Showing posts with label JASDF. Show all posts
Showing posts with label JASDF. Show all posts

Thursday, 27 June 2019

Gone In 35 Seconds : Spatial Disorientation And The First Fatal F-35 Crash  



 F-35A Photo : JASDF




The Lockheed Martin F-35 Lightning II is one of the newest and most advanced tactical fighter that is beginning to populate the air forces of the United States and some of its allies in sufficient numbers to make a difference operationally. Despite having a difficult development cycle which was plagued with everything from cost over-runs to performance issues, the F-35 has a relatively benign safety record and managed to remain crash-free for 12 years since its first flight. That all changed in October 2018 when a US Marine Crops F-35B suffered engine failure and crashed during a routine training flight in South Carolina. Fortunately there were no fatalities as the pilot managed to eject safely.

The first and only fatal crash of the F-35 occurred on 9th April 2019 and it involved a Japan Air Self Defense Force F-35A operating out of Misawa Air Base ( 三沢基地 ). The crash site was the Pacific Ocean some 135km due east of Misawa. The pilot apparently flew the aircraft at high speed into the sea and did not send any signal of distress nor attempted to eject prior to impact. Parts of the wreckage were found scattered over a wide area on the seabed at a depth of 1500m. After 2 months of investigations, the JASDF concluded that spatial disorientation was most likely the cause of the mishap though gravity induced loss of consciousness could also be a remote possibility.

How could an accident like this happen and what is spatial disorientation? Could better pilot training have prevented such an accident?



F-35A 89-8706 Photo : JASDF



Japan's F-35A


The Japanese MOD placed an initial order for 42 F-35A back in Dec 2011 to replace its fleet of ageing F-4EJ Phantoms. 4 would be assembled at Lockheed Martin's Fort Worth plant while the rest would be built at the Mitsubishi Heavy Industries Komaki South F-35 Final Assembly and Check Out ( FACO ) facility in Aichi Prefecture. In those days the unit cost of the F-35A was USD126million or about JPY14billion. JASDF has so far received 13 F-35A and they are assigned to the 302nd Tactical Fighter Squadron of the 3rd Air Wing based at Misawa Air Base. Misawa is located in Aomori Prefecture in the North-eastern region of Japan. Aomori is famous for its apples and also for its scallops farmed in Mutsu Bay.


F-35A 79-8705 at Misawa AB on 2 Nov 2017 for safety checks
 before its trans-Pacific flight to the US. USAF Photo
 
 
JASDF F-35A 79-8705 escorted by a USAF F-16 assigned to the 115th Fighter Wing,
Wisconsin Air National Guard on its maiden voyage across the Pacific on 6 Nov 2017.
Photo : USAF




The Fatal Accident


According to press release information from JASDF ( Japanese only ), the F-35A that crashed had the serial number 79-8705 and production number AX-5. It was the first Japanese-assembled F-35A and it was only unveiled at the Komaki plant on 5th Jun 2017. Its first flight was on 12th Jul 2017. It was flown to Misawa AB on 2 Nov 2017 to prepare for the trans-Pacific flight to the US for final flight testing. This was to ensure all future Japanese assembled F-35s were up to standard. It went into active service on 28th May 2018 with the transitional F-35 squadron, a temporary unit of the JASDF, before the aircrafts were assigned to the 302nd TFS. The 302nd TFS had been operating out of Hyakuri AB for several years and only completed the relocation to Misawa Air Base in March 2019.

The pilot was subsequently revealed as Major Hosomi Akinori ( 細見彰里 ), a 41 year old veteran with 3200 hours of flight experience but only 60 of those hours were type specific for the F-35A. Japanese media stated that this aircraft has the latest Block 3F mission software with full warfighting capability.



F-35A 79-8705 at Nagoya Airport NKM/RJNA on 2 Nov 2017
Photo Yabyansan via flyteam.jp


On that fateful Tuesday evening of 9th April 2019, the sun had set at 1805 hours. Maj Hosomi was the flight leader for a group of four F-35A on routine air combat maneuvering ( ACM ) training over the Pacific Ocean off the coast of Aomori. The formation took off from Misawa Air Base at 1859 hours and proceeded to perform two-on-two ACM training. At 1925 hours Maj Hosomi reported that the two opposing aircrafts had been shot down in the training with the transmission " 21, two kills ", 21 being his call sign. At 1926 hours the F-35A was at an altitude of 31500ft when ground controllers advised the major to make a turn to port and to descend in order to maintain a safe distance from an approaching US military aircraft ( type unspecified ) at 37000ft. Maj Hosomi replied " Affirmative, Roger " and began his turn and descend. Twenty seconds later, upon completing the turn and by then descended to 15500ft, Maj Hosomi transmitted in a calm voice " Roger, Knock it off " ( meaning termination of training ). Information from datalink and ground radar would later reveal that at this stage the F-35A descended with a speed of 900km/h. Within the next 15 seconds, the F-35A would continue its rapid descend from 14500ft with a speed of 1100km/h and then disappeared from the radar screens when it plunged below 1000ft. The time of impact was estimated at 1926 hours 30 seconds.




Plan view ( view from above ).
Red arrow shows path of Hosomi's F-35A.
Green arrow shows passing US military aircraft.
1. 1925hrs  2. 1926hrs  3. 1926hr15s  4. 1926hr30s
Source : JASDF


Side View ( vertical view ) Source JASDF




Spatial representation of F-35A final flight path. JASDF


Search and Rescue


The search and rescue ( SAR ) effort was probably activated the moment team mates and ground control lost contact with the distressed F-35A. JASDF reported that by 1947 hours eleven of their SAR assets were already airborne. At 1950 hours 5 ships and 2 aircrafts from the Maritime Self Defense Force ( JMSDF ) also joined the search effort. At 2145 hours floating debris had been located. Some of these were later recovered by a UH-60J helicopter from the SAR team operating out of Akita at 2210 hours. At 2248 hours the destroyer escort Chikuma was also on site to recover floating debris. The Air Staff had by then ( 2230 hours ) established an accident investigation committee. Eventually US Forces Japan and the Japanese Coast Guard would also chip in with SAR assets. The various units involved in the immediate SAR effort were as follows:

JASDF : 2 x U-125A and 2 x UH-60J Blackhawk
JMSDF : 1 x P-3C Orion and 1 x SH-60J Seahawk and 5 ships
USFJ    : 1 x P-8 Poseidon
JCG      : 3 ships


U-125A SAR Bizjet



UH-60J SAR Helo




Crash site is in the Pacific Ocean 135km east of Misawa AB.
Exact location of the wreckage is kept secret for obvious reasons.

 

Recovery and Salvage



In the week following the crash up to 17th April, multiple P-8A Poseidon Multi-mission Maritime Aircraft and the guided missile destroyer USS Stethem ( DDG-63 ) also joined in the JASDF-led search effort covering some 5000 sq nautical miles in area.

