On paper, to the north, those Pakistan Army (PA)
battle formations that are LoC-specific and Chicken’s Neck-specific are the Mangla-based
I Corps that comprises the Gujranwala-based 6 Armoured Division, Kharian-based 17
Infantry Division, the 37 Mechanised Infantry Division also in Kharian,
and the 8 Independent Armoured Brigade; and the Rawalpindi-based X Corps that includes the
Gilgit-based Force Command Gilgit-Baltistan, Murree-based
12 Infantry Division, Mangla-based 19 Infantry Division, the Jhelum-based
23 Infantry Division, and the Rawalpindi-based 111 Independent Infantry
Brigade. Formations allocated for operations along the ‘Shakargarh Bulge’ are
the Gujranwala-based XXX Corps comprising the Sialkot-based 8 Infantry
Division and 15
Infantry Division; Lahore-based IV Corps with
its 10 and 11 Infantry Divisions, two semi-mechanised Independent Infantry
Brigades (including the 212 Bde) and one Independent Armoured Brigade; and the
Multan-based II Corps made up of the Multan-based 1 Armoured
Division, and the
Okara-based 14 Infantry Division, 40 Infantry Division and an
Independent Armoured Brigade. Thus far, no significant forward deployments of any of these formations
have taken place.
Down south, the battle formations arrayed against
Rajasthan include the Bahawalpur-based XXXI Corps with its 26 Mechanised Division, 35
Infantry Division, two Independent Armoured Brigades and the 105
Independent Infantry Brigade; and the Karachi-based V Corps with its Pano Aqil-based 16 Infantry Division, Hyderabad-based
18 Infantry Division, Malir-based 25 Mechanised Division, plus three
Independent Armoured Brigades at Malir, Pano Aqil and Hyderabad. So far, only some
elements of the 25 and 26 Mechanised Divisions have been deployed opposite an
area stretching from Jaisalmer to Fort Abbas and the PA has begun flying
relentless sorties of its Shahpar (CH-3) tactical UAVs that were acquired from
China’s CATIC in 2012.
This is probably a precautionary measure aimed at
monitoring the IA’s upcoming Division-level armoured/mechanised infantry
exercises that are held during wintertime. Along the Durand Line, formations
that are deployed include the Peshawar-based XI Corps currently with its
7, 9, 14, 17 Divisions and part of 23 Division, along with two independent
infantry brigades; and the Quetta-based XII Corps with the 33 and 41
Infantry Divisions).
The PA, however, is most
unlikely to attempt any form of escalation along either the LoC or the WB since
it presently has a deployment ratio of 54.6%, while the resting and
re-equipping ratio is 12.7%, and the remaining 33% is undergoing the training
cycle. This trend will continue for at least another four years, since the
defunct Durand Line too became active from mid-2014.
It may be recalled that
since March 2002, the PA has been forced by elements that later on went on to
become the Tehrik-e-Taliban Pakistan (TTP) by 2006 to wage a three-front war
against the TTP and the Islamic Movement of Uzbekistan (IMU) in South
Waziristan (which also included Chechan and Uighur militants; against the
anti-Shia Lashkar-e-Jhangvi (LeJ) and
Sipah-e-Sahaba Pakistan in the sensitive Darra Adam Khel-Kohat area of
Khyber Pakhtunkhwa or KPK (formerly NWFP) and the Shia-dominated Kurram Agency
of FATA; and, against the Tehrik-e-Nifaz-Shariat-e-Mohammadi (TNSM), headed by
Maulana Fazlullah, and the Jaish-e-Mohammad (JeM) in the Swat Valley of KPK.
