wuzetian
New Member
- Joined
- May 15, 2013
- Messages
- 194
- Likes
- 166
Stop this LSA trolling ... [emoji35] [emoji35] [emoji35] [emoji35] [emoji35] . There is no aircraft called LSA .
AMCA - Advanced Medium Combat Aircraft (HAL)
- Thread starter screwterrorists
- Start date
smestarz
New Member
- Joined
- Nov 3, 2012
- Messages
- 1,929
- Likes
- 1,056
Su-30 MKI will be in a way replaced by FGFA/PAKFA (apparently)
MiG-29, Mirage 2000 and Jaguar will be replaced by AMCA
MiG-21, MiG-27 replaced by Tejas
But for Tejas MK II I want it to be light weight fighter, but instead of single engine, I prefer two smaller engines with less thrust per engine but higher combined thrust. This helps the place to survive better (in case of engine failure)
MiG-29, Mirage 2000 and Jaguar will be replaced by AMCA
MiG-21, MiG-27 replaced by Tejas
But for Tejas MK II I want it to be light weight fighter, but instead of single engine, I prefer two smaller engines with less thrust per engine but higher combined thrust. This helps the place to survive better (in case of engine failure)
smestarz
New Member
- Joined
- Nov 3, 2012
- Messages
- 1,929
- Likes
- 1,056
Vstol is guy from IDF, who has apparently designed a light stealth aircraft (paper plane)
HariPrasad-1
New Member
- Joined
- Jan 7, 2016
- Messages
- 9,645
- Likes
- 21,138
Professor Pradyuman das is well known figure in Aerodynamics and plane design And Vstol Jokey is a guy who has designed his own stealth plane which he claims that will be as stealthy as F22 and defeat anything in sky except F22.
wuzetian
New Member
- Joined
- May 15, 2013
- Messages
- 194
- Likes
- 166
Kindly provide details of this professor, his qualifications and his papers published
- Joined
- Mar 19, 2016
- Messages
- 5,724
- Likes
- 11,638
Developing a 4th gen plane altogether today does not makes much sense
I want tejas mk2 to be what gripen e is,higher thrust engine,2 more hard points,m ore payload(preferably 5-6 tonnes).
Su-30's have a long way to go
They are gonna serve till 2050-55 with proper upgrades.
When we will talking about retirement of flankers(su-30's),we should develop a 6th gen jet fighter..........
Air force should have 900-1100 jets to counter 2 front threat because current sanctioned strength is not enough to counter threats.....
HariPrasad-1
New Member
- Joined
- Jan 7, 2016
- Messages
- 9,645
- Likes
- 21,138
search yourself........................
singh100ful
New Member
- Joined
- Nov 7, 2016
- Messages
- 102
- Likes
- 74
Cannot find anything on internet.
Will be glad if you help out.
smestarz
New Member
- Joined
- Nov 3, 2012
- Messages
- 1,929
- Likes
- 1,056
There are few things that you fail to understand,,, COST
Cost of buying, using and maintaining,
This cost will be huge for 5th Gen plane considering all the "goodies" where as will be much cheaper for 4th Gen plane. So, my direction for Tejas Mk II will be twin engined plane, and that too 4.5++ Gen, The important thing is to have the plane to be very capable, and have good value for money in terms of buying, using and maintaining.
With Twin engines, it will be having better thrust than Gripen, or any other single engine plane.
Su-30 MKI as per me have 15-20 years more to go
What will be your direction of 6th Gen plane? I am curious to know,,
My direction for a 6th Gen plane will be something smaller (like Me-163 Komet) with say 4-6 missiles, and these peform like swam of bees. Individually they are not strong, but collectively they can defeat anyone simply by overwhelming the target.
The cost of such a plane should be cheaper say 10-15 million per plane, should not be too modern, but have all sort of 4.5th Gen tech, and select few from the swarm have some 5th Gen tech for having the surprises.
And these 5th Gen planes in the swarm should be the one which are the "Directors" of the swarm, identifying and alloting the targets to individual planes
Cost of buying, using and maintaining,
This cost will be huge for 5th Gen plane considering all the "goodies" where as will be much cheaper for 4th Gen plane. So, my direction for Tejas Mk II will be twin engined plane, and that too 4.5++ Gen, The important thing is to have the plane to be very capable, and have good value for money in terms of buying, using and maintaining.
With Twin engines, it will be having better thrust than Gripen, or any other single engine plane.
Su-30 MKI as per me have 15-20 years more to go
What will be your direction of 6th Gen plane? I am curious to know,,
My direction for a 6th Gen plane will be something smaller (like Me-163 Komet) with say 4-6 missiles, and these peform like swam of bees. Individually they are not strong, but collectively they can defeat anyone simply by overwhelming the target.
The cost of such a plane should be cheaper say 10-15 million per plane, should not be too modern, but have all sort of 4.5th Gen tech, and select few from the swarm have some 5th Gen tech for having the surprises.
And these 5th Gen planes in the swarm should be the one which are the "Directors" of the swarm, identifying and alloting the targets to individual planes
lcafanboy
New Member
- Joined
- Mar 24, 2013
- Messages
- 5,875
- Likes
- 37,838
AMCA - The Conqueror in making
1/26/2017
5 Comments
AMCA or the Advanced Medium Combat Aircraft is a fifth-generation fighter aircraft which will be manufactured by HAL. The AMCA programme is envisaged as replacement for a host of aircraft currently operated by the IAF as well as to fill gaps left by retirement of the Dassault Mirage 2000s, SEPECAT Jaguars and Mig-27s.ADA describes the AMCA as a "multirole combat aircraft for air superiority, point air defense, deep penetration/strike, special missions".
Unofficial design work on the AMCA started in 2008 with official work started in 2011 and completed in 2014. In 2008 Indian Navy also showed interest in the naval variant of AMCA. All the design work is completed and ADA is waiting for the approval of Indian government to develop the first prototype.
