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Air Power Australia Analysis 2009-02
3rd February 2009
by Dr Carlo Kopp, SMAIAA, MIEEE, PEng
© 2008, 2009 Carlo Kopp
The only US combat aircraft design to be in production before 2020 with the capability to penetrate and survive in modern Integrated Air Defence Systems is the F-22 Raptor. The depicted aircraft is dropping a GBU-32 JDAM guided bomb (US Air Force image).
Abstract
The United States and its Allies have relied since the end of the Cold War upon the ability to quickly overwhelm an opposing IADS, and the ability to then deliver massed precision firepower from the air, as the weapon of choice in resolving nation state conflicts.
The reality of evolving IADS technology and its global proliferation is that most of the US Air Force combat aircraft fleet, and all of the US Navy combat aircraft fleet, will be largely impotent against an IADS constructed from the technology available today from Russian and, increasingly so, Chinese manufacturers.
If flown against such an IADS, US legacy fighters from the F-15 through to the current production F/A-18E/F would suffer prohibitive combat losses attempting to penetrate, suppress or destroy such an IADS.
The IADS technology in question is currently being deployed by China, Iran, Venezuela, and other nations, most of which have poor relationships with the Western alliance.
Until the US Air Force deploys significant numbers of the intended New Generation Bomber post 2020, only aircraft types in the US arsenal will be capable of penetrating, suppressing and destroying such an IADS – the B-2A Spirit and the F-22A Raptor.
There are only twenty B-2As in existence and retooling to manufacture a B-2C is an expensive approach given the commitment to the New Generation Bomber.
The United States therefore has only one remaining strategic choice at this time. That strategic choice is to manufacture a sufficient number of F-22A Raptors to provide a credible capability to conduct a substantial air campaign using only the B-2A and F-22A fleets.
The expectation that the US can get by with a small “golden bullet” fleet of stealth aircraft to carve holes in IADS to permit legacy aircraft to attack is no longer credible. The difficulty in locating and killing the new generation of self propelled and highly survivable IADS radars and launchers presents the prospect of a replay of the 1999 OAF campaign, with highly lethal SAM systems waiting in ambush, and mostly evading SEAD/DEAD attacks.
The F-22A Raptor will therefore have to perform the full spectrum of penetrating roles, starting with counter-air, and encompassing SEAD/DEAD, penetrating ISR and precision strike against strategic and tactical targets. The B-2A fleet can robustly bolster capabilities, but the small number of these superb aircraft available will result inevitably in very selective use.
If we assume an aircraft configuration reflecting the planned F-22A Block 40 configuration, and a contingency of similar magnitude to Desert Storm in 1991, then the required number of F-22A aircraft to cover the spectrum of penetrating roles is of the order of 500 to 600 aircraft in total.
The United States no longer has any real choices in this matter, if it wishes to retain its secure global strategic position in the 2010 – 2020 time window. Any other force structure model will result in a nett loss of strategic potential, and produce strategic risks, which neither the US nor its Allies can afford.
“We must preserve our unparalleled airpower capabilities to deter and defeat any conventional competitors, swiftly respond to crises across the globe, and support our ground forces.”
Defense Policy Agenda Statement,
Obama Administration, 2009
Disclaimer: No classified materials needed to be used, nor were classified materials used in the preparation of this analysis.
The stunning successes achieved in US led air campaigns since 1991 have been owed more than anything to the US technological and operational capabilities to penetrate and suppress opposing Integrated Air Defence Systems (IADS).
Ongoing technological evolution of IADS capabilities since 1991, and a failure by the US to further evolve its once formidable relative capabilities, now present the prospect of the US being unable to achieve a decisive advantage in an air campaign, either quickly or with low expenditures in aircraft and aircrew losses.
At this point in time the US has firm commitments for only 183 F-22A Raptor aircraft, and an operational fleet of only 20 B-2A Spirit stealth bombers. Yet these are the only aircraft capable of surviving in the kind of IADS environment we now see emerging globally.
To best appreciate exactly how and why this strategic change has occurred, and occurred so pervasively, it is necessary to explore defence penetration strategies, Russian and Chinese technological strategy in IADS evolution, and how these strategies are manifested in specific designs for IADS components.