The TTP’s cadre base is more than 20,000 tribesmen and the Abdullah Mehsud
group from the Alizai clan of the
Mehsud tribe from South Waziristan commands about 5,000 fighters. Other
militant groups within the TTP include Maulvi
Nazir from the Kaka Khel sub-tribe of the Ahmadzai Waziri tribe (South
Waziristan), Hafiz Gul Bahadur from the Ibrahim Khel clan of the Utmanzai Wazir
tribe (North Waziristan), the Haqqani network using manpower from the Mezi
sub-tribe of the Zadran tribe (North Waziristan), Mangal Bagh (Khyber), TNSM
(Swat, Dir, Malakand), and Faqir Mohammad (Bajaur).
Some 35% of PA troops (about
180,000 out of an end-strength of approximately 550,000 active-duty personnel
and another 500,000 reservists) were engaged in LIC campaigns since 2007 till
2014 and are still literally bogged down throughout the entire 27,200 square
kilometres of FATA.
Formations fully committed to LIC operations include the 37
Mechanised Infantry Division and 17 Infantry Division from Mangla-based I Corps
in Swat, 19 Infantry Division from X Corps in northern Swat (based out of
Jhelum), 7 Infantry Division from Rawalpindi-based X Corps in North Waziristan
(based out of Mardan), 9 Infantry Division from Peshawar-based XI Corps in
South Waziristan (based out of Kohat), 14
Division from Multan-based II Corps, Jhelum-based 23 Division (with 7
infantry brigades) of the X Corps, and 40
Infantry Division. The Gujranwala-based XXX Corps and the Bahawalpur-based XXXI
Corps lent one Brigade each.
In all, there
are approximately 17 infantry brigades or 45 infantry battalions, and 58
Frontier Corps (FC) wings now engaged in LIC operations. By mid-2011,
1,83,400 troops had a westward deployment orientation (it now stands at
206,000), while another 10,000 are now abroad on UN-related peacekeeping
missions.
Clearly, therefore, the PA is
most unlikely to stage large-scale land offensives involving manoeuvre warfare.
Instead, the PA, whose MBT armoury presently comprises 550 Al Khalids, 320 Type
85IIAPs upgraded to Al Zarrar standard, 500 Type 59s upgraded to Al Zarrar
standard, 380 Type 59s, 450 69IIAPs, and 320 T-80UDs, making for a total of
2,520 tanks, is likely to do what it did in both 1965 and 1971, i.e. use the
combination of its armoured and mechanised infantry assets to swiftly transform
Pakistan’s semi-urban and rural areas bordering India’s Jammu & Kashmir,
Punjab and Rajasthan states into impregnable fortresses for the sake of
blunting the Indian Army’s (IA) expected shallow-depth land offensives that
could be launched from southern J & K and northern Punjab through the
Chicken’s Neck and Shakargarh Bulge areas.
Given Pakistan’s elongated
geography, it is possible for the PA to use its interior lines of
communications for deploying its warfighting assets to their forward
concentration areas within 72 hours. To this end, the PA has since 2007 built a
sprawling new central ammunition storage depot to the South of its Mangla
Cantonment, and has also expanded the existing depot at Kharian.
Therefore, the IA’s principal doctrinal challenge is to seek ways of
enticing the PA to come out in the open so that its armoured/mechanised infantry
formations are forced to engage in manoeuvre wars of attrition, during which
the IA will be required to swiftly locate and destroy in detail the adversary’s
warfighting assets and capabilities. Exactly how this can be achieved is explained below.
Terrain Matching System (TMS) is an
intelligent decision-support system based on the integration of CBR and fuzzy
multi-criteria decision making. Classically, CBR uses symbolic and/or numeric
attributes. However, in reality there exists a certain degree of fuzziness and
uncertainty associated with the descriptors used for characterising problems.
Also, these problems can be better represented using linguistic world
expressions. Fuzzy case-based reasoning is a methodology, which uses linguistic
or realistic variables for case representation. It emulates human reasoning
about similarity of real-world cases, which are fuzzy (continuous and not
discrete). TMS consists of two components, i.e., the application developer and
the problem solver. The application developer is responsible for development of
any application desired by a domain expert (he/she should be able to define any
number of slots of different data required to define an application, through
slot manager). There is a provision for the domain expert to assign different
properties to slots in terms of indexing, fuzzy, descriptive, default values,
etc. through the case manager. Fuzzy function suitable for a particular
application can also be specified. This module has restricted access rights.
