Hunter F.6

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This page is about the British jet fighter Hunter F.6. For other versions, see Hunter (Family).
GarageImage Hunter F.6.jpg
Hunter F.6
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The early variants of the Hawker Hunter, the F.1 and F.2, faced significant issues including a lack of range and compressor stalls caused by the nose-mounted armament. These problems were addressed through the development of improved designs, the Avon-engined F.4 and Sapphire-engined F.5, which featured increased fuel capacity and modifications to the armament. These were further developed into the Hunter F.6, which had a larger engine, altered wing design, and increased fuel capacity. The F.6 became the Royal Air Force's frontline fighter until 1963, when it started being replaced by the English Electric Lightning. While Hunters in RAF service never carried any guided air-to-air armament, one Hunter F.6 was used as a testbed for the development of the Hawker Siddeley SRAAM, an alternative to AIM-9B Sidewinder and Firestreak missiles. Although the SRAAM program was eventually canceled, its design work laid the foundation for the AIM-132 ASRAAM.

Introduced in Update 1.89 "Imperial Navy", the Hunter F.6 is a further improvement of the preceding Hunter F.1 with a more powerful engine, retaining the excellent high-speed manoeuvrability and energy retention, as well as the complement of potent 30 mm ADEN cannons. However, its main feature is the extremely manoeuvrable but also extremely short range SRAAM missiles, whose thrust-vectoring capabilities allow them to easily hit targets at most angles within a 1 km radius. Unfortunately, they are very easily decoyed by flares. Being a subsonic airframe and lacking an afterburner, the Hunter F.6 is typically slower than its contemporaries at the battle rating, as well as lacking other increasingly common features such as countermeasures, RWR, or radar.

General info

Flight performance

Air brakes
Allows you to dramatically reduce the flight speed by releasing special flaps
Max speed
at 0 m1 148 km/h
Turn time25 s
Max altitude15 500 m
EngineRolls-Royce Avon Mk.203
Cooling systemAir
Take-off weight11 t

As with many early jet aircraft, the Hunter is slow and ungainly on takeoff and landing and is quite lethargic while flying at slow speeds. However, once this fighter begins to accelerate, it can hit speeds exceeding 800 km/h and similar to the early French Mystère fighters, can only achieve supersonic speeds during a dive. While a clumsy aircraft at low speeds, it is a rather good turning aircraft at higher speeds, though still surpassed by some sub and supersonic aircraft. It can hold a 9-10 G turn without risking breaking its wings, however, anything above this and you risk shearing off a wing. This fighter has extremely good energy retention, far above any supersonic and above many subsonic aircraft, which can be used to its advantage to maintain a controlling position on the battlefield.

Characteristics Max Speed
(km/h at 0 m - sea level)
Max altitude
Turn time
Rate of climb
Take-off run
Stock 1,138 1,132 15500 25.8 27.2 56.1 50.0 820
Upgraded 1,159 1,148 24.5 25.0 86.0 70.0


Combat flaps Take-off flaps Landing flaps Air brakes Arrestor gear Drogue chute
Wings (km/h) Gear (km/h) Flaps (km/h) Max Static G
Combat Take-off Landing + -
1,193 450 603 581 465 ~12 ~5
Optimal velocities (km/h)
Ailerons Rudder Elevators Radiator
< 850 < 600 < 690 N/A

Engine performance

Engine Aircraft mass
Engine name Number Basic mass Wing loading (full fuel)
Rolls-Royce Avon Mk.203 1 6,499 kg 249 kg/m2
Engine characteristics Mass with fuel (no weapons load) Max Takeoff
Weight (each) Type 4m fuel 13m fuel
1,175 kg Axial-flow turbojet 6,910 kg 7,868 kg 10,886 kg
Maximum engine thrust @ 0 m (RB/SB) Thrust to weight ratio @ 0 m (100%)
Condition 100% WEP 4m fuel 13m fuel MTOW
Stationary 4,242 kgf N/A 0.61 0.54 0.39
Optimal 5,132 kgf
(1,193 km/h)
N/A 0.74 0.65 0.47

Survivability and armour

Crew1 person
Speed of destruction
Structural0 km/h
Gear450 km/h
  • 64 mm Bulletproof glass - Armoured windscreen
  • 12.7 mm Steel - Armour plate behind the pilot

