Difference between revisions of "R-60"

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{{About
 
{{About
 
| about = Soviet air-to-air missile '''{{PAGENAME}}'''
 
| about = Soviet air-to-air missile '''{{PAGENAME}}'''
| and
 
 
| usage = other versions
 
| usage = other versions
| link-1 = R-60M
+
| link = R-60 (Family)
| link-2 = R-60MK
 
 
}}
 
}}
 
[[File:R-60.png|thumb|x250px|R-60s mounted on the [[MiG-21SMT]]]]
 
[[File:R-60.png|thumb|x250px|R-60s mounted on the [[MiG-21SMT]]]]
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{{Navigation-Start|Vehicles equipped with this weapon}}
 
{{Navigation-Start|Vehicles equipped with this weapon}}
  
{{Navigation-First-Line|'''Jet fighters'''}}{{Specs-Link|mig-21_sps_k}}{{-}}{{Specs-Link|mig-21_mf}}{{-}}{{Specs-Link|mig-21_smt}}{{-}}{{Specs-Link|mig-21_bis}}
+
{{Navigation-First-Line|'''Jet fighters'''}}
{{Navigation-Line|}}{{Specs-Link|mig_23mld}}{{-}}{{Specs-Link|mig_23mla}}
+
{{Navigation-Line|MiG-21}}{{Specs-Link|mig-21_sps_k}}{{-}}{{Specs-Link|mig-21_mf}}{{-}}{{Specs-Link|mig-21_mf_hungary}}{{-}}{{Specs-Link|mig-21_smt}}
 +
{{Navigation-Line|MiG-29}}{{Specs-Link|mig_29_9_13}}{{-}}{{Specs-Link|mig_29_9_12_germany}}{{-}}{{Specs-Link|mig_29_9_12b_hungary}}
  
{{Navigation-Line|'''Strike aircraft'''}}{{Specs-Link|su_17m2}}{{-}}{{Specs-Link|su_22m3}}{{-}}{{Specs-Link|su_22um3k}}{{-}}{{Specs-Link|su_25}}{{-}}{{Specs-Link|yak-38}}{{-}}{{Specs-Link|yak-38m}}
+
{{Navigation-Line|'''Strike aircraft'''}}
 +
{{Navigation-Line|Su-17}}{{Specs-Link|su_17m2}}
 +
{{Navigation-Line|Su-22}}{{Specs-Link|su_22m3}}{{-}}{{Specs-Link|su_22m3_hungary}}{{-}}{{Specs-Link|su_22um3k}}
 +
{{Navigation-Line|Su-25}}{{Specs-Link|su_25}}
 +
{{Navigation-Line|Yak-38}}{{Specs-Link|yak-38}}{{-}}{{Specs-Link|yak-38m}}
  
{{Navigation-Line|'''Attack helicopters'''}}{{Specs-Link|mi_24p}}{{-}}{{Specs-Link|mi_24p_german}}{{-}}{{Specs-Link|mi_24p_german_hfs80}}{{-}}{{Specs-Link|mi_24v}}
+
{{Navigation-First-Line|'''Attack helicopters'''}}
 +
{{Navigation-Line|Mi-24}}{{Specs-Link|mi_24p}}{{-}}{{Specs-Link|mi_24p_hungary}}{{-}}{{Specs-Link|mi_24p_german}}{{-}}{{Specs-Link|mi_24p_german_hfs80}}{{-}}{{Specs-Link|mi_24v}}{{-}}{{Specs-Link|mi_24v_hungary}}
  
 
{{Navigation-End}}
 
{{Navigation-End}}
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== General info ==
 
== General info ==
 
<!-- ''Tell us about the tactical and technical characteristics of the missile.'' -->
 
<!-- ''Tell us about the tactical and technical characteristics of the missile.'' -->
 +
 
{| class="wikitable" style="text-align:center"
 
{| class="wikitable" style="text-align:center"
 