IADS Evolution
The subject of technological strategies and countering technological adaptations for penetrating IADS has been recently detailed in [1], [2], [3], [4] and [5]. However, to date we have yet to see a more comprehensive analysis of the ongoing trends in this evolution.
Until the advent of the F-117A during the mid 1980s, tasked in a large part with crippling key command posts in an opposing IADS, Western defence penetration and IADS suppression strategies were essentially a sophisticated but linear evolution of techniques first pioneered during the 1940s Combined Bomber Offensive over Germany.
During that period the RAF and USAAF first employed standoff jamming and escort jamming aircraft, but also employed low altitude penetration below radar coverage on numerous critical bombing raids. The British pioneered the model of Suppression/Destruction of Enemy Air Defences (SEAD/DEAD) flying rocket and gun armed Typhoon fighters against Luftwaffe search and acquisition radars. It is also significant that the Germans pioneered the Surface to Air Missile (SAM) with their Wasserfall ands Rheintochter designs, neither of which achieved operational status, but both of which provided the technological jumpstart for US, British and Soviet developments post-war [6], [7].
The protracted Vietnam conflict provided the next important stage in this evolution, as the Soviets deployed the S-75/SA-2 Guideline SAM en masse to defend North Vietnam, and the US developed and deployed specialised EB-66, EA-6A/B and EKA-3B tactical jamming and anti-radiation missile firing EF-100F, A-6B, F-105G and EF-4C SEAD aircraft to cripple this IADS. In parallel the US deployed the F-111A which used automatic terrain following to evade SAM acquisition and engagement radars [8], [9], [10], [11].
While opinions and assessments often differ widely on the success of the US SEAD/DEAD campaign in Vietnam, what is abundantly clear is that the combination of jamming and lethal attacks against missile batteries and supporting radars worked, to the extent that sustainable loss rates in penetrating bombers were achieved. In this respect the combination of jamming and lethal attacks must be considered to be the winner, as the IADS strategic aim of achieving unsustainable bomber loss rates was simply not achieved. Against the tens of thousands of sorties flown, the success rate of the SAMs was not good enough to deter penetration.
The 1973 Yom Kippur conflict presented a mixed outcome. Initially the highly mobile Soviet supplied 2K12 ZRK Kub / SA-6 Gainful and static S-125 Neva / SA-3 Goa inflicted significant loss rates on Israeli fighter aircraft, but innovative low level flying tactics and use of land manoeuvre forces swung the final outcome in favour of the Israelis [12], [13].
The US further refined its technological capabilities during the late 1970s, developing the very capable F-4G Wild Weasel IV and EF-111A Raven, both of which set long term benchmarks for these respective capabilities. The rather simple AGM-45 Shrike anti-radiation missile was replaced by the sophisticated digital AGM-88 HARM [14].
The Soviet reaction to the IADS debacle in Vietnam, and the not entirely convincing performance during the Yom Kippur conflict, and the subsequent Syrian debacle in 1982, was to develop a new generation of SAMs and radars, with more range, better jam resistance, and importantly much better mobility [15].
These weapons were the S-300P / SA-10A Grumble semi-mobile strategic air defence missile, with its semi-mobile 5N63 Flap Lid engagement radar, modelled on the US MPQ-53 Patriot radar, and the sibling Soviet Army high mobility weapon, the S-300V / SA-12A/B Giant/Gladiator [16], [17].
By the early 1980s Soviet Voyska PVO units were receiving the self propelled S-300PS / SA-10B, soon followed by the digital S-300PM / SA-10C, a true analogue to the MIM-104 Patriot, but with better battery mobility. Concurrently, the medium range Army 2K12 / SA-6 was being replaced with the more capable 9M38 / SA-11 Gadfly [18].