Modifications and economy

Repair costBasic → Reference
AB3 710 → 5 435 Sl icon.png
RB9 410 → 13 785 Sl icon.png
SB12 560 → 18 400 Sl icon.png
Total cost of modifications255 000 Rp icon.png
401 000 Sl icon.png
Talisman cost2 700 Ge icon.png
Crew training210 000 Sl icon.png
Experts740 000 Sl icon.png
Aces2 600 Ge icon.png
Research Aces1 010 000 Rp icon.png
Reward for battleAB / RB / SB
90 / 330 / 270 % Sl icon.png
226 / 226 / 226 % Rp icon.png
Flight performance Survivability Weaponry
Mods aerodinamic fuse.png
Fuselage repair
17 000 Rp icon.png
27 000 Sl icon.png
430 Ge icon.png
Mods jet compressor.png
14 000 Rp icon.png
22 000 Sl icon.png
350 Ge icon.png
Mods booster.png
New boosters
14 000 Rp icon.png
22 000 Sl icon.png
350 Ge icon.png
Mods aerodinamic wing.png
Wings repair
16 000 Rp icon.png
25 000 Sl icon.png
400 Ge icon.png
Mods jet engine.png
16 000 Rp icon.png
25 000 Sl icon.png
400 Ge icon.png
Mods g suit.png
21 000 Rp icon.png
33 000 Sl icon.png
530 Ge icon.png
Mods armor frame.png
14 000 Rp icon.png
22 000 Sl icon.png
350 Ge icon.png
Mods jet engine extinguisher.png
21 000 Rp icon.png
33 000 Sl icon.png
530 Ge icon.png
Mods armor cover.png
21 000 Rp icon.png
33 000 Sl icon.png
530 Ge icon.png
Mods ammo.png
17 000 Rp icon.png
27 000 Sl icon.png
430 Ge icon.png
Mod arrow 1.png
Mods pilon bomb.png
500 LB
17 000 Rp icon.png
27 000 Sl icon.png
430 Ge icon.png
Mod arrow 0.png
Mods pilon bomb.png
1000 LB
14 000 Rp icon.png
22 000 Sl icon.png
350 Ge icon.png
Mod arrow 0.png
Mods weapon.png
16 000 Rp icon.png
25 000 Sl icon.png
400 Ge icon.png
Mods pilon block rocket.png
Matra SNEB
16 000 Rp icon.png
25 000 Sl icon.png
400 Ge icon.png
Mod arrow 0.png
Mods air to air missile.png
21 000 Rp icon.png
33 000 Sl icon.png
530 Ge icon.png


Offensive armament

Weapon 14 x 30 mm ADEN cannon
Ammunition600 rounds
Fire rate1 200 shots/min
Main article: ADEN (30 mm)

The Hunter F.6 is armed with:

  • 4 x 30 mm ADEN cannons, chin-mounted (150 rpg = 600 total)

Suspended armament

List of setups (11)
Setup 12 x SRAAM air-to-air missiles
Setup 22 x 500 lb H.E. M.C. Mk.II bomb
Setup 34 x 500 lb H.E. M.C. Mk.II bomb
Setup 42 x 1000 lb M.C. Mk.I bomb
Setup 54 x 1000 lb M.C. Mk.I bomb
Setup 62 x 500 lb H.E. M.C. Mk.II bomb
2 x 1000 lb M.C. Mk.I bomb
Setup 74 x SRAAM air-to-air missiles
Setup 82 x 500 lb H.E. M.C. Mk.II bomb
36 x SNEB type 23 rocket
Setup 92 x 1000 lb M.C. Mk.I bomb
36 x SNEB type 23 rocket
Setup 1036 x SNEB type 23 rocket
Setup 114 x SRAAM air-to-air missiles
36 x SNEB type 23 rocket

The Hunter F.6 can be outfitted with the following ordnance:

  • Without load
  • 2 x SRAAM missiles
  • 2 x 500 lb H.E. M.C. Mk.II bombs (1,000 lb total)
  • 4 x 500 lb H.E. M.C. Mk.II bombs (2,000 lb total)
  • 2 x 1,000 lb M.C. Mk.I bombs (2,000 lb total)
  • 4 x 1,000 lb M.C. Mk.I bombs (4,000 lb total)
  • 2 x 1,000 lb M.C. Mk.I bombs + 2 x 500 lb H.E. M.C. Mk.II bombs (3,000 lb total)
  • 4 x SRAAM missiles
  • 36 x SNEB type 23 rockets + 2 x 500 lb H.E. M.C. Mk.II bombs (1,000 lb total)
  • 36 x SNEB type 23 rockets + 2 x 1,000 lb M.C. Mk.I bombs (2,000 lb total)
  • 36 x SNEB type 23 rockets
  • 36 x SNEB type 23 rockets + 4 x SRAAM missiles