! colspan="2" | Missile characteristics
 
! colspan="2" | Missile characteristics
 
|-
 
|-
| '''Mass''' || 44 kg
+
| '''Mass''' || 43.50 kg
 
|-
 
|-
 
| '''Guidance''' || IR
 
| '''Guidance''' || IR
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| '''Lock range (rear-aspect)''' || 5 km
 
| '''Lock range (rear-aspect)''' || 5 km
 
|-
 
|-
| '''Launch range''' || 8 km
+
| '''Launch range''' || 10 km
 
|-
 
|-
 
| '''Maximum speed''' || 2.5 M
 
| '''Maximum speed''' || 2.5 M
Line 47: Line 52:
 
| '''Maximum overload''' || 30 G
 
| '''Maximum overload''' || 30 G
 
|-
 
|-
| '''Missile guidance time''' || 21 secs
+
| '''Missile guidance time''' || 25 secs
 
|-
 
|-
 
| '''Explosive mass''' || 1.15 kg TNTeq
 
| '''Explosive mass''' || 1.15 kg TNTeq
Line 69: Line 74:
 
=== Comparison with analogues ===
 
=== Comparison with analogues ===
 
<!-- ''Give a comparative description of missiles that have firepower equal to this weapon.'' -->
 
<!-- ''Give a comparative description of missiles that have firepower equal to this weapon.'' -->
Compared to the most common air-to-air missiles such as AIM-9J or R550 Magic, R-60 tends to have the upper hand in most chasing/dogfighting scenarios due to its extended turning capability possible through the long engine burn time and high G tolerance although this is offset by its distinctly larger seeker FOV and smaller gimbal compared to the AIM-9J and R550 Magic. The smaller gimbal means leading the missile is more difficult compared to its contemporaries.
+
Compared to the most common air-to-air missiles such as AIM-9J or R550 Magic, the R-60 tends to have the upper hand in most chasing/dogfighting scenarios due to its extended turning capability possible through the long engine burn time and high G tolerance although this is offset by its distinctly larger seeker FOV and smaller gimbal compared to the AIM-9J and R550 Magic. However, the R-60 has a much more limited range then the AIM-9J and the Magic and the smaller gimbal means leading the missile is more difficult compared to its contemporaries.
  
 
== Usage in battles ==
 
== Usage in battles ==
Line 75: Line 80:
 
'''Important details:'''
 
'''Important details:'''
  
Every missile greatly performs better when at higher altitudes, this should be used to your advantage as missiles becomes unavoidable when launched at a reasonable range and altitude if the target doesn't deploy countermeasures, missiles accelerate faster, pull harder and reach higher velocities at higher altitudes due to the reduced drag. This comes as a double edge sword however as your missiles perform better, the enemy's missiles do as well which means that you shouldn't put yourself in a position where enemies can engage you while you're engaging a target. Coming in at unexpected angles while being undetected is the best way to utilize R-60s and every other missile.
+
Every missile performs much better when at higher altitudes; this should be used to your advantage as missiles becomes unavoidable when launched at a reasonable range and altitude if the target doesn't deploy countermeasures. Missiles accelerate faster, pull harder and reach higher velocities at higher altitudes due to the reduced drag. This comes as a double edge sword, however, as your missiles perform better, the enemy's missiles do as well which means that you shouldn't put yourself in a position where enemies can engage you while you're engaging a target. Coming in at unexpected angles while being undetected is the best way to utilize R-60s and every other missile.
  
The higher the speed of which the missile is launched, the faster the missile will reach its optimum manoeuvrability, therefore keeping your speed high and obtaining optimal launch conditions are instrumental to a successful missile kill.
+
The higher the speed at which the missile is launched, the faster the missile will reach its optimum manoeuvrability, therefore keeping your speed high and obtaining optimal launch conditions are instrumental to a successful missile kill.
  
 
Use of radar slaving may prove to be incredibly useful when leading a target, especially when the dogfight continually changes angles and pointing the nose towards the target may not be possible.
 