The problem-solver has major sub-parts like search engine, the similarity
computation module and the solution module. The search engine retrieves the
cases indexed by relevant indexing slots and computes similarity between the
query case and the cases retrieved from the case base. The cases entered
through the case manager under a case type, are indexed by the slots, which are
specified as indexing slots for that case type. Multi-criterion algorithm plays
a role in determining the usefulness of the selected cases. Search for most
similar and most useful cases results in the selection of only those cases that
are superior to or that dominate other cases in the case-base. Once a query
case is submitted, the similarity computation module of the shell retrieves the
cases similar to the current problem or situation using the indices. Each past
case is assessed for similarity to the current case according to the multiple
attributes. Similarity assessments are performed sequentially according to the
order of importance of attributes and help in determining usefulness of the
selected case for the current situation. The solution module proposes a
solution as evaluated by the decision system. The solution-case is having the
highest similarity score among all the retrieved similar cases. Thus, the most
useful and most similar case would be considered as the final suggested
solution to the user. The application of the module has been demonstrated for
finding terrain similar to a given target terrain, which is often the denied or
inaccessible terrain in a specific context. The multi-criteria decision-making
capability has been demonstrated by solving the problem of choosing the best
single/multiple air-drop/landing zones near a mission objective with specified
coordinates in an arid/semi-arid region.
Key
Areas Requiring Attention
It is obvious from the above-mentioned dispositions of the
PA’s armoured/mechanised infantry formations that Pakistan’s heartland remains its
province of Punjab, and nothing else. From this, one can deduce that the full
conventional might of the PA will be utilised for denying the IA the
much-needed space for deep AirLand battles. All talk, therefore, of the PA
acquiring ‘full-spectrum’ nuclear deterrence through the deployment of TNWs to
thwart large-scale IA land offensives is therefore utter baloney and boulderdash.
This becomes starkly evident when analysing the IA’s objectives for its future AirLand
campaigns that will most likely focus on ways and means of seizing back
Pakistan-Occupied Kashmir (PoK) through multi-dimensional AirLand campaigns being
launched from the southwest, east and to the north00all aimed at capturing the
districts of Bagh, Bhimber, Kotli, Mirpur and Muzaffarabad. The PA will
consequently be forced to commit the bulk of its offensive Strike Corps
formations against those IA’s offensive formations poised for breakout throughout
India’s Punjab State and the southern portion of Jammu & Kashmir State. In
such a scenario, should the IA be tasked with the attainment of India’s
strategic objectives through a high-intensity AirLand campaign lasting up to a
fortnight (to be waged by the IA’s mission-tailored Integrated Battle Groups,
or IBG), then the IA will be required to be supplied with two vital
force-multiplier capabilities that will bestow the IA with the overwhelming
superiority required for waging knowledge-based warfare through effects-based
tactical operations: tools for mastering the OODA Loop (which refers to the
decision cycle of observe, orient, decide, and act) such as integral land-based
and airborne intelligence, surveillance, target acquisition and reconnaissance
(ISTAR) assets capable of providing real-time targetting updates to Army
Aviation Corps platforms, the DRDO-developed and BEL-built Shakti ACCCS and the
on-site armoured vehicles; and customised armoured vehicles armed with target-specific
weapons.
OODA Loop
Over the past 16 years, significant efforts have been made
by India’s Ministry of Defence-owned DRDO laboratories and DPSUs like Bharat
Electronics Ltd (BEL) toward the fielding of RF-based and optronic sensors for
battlespace surveillance. Latest examples of these include the BEL-developed LRRSS,
the DRDO-developed and BEL-built BFSR-XR 50km-range and BFSR-ER 15km-range battlefield
surveillance radar, and the IRDE-developed and BEL-built, armoured
vehicle-mounted SEOS with 15km-range.