The USN subsequently chartered a commercial dive support and construction vessel, the Van Gogh, to assist in the search. The Singapore-operated Van Gogh with its onboard USN salvage team supported the search efforts of the research vessel Kaimei, owned by the Japan Agency for Marine-Earth Science and Technology ( JAMSTEC ) and the JDS Chiyoda, a submarine rescue tender of the JMSDF. The 5747t Kaimei has sophisticated equipment to conduct high resolution 2D and 3D survey of the seafloor and is equipped with a remotely operated vehicle that can dive to a depth of 3000m.

The USN also deployed the latest version of its cable-controlled undersea recovery vehicle, the CURV-21 and the TPL-25 ( Towed Pinger Locator ) system in the salvage operation. On or after 3rd May, parts of the flight data recorder a.k.a. the black box were recovered. It was however severely damaged and no useful data could be retrieved. Its recovery therefore did not help in the crash investigation. Much of the wreckage were scattered in a wide area under 1500m of seawater.


The Kaimei deep-sea research vessel

The Van Gogh transiting Naha, Okinawa on 16th April 2019.
Credit on photo.
 
TPL-25 is a towed sensor used for locating emergency relocation pingers
 on downed navy and commercial aircraft at a maximum depth of 20000ft.
USN Photo 



The USN finally called off the search and salvage effort on 8th May though the Japanese MOD felt obliged to continue until they too gave up on 4th June, almost 2 months after the crash. Maj Hosomi's body was never found and his death was confirmed by the Japanese MOD on 7th June. Following the crash Japan has grounded its remaining fleet of 12 F-35A and suspended pre-delivery flight tests for the 14th F-35 from MHI's Komaki FACO facility.


Air Crash Investigation



With the paucity of information obtainable from the wreckage, the crash investigators had relied heavily on communications, ground radar tracking and peer-to-peer datalink information from the F-35's Multifunction Advanced Data Link ( MADL ) to reconstruct the unfolding events prior to the fatal accident. They eventually came to the conclusion that it was most likely due to pilot error, specifically spatial disorientation, that caused the crash. Engine failure was possibly ruled out as the aircraft in question was flying quite normally less than a minute before the crash and there were no signs that the pilot found anything amiss and no alarm had been raised regarding any malfunctions. The last radio transmission from the pilot in a calm voice 15 seconds prior to impact also supported the fact that nothing of distress had been detected at that point in time.

The investigators also somehow determined that Maj Hosomi did not attempt to eject from his aircraft as it was barreling towards the surface of the sea and neither did he respond to alerts from the aircraft's warning systems such as the ground proximity warning system.

The execution of several abrupt maneuvers in rapid succession which included turning, rolling and descending could have severely affected his spatial awareness leading to the wrong corrective actions, potential converting a dangerous situation into an irrecoverable one. The final verdict of the investigators named spatial disorientation to be the most likely cause of the fatal crash with gravity -induced loss of consciousness as a remote possibility.

So what is spatial disorientation and what role does it have in aviation disasters? In order to understand spatial disorientation, we need to dwell into realm of aeromedical physiology a little.

 


Introduction to Spatial Disorientation by Hank Caruso
Image : Naval Aviation News

 

Spatial Orientation


Spatial orientation refers to the natural human ability to maintain our body orientation and posture in relation to our physical environment, at rest and during motion. From an evolutionary point of view humans are adapted to maintaining spatial orientation to the ground. Three-dimensional environments encountered during flight or deep diving are unfamiliar to the human body and can create sensory conflicts and illusions that makes spatial orientation difficult or sometimes impossible to achieve.

According to the Federal Aviation Administration ( FAA ), statistics show that between 5 to 10% of all general aviation accidents can be attributed to special disorientation, of which 90% are fatal.


Sensory Systems


Achieving spatial orientation requires the effective perception and interpretation of sensory inputs from the visual, vestibular, proprioceptive and auditory senses.

Visual references provide the dominant sensory information to maintain spatial orientation. This is especially true if our body and / or environment is in motion.

The vestibular system located in the inner ear has two distinct components with the 3 semicircular canals responsible for detecting angular acceleration ( rotational movements ) in 3 different axis corresponding to the pitch, yaw and roll movements of an aircraft while the otolith organs ( utricule and the saccule ) detects linear and gravitational acceleration respectively.

The proprioceptors are sensory receptors located in the muscles, tendons, joints and skin that play a small role in maintaining spatial orientation. They do however give some indication of posture by sensing the relative position of our body parts in relation to each other and by sensing points of physical contact between body parts and the surrounding environment.

Auditory input has the smallest role among all the senses involved in maintaining spatial orientation.

The Federal Aviation Administration videos below may help you understand the functions of the vestibular system.






Vestibular Illusions Leading To Disorientation



Since visual cues are the most important sensory input for maintaining spatial orientation, the loss of a reliable external visual reference point such as the horizon at night or in adverse weather may lead to the vestibular and proprioceptive systems not interpreting the actual motion of the body through space correctly. Here are some of the vestibular illusions that can occur during flight. Somatogyral illusions originate from the semi-circular canals while somatogravic ones originate from the otolith organs :

The Leans ( somatogyral ) - sudden return to level flight after a gradual and prolonged turn that was unnoticed by the pilot

The Graveyard Spin ( somatogyral ) - entering a prolonged ( more than 15 or 20 seconds ) spin intentionally or unintentionally, the pilot gradually loses the sensation of turning and when the turn is corrected feels a strong sensation of turning in the opposite direction. Any attempts to correct this false illusion results in the aircraft returning to spinning in the original direction, all the while losing altitude. Ground impact is inevitable unless this spatial disorientation is recognized early.





The Graveyard Spiral ( somatogyral ) - similar to Graveyard spiral but caused by return to level flight after prolonged intentional or unintentional bank turn.

The Coriolis Illusion ( somatogyral ) - also known as the cross-coupled stimulation, it is a severe tumbling sensation brought about by moving the head out of the plane of rotation, simultaneously stimulating one set of semi-circular canals while deactivating another set. It can happen when the pilots tilts his head upwards, downwards or sideways when the aircraft is turning. It causes a strong and unpleasant sensation of tumbling which often has a rapid onset. The tumbling feeling can be bad enough to cause nausea and the pilot may feel the aircraft pitching, rolling and yawing all at the same time. It can result in the pilot quickly becoming incapacitated by vertigo and losing control of the aircraft. The severity of this phenomenon is a function of the magnitude of the initial turn, the direction of the head movement and the speed at which the head movement is made.

The G-Excess Illusion ( somatogyral ) - a vestibular illusion that can occur even in VFR ( visual flight rules ) conditions. Happens when the aircraft enters a tight turn that puts more than 1G load on it and the pilot looks back at the turn. An illusion of underbank occurs if the head is facing the inside of the turn elevated or if the head is facing the outside of the turn depressed. The pilot can erroneously perceive that the angle of bank and G-load are decreasing. The instinctive reaction to apply more bank could stall the aircraft or result in ground impact and is particularly dangerous in low altitude and high speed operations. Here's a USAF video on the G-Excess illusion.