Use of radar slaving may prove to be incredibly useful when leading a target, especially when the dogfight continually changes angles and pointing the nose towards the target may not be possible.
Line 83: Line 88:
 
'''Launching at a target flying away from you''':
 
'''Launching at a target flying away from you''':
  
This is the optimum launch angle against a target. When at sea level, the maximum range in relation of yourself to the target is around 2,200 m, given that the target is flying at the same speed, same direction and not manoeuvring. This changes depending on whether the target is moving slower or faster than you. The slower the target in comparison to you, the further you can launch your missile at the target. The faster the target in comparison to you, the shorter the range is of your missile. Range is also heavily influenced by the altitude of yourself and of the target. The higher the altitude, the less drag and therefore, the longer the range is.
+
This is the optimum launch angle against a target. When at sea level, the maximum range in relation of yourself to the target is around 2,200 m, given that the target is flying at the same speed, same direction and not manoeuvring. This changes depending on whether the target is moving slower or faster than you. The slower the target in comparison to you, the further you can launch your missile at the target. The faster the target in comparison to you, the shorter the range of your missile. Range is also heavily influenced by the your altitude and that of the target. The higher the altitude, the less drag and therefore, the longer the range.
  
 
'''Launching at a target, perpendicular to you:'''
 
'''Launching at a target, perpendicular to you:'''
  
When the target is flying perpendicular to you, the important factors are giving your missile the optimum launch conditions to be able to pull enough Gs to hit your target. These optimum conditions include; launching your missile at a high speed (preferably above Mach), keeping enough distance between you and the target, as well as leading target as much as you can to reduce the amount of energy the missile has to use to reach the target. If the target is slower, these conditions are easier to fulfill when engaging a target. However, if the target is moving at very high speeds, such attempt at hitting the target will likely result in missing the target and greater launch conditions are required to hit the target.
+
When the target is flying perpendicular to you, the important factors are giving your missile the optimum launch conditions to be able to pull enough Gs to hit your target. These optimum conditions include; launching your missile at a high speed (preferably above Mach 1), keeping enough distance between you and the target, as well as leading target as much as you can to reduce the amount of energy the missile has to use to reach the target. If the target is slower, these conditions are easier to fulfill when engaging a target. However, if the target is moving at very high speeds, such an attempt at hitting the target will likely result in missing the target and better launch conditions are required to hit the target.
  
 
Once again, higher altitudes greatly improve the performance of the missile, meaning that such angles for a missile towards the target may be impossible at lower altitudes, while being easy for the missile at higher altitudes.
 
Once again, higher altitudes greatly improve the performance of the missile, meaning that such angles for a missile towards the target may be impossible at lower altitudes, while being easy for the missile at higher altitudes.
Line 93: Line 98:
 
'''Remember:'''
 
'''Remember:'''
  
Your goal when using missiles, are to obtain the optimum launching parameters for your missile to successfully hit the target. Positioning and teamwork are instrumental to be able to obtain these launch conditions for your missiles. Using missiles to force your target into an optimum position may be necessary to launch a second missile at the target.
+
Your goal when using missiles, is to obtain the optimum launching parameters for your missile to successfully hit the target. Positioning and teamwork are instrumental to be able to obtain these launch conditions for your missiles. Using missiles to force your target into an optimum position may be necessary to launch a second missile at the target.
  
 
=== Pros and cons ===
 
=== Pros and cons ===
Line 103: Line 108:
 
* Light missile (in comparison to other similar missiles, better performance at lower speeds and higher altitudes).
 
* Light missile (in comparison to other similar missiles, better performance at lower speeds and higher altitudes).
 
* Longer burn time (useful for longer range engagements).
 
* Longer burn time (useful for longer range engagements).
* One of the best missiles for extremely short ranges  
+
* One of the best missiles for extremely short ranges
 
* Radar slaving (easier to lead targets)
 
* Radar slaving (easier to lead targets)
  
Line 115: Line 120:
 
Development at the GMKB Vympel bureau (formerly OKB-4 prior to 1967) on what would be known as the '''R-60''' (also known by the bureau designation ''K-60'' or ''izdeliye 62'') began in the early 1970s. The missile specifications were designed under the requirements for a short-launch range missile capable of high-G turns, high angle speed tracking, in a package of low weight and size for mounting on an aircraft.<ref name="GordonAAM_cite1">Gordon 2004, p.29</ref> In the United States and NATO, the R-60 was designated the ''AA-8'' and ''Aphid'' respectively.<ref name="GordonAAM_cite2">Gordon 2004, p.30</ref>
 
