1 CONTENTS Aircraft 04 Chengdu J-20. China’s ram for “cheese boxes on rafts” Summing-up 12 Russia’s aviation industry in 2010: from Sukhoi PAK FA to Tupolev TU-204SM Review of the Most Important Events of the Last Year Engines 20 The Motor Sich: Development, Production and Services Avionics 24 “Radionix” (Microwave Systems Design Company) — crisis solutions to upgrade fighters’ avionics Navigation 28 Compas: priorities of space navigation View of analyst 32 India and Russia: new joint military projects 44 Russian arms trade Bangalor's Sky Waiting № 1. 2011 Bangalor's Sky Waiting
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1
CONTENTS
Aircraft
04 Chengdu J-20. China’s ram
for “cheese boxes on rafts”
Summing-up
12 Russia’s aviation industry in 2010:
from Sukhoi PAK FA
to Tupolev TU-204SM
Review of the Most Important Events
of the Last Year
Engines
20 The Motor Sich:
Development, Production
and Services
Avionics
24 “Radionix” (Microwave Systems
Design Company) — crisis solutions
to upgrade fighters’ avionics
Navigation
28 Compas: priorities of space
navigation
View of analyst
32 India and Russia:
new joint military projects
44 Russian arms trade
Bangalor's Sky Waiting
№ 1. 2011
Bangalor's Sky Waiting
2
Yet another exhibition of world aviation industry achievements — Aero India 2011 — has
opened its doors. The show gathered a large number of professionals from many countries,
two of which are India and Russia. These two powers have much in common in the aviation
sector, and India has been Russia’s strategic partner for many decades. Since the early
1960s India has been purchasing Soviet and Russian aviation equipment. Today, this
partnership has stepped to a new level. Not only does India purchase aircraft but the two
countries work on joint development projects, the most important one is the PAK FA T-50.
India keeps stressing the critical importance of the project in the light of the recent flight
tests of China’s Chengdu J-20 fighter. The T-50 is developing successfully; the second
prototype is currently passing tests.
Apart from this, in 2010 a joint venture was established to develop the multipurpose
transport plane (MTA). The project also holds the status of joint programme which is
of great concern for both Russia and India.
The third important fact is that Russia is taking part in tender for selling 126 fighters for
the Indian Air Force with its MiG-35. These aircraft have successfully completed flight
tests in both countries, and Russia has every chance to win the tender partly because
MiG-35 has been unified with the MiG-29K fighter, which is currently entering service
with the Indian Navy. Apart from the mentioned competition Russia is also participating
in tender for supplying the light scout helicopters for the Indian Armed Forces with its
K-226s. Russia also hopes the final choice will be in favour of these machines. Trying to
describe the scope of Russian-Indian partnership it’s noteworthy that India’s advanced jet
trainer is equipped with Russian AL-55 engines. Some other interesting facts come to my
mind as well...
A lot can be said about Russian-Indian joint projects and military and technical
cooperation but let’s sum it up to one phrase: “There is no other country like India for Russia
to lead such a great number of joint projects and sign contracts to supply various aircraft
equipment. Today, India is Russia’s major strategic partner in the aviation industry”. While
reading feature of this issue you’ll face some facts proving the statement and will find a lot
of interesting and useful information.
I wish you successful and fruitful work at the Aero India 2011, as well as fresh impressions
and prospective business contacts.
Yours faithfully,
Alexander Gudko
Director GeneralEvgeny Osipov
Deputy Director GeneralAlexander Kiryanov
Commercial Director Denis Kostin
Marketing Director Leonid Belyaev
Marketing Manager Elena Bebneva
Creative DirectorAlexander Strelyaev
Editor-in-Chief of A4 Press PublishingViktor Murakhovskiy
The magazine is registered in the Committee for Press of the Russian Federation. Certificate № 016692 as of 20.10.1997. Certificate № 77-15450 as of 19.05.2003.
8-10 March, 2011AsiaWorld-Expo, Hong Kongwww.AsianAerospace.com
Is the high growth occurring in Asia at the heart of your corporate development strategy?
It should be.
Book your opportunity in the heart of this growing commercial market Right Now
Organised by
For more information, please contact: David Lim Tel: +65 6780 4669 Email: [email protected]
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Associated Event
Aircraft
4
Before touching off the ground, the pi-
lot made several passes over the runway
so as to expose his airplane to the cameras
of “aviation admirers” all round the place.
Those took photos of the aircraft from dif-
ferent angles and depicted everything they
wanted except for doors of internal weap-
ons bays.
These doors were either thoroughly hid-
den or removed from the shots by the picture
takers on the insistence of very competitive
advisers. But it is even more likely that these
doors were not actually fitted to the J-20
first operable prototype. They are not need-
ed on the very first operable aircraft dedi-
cated to assessment of flight performance,
flight envelope, various engine settings,
functioning of the essential onboard systems,
proving flight control algorithms. As a rule,
third or even later prototypes are devoted
to weapons testing, but these are yet to be
constructed and outfitted.
The J-20 first public flight occurred just
in time when US defense secretary Rob-
ert Gates was in Beijing on an official vis-
it. Once there, he was trying to calm down
the Chinese leaders who were much wor-
ried about pending deliveries of modern
US-made weapons to Taiwan. Beijing con-
siders this island an essential part of China.
A lot of pictures appeared on the In-
ternet on the memorable day of 11 Jan-
uary. These shots gave more information
on the new airplane. In particular, they re-
veal the shape of the wing and its position-
ing in relation to fuselage. This makes it
possible to make some preliminary conclu-
sions about the aerodynamics layout and
technical characteristics of the J-20, and
make guesses as to the main task the new
jet shall be solving after entering squad-
ron service.
The J-20 represents a relatively large
tactical jet with the canards (foreplanes)
and large delta wing. The fuselage length
is somewhere between 23 and 25 me-
ters, wingspan between 13 and 14 me-
ters. By our estimation the maximum take-
off weight shall be in the region of 40 tons,
and operating empty weight twice less
than that.
Many aviation experts believe that
the J-20 relies on a pair of Russian engines
or their Chinese copies. In other words,
the J-20’s engines are picked out among
members of the big family uniting the Item
117, AL-31F, WS-14 and WS-10 Taihang.
Two engines together develop in between
30 and 40 tons of thrust. If that is so, then
the capability of the propulsion system
On 11 January 2011 the new Chinese combat jet flew for the first time (in public, at least). The new
airplane is referred to as the Chengdu J-20. Chengdu is the name of the city which houses a few
aviation industry enterprises, including aircraft manufacturing plants producing jetfighters and design
houses developing them. Great many outsiders watched the J-20 fly, as they happened “by chance”
to be around the fence of Chengdu factory’s aerodrome on that day. The flight itself was uneventful.
It took place in the conditions of clear skies allowing photographers to make some good shots.
CHENGDU J-20.CHINA’S RAM FOR “CHEESE BOXES ON RAFTS”
Aircraft
5A I R F L E E T · 1 · 2 0 1 1 ( 8 6 )
is enough for supercruise, or supersonic
cruise flight at military power (highest pow-
er setting without afterburning). We may
also expect that the J-20 with restricted fu-
el and combat load (for instance, when fly-
ing air-to-air mission) can fly vertical with-
out losing speed at subsonic regimes and
low altitudes.
When in-flight photos appeared,
the J-20 became the hottest topic for dis-
cussion among aviation enthusiasts round
the world. But as it appeared, the enthu-
siasts, and even world-famous western
journalists, had difficulty in classification
of the new Chinese warplane. Is it a su-
periority fighter? Is it a supersonic bomb-
er? Or, perhaps, it is a multirole, multimode
airplane? Even columnist and experts with
world’s leading aviation magazines hes-
itated to give their clear answer to these
questions, — that in the view of them hav-
ing good sources in the US and Europe-
an intelligence bodies, defense ministries
and the industry. It seems that not only jour-
nalists, but the professionals were in some
state of shock after seeing the new Chi-
nese bird.
First of all, let’s determine J-20’s center
of gravity position. There are some pho-
tos available of the J-20 taxiing, in which
we can clearly see its long fuselage, wing-
to-fuselage connection and landing gears.
The J-20 undercarriage is fighter’s clas-
sics: three-point with a nose gear. And so it
makes it easy to determine center of grav-
ity position. To do that we take the main
landing gear strut, and attach a line to
it starting on the wheel’s ground contact
point. The line goes up with at an angle of,
say, 15 degrees, leaning towards the nose
of the airplane. The point where it cross-
es the fuselage center line is the most likely
position for the airplane’s center of gravity.
Here comes the first surprise: the like-
ly center of gravity position rests… too far
from the mean aerodynamics chord (MAC)
of the wing. As a first iteration for aircraft
designers, the center of gravity must be
somewhere 25–35% of the wing’s MAC, —
like so is prescribed in the classic aircraft
design books.
But the Chinese airplane appears to
have the center of gravity position some-
where at MAC’s edge. It is fairly strange
for a maneuverable fighter, since bal-
ancing of the aerodynamic forces and
the gravity will require relatively high de-
flection of the control surfaces — canards
in the J-20’s case. Should this airplane try
to execute high-G maneuvers at subsonic
speeds, the deflection of the canards could
be a limitation. All this is rather strange
for a maneuverable fighter… But not for
the J-20, which does not appear to be one
of those!
Let’s take a look at other available pho-
tos, in which the J-20 goes in for the land-
ing with landing gear down. Apparent-
ly, the canards are set at a rather high pos-
itive angle (leading edge upwards), while
the wing has its leading edge deflected
downwards. The trailing edge surfaces are
also deflected down, at rather a small an-
gle. Obviously, at the approach for land-
ing configuration, the wing’s center line
is highly curved by means of the leading
and training edges down, which increases
lift (achieved through altering the camber
of the wing). But not so much as in the case
of classical flaps.
All this is, again, fighter classics for
the delta winged aircraft with foreplanes.
And here lies their limitation: the pilot can-
not move the trailing edge further down,
since the resulting lift force that builds up
on the training edge will be hard to bal-
ance with the canards, in the view of their
limited deflection scope (in the view
of them stalling).
It is well known from the aviation his-
tory how to enable delta-winged air-
planes to generate more of the lift force
at landing. For that purpose the canards
are placed as close to the fuselage’s nose
as possible, to have a larger distance to
The J-20 relies on a pair of Russian engines or
their Chinese copies coming from the big family
uniting the Item 117, AL-31F, WS-14 and WS-10
Taihang
Aircraft
6
the center of gravity. For instance, the Tu-
polev Tu-144 supersonic jet liner had fore-
planes that were retracted into fuselage
all the time except landing. But Cheng-
du designers did not do this. Rather, they
positioned the canards fairly close to
the center of gravity position, and thus
sacrificed their effectiveness at landing for
some other purposes.
What purposes? Firstly, for non-retract-
able foreplanes it is important to have
them within the supersonic cone as it sets
on the top of the airplane’s nose at Mach
numbers exceeding 1.0. This lead to a con-
clusion what the Chinese must have been
purposely shaping the J-20 for superson-
ic flying.