What is lacking, however, is the
availability of synthetic aperture radar-based sensors capable of providing high-resolution, photographic-like imagery, even in
inclement weather or darkness. The most obvious solution therefore lies in
equipping the recce-scout RSH version of the HAL-developed LUH with a lightweight
SAR sensor like SAAB’s Carabas, plus s stabilized LRRSS. The Carabas is
designed to enable superior foliage and camouflage penetration (FOPEN)
capabilities, wide-area surveillance and automatic target detection. It is
based on low-frequency SAR and change detection technology and it also exploits
polarimetric sensing. Carabas utilses two very broad bands in the low VHF
and UHF domains: 20–90MHz and 140–360MHz, respectively. It is the low VHF band
that gives Carabas its supreme penetration performance, while the UHF band is
more important for detecting smaller targets in lighter vegetation. Carabas’
signals penetrate foliage without reflections through all vegetation types and
man-made camouflage. The Army Aviation RSH helicopters, when equipped with such sensors, will
not only make the battlespace transparent and almost eliminate the fog of war,
but will also be able to provide real-time situational awareness updates to the
command post of Brigade-sized or Battalion-sized IBGs, based on which the IBG’s
commander will be able to rapidly respond to specific requests for both direct
and indirect fire-support, as well as wage effects-based combined arms
operations with both a wide variety of armoured vehicles and the Rudra
gunships.
Supplementing these will be a host of digitised
GIS-based tools (pertaining to both friendly and enemy territories) that are
now available (work on them began in 2009) for the IA’s South-Western, Western
and Northern Command HQs and can be readily uploaded on to any armoured vehicle’s
autonomous land navigation system (ALNS). Terrain analysis is the starting
point in conceptualising a battle. Natural or man-made diversity grants
different values for different areas, creates centres of gravity, breaks up
terrain into areas with varying degree of mobility, and creates checkpoints and
exclusion zones. Differences in elevation, soil-bearing pressure and other
trafficability issues, the location of natural obstacles such as rivers,
swamps, defiles, crevasses and artificial obstacles like intelligent
minefields, tank bumps, fortified gun posts, underground bunkers, deliberate
flooding and the existence of buildings, roads, bridges, dams, and religious
sites; all have an effect on build-up, mobility, troops and weapons deployment,
and field communications. These considerations apply to conventional and non-linear
dispersed operations equally. In order to succeed, all land-based military
campaigns require processing of terrain data and effective use of terrain
information functions such as planning, controlling, organising and
decision-making. Terrain information, therefore, is unquestionably a critical
resource in the operation of all military organisations.
Military Geospatial Information System
(MGIS) helps in generating terrain trafficability maps, commonly referred to as
Going Maps (GM), when data pertaining to five thematic layers, viz., soil,
slope, moisture, land use, and landform is fed into the system. It is then
integrated to produce the GMs in a three-level hierarchical manner. At every level,
the theme integration takes place through a trafficability-ranking matrix,
which actually encodes the domain knowledge for mobility. The theme integration
is implemented using an artificial neural network in a GIS environment to
overcome the limitations of spatial analysis of a conventional GIS and to
incorporate the generalisation ability of a neural network into the system. The
system divides going conditions into three categories, namely, ‘good going,
'restricted going’, and ‘difficult going’. Beside the generation of GMs, the
MGIS can also assess the ground water potential of a given terrain based on
case-based reasoning (CBR). A typical CBR cycle comprises the following four
steps: Retrieve the most similar cases, re-use the cases to solve the problems,
revise the proposed solution if necessary, and retain the new solution as part
of a new case. The attributes used for assessment of the groundwater potential
of a given terrain are geology, landform, land use, soil, slope, and lineament.