Inversion Illusion ( somatogravic ) - usually involves high performance aircrafts, a steep ascend followed by a sudden return to level flight causes the illusion of tumbling backwards or being inverted. The pilot invariably respond by lowering the nose of the aircraft which intensifies the illusion.

Head-Up Illusion ( somatogravic ) - sudden forward linear acceleration during level flight creates illusion that the nose of the aircraft is pitching up. The pilot's response is to pitch the nose down. Night take-off from a well-lit airport into a completely dark sky and carrier catapult take-off are examples that can cause this illusion.

Head-Down Illusion ( somatogravic ) - sudden linear deceleration during level flight creates sensation that the aircraft is pitching down. The pilot may then pitch the nose up and if this occurs when the airspeed is already low such as during final approach, a stall may be inevitable.

With so many possible scenarios that can lead to spatial disorientation, I have had a new found respect for aviators, especially those who fly advanced military fighter jets. It should be noted that visual illusions, of which there are just as many compared with vestibular illusions, have yet to be included in the discussion since they are not relevant in the final flight of F-35A 79-8705.


G-Excess Illusion by Hank Caruso
Image : Naval Aviation News


What Could Have Happened



The sky would be dark over the Pacific Ocean off the coast of Misawa by 1926 hours on 9th April 2019. The waxing crescent moon would have been setting and close to the south-western horizon. The ocean surface would have been dark save for a few dim lights from fishing vessels or the occasional commercial vessel transiting through that area. If there were significant cloud cover on that night, it could have made things worse. Therefore one could possibly conclude that there would have been little visual input for Maj Hosomi and his team when they were flying that night. The most important sensory system for maintaining spatial orientation had been removed.

If the flight path diagrams released by the MOD were drawn to scale and were accurate, we can see that Maj Hosomi's F-35 did make some maneuvers in its final 2 minutes of flight that could potentially trigger spatial disorientation. There was the sustained turning which began from 1925 hours when he was directed to descend but at no point was there a sudden return to level flight. There was also an initial rapid descend followed by an even more acute turning rate before the final plunge.

From the communications intercepts, Maj Hosomi was still communicating normally 15 seconds prior to impact. So it is likely that the spatial disorientation could have taken place earlier but went unrecognized by Maj Hosomi or a sudden and highly debilitating event could have taken in the last 15 seconds of flight.

Looking at the flight profile I would say a G-Excess type spatial disorientation could be the most likely illusion encountered by Maj Hosomi. After all, he was turning at relatively low altitudes ( 14500ft and below ) and at very high speed ( in excess of 1100km/h ) in the final 15 seconds of flight. Looking back at the turn at this point in time could trigger the G-Excess phenomenon and if he had responded inappropriately by increasing the angle of bank without a corresponding increase in back pressure on the stick, the result will be a rapid deterioration into a controlled flight into terrain ( CFIT ) situation. There may simply not be enough altitude or time for recovery.

The Coriolis type phenomenon is also possible during the final turn taken by the F-35 as Maj Hosomi could have inadvertently looked up, down or sideways during the turn thus triggering the incapacitating tumbling sensation characteristic of this vestibular illusion. It could be severe enough to make him lose control of the aircraft.

Contributing factors that could have lead to the loss of spatial orientation include fatigue, inclement weather, unexpected change of flight plans, distractions caused by equipment malfunctions, personal time pressures and even the personal attitude of the pilot ( self-confidence ). Many of these factors could be at work on that fateful night.



The waxing crescent moon on 9th April 2019



The waxing crescent moon would be close to the southern horizon
in the constellation of Sagittarius not far from Saturn.
Image : Sky and Telescope 



How To Prevent Spatial Disorientation


The surest way to completely prevent becoming spatially disorientated is to avoid flying altogether. If that's not an option, then experiencing spatial disorientation illusions in a controlled environment such as a Barany chair, a vertigon, or better still a Virtual Reality Spatial Disorientation Demonstrator ( spatial disorientation trainer ) can be important to help raise the awareness of spatial disorientation and to enable the aviator to recognize spatial disorientation early should it occur during flight.

The FAA's advice to avoid flight conditions that may lead to spatial disorientation is sensible but obviously not applicable to military pilots who may have to fly in the most adverse conditions.

That said, if the aviator still find himself or herself caught in a state of spatial disorientation, the most appropriate action would be to disregard one's sensory perception and to trust the flight instruments instead.

In its press release, the Air Staff concluded with separate recommendations for preventing G-LOC and spatial disorientation among F-35 pilots. For the latter, it recommended better pilot education and awareness on spatial disorientation as well as training on spatial disorientation trainer and training on flight simulator.

So let's take a closer look at spatial disorientation trainers and what they can do.


Virtual Reality Spatial Disorientation Demonstrator


The sensation of spatial disorientation cannot be faithfully reproduced in a conventional flight simulator. To experience such vestibular illusions one would need a special spatial disorientation trainer such as those made by the American company ETC Aircrew Training Systems. Such trainers not only enable pilots to experience the feeling of spatial disorientation and learn to recognize some of those illusions, they also train pilots in coping and recovery skills in an interactive environment.



ETC GL-6000 Spatial Disorientation Trainer aka Kraken.
Image : ETC Aircrew Training Systems


ETC makes many different types of air crew training equipment including several models of spatial disorientation trainers. The most advanced of these would be the GL-6000 Kraken - a research grade SD trainer that would set you back USD19million, and the price does not include the facilities you would need to house it. The only commissioned unit belongs to the US Navy and is located at the Captain Ashton Graybiel Acceleration Research Facility at Naval Medical Research Unit Dayton, Wright-Patterson AFB. The Kraken is so amazing it can have sustained motion in 360 degrees over 6 axis - pitch, yaw, roll, vertical, horizontal and planetary. It can reproduce a sustained 3G acceleration and can reproduce the motion forces experienced in not just fixed-wing aircrafts but also rotary, high speed watercrafts, submarines, high-speed land vehicles and more.

Of course not everybody can afford the Kraken or needs the Kraken. The JASDF has been a loyal client of ETC for the past 30 years with its purchase of the Gyrolab GL-1500 basic spatial disorientation trainer in 1989 followed by the purchase of the Gyrolab GL-4000 advanced spatial disorientation trainer in 2006. ETC announced the decision by the Japanese Defense Agency ( as the Ministry of Defense was then known as ) to purchase the GL-4000 in March 2005 and quoted the price at USD 4 million. It was to replace the then more than 15 year old GL-1500.