The broad requirements outlined for the AMCA are to incorporate a high degree of stealth, a high internal and external weapons payload, high internal fuel capacity, and the ability to swing from an air-to-air role to air-to-ground. It is also expected to have the ability to super cruise. This allows the aircraft to travel at supersonic speeds with greater endurance as the afterburners do not have to be used with the additional fuel usage. Even though future air combat has been envisaged as being beyond visual range excluding the likelihood of aerial dogfights as before, the AMCA is expected to sport a thrust vectoring engine. The ADA is designed the AMCA as a platform with high survivability, to meet the challenges of future air defense environments through a combination of moderate stealth, electronic warfare capability, sensors and kinetic performance. The design philosophy seeks to balance aerodynamics and stealth capabilities.
The aircraft will have a weight of 16-18 tons. 16-18 tons with 2-tons of internal weapons and 4-tons of internal fuel. Combat ceiling will be 15-km, max speed of 1.8-Mach at 11-km. The AMCA will be powered by 2 x 90KN engines with vectored nozzles.
Airframe
AMCA will use carbon-fibre composites (C-FC), and titanium alloy steels for construction. The AMCA would employs C-FC materials for up to 80% of its airframe by weight, including in the fuselage (doors and skins), wings (skin, spars and ribs), elevons, tailfin, rudder, air brakes and landing gear doors. Composite materials are used to make an aircraft both lighter and stronger at the same time compared to an all-metal design, and the amca's percentage employment of C-FCs is one of the highest in an aircraft. Apart from making the aircraft much lighter compared to conventional metal airframed aircraft, There are also fewer joints and rivets, which increases the aircraft's reliability and lowers its susceptibility to structural fatigue cracks. The majority of these are bismaleimide (BMI) and composite epoxy material. The aircraft will be the first mass-produced aircraft to include structural nanocomposites, namely carbon nanotube reinforced epoxy. Stressed ducts in s-shape are locked with airframe with the loaded bulkheads which are made of composite materials spanning the aircraft from air intake to engine shafts
Aerodynamics
AMCA is a relaxed static stability design with a shoulder mounted diamond shaped trapezoidal wings, a profile with substantial area-ruling to reduce drag at transonic speeds, and an all-moving Canard-Vertical V-tail with large fuselage mounted Tail-wing. Flight control surfaces include leading and trailing-edge flaps, ailerons, rudders on the canted vertical stabilizers, and all-moving tailplanes; these surfaces also serve as Air brakes.
Trapezoidal wings reduces the air drag at higher mach thus giving the aircraft the ability to supercruise. Also it provide a better handling at subsonic speed than other delta wing aircrafts, which makes it suitable for ground attack roles too.
Relaxed static stability will give increased maneuverability to AMCA. Greater stability leads to lesser control surface authority, therefore a less stable design will have a faster response to control inputs. A less stable aircraft requires smaller control deflections to initiate maneuvering; consequently drag and control surface imposed stresses will be reduced and aircraft responsiveness will be enhanced.
Overall AMCA looks close to F-22 with a faceted shape making up the fuselage. The single-seat cockpit will seat behind a short nose cone assembly with angled, rectangular intakes fitted to either side and aft of the cockpit position. These openings will aspirate the twin turbofan engine arrangement found at the extreme aft section of the aircraft, arranged in a side-by-side formation. The main wingplanes will be set a midships and aft while being completed in a symmetrical trapezoidal form. The horizontal tailplanes will be featured directly aft of the mainplanes. Its weapons bay will be installed at the airframe's center mass, slightly ahead of midships. Probably AMCA will have almost similar aerodynamic and energy – maneuverability performance like F22 raptor. The incorporation 3D thrust vectoring make AMCA extreme maneuverable. AMCA also can with stand departure resistants at a similar level like in F22.
AMCA will use a digital Fly – By – Light system to control the flight. The digital FBL system of the aircraft employs an advance next-generation distributed digital flight control computer (DDFCC) made by Aeronautical Development Establishment (ADE) comprising four computing channels, each with its own independent power supply and all housed in differently placed LRU. The DFCC receives signals from a variety of sensors and pilot control stick inputs, and processes these through the appropriate channels to excite and control the elevons, rudder and leading edge slat hydraulic actuators. DFCC provides Raising the wing flaps and ailerons on one side and lowering them on the other provided roll. The pelikan-tail fins are angled at 27 degrees from the vertical. Pitch is mainly provided by rotating these pelikan-tail fins in opposite directions so their front edges moved together or apart. Yaw is primarily supplied by rotating the tail fins in the same direction. The AMCA is designed for superior high Angle of attack (AoA) performance. Deflecting the wing flaps down and ailerons up on both sides simultaneously provided for Aerodynamic braking
Stealth
The design of the AMCA includes a very small radar cross-section & will also have serpentine like air intakes, internal arsenal as well as the state-of-the-art radomes in order to enhance its stealth feature. The design will also be supplemented through radar-absorbing composites as well as paints.
The front end of AMCA comprising the cockpit and radome as well as the air intakes—seems much closer to the Boeing X-36 unmanned research aircraft. The rest has resemblance to F22 raptor.
AMCA also optimized to reduce acoustic signature as well as reduced visibility to the naked eye.
The design based stealth characteristics of the aircraft will include
the above pictures shows the plan-form alignment of AMCA for stealth .
Front aspect
Engine fan blades are heavily contribute to increase of RCS so masking the engines is a key aspect in stealth. To mask the engines ADA proposed the idea of S Curve/ Serpentine air intake. This is achieved in two ways: with the internal weapons bay and cockpit placed in front of the engines. This creates partial vertical masking. Partial horizontal masking is achieved by offsetting the alignment of air intakes. Theoretically, between the partial vertical and horizontal masking, the engines blades are fully concealed in the front hemisphere. However, since the official renderings of the ADA are not scaled and show an ongoing process, the extent of masking of the engine remains unclear.
The ADA claims the radome of the AMCA will be of 'advanced construction', presumably meaning that it will only allow the operating frequencies of the mated radar to transmit from the dome, while blocking other radars (Frequency selective surface). This is a significant stealth measure since normal radomes are merely shaped for aerodynamic efficiency but freely allow radar waves through. This means adversarial radar waves 'see' past the radome onto a flat heavily radar reflective surface. Wing and Vertical Tail is blended to the fuselage this will give enough stealth to avoid detection through AWACS platforms.