The case-base is prepared using cases having the aforementioned attributes
along with the results of the training case. Once a query case is received the
most similar cases are retrieved. Afterwards, the retrieved cases are combined
with the new case using ‘re-use’ mechanism to present the proposed solution to
the query case. The ‘revise’ process tests the obtained solutions for success,
typically on a real-world situation. Finally, the useful experience is ‘retained’
for future use, and the case-base is updated accordingly.
Terrain Feature Extraction System (TFES)
is being used for extracting terrain parameters or themes (land-use/land cover,
landform, and soil type) from satellite images and associated knowledge base in
an automated mode. The land use, landform, and soil layer has 10, 28, and 12
classifications, respectively. For land-use classification, a multi-layer
perceptron (MLP) is used for training and subsequent generation of
corresponding themes. The landform classification uses a texture-based method
for creating a database that is used for training MLP. However, texture-based
methods alone are not sufficient for generating landform themes. The advantage
with land-use is that the satellite images always capture the top canopy of the
earth’s surface, whereas for landform as well as soil-theme extraction, one has
to penetrate through the canopy and infer the thematic information based on
some ‘association rule’, or some other ‘relevant knowledge’. TFES first tries
to identify the terrain category to which the given image belongs. Afterwards,
it undertakes texture-, connectivity- and shape-based methods to delineate the
actual landform classes. The soil-theme extraction module actually divides the
computational process into two phases. The first phase uses the coarse classification
using MLP-trained-by-error back-propagation algorithm, whereas the second phase
allows the coarse-classified imagery to pass through a ‘rough-CBR’ system to
get the final soil classification. The rough set-theoretic approach is employed
in the final classification stage for its ability to discover
decision/classification rules from the data. The discovered rule-set is
referred to as the ‘soil information system’.
Terrain Reasoner System (TRS) helps
decision-makers (troop commanders, wargamers and mission planners) in a combat
development setting for arriving at route alternatives that are largely
determined by the threat capability of the obstacles and strategic nature of
the regions to be negotiated for a pre-specified mission accomplishment risk
factor (MARF). The problem of navigation and route planning of vehicles or
troops is defined as the final behavioural outcome of a sequence of complex
decisions involving several criteria that are often conflicting and difficult
to model. A fuzzy inference system has been built to implement the
perceive-reason-act decision cycle of a moving agent representing a vehicle or
a foot soldier in a safety-critical tactically driven scenario. A two-person
soft-game model has also been developed to compute the best-next-move for a
reflex, goal-oriented, rational, and utility-driven moving agent. The route
computation takes place directly over a satellite image that has been
classified as ‘go’, ‘slow-go’ and ‘no-go’ region. While the route traced by the
agent is locally optimum in a defined tactical sense, global optimality can be
achieved through a process of adaptive learning over several simulation
episodes. The agent-task environment interaction model is extended into the
virtual reality graphics environment. The baseline virtual reality extension
can be invoked by the user through access buttons in the graphic user interface.
By a proper selection of the camera placements and view perspectives, the user
is able to remain either static in a particular position or moveable along with
the roving agent and can watch (in 3-D) the tactical manoeuvre performed by the
roving agent from different vantage points. The virtual reality implementation
is meant to serve as an exploratory tool for finding strategically interesting
configurations of various objects thereby enhancing the user's situational
awareness of the scene.
Customised
Armoured Vehicles for Waging Knowledge-Based Manoeuvre Warfare
First firm indications of the kind of futuristic families
of armoured vehicles required for the future digitised AirLand battlespace emerged
two years ago when, following 10 years of operations analysis starting in the
mid-1990s and the consequential 10 years
of military-industrial R & D work that began in 2005, the Russian Army unveiled
its Ob’yekt
148 T-14 Armata MBT, the Ob’yekt 149
T-15 tracked heavy fire-support combat vehicle (FSCV), the Ob’yekt 693 and Ob’yekt 695 Kurganets-25 tracked ICVs, and lastly the 8 x 8 Boomerang
VPK-7829 wheeled APC. Just prior to that, the Russian Army had already developed
the BMPT-72 FSCV, which will in future be superceded by the Ob’yekt 149 T-15 tracked Heavy ICV.