Usage in battles

The Hunter F.6 is a transonic aircraft in level flight but can reach supersonic in a dive. That means that it is faster than other subsonic aircraft it will face but slower than supersonic aircraft like the F-100D and the MiG-19PT. Make sure to maintain speed, as it is most manoeuvrable at higher speeds, and very slow to turn when slow. The energy retention is almost an order of magnitude higher than supersonic aircraft, which bleed speed in sharp turns, this can be both a blessing and a curse, when in a prolonged turning engagement, your energy retention advantage will allow you to pull away from a supersonic at the end of a turn; however, a plane such as the F-100D can use it's worse energy retention to stay on your tail. In many situations, when you have a supersonic on your tail, making them overshoot is very difficult, but if you can, the SRAAMS will make short work of them. When facing subsonic aircraft, simply outrun them with your superior speed, try not to engage in a turn-fight with subsonic aircraft, as they are often able to best you in a dogfight, especially at low speeds, where the Hunter really shows its weaknesses. The plane, under most circumstances, does not rip it's wings, even under extended, high G turns; although if you combine a 9-10 G turn and roll or yaw, the plane can rip. Unlike some other planes, you have almost no chance of making it back to the airfield with a broken wing.

The SRAAMs (short range air-to-air missiles) have a unique playstyle. They are much shorter range than other missiles, but extremely manoeuvrable, able to turn inside most aircraft. Anytime that you are within around 1 km of the target and the speed difference is not too great, they are very unlikely to miss. If you are out of around 1.2 km or greater, the missile will run out of fuel before reaching its target. An important note is that the missile cannot manoeuvre after the rocket motor burns out, and self-destructs. The best use case is to fire them while in a turn with another aircraft, as the missile is manoeuvrable enough to cut them off.

The aircraft does have a rangefinding radar, but it is near useless except in simulator battles.


This aircraft is an extremely potent aircraft at its tier, but it has its weaknesses. For one, it does not turn very well, most supersonics and nearly all subsonic aircraft can outturn it. Secondly, it has good energy retention, so even supersonics may find it hard to disengage from a turning engagement. To attack this aircraft, come in from behind it, and preferably from the top or bottom. Do not attack from the front, as the quad 30 mm cannons will make short work of anything in their path. If your initial attack is unsuccessful, do not attempt to extend out in front of the Hunter; rather go into the vertical, as you will get caught by an SRAAM if you extend horizontal. If you suspect that a Hunter is nearby, do not allow your speed to drop below 800-1,000 km/h, as anything below these speeds will allow the Hunter to catch and kill you.

If you have one on your tail, and if you are in a supersonic, you should try to out-accelerate them, if they launch an SRAAM within 1km, you will not be able to dodge. If you are in an subsonic, do not attempt to extend, rather bring the Hunter to your teammates to get rid of them. If they launch a missile, there is very little you can do, but a hard roll while fully pitching up may allow you to dodge an SRAAM. In a subsonic, the Hunter can outrun you, so the best play would be to stay out of range of the Hunter, with teammate cover. In a supersonic, you are faster than the Hunter, so stay out of its range, while looping around and making passes at it, remember to never venture in front of it.


The Hunter F.6 is equipped with an AN/APG-30 rangefinding radar, located in the nose of the aircraft. It will automatically detect other planes within the scanning area and display the range to the closest target. It is linked with a gyro gunsight and can help with aiming at close range.

AN/APG-30 - Rangefinding radar
Azimuth Tracking
Elevation Tracking
2,750 m 300 m ±9° ±9°

Pros and cons


  • Highly agile short-range air-to-air missiles
  • Deadly nose-mounted 30 mm ADEN cannons
  • Enhanced handling at high speeds
  • Good payload options
  • Excellent energy retention


  • Subsonic
  • No countermeasures
  • No RWR
  • Heavily dependent on the missiles to perform well
  • No afterburner
  • No drogue chute: landing can be difficult on short runways
  • As with most jets, not very manoeuvrable at low speeds
  • Can rip wings when pitch and roll are combined with New Boosters equipped