Development at the GMKB Vympel bureau (formerly OKB-4 prior to 1967) on what would be known as the '''R-60''' (also known by the bureau designation ''K-60'' or ''izdeliye 62'') began in the early 1970s. The missile specifications were designed under the requirements for a short-launch range missile capable of high-G turns, high angle speed tracking, in a package of low weight and size for mounting on an aircraft.<ref name="GordonAAM_cite1">Gordon 2004, p.29</ref> In the United States and NATO, the R-60 was designated the ''AA-8'' and ''Aphid'' respectively.<ref name="GordonAAM_cite2">Gordon 2004, p.30</ref>
  
The missile design's basis was from the [[R-13M|R-13]]. One major design distinction on the R-60 was the addition of small fixed canard surfaces (termed "destabilisers") in front of the rudder to improve their efficiency at high angles of attack.<ref name="GordonAAM_cite1"/> The missile is guided via the Komar (''Mosquito'') IR seeker with an uncooled optical element. The rudder actuators are powered by gases bled from the rocket motor, assisted with a pressure accumulator. Two turbine-driven generators are also present, powered by bleeding the rocket motor gases in order to provide the electrical power for the missile's systems.<ref name="GordonAAM_cite1"/> The missile's solid-fuel rocket motor has a burn time of 3-5 seconds, and a self-destruct timer of 25 seconds should the missile miss.<ref name="GordonAAM_cite2"/>
+
The missile design's basis was from the [[R-13M|R-13]]. One major design distinction on the R-60 was the addition of small fixed canard surfaces (termed "destabilisers") in front of the rudder to improve their efficiency at high angles of attack.<ref name="GordonAAM_cite1" /> The missile is guided via the Komar (''Mosquito'') IR seeker with an uncooled optical element. The rudder actuators are powered by gases bled from the rocket motor, assisted with a pressure accumulator. Two turbine-driven generators are also present, powered by bleeding the rocket motor gases in order to provide the electrical power for the missile's systems.<ref name="GordonAAM_cite1" /> The missile's solid-fuel rocket motor has a burn time of 3-5 seconds, and a self-destruct timer of 25 seconds should the missile miss.<ref name="GordonAAM_cite2" />
  
Measures to improve the R-60's resistance against electric counter-measures included the development of two different proximity fuses. The Strizh (''Swift'') optical fuse is the active fuse that detonates the missile within 1-5 metres of the target. The second is the Kolibri (''Colibri'') radar proximity fuse with antennas receiving pulsed radio signals. Missiles with the Kolibri installed are designated ''R-60K''.<ref name="GordonAAM_cite2"/> A variant of the R-60 was also produced, designated ''R-60U'' and lacks fins or rudders, with a data recorder installed in the warhead space and a ballast in the rocket motor space. This was intended for training with the missile retained on the pylon while the data recorder captured the pilot's actions to ensure proper preparations and requirements are met before a mock launch was attempted.<ref name="GordonAAM_cite3">Gordon 2004, p.32</ref><ref name="GordonAAM_cite4">Gordon 2004, p.25</ref>
+
Measures to improve the R-60's resistance against electric counter-measures included the development of two different proximity fuses. The Strizh (''Swift'') optical fuse is the active fuse that detonates the missile within 1-5 metres of the target. The second is the Kolibri (''Colibri'') radar proximity fuse with antennas receiving pulsed radio signals. Missiles with the Kolibri installed are designated ''R-60K''.<ref name="GordonAAM_cite2" /> A variant of the R-60 was also produced, designated ''R-60U'' and lacks fins or rudders, with a data recorder installed in the warhead space and a ballast in the rocket motor space. This was intended for training with the missile retained on the pylon while the data recorder captured the pilot's actions to ensure proper preparations and requirements are met before a mock launch was attempted.<ref name="GordonAAM_cite3">Gordon 2004, p.32</ref><ref name="GordonAAM_cite4">Gordon 2004, p.25</ref>
  