The FSCV has today emerged as an irreplaceable
element of the combined-arms, armour-heavy IBGs since it plays the critical
role of supporting the armoured assault team with target acquisition and close-/medium-range
fire-support and anti-armour team suppression. It is also highly effective in both
rural and urban areas, offering elevations and depression angles for both main
weapons and their associated optronic sensors. Without the BMPT-72’s existence
today, MBTs like the T-90S, T-72CIA and Arjun Mk.1A would be highly vulnerable
to anti-armour ambushes laid by dug-in hostile forces lurking within rural
farmhouses of the type prevalent in Pakistan’s eastern Punjab province and
southern PoK.
The
BMPT-72’s turret contains 850 rounds of APRS-T, HEF-I, AP-T, plus KE rounds. A redesigned
turret with lower profile and better protection, including armoured shields for
protecting the 9M123 Khrizantema ATGMs from splinters and small-arms fire, have
been incorporated. The ATGM launchers are positioned oblique side-by-side
rather than the previous stack configuration. The BMPT-72 also uses improved
fire-control and navigation systems, utilising video, thermal imaging and laser
rangefinder sights for both the commander and gunner. The standard T-72 hull has
received a remodeling with add-on armour and reactive armour modules, with slat
armour protecting the rear area. The laser-guided 6km-range 9M123F version of
the Khrizantema, developed byKBM Kolomna Machine Design Bureau,
comes with a thermobaric warhead for destroying bunkers and other man-made dwelling
structures.
Another
vehicle similar to the BMPT-72 is Israel’s Nammer heavy ICV, which comjes
equipped with state-of-the-art vectronics developed by ELBIT Systems for
offering dramatically enhanced all-round situational awareness.
Yet another vital component of the IBG
when waging manoeuvre is the land-mobile 120mm breech-loading mortar, which had
until recently remained a much maligned and
under-appreciated weapon. The IA’s military planners and warfighters tend to be
enamoured with high-tech weapon systems and fail to recognise the potential of
a tried and true weapon that has been around since before the American Civil
War. While high-tech weapon systems have their place on the battlefield, they
are expensive and should be used for high-value targets. It is universally
accepted that the mortar is an indirect fire weapon. However, few are aware that the mortar
can also be utilised in a direct-fire role. When mounted on a lightweight
armoured vehicle and firing high-explosive fin-stabilised, shallow coned-shape
charge—high explosive squash head— munitions, the mortar can have a devastating
effect on brick and masonry walls. What once provided cover and concealment to
the enemy now becomes a lethal, casualty producing, spall.
The devastation can be
localised without bringing down entire structures. The secret to employing the mortar in the
direct-fire mode is the incorporation of a breech block and a pivoting base rather
than the traditional base-plate. The breach block and pivoting base-plate allow
the mortar to be used in the traditional muzzle-loaded role using conventional
munitions, or in the breech-loaded direct-fire mode using specialised
munitions. The concept of using a
mortar in, both, an indirect fire and a direct-fire mode had its advent during
World War-2 when the Swiss developed a 105mm breech-loaded mortar. However,
this was not adopted by any of the warring powers. After WW-2, this weapon
became commercially available and was purchased in limited quantities by both Pakistan
and Malaysia.
The idea of a breech-loading mortar, although
not new, now seems to be receiving renewed interest.
In 1996 BAE Hagglunds
and the Finnish armaments developer Patria developed the advanced mortar system
(AMOS) a turret-mounted, breech-loaded, twin-barreled 120mm for mounting on
both tracked and wheeled vehicles, as well as coastal patrol vessels. The AMOS
is capable of firing a wide range of conventional and specialised ammunition.