The cockpit & canopy presents a problem similar to the radome. Shaped for vision and aerodynamic efficiency, the jagged edges and facets of the cockpit within reflect radar waves increasing its RCS. Radar waves normally enter the cockpit reflects of objects & possibly return to the radar and even the HMD of pilot itself contributes to RCS. India’s Light Combat Aircraft canopy is coated with a thin film transparent conductor of Indium Tin Oxide. The coating is thin enough that it has no adverse effect on pilot vision and can reflect the radar waves away from the radar antenna. An advanced version of this is also expected in AMCA. AMCA also propose a frameless bubble canopy to increase its stealth profile, but manufacturing of this kind of canopy is really a challenge.
Rear aspect
Perhaps the most significant feature that detracts from stealth in this early design of AMCA is the circular engine exhausts. These are not just radar reflective but also erode stealth in the infra-red and other electro-optical detection arenas. In contrast, square exhausts, as seen on the F-22, reduce infrared signatures by up to 25 percent given the percentage increase in surface area of a square over a circle of the same dimensions. But this approach also reduced the thrust output of F22. AMCA may be come with a 3D thrust vectoring so a square exhaust with a zig-zag nozzle like F22 to reduce radar and IR signature is unlikely. This kind of nozzle is heavy and less maneuverable.
But surely AMCA, s thrust vectoring nozzle will have some design features to reduce infrared emissions to mitigate the threat of infrared surface-to-air or air-to-air missiles but not upto the mark of F22 Raptor. Additional measures to reduce the infrared signature include special paint and active cooling of leading edges to manage the heat buildup from supersonic flight.
1/26/2017
5 Comments
AMCA or the Advanced Medium Combat Aircraft is a fifth-generation fighter aircraft which will be manufactured by HAL. The AMCA programme is envisaged as replacement for a host of aircraft currently operated by the IAF as well as to fill gaps left by retirement of the Dassault Mirage 2000s, SEPECAT Jaguars and Mig-27s.ADA describes the AMCA as a "multirole combat aircraft for air superiority, point air defense, deep penetration/strike, special missions".
Unofficial design work on the AMCA started in 2008 with official work started in 2011 and completed in 2014. In 2008 Indian Navy also showed interest in the naval variant of AMCA. All the design work is completed and ADA is waiting for the approval of Indian government to develop the first prototype.
The broad requirements outlined for the AMCA are to incorporate a high degree of stealth, a high internal and external weapons payload, high internal fuel capacity, and the ability to swing from an air-to-air role to air-to-ground. It is also expected to have the ability to super cruise. This allows the aircraft to travel at supersonic speeds with greater endurance as the afterburners do not have to be used with the additional fuel usage. Even though future air combat has been envisaged as being beyond visual range excluding the likelihood of aerial dogfights as before, the AMCA is expected to sport a thrust vectoring engine. The ADA is designed the AMCA as a platform with high survivability, to meet the challenges of future air defense environments through a combination of moderate stealth, electronic warfare capability, sensors and kinetic performance. The design philosophy seeks to balance aerodynamics and stealth capabilities.
The aircraft will have a weight of 16-18 tons. 16-18 tons with 2-tons of internal weapons and 4-tons of internal fuel. Combat ceiling will be 15-km, max speed of 1.8-Mach at 11-km. The AMCA will be powered by 2 x 90KN engines with vectored nozzles.
Airframe
AMCA will use carbon-fibre composites (C-FC), and titanium alloy steels for construction. The AMCA would employs C-FC materials for up to 80% of its airframe by weight, including in the fuselage (doors and skins), wings (skin, spars and ribs), elevons, tailfin, rudder, air brakes and landing gear doors. Composite materials are used to make an aircraft both lighter and stronger at the same time compared to an all-metal design, and the amca's percentage employment of C-FCs is one of the highest in an aircraft. Apart from making the aircraft much lighter compared to conventional metal airframed aircraft, There are also fewer joints and rivets, which increases the aircraft's reliability and lowers its susceptibility to structural fatigue cracks. The majority of these are bismaleimide (BMI) and composite epoxy material. The aircraft will be the first mass-produced aircraft to include structural nanocomposites, namely carbon nanotube reinforced epoxy. Stressed ducts in s-shape are locked with airframe with the loaded bulkheads which are made of composite materials spanning the aircraft from air intake to engine shafts
Aerodynamics
AMCA is a relaxed static stability design with a shoulder mounted diamond shaped trapezoidal wings, a profile with substantial area-ruling to reduce drag at transonic speeds, and an all-moving Canard-Vertical V-tail with large fuselage mounted Tail-wing. Flight control surfaces include leading and trailing-edge flaps, ailerons, rudders on the canted vertical stabilizers, and all-moving tailplanes; these surfaces also serve as Air brakes.
Trapezoidal wings reduces the air drag at higher mach thus giving the aircraft the ability to supercruise. Also it provide a better handling at subsonic speed than other delta wing aircrafts, which makes it suitable for ground attack roles too.
Relaxed static stability will give increased maneuverability to AMCA. Greater stability leads to lesser control surface authority, therefore a less stable design will have a faster response to control inputs. A less stable aircraft requires smaller control deflections to initiate maneuvering; consequently drag and control surface imposed stresses will be reduced and aircraft responsiveness will be enhanced.
Overall AMCA looks close to F-22 with a faceted shape making up the fuselage. The single-seat cockpit will seat behind a short nose cone assembly with angled, rectangular intakes fitted to either side and aft of the cockpit position. These openings will aspirate the twin turbofan engine arrangement found at the extreme aft section of the aircraft, arranged in a side-by-side formation. The main wingplanes will be set a midships and aft while being completed in a symmetrical trapezoidal form. The horizontal tailplanes will be featured directly aft of the mainplanes. Its weapons bay will be installed at the airframe's center mass, slightly ahead of midships. Probably AMCA will have almost similar aerodynamic and energy – maneuverability performance like F22 raptor. The incorporation 3D thrust vectoring make AMCA extreme maneuverable. AMCA also can with stand departure resistants at a similar level like in F22.