The R-60 missiles production would start in 1973, with deployment in 1975. The missiles are installed onto aircraft via the APU-60-1 single missile rail or the APU-60-2 double missile rail, with the APU-60-1 usually mounted onto the BD3-60-23F1 or BD3-60-23F1 pylons.<ref name="GS_Stinger">GlobalSecurity.org "AA-8 APHID"</ref><ref name="GordonAAM_cite3"/>
+
The R-60 missiles production would start in 1973, with deployment in 1975. The missiles are installed onto aircraft via the APU-60-1 single missile rail or the APU-60-2 double missile rail, with the APU-60-1 usually mounted onto the BD3-60-23F1 or BD3-60-23F1 pylons.<ref name="GS_Stinger">GlobalSecurity.org "AA-8 APHID"</ref><ref name="GordonAAM_cite3" />
  
 
The R-60 would be refined further into the ''[[R-60M]]'' variant.
 
The R-60 would be refined further into the ''[[R-60M]]'' variant.
Line 132: Line 137:
  
 
;Related development
 
;Related development
* [[R-60M]]
+
 
* [[R-60MK]]
+
* [[R-60 (Family)]]
  
 
== External links ==
 
== External links ==
Line 146: Line 151:
  
 
;Bibliography
 
;Bibliography
 +
 
* GlobalSecurity.org "AA-8 APHID" ''Global Security'', [https://www.globalsecurity.org/military/world/russia/aa-8.htm Website]. Accessed 03 Jul. 2021 ([https://web.archive.org/web/20210703202542/https://www.globalsecurity.org/military/world/russia/aa-8.htm Web Archive]).
 
* GlobalSecurity.org "AA-8 APHID" ''Global Security'', [https://www.globalsecurity.org/military/world/russia/aa-8.htm Website]. Accessed 03 Jul. 2021 ([https://web.archive.org/web/20210703202542/https://www.globalsecurity.org/military/world/russia/aa-8.htm Web Archive]).
 
* Gordon, Yefim. ''Soviet/Russian Aircraft Weapons Since World War II.'' Midland Publishing, 2004.
 
* Gordon, Yefim. ''Soviet/Russian Aircraft Weapons Since World War II.'' Midland Publishing, 2004.

Latest revision as of 20:43, 3 June 2024

This page is about the Soviet air-to-air missile R-60. For other versions, see R-60 (Family).
R-60s mounted on the MiG-21SMT

Description

The R-60 missile (scale is approximate)


The R-60 is a Soviet infrared homing air-to-air missile. It was introduced in Update 1.85 "Supersonic".

Vehicles equipped with this weapon

Vehicles equipped with this weapon
Jet fighters 
MiG-21  ◄MiG-21 SPS-K · ◊MiG-21MF · ◔MiG-21MF · MiG-21SMT
MiG-29  MiG-29 · ◊MiG-29 · ◔MiG-29
Strike aircraft 
Su-17  Su-17M2
Su-22  Su-22M3 · ◔Su-22M3 · ◊Su-22UM3K
Su-25  Su-25
Yak-38  Yak-38 · Yak-38M
Attack helicopters 
Mi-24  Mi-24P · ◔Mi-24P · ◊Mi-24P · ◄Mi-24P HFS 80 · Mi-24V · ◔Mi-24V

General info

Missile characteristics
Mass 43.50 kg
Guidance IR
Aspect Rear-aspect
Lock range (rear-aspect) 5 km
Launch range 10 km
Maximum speed 2.5 M
Maximum overload 30 G
Missile guidance time 25 secs
Explosive mass 1.15 kg TNTeq

The R-60, a short range infrared homing missile, is usually most effective at ranges between 600 and 2,200 m (at sea level). The burn time of the R-60's propellant is 3 seconds. Compared to other missiles, the R-60 accelerates slower but for longer when comparing to other missiles (the AIM-9Js fuel last for 2.2 seconds with more force, R-60s having 3 seconds but with less force). The R-60s have better total-force-to-weight ratio when compared to the AIM-9Js. Comparing the AIM-9Js to the R-60s, R-60s have almost half the weight of the AIM-9Js, meaning the R-60s pulls better at lower speeds and higher altitudes.