The distinguishing features of this late Cold War generation of IADS systems were in very high mobility, all three of these systems being capable of firing five minutes after coming to a halt, and being capable of departing a location within 5 minutes of completing a missile engagement. The S-300PS/PM and S-300V both employed high power, and for that period, exceptionally long ranging phased array engagement radars, much more difficult to jam than the engagement radars in the SA-2, SA-3 and SA-6 deployed and used during the 1960s and 1970s, and much more difficult to target with anti-radiation missiles. Importantly, the SA-10, SA-11 and SA-12 employed radio frequency datalinks, which allowed the battery command posts, engagement radars and missile launch vehicles considerable flexibility in how the battery was deployed geographically [19], [20].
When Saddam invaded Kuwait, the US possessed a robust conventional SEAD/DEAD capability in its fleets of HARM firing F-4G Wild Weasel and F/A-18 Hornet fighters, and a robust tactical jamming capability in the mixed fleet of EF-111A Ravens and EA-6B Prowlers. Less visible was the 37th Tactical Fighter Wing equipped with 60 F-117A Nighthawk stealth fighters.
The overwhelming and indeed crushing defeat of Saddam’s Soviet and French supplied IADS in 1991 was the result of a concentrated, coordinated and sustained effort using aerial decoys, SEAD/DEAD assets, jammers against IADS radars, and the F-117A against key hardened command posts [21], [22].
There are several key observations, which must be made about this campaign.
The first is that it was representative of the NATO vs. Warpac scenarios of that period – while the Soviets had good numbers of SA-10, SA-11 and some SA-12 deployed, these were mostly committed to protecting strategic targets inside Soviet territory, leaving much of the IADS capability in Central Europe to Warsaw Pact allies equipped with a mix of SA-2, SA-3, SA-4, SA-5 and SA-6 batteries. While these systems were better maintained, often of better subtypes, and more competently operated than Iraqi systems, they also had to cope with the full capabilities of NATO and the US, not just the forces deployed during Desert Shield.
The second observation is a corollary of the first, in that the new highly mobile SA-10, SA-11 and SA-12 were not deployed in Iraq. Indeed, Iraqi deployment doctrine of that period paid little attention to mobility, with SAM batteries nearly always fixed in location.
To achieve the intended effect against this legacy IADS, the US expended hundreds of drones, and importantly, around 2,000 AGM-88 HARM anti-radiation missiles, to which must be added the complete but smaller warstock of British ALARM anti-radiation missiles.
The Desert Storm campaign remains a key historical benchmark, but unfortunately it has also created quite unrealistic expectations of what can be achieved over the longer term.
The next significant air campaign was the 1999 Operation Allied Force effort against Serbia. While it has been considered a success due to the low aggregate loss rates of Coalition aircraft, the success of the SEAD/DEAD effort was much less convincing. While the Coalition did successfully destroy most of the static SA-2 and SA-3 batteries, they only managed to destroy 3 out of 25 mobile SA-6 batteries, or 12% percent of that total, despite the large number of HARMs launched. Disciplined “shoot and scoot” tactics by the Serbian defenders, intended to keep missile batteries alive, resulted in a persistent threat of sniping attacks which kept much of the NATO force of F-16CJs, EA-6Bs and Tornado ECRs occupied chasing SAM systems, largely to no avail. The Serbians did execute one particularly successful ambush, killing an F-117A stealth fighter using a legacy SA-3 missile battery [23].
The Allied force campaign happened a decade ago, since then there have been no significant air campaigns in which an IADS was employed to deny access to attacking aircraft.
What the Desert Storm and Allied Force campaigns did achieve was to provide both a focus and an imperative for further evolutionary growth in IADS capabilities, doctrine and technological strategy.
In the decade that has elapsed since Allied Force, we have seen a commercially and strategically driven flurry of developmental activity in the Russian and Chinese defence industries, reacting to the lessons of the 1990s, but also exploiting the globalised market for high technology, especially computer technology, commodified high performance microprocessor chips, and Gallium Arsenide microwave chips. Perhaps the only silver lining in this situation is that the global Internet provides Western observers with a much clearer picture of technological evolution in Russia, less so in China, than during the late Cold War and early 1990s [24].
We can now identify a number of key trends in IADS evolution, which are well established, and will define the basic features of well constructed near future air defences, such technologybeing globally marketed by Russia, former Soviet Republics, and China.