AMCA will use a digital Fly – By – Light system to control the flight. The digital FBL system of the aircraft employs an advance next-generation distributed digital flight control computer (DDFCC) made by Aeronautical Development Establishment (ADE) comprising four computing channels, each with its own independent power supply and all housed in differently placed LRU. The DFCC receives signals from a variety of sensors and pilot control stick inputs, and processes these through the appropriate channels to excite and control the elevons, rudder and leading edge slat hydraulic actuators. DFCC provides Raising the wing flaps and ailerons on one side and lowering them on the other provided roll. The pelikan-tail fins are angled at 27 degrees from the vertical. Pitch is mainly provided by rotating these pelikan-tail fins in opposite directions so their front edges moved together or apart. Yaw is primarily supplied by rotating the tail fins in the same direction. The AMCA is designed for superior high Angle of attack (AoA) performance. Deflecting the wing flaps down and ailerons up on both sides simultaneously provided for Aerodynamic braking
Stealth
The design of the AMCA includes a very small radar cross-section & will also have serpentine like air intakes, internal arsenal as well as the state-of-the-art radomes in order to enhance its stealth feature. The design will also be supplemented through radar-absorbing composites as well as paints.
The front end of AMCA comprising the cockpit and radome as well as the air intakes—seems much closer to the Boeing X-36 unmanned research aircraft. The rest has resemblance to F22 raptor.
AMCA also optimized to reduce acoustic signature as well as reduced visibility to the naked eye.
The design based stealth characteristics of the aircraft will include
- optimized edge matching
- Airframe shaping
- Body confirming antennae
- A low IR signature all the way through nozzle design
- Engine bay cooling as well as work on decreased exhaust temperature.
the above pictures shows the plan-form alignment of AMCA for stealth .
Front aspect
Engine fan blades are heavily contribute to increase of RCS so masking the engines is a key aspect in stealth. To mask the engines ADA proposed the idea of S Curve/ Serpentine air intake. This is achieved in two ways: with the internal weapons bay and cockpit placed in front of the engines. This creates partial vertical masking. Partial horizontal masking is achieved by offsetting the alignment of air intakes. Theoretically, between the partial vertical and horizontal masking, the engines blades are fully concealed in the front hemisphere. However, since the official renderings of the ADA are not scaled and show an ongoing process, the extent of masking of the engine remains unclear.
The ADA claims the radome of the AMCA will be of 'advanced construction', presumably meaning that it will only allow the operating frequencies of the mated radar to transmit from the dome, while blocking other radars (Frequency selective surface). This is a significant stealth measure since normal radomes are merely shaped for aerodynamic efficiency but freely allow radar waves through. This means adversarial radar waves 'see' past the radome onto a flat heavily radar reflective surface. Wing and Vertical Tail is blended to the fuselage this will give enough stealth to avoid detection through AWACS platforms.
The cockpit & canopy presents a problem similar to the radome. Shaped for vision and aerodynamic efficiency, the jagged edges and facets of the cockpit within reflect radar waves increasing its RCS. Radar waves normally enter the cockpit reflects of objects & possibly return to the radar and even the HMD of pilot itself contributes to RCS. India’s Light Combat Aircraft canopy is coated with a thin film transparent conductor of Indium Tin Oxide. The coating is thin enough that it has no adverse effect on pilot vision and can reflect the radar waves away from the radar antenna. An advanced version of this is also expected in AMCA. AMCA also propose a frameless bubble canopy to increase its stealth profile, but manufacturing of this kind of canopy is really a challenge.
Rear aspect
Perhaps the most significant feature that detracts from stealth in this early design of AMCA is the circular engine exhausts. These are not just radar reflective but also erode stealth in the infra-red and other electro-optical detection arenas. In contrast, square exhausts, as seen on the F-22, reduce infrared signatures by up to 25 percent given the percentage increase in surface area of a square over a circle of the same dimensions. But this approach also reduced the thrust output of F22. AMCA may be come with a 3D thrust vectoring so a square exhaust with a zig-zag nozzle like F22 to reduce radar and IR signature is unlikely. This kind of nozzle is heavy and less maneuverable.
But surely AMCA, s thrust vectoring nozzle will have some design features to reduce infrared emissions to mitigate the threat of infrared surface-to-air or air-to-air missiles but not upto the mark of F22 Raptor. Additional measures to reduce the infrared signature include special paint and active cooling of leading edges to manage the heat buildup from supersonic flight.
lcafanboy
New Member
- Joined
- Mar 24, 2013
- Messages
- 5,875
- Likes
- 37,838
If the current graphics translate accurately into the production design of the aircraft, a high level of stealth can be expected from it against radars operating in the L band. X to C band stealth, however, will be heavily dependent of the quality of construction, the shaping of the facets and joints, and of the equipment and weapons bay doors.
Sensors
The Senor suites in AMCA led by the LRDE and BEL which include many private and foreign contributes.
The primary sensor will be gallium Nitride (GaN) based radar. Infrared based systems like IRST, missile warning systems, laser warning system also added internally in the AMCA. The IRST sensors are placed in all sides of the AMCA to provide full angle coverage like in Rafale and F 35. The proposed IRST system is work similar to the F 35’s EOTS who shares the information’s to friendly units like via the satellite and highly secured data links. But the fact remains that only United States and China have developed conformal IR/Synthetic vision Sensors & Tracking system and there will be significant developmental hurdles here.
AMCA also comes with self protection jammer system to jam enemy radar guided missiles from both air and ground. Electronic counter measure systems to confuse the infrared guided missiles (DIRCM) and a radar warning receiver too added to detect enemy radar frequencies.