It is also important to note that this missile can uncage its seeker which allow the user to lead the target before launching. Although there is only a brief window of opportunity to fire as uncaging the seeker only maintains lock for a short period of time before it resets to acquire another target unless slaved to radar.

When compared to the AIM-9Js, the R-60s have double the inner FOV of the seeker head, meaning it is easier to acquire a lock when doing turning engagements, though this comes at the cost of being able to be fooled easier by flares and other countermeasures, since these may come into the view of the missiles (This is also the reason why AIM-9Js are less likely to be fooled by flares when compared to R-60s).

Unlike the heavier missiles (such as AIM-9Js), R-60s will be able to hit targets at extremely close ranges of up to roughly 550 m. This is all due to the very lightweight design on the missile itself.

One major problem of the R-60 is its tendency to almost always be fooled by flares. If the target has flares, even while stalling, the missile will be fooled and follow the flares anyway. It is recommended to only target unaware enemies or those without flares.

Effective damage

Due to the low explosive mass of 1.15 kg of TNT, R-60 requires closer detonation or a direct hit on a target, in order to deal sufficient damage, especially when compared to missiles such as AIM-9J which have almost 5 x the explosive mass.

Comparison with analogues

Compared to the most common air-to-air missiles such as AIM-9J or R550 Magic, the R-60 tends to have the upper hand in most chasing/dogfighting scenarios due to its extended turning capability possible through the long engine burn time and high G tolerance although this is offset by its distinctly larger seeker FOV and smaller gimbal compared to the AIM-9J and R550 Magic. However, the R-60 has a much more limited range then the AIM-9J and the Magic and the smaller gimbal means leading the missile is more difficult compared to its contemporaries.

Usage in battles

Important details:

Every missile performs much better when at higher altitudes; this should be used to your advantage as missiles becomes unavoidable when launched at a reasonable range and altitude if the target doesn't deploy countermeasures. Missiles accelerate faster, pull harder and reach higher velocities at higher altitudes due to the reduced drag. This comes as a double edge sword, however, as your missiles perform better, the enemy's missiles do as well which means that you shouldn't put yourself in a position where enemies can engage you while you're engaging a target. Coming in at unexpected angles while being undetected is the best way to utilize R-60s and every other missile.

The higher the speed at which the missile is launched, the faster the missile will reach its optimum manoeuvrability, therefore keeping your speed high and obtaining optimal launch conditions are instrumental to a successful missile kill.

Use of radar slaving may prove to be incredibly useful when leading a target, especially when the dogfight continually changes angles and pointing the nose towards the target may not be possible.

Launching at a target flying away from you:

This is the optimum launch angle against a target. When at sea level, the maximum range in relation of yourself to the target is around 2,200 m, given that the target is flying at the same speed, same direction and not manoeuvring. This changes depending on whether the target is moving slower or faster than you. The slower the target in comparison to you, the further you can launch your missile at the target. The faster the target in comparison to you, the shorter the range of your missile. Range is also heavily influenced by the your altitude and that of the target. The higher the altitude, the less drag and therefore, the longer the range.

Launching at a target, perpendicular to you:

When the target is flying perpendicular to you, the important factors are giving your missile the optimum launch conditions to be able to pull enough Gs to hit your target. These optimum conditions include; launching your missile at a high speed (preferably above Mach 1), keeping enough distance between you and the target, as well as leading target as much as you can to reduce the amount of energy the missile has to use to reach the target. If the target is slower, these conditions are easier to fulfill when engaging a target. However, if the target is moving at very high speeds, such an attempt at hitting the target will likely result in missing the target and better launch conditions are required to hit the target.

Once again, higher altitudes greatly improve the performance of the missile, meaning that such angles for a missile towards the target may be impossible at lower altitudes, while being easy for the missile at higher altitudes.

Remember:

Your goal when using missiles, is to obtain the optimum launching parameters for your missile to successfully hit the target. Positioning and teamwork are instrumental to be able to obtain these launch conditions for your missiles. Using missiles to force your target into an optimum position may be necessary to launch a second missile at the target.