With both guns sharing a common cradle, the AMOS is capable of multiple rounds
simultaneous impact. In 2007 BAE tested its non-line-of-sight mortar,
NLOS-M platform. Like the AMOS it fired a wide range of conventional and
specialised mortar munitions, and like AMOS, it was capable of multiple round
simultaneous impact. To date, the development of such mortars has focused on
120mm systems, which were tied to larger programmes.
A mortar that can be either
breech-loaded or muzzle-loaded, and can be used in either an indirect or
direct-fire mode, is still worth pursuing particularly for use in the current
theatres of operation in South Asia. The focus should also be on 81mm calibres.
The ability to deny the enemy cover and concealment afforded by brick and masonry
walls without having to demolish entire structures or rely on high-tech weapon
systems needs its day in court. Leveraging
existing technologies to put such a weapon system in the hands of troops today,
and not five years down the road, is both affordable and low-risk,
technologically. An 81mm lightweight vehicle mounted breech-loaded mortar,
designed to accompanying dismounted ground troops operating in an urban or
rural environments, or in support of remote outposts, will provide immediate
direct-fire or indirect fire capabilities to small unit leaders at the squad-
and platoon-leveld. Commanders could concentrate the fires of mortars from
decentralised locations on targets of opportunity, or employ the mortar systems
independently, or as part of existing organic fire-support assets from a
centralised location in support of ground operations.
The last vital component of the IBGs are
the armoured vehicle-mounted surveillance and target acquisition (SATA) systems
and sensors that, when mounted atop raisable hydraulic masts, provide enhanced
situational awareness and fire-support coordination vectors for the MBTs, FSCVs,
ICVs and APCs. So what are the IA’s home-grown options that can be rapidly exploited
in order to field the fleets of FSCVs, APCs and SATA-related platforms?
Before exploring the various available homegrown
platform options, it will be worthwhile to take note of the fact that over the
past 15 years, significant military-industrial competencies have been attained
in areas like automotives, digitised vectronics and related data-buses, composites-based
appliqué armour and ceramics-based add-on armour tiles, and soft-kill and
hard-kill self-defence suites—some of which are highlighted in the following
slides:
Tailor-Made
Platform Options
From the above, it becomes evident that
if the intention is to acquire overwhelming conventional superiority against
its adversary, the IA will be required to undertake a radical makeover of its
manoeuvre warfare force structures. For instance, a Regimental IBG will then
have to comprise two ISTAR vehicles, 40 MBTs like the Arjun Mk.1A, eight FSCVs,
four breech-loading mortar carriers, 15 BMP-2 ICVs, and up to 20 wheeled 8 x 8
APCs. But rather than procure new-build vehicles for developing such platforms,
preference must be given to the modification and upgrade (through
public-private industrial partnerships) of existing armoured vehicles that are
presently lying totally unutilised.
For instance, up to 2,200 Vickers
Mk.1/Vijayanta 39-tonne medium battle tanks were built from the late 1960s till
the early 1980s. On the other hand, 1,800 T-54
and 36-tonne T-55 medium battle tanks were inducted into service throughout the
1960s and 1970s. The first batch of 300 T-54s were
ordered in 1964 from the USSR and were delivered between 1965 and 1967. The
second batch of 225 T-55s were
ordered in 1968 and were delivered between by 1971. The third batch of 650
T-55s were ordered in 1971 and were
delivered between 1971 and 1974. In addition, 274
T-54s, 44 T-55s and seven T-55AKs were ordered in 1970 from
Czechoslovakia and delivered between 1970 and 1971. A further 300 T-55s were ordered in 1971 from Poland and
delivered in the same year. Of these, 800 T-55s were upgraded with Polish assistance
in the 1980s.