The Multifunction RF Sensor, which has broad spectrum agility, includes capabilities for electronic countermeasures (ECM), electronic support measures (ESM), communications functions, and possibly even microwave weapon functions. AMCA will be integrated from the cockpit to accompanying UAVs and UCAVs which will include DRDO AURA, DRDO Rustom through encrypted datalink connections
Sensor Fusion
In AMCA all the data collected from the various sensors processes and present to the pilot as a single integrated picture of the battle field and possibly share to other fighters and ground stations automatically (Net centric). This kind of sensor fusion will provide the pilot a stunning situational awareness.
AMCA will have vehicle management (including weapons), data fusion, decision aids, integrated modular avionics, internal carriage of weapons, signature control. The AMCA is likely to have fly - by - light system. It makes AMCA more immune to electronic attacks (EMI – electromagnetic interference, HIRF –High energy radiated fields) and much better transmission speed and processing capabilities. Fly – by – light is also helps to reduce the weight of the aircraft. The higher band width of fly – by – light is very useful in controlling the aircraft at high speeds. Higher bandwidth ensures higher data transfer rate, therefore pilots command passes rapidly from aircraft cockpit to control surfaces which ensures smooth aircraft maneuvering even in high speeds especially AMCA is designed as an aircraft with super cruise capability the advantage of Fly – by – light is enormous and also improves the safety margin of AMCA.
Another major advantage of Fly – By – Light is , AMCA will use composites to make its body , use of composite materials in aircraft structures will decrease the effect of electronic attack of enemies cos composites are less suspected to EMI than metal structures .Consequently, FBW are subjected to greater electrical interference which can degrade performance .But optical pulses transmitted by FBL system are unaffected by the much lower frequency electromagnetic waves that characterize the Electronic attack threat.
AMCA will have another feature called self repair / self protection. Self repair will achieve with the help of self-diagnosing and self-healing systems that distribute the work load to other systems from affected to non-affected systems. Self protection would be provided with the use of nanotechnology to produce advanced composite materials designed to have a higher resistance to damage and therefore reducing the damage surface area. The aircraft uses Self Repairing Flight Control Capability to automatically detect failures or damage in its flight control surfaces, and using the remaining control surfaces, calibrate accordingly to retain controlled flight. The use of adaptive neural networks would be a key feature in self healing and self repairing they can record all the faults occurred and also can learn from the previous faults.
But it is not an easy task to develop this kind of highly advanced capabilities. Sensor fusion is a necessity in 5th generation fighter aircrafts, only time will say how good will be AMCA, s sensor fusion.
Radar
The AMCA will incorporate an Active Electronically Scanned Array (AESA) which, the official illustrations indicate, is also mechanically steerable. This is an advantage as the beam manoeuvrability of an AESA can be stretched to a broader detection area.
The AMCA hosts new generation GaN based AESA for superior detection and performance. Some information’s reported that, state owned LRDE is initiated a project to develop a small size air borne X band GaN based AESA radar for AMCA. LRDE already shows a model of AESA radar in last year’s Aero India exhibition. The use of GaN will give significant benefits of power density, efficiency, and bandwidth to AMCA. Furthermore the use of GaN will solve substantial system-related issues, such as the need for higher operating voltages, more efficient heat removal techniques, and high reliability
The under development Uttam AESA radar intended for Tejas LCA is not good for fifth generation fighters like AMCA. It’s reported earlier that, India and Israel working for a joint project to develop a GaN based AESA for fighter jets. However due to the importance of the program the information’s are highly classified.
Cockpit
One of the most dramatic aspects AMCA will be its cockpit and man-machine interface. AMCA cockpit could have a panoramic active-matrix display of the kind available on American fifth generation aircraft with dimensions of 60 by 24 centimeters designed by DARE and manufactured by Samtel or 44 by 18 centimetres by HALBIT which is a joint-venture between HAL and Elbit Systems . Conventional systems would be replaced with touch screen interfaces and voice commands (cockpit speech-recognition system). AMCA pilot will have a helmet-mounted display system that allows the jettisoning of a HUD from the AMCA cockpit altogether.
The primary flight controls are arranged in a hands-on-throttle-and-stick (HOTAS)-compatible configuration, with a right-handed side-stick controller and a left-handed throttle. HOTAS will give more control over air craft, because they give independent analog control over all three rotational axes (Pitch, Roll, and Yaw) as well as thrust. AMCA's cockpit has a secondary "get-you-home" panel providing the pilot with essential flight information in case of an emergency.
The pilot interacts with on-board systems through a multi-functional keyboard and several selection panels. The Head up Display and helmet-mounted display and sight (HMDS), and hands-on-throttle-and-stick (HOTAS) controls reduce pilot workload and increase situation awareness by allowing the pilot to access navigation and weapon-aiming information with minimal need to spend time "head down" in the cockpit.
Propulsion
AMCA is a twin-engines aircraft which is powered by 2X GTRE k9 + or K 10 engine that can capable of producing 11-Kn-125Kn thrust each. The aircraft has a maximum takeoff weight is 29 tonnes: 2 tonnes of internal weapons and 4 tonnes of internal fuel. It can achieve maximum speed of 2.5+ Mach (2665 + Km/h) at altitude and Mach 1.2 at sea level and have a cruise speed of Mach 1.6 at super-cruise. The AMCA would have range of 2800 km and climb at the altitudes @ 13,716m/min.
Avionics
The envisaged avionics of AMCA would be the best in this world if everything goes as planned. The system architecture of AMCA is much more advanced than what we seen in LCA Tejas. AMCA looking towards a quadruplex fly-by-light electrooptic architecture with fiber optic links for signal and data communications. And unlike centralized architecture on the Tejas, the AMCA proposes to sport a distributed architecture with smart sub-systems. Similarly, unlike the LCA's centralized digital Flight control computer (DFCC), the AMCA could have a distributed system with smart remote units for data communication with sensors and actuators, a system that will necessitate much faster on-board processors.
The mechanical gyros and accelerometers are avoided in AMCA rather it will use fiber optic gyros, ring laser gyros and MEMS gyros (MicroElectroMechanical Systems). The pressure probes and vanes that make up the air-data sensors will evolve into an optical and flush air data system, and position sensors will be linear/rotary optical encoders. Significantly, actuators -- currently electro-hydraulic/direct drive using in the conventional aircrafts could be changed to electrohydrostatic, to accrue substantive weight savings on the AMCA.