Why the Chinese shaped the J-20
in the way it is? Perhaps, they are unfa-
miliar with the classic solutions for a del-
ta-winged, canard-equipped fighter? No,
this is not the case knowing that Chengdu’s
previous design was the J-10 light weight
fighter, now in service with PLAAF. On its
first public flight, the J-20 was escorted by
a J-10B twin seater, the operational train-
er version of the baseline J-10 single seat
fighter. This airplane was the star of the Air-
show China 2008 and 2010, when it flew
superbly with the PLAAF display team pi-
lots at the controls. The J-10 is a very ma-
neuverable airplane, and this is the testimo-
ny of the Chinese designers’ skills in devel-
opment of maneuverable fighter aircraft.
What is the J-20? Is it
a superiority fighter?
Is it a supersonic
bomber? Or, perhaps, it
is a multirole, multimode
airplane? Few columnists
and experts dared to give
their explicit answer
F-35C Lightning II
Chengdu J-10B twin seat
operational trainer
Importance of proper shaping of supersonic fighters can be illustrated by the case with the Sukhoi Su-27S, where suffix “S” points at the optimized version with reduced transonic drag. The optimization effort was made by Sukhoi designers in cooperation with TsAGI, as they tried to improve transonic performance of then-new fighter. Three TsAGI’s big wind tunnels, the T-112, T-108 and T-109 were used in the process. As a result of very accurate optimization of the fighter’s cross section distribution diagram, the Su-27’s “wave drag” was reduced by 25% — not before the designers had virtually redeveloped the airplane (the initial aircraft was referred to the Su-27, improved the Su-27S).
Aircraft
7A I R F L E E T · 1 · 2 0 1 1 ( 8 6 )
Aircraft
8
The J-10 is a classic design with “prop-
er” positioning of the center of gravity, like
in the books. This is clear to tell looking
at the main landing gear struts attached
to the fuselage somewhere near 15–30%
of the wing’s MAC. So, let us ask ourselves
the same question again, why the Chinese
designers shaped the J-20 in the way it is?
Here are some suggestions.
First, to achieve smooth airflow with de-
sirable parameters at the entry to the en-
gine’s fan, the J-20’s designers have to
make the air intakes rather long. This was
an important consideration at design stage.
Second, they also needed to make
the air channel S-shaped, so as to hide
the fan blades from the radio waves emit-
ted by enemy radars. The latter is need-
ed for a lower visibility of the airplane. It
is worth to notice that the J-20’s air intakes
resemble those first tried on the Lockheed
Martin F-35 Lightning II. This gives move
ground to assert that the J-20 is optimized
for supersonic regimes and supercruise,
much like the F-35.
Third, let us make distribution diagram
for the airplane’s cross section along
the J-20’s fuselage centerline. We need to
take account of the thickness of the wing,
canards and tailplanes. The diagram is
very smooth, — exceptionally smooth! It
comes without a peak, running smooth-
ly at approximately the same height from
F-22 Raptor
F-22 Raptor —
Cutaway
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Aircraft
9A I R F L E E T · 1 · 2 0 1 1 ( 8 6 )
the tops of the air intakes all the way to
the engine nozzles.
This seems to be the main thing for
the Chengdu designers. Apparently, they
wanted to make the airplane’s equiva-
lent body of rotation as narrow as possi-
ble. And they needed to make provision
for internal carriage of weapons, which
is a characteristic feature for fifth gener-
ation fighters. In actual fact, the J-20 has
much smoother cross section distribution
diagram than the F-22A Raptor, the F-35
Lightning II and the Sukhoi T-50 (PAK FA or
FGFA). Apparently, it required quite an ef-
fort from Chengdu designers and so made
them go for compromises on other things.
Should the designers from Chendgu
have made it “classic”, they would not
have moved the wing all the way towards
the engine nozzles. But they did because it
was the only effective way to make the air-
plane as narrow as possible, with the need
for big air intakes, air-supply channels and
internal weapons bays.
Again, this is the main thing about
the J-20 design, and it sets it apart from
all other known next-generation fight-
ers. Other designs have “peaks” in some
60–70% down the way from the fuselage
nose tip to the engine nozzles.
A smooth cross section distribution dia-
gram is important for transonic drag. Su-
personic aircraft are being designed
in accordance with so-called “area rul-
ing”. For high Mach numbers (M>2)
the distribution diagram is not so impor-
tant as for transonic regimes, M=1…1.5. It
seems the Chinese designers optimized
their new jet for transonic regimes and
moderate supersonic speeds.
Our impression from the J-20 is that it
is an uncompromised airplane for super-
cruse, for flying at moderate supersonic
speeds corresponding to Mach M=1.3–
1.6. Such speeds can be achieved with-
out afterburning. Surely, the J-20 can ac-
celerate to M=2 and faster, but this would
require engaging afterburners. In turn,
the fuel burn will go high, lowering oper-
ational range of the aircraft and enlarg-
ing its heat signature.
In our view the Chinese designers op-
timized their new jet for M=1.3–1.6. Ma
tej
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Aircraft
10
Here comes the clue: the J-20 is a mis-
sile launching platform able to evade en-
emy interceptors by high cruise speed.
The J-20 may prove a good interceptor, —
very possibly. But its main task seems to
be anti-shipping: firing missiles at enemy
warships while denying their air defense
cover.
It may well be that one day the new
Chinese jets would be used in anger. And
it would probably be PLAAF sending their
pilots to attack warships off the coast
of a freedom-loving island not far from
the mainland China.
The history of the powerful US Na-
vy can be traced back to the famous
duel of the USS Monitor and VSS Vir-
ginia (Merrimack) on 9 March 1862,
the first-ever battle of ironclads. Although
the Confederacy gunners scored hun-
dreds of direct hits, shells bounced off
her armor: the Monitor seemed to have
impunity to enemy fire. The USS Moni-
tor, a 987-ton armored turret gunboat,
was built at New York, with a large sin-
gle cannon turret on a low freeboard. Af-
ter the battle, the North Americans con-
structed fifty monitors modeled on their
namesake and made them the back-
bone of their navy. For their rather strange
looks, these ships were called “cheese
boxes on rafts”. Since the memorable Bat-
tle of Hampton, the North Americans nev-
er lose at sea, and now their cheese box-
es sale when and where they want. China
prepares a ram for them.
Vladimir Karnozov
J-20 seems to be
intended for anti-
shipping: firing missiles
at enemy warships while
evading interceptors by
means of higher speeds
Sukhoi T-50
Aircraft
11A I R F L E E T · 1 · 2 0 1 1 ( 8 6 )
Summing-up
12
First Fifth Generation FighterOn 29 January 2010, Sukhoi conduct-
ed the first flight of its prototype of the PAK
FA fifth generation fighter from KnAAPO’s
(Komsomolsk-on-Amur Aircraft Produc-
tion Association) site. The Sukhoi PAK FA
(or Promising Aircraft of Frontline Aviation)
will replace the operational fighters of pre-
vious generations resulting in achievement
of the strategic parity between the Russia’s
and US Air Forces in terms of fighter avia-
tion technologies.
As reported in the official press release
by the Sukhoi Company, unlike the fight-
ers of previous generations the PAK FA
combines the features of both strike air-
craft and fighter. The fifth generation air-
craft is equipped with brand new avionics,
which integrates an “electronic pilot” func-
tion, as well as with phased-array anten-
na radar. As such, it significantly decreas-
The year of 2010 turned to be a momentous year for the Russian aviation industry. It was marked
by the first test flights of the Sukhoi fifth generation fighter and new Tupolev civil airliner at the
beginning and at the turn of the last year, respectively. Such events as certification of SaM-146
engine, which is intended for Sukhoi Superjet-100, and integration of the Russian and Ukrainian
aircraft manufacturers are no less important.
RUSSIA’S AVIATION INDUSTRY IN 2010:FROM SUKHOI PAK FA TO TUPOLEV TU-204SM
Review of the Most Important Events of the Last Year
Summing-up
13A I R F L E E T · 1 · 2 0 1 1 ( 8 6 )
es pilot load and allows concentrating
on fulfilment of tactical missions. New air-
craft onboard equipment allows real-time
data exchange with ground control sys-
tems as well as within the air group. Appli-
cation of composite materials and innova-
tive technologies, aerodynamic configu-
ration, and actions based on engine noise
reduction provide unprecedentedly low
level of radar, optical and infrared visibility.
This significantly enhances the combat ef-
fectiveness against air and ground targets
at any time of the day in both visual and
adverse weather conditions.
According to the Russian analyti-
cal reports, the effective reflecting area
of the new aircraft amounts to 0.5 square
metres while the same characteris-
tics of the Su-30MKI fighter equals to
20 square metres. Some Russian media
sources reported that this effective reflect-
ing area of 0.5 square metres in the for-
ward hemisphere was related to airframe.
After application of anti-radar coating and
replacement of the cockpit canopy with
the one with radio wave absorbing coat-
ing, the effective reflecting area value may
decrease up to 0.01–0.03 square metres.
All weapons intended for the new fifth
generation fighter are kept inside the fuse-
lage bay. This crucial feature increases its
stealth capability and ensures a superson-
ic cruise speed at unboosted engine oper-
ation. The view of the Sukhoi PAK FA from
below clearly shows the half-doors of two
weapon bays arranged longitudinally one
after another. Their size makes it possi-
ble to room the advanced missiles devel-
oped by Tactical Missile Weapon Corpo-
ration in accordance with the Comprehen-
sive Target Programme on Development
of New Air Weapons, which is being im-
plemented along with the PAK FA develop-
ment programme. Some media sources re-
port that the PAK FA developers managed
to solve the problem regarding opening
the half-doors and launching missiles in su-
personic mode.
The first fifth-generation fighter proto-
type is equipped with engines, designated
as “product 117", developed by Saturn Re-
search and Production Association in Ry-
binsk. In fact, this engine is a deep mod-
ernization of the well-known AL-31FP with
improved specific and long-term perfor-
mance characteristics. Many experts agree
that the Sukhoi aircraft will require a new
engine in order to achieve the same flight
and technical characteristics as the Ameri-
can F-22A. In this respect, it is hardly pos-
sible to use AL-41 engine developed for
the MiG 1.42 new generation fighter since
it has different dimensions which are not
acceptable for the Sukhoi PAK FA. How-
ever the technologies applied in the AL-41
engine may be certainly used for the de-
velopment of a new engine, which has not
acquire any name so far.
The Sukhoi PAK FA will be equipped with
active phased array radar developed by
V. Tikhomirov Scientific Research Institute
of Instrument Design in Zhukovsky. The ac-
tive phased array radar is expected to be-
come the core of the multifunctional inte-
grated avionic system. In addition to the ra-
dar the multifunctional integrated avionic
system includes electronic warfare sys-
tem, identification friend-or-foe (IFF) sys-
tem, and suspended millimetre-wave radio
detector.
The second PAK FA fifth generation pro-
totype (T-50) will join the flight test pro-
gramme at the beginning of this year. This
was declared by the president of the Unit-
ed Aircraft Corporation Alexey Fyodorov
in December 2010. According to Alexey
Fyodorov, this new aircraft is not an equiv-
alent of the developed prototype, but
“rather a supplement to the performance
of the first fighter’s prototype”.
In July 2010, the first deputy defence
minister of the Russian Federation Vladi-
mir Popovkin said that the new Russian fifth
generation fighter would be purchased to-
gether with the weapons and ground sup-
port equipment. He did not mention the ex-
act amount of funds to be allocated by
the Ministry of Defence of the Russian Fed-
eration for acquisition of the T-50, but he
noted that the Air Force needed at least
50–100 aircrafts of this type.