(To be continued)
3rd February 2009
by Dr Carlo Kopp, SMAIAA, MIEEE, PEng
© 2008, 2009 Carlo Kopp
The only US combat aircraft design to be in production before 2020 with the capability to penetrate and survive in modern Integrated Air Defence Systems is the F-22 Raptor. The depicted aircraft is dropping a GBU-32 JDAM guided bomb (US Air Force image).
Abstract
The United States and its Allies have relied since the end of the Cold War upon the ability to quickly overwhelm an opposing IADS, and the ability to then deliver massed precision firepower from the air, as the weapon of choice in resolving nation state conflicts.
The reality of evolving IADS technology and its global proliferation is that most of the US Air Force combat aircraft fleet, and all of the US Navy combat aircraft fleet, will be largely impotent against an IADS constructed from the technology available today from Russian and, increasingly so, Chinese manufacturers.
If flown against such an IADS, US legacy fighters from the F-15 through to the current production F/A-18E/F would suffer prohibitive combat losses attempting to penetrate, suppress or destroy such an IADS.
The IADS technology in question is currently being deployed by China, Iran, Venezuela, and other nations, most of which have poor relationships with the Western alliance.
Until the US Air Force deploys significant numbers of the intended New Generation Bomber post 2020, only aircraft types in the US arsenal will be capable of penetrating, suppressing and destroying such an IADS – the B-2A Spirit and the F-22A Raptor.
There are only twenty B-2As in existence and retooling to manufacture a B-2C is an expensive approach given the commitment to the New Generation Bomber.
The United States therefore has only one remaining strategic choice at this time. That strategic choice is to manufacture a sufficient number of F-22A Raptors to provide a credible capability to conduct a substantial air campaign using only the B-2A and F-22A fleets.
The expectation that the US can get by with a small “golden bullet” fleet of stealth aircraft to carve holes in IADS to permit legacy aircraft to attack is no longer credible. The difficulty in locating and killing the new generation of self propelled and highly survivable IADS radars and launchers presents the prospect of a replay of the 1999 OAF campaign, with highly lethal SAM systems waiting in ambush, and mostly evading SEAD/DEAD attacks.
The F-22A Raptor will therefore have to perform the full spectrum of penetrating roles, starting with counter-air, and encompassing SEAD/DEAD, penetrating ISR and precision strike against strategic and tactical targets. The B-2A fleet can robustly bolster capabilities, but the small number of these superb aircraft available will result inevitably in very selective use.
If we assume an aircraft configuration reflecting the planned F-22A Block 40 configuration, and a contingency of similar magnitude to Desert Storm in 1991, then the required number of F-22A aircraft to cover the spectrum of penetrating roles is of the order of 500 to 600 aircraft in total.
The United States no longer has any real choices in this matter, if it wishes to retain its secure global strategic position in the 2010 – 2020 time window. Any other force structure model will result in a nett loss of strategic potential, and produce strategic risks, which neither the US nor its Allies can afford.
“We must preserve our unparalleled airpower capabilities to deter and defeat any conventional competitors, swiftly respond to crises across the globe, and support our ground forces.”
Defense Policy Agenda Statement,
Obama Administration, 2009
Disclaimer: No classified materials needed to be used, nor were classified materials used in the preparation of this analysis.
The stunning successes achieved in US led air campaigns since 1991 have been owed more than anything to the US technological and operational capabilities to penetrate and suppress opposing Integrated Air Defence Systems (IADS).
Ongoing technological evolution of IADS capabilities since 1991, and a failure by the US to further evolve its once formidable relative capabilities, now present the prospect of the US being unable to achieve a decisive advantage in an air campaign, either quickly or with low expenditures in aircraft and aircrew losses.
At this point in time the US has firm commitments for only 183 F-22A Raptor aircraft, and an operational fleet of only 20 B-2A Spirit stealth bombers. Yet these are the only aircraft capable of surviving in the kind of IADS environment we now see emerging globally.
To best appreciate exactly how and why this strategic change has occurred, and occurred so pervasively, it is necessary to explore defence penetration strategies, Russian and Chinese technological strategy in IADS evolution, and how these strategies are manifested in specific designs for IADS components.