The AMCA could feature highly evolved integrated control laws for flight, propulsion, braking, nose wheel steer and fuel management and adaptive neural networks for fault detection, identification and control law reconfiguration. Flights controls of the aircraft are both highely Integrated and independent of each other's which includes flight controls, engine controls, brake and landing controls, and other systems this is possible due the active controls gears systems (ACGS).
The AMCA's avionics systems architecture will feature a central computational system connected internally and externally on an optic fiber channel by means of multiport connectivity switching modules. In such a system, functionality will be mapped on resourced optimally and reallocated when faults occur (Self healing).Data communications on the AMCA's processing modules will be through a high-speed fiber channel bus, IEEE-1394B-STD. The connectivities will be switched by means of a multiport switching matrix, with data speeds of 400MB/second.
The AMCA could have integrated radio naviation systems, where all functions earlier done by analogue circuits will be shifted onto digital processors. Communication system will be based on software radio ranging from UHF to K band, with data links for digital data/voice data and video.
Algorithms of AMCA will be one of the best, the AMCA pilot will get a decision aid in the form of ability to plan attack strategies, avoid strategies, retreat strategies and evasive strategies for himself and his buddies. Fault recording and coverage in the maintenance and diagnostics algorithms on the AMCA will be one of the most advanced ones. This kind of fault recording will be used to iterate more advanced algorithms and decision aid.
The AMCA's EW suite is developed by the Defence Avionics Research Establishment (DARE) with support from the Defence Electronics Research Laboratory (DLRL). This EW suite includes a radar warning receiver (RWR), Missile Approach Warning (MAW) and a laser warning receiver (LWR) system, Infrared & Ultraviolet Missile warning sensors, self-protection jammer, chaff, jaff and flare dispenser, an electronic countermeasures (ECM) suite and a towed radar decoy (TRD).
Weapons
With advanced sensors the aircraft will be loaded with missiles like DRDO Astra along with some other superior missiles, standoff weaponry as well as precision weapons. The aircraft will feature the ability to deploy Precision Guided Munitions. It will also feature extensive detection range as well as targeting range with the capacity to release arsenals at supersonic speed.
The AMCA features two internal weapons bays which can carry four air-air missiles each. A total of eight missiles are carried in the internal bays, and there are external hardpoints for mounting up to six underwing pylons including two near wingtip pylons and two for drop tanks along with two hardpoints underneath the aircraft's belly, with two on the each side of the weapons bay. AMCA's high cruising speed substantially increases weapon effectiveness compared to its predecessors due to its ability to launch weapons at supersonic speed
References
1. Abhijit Iyer-Mitra and Pushan Das. "The Advanced Medium Combat
Aircraft:A Technical Analysis".
2. Aviation week
3. ADA
4. Wikipedia
5. Many other news and articles
http://fullafterburner.weebly.com/next-gen-weapons/amca-the-conqueror-in-making
Sensors
The Senor suites in AMCA led by the LRDE and BEL which include many private and foreign contributes.
The primary sensor will be gallium Nitride (GaN) based radar. Infrared based systems like IRST, missile warning systems, laser warning system also added internally in the AMCA. The IRST sensors are placed in all sides of the AMCA to provide full angle coverage like in Rafale and F 35. The proposed IRST system is work similar to the F 35’s EOTS who shares the information’s to friendly units like via the satellite and highly secured data links. But the fact remains that only United States and China have developed conformal IR/Synthetic vision Sensors & Tracking system and there will be significant developmental hurdles here.
AMCA also comes with self protection jammer system to jam enemy radar guided missiles from both air and ground. Electronic counter measure systems to confuse the infrared guided missiles (DIRCM) and a radar warning receiver too added to detect enemy radar frequencies.
The Multifunction RF Sensor, which has broad spectrum agility, includes capabilities for electronic countermeasures (ECM), electronic support measures (ESM), communications functions, and possibly even microwave weapon functions. AMCA will be integrated from the cockpit to accompanying UAVs and UCAVs which will include DRDO AURA, DRDO Rustom through encrypted datalink connections
Sensor Fusion
In AMCA all the data collected from the various sensors processes and present to the pilot as a single integrated picture of the battle field and possibly share to other fighters and ground stations automatically (Net centric). This kind of sensor fusion will provide the pilot a stunning situational awareness.
AMCA will have vehicle management (including weapons), data fusion, decision aids, integrated modular avionics, internal carriage of weapons, signature control. The AMCA is likely to have fly - by - light system. It makes AMCA more immune to electronic attacks (EMI – electromagnetic interference, HIRF –High energy radiated fields) and much better transmission speed and processing capabilities. Fly – by – light is also helps to reduce the weight of the aircraft. The higher band width of fly – by – light is very useful in controlling the aircraft at high speeds. Higher bandwidth ensures higher data transfer rate, therefore pilots command passes rapidly from aircraft cockpit to control surfaces which ensures smooth aircraft maneuvering even in high speeds especially AMCA is designed as an aircraft with super cruise capability the advantage of Fly – by – light is enormous and also improves the safety margin of AMCA.
Another major advantage of Fly – By – Light is , AMCA will use composites to make its body , use of composite materials in aircraft structures will decrease the effect of electronic attack of enemies cos composites are less suspected to EMI than metal structures .Consequently, FBW are subjected to greater electrical interference which can degrade performance .But optical pulses transmitted by FBL system are unaffected by the much lower frequency electromagnetic waves that characterize the Electronic attack threat.
AMCA will have another feature called self repair / self protection. Self repair will achieve with the help of self-diagnosing and self-healing systems that distribute the work load to other systems from affected to non-affected systems. Self protection would be provided with the use of nanotechnology to produce advanced composite materials designed to have a higher resistance to damage and therefore reducing the damage surface area. The aircraft uses Self Repairing Flight Control Capability to automatically detect failures or damage in its flight control surfaces, and using the remaining control surfaces, calibrate accordingly to retain controlled flight. The use of adaptive neural networks would be a key feature in self healing and self repairing they can record all the faults occurred and also can learn from the previous faults.