During the next two years Sukhoi is plan-
ning to complete testing of the PAK-FA air-
frame and in 2013 the Ministry of Defence
The second PAK FA fifth generation prototype
(T-50) will join the flight test programme at the
beginning of this year
Summing-up
14
of the Russian Federation will conclude
a contract with Sukhoi Company for deliv-
ery of ten aircrafts for testing their weap-
ons. The first stage of trials is to be com-
pleted by the end of 2013. According to
the preliminary data, the Ministry of De-
fence of the Russian Federation will pur-
chase a number of the Sukhoi PAK-FA fight-
ers in 2016.
Tu-204SM: Deep ModernizationEleven months later, on 29 December
2010, Aviastar SP (Ulyanovsk) witnessed
the first flight of the Tu-204SM prototype.
This new aircraft is a deeply modernized
version of the Tu-204-100 developed by
Tupolev Design Bureau in the Soviet times.
According to the developers, the Tu-204
has competitive performance, and there-
fore it can be compared with major foreign
competitors (the Tu-204 is considered to
be an equivalent to the Boeing 757 manu-
factured from 1982 till 2005). The cost-ef-
fectiveness analysis of medium-range jet
airlines, conducted by Tupolev, justified
the feasibility of modernizing the Tu-204 to
increase its competitiveness in the respec-
tive market.
This modernization resulted in de-
velopment of the Tu-204SM airlin-
er. The PS-90A2 engine was selected as
the power plant. PS-90A2 is a unified, tur-
bofan, two-shaft engine with core and
secondary flows provided with a reverser
in the secondary flow and sound-attenuat-
ing system.
The engine was designed by Aviadviga-
tel JSC (located in the city of Perm) in coop-
eration with the US Pratt & Whitney Com-
pany. The PS-90A2 engine was certified
on 25 December 2009 (the related deci-
sion was made at the meeting of the Pre-
sidium of the Aviation Register of Interstate
Aviation Committee in Moscow).
As reported in Aviadvigatel official
press release, PS-90A2 was developed to
meet all international requirements, name-
ly AP-33 (airworthiness) and AP-34 (envi-
ronmental protection). In addition, this new
engine developed by Perm Design Bureau
will significantly reduce the life-cycle cost
(by 35–37%) and increase the reliabili-
ty of the product compared to the base-
line PS-90A engine. Unlike the basic ver-
sion, the PS-90A2 engine is equipped with
high-pressure turbine with single-crystal
rotor blades made of ZHS-36MONO al-
loy, and new automatic control system.
The developers applied sound-absorbing
structures of the second generation, new
digital electronic engine controller, and
implemented the advanced design and
technological solutions that ensure break
localization of the damaged rotor blades.
The document emphasized that certifica-
tion of the PS-90A2 engine went hand
in hand with its commercial production by
Perm Motor Plant.
In addition, the Tu-204SM will be pro-
vided with a new auxiliary power unit
(APU) TA-18-200 with a 90 kW genera-
tor instead of TA-12-60. Apart from that
it has efficient fuel consumption, great-
er altitude performance, and lower life cy-
cle costs. Initially, the TA-18-200 auxilia-
ry power unit with a 60 kW generator was
designed for the AN-124 and AN-70 air-
crafts. In August 2010, the deputy director
general and chief designer of Aerosila Re-
search and Production Enterprise Leonid
Plakhov said that flight testing of the new
APU should be completed in the second or
third quarter of 2011. Another important
advantage of the modernized Tu-204SM
Ph
oto
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Nik
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Tu-204SM
Summing-up
15A I R F L E E T · 1 · 2 0 1 1 ( 8 6 )
is crew reduction. The crew number will be
reduced from three to two people, name-
ly the aircraft commander and co-pilot ex-
cluding flight engineer. The flight-naviga-
tion system will be replaced with a new
one developed by Aviapribor Company.
It will allow landing as per IIIA category.
In addition, the Tu-204SM is to be provid-
ed with new communication system, and
digital air conditioning system. At the same
time, the plane continues to hold the same
position which lies between the Boeing
737/Airbus A320 families and twin-isle
Boeing 767/Airbus A330.
The completion of certification and first
deliveries of the new airliner are scheduled
for the end of this year.
Red Wings Airlines will be the first cus-
tomer to purchase 44 aircrafts of Tu-
204SM type from Russia’s largest aircraft
lessor, Ilyushin Finance (IFC). The contract
concluded between IFC and Red Wings is
estimated at 1.5 billion dollars.
The aircraft assembly will continue till
2015–2020. After 2015, the Tu-204SM
production capacities will be refocused
on the production of promising Irkut MS-21
jet airliner. According to the developers,
the MS-21 will be by 30% cheaper than
its counterparts, by 20–25% more effi-
cient in terms of fuel consumption and by
15–20% cheaper in terms of usage and
maintenance. Apart from that it will have
1020 more seats in the passenger com-
partment and the fuselage will be by 10–
20 cm larger in diameter. Irkut Corpora-
tion president Oleg Demchenko said, “The
MS-21 will become the world leader
МS-21
The president of Irkut Corporation Oleg Demchenko: “The MS-21 will become
the world leader in terms of application of composite materials among the nar-
row-body long-range aircrafts”
Summing-up
16
in terms of application of composite mate-
rials among the narrow-body long-range
aircrafts”.
The timeline for MS-21 development pro-
gramme was specified last year. The first
operating model of the Russian-made
PD-14 engine, which is intended for this
particular jet along with the American
R1000G, will appear in 2012. The engine
will be certified two years later accord-
ing to Aviadvigatel chief designer Alexan-
der Inozemtsev. According to the president
of Aerokompozit JSC (subsidiary company
of the United Aircraft Corporation) Anato-
ly Gaydansky, the first wing for MS-21 will
be ready by 2013. The jet itself will per-
form its first flight in 2014 and will be intro-
duced into the market in 2016.
As far as today goes, some foreign cus-
tomers show an interest in procurement
of the Irkut MS-21 jet airliner. For instance,
Malaysia's Crecom Burj Bhd (investment
holding) signed an agreement with Rus-
sian Irkut Corporation for the procurement
of 50 MS-21.
Yak-130: Batch SuppliesAt the end of 2010, the deputy chief
of Russia’s Air Force, lieutenant general
Igor Sadofyev officially announced that
the Air Force would start batch supplies
of the Yakovlev Yak-130 jet trainers. At
the same time they will be supplied to Al-
geria. The Yak-130 jet trainer is intended
for training of cadets at the flying school,
training of pilots at the combat training
centres for specific type of combat air-
craft in order to extend the operational ser-
vice life of combat aircraft. Apart from that,
the trainees are taught such skills as tak-
ing-off, landing, piloting, navigating, per-
forming sophisticated manoeuvres, acquir-
ing the special skills to operate an aircraft
at the limiting flight operation modes or
in case of various failures of the system or
pilot’s errors, performing close combat for-
mation flight operations during the daytime
and in clear weather conditions, learn-
ing weapon systems and its fundamentals
when being used to engage ground and
Yak-130
SSJ-100 & SaM-146
Summing-up
17A I R F L E E T · 1 · 2 0 1 1 ( 8 6 )
air targets, and training offensive and de-
fensive manoeuvres. By the way, the air-
craft’s manoeuvring performance simulates
the flights of the fourth and fifth generation
combat aircrafts. The integrated control
system with the reprogramming function al-
lows the pilot to be taught for any aircraft,
i.e. Su-30, MiG-29, F-16, F-15, Rafale, Ty-
phoon, F-22, and F-35.
The new Yak-130 has a takeoff weight
of 9 tons, fuel capacity of 1.6 tons, and
operating ceiling of 12,000 metres. It at-
tains a top speed of a thousand miles per
hour. The aerodynamic design enables
the controlled flight at an attack angle
of up to 35 degrees.
It can be also used as a light strike fight-
er. The Yakovlev Yak-130 is equipped with
six struts and can carry all kinds of modern
air weapons. The cockpit and power plant
are provided with light armour protection.
Engines: SaM-146 Certification and Launching of Gas Generator for PD-14
On 13 August 2010, the Interstate
Aviation Committee issued Certificate
No. 315-AMD for the SaM-146 power
plant developed by Saturn Research and
Production Association (Russia) and Snec-
ma S.A. (France). The SaM-146 is an inte-
grated power plant which consists of en-
gine, engine nacelle and reversing thrust
device. The SaM146 engines are installed
on the Sukhoi Superjet-100 produced by
Sukhoi Civil Aircrafts (Russia) in cooper-
ation with Alenia Aeronautica (Italy) sup-
ported by Boeing (US).
“The SaM-146 has all necessary ad-
vantages to approach the world mar-
ket in the face of fierce competition when
the customer demands low cost, on-call
mission high reliability, high level of main-
tainability and compliance with the up-to-
date environmental requirements,” the de-
velopers note.
The batch supplies of power plant in-
tended for the Sukhoi Superjet-100 began
in late August last year.
The certification testing of PD-14 engine
is still to take place. Meanwhile, Aviadvi-
gatel launched the experimental gas gen-
erator for PD-14 on 26 November 2010.
As noted in the press release, its launching
was successful.
One might say that the advent of a new
unified gas generator has broken new
ground in Russian civil aircraft- and en-
gine-building industry. Aviadvigatel di-
rector general Alexander Inozemtsev em-
phasized that such gas generator had no
equivalents in the world as of today. It is
known that many countries are implement-
ing research and development works to
design the advanced engines. These works
are being at different stages today, though
all information regarding the market play-
ers is tracked.
According to the current business
plan, engine-demonstrator PD-14 based
on a new gas generator is to be construct-
ed in April 2012.
“Our analysis shows that the engine will
be competitive in the thrust range from 7 to
20 tons. If it is less than 7 tons, the engine is
considered too large and its performance
will not be competitive, and if it is over 20
tons, the gas generator will be overboosted
and it hardly be possible to ensure high en-
gine life,” Mr. Inozemtsev said.
The new engine is developed with ap-
plication of the advanced technologies.
As such, it will be provided with light-
weight fan hollow blades despite the fact
that the conventional blades are not used
in 2-metre engine in diameter due to their
heavy weight. Ufa plant will become
the fourth largest centre which applies this
kind of blades after Rolls-Royce, General
Electric, and Pratt & Whitney.
The latest technologies are also used
in production of low-pressure turbine (high-
tensile alloys based on intermetallic titani-
um compound allow obtaining the lowest
possible weight).
The engine structures as well as nacelles
should be made of glass and carbon fibre
reinforced plastics (the share of composite
materials amounts to about 65%).
According to experts, if all parameters
and characteristics are achieved, this engine
will be competitive in the next 20–25 years.
Integration of UAC and Antonov ASTC: Breaking the Ice
It is worthy to note another event. It is not
associated with the production and mar-
keting of new products, but it is of crucial
importance for the whole aviation indus-
try of Russia. On 27 October 2010, Unit-
ed Aircraft Corporation JSC (UAC, Russia)
Antonov Aeronautical Scientist/Technical
Complex (Antonov ASTC, Ukraine) signed
an agreement on establishment of joint
venture UAC — Civil Aircraft Ltd. Manag-
ing Company. This agreement was signed
in the presence of Russia’s prime minister
Vladimir Putin and Ukraine’s prime minister
Mykola Azarov making it a high-status SaM-146
Summing-up
18
agreement. In addition, the document con-
cerning the rights of participants was ini-
tialed by UAC president Alexey Fyodor-
ov and chairman of the Board of Antonov
ASTC Dmitry Kiva.