Gyrolab GL-1500 Basic SD Trainer. Used by JASDF since 1989.
Replaced by the GL-4000.
Image : ETC Aircrew Training Systems



Gyrolab GL-4000 Advanced SD Trainer. Used by JASDF since 2006.
Replaces the older GL-1500.
Image : ETC Aircrew Training Systems

Using its proprietary GYROLAB technology, ETC's spatial disorientation simulators provides the pilot with the most realistic flight experience short of actually flying the aircraft by combining the latest cutting edge flight simulation technology, including simultaneous ± 360 degree motion in pitch, roll, yaw and planetary, with real-world high definition visuals, realistic engine and flight sounds, detailed cockpit with closed loop flight controls and high fidelity flight models. These fixed and rotary flight profiles are flight-realistic and fully automated. Instructors can also create their own flight profiles through a proprietary editor software thereby allowing the trainer to keep pace with changing training requirements throughout its life cycle. ETC claims that the GYROLAB's ± 360 degree motion capability and its planetary motion, which gives it the capability to generate up to 3.0 Gs, makes it the most realistic and effective flight trainer currently available. And since all axes of motion can be used simultaneously, it can accurately reproduce the motion cues that cause pilots to mistake their aircraft position and motion with respect to the earth's surface, an error we call spatial disorientation or 空間識失調 ( Kukan Shiki Shicho ) as the Japanese know it.


Spatial Disorientation - The Scourge



Spatial Disorientation has always been a serious problem affecting military air forces and commercial airlines worldwide, resulting in many lost pilot ( and passenger ) lives and billions of dollars of aircraft losses. ETC estimated that it accounts for about a third of all military aircraft accidents globally.

The situation can only worsen as military aircrafts become increasing more complex and capable with faster acceleration, tighter turns and higher climbing rates. Increasingly challenging flight activities, increased night and inclement weather operations, night vision goggle flight operations all contribute to a greater risk of the occurrence of spatial disorientation.

Even the most experienced pilot can be susceptible to being spatially disorientated as basic human anatomy and physiology dictates our usual response to unusual external stimuli and those illusions, whether visual, vestibular or otherwise will affect the rookie and the veteran in exactly the same way. Having experienced spatial disorientation before will also not confer immunity to its effects in the future. It will however allow the disorientation event to be recognized more readily the next time it is encountered.

The only cost effective way to prevent spatial disorientation in military pilots of high performance jets is through education, by increasing awareness, and through training on a dedicated spatial disorientation trainer. The ultimate aim is to train the pilot to be able to recognize spatial disorientation early enough to apply the necessary coping and recovery response to avert a potential disaster. Awareness and preparedness are the two pillars in preventing spatial disorientation related accidents.

The loss of JASDF's F-35A with its pilot was a tragic accident from which lessons can be learnt. Since the cost of an advanced spatial disorientation trainer like the ETC GYROLAB GL-4000 or the AMST Airfox is miniscule compared to the cost of a modern 4th or 5th generation fighter jet, maybe all current and future F-35 operators should consider channeling more funds and effort in the procurement and the effective use of such training apparatus.

If God had intended us to fly, he would have made us better ears. Remember, 35 seconds, probably less, was all it had taken to destroy a brand new stealth fighter and claim the life of its pilot.



Addendum



In response to reader comment ... Thanks Ax

Although the Automatic Ground Collision Avoidance System ( Auto GCAS * ) has already been successfully installed on the F-16 since 2014 and has been credited with several saves since, the F-35 currently only has an earlier version of the software known as the Manual Ground Collision Avoidance System ( MGCAS ). This will require the pilot to be able to hear, see, process and heed the MGCAS warning and manually fly the aircraft away from the ground. MGCAS will not prevent a ground collision if the pilot is already unconscious or severely incapacitated by spatial disorientation.

The only thing that could have saved Major Hosomi will be an Auto GCAS, which upon failure of a correct response to a ground collision warning, will assume temporary control and engage the autopilot to row the aircraft upright and initiate a 5-G pull, getting the pilot and aircraft out of harm's way. Unfortunately Auto GCAS has yet to be operational on the F-35.

With successful implementation of the Auto GCAS on the F-16, the knowhow and experience allowed the Air Force Research Laboratory at Wright-Patterson AFB to fast-track F-35 Auto GCAS development and testing. Originally slated for F-35 Block 4.3 upgrade in late 2025, all tests for the life-saving technology has been completed in April 2019, and has been recommended for fielding, seven years ahead of schedule.

Meanwhile, work on the Automatic Integrated Collision Avoidance System goes on ...

AFRL's video on Auto GCAS here.

* In Japanese Auto GCAS is known as 自動地表面衝突回避システム
 
 
Automatic Collision Avoidance Technology / Fighter Risk Reduction Program Logo
Image : NASA
















Tuesday, 12 July 2016

The Quest For Stealth : Japan's Mitsubishi X-2 Experimental Fighter 日本三菱重工 X-2 ステルス戦闘機

 
 
 
 
First Flight of the Mitsubishi X-2 on 22nd Apr 2016.
Photo credit Akira Uekawa
 
 

 

Japan's Stealth Fighter Program



Japan has a nascent stealth fighter program run by the Ministry of Defense's Acquisition Technology And Logistic Agency ( ATLA ) for the Japan Air Self Defense Force ( JASDF ) and it is known as the Advanced Technology Demonstrator - X  ( ATD-X ) Stealth Fighter Program or 先進技術実証機 senshin gijutsu jisshoki. As the name implies, it is a prototype to test advanced concepts in stealth and other aviation technology that can ultimately be utilized by a future generation fighter design.

Not many countries in the world can boast of having independently embarked on stealth aircraft development. Apart from the United States who is the undisputed leader in stealth technology, only Russia, China and Japan can claim to have truly indigenous stealth fighter programs. Being a Tier 1, Tier2 or Tier 3 partner in the Joint Strike Fighter Program does not count since most of the work is done by the Americans.

The Russian effort has resulted in the Sukhoi PAK-FA ( T-50 ) which is about to enter service this year while the Chinese are said to have the J-20 already in low rate initial production ( LRIP ) and are in an advanced stage with their J-31. This article takes a closer look at how the Japanese are fairing.


Replacing JASDF's Ageing Fighters



The JASDF currently operates a fleet of ageing fighter aircrafts including the Vietnam War era F-4EJ Kai, the F-16 derived F-2 and the F-15J. Back in 2005, they were really keen to have the F-22A as the replacement for some of these old aircrafts, but to safeguard its supremacy in stealth technology, the United States decided not to export their most capable stealth fighter to anyone, not even to their most trusted ally Japan. Instead, the Americans have been pushing everybody to accept the second best option, the problem plagued, expensive and long overdue F-35 Joint Strike Fighter ( JSF ). So, in a way, the Japanese had been forced to develop their own stealth fighter. The ATD-X program was launched.

Meanwhile, with the F-4EJ way beyond its sell-by date, and perhaps alarmed by the emergence of Chinese stealth jets, the Japanese finally decided in 2011 to acquire 42 F-35A JSF as an interim measure to replace the Phantoms. 38 of the 42 F-35A will be assembled by Mitsubishi Heavy Industries in their Nagoya plant. Mitsubishi will also be involved in testing the JSF's stealth against radars, and the experience gained in the development and manufacturing of the F-35 should contribute towards the development of Japan's indigenous stealth fighter.