But it is not an easy task to develop this kind of highly advanced capabilities. Sensor fusion is a necessity in 5th generation fighter aircrafts, only time will say how good will be AMCA, s sensor fusion.
Radar
The AMCA will incorporate an Active Electronically Scanned Array (AESA) which, the official illustrations indicate, is also mechanically steerable. This is an advantage as the beam manoeuvrability of an AESA can be stretched to a broader detection area.
The AMCA hosts new generation GaN based AESA for superior detection and performance. Some information’s reported that, state owned LRDE is initiated a project to develop a small size air borne X band GaN based AESA radar for AMCA. LRDE already shows a model of AESA radar in last year’s Aero India exhibition. The use of GaN will give significant benefits of power density, efficiency, and bandwidth to AMCA. Furthermore the use of GaN will solve substantial system-related issues, such as the need for higher operating voltages, more efficient heat removal techniques, and high reliability
The under development Uttam AESA radar intended for Tejas LCA is not good for fifth generation fighters like AMCA. It’s reported earlier that, India and Israel working for a joint project to develop a GaN based AESA for fighter jets. However due to the importance of the program the information’s are highly classified.
Cockpit
One of the most dramatic aspects AMCA will be its cockpit and man-machine interface. AMCA cockpit could have a panoramic active-matrix display of the kind available on American fifth generation aircraft with dimensions of 60 by 24 centimeters designed by DARE and manufactured by Samtel or 44 by 18 centimetres by HALBIT which is a joint-venture between HAL and Elbit Systems . Conventional systems would be replaced with touch screen interfaces and voice commands (cockpit speech-recognition system). AMCA pilot will have a helmet-mounted display system that allows the jettisoning of a HUD from the AMCA cockpit altogether.
The primary flight controls are arranged in a hands-on-throttle-and-stick (HOTAS)-compatible configuration, with a right-handed side-stick controller and a left-handed throttle. HOTAS will give more control over air craft, because they give independent analog control over all three rotational axes (Pitch, Roll, and Yaw) as well as thrust. AMCA's cockpit has a secondary "get-you-home" panel providing the pilot with essential flight information in case of an emergency.
The pilot interacts with on-board systems through a multi-functional keyboard and several selection panels. The Head up Display and helmet-mounted display and sight (HMDS), and hands-on-throttle-and-stick (HOTAS) controls reduce pilot workload and increase situation awareness by allowing the pilot to access navigation and weapon-aiming information with minimal need to spend time "head down" in the cockpit.
Propulsion
AMCA is a twin-engines aircraft which is powered by 2X GTRE k9 + or K 10 engine that can capable of producing 11-Kn-125Kn thrust each. The aircraft has a maximum takeoff weight is 29 tonnes: 2 tonnes of internal weapons and 4 tonnes of internal fuel. It can achieve maximum speed of 2.5+ Mach (2665 + Km/h) at altitude and Mach 1.2 at sea level and have a cruise speed of Mach 1.6 at super-cruise. The AMCA would have range of 2800 km and climb at the altitudes @ 13,716m/min.
Avionics
The envisaged avionics of AMCA would be the best in this world if everything goes as planned. The system architecture of AMCA is much more advanced than what we seen in LCA Tejas. AMCA looking towards a quadruplex fly-by-light electrooptic architecture with fiber optic links for signal and data communications. And unlike centralized architecture on the Tejas, the AMCA proposes to sport a distributed architecture with smart sub-systems. Similarly, unlike the LCA's centralized digital Flight control computer (DFCC), the AMCA could have a distributed system with smart remote units for data communication with sensors and actuators, a system that will necessitate much faster on-board processors.
The mechanical gyros and accelerometers are avoided in AMCA rather it will use fiber optic gyros, ring laser gyros and MEMS gyros (MicroElectroMechanical Systems). The pressure probes and vanes that make up the air-data sensors will evolve into an optical and flush air data system, and position sensors will be linear/rotary optical encoders. Significantly, actuators -- currently electro-hydraulic/direct drive using in the conventional aircrafts could be changed to electrohydrostatic, to accrue substantive weight savings on the AMCA.
The AMCA could feature highly evolved integrated control laws for flight, propulsion, braking, nose wheel steer and fuel management and adaptive neural networks for fault detection, identification and control law reconfiguration. Flights controls of the aircraft are both highely Integrated and independent of each other's which includes flight controls, engine controls, brake and landing controls, and other systems this is possible due the active controls gears systems (ACGS).
The AMCA's avionics systems architecture will feature a central computational system connected internally and externally on an optic fiber channel by means of multiport connectivity switching modules. In such a system, functionality will be mapped on resourced optimally and reallocated when faults occur (Self healing).Data communications on the AMCA's processing modules will be through a high-speed fiber channel bus, IEEE-1394B-STD. The connectivities will be switched by means of a multiport switching matrix, with data speeds of 400MB/second.
The AMCA could have integrated radio naviation systems, where all functions earlier done by analogue circuits will be shifted onto digital processors. Communication system will be based on software radio ranging from UHF to K band, with data links for digital data/voice data and video.
Algorithms of AMCA will be one of the best, the AMCA pilot will get a decision aid in the form of ability to plan attack strategies, avoid strategies, retreat strategies and evasive strategies for himself and his buddies. Fault recording and coverage in the maintenance and diagnostics algorithms on the AMCA will be one of the most advanced ones. This kind of fault recording will be used to iterate more advanced algorithms and decision aid.
The AMCA's EW suite is developed by the Defence Avionics Research Establishment (DARE) with support from the Defence Electronics Research Laboratory (DLRL). This EW suite includes a radar warning receiver (RWR), Missile Approach Warning (MAW) and a laser warning receiver (LWR) system, Infrared & Ultraviolet Missile warning sensors, self-protection jammer, chaff, jaff and flare dispenser, an electronic countermeasures (ECM) suite and a towed radar decoy (TRD).