Establishment of the joint venture is
the first step towards integration. “It will take
one or two years until Antonov ASTC per-
forms an independent evaluation,” UAC
president Alexey Fyodorov comments. After-
wards, the parties will be offered various in-
tegration options and, in particular, the op-
portunity to define the amount of shares to
start an integration process. Mr. Fyodorov
clarified that each of the parties would have
the opportunity to abandon the offer and
put forward its options for discussion.
The joint venture, therefore, will be
aimed at coordination of interaction be-
tween two aircraft building companies. Af-
ter completion of all the necessary prelim-
inary unification processes, the joint ven-
ture will be liquidated and the Ukrainian
party will be able to participate in de-
velopment of the Russian aircraft proj-
ects, such as MS-21 or Sukhoi Super Jet-
NG (130). The UAC sources say that
Ukraine has always taken the strongest po-
sitions in the field of construction of com-
posite wings and other parts where such
advanced materials are used. Therefore,
the Ukrainian developers are sure to take
a significant place in this project.
Meanwhile, UAC president Alexey Fy-
odorov outlined four tasks to be solved by
the joint venture:
1) Coordination of sales and promotion
of jointly developed products (the Antonov
An-148 family).
2) Unification of conditions on delivery
of component parts (in terms of price) to
aircraft-building factories in Kiev and Vo-
ronezh.
3) Establishment of spare parts depot
for operators (Alexey Fyodorov added
here that the United Aircraft Corporation
could establish these warehouses by direct
procurements. However, the replacement
of parts and assemblies at the aircrafts is
usually accompanied by a broad range
of questions to the developers of aircraft.
Therefore, the participation of the Ukraini-
an party in this project is a must).
4) Preparation for integration and mutu-
al assistance regarding this issue. For ex-
ample, the Russian party could share its ex-
perience in evaluation and corporatization
of the state enterprises with Ukraine.
According to Mr. Fyodorov, Antonov
ASTC integration into UAC will bring
a much-needed technical and technologi-
cal revolution in the Ukrainian aviation in-
dustry.
It should be mentioned that in December
2009 Russia began commercial operation
of the new short-range jet airliner Antonov
An-148-100, developed by the Antonov
Aeronautical Scientific/Technical Complex
and assembled in Russia. This is the on-
ly aircraft which was jointly developed
and commercially produced by Russia and
Ukraine for the last 20 years. The devel-
opment of this aircraft involved more than
200 enterprises, 70% of which are locat-
ed in Russia, 25% in Ukraine, and 5% over-
seas. Its final assembly was implemented
by VASO JSC (Voronezh Aircraft-Building
Joint Stock Company). The AN-148 was
developed on the principle risk-sharing
partnership. The total investment volume
exceeded 400 million dollars.
In February 2010, the first three
An-148-100 airliners were handed over
to Rossiya, the launch customer for the air-
craft, which leased them according to fi-
nancial leasing agreement with Ilyushin Fi-
nance Co. (IFC). VASO is going to produce
9 more jets of this type by the end of this
year. In future it will produce 36 aircrafts
per year. In general, the demand for this
aircraft on domestic and foreign markets is
estimated at 500 aircrafts.
Mikhail Nayden
An-148-100 is the only aircraft which was jointly
developed and commercially produced by Russia
and Ukraine for the last 20 years
Producing of the An-148-100 aircraft in the assembly shop of the Voronezh Aircraft-Building Joint Stock Company
Aircraft
19A I R F L E E T · 1 · 2 0 1 1 ( 8 6 )
Engines
20
The Quality and reliability of produc-
tion, which is produced by Enterprise, con-
firmed by its successful exploitation in more
than 120 world countries.
Due to objective estimation the aircraft
industry of Ukraine is among the first ten
world countries if taking into consideration
its research-and-production potential and
airplanes produced by Antonov — SE as
well as engines produced by Motor Sich
JSC and Ivchenko-Progress — SE are its
visiting card at all aerospace saloons.
Indian Republic with its one of the most
intensively developing economy
in the world is for Ukraine а leading part-
ner in the counties of the Asian-Pacific re-
gion. Ukraine is а foreign trade partner
of India in CIS and two-sided turnover be-
tween our countries has а steady growth
trend.
А considerable part of turnover make up
aerotechnics deliveries and rendering ser-
vices to ensure its operation.
The corporation between Ukraine and
India started in far 1961 and is successfully
developing at present time.
In 1984 more than one hundred military-
transport airplanes An-32 were supplied
to Indian Republic, which were designed
in Ukraine in accordance with technical
requirements specified by Ministry of De-
fense in India.
High aircraft performance characteris-
tics and reliability guaranteed by airplanes
An-32 and their engines AI-20 during ex-
ploitation in extreme conditions of moun-
tainous regions and hot climate promoted
Ministry of Defense in India taking the de-
cision about this airplane modernization
with the purpose of its further exploitation.
THE MOTOR SICH:DEVELOPMENT, PRODUCTION AND SERVICES
The Motor Sich JSC in Zaporozhye — is one of the biggest Enterprises which realizes the full cycle of modern air engines creation from marketing research, development and production to maintenance while operation and repair. During the years of its activity the Enterprise won respect and authority among Customers and successfully cooperates with leading firms of the former Soviet Republics and foreign countries.
“RADIONIX” (MICROWAVE SYSTEMS DESIGN COMPANY) — CRISIS SOLUTIONS TO UPGRADE FIGHTERS’ AVIONICS
Due to the current economic situation caused by the global financial crisis, most countries have significantly adjusted their programmes for the Air Forces development in the direction of increasing the amount of work on upgrading of existing aviation equipment in military service and waiving the purchasing of new models, because of the high costs for their development and production.
UU52155A(B,G), UU52172A(B),
UU52158
UM45210, UM45212
UM45211, UM45213
Director of Radionics Ltd. Stanislav Zavyalov
Avionics
25A I R F L E E T · 1 · 2 0 1 1 ( 8 6 )
the result the significant technical charac-
teristics improvement has been achieved.
Application of microwave modules, de-
veloped by LLC “Radionix” can consider-
ably improve the quality characteristics
of the MiG -29, Su-27 and Su-30MKK
fighters weapon control systems radars.
One of the most important and diffi-
cult task is to implement a fundamentally
new operational modes for radars, such
as ground mapping by the lateral search
mode with the antenna aperture synthe-
sis algorithm application , multi-position
operational modes, modes of long-dis-
tance detection that can provide a multi-
functionality for the fighters under mod-
ernization.
In order to implement the ground (sea)
target search radar modes the following
units developed by “Radionix” company
should be installed:
– N019-09R — multi-channel microwave
receiver;
– N001-22R — multifunctional frequency
synthesizer (BZG);
– BTSO-R — digital signal processor unit
which includes:
the module of standard radar modes
(MSRR), the module for assessment of air
situation (ITI) and the module for radar
antenna aperture synthesizing (MTSRSA).
Installation of new microwave receivers
and applying the optimized algorithms for
digital Doppler filtering of BTSO-R unit al-
lows to increase significantly the detection
range of aerial targets (up to 30...35%
of the existing system range), and al-
so provides wideband signals implemen-
tation by generated microwave signals
phase modulation to realize the ground
targets search modes.
In contrast to the well-known concept
of the bypass channel, realized by “Rus-
sian Avionics” company, all the process-
ing of analog signal, including linear am-
plification and quaternary processing, is
performed within a universal receiver
module which is included in N019-09R
receiving unit.
Installing a new 3-channel microwave
radar receiver N019-09R with the two
separated channels at the intermediate
frequencies of Fpr1=28MHz and
Fpr2=84MHz (narrowband and
broadband channels respectively )
allows to realize two different modes
of radar signals processing The mode
of narrowband Doppler filtering is used
to detect targets in a free space while
the broadband mode involves radar
working with high resolution to detect
small, stationary and low speed targets
against the backdrop of ground or sea
surface.
N001-22R-multifunctional frequency
synthesizer (BZG) is a complex, multi-
functional product designed to generate
a full range of HF, microwave signals with
the desired characteristics in accordance
with the information being sent from
the onboard computer.
A new concept of frequency
synthesis, applied in the development
of the multifunctional frequency synthesizer
(BZG), provides a low frequency noise and
phase noise characteristics, the possibility
of simple programming adaptation
TECHNICAL SPECIFICATIONS OF N001-22R UNIT
Frequency range Х band
Frequency channels number 52
microwave signals output power, mW 20
synchronization signals power, mW 20
carrier isolation (between the pulses), dB 60
power density of the stray radiation 10–7 mW/sm2
set up time, min 3
Avionics
26
to the national frequency spectrum
requirements, as well as to the radio-link
types to control air-to-air guided weapons.
The separate modules and subsystems
of BZG unit have a high degree
of unification with the regular devices,
which provides an opportunity to
repair the old units by using the newly
developed modules.
BTSO-R unit for digital processing
of radar signals equipped with
the module of standard radar modes
(MSRR) implements the narrowband
Doppler filtering optimized algorithms,
which allows to significantly improve
the selection of signals reflected
from moving targets on the backdrop
of ground noise in the air-to-air radar
modes, detection and close-in action
when working with high and medium
pulse repetition frequency.
The air surveillance module (MDO)
is an optional one, which implements
the algorithm
of the Doppler
signal processing
with longer period
for coherent
accumulation. It
became possible
due to the increase
in parameters
of long-term
frequency stability
for N001-22R unit
(BZG)
MTSRSA module
is designed
to implement
the ground targets
search modes for
the ground (sea)
surface, and implements the algorithms
for straight forward and lateral antenna
aperture synthesizing and Doppler beam
sharpening.
Thus the installation of a new BTSO-R
unit into airborne radar system will make
possible to:
– significantly improve the detection
characteristics;
– increase ECM immunity of airborne
radar;
– improve reliability and maintainability
of the system without any significant
changes in the radar maintenance
schedule.
Technical solutions that were found and
implemented by the company specialists
in the process of creating the microwave
modules of “coherent chain”, as well
as the development of upgraded units
for the N001 and NO19 radars, have
brought the company to the level
of system developers. Currently,
the results obtained during the works
on modernization of airborne radar
systems for jet fighters are used to design
the microwave assembly for weather and
TECHNICAL SPECIFICATIONS OF N019-09R UNIT
frequency band Х band
noise figure ,dB 3,5
P-1 input signal level, dBm 35
input VSWR 1,5
bandwidth on fпч2=28 MHz at level –3 dB ,MHz 5
bandwidth on fпч2=84 MHz at level –3 dB,MHz 30
Avionics
27A I R F L E E T · 1 · 2 0 1 1 ( 8 6 )
navigation radar called “Esmeralda”,
which is currently being developed by
the company.
Apart from a standard set of weather
and navigation modes this radar will have
the modes for detection of wind shear,
and turbulence, for scanning the ground
surface with synthesizing of aperture (SA)
and Doppler beam narrowing (DOL).
In future, this system will provide
a platform for testing the design solutions
required for creation of multifunctional
airborne radar systems. It is assumed that
the expansion of the radar functionality
will be achieved through improvements
in software and optimization of algorithms
for digital processing of information
from the weapon control system.