Mitsubishi Heavy Industries



Mitsubishi Heavy Industries ( MHI 三菱重工 ) is a conglomerate with interests spanning the aerospace, marine, land transport, energy and environment domains. Their products are so diverse that it is almost impossible to list everything. Some of the more prominent ones include the Soryu-class attack submarine, the Mitsubishi Regional Jet ( MRJ ), Atago-class Aegis destroyers, Patriot SAM system and the Type-10 MBT.

All of JASDF's post-war fighter aircrafts had so far been designed or license-produced by MHI, from the F-86 Sabre to the F-104J Starfighter, followed by the F-4EJ Phantom, F-1, F-15J, F-2 and now the F-35.

Of course those who are familiar with military history will tell that Mitsubishi is actually most famous for the long range carrier-borne fighter known as the A6M Zero or the Reisen (零戦). This legendary fighter was designed by aeronautical engineer Jiro Horikoshi ( 堀越二郎 ), and its performance was unmatched by any western combat aircraft at the beginning of World War II, attaining a kill ratio of 12:1. It was extensively used by the Imperial Japanese Navy on the raid on Pearl Harbour in Dec 1941, an event that marked the beginning of the Pacific War.



1:72 scale model of the Mitsubishi A6M2b Zero ( Type 21 ).
 Photo : Hasegawa Model Co.



So, it is quite obvious that MHI has been a key player when it came to Japanese fighter design and production for close to a century, stretching back to the pre-war years.
 

 


Mitsubishi X-2 Stealth Fighter



The X-2 is a single-seat, twin-engine, thrust-vectoring, low-observable technology demonstrator. It has a shape similar to other stealth aircrafts like the F-22 and the PAK-FA with a flat looking body and two outward canting vertical stabilizers. The air intake ducts were shaped to conceal the engine fan blades from radar waves and access panels have serrated edges. In fact it looked like a miniature version of the F-22.

It was initially launched as the ATD-X program following the failure by Japan to acquire an export version of the F-22, the project was under the jurisdiction of the Technical Research and Development Institute ( TRDI ) which was the predecessor of the current ATLA.

Anechoic chamber tests carried out in France in 2005 on a full scale ATD-X model suggested that it had a radar cross section ( RCS ) equivalent to an object the with a size somewhere between that of an insect and a bird. These electromagnetic spectrum reflection and absorption tests were originally intended to be done at a USAF test facility but approval was not granted.

In the spring of 2006, a radio-controlled 1 : 5 scale model of the ATD-X constructed out of carbon fibre reinforced plastic with a length of 3m and width of 2m and a weight of 45kg was first flown at the Multi-Purpose Aerospace Park in the Taikicho District of Hokkaido ( 北海道大樹町 ). A total of 4 such remotely controlled aircrafts were eventually constructed and 40 test flights were conducted until Nov 2007.

Subsequently, the ATD-X program was given the full go ahead in 2007. Mitsubishi Heavy Industries was appointed the main contractor. As usual the early developments were cloaked in secrecy. The stealth prototype was commonly referred to as the Shinshin ( spirit of the heart ).

In order to keep developmental cost low, the X-2 reuses some components from previously developed aircraft types. This included the canopy and the ejection seat from the Kawasaki T-4 intermediate jet trainer which itself was taken from the Mitsubishi F-1 strike fighter. The main and rear landing gears were taken from the Mitsubishi T-2, the jet trainer developed from the F-1.

By 2009 39.4 billion yen had already been invested. 90% of the X-2's components are indigenously manufactured in Japan. Mitsubishi manufactures the fuselage and landing gears, Kawasaki the cockpit and canopy, Fuji the main wing and tail stabilizers, IHI the engines, in total about 220 Japanese aerospace companies supplying several hundred thousand different parts and components.

The ATD-X prototype was officially unveiled on 28th Jan 2016 by which time it had been given the designation X-2.

Advance technology that the ATD-X will test and evaluate includes the usual stuff one would expect for a 5th generation stealth fighter and more :

Low observable or stealth technology, like radar absorbing coating and materials. The body of the aircraft is said to be covered with a layer of new composite material of ceramic and silicon carbide capable of absorbing radar waves. The canopy itself would be emission-proofed with its own special coating.

Second generation AESA radar. Japan is the first country to have an AESA radar installed on a production combat fighter the Mitsubishi F-2 and that was almost twenty years ago. Although initially plagued with problems, the technology had matured and the experience gained by Japan would no doubt be a useful contribution towards the design of a new generation AESA radar.

Thrust vectoring and super-maneuverability. Each engine nozzle have a trio of unusual paddle contraptions similar to what was seen on the German-American X-31 experimental aircraft for vectoring engine thrust.

Indigenously developed high-thrust low by-pass turbofan capable of super-cruising - sustained super-sonic flight without the involvement of afterburners. Some of the experience gained in developing the XF5-1 engine for the X-2 had already been applied to the production F-7-10 engine used by the P-1 maritime patrol aircraft.

Fly-By-Light advance fibre optic flight control system, likely an improved version over the first generation control system used in the P-1. This Integrated Flight Propulsion Control ( IFPC ) links flight control with nozzle and thrust control to enable some form of automatic recovery from combat damage.

Next generation Infra-Red Search and Tract ( IRST ) and radio frequency sensors as well as Head Up Display and Helmet Mounted Display technology.

Advance Electronic Support Measures ( ESM ) and Electronic Countermeasures ( ECM ) suites. Likely electronic attack capability.

The specifications for the X-2 are as follows :


Length : 14.2m

Wingspan 9.1m

Height : 4.5m

Weight : 9.7 tons

Engine : IHI XF5-1 Afterburning Turbofan x 2

 
 
Thrust vectoring paddles of the super-maneuverable X-31
experimental aircraft. Wikipaedia


IHI XF5-1 Afterburning Turbofan. Wikipaedia 
 
 
A 1:14 scale transonic (遷音速) wind tunnel model of the X-2,
also known as the Shinshin ( 心神 ), on display at the
 JASDF Hamamatsu Air Park taken during my visit
on 11th Jun 2016.

 
 
 
 

First Flight




Since the X-2's official unveiling on 28th Jan 2016, it had attained several important milestones. Low speed ground taxiing test was carried out on 11th Feb followed later by high speed full afterburner acceleration test on the runway.

After several delays due to technical issues and poor weather, the X-2 finally took to the skies for the very first time on 22nd Apr 2016. At 0847 hours local time, the experimental aircraft took off from Nagoya Airport in Aichi Prefecture, flew for 26 minutes and landed at the JASDF Gifu Air Base about 50km away at 0913 hours. The X-2 was accompanied by at least two chase planes, a F-2 and a F-15. During the brief, uneventful flight, the X-2 attained a maximum altitude of 12000 feet and a maximum speed of 370km/h. It underwent simple tests like ascend, descend and circling operations after entering the designated test flight zone. It also made a few simulated landings in the air before a final safe touch down. The MHI test pilot subsequently described the aircraft's handling as extremely stable and that it performed just as the simulator training had predicted. The Ministry of Defense considered the first flight a successful test in their press release ( in Japanese ).