When the Avon-engined Hawker Hunter F.1 and the Sapphire-engined Hawker Hunter F.2 entered service in 1954, it soon became apparent that the initial variants suffered a number of issues, the most important of which was its general lack of range. Flying on internal fuel supplies only, the aircraft's endurance was limited to about an hour, an issue which became painfully apparent on February 8th 1956 when a flight of 8 Hunters of the Central Fighter Establishment, a Royal Air Force training unit, were unable to land at their assigned base or divert to any suitable other base due to deteriorating weather conditions, with 6 aircraft being lost and one pilot killed in the ensuing confusion. Another important issue with the type was its nose-mounted armament which caused two distinct issues: at higher altitudes - and oddly enough, only on the Avon-engined F.1 variant - the gun exhaust gasses could be ingested by the wingroot air intakes, causing a compressor stall; on both versions, the cannon ammo links, which were ejected from the aircraft, had a tendency to strike the fuselage undersides, causing damage to the surfaces. The original concept of using the flaps as a split airbrake would in turn cause sudden pitch trim changes when deployed. While the latter issue was resolved relatively easily by adding a simple one-piece airbrake underneath the rear fuselage, the flight range and gun firing issues were much more serious, effectively rendering these early variants of the Hunter useless as fighter aircraft.

The issues with the design were identified relatively early on, leading to a crash program to rectify them. To improve the range of the Hunter, new bag-type fuel tanks were added inside the wing leading edge, as well as the ability to carry external fuel tanks underneath the wings, outboard of the landing gear. This increased the aircraft's endurance from just under an hour to about an hour and twenty-five minutes. Oddly, despite the comparatively short range of the type, the Hunter would never be given an in-flight refuelling capacity, simply because no funds were allocated for such a project in 1950s austerity Britain. The issues with the armament were in turn solved by the addition of baffles to the gun barrels, which diverted the gun exhaust gasses; and by adding large blisters underneath the nose to collect the spent ammo links. The resulting improved designs, the Avon-engined F.4 and Sapphire-engined F.5, first flew on October 19th and 20th 1954 respectively, entering squadron service in the spring of 1955 (the F.4 doing so with 54 Squadron in March of 1955; the F.5 with 263 Squadron in February of 1955). Despite the Sapphire variants suffering less issues than the Avon ones, production of them was cut short as they had only been intended as a 'fall-back' design in case the more advanced Avon had proved to be a failure. As a result, just 45 Sapphire-engined F.2s and 105 F.5s were built, compared to 139 Avon 100-engined F.1s and 349 F.4s. Additionally, 96 F.4s were built under license by Fokker for the Royal Netherlands Air Force, and 112 by Fairey Aviation for the Belgian Air Force. Another 120 F.50s - a nation-specific export version of the F.4 - were built by Hawker for the Royal Swedish Air Force, and 30 F.51s for the Royal Danish Air Force.

In the early 1950s, Rolls-Royce began working on the development of the Avon engine: the Avon 200 series was an uprated variant, which featured a can-annular combustion chamber and Sapphire style compressor. Due to these design changes, the Series 200 had a larger diameter than the Series 100, effectively making retrofitting the type impossible to earlier Hunters without rebuilding the entire fuselage. As such, a new fuselage was designed for the Hunter, which was capable of housing the large-diameter Avon 200, necessitating the move of a number of fuselage fuel tanks from the central fuselage to the rear. The increase of power offered by the new engine - 10,000 lb thrust for the Avon 203/207 as compared to 7,500 to 8,000 lb of the earlier Avon 113/115/119/120 and 121 - did introduce a new issue, namely a severe tendency for the type to pitch up at transonic speeds. In order to cure this, an altered wing was designed, which featured a distinctive 'dog-tooth' leading edge. Finally, the number of wing hardpoints capable of carrying additional fuel tanks was increased from two to four, considerably increasing the type's range. The resulting variant, the P.1099 or Hunter F.6, first flew on January 22nd 1954. This would prove to be the last dedicated fighter modification intended for Royal Air Force service.

Serial production of the Hunter F.6 commenced in 1956 with the first of 383 aircraft being delivered to the Royal Air Force in August of that year. As was the case with the F.4, license-production of the F.6 was taken up by Fokker and Fairey Aviation, who respectively produced 93 and 144 aircraft for the Royal Netherlands and Belgian Air Forces.