The application of a programmable
signal processor (PSP) has allowed to
use one (or group) of the processors for
various tasks, including communications
and navigation, which significantly
extends the radar capabilities. First
of all the growth of PSP productivity
with fast Fourier transform algorithm
application would affect the ability
of radar to distinguish the signals from
the target in a wider spectrum in real
time. The practical outcome of such
feature could be automatic (without
request) detected target nationality
and type recognition. Information
signs of recognition in this case will
be the fluctuations of the reflected
signal in a broad band (wide range).
Measuring the spectrum and amplitude
characteristics of fluctuations would allow
compare the parameters of the reflected
signal with the available database and,
thus, it would be possible to identify with
high probability the type of the target.
The expanding of radar capabilities
in air-to-ground mode, such as higher
resolution in mapping mode and
recognition of moving targets (ground
ones with a relatively low speed) may
be considered as a second application
of the improvements in question.
Another direction of the company
activities is developing a aircraft
perspective radio-electronic protection
system, called “Omut” (Whirlpool), which
is intended to replace the outdated
L006LM and L203B(I) systems.
This radio-electronic protection
system includes radio-electronic
surveillance system, with programmed
database of threats and their priority,
and an electronic countermeasures
system, thus provides high probability
of suppression of the enemy target
acquisition radar systems.
“Omut” (Whirlpool) radio-electronic
protection complex provides real time
detection and identification
of enemy radars, evaluates the level
of threat and selects the optimal set
of electronic countermeasures for radars
of anti-aircraft missile systems, fighters, as
well as of missiles with active and semi-
active homing devices.
Since the moment of its creation,
the company embarked on the creation
of competitive complex set of products
which are not inferior in their technical
characteristics the best world standards.
High scientific and technical potential,
the availability of material and test
facilities and technological capabilities
allow the company to implement a full
cycle of development, testing and serial
production of the most sophisticated
products of modern avionics.
TECHNICAL SPECIFICATIONS OF EW COMPLEX
Multiple radar suppression capability, radars 20
frequency band Х, Ka
output power at P-1, W, not less than 80
operating temperature range, °С –60…+80
weight, kg, not more than 45
number of preprogrammed ECM systems, not less than 200
Navigation
28
The company has a rich history start-
ing from 1918, when the Soviet govern-
ment issued a decree on establishing
a plant for manufacturing telegraph devic-
es. The Compas MDB created a first ev-
er powerful (for that time) transmit-receive
airborne radio station of up-to 5,000 km
operational range, which provided for
the Moscow — North Pole -Vancouver
record flight by Valery Chkalov’s crew
aboard ANT-25 on July 18 to 20, 1937.
In 1948, the Compas Design Bureau
was detached to become an independent
structure dealing with the development
of navigation and communication equip-
ment. As an item of radio navigation equip-
ment products, the Bureau developed a ra-
dio direction finder called ‘Golden Arrow’,
which was helpful in assisting the crew
in adverse weather conditions to find
the direction of required maneuver, so as
to reach the airfield and carry out landing.
The modern radio direction finder is an au-
tomatic portable device of relatively low
energy consumption, featuring the wide
use of digital signal processing techniques
and almost not requiring field maintenance.
When developing hardware, the staff
of Compas MDB relies on the most up-to-
date technologies, for the company mainly
specializes in delivering products for avia-
tion and rocket-and-space facilities.
In the 1970s the digital signal processing
techniques were largely used in the compa-
ny’s innovative developments. Those tech-
niques helped reduce the hardware weight,
size and power consumption and create:
– For the Air Force — A-723 radio navi-
gation receiver-indicator which operat-
ed with Alpha and Omega ground ra-
dio navigation phase systems of glob-
al coverage, as well as with pulse phase
systems, including Chaika and Loran-S;
– For the Navy — Mars-75 multi-frequen-
cy phase radio navigation system des-
ignated for supporting ship naviga-
tion, executing hydrographic and op-
erational works, as well as servicing
flights of aircraft at speeds not exceed-
ing 1,000 km/h.
The GLONASS, GPS and GALILEO
global satellite navigation systems are
subject to active radio interference, due
to the low strength of signals emitted by
space vehicles. On the horizon of earth
surface, they are 40 decibels weaker than
natural radio noises. The signals of such
a low level are effectively suppressed by
radio electronic warfare facilities, where
a 1-watt strong noise interference transmit-
ter would disturb the operation capacity
of satellite radio navigation systems’ hard-
ware within a radius of 32 km.
In order to level down the influence
of natural and artificial interference, we
have created satellite navigation equip-
ment which features a higher level of inter-
ference immunity.
Taking into account the imperatives
of our era, the hardware is being worked
out for aviation and guided weapon sys-
tems, and the research and development
works are going on to enable the accom-
plishment of combat tasks in the environ-
ment polluted by enemy radio electron-
ic countermeasures. To jam the new equip-
ment, an enemy would need jamming
stations of such a high capacity that will
make them easily discoverable and vulner-
able for destruction by appropriate means.
The enhancement of digital components
of navigation hardware allows minimiz-
ing the share of analogous devices. When
the hardware is mounted to different ve-
hicles, their capabilities have to be mod-
ified in conformity with specific tasks and
parameters of a vehicle. In terms of anal-
ogous equipment, it would mean serious
problems of adaptation, to the extent of re-
starting the development cycle. For the dig-
ital equipment, in most cases it is enough to
update the software, and so to obtain new
qualities of a product.
In order to enable the efficient execu-
tion of all the above mentioned proce-
dures before mounting a product in vehi-
cles, the satellite navigation system simula-
tor, modeling GLONASS/GPS/GALILEO,
has been developed. The development
of the satellite navigation system simulator
turned to be a complex task, with the use
of most modern techniques of digital sig-
nal processing. The functions fulfilled by
COMPAS: PRIORITIES OF SPACE NAVIGATIONThe Compas Moscow Design Bureau (Open Joint Stock Company) is an up-to-date research & production enterprise majoring in development and manufacture of consumer professional equipment for high-precision navigation operated by signals of GPS/GLONASS/GALILEO satellite navigation systems.
Mikhail Pestrakov,
Commercial Director,
Director of special projects
and at large, Compas MDB
Navigation
29A I R F L E E T · 1 · 2 0 1 1 ( 8 6 )
the simulator in the industrial and research
field are very broad. Those are, for ex-
ample, definition of technical solutions
at the stage of consumer navigation equip-
ment (CNE) development, adjustment and
settings, the assessment of work quality
during the production process at the man-
ufacturing plant, issues of incoming inspec-
tion and periodical checks during the CNE
life cycle, training technical staff in oper-
ating it, conducting a complex of scientif-
ic and laboratorial researches, as well as
in-line simulation with the goal of defin-
ing a place for mounting the CNE in the ve-
hicle, including highly dynamic systems,
working out scenarios of CNE-mounting
vehicle movement in the prescribed trajec-
tories with the consideration of complex
impacts of atmosphere, ionosphere (ra-
dio wave propagation conditions), and
use of a priori and a posteriori information
on the location of satellites in the space
grouping at a certain time period.
The A-737 basic product (airborne
GLONASS/GPS satellite radio navigation
systems receiver-indicator) was developed
in the 1980s, primarily for the military avi-
ation. Today, the products of this series are
mounted almost virtually in all the aircraft.
The purpose of our equipment is to define
the position vector of an aircraft, i.e. three
location constituents, three velocity constit-
uents, and to receive the exact time read-
ing, since the use of satellite navigation en-
ables to tie to the unified time system.
The A-737 product provided a basis for
several modifications, which support addi-
tional functions and enhance the product
capabilities in precision of position finding.
For instance, the A-737I product brings
together the capabilities of satellite nav-
igation and navigation based on terres-
trial pulse and phase radio systems. Such
a technological solution is due to the fact
that the interference resistance of receiv-
er-indicators of satellite navigation sys-
tems is not very high, and as for the signals
of pulse-phase systems, it is much more dif-
ficult to jam them. In combat environment
the use of two-system equipment would
largely enhance the capabilities of com-
bat operations when enemy uses electronic
countermeasures.
The next modification is A-737D, which
supports differential operation mode.
The results of navigational measurements
defined by the satellite navigation systems’
receiver-indicators contain errors. One
of them is related to the inaccuracy of da-
ta about the space vehicle movement pa-
rameters (ephemeral information). Since
the distance is measured from the vehicle
to space vehicles, and such distances are
used for calculating the vehicle’s position,
the precision of the whole system depends
on the accuracy of definition of space ve-
hicle position. The second error is relat-
ed to the fact that the signal emitted by
the space vehicle goes through the iono-
sphere, troposphere, where it is refracted
and twisted, and, therefore, the measured
distance to the space vehicle proves to be
inaccurate. To get rid of these errors, espe-
cially when high precision in position find-
ing is required, for example, in the guided
weapons operational employment, the dif-
ferential error-corrections are used. These
corrections are formed by the terrestri-
al segment of the system, enabling to in-
crease the precision to single meters, which
is essential for destroying pin-point targets.
In the same time we were given a task
of creating equipment for the guided high-
precision weapons. This task primarily had
to be solved for the correction enabled
aviation weapons. We created the satel-
lite navigation hardware specially for that
purpose. During the testing of the product
using the differential mode, we succeed-
ed in achieving the circular probable er-
ror calculable in single meters. The hard-
ware belonging to this class is mounted to
the correction-enabled aviation weapons.
GNSS IM-2 signal simulator
Navigation
30
The Compas MDB currently deals with is-
sues of development and production of ra-
dio navigation systems in various lines:
– Small size automatic direction finders
for all aircraft of military and civil avia-
tion (ARK-32, ARK-35, ARK-40);
– A series of A-737 aviation receiver-
indicators for the high precision po-
sition finding of different vehicles by
GLONASS/GPS satellite navigation
system signals (GALILEO in future) and
terrestrial radio navigation pulse-phase
and phase systems;
– products for ground-supported trajec-
tory measurements of boosters, upper-
stage rockets and space vehicles (dis-
posable load);
– map-enabled navigation pads, provid-
ing the planning and execution of flights
on air-routes and any prescribed routes
out of the air-routes, as well as the air-
craft special employment tasks, oper-
ates with signals of GLONASS/GPS
satellite navigation systems;
– equipment of navigational medium for-
mation: local system of differential er-
ror-corrections, retransmitter of satellite
signals;
– instrument landing system for aircraft
(helicopters) onto air capable ships and
unequipped loading sites;
– portable receiver-indicator for the per-
sonal use of signals of GLONASS/GPS
satellite navigation systems (GALILEO
in future);
– a number of aerials of different desti-
nation;
– dedicated jam resistant consumer nav-
igation equipment operating with
GLONASS/GPS satellite navigation
systems for aircraft of all kinds and pur-
poses;
– monitoring, security and centralized
control systems for rail transport;
– dedicated navigation equipment for
the control systems of automobile trans-
port.
One of the main lines of activities
in the Compas MDB is the development
of navigation complex for helicopter ship
landing.
We were a success in creating such
a system. Its main difference from the same
standard systems is that it operates
in the mode of relative navigation. That
is, when the system is activated, the air-
craft ‘ties’ itself to the center of landing
pad of the ship. And wherever the ship was
going, and whatever was the helicopter
movement, its position is always defined
relating to the center of the helipad.