All these vehicles can easily be
modified and upgraded through the installation of all those items mentioned
above. In addition, both the Vickers Mk.1/Vijayantas and T-55s need to be
fitted with new powerpacks, with the obvious choice being the Model V-84MS
four-stroke 12-cylinder multi-fuel engine developing 840hp, which has been
licence-built by the MoD-owned and Avadi Heavy Vehicles Factory since the late
1980s.
Following the structural upgrades to
their hulls and fitment of new powerpacks and vectronics, different types of mission-specific
turrets will have to be installed. For instance, the ISTAR vehicle will require
the installation of raisable hydraulic masts containing BFSR-ER & SEOS sensors,
which will receive locational data from a RSH helicopter equipped with foliage-penetration
SAR and will then take over the task of zeroing in on the precise positions of
hostile mortar locations, bunkers and camouflaged MBTs.
For command-and-control purposes, the
T-55’s OFB-developed Taimour APC version will come in handy.
The FSCV, on the other hand, will have a
target acquisition/fire-control system comprising a commander’s panoramic sight
identical to that of the Arjun Mk.1A and a gunner’s sight that uses the TISAS
and TISK vectronics of the BMP-2K, but its main job will be to target hostile
bunkers and dug-in enemy infantry concentrations with both its twin 30mm 2A42
cannons as well as 9M123F Khrizantema missiles armed with thermobaric warheads
that create a sustained and intense pressure-wave, which can be used against
bunkers and hardened targets, while causing minimum damage to the surrounding areas.
Accompanying the FSCV will be the 120mm
breech-loading mortar carrier for engaging dug-in enemy infantry concentrations.
The existing BMP-2 ICVs will be required
to be re-equipped with a new-generation turret containing TISAS vectronics, a
single 2A42 cannon, plus a 30mm automatic grenade launcher.
In addition, each BMP-2’s embedded
infantry squad should be armed with a 9P135M Manportable launcher with FLAME
adaptation kit, plus four Konkurs-M and four Milan-2T ATGMs.
Lastly, the wheeled 8 x 8 APCs like the
TATA Motors-developed Kestrel will require only a 12.7mm machine-gun mounted on
a remote-controlled weapon station (RCWS) of the type already on board the
Arjun Mk.1A MBT.
Thus, the vehicular configuration of a Regimental IBG will include all the vehicles shown in the slide below.
Other
Platform Possibilities
Several financially attractive options
exist with regard to making effective use of modified hulls of the T-55 and
Vijayanta medium tanks. These include:
Using the T-55’s re-engined hull for mounting
customised turrets housing demining flails, like what has been attempted by the
DRDO under the CMF-72 project.
Using the T-55’s re-engined hull for mounting
full-width mine-ploughs that can be used for swiftly breaching minefields laid
in-depth (up to 1,600 yards).
Using the Vijayanta’s re-engined hull to
house AAA turrets like the Typhoon from Israel’s RAFAEL, or the upgraded
ZSU-23-4’s turret.
Using the Vijayanta’s re-engined hull to
house low-level tactical gapfiller air-defence radars like the L-band Bharani that
can be raised with the help of a hydraulic mast.
Finally, for base air defence, a
truck-mounted solution can well be developed by making use of the OFB-built AK-630M
cannon that makes use of the BEL-built Lynx UX multi-sensor fire-control
system.
(Concluded)
WTF!
WTF!
It appears that the NORINCO’s
ZBD-08 tracked carrier carrying the AFT-10 CM-501G NLOS-ATGMs too has felt the
need for a panoramic target acquisition/tracking system just like the IA had
felt the need for its NAMICAs armed with Nag ATGMs! This new version of the
ZBD-08/AFT-10 combination is now at the expo centre in Zhuhai for the forthcoming
Airshow China 2016 event (starting November 1), which will be an aerospace
event in name only and will play host to the complete range of land-based
weapons developed by various military-industrial entities of China. Judging by
external looks, especially the camouglage paint patterns, all such weapons
platforms are being targetted for sales in the Middle East/North Africa
regions.