Pros and cons

Pros:

  • Large seeker FOV (making it easier to obtain a lock without pointing the nose directly towards the target).
  • Light missile (in comparison to other similar missiles, better performance at lower speeds and higher altitudes).
  • Longer burn time (useful for longer range engagements).
  • One of the best missiles for extremely short ranges
  • Radar slaving (easier to lead targets)

Cons:

  • Large seeker FOV (more prone to countermeasures such as flares, due to the increased likelihood of the countermeasures coming into view of the seeker).
  • Lacking TNT load can fail to sufficiently damage targets even on close proximity

History

Development at the GMKB Vympel bureau (formerly OKB-4 prior to 1967) on what would be known as the R-60 (also known by the bureau designation K-60 or izdeliye 62) began in the early 1970s. The missile specifications were designed under the requirements for a short-launch range missile capable of high-G turns, high angle speed tracking, in a package of low weight and size for mounting on an aircraft.[1] In the United States and NATO, the R-60 was designated the AA-8 and Aphid respectively.[2]

The missile design's basis was from the R-13. One major design distinction on the R-60 was the addition of small fixed canard surfaces (termed "destabilisers") in front of the rudder to improve their efficiency at high angles of attack.[1] The missile is guided via the Komar (Mosquito) IR seeker with an uncooled optical element. The rudder actuators are powered by gases bled from the rocket motor, assisted with a pressure accumulator. Two turbine-driven generators are also present, powered by bleeding the rocket motor gases in order to provide the electrical power for the missile's systems.[1] The missile's solid-fuel rocket motor has a burn time of 3-5 seconds, and a self-destruct timer of 25 seconds should the missile miss.[2]

Measures to improve the R-60's resistance against electric counter-measures included the development of two different proximity fuses. The Strizh (Swift) optical fuse is the active fuse that detonates the missile within 1-5 metres of the target. The second is the Kolibri (Colibri) radar proximity fuse with antennas receiving pulsed radio signals. Missiles with the Kolibri installed are designated R-60K.[2] A variant of the R-60 was also produced, designated R-60U and lacks fins or rudders, with a data recorder installed in the warhead space and a ballast in the rocket motor space. This was intended for training with the missile retained on the pylon while the data recorder captured the pilot's actions to ensure proper preparations and requirements are met before a mock launch was attempted.[3][4]

The R-60 missiles production would start in 1973, with deployment in 1975. The missiles are installed onto aircraft via the APU-60-1 single missile rail or the APU-60-2 double missile rail, with the APU-60-1 usually mounted onto the BD3-60-23F1 or BD3-60-23F1 pylons.[5][3]

The R-60 would be refined further into the R-60M variant.

Media

Excellent additions to the article would be video guides, screenshots from the game, and photos.

See also

Related development

External links

References

Citations
  1. 1.0 1.1 1.2 Gordon 2004, p.29
  2. 2.0 2.1 2.2 Gordon 2004, p.30
  3. 3.0 3.1 Gordon 2004, p.32
  4. Gordon 2004, p.25
  5. GlobalSecurity.org "AA-8 APHID"
Bibliography
  • GlobalSecurity.org "AA-8 APHID" Global Security, Website. Accessed 03 Jul. 2021 (Web Archive).
  • Gordon, Yefim. Soviet/Russian Aircraft Weapons Since World War II. Midland Publishing, 2004.