We expect that the successful test results
would open up new alternatives of using
the system in civil industries. Today there
is a topical issue of providing the helicop-
ter communication with shelf-based drilling
plates, ensuring flights of deck-based avi-
ation of the icebreaking fleet, scientific re-
search ships and other sea vessels.
In 1996, the company created navi-
gation means providing ground-support-
ed trajectory measurements for products
of rocket-and-space industry: boosters,
rockets, upper-stage rockets and pay-
load. The equipment functions efficient-
ly and reliably in rocket-and-space vehi-
cles and is demanded by rocket manufac-
turers. One of reasons of the demand for
such an equipment is the need for high-
precision control of trajectory parameters.
There is no secret that the rocket when de-
viating from the trajectory beyond the ad-
missible limits, has to be destroyed. Since
the creation and maintenance of terrestrial
complexes of ground-supported trajecto-
ry measurements is a very expensive activi-
ty, the use of satellite navigation equipment
facilitates the task significantly.
As our company gained a certain expe-
rience, it succeeded in creating the equip-
ment of smaller size, less weight, with bet-
ter characteristics. Compared to the first
product installed to the booster which was
4.5 kg heavy, the equipment now weighs
1.5 kg, and there is a trend of further re-
duction of weight and size characteris-
tics. There are examples of building these
products into the telemetric complexes
of minor space vehicles. About ten of such
minor space vehicles have been launched,
and the first ‘Zeya’ vehicle equipped with
our receiver-indicator was set into orbit
in 2007. By that we reconfirmed the pos-
sibility of using satellite navigation hard-
ware at very high vehicle movement
speeds.
The obtained high results in the use
of satellite navigation in the precision
weapons, namely aviation weapons, pri-
marily, the correction-enabled aviation
bombs, lead to the fire accuracy enhance-
ment, in the context of cannon artillery.
A new trend in the context of diversifica-
tion of company’s product mix is the devel-
opment of search and rescue system with
the use of GLONASS/GPS equipment, as
well as the “Gonets” satellite communica-
tion segment. The above-mentioned sys-
tem will help significantly reduce time for
search and rescue of the those in distress
as well as boost the search operations ef-
ficiency. It is notable that the existing sys-
tems do not allow appropriately perform-
ing the set tasks.
The search and rescue operation be-
gins with the reception of distress message,
which can appear as a signal of distress
received or vehicle’s fallout from the ra-
dar’s screen or missing scheduled radio
contact. After establishing the fact of dis-
tress, it is necessary to find the location
of those suffering distress with the sufficient
accuracy for rescue groups to contact di-
rectly those in distress.
For the sake of accomplishment
of search and rescue tasks, fast and effec-
tive coordination of actions of search and
rescue forces, the two-way information ex-
change between them and those in distress,
thus decreasing the detection time and re-
ducing the duration of search and rescue
operations. The missing possibility of such
an information exchange should be con-
sidered as one of the main drawbacks
of the existing systems.
In order to remove the mentioned short-
comings of the system, the space system
of search and rescue is now under devel-
Automatic
radio compass ARC-35-1
Navigation
31A I R F L E E T · 1 · 2 0 1 1 ( 8 6 )
opment. It envisages the two-way data ex-
change between the distressed and rescue
services. The systems is comprised of three
segments:
– The space segment is represent-
ed by navigation space vehicles
of GLONASS/GPS satellite navigation
systems, as well as satellites of global
communication systems;
– The user segment includes emergency
radio buoys designed both for being
mounted to mobile vehicles (ARB) and
for the personal use (ARB-N). There is
also a tendency for using radio bea-
cons in certain fixed installations, with
the purpose of sending warning sig-
nals in critical conditions (for example,
in case of ecological or other emer-
gencies);
– The control system consists of the Unified
Coordination Center (UCC), which col-
lects information about arisen emergen-
cies, and a network of regional com-
mand and control posts. The UCC func-
tions include the monitoring of the whole
system.
The emergency radio buoys define
their positions through the GLONASS/
GPS navigation signals. When using both
the two global satellite positioning sys-
tems, the probability of exact position find-
ing for ARB increases a lot. The emergen-
cy message made in the ARB is delivered
to the UCC through the radio channel
of global satellite communication sys-
tems. The emergency messages contains
the ARB’s identifier, the exact position
of the ARB at the time of emergency signal
or message sending, the accident time and
accident characteristic. The UCC makes
the response (acknowledgment) to the re-
ceived emergency message, which goes
to the distressed ARB through the channel
of global communication systems.
This system does not require the devel-
opment of communication system, since
there is a possibility of using the formerly
developed and currently operating glob-
al satellite communication systems, which
allow not only organizing the two-way
communication channel, but the all-weath-
er and round-the-clock radio communi-
cation. The main advantage is that there
are no interruptions in communication ses-
sions. Therefore, the information about
the distressed will be delivered to the UCC
in the minimum time.
The use of the two-way data exchange
will enable the fast and effective coordina-
tion of actions of search and rescue teams
and those in distress, and at that the dis-
tressed will be informed that their distress
signal has been discovered and the search
and rescue services have initiated the res-
cue operation.
The company’s future plans are relat-
ed with the improvement of radio naviga-
tion equipment, increase of interference re-
sistance, integration with other navigation
systems, precise control of air-dropped
loads, logistics navigation systems and
complexes of transport communications,
navigation products of general usage.
Mikhail Pestrakov,
Commercial Director,
Director of special projects
and at large, Compas MDB
32
View of analyst
INDIA AND RUSSIA:NEW JOINT PROJECTS IN THE FIELD
OF MILITARY AIRCRAFT TECHNOLOGIES
33
View of analyst
A I R F L E E T · 1 · 2 0 1 1 ( 8 6 )
The related future programs may be di-
vided into two types, namely the agreed
projects on direct procurement of the Rus-
sian aircrafts (or on their joint development
and production) and tenders which invite
the largest global manufacturers of aircraft
technology including Russia.
Today India is the only country Russia is
going to cooperate with regarding the ten-
year military-technical cooperation (from
2011 till 2020).
Under this cooperation program two na-
tions are collaborating on a number of proj-
ects in the field of aircraft, helicopter, ma-
rine, and land technologies. However, most
large-scale programs are being implement-
ed in the field of aircraft technologies.
The tender for the supply of medium-
lift multi-role fighters for Indian Air Force,
which cost is estimated at $10-12 billion, is
crucially important to determine the trend
in military-technical cooperation between
India and Russia.
Tender for Supply of 126 Medium-Lift Multi-Role Fighters
The contract on procurement of 126 me-
dium multi-role combat aircrafts (MMRCA)
is expected to be signed by mid 2011.
In December 2010, the Indian Air Force
completed the assessment of requests for
proposal, and forwarded tender documen-
tation to the Ministry of Defence of India
for approval.
The aircrafts submitted to tender were
tested in India in 2009–2010 under
the corresponding operational environ-
ment. Their flight testing was attended
by the specialists of Bangalore Aircraft
and Systems Testing Establishment (ASTE)
in Bangalore, Hindustan Aeronautics Ltd
(HAL), Defence Research and Develop-
ment Organization (DRDO), India’s Minis-
try of Defence and Air Force.
The aircrafts were tested under humid
weather conditions at the airfield in Ban-
galore, hot desert conditions in Jaisalmer,
and cold mountain condition in Leh.
The Indian Air Force expects that
the contract will be signed by July 2011.
Yet, six other aircrafts lay claim to
the victory in tender as well. These are
the Boeing F/A-18E/F Super Hornet,
the Lockheed Martin F-16IN, the Mikoyan
MiG-35, the Saab JAS 39 Gripen (Swe-
den), the Dassault Aviacion Rafale (France),
and the Eurofighter EF-2000 Typhoon.
Russia and India are going to implement a number of scale projects in the Field of Military Aircraft Technologies. A wide representation of Russia at the AERO INDIA-2011 Air Show testifies to the fact that the Indian weapon market is of crucial importance for Moscow. The exhibition will coincide with another round of negotiations between Russia and India regarding a number of projects to be implemented in the field of aircraft technology in the near future.
CURRENTLY RUSSIA PARTICIPATES IN FOUR TENDERS OFFERED BY INDIAN AIR FORCE AND NAVY FOR THE SUPPLY OF MILITARY
AND DEFENCE AIRCRAFTS
MiG-35
34
View of analyst
According to the tender requirements,
the winner will supply 18 aircrafts to the In-
dian Air Force in 2012. Other 108 air-
crafts will be manufactured at the facilities
of Hindustan Aeronautics Ltd (HAL) which
shall commission the first aircraft in 54
months after signing the contract. It is ex-
pected that all aircrafts will be delivered to
the customer by 2020.
New MMRCA fighters will remain in ser-
vice for 40 years. The future contractor will
have to reinvest 50% of the contract value
into the Indian defence industry.
According to the request for proposal
announced by the Indian Ministry of De-
fence, the number of purchased aircrafts
may increase by 50%, that is to say 189
aircrafts.
The Russian Mikoyan MiG-35 fighter is
in the running to win the tender.
Tender for Supply of Carrier-Based Fighters for Indian Navy Aircraft Carrier
In November 2009, the Indian Na-
vy announced the tender for procurement
of the carrier-based fighters for future air-
craft carriers. The Navy has forward-
ed the requests for information to Boe-
ing, Dassault Aviacion, and MiG compa-
nies. It is expected that India will purchase
16 carrier-based fighters and will proba-
bly increase the order up to 40 aircrafts
to be based on three Indian aircraft carri-
ers. The first aircraft carrier was laid at Co-
chin Shipyard in February 2009. Accord-
ing to the schedule, it will be handed over
to the Indian Navy in 2015.
Tender for Procurement of Aerial Refuelling Military Aircrafts
In September 2010, the Indian Minis-
try of Defence announced a new tender
on procurement of aerial refuelling mili-
tary aircrafts after cancellation of the re-
sults of the previous tender nine months
ago.
The Government of India decided to
resume tender for procurement of six
aerial refuelling military aircrafts af-
ter the Ministry of Finance refused to ap-
prove a $1.5 billion contract on acquisi-
tion of the Airbus A330 aerial tankers with
EADS in September 2009.
The updated requests for proposals
(RFP) have been forwarded to the com-
panies in the USA, Europe, and Russia.
The procurement contract cost is estimated
at $2 billion.
As compared to the previous ten-
der, the requirements have remained un-
changed except for an issue regarding
statement of costs for the whole service life
of the aircrafts.
It is expected that apart from Airbus Mil-
itary and Rosoboronexport the new tender
participant list will include Boeing as well.
It will take at least 2 years for the Minis-
try of Defence of India to evaluate the RFPs
and determine a winner.
Earlier in 2003–2004, the Indian Air
Force acquired six Ilyushin Il-78 aerial re-
fuelling aircrafts which can carry 75 tons
of fuel and refuel the Dassault Mirage
2000, Jaguar and Su-30MKI aircrafts be-
ing in service of the Indian Air Force.
Tender for Procurement of Medium Range Maritime Reconnaissance Aircrafts
Program 3The third program is modernization of fif-
ty Sukhoi Su-30MKI fighters delivered to
India in previous years.
In summer 2010, the Indian Air Force de-
clared its intention to upgrade fifty Suk-
hoi Su-30MKI fighters delivered to India
in previous years in the coming three to
four years.
With the assistance of Russia, India will
install new avionics, upgrade the aircraft
design and enlarge the range of aircraft
weapons.