The Hawker Hunter F.6 remained the Royal Air Forces' frontline fighter until 1963 when it increasingly began to be replaced by the English Electric Lightning, which was a supersonic design capable of carrying air-to-air missiles. As its duties as a dedicated fighter came to an end, many of the Royal Air Force's Hunters were either converted to the FGA-9 ground attack variant (144 built including 12 F.6 conversions, entering RAF service in 1960) or bought back by Hawker for conversion to export variants.

While in Royal Air Force service the Hunter never carried any guided air-to-air armament, it is worth noting that the F.6s of the Royal Netherlands Air Force was the first of their type to be fitted with the Philco Ford GAR-6 (or AIM-9B) Sidewinder missiles and this as early as 1959. Similarly, the Hunter F.50s of the Royal Swedish Air Force were equipped with locally-built RB24B (AIM-9B) Sidewinder missiles in 1960. However, a single Hunter F.6 (XG210) was used as a testbed in 1977 during the development of a new type of air-to-air missile. This weapon, the Hawker Siddeley SRAAM or Short Range Air-to-Air Missile, was a weapon system developed as an alternative to the American Sidewinder and the British Firestreak missiles.

Originally developed as private venture under the name Taildog, the new weapon was intended as a Sidewinder replacement, a short-range, low-cost missile that would fill the gap between guns and then-current missiles like Firestreak and Red Top. Originally, its design aims were a missile capable of engaging targets between 250 m and 2 km on a very wide field of view, so that it would be capable of locking onto a target even if this was rapidly crossing the interceptor aircraft's path. In order to make it extremely agile, the weapon would make use of thrust vectoring through six vanes in the rocket exhaust. Design work started in 1968, but following an official request for proposals in 1972, 'Taildog' evolved from a private venture into an official study.

Under the new program, two versions were studied, namely the 'basic' SRAAM-75 and the 'advanced' SRAAM-100, both sharing the same airframe but having a different electronics fit each. Compared with Taildog, SRAAM was slightly longer and made use of a single-piece dome-shaped deflector, but otherwise, both designs were very similar. Unlike other designs of the time, SRAAM was designed to operate fully autonomic, with the target seeking system contained within the weapon rather than requiring radar or other feedback from the carrier aircraft. As such, SRAAM could be mounted on any aircraft without the need for weapons-specific modifications. Furthermore SRAAM was designed to be fired from a twin-tube pod that could be mounted to a single hardpoint, effectively doubling the number of weapons that could be carried by any aircraft (as opposed to designs like the Sidewinder, Firestreak or Red Top, of which just one could be carried on a single hardpoint).

Due to defence cuts, the contract for the SRAAM was cancelled in 1974 in favour of development work on the AIM-7 Sparrow-derived Skyflash, but development work continued, with the SRAAM being designated a technology demonstrator. As such, eight missiles were launched during weapons trials in 1977, both from a ground test stand and from a Hawker Hunter testbed. The same year, the improved AIM-9L Sidewinder was selected to cover the requirements originally covered by the SRAAM. Work performed on the SRAAM design would go on to form the basis of the ASRAAM program, which was started in 1980 and eventually resulted in the AIM-132 ASRAAM which entered RAF service in 1998.


With the availability of the more powerful Rolls-Royce Avon 200 series engines in the early 1950s, the Hawker company began developing a new modification of their Hunter jet fighter, which would eventually result in the creation of the Hunter F.6 - one of the last dedicated fighter modifications of this aircraft.

The new Hunter featured, apart from a more powerful engine, a number of other tweaks and changes, most notably, a redesigned wing which contributed to the aircraft's overall stability during transonic flight. The first prototype of the F.6 flew in January 1954, with serial production commencing in 1956. Overall, 383 aircraft of the type entered service with the RAF before being decommissioned in the early 1980s.

In the late 1970s, the Hunter F.6 was used as a testbed for a new type of air-to-air missile developed by Hawker Siddeley since the late '60s. The SRAAM, or Short Range Air-to-Air Missile, was a weapon system developed as an alternative to the American Sidewinder and the British Firestreak missiles.

As the name suggests, the SRAAM was designed for shorter range deployments during dogfights, in situations where pilots would find it difficult to achieve a reliable lock-on with existing missiles. As such, the SRAAM possessed extremely good agility and didn't cost as much to produce, but was severely limited in range. Despite this however, the weapon didn't see active use, but was instead further developed into a more advanced version which eventually did get adopted and is still in use today.



See also

Related development
Aircraft of comparable role, configuration and era

External links

Hawker Aircraft Limited
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