Missiles
USA 
AAM  AIM-54A Phoenix · AIM-54C Phoenix · ATAS (AIM-92) · AIM-120A · AIM-120B · Fakour-90 · Sedjeel
Sparrow  AIM-7C · AIM-7D · AIM-7E · AIM-7E-2 · AIM-7F · AIM-7M
Sidewinder  AIM-9B · AIM-9C · AIM-9D · AIM-9E · AIM-9G · AIM-9H · AIM-9J · AIM-9L · AIM-9M · AIM-9P
AGM  AGM-22 · APKWS II (M151) · APKWS II (M282) · BGM-71D TOW-2
Bullpup  AGM-12B Bullpup · AGM-12C Bullpup
Hellfire  AGM-114B Hellfire · AGM-114K Hellfire II
Maverick  AGM-65A · AGM-65B · AGM-65D · AGM-65E2 · AGM-65G · AGM-65L
ATGM  LOSAT/MGM-166A
TOW  BGM-71 · BGM-71A · BGM-71B · BGM-71C
SAM  FIM-92 Stinger · MIM-72 · MIM146
Naval SAM  RIM-24A
Germany 
AAM  AIM-9B FGW.2 Sidewinder · AIM-9L/I Sidewinder · Flz Lwf 63 · Flz Lwf 63/80
AGM  9M14M Malyutka · Flz Lwf LB 82 · HOT-1 · HOT-2 TOW · HOT-3 · PARS 3 LR
AShM  AS.34 Kormoran
ATGM  HOT-K3S · Spike-LR II
SAM  Roland
Naval SAM  Strela-2M
USSR 
AAM  9M39 Igla · R-3R · R-3S · R-13M1 · R-23R · R-23T · R-24R · R-24T · R-27ER(1) · R-27ET(1) · R-27R(1) · R-27T(1) · R-60 · R-60M · R-60MK · R-73(E) · R-77
AGM  9K127 Vikhr · 9M17M Falanga · 9M120 Ataka · 9M120-1 Ataka
  Kh-23M · Kh-25 · Kh-25ML · Kh-29L · Kh-29T · Kh-29TE · Kh-29TD · Kh-66 · S-25L · S-25LD
ATGM  3M7 · 9M14 · 9M113 Konkurs · 9M114 Shturm · 9M123 Khrizantema · 9M133 · 9M133FM3 · 9M133M-2
SAM  95Ya6 · 9M311 · 9M311-1M · 9M331 · 9M37M
Naval SAM  Volna-M
Britain 
AAM  Fireflash · Firestreak · Red Top · Skyflash · Skyflash SuperTEMP · SRAAM · R-Darter
AGM  AGM-65E · AS.12 · ZT-6 Mokopa
AShM  AJ.168
ATGM  BAe Swingfire · MILAN · MILAN 2 · ZT3
SAM  Starstreak
Japan 
AAM  AAM-3 · AAM-4
AGM  Ki-148 I-Go Model 1B
ATGM  Type 64 MAT · Type 79 Jyu-MAT
SAM  Type 81 SAM-1C · Type 91
China 
AAM  PL-2 · PL-5B · PL-5C · PL-5EII · PL-7 · PL-8 · PL-12 · SD-10(A) · TY-90
AGM  AKD-9 · AKD-10 · Fire Snake 90A · HJ-8A · HJ-8C · HJ-8E · HJ-8H
ATGM  302 · HJ-73 · HJ-73E · HJ-9 · QN201DD · QN502CDD
SAM  HN-6
Italy 
AAM  Aspide-1A · MAA-1 Piranha
AGM  AGM-65H · CIRIT · L-UMTAS · Spike ER
ATGM  Spike-LR II
Naval AShM  Nettuno
SAM  Mistral SATCP
France 
AAM  AA-20 Nord · Matra R511 · Matra R530 · Matra R530E · Matra Super 530D · Matra Super 530F · Matra R550 Magic 1 · Matra R550 Magic 2 · Mistral · MICA-EM
AGM  9M14-2 Malyutka-2 · AS-20 Nord · AS-30 Nord · AS-30L Nord · HOT-1 · HOT-2 TOW · HOT-3 · Spike ER
ATGM  HOT · SS.11
SAM  Roland · VT1
Sweden 
AAM  RB24 · RB24J · RB71 · RB 74 · RB 74(M) · RB 99
AGM  Rb05A · RB 53 Bantam · RB 55B Heli TOW · RB 55C Heli TOW · RB 75 · RB 75T
ATGM  Rbs 55 · Rbs 56
SAM  Rbs 70
Israel 
AAM  Shafrir · Shafrir 2 · Python 3 · Derby
ATGM  Spike-LR II
  AAM = Air-to-Air Missile   AGM = Air-to-Ground Missile   AShM = Anti-Ship Missile   ATGM = Anti-Tank Guided Missile (Ground mounts)   SAM = Surface-to-Air Missile