It is expected that Russia will upgrade
the first five fighters of the Indian Air Force.
The rest 45 aircrafts are to be modernized
in India.
Program 4The forth promising project is the pro-
gram on acquisition of two additional Phal-
con AEW&C aircrafts.
As soon as India receives the last
AEW&C aircraft in 2011, it is going to or-
der two more Phalcon aircrafts with air-
borne early warning and control system
(AEW&C) based on the Ilyushin IL-76.
The Indian Air Force has already initiat-
ed the process of acquiring two addition-
al AEW&C aircrafts. They will join the air-
craft fleet consisting of three Phalcon sys-
tems acquired according to the trilateral
$1.1 billion contract concluded between
India, Russia and Israel in March 2004.
Pursuant to the contract, India had an op-
tion to acquire other three to five aircrafts
of this type.
The aircrafts are equipped with four en-
gines of PS-90A-76 type, active phased
array radars, Belgium 20-inch LCD in-
dicators, electronic countermeasure sys-
tems manufactured by Israeli Company Al-
bit Systems, and other systems developed
in India and France. The aircrew consists
of eighteen people. The EL/M-2075 air-
borne radar can detect the targets at a dis-
tance of 400 km and track nearly 60 tar-
gets simultaneously in 360-degree range.
Two such aircrafts have been already in-
ducted into the Indian Air Force. The first one
was delivered on 25 May 2009. The sec-
ond Ilyushin Il-76 with AEW&C system was
supplied to India on 25 March 2010. De-
livery of the third aircraft to India was ini-
tially scheduled for 2010. However, based
on the experience gained during opera-
tion of the first two aircrafts, the Defence Re-
search and Development Organization (DR-
DO) requested Israel Aerospace Industries
(IAI) to provide the last aircraft with addition-
al equipment. The platform was supplied to
Israel by the Russian manufacturers in Octo-
ber 2010. According to the preliminary da-
ta, the last aircraft will be delivered to the In-
dian Air Force in mid 2011. All aircrafts will
be stationed at the air base in Agra, where
the Il-76 military transport aircrafts and Il-78
aerial refuelling military aircrafts are kept.
The $1.1 billion contract on procurement
of three Phalcon EL/M-2075 radars de-
veloped by Elta Company and installation
on the Russian IL-76 aircrafts was signed by
the Ministry of Defence of India in March
2004.
MAJOR CONTRACTS AND AGREEMENTS CONCLUDED BETWEEN INDIA AND RUSSIA IN 2010
Falcon
Fifth Generation Fighter Development Program
During the official visit of the Russian
President Dmitry Medvedev to India on 21
December 2010, the nations signed
a deal for design and development of ad-
vanced fifth generation fighter aircraft
(FGFA).
The estimated cost of the contract
on draft design of the Indian FGFA ver-
sion is $ 295 million. These works are to be
completed within 18 months.
In general, the development and test-
ing of these prototypes require from
eight to ten years. The estimated cost
38
View of analyst
of the development program is $12 billion.
Russia and India will have equal shares
in this program.
The first time Russia offered India to devel-
op a new fighter was eight years ago, but
the parties failed to agree on business in-
terests in the project. In October 2007, two
nations signed a preliminary intergovern-
mental agreement on FGFA joint develop-
ment on the basis of the Russian Sukhoi PAK
FA (promising aircraft of frontline aviation).
This is the first project in the modern his-
tory of Russia when it develops the state-of-
the-art weapon systems together with other
country. Therefore, the allocation of duties
in the project was an issue of crucial impor-
tance and required a thorough elaboration.
As a result, it took three years to final-
ize the general contract and nondisclosure
agreement after long-term intergovernmen-
tal negotiations. In March 2010, the par-
ties signed a preliminary technical agree-
ment which outlines the participation inter-
ests as well.
The Indian Air Force plans to acquire
from 250 to 300 fifth generation fighters.
According to the HAL data, the share
of the Indian defence industry in the joint
project will be nearly 30%. In particular,
the Indian company will develop software
for onboard computer, navigation systems,
multifunction cockpit displays, components
made of composite materials and self-pro-
tection system. Additionally, India will re-
design the single-seat PAK FA into dual-
seat fighter since according to the strategy,
adopted by the Indian Air Force, the air-
crafts are intended for various missions.
In future, the Indian fifth generation fighter
will replace the three types of combat air-
crafts being in service today.
The single-seat fighters will be serial-
ly produced in 2017–2018. The dual-
seat aircrafts will be inducted into service
in 2019–2020. It is planned to produce
around 200 dual-seat aircrafts for the Indi-
an Air Force.
Joint-Venture Agreement on Co-Development of Multi-Role Transport Aircraft
On 9 September in New Deli Russia and
India entered into an agreement on founda-
tion of a Joint Venture Company (JVC) to de-
sign and develop a new generation medi-
um-lift jet multi-role transport aircraft (MTA).
The shareholders of a new company
are India’s Hindustan Aeronautics Limited
(50%), and Russia’s United Aircraft Corpo-
ration (25%) and Rosoboronexport State
Corporation (25%). The JVC headquarters
will be located at Bangalore. The aircraft
will be assembled both in Russia and India.
The formal intergovernmental agreement
on implementation of the MTA project was
signed by Russia and India on 12 Novem-
ber 2007 when the prime minister of India
Manmohan Singh visited Moscow. The es-
timated cost of the project is $600 million.
The project will be bankrolled equally by
Russia and India. Each party will allocate
Prime Minister Dr. Manmohan Singh and president of Russian Federation
Dmitry Medvedev during the official visit of Mr. Medvedev to India
The official signing of the contract between Rosoboronexport and HAL
for creating a draft technical design of India’s version of the FGFA
39
View of analyst
A I R F L E E T · 1 · 2 0 1 1 ( 8 6 )
$300.35 million towards the MTA devel-
opment. This amount includes the expendi-
tures prior to proceeding to the MTA full-
rate production.
The new MTA is designed to replace
the aging fleet of Soviet Antonov An-12,
An-26 and An-32 transport aircrafts. As
of now Indian Air Force has around one
hundred of Antonov An-32 transports.
The twin-jet powered MTA will be 33 m
long with wingspan of around 30 m. Max-
imum payload capacity of the MTA will
be 18 to 20 tons. The MTA will feature
a takeoff weight of 65 tons, cruise speed
of 800 km/h, and flight range of 2 500
to 2 700 km. The service ceiling will be
12 km. The aircraft will have a glass cock-
pit, modern avionics, fly-by-wire system,
and full authority digital engine control
(FADEC). The engine type is still not speci-
fied and will be chosen by tender.
The Russian and Indian MTA models will
be developed on maximally unified tech-
nologic basis. The airframe will be assem-
bled on a 50-50 basis. Individual subsys-
tems will be designed with allowance for
potential export to third countries.
The MTA can be operated at day and
night in any world region, under any cli-
matic and weather conditions. The MTA
will function like a military aircraft capa-
ble of short landings and takeoffs on poor-
ly maintained runways, including those
in high-altitude air facilities in the Himalayas.
India and Russia plan to produce 205
aircraft. Off take has been put at 40 air-
craft for the Indian Air Force to transport
troops, materiel and cargoes. India will
have an option to acquire additional 100
MTAs. The Russian Air Force confirmed
the intention to acquire 100 MTAs.
Essential competitive advantage
of the MTA is its comparatively low cost.
The aircraft may compete against An-
tonov An-12, An-26 and An-32 as well as
against C-130J Super Hercules.
Contract for Delivery of 29 Mikoyan Mikoyan MiG-29K Carrier-Based Fighter Jets
Russia and India signed the con-
tract on delivery of 29 Mikoyan Mikoy-
an MiG-29K fighters on 12 March 2010
when the prime minister of the Russian Fed-
eration Vladimir Putin visited India. The first
delivery is scheduled for 2012. The con-
tract is worth a total of $1.5 billion. Six-
teen out of twenty-nine Mikoyan Mikoyan
MiG-29K fighters will be based on the Vi-
kramaditya aircraft carrier.
An important part of the Indian Navy
Mikoyan MiG-29K/KUB fighter acquisi-
tion program is the creation of the shore-
based test facility for maintenance of air-
craft and training of pilots which was
constructed in April 2009 at INS Han-
sa, Goa.
The fighters will be operated from
the INS Hansa (Goa) till commissioning
of the Vikramaditya aircraft carrier.
MAJOR AIR FORCE PROGRAMS UNDER IMPLEMENTATION
Sixteen Mikoyan MiG-29K/KUB Fighter Supply Program
The first four Mikoyan MiG-29K/KUB
carrier-based fighters were formally in-
ducted into the Navy by Defence Minis-
ter AK Antony at a ceremony which took
place on 19 February 2010 at INS Hansa.
The ceremony was also attended by Min-
ister of Industry and Trade of the Russian
Federation V.Khristenko.
The Indian Ministry of Defence signed
a contract stipulating the supply of sixteen
Mikoyan MiG-29K fighters, including four
dual-seat Mikoyan MiG-29K/KUB train-
ers, to India in January 2004. The contract
is part of a $1.5 billion deal to refit and de-
liver the Admiral Gorshkov aircraft carrier.
The first four Mikoyan MiG-29K fighters,
in a knocked down condition, were deliv-
ered to India in December 2009. In Sep-
tember 2009 these Mikoyan MiG-29Ks
passed their test flights from the deck
of the Admiral Kuznetsov heavy aircraft
carrying cruiser in the Barents Sea. These
trials were the part of the pilot training and
test program.
The remainder twelve Mikoyan
MiG-29Ks are awaited to be supplied
in four-unit batches in 2010–2011. Before
delivery of the Vikramaditya aircraft car-
rier which was rescheduled for late 2012,
the fighters will be based on INS Hansa
equipped with a simulator for deck land-
ing and takeoff training. The Mikoyan
MiG-29Ks will be a part of the 303 squad-
ron, nicknamed Black Panther.
MTA
40
View of analyst
The ship-based Mikoyan MiG-29K is
the “4++” generation aircraft which is ca-
pable of day/night, all-weather, year-
round operation in any climate. The aircraft
will be able to control the air, to provide
air defence of the ship and to engage sur-
face and ground targets. Despite of formal
resemblance the new aircraft weighs by
30% more as against the Indian Air Force
Mikoyan MiG-29B. The Mikoyan MiG-
29K fighter will be equipped with missiles
capable of engaging non-LOS targets,
guided anti-ship missiles, unguided missiles,
aerial bombs and 30-mm caliber gun.
The Mikoyan MiG-29K fighter features
improved performances and reliability.
The aircraft avionics is based on the open
architecture. The general-purpose multi-
mode onboard Zhuk-ME radar is capable
of tracking up to ten targets and simultane-
ous firing against four targets.
The aircraft features an improved air-
frame made of composite materials, low
radar signature, high payload, high-ca-
pacity fuel tanks and air-to-air refuelling
(AAR) system, modified wing bending, and
quad-redundant full authority digital en-
gine control.
To land on the aircraft carrier’s deck,
the carrier-based Mikoyan MiG-29K fight-
ers are equipped with retaining gear and
reinforced landing gear, flexible wings and
special coat preventing sea water corrosion.
Indian Navy Ilyushin Il-38 Improvement Program
In mid-February 2010 Russia complet-
ed refit of five Indian Navy Ilyushin Il-38
ASW patrol aircrafts. The last (fifth) refitted
Ilyushin Il-38S/D landed in the naval air
base in Goa.