IADS Evolution
The subject of technological strategies and countering technological adaptations for penetrating IADS has been recently detailed in [1], [2], [3], [4] and [5]. However, to date we have yet to see a more comprehensive analysis of the ongoing trends in this evolution.
Until the advent of the F-117A during the mid 1980s, tasked in a large part with crippling key command posts in an opposing IADS, Western defence penetration and IADS suppression strategies were essentially a sophisticated but linear evolution of techniques first pioneered during the 1940s Combined Bomber Offensive over Germany.
During that period the RAF and USAAF first employed standoff jamming and escort jamming aircraft, but also employed low altitude penetration below radar coverage on numerous critical bombing raids. The British pioneered the model of Suppression/Destruction of Enemy Air Defences (SEAD/DEAD) flying rocket and gun armed Typhoon fighters against Luftwaffe search and acquisition radars. It is also significant that the Germans pioneered the Surface to Air Missile (SAM) with their Wasserfall ands Rheintochter designs, neither of which achieved operational status, but both of which provided the technological jumpstart for US, British and Soviet developments post-war [6], [7].
The protracted Vietnam conflict provided the next important stage in this evolution, as the Soviets deployed the S-75/SA-2 Guideline SAM en masse to defend North Vietnam, and the US developed and deployed specialised EB-66, EA-6A/B and EKA-3B tactical jamming and anti-radiation missile firing EF-100F, A-6B, F-105G and EF-4C SEAD aircraft to cripple this IADS. In parallel the US deployed the F-111A which used automatic terrain following to evade SAM acquisition and engagement radars [8], [9], [10], [11].
While opinions and assessments often differ widely on the success of the US SEAD/DEAD campaign in Vietnam, what is abundantly clear is that the combination of jamming and lethal attacks against missile batteries and supporting radars worked, to the extent that sustainable loss rates in penetrating bombers were achieved. In this respect the combination of jamming and lethal attacks must be considered to be the winner, as the IADS strategic aim of achieving unsustainable bomber loss rates was simply not achieved. Against the tens of thousands of sorties flown, the success rate of the SAMs was not good enough to deter penetration.
The 1973 Yom Kippur conflict presented a mixed outcome. Initially the highly mobile Soviet supplied 2K12 ZRK Kub / SA-6 Gainful and static S-125 Neva / SA-3 Goa inflicted significant loss rates on Israeli fighter aircraft, but innovative low level flying tactics and use of land manoeuvre forces swung the final outcome in favour of the Israelis [12], [13].
The US further refined its technological capabilities during the late 1970s, developing the very capable F-4G Wild Weasel IV and EF-111A Raven, both of which set long term benchmarks for these respective capabilities. The rather simple AGM-45 Shrike anti-radiation missile was replaced by the sophisticated digital AGM-88 HARM [14].
The Soviet reaction to the IADS debacle in Vietnam, and the not entirely convincing performance during the Yom Kippur conflict, and the subsequent Syrian debacle in 1982, was to develop a new generation of SAMs and radars, with more range, better jam resistance, and importantly much better mobility [15].
These weapons were the S-300P / SA-10A Grumble semi-mobile strategic air defence missile, with its semi-mobile 5N63 Flap Lid engagement radar, modelled on the US MPQ-53 Patriot radar, and the sibling Soviet Army high mobility weapon, the S-300V / SA-12A/B Giant/Gladiator [16], [17].
By the early 1980s Soviet Voyska PVO units were receiving the self propelled S-300PS / SA-10B, soon followed by the digital S-300PM / SA-10C, a true analogue to the MIM-104 Patriot, but with better battery mobility. Concurrently, the medium range Army 2K12 / SA-6 was being replaced with the more capable 9M38 / SA-11 Gadfly [18].
The distinguishing features of this late Cold War generation of IADS systems were in very high mobility, all three of these systems being capable of firing five minutes after coming to a halt, and being capable of departing a location within 5 minutes of completing a missile engagement. The S-300PS/PM and S-300V both employed high power, and for that period, exceptionally long ranging phased array engagement radars, much more difficult to jam than the engagement radars in the SA-2, SA-3 and SA-6 deployed and used during the 1960s and 1970s, and much more difficult to target with anti-radiation missiles. Importantly, the SA-10, SA-11 and SA-12 employed radio frequency datalinks, which allowed the battery command posts, engagement radars and missile launch vehicles considerable flexibility in how the battery was deployed geographically [19], [20].
When Saddam invaded Kuwait, the US possessed a robust conventional SEAD/DEAD capability in its fleets of HARM firing F-4G Wild Weasel and F/A-18 Hornet fighters, and a robust tactical jamming capability in the mixed fleet of EF-111A Ravens and EA-6B Prowlers. Less visible was the 37th Tactical Fighter Wing equipped with 60 F-117A Nighthawk stealth fighters.
The overwhelming and indeed crushing defeat of Saddam’s Soviet and French supplied IADS in 1991 was the result of a concentrated, coordinated and sustained effort using aerial decoys, SEAD/DEAD assets, jammers against IADS radars, and the F-117A against key hardened command posts [21], [22].
There are several key observations, which must be made about this campaign.
The first is that it was representative of the NATO vs. Warpac scenarios of that period – while the Soviets had good numbers of SA-10, SA-11 and some SA-12 deployed, these were mostly committed to protecting strategic targets inside Soviet territory, leaving much of the IADS capability in Central Europe to Warsaw Pact allies equipped with a mix of SA-2, SA-3, SA-4, SA-5 and SA-6 batteries. While these systems were better maintained, often of better subtypes, and more competently operated than Iraqi systems, they also had to cope with the full capabilities of NATO and the US, not just the forces deployed during Desert Shield.
The second observation is a corollary of the first, in that the new highly mobile SA-10, SA-11 and SA-12 were not deployed in Iraq. Indeed, Iraqi deployment doctrine of that period paid little attention to mobility, with SAM batteries nearly always fixed in location.
To achieve the intended effect against this legacy IADS, the US expended hundreds of drones, and importantly, around 2,000 AGM-88 HARM anti-radiation missiles, to which must be added the complete but smaller warstock of British ALARM anti-radiation missiles.
The Desert Storm campaign remains a key historical benchmark, but unfortunately it has also created quite unrealistic expectations of what can be achieved over the longer term.
The next significant air campaign was the 1999 Operation Allied Force effort against Serbia. While it has been considered a success due to the low aggregate loss rates of Coalition aircraft, the success of the SEAD/DEAD effort was much less convincing. While the Coalition did successfully destroy most of the static SA-2 and SA-3 batteries, they only managed to destroy 3 out of 25 mobile SA-6 batteries, or 12% percent of that total, despite the large number of HARMs launched. Disciplined “shoot and scoot” tactics by the Serbian defenders, intended to keep missile batteries alive, resulted in a persistent threat of sniping attacks which kept much of the NATO force of F-16CJs, EA-6Bs and Tornado ECRs occupied chasing SAM systems, largely to no avail. The Serbians did execute one particularly successful ambush, killing an F-117A stealth fighter using a legacy SA-3 missile battery [23].
The Allied force campaign happened a decade ago, since then there have been no significant air campaigns in which an IADS was employed to deny access to attacking aircraft.
What the Desert Storm and Allied Force campaigns did achieve was to provide both a focus and an imperative for further evolutionary growth in IADS capabilities, doctrine and technological strategy.
In the decade that has elapsed since Allied Force, we have seen a commercially and strategically driven flurry of developmental activity in the Russian and Chinese defence industries, reacting to the lessons of the 1990s, but also exploiting the globalised market for high technology, especially computer technology, commodified high performance microprocessor chips, and Gallium Arsenide microwave chips. Perhaps the only silver lining in this situation is that the global Internet provides Western observers with a much clearer picture of technological evolution in Russia, less so in China, than during the late Cold War and early 1990s [24].
We can now identify a number of key trends in IADS evolution, which are well established, and will define the basic features of well constructed near future air defences, such technologybeing globally marketed by Russia, former Soviet Republics, and China.
(To be continued)
Last edited:
