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Thrust to Weight Ratios of all Fighter Planes

Manticore

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TWR or T/W ratio = (Max Thrust of Engine / (Empty Weight + (3.505 Tonnes of Fuel & Weapons, or only Internal Fuel)))

1.30 - Su-35BM
1.29 - F-15K
1.26 - Su-27S
1.25 - Eurofighter
1.24 - Mig-35
1.23 - Su-27SK & J-11A
1.19 - Rafale C
1.19 - Mig-29M/M2
1.19 - F-15C
1.18 - F-22 (T/W = 1.37 with Round nozzles)

1.16 - Su-30MKK
1.15 - F/A-18E/F
1.15 - Mig-29B (9-12)
1.14 - Su-30MKI
1.13 - Rafale M
1.13 - Mig-29 (9-13), S, SD, SE & SM
1.10 - Mig-29 BM & SMT (T/W = 1.15 during Emergency Thrust*)
1.09 - F-16E Block 60
1.09 - Mig-29K
1.09 - F-18C

1.09 - J-8III(or J-8C)
1.08 - F-35A
1.08 - F-14 B & D
1.06 - F-16C Block 52 (Block 50: T/W = 1.055)
1.05 - J-8IIm
1.04 - AV-8B+ Harrier II
1.03 - F-2A (F-2B: 1.02)
1.03 - JH-7
1.02 - F-16A Block 10
1.01 - J-8II & J-8IIb & J-8IId

1.00 - F-35B
1.00 - Harrier GR7A
0.99 - Su-34 & Su-32FN & Su-27IB
0.99 - Sea Harrier FA2 & FRS51
0.99 - F-16A Block 20
0.98 - J-10A
0.97 - Su-15T
0.95 - MiG-23 P, ML, MLA & MLD
0.94 - F-35C
0.94 - Gripen NG

0.94 - F-4E
0.94 - J-8
0.93 - Mirage 2000-5
0.93 - Su-15TM
0.93 - F-101B
0.92 - Harrier GR7
0.92 - E E Lightning F6
0.91 - F-16C Block 25
0.91 - Yak-28 I & P
0.91 - F-111F

0.91 - Su-24
0.90 - Su-15
0.88 - Mirage-2000 C & H
0.87 - LCA
0.87 - F-14A
0.87 - Mig-23 MF & MS
0.87 - Su-24 M, MK & M2
0.86 - ****-1
0.86 - Su-9
0.84 - Su-11

0.84 - Su-17M
0.83 - Tornado F3 Air Defence Variant
0.83 - Tornado GR1
0.83 - Su-20
0.82 - JF-17 (T/W = 0.86 during Emergency Thrust*)
0.82 - Su-22
0.81 - Gripen A
0.81 - Su-7B
0.81 - F-20
0.80 - Gripen C

0.80 - Mig-27K
0.80 - Su-7BM
0.79 - Mig-21 Bis (T/W = 1.11 in Emergency Thrust mode**)
0.79 - JA-37 Viggen
0.79 - Mig-27
0.79 - Su-17M2
0.78 - Mig-23BN
0.78 - Su-7 BKL & BMK
0.78 - Javelin FAW MK9
0.77 - Mig-23S

0.77 - J-7IIIa
0.76 - Mig-27 D & ML
0.76 - Mig-23M(E)
0.76 - F-106A
0.76 - F-7MG & F-7BG & F-7PG & J-7E & J-7G (WP-7N: T/W = 0.69)
0.76 - Q-5D
0.75 - Kfir C.7
0.75 - Kfir C.2
0.75 - AJ-37 Viggen
0.75 - J-7III

0.74 - Mig-21SM
0.73 - Su-17
0.73 - Mig-21MF
0.73 - Su-17M3
0.73 - Mig-19S*** (MTOW T/W = 0.86)
0.72 - Yak-27K
0.72 - Su-17M4
0.72 - F-104G
0.71 - Mig-19P*** (MTOW T/W = 0.84)
0.71 - Mig-21PF

0.71 - Supermarine Scimitar F.1
0.71 - Cheetah C
0.70 - Mig-21M
0.70 - Su-25SM
0.69 - Jaguar GR1
0.69 - J-35F Draken
0.69 - Mig-21F
0.69 - Mig-21 F-13
0.69 - J-7II
0.69 - Su-25 or Su-25T

0.68 - F-105F/G
0.68 - Mirage 50
0.68 - F-7M(or F-7MP or F-7MB) & F-7P
0.67 - F-1
0.67 - F4D-1/F-6 Skyray
0.66 - Mirage F-1
0.66 - F-8P
0.64 - F-102A
0.63 - Sea Vixen FAW.2
0.63 - Su-25TM or Su-39

0.62 - Yak-27
0.61 - Yak-38M (TWR during STOVL/VTOL takeoff: 1.20)
0.61 - Mirage-5A
0.61 - J-32B Lansen
0.60 - A-4S1
0.59 - Mirage-III E & D
0.58 - Yak-38 (T/W during STOVL/VTOL takeoff: 1.16)
0.58 - IAI Nesher
0.58 - F-5E Tiger-II
0.56 - F-100D

0.56 - A-6E
0.55 - A-7E
0.51 - Super Étendard
0.50 - F3H-2 Demon
0.49 - A-10A
0.49 - F-11A
0.49 - AMX
0.47 - Étendard-IV M
0.46 - F-89D
0.46 - Super Mystère B.2

0.46 - Hunter F 6
0.45 - Marut Mk.1
0.43 - Yak-25
0.43 - F-94C/F-97A
0.43 - F9F-8/F-9J Cougar
0.41 - A-37B
0.37 - Mystère IVA
0.37 - FJ-4 Fury
0.36 - F7U-3M
0.34 - F-84F

0.33 - J-29F Tunnan
0.33 - P-80C
0.32 - Supermarine Attacker F.1
0.31 - F2H-3 Banshee
0.30 - Ouragan M.D.450B
0.30 - F3D-2 Sky Night
0.29 - Venom FB.1
0.29 - F-84G


Pure Interceptors
1.30 - Mig-31M
1.30 - Mig-31BM
1.28 - Mig-31B
1.27 - Mig-31FE
1.27 - Mig-31E
1.22 - Mig-31
1.21 - Mig-25M
1.00 - Mig-25 P & PD
0.93 - Mig-25BM
0.74 - Tu-128




Empty Weight - Thrust - Aircraft

41,447 - 31,967 X 2 - Su-35BM
37,500 - 29,160 X 2 - F-15K
36,111 - 27,557 X 2 - Su-27S
24,251 - 20,000 X 2 - Eurofighter
24,251 - 19,841 X 2 - Mig-35
37,192 - 27,557 X 2 - Su-27SK & J-11A
20,948 - 17,000 X 2 - Rafale C
25,573 - 19,841 X 2 - Mig-29M/M2
31,700 - 23,450 X 2 - F-15C
43,340 - 30,100 X 2 - F-22(35,000lbf - Thrust with round nozzle)

39,903 - 27,557 X 2 - Su-30MKK
30,600 - 22,000 X 2 - F/A-18E/F
24,030 - 18,300 X 2 - Mig-29B (9-12)
40,565 - 27,557 X 2 - Su-30MKI
22,478 - 17,000 X 2 - Rafale M
24,692 - 18,300 X 2 - Mig-29 (9-13), S, SD, SE & SM
25,573 - 18,300 X 2 - Mig-29 BM & SMT (19,180lbf - Emergency Thrust*)
22,000 - 32,500 X 1 - F-16E Block 60
28,550 - 19,841 X 2 - Mig-29K
24,700 - 17,700 X 2 - F-18C