The second flight of the X-2 took place on 18th May 2016 and was again rather uneventful. It was supposed to accelerate to a higher speed and retract its landing gears.

In the next two years or so, if all goes well, the X-2 will be performing another 50 test flights for more in depth studies of its aerodynamic and stealth characteristics. After that, Japan can decide whether it wants to pursue this stealth fighter venture on its own or if it wishes to partner other countries to develop the next generation fighter for the JASDF.



The X-2 during its maiden flight on 22nd Apr 2016. JASDF Photo


 
The X-2 during its maiden flight on 22nd Apr 2016. JASDF


The X-2 accompanied by a F-2 chase plane during its maiden flight. JASDF
 
 
 
Video of maiden flight.
 
 
Another video of first flight. 
 
 
Video of second flight
 
 
 



The Mitsubishi F-3



The Japanese hope that the technology used in the ATD-X / X-2 will eventually lead to the development and fielding of a new generation indigenous stealth fighter by 2030. This next generation fighter will presumably be designated the F-3, as the previous generations of fighters were designated the F-1 and the F-2.

The F-3 will likely be the replacement for both the F-15J and the slightly newer F-2. The F-15J began its service with the JASDF in 1984 and celebrated its 30th anniversary 2 years ago. They would have served 46 years in the JASDF by 2030. The F-2 entered service in 2000 and would have served 30 years by the end of the next decade.

Physically, the F-3 will have to be a lot bigger than the X-2 as it would have to carry loads of fuel to achieve the long endurance that the JASDF required to defend their island chains. The bigger airframe will also provide for a large internal weapons bay ( which the X-2 lacks ) for at least six large missiles and of course, bigger and more powerful engines.

You can watch the computer generated animation of the F-3A and the F-3E Strike Shinshin attacking a Chinese Carrier Battle Group in a sea battle in the year 2035, shooting down J-15s with cannons, AAM-4 and AAM-5 missiles and sinking two aircraft carriers with ASM-3 anti-ship missiles. Yes, go kick some Chinese Ass. Just don't expect the final F-3E, wherever that came from, to be shaped like what was depicted in the movie, with delta wings and without vertical stabilizers like the B-2 Spirit.




Japanese and Chinese carrier battle groups slug it out in this imaginary sea battle in 2035



Failure Is Not An Option?



Just like ship hulls, no airframe would last forever. Ageing aircrafts would have to be retired and replaced when they reach their rated flight hour limit. Japan's frontline combat fighters face an ever increasing operational tempo in recent years with record numbers of airspace violation incidences from Chinese aircrafts in the south and Russian aircrafts in the north. In FY2015 ( 1 Apr 2015 to 31 Mar 2016 ) MOD figures indicated 571 scrambles against Chinese aircrafts alone and 873 scrambles in total. At this rate, the F-15s and the F-2 may well have to be replaced even earlier than projected.




Latest cumulative JASDF scramble data from 1958 ( Showa 33 ) to 2016 ( Heisei 28 )
released on 5th Jul including figures for 1Q2016 ( red bar ), a record breaking 281 sorties.
Vertical axis indicates total number of scrambles while horizontal axis indicates the year.



So there is a sense of urgency for the X-2 stealth fighter program to progress in a timely manner and to culminate in the form of Japan's next generation fighter by the year 2030. Failure is really not an option.

The Japanese MOD had already issued a request for information on the next generation fighter to replace the F-2 from foreign and domestic aerospace companies, to be submitted by 5th Jul 2016. A tender worth an estimated $40 billion for about a hundred aircrafts will be launched sometime this month with MHI, Boeing, Lockheed Martin, SAAB and the Eurofighter Consortium either already invited or expressing interest. It is believed that three options existed, buying or upgrading an existing design ( F-15J? ), buying a new aircraft type from a foreign supplier and finally a domestically developed aircraft, likely with the help of foreign partners. A decision on the tender will be made by 2018 and the aircraft likely to enter service at the end of the next decade.

Currently, perhaps only two things could derail the X-2 program and prevent the development of an indigenous F-3. If the United States would come to its senses and somehow not only restart the production of the F-22 Raptor but agree to export it to Japan at a reasonable price, that could kill the X-2 and the F-3. If the F-35A could overcome its teething problems in short order and morph into the 5th generation fighter that it was supposed to be, coupled with a significant decrease in price with the commencement of volume production, that too could affect the X-2. In truth, neither of these hypothetical scenarios look likely to happen in the near term.

If and when the X-2 program is brought to fruition in the form of an operational 5th generation stealth fighter, it might just be the most significant weapon system developed in post-war Japan. And that's because at least for the free world, it would break the monopoly of the F-35 as the only option for an export stealth fighter.

To many Japanese, the X-2 is a symbol of hope that Japan could once again produce a world class fighter and be a dominant player in the aviation industry, just like it did 80 years ago with the Mitsubishi A6M Zero. That dream will progressively become closer to reality with each successful test flight of the X-2. Go forth and soar with the winds. Gambatte X-2!  

Wednesday, 15 June 2016

JASDF Chitose Air Festival 2015 Special Stamp Issue 航空自衛隊 平成27年度 千歳基地航空祭 特殊切手

 

Chitose




Chitose City ( 千歳市 ) is located in the southwestern part of Japan's Hokkaido Island and is probably most well known as a gateway to Hokkaido with its Shin-Chitose International Airport ( 新千歳空港 ). It is about 40km form Sapporo which is the biggest city in Hokkaido.

Co-located with the Shin-Chitose International Airport is the Japan Air Self Defense Force's ( JASDF 航空自衛隊 kokujietai ) Chitose Air Base. Such arrangements with military air base and civilian airport side by side is apparently quite common in Japan, as we have previously seen in Naha, Okinawa.

Every summer, the Chitose Air Base will have an Air Festival where the grounds will be open for the public and aircrafts and equipment displayed. There will also be flight demonstrations, helicopter rides, fun, food and entertainment. Of course businesses will be quick to churn out souvenirs and memorabilia of all sorts to commemorate the event. In this aspect, Japan Post is no exception and there was a special limited edition stamp issue last year, and the year before, just for that.

 
 





The Chitose Air Festival 2015 Special Stamp Issue



As it turned out, I was in Chitose earlier this month for the 36th Chitose JAL International Marathon. Shortly after landing at Chitose Airport, I happened to drive past a small post office not far from the main entrance of the North Chitose Garrison of the Japan Ground Self Defense Force and decided to check it out. Imagine my delight when I discovered that there were 4 complete sets of the limited edition Chitose Air Festival 2015 stamp sheetlet for sale. I vaguely remembered that I had wanted to order this item online from Japan Post last year when it was issued but failed to do so because it was sold out in a matter of days! I grabbed all four.

