IGS spacecraft are built by Mitsubishi Electric, likely based on a commercial satellite bus.

It is known that the spacecraft have a mass of about 1,000 to 1,400 Kilograms when launched in pairs and that power generation is accomplished by solar arrays. Satellites launched without a companion could be much heavier based on the payload capability of the H-IIA which can deliver up to four metric tons into an IGS-type orbit. Orbital data of IGS spacecraft is not provided regularly, but satellite trackers around the world have been keeping tabs on the constellation.

The IGS Optical 5 Satellite is an operational fifth generation optical satellite that follows in the footsteps of IGS IGS 8B satellite that serves an experimental role to confirm the functionality of the optical payload, clearing the instruments for operational deployment. Resolution of the 5th generation of optical satellites is believed to be better than 50 centimeters possibly as high as 40 centimeters.

8547060_orig.jpg

Please mention date of the OP, as well as a link to it.

Thanks!
 
.
Classified:p:.

:lol:You're mean!

Japan also can into making many missiles:

AAM-5

800px-JASDF_AAM-5_TVC_behn_20131124.JPG


1280px-JASDF_AAM-5_20131124.JPG


komatsu2010_08.jpg


800px-JASDF_AAM-5_Seeker_20131124.JPG


1024px-AAM-5-001.jpg


img_1


Performance specifications

Missile diameter
12.6cm
Missile overall length 2.86m
Missile full width 44cm
Missile weight 83.9kg
Warhead Directional warhead
Fuse Active laserproximity fuse
Firing range 35 km (19 nmi)
Promotion method Solid rocket
Induction system Mid sail: INS +CoLOS
end sail:infrared image (IIR)
Flying speed M3

Please mention date of the OP, as well as a link to it.

Thanks!

March 26, 2015. I'll convince my Swedish friend to add the date.
 
Last edited:
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AAM-4

e134.jpg


JASDF_AAM-4_Warhead_Section_20131124.JPG


800px-JASDF_AAM-4_in_Hamamatsu_Air_Base_20140928.JPG


JASDF_AAM-4B_20131124.JPG


635218324610170220jap1.jpg


Performance specifications
Missile diameter
20.3cm
Missile overall length 366.7cm
Missile full width 77cm
Missile weight 220 kg
Warhead Directional explosive warhead
Firing range Private (possibly around 100km)
Promotion method Solid fuel rocket( IHI AerospaceCo., Ltd.)
Induction system
Mid sail: inertia- command guidance
endings sail:ARH
Flying speed Mach 4-5
 
.
US approves sale of submarine-launched Harpoon Block II to Japan



The US Department of State has approved the possible sale of UGM-84L Harpoon Block II submarine-launched missiles to Japan.

p1630614.jpg

An artist's rendering of a Boeing Harpoon Block II missile. The US government has approved the possible sale of UGM-84L submarine-launched Block II missiles to Japan. (The Boeing Company)

The announcement was made on 13 May by the Defense Security Co-operation Agency (DSCA), which said the approval covered the sale of the missiles and associated equipment, parts, training, and logistics support. The deal is estimated to be worth USD199 million.

The government of Japan has requested 48 UGM-84L Block II missiles to supplement its existing Harpoon missile capability, the DSCA said.

The Japan Maritime Self-Defense Force (JMSDF) currently deploys UGM-84C and RGM-84C Harpoon missiles across its submarine and surface forces.



US approves sale of submarine-launched Harpoon Block II to Japan - IHS Jane's 360



@Indus Falcon @Transhumanist @SvenSvensonov @AMDR @F-22Raptor
 
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