Weapons
With advanced sensors the aircraft will be loaded with missiles like DRDO Astra along with some other superior missiles, standoff weaponry as well as precision weapons. The aircraft will feature the ability to deploy Precision Guided Munitions. It will also feature extensive detection range as well as targeting range with the capacity to release arsenals at supersonic speed.
The AMCA features two internal weapons bays which can carry four air-air missiles each. A total of eight missiles are carried in the internal bays, and there are external hardpoints for mounting up to six underwing pylons including two near wingtip pylons and two for drop tanks along with two hardpoints underneath the aircraft's belly, with two on the each side of the weapons bay. AMCA's high cruising speed substantially increases weapon effectiveness compared to its predecessors due to its ability to launch weapons at supersonic speed
References
1. Abhijit Iyer-Mitra and Pushan Das. "The Advanced Medium Combat
Aircraft:A Technical Analysis".
2. Aviation week
3. ADA
4. Wikipedia
5. Many other news and articles
http://fullafterburner.weebly.com/next-gen-weapons/amca-the-conqueror-in-making
- Joined
- Apr 8, 2016
- Messages
- 1,489
- Likes
- 5,808
kunal1123
New Member
- Joined
- Jan 12, 2017
- Messages
- 594
- Likes
- 1,142
i know it's from idrw.org but still some good news...
Latest update on AMCA: Navy in, IAF puts a number and DRDO working on final design
Navy is ready to deploy its own team to help ADA develop Naval AMCA independently customised as per Navy requirements. Indian Navy and ADA are likely to discuss funding and design feasibility this year. Naval AMCA will require hardening of the fuselage, reinforced undercarriage and new landing gear system for carrier-based operations.
IAF puts a number Initial requirements for AMCA currently been discussed between ADA and IAF is 115-120 aircraft to replace its current fleet of 60 Mig-29UPG and 50+ Mirage-2000 when they are up for retirement post-2030. IAF is clear that AMCA will replace all Medium class Combat jet in its current fleet but it is still an initial estimate since Indian Air-force also has 120 Jaguar Strike aircraft which all will be gone by 2030, which too requires replacement but Jaguar replacement might also come in the procurement of LCA-Tejas MK2.
http://idrw.org/latest-update-on-amca-navy-in-iaf-puts-a-number-and-drdo-working-on-final-design/
Latest update on AMCA: Navy in, IAF puts a number and DRDO working on final design
Navy is ready to deploy its own team to help ADA develop Naval AMCA independently customised as per Navy requirements. Indian Navy and ADA are likely to discuss funding and design feasibility this year. Naval AMCA will require hardening of the fuselage, reinforced undercarriage and new landing gear system for carrier-based operations.
IAF puts a number Initial requirements for AMCA currently been discussed between ADA and IAF is 115-120 aircraft to replace its current fleet of 60 Mig-29UPG and 50+ Mirage-2000 when they are up for retirement post-2030. IAF is clear that AMCA will replace all Medium class Combat jet in its current fleet but it is still an initial estimate since Indian Air-force also has 120 Jaguar Strike aircraft which all will be gone by 2030, which too requires replacement but Jaguar replacement might also come in the procurement of LCA-Tejas MK2.
http://idrw.org/latest-update-on-amca-navy-in-iaf-puts-a-number-and-drdo-working-on-final-design/
- Joined
- Mar 19, 2016
- Messages
- 5,724
- Likes
- 11,638
Absolute nonsense shit
Such quality can only be expected from idrw
The numbers will go above 400 for iaf for sure
- Joined
- Jul 12, 2014
- Messages
- 32,663
- Likes
- 151,106
Read again..
Numbers are being projected up to 2030. You mean to say AMCA which is not even ready on paper will be made more than 20 per year before 2030.
- Joined
- Mar 19, 2016
- Messages
- 5,724
- Likes
- 11,638
It will be ready by 2030.......
After that we can produce it at the rate of at least 2-3 squadrons per year..........
Achievable target I beleive....
Plus I misread...
- Joined
- Jan 30, 2015
- Messages
- 5,005
- Likes
- 8,882
I bet it will take more time or it will be scraped completely. Mark my words.
ISRO is the only central government entity which is competing with world players. 2030 is doubtful.
Sent from my ASUS_Z00LD using Tapatalk
kunal1123
New Member
- Joined
- Jan 12, 2017
- Messages
- 594
- Likes
- 1,142
i don't think so look at lca time line for example
1986 fund allotment 1990 Design of LCA was finalized
1993
Full funding started from April 1993
1995 work on TD-1 start ,TD-2 in 1998.
2001 - 4 January - LCA’s maiden flight successfully completed by Technology Demonstrator TD-1,
2003 PV-1 makes a successful maiden flight
2007 Limited Series Production LCA
so basically it taken 12 year to start limited series production and that to including all the challenges drdo and hal has to take (sanction ,engine , change in requirement, first modern combat aircraft after long 20 year break last hf 24 was produce around 1985 i guss , no aerospace industrial back, cash blocking for testing)
now if ifa ,navy,drdo and hal is working together from starting and the engine selection is taking from start i think that the time line can be reduced by 4 year min.. to start the full production by 2030
here are my time line for amca (if engine selected )
2018 funding
2020 work on first td start
2021 2nd td
2024-25
pv 1
2027-28 limited series production..
2030-2031 spv 1.
lca timiline sources wiki...
https://en.wikipedia.org/wiki/Timeline_of_HAL_Tejas#1980s
Last edited:
lcafanboy
New Member
- Joined
- Mar 24, 2013
- Messages
- 5,875
- Likes
- 37,838
It can be ready by 2030. Design already freezed. All proven technologies are going in Kaveri snecma engine, Elta 2052 gaN AESA, spectra ew, just integration and testing required. So very much possible.
- Joined
- Jul 12, 2014
- Messages
- 32,663
- Likes
- 151,106
Any opinions on 5th gen tech. Your timelines maybe good for the airframe but what about tech?
So far we haven't heard anything about AMCA tech, even theoretically..
When I say tech, I mean 360 degree visibility , network centric capabilities etc.