22,509 - 16,535 X 2 - J-8III(or J-8C)
29,300 - 39,900 X 1 - F-35A
43,600 - 27,800 X 2 - F-14 B & D
19,700 - 29,160 X 1 - F-16C Block 52 (Block 50: 420lb & 240lbf more)
21,671 - 15,422 X 2 - J-8IIm
14,865 - 23,400 X 1 - AV-8B+ Harrier II
21,000 - 29,600 X 1 - F-2A (F-2B: 21,235lb)
31,967 - 20,515 X 2 - JH-7
15,600 - 23,830 X 1 - F-16A Block 10
21,671 - 14,815 X 2 - J-8II & J-8IIb & J-8IId

32,000 - 39,900 X 1 - F-35B
15,708 - 23,400 X 1 - Harrier GR7A
49,163 - 28,219 X 2 - Su-34 & Su-32FN & Su-27IB
14,052 - 21,450 X 1 - Sea Harrier FA2 & FRS51
16,285 - 23,830 X 1 - F-16A Block 20
20,394 - 27,557 X 1 - J-10A
22,818 - 14,770 X 2 - Su-15T
22,553 - 28,660 X 1 - MiG-23 P, ML, MLA & MLD
34,800 - 39,900 X 1 - F-35C
15,653 - 22,000 X 1 - Gripen NG

30,328 - 17,845 X 2 - F-4E
20,470 - 13,219 X 2 - J-8
16,000 - 22,045 X 1 - Mirage 2000-5
23,970 - 14,770 X 2 - Su-15TM
28,495 - 16,900 X 2 - F-101B
15,708 - 21,450 X 1 - Harrier GR7
28,042 - 16,360 X 2 - E E Lightning F6
18,238 - 23,770 X 1 - F-16C Block 25
21,980 - 13,448 X 2 - Yak-28 I & P
47,481 - 25,100 X 2 - F-111F

46,738 - 24,692 X 2 - Su-24
22,531 - 13,669 X 2 - Su-15
16,538 - 21,384 X 1 - Mirage 2000 C & H
14,330 - 19,100 X 1 - LCA
40,104 - 20,900 X 2 - F-14A
24,008 - 27,558 X 1 - Mig-23 MF & MS
49,163 - 24,801 X 2 - Su-24 M, MK & M2
14,300 - 09,500 X 2 - ****-1
16,920 - 21,164 X 1 - Su-9
18,876 - 22,267 X 1 - Su-11

21,605 - 24,692 X 1 - Su-17M
31,970 - 16,410 X 2 - Tornado F3 Air Defence Variant
31,065 - 16,005 X 2 - Tornado GR1
21,936 - 24,692 X 1 - Su-20
14,520 - 18,300 X 1 - JF-17 (19,180lbf - Emergency Thrust*)
23,027 - 25,353 X 1 - Su-22
14,595 - 18,097 X 1 - Gripen A
18,453 - 21,164 X 1 - Su-7B
13,150 - 17,000 X 1 - F-20
14,991 - 18,097 X 1 - Gripen C

26,252 - 27,558 X 1 - Mig-27K
18,629 - 21,164 X 1 - Su-7BM
12,037 - 15,654 X 1 - Mig-21 Bis (21,829lbf - Emergency Thrust**)
27,866 - 28,100 X 1 - JA-37 Viggen
24,317 - 25,336 X 1 - Mig-27
23,369 - 24,692 X 1 - Su-17M2
24,692 - 25,336 X 1 - Mig-23BN
19,599 - 21,164 X 1 - Su-7 BKL & BMK
23,955 - 12,300 X 2 - Javelin FAW MK9
21,583 - 22,487 X 1 - Mig-23S

11,629 - 14,815 X 1 - J-7IIIa
25,573 - 25,336 X 1 - Mig-27 D & ML
22,046 - 22,487 X 1 - Mig-23M(E)
24,420 - 24,500 X 1 - F-106A
11,667 - 14,650 X 1 - F-7MG & F-7BG & F-7PG & J-7E & J-7G (WP-7N: 13,450lbf)
14,054 - 08,269 X 2 - Q-5D
17,130 - 18,750 X 1 - Kfir C.7
16,061 - 17,901 X 1 - Kfir C.2
27,006 - 25,970 X 1 - AJ-37 