In any case, this special stamp set comprising of 2 separate sheetlets of ten ¥82 and ¥52 stamps respectively was issued on 15th July 2015. Only a total of 1300 sheetlets of each denomination was released, making it a limited edition. They were available from 38 post offices in cities around the air base including Chitose, Eniwa, Kita-Hiroshima, Sapporo and Otaru. The ¥52 sheetlet came bundled with a big B5 sized postcard and a folding paper fan while the ¥82 sheetlet had a sheet of stickers depicting the various aircrafts of the air base. Both sell for ¥1800 each, or about USD17.00 at today's exchange rates, consumption tax included, which was way above their face value, just like the JGSDF Kamifurano Garrison stamp issue.



The ¥52 sheetlet of 10 sticker stamps.


The folding paper fan bundled with the ¥52 sheetlet.


Giant B5 sized postcard depicting the Boeing 747-400
special transport, Kawasaki T-4 trainer and
Mitsubishi F-15J fighters bundled with
the ¥52 sheetlet.


The ¥82 sheetlet of 10 sticker stamps.




The sticker sheet that came with the ¥82 sheetlet showing F-15J
in 203 Fighter Squadron 50th anniversary
as well as JASDF 60th anniversary paint schemes.



History of Chitose Air Base




Chitose Air Base ( 千歳基地 Chitose Kichi ) is JASDF's northern-most major air base. It is tasked to monitor and protect Japan's maritime border with Russia. It started out as a airfield built from a ten hectare plot of land donated by the villagers of Chitose and had its first flight in 1926. In 1934 the landing strip was extended and by 1937 it was taken over by the Imperial Japanese Navy. After the end of World War II was taken over by the United States Army Air Force and later the United States Air Force.

It was used mainly as a logistics and maintenance facility in the years leading to the Korean War, and then as an emergency landing field for aircraft returning from combat missions in Korea. It was also around that time ( 1951 ) when it started the first scheduled civilian flights to Tokyo, operated by Japan Airlines. So in effect the air base served a dual purpose as a civilian airport as well.

The USAF returned the facility to Japanese control in 1957 and the newly formed JASDF wasted no time in transferring its 2nd Air Wing with its F-86F from Hamamatsu Air Base to Chitose that same year. By 1963 a passenger terminal was built and immigration facilities were added in 1972, just in time for the Sapporo Winter Olympics.

In 1974, the 2nd Air Wing had its F-86Fs replaced by the then state of the art F-4EJ Phantom. The Phantoms were eventually transferred to Okinawa in 1985, after Chitose began receiving the F-15J as their replacement.

Chitose Airbase was the original intended destination of the Soviet MiG-25 fighter pilot Viktor Belenko during his daring defection to Japan on 6th Sep 1976 forty years ago. He missed Chitose due to poor weather ( poor visibility ) and shortage of fuel and ended up landing at the civilian airport at Hakodate. You can read about the entire MiG-25 incident here.


Aerial photograph of Chitose Air Base and Airport in 1975. Wikipaedia




In 1988, the construction of the Shin Chitose Airport was completed and the civilian air traffic was channeled to its dedicated runway. By 1996, a second runway was added and military and civilian traffic were completely segregated, each with their own runways but sharing the same air traffic control.


Chitose Air Base and Shin Chitose Airport ( New Chitose airport ) in 2009.



Enlarged from above image. UH-60J, CH-47J, T-4 and F-15J clearly identifiable.




Today, Chitose Air Base is home to the JASDF's Northern Air Defense Force's 2nd Air Wing comprising of the 201st and 203rd Tactical Fighter Squadrons ( F-15J and T-4 ), the 3rd Air Defense Missile Group comprising of the 9th and 10th Missile Battalion ( Patriot PAC-3 ), the Special Airlift Group with its 701st Squadron ( Boeing 747-400 ) and the Chitose Air Rescue Squadron ( U-125A and UH-60J ) together with all their support and maintenance units.

 You can watch the excellent JASDF video below ( in Japanese ) about Chitose Air base to learn about its units and operations.








Mitsubishi F-15J and F-15DJ : 201st and 203rd Tactical Fighter Squadrons




The Mitsubishi F-15J and the twin seat F-15DJ are currently the most numerous and capable frontline multi-role fighter of the JASDF. They have been in service since 1984, replacing the Lockheed F-104 Starfighter. Already being selected as Japan's next generation fighter in 1975, their acquisition was accelerated by the sudden realization of a serious air defense capability gap when on 6th Sep 1976, a defecting Soviet MiG-25P Foxbat intruded into Japanese air space over Hokkaido and landed at Hakodate Airport without being intercepted by the Japanese fighters ( 2 x F-4EJ Phantoms, 302nd TFS ) scrambled from Chitose Air Base.

The F-15J and the twin seat DJ version will eventually be replaced by Japan's next generation fighter, presumably known as the F-3, by the end of next decade.



F-15J of the 201st TFS with JASDF 60th anniversary colours.




F-15J of the 201st Tactical Fighter Squadron with JASDF 60th anniversary paint scheme.


This exact photo was used for the stamp design shown above.
F-15J of the 201st TFS with JASDF 60th anniversary paint scheme.
Photo : Chitose Air Base / Japan MOD

 
 
F-15J of the 203rd Tactical Fighter Squadron with their
50th Anniversary paint scheme.

 
The same F-15J 52-8847 depicted on the stamp above with
203rd Tactical Fighter Squadron 50th anniversary paint scheme.
Photo : Chitose Air Base / Japan MOD
 
 
2 F-15J over snowy mountains.
   
 
2 F-15J from the 201st and 203rd TFS over snowy mountains.
This photo was used in the stamp design shown above.
Photo : Chitose Air Base / Japan MOD


F-15J of the 203rd Tactical Fighter Squadron.
Photo Chitose air base / Japan MOD


F-15J of the 201st Tactical Fighter Squadron " Fighting Bears " ( 闘羆 tatakae higuma ).
Photo Chitose air base / Japan MOD







 

 
 
 




Boeing 747-400 VIP Transport : Special Airlift Group


The decision to acquire two Boeing 747-400 special transport for the Japanese Government were made in 1987 and the aircrafts were delivered in late 1991. Initially registered as civilian aircrafts under the jurisdiction of the Prime Minister's Office, these Jumbo Jets were transferred to the Japanese Defense Agency ( now Ministry of Defense ) in 1993. They form the 701st Squadron of the Special Airlift Group ( 特別航空輸送隊 Tokubetsu Kokuyusotai ) which is based in Chitose Air Base.

They are mainly used for transporting members of the Japanese Royal Family and ministers of the Japanese Government while they are on official duties, as well as for ferrying visiting foreign dignitaries. They are also used for flying SDF personnel on peacekeeping missions, evacuating overseas Japanese citizens during times of crisis and occasionally for transporting refugees of other nations during conflicts elsewhere in the world.