Five Indian Navy Ilyushin Il-38 aircrafts
were refitted in Russia under a $200 mil-
lion contract dated 2002. The major im-
provement was the installation of Morskoy
Zmey search and target system.
The improvement program made it pos-
sible to extend the Indian Navy Ilyushin
Il-38 aircraft service life for 15 years and
to release the Indian Navy from urgency
to procure state-of-the-art aircrafts for re-
connaissance and antisubmarine warfare.
The refitted Ilyushin Il-38S/D aircrafts will
be further used by Indian Naval Air Com-
mand, communication intelligence and
control systems group, and reconnaissance
air force.
Tupolev Tu-142ME Repair and Refit Program
In August 2010, on completion
of the scheduled repair and refit by
TAVIA JSC, the long-range ASW Tupolev
Tu-142ME aircraft was handed over to
the Indian Navy. The overhaul and re-
fit of one more Indian Navy Tupolev
Tu-142ME aircraft was to be completed by
late 2010.
In 1986 Russia supplied 8 ASW Tupolev
Tu-142MK aircrafts designated as Tupolev
Tu-142ME.
The improved Tupolev Tu-142ME may be
used for day/night all-weather surveillance
and protection of national waters, elec-
tronic reconnaissance, searching, track-
ing and firing of advanced low-noise sub-
marines running up-top or snorkeling at full
or slow speed or lying still on sea ground.
The Tupolev Tu-142ME aircraft equipped
with missiles is capable of attacking sur-
face ships, ground and coastal targets. BrahMos missile (air version)
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Maximum flight range of the Tupolev
Tu-142ME aircraft is 12000 km, maxi-
mum flying speed at weight of 138 tons
at 7000 m altitude is 855 km/h, cruise
speed is 735 km/h, inflight endurance
is 9 hours. Maximum payload capacity
of the aircraft carrying six BrahMos cruise
missiles is 9.6 tons (the BrahMos missile
erection option is proposed by Indian Na-
vy). Standard payload with eight X-35
ASMs is 4.4 tons. The standard ASW mod-
el aircraft accommodates up to 140 radio
sonobuoys.
Indian Air Force Mikoyan MiG-29 Fleet Improvement Program
In February 2009 Mikoyan MiG РСК
initiated the project for improvement
of the Indian Air Force Mikoyan MiG-29
fleet. The total number of Indian Air Force
Mikoyan MiG-29 aircrafts to be refitted
is 62. These aircrafts were supplied to In-
dia in three batches at different time and
their technical condition differs a lot. Rus-
sia will bring all the aircrafts into equal op-
erating state.
Mikoyan MiG РСК plans to refit the first
six aircrafts, i.e. four single-seat and two
dual-seat aircrafts, at its facilities. The refit
is to be completed in 2011.
The remainder aircrafts will be refitted
in India at the 11th aircraft repair plant.
Mikoyan MiG РСК will forward all the re-
quired technical documents to the plant.
Some avionics for improvement will be de-
livered from Russia, and some assemblies
will be supplied by Hindustan Aeronautics
Limited (HAL).
The Indian government and Mikoyan
MiG РСК entered into a contract for re-
fit of sixty two Mikoyan MiG-29 fighters
on 7 March 2008. The contract is worth
a total of $964 million.
Sukhoi Su-30MKI Fighter Licensed Production Program
In the last few years Hindustan Aero-
nautics Limited (HAL) reduced the timeline
of Sukhoi Su-30MKI fighter licensed pro-
duction. In 2009 HAL delivered 23 fight-
er to the Indian Air Force. In 2010 HAL
planned to supply 28 Sukhoi Su-30MKI
fighters.
By summer 2010 the Indian Air Force ac-
quired 74 Sukhoi Su-30MKI fighters from
HAL.
Today the Indian Air Force has five Suk-
hoi Su-30MKI squadrons, three of them be-
ing based in Buna and two — in Bareili. In-
dia plans to deploy other two squadrons
in Punjab and in the northeast of the country.
The importance of Sukhoi Su-30MKI
fighters for India is justified by the fact that
HAL was advised to complete the licensed
production of one hundred forty Sukhoi
Su-30MKI fighters by 2015 at all hazards
(i.e. ahead of schedule).
An initial $1462 billion contract for de-
livery of forty Sukhoi Su-30MKI fighters for
the Indian Air Force was signed on 30 No-
vember 1996. Pursuant to this contract
eight Sukhoi Su-30K version aircrafts
were manufactured and handed over to
the customer in 1997. The other contract-
ed aircrafts were manufactured and deliv-
ered in Sukhoi Su-30MKI version. In 1996
the Indian Ministry of Defence placed
an order for additional ten Sukhoi Su-30K
fighters which were purchased for $277
million. In 2000 India signed a $3.5 billion
agreement for licensed production of 140
Sukhoi Su-30MKI fighters at HAL facilities
using vehicle sets delivered by Russia.
In 2007 India contracted addition-
al 40 Sukhoi Su-30MKI fighters at a cost
of $1.6 billion for the Indian Air Force.
Besides, India effected a trade-in deal
for 18 Sukhoi Su-30MKI fighters instead
of earlier delivered Sukhoi Su-30K fighters.
AL-55I Engine Licensed Production Program
The HAL Company plans to launch a full-
rate production of AL-55I engines under
Russian license in the coming two-three
years.
The present-day problem is to se-
lect a site in Koraputa (Orissa) to deploy
the engine production facilities in two to
three years. The AL-55I engine was de-
signed by Saturn Research and Devel-
opment Company for India special ben-
efit. The engine was certified after suc-
cessful endurance testing in Russia and is
to be mounted on the advanced Indian
HJT-36 УТС. Six engines have been de-
livered, and other ten have been ordered
and are awaited. The Indian Air Force
plans to acquire total 85 HJT-36 УТС.
Summary Pursuant to the statement by the Defence
Minister AK Antony, the Indian Air Force
will consist of 42 squadrons by the end
of the 13th schedule period (by 2022),
which is more than it was previously ap-
proved by the Indian government.
According to the Defence Minister’s
comments on the question from depu-
ties of the Upper Chamber of Indian Par-
liament, in 2007–2022 by the end of 11th,
12th and 13th schedule periods the Indi-
an Air Force will have 35.5, 35 and 42
squadrons respectively.
AK Antony stated that at the beginning
of the 11th schedule period the Indian Air
Su-30
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Force consisted of 32 squadrons only. To-
day the Indian government authorized de-
ployment of 39.5 fighter squadrons.
The Indian Air Force will be in crash air
alert as soon as Sukhoi Su-30MKI fighters,
Jaguar, medium multi-role combat aircraft
(MMRCA), fifth generation fighter aircraft
(FGFA) and light combat aircraft (LCA) are
inducted into service.
Over recent years India headed the list
of worldwide leaders in the total weapon
imports through implementation of military
refit programs. India holds the top position
as per the scheduled total imports of prod-
ucts for military purposes for the coming
years.
Russia’s peers in Indian weapon market
are Israel, United Kingdom, USA, France,
Ukraine, Italy, Sweden and some other
countries.
Russia is able to reserve at least a half
of the Indian weapon market.
Once the quantity of the Russian-man-
ufactured end products for military pur-
poses to be delivered is reduced, the mil-
itary technical cooperation will be fo-
cused on transfer of licenses for production
of Russian products for military purposes
in India, for joint and special-order R&D,
and for foundation of joint venture compa-
nies to develop, produce, refit and repair
the products for military purposes.
The major projects associated with
transfer of license for production of Rus-
sian products for military purposes in-
clude the licensed production of multipur-
pose Sukhoi Su-30MKI fighters, T-90S
MBT, and AL-55I aircraft engines for Indi-
an HJT-36 УТС as well as HJT-39 and se-
ries 3 RD-33 for Mikoyan MiG-29 fighters.
Due to large-scale transfer of technologies,
India and Russia signed an agreement for
mutual protection of intellectual proper-
ty rights.
One of the most successful projects is
the co-production of BrahMos cruise mis-
siles by BrahMos Aerospace JVC.
Russia participates in several tenders to
deliver helicopters for the Indian Air Force.
This year Russia will lease out the Type
971 Schuka-B nuclear-powered submarine
to the Indian Navy for a term of ten years.
The rental cost is $650 million.
All contract issues pertaining to refit
of the Admiral Gorshkov aircraft carrier in-
to Vikramaditya aircraft carrier have been
finalized with India. The contracts for sup-
ply of 45 Mikoyan MiG-29K/KUB fight-
ers have been signed. Now India and
Russia negotiate the acquisition of other
42 Sukhoi Su-30MKI fighters and imple-
ment the program of refitting 62 MiG-29
fighters belonging to the Indian Air Force.
The joint program for delivery of Phalcon
AEW&C aircrafts to the Indian Air Force is
under implementation.
Russia and India implement several
large-scale projects for Air Force, Navy
and Armed Force.
In late December 2010 on the eve of vis-
it to India the Russian president Dmit-
ry Medvedev stated that “India like Rus-
sia conducts the external policy and main-
tains communication with other countries
in the field of military technical coopera-
tion. It is reasonable that western manu-
facturers of weapon and other products
for military purposes are much interested
in cooperation with India”.
“We do not hesitate and are ready to
compete. The most important thins is to be
honest and to play according to the rules”,
Dmitry Medvedev emphasized.
Igor Ilyin
Is India Going to Achieve a Record?Russia’s Centre for Analysis of World Arms Trade (CAWAT) forecasts
that arms import contracts India will conclude in 2011 will have the largest worth in its history.
India has been one of the three world’s largest arms importers in the last four years.
According to CAWAT’s preliminary information, India ranked third in the world by the worth of arms import contracts it concluded ($3.756 bil-lion) in 2010 giving way only to the UAE ($6.71 billion) and Taiwan ($4.131 billion).
There was a slight decrease in this figure in 2010 as India postponed taking final decisions on some projects including those carried out with Russia to 2011. It is expected to choose the winners in a number of major tenders in 2011. If India keeps to the schedule, the worth of contracts it will make this year will reach the largest figure in all its history.
For comparison: In 2007, the total cost of India’s arms import contracts equaled $4.783 billion, in 2008 — $4.256 billion and in 2009 — $6.933 billion. In the last four years (2007–2010), India concluded $19.729 billion worth of arms imports contracts ranking the second in the world behind only the UAE with $21.508 billion.
As for the actual volume of arms imports, India was the third with the amount of $4.556 billion in 2010 with only Australia and the US ahead ($6.134 billion and $4.886, respectively). In the above-mentioned four-year period, India imported $12.815 billion worth of armaments thus ranking the second after the US with its $17.122 billion.
In 2007, the actual volume of India’s arms imports reached $2.5 billion, in 2008 — $2.5 billion and in 2009 — 3.255 billion. Considering the figure for 2010, we can say that India has been significantly increasing its arms imports under priorly-concluded contracts year by year.
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Russia has two things that sell well in the global marketplace: natural resources (oil, gas, timber,
metals) and weapons. While the former represents a much larger volume in terms of volumes and
amounts, the export of weapons carries strategic importance. It helps the Kremlin build good relations
with governments of other countries, and brings these nations into the Russian sphere of commercial
relations, cooperation and other key areas. Another important aspect is that such activity helps
domestic manufacturers stay in the business and develop critical technologies.