If any new-generation BVRAAM is to
become a ‘game-changer’, then it has to have vastly improved kinematic
capability compared with that of existing BVRAAMs. This requires substantial increases
in two key parameters: ‘F-Pole’, i.e. the distance between the BVRAAM-launching
MRCA and its target when the BVRAAM hits; and a ‘no-escape zone’, the range
within which the BVRAAM can be fired and the target, no matter how it
manoeuvres, cannot escape. When an existing BVRAAM the like AIM-120D AMRAAM,
MICA or R-77/RVV-AE is fired at a target, it delivers the same amount of thrust
over a certain period regardless of the tactical scenario. If the target can be
reached without the rocket motor burning out, or shortly after it does so, the
BVRAAM will have a high-energy state during its terminal attack phase. This
will allow it to manoeuvre very hard, easily countering a targeted combat
aircraft trying to evade the incoming BVRAAM. If the target is farther away,
the BVRAAM will usually climb to a high altitude while its rocket motor is
burning and then coast on its built-up energy with gravity on its side until it
reaches the terminal phase of its flight (its final attack run. If the target
is not too far away, and the BVRAAM is still above it, it will dive down on the
target in an attempt to maximize its ability to make hard manoeuvres. The
longer the shot, the less energy the BVRAAM will have for its critical terminal
phase of flight.
Whereas the AMRAAM’s rocket motor burns
for seconds, then the missile coasts, a Meteor-type BVRAAM is under ramjet
thrust for its complete flight. Consequently, the latter’s average velocity is
higher and the Meteor arrives with the energy to out-manoeuvre its target.
Thus, both the F-Pole and the no-escape zone are increased. Instead of burning
off all its fuel right after launch it can throttle its engine back during
cruise, thus saving fuel. As it approaches its target it can throttle up,
eventually making its terminal attack while at its highest possible energy
state, around Mach 4.5, even when fired over long ranges. Not only does this
mean the Meteor will have more energy to manoeuvre during the endgame of the
engagement, but this capability also drastically increases the size of the no-escape
zone. Basically, the Meteor has a far greater ability to chase and catch enemy combat
aircraft over long ranges.
The Meteor’s data-link also has two-way
capability, so the pilot could re-target the BVRAAM while it is already on its
way. The pilot can also see the Meteor’s fuel-burn rate, kinematic energy and
tracking state in real-time. This is essential for making quick decisions as to
whether or not to fire another BVRAAM at the target or to run away if it is
properly tracking toward the target or has obtained its own lock. The Meteor
will be able to get those crucial mid-course guidance updates not just from the
MRCA that fired it, but from “third party” sources as well. These can include
other MRCAs, airborne early warning & control (AEW & C) platforms, and
land and sea-based radar and electronic surveillance systems that provide their
own situational awareness data to the missile-firing MRCA via data-link. Thus,
with many assets contributing to a common tactical network “picture” via common
data-link waveform and language, it provides information that anyone, including
the Meteor-armed BVRAAM and the Meteor itself, can exploit.
While the above-mentioned reasons are
precisely why the Indian Air Force (IAF) has ordered the MBDA-developed Meteor
BVRAAMs for its 36 Rafale M-MRCAs, the operational requirement for such
ramjet-powered BVRAAMs is for 2,500 units. And there’s another catch: the
Meteor BVRAAM should be compatible with the mission avionics of all types of
MRCAs that are in service with the IAF. This, in turn, represents a systems
integration challenge, but there is a solution, nevertheless.
This involves, on
one hand the installation of indigenous mission computer, stores management
system and pylon interface avionics (all using the MIL-STD-1760 digital
databus) on MRCAs like the Tejas Mk.1, Tejas Mk.1A, Super Su-30MKI and MiG-29UPG, while on
the other the Meteor’s MBDA-developed Ku-band active seeker and a module of its
rear-mounted two-way data-link can be replaced by corresponding India-supplied avionics
and sensors that are used by the indigenously-developed Astra-1 BVRAAM. This
way, the MMRs of Russia- and Israel-origin can seamlessly be integrated with
the Meteor BVRAAM, since India will first have the avionics and sensors integrated with the Israel-origin and Russia-origin MMRs at the Israel-based and Russia-based avionics integration test-rigs and then supply them to MBDA for installation inside the Meteor airframes.
Engineering studies to this effect were
jointly undertaken by MBDA and India’s Defence R & D Organisation (DRDO) back
in 2016, when the DRDO began its own in-house conceptual studies on develop a
solid-fuel ducted rocket (SFDR)-powered BVRAAM. It then emerged that a
suitably-modified Meteor BVRAAM containing DRDO-developed avionics was indeed
possible to both develop and integrate with the Russia-/Israel-supplied
AESA-MMRs, while at the same time not violating the IPRs of the MMR-supplying
foreign OEMs. In fact, MBDA is already well into such a re-engineering
programme for Japan, with whom the UK first began holding exploratory talks in 2014 on the prospects of a Meteor BVRAAM fitted with
an AESA-based Ka-band millimetric frequency seeker that was developed by
Mitsubishi Electric Co (MELCO) in the previous decade for the indigenously
developed AAM-4B (Type-99) BVRAAM. Later, in January 2017 the Cooperative
Research Project on the Feasibility of a Joint New Air-to-Air Missile (JNAAM)
commenced. If all goes well, then such a BVRAAM will begin flight-tests in 2023.
In India too, R & D work began in
2016 for developing AESA-based X-band and Ku-band active seekers for both the XR-SAM
long-range surface-to-air missile and the SFDR-powered Astra-2 BVRAAM, with Hyderabad-based
Astra Microwave already having built two types of such seekers (developed by the DRDL/RCI), with work
now underway on developing their Ka-band successors that too will be compatible
with the Meteor BVRAAM.
The Ka-band seeker with an active phased-array antenna (with 20km-range) and a secondary X-band passive channel will replace existing Ku-band seekers (with 6km-range) and
provide higher resolution and countermeasures resistance. Such seekers can
effortlessly work across multiple frequencies simultaneously, which makes them
not only better at finding objects, but are also more difficult to detect. In
addition, electronically steered antenna beams also offer other improvements:
it is possible to perform an adaptive antenna beam-forming based on antenna
sub-group transmit (Tx) and receive (Rx) channels or even adjusting all the
single antenna transceiver elements. This put us into a position to use
algorithms of super resolution in order to recognise and localise jammer
sources while concurrently conducting target acquisition and tracking.