The venerable Boeing 747 is a design that dates back to the sixties and is no longer in production. These ageing transports are slated for retirement in 2019, so they will not be around for much longer. The Special Airlift Group's headquarters is in Chitose Air Base.




Boeing 747-400 VIP transport with F-15J.





Boeing 747-400 VIP transport taking off.





Boeing 747-400 VIP transport with
a pair of F-15J.



This exact photo of the Boeing 747-400 VIP transport with 2 escorting
F-15J was used in the stamp design shown above.
Photo : Chitose Air Base / Japan MOD
 

Boeing 747-400 of the Special Airlift Group over
Lake Shikotsu, Hokkaido. Photo : JASDF SAG
 
 
Good things come in twos. The first aircraft for the
mission and the second as spare. Photo JASDF SAG.


Close-up of the Boeing 747-400 taking off. Photo : JASDF SAG





JASDF Special Air Lift Group emblem
Image : Special Air Lift Grp
 



701st Squadron emblem depicting Cygnus, the constellation of the the Swan.
The star is probably Deneb or Alpha Cygni, the brightest star
in the constellation of Cygnus. Image : Special Air Lift Grp


Boeing KC-767J : 404th Tactical Airlift Tanker Squadron


The JASDF has 4 Boeing KC-767J Multi Role Tanker Transport ( MRTT ) with the 404th Tactical Airlift Tanker Squadron based at Komaki Air Base in Aichi Prefecture. They are the military derivative of the Boeing 767-200ER airliner and has a tail boom for fuel transfer. It was based on the shorter 767-200ER as there was concern with the boom striking the ground during take off and landing if the 767-300 with a longer fuselage was used.

As its name implies, it can be used as a transport for personnel and cargo or as an aerial tanker. JASDF actually has another derivative of the Boeing 767, the E-767J Airborne Early Warning And Control ( AWACS ), under the 602nd Squadron based in Hamamatsu Air Base in Shizuoka Prefecture. The aircraft depicted in the stamp lacks a rotating radar dome on its upper fuselage and is therefore not likely the be the E-767 but is the KC-767J instead.

I suspect the KC-767J is routinely deployed to Chitose because I happened to photograph one sitting inside the air base shortly after I arrived at Shin Chitose Airport, while being ferried to the car rental outlet.


Likely the KC-767J at the Air Festival in this low resolution image of the stamp.





The KC-676J in a 2015 photo. Wikipaedia
 
 
KC-767J 97-3603 photo taken from motorway at the perimeter of Chitose Air Base 3rd Jun 2016. 


UH-60J : Air Rescue Squadron


The Chitose Air Rescue Squadron  ( 航空救難隊 Koku Kyunantai ) operates 2 types of aircraft. The fixed-wing U-125A search aircraft ( 救難捜索機 ) which is a derivative of the British Aerospace 125, a twin-engine mid-size corporate jet and the Mitsubishi UH-60J Blackhawk Search and Rescue helicopter ( 救助機 ).

The SAR squadron is responsible for locating and saving victims of air crash accidents and they also help out with large scale disaster relief operations, mountaineering accidents and sea rescues.


Mitsubishi UH-60J of the Chitose Air Rescue Squadron.


A Mitsubishi UH-60J Blackhawk of the
Hyakuri Air Rescue Squadron seen with external fuel tanks.
Photo : Wikipaedia
 
 
UH-60J of the Niigata Air Rescue Squadron in
Niigata Air Base 50th anniversary colours in 2012. wikipaedia

The U-125A search aircraft is not depicted by the stamps
but it does equip the Chitose Air Rescue Squadron. Wikipaedia



Kawasaki T-4 : Blue Impulse Aerobatics Team


The Blue Impulse is JASDF's flight demonstration team with a history tracing back to 1960. Then the first generation aircraft used was the North American F-86F Sabre, followed by the Mitsubishi T-2 from 1980 and finally the Kawasaki T-4 Intermediate Jet Trainer ( 中等練習機 ) from 1995. The Blue Impulse aerobatics team of the 11th Squadron are not indigenous to Chitose but are based in Matsushima Air Base. They are at Chitose to perform their aerial stunts during the Air Festival and are therefore included in the stamp design.

However, the 201st and 203rd Tactical Fighter Squadrons are composite units with F-15J/DJ fighters and T-4 trainers and it is not uncommon to see these T-4 buzzing around the skies of Hokkaido. Just last October, I was exploring the Hell Valley of Noboribetsu Onsen which is near Chitose when a couple of T-4 overflew the resort town low enough for me to have a visual ID.

 

 
 

 
 

 
 
 
 
 
Number 5 aircraft of the 6 plane Blue Impulse
aerobatics team flying low in 2009. Photo : Wikipaedia


Kawasaki T-4 of the JASDF's Blue Impulse Team performing
their aerial display in 2010. Photo : Wikipaedia
 
 
Blue Impulse patch



 The Chitose Air Festival 2016


The annual Chitose Air Festival ( 千歳基地航空祭 Chitose Kichi Koku Matsuri ) is a publicity event for the JASDF where it can showcase its equipment and capabilities. It is also probably an effective way to recruit new members for the Self Defense Force and might just inspire the next generation to join the military service when they grow up.



The date of the Chitose Air Festival 2016 has been finalized : 7th Aug 2016.
Image : Chitose Air Base / Japan MOD
 
 



If you are in Hokkaido this August, why not consider visiting the Chitose Air Festival 2016? It will be held on 7th Aug and admission is free. How to get there? If you are arriving at Shin-Chitose Airport, you are already there! Go to the Airport's train terminal, the JR Minami-Chitose Station and there will be a temporary shuttle bus stop less than 5 minutes walk away with buses to bring you to the Air Base ( 10 min ¥210 ) from 7am to 1:30pm. Return trips from the Chitose Air Base to the train station starts from 1:30pm until 4:30pm. From Sapporo, take the rapid train service towards Chitose Airport from JR Sapporo Station to the JR Minami-Chitose Station ( 30 min, ¥840 non-reserved seats, ¥1140 reserved seats ) and similarly walk to the same temporary bus stop ( see image below ).

If you drive or rent a vehicle, park at the Kirin Beer Factory and take the shuttle service from the car park ( green label in the map below ). Kirin Beer has a huge car park for visitors and was also one of the designated parking areas for the Chitose JAL International Marathon.




Minami-Chitose Station ( Red Arrow ) is just outside the perimeter of Chitose Air Base ( in lilac )




 

And while you are at it, keep a lookout for the corresponding special stamp issue for 2016 which I am quite certain will be released. Why am I so sure? Because Japan Post has been doing this annually since 2012 ( see below ). Already the 2015 ¥52 sheetlet which originally cost ¥1800 is now retailing for ¥2880 online. That's a 60% appreciation in less than a year, a benchmark which even the best fund manager would find difficult to beat!



 

 
 




 
The 2015 stamp sheetlet in its retail packing.

 
The Blue Impulse at Chitose Air Festival 2016 on 7th Aug. Photo : JASDF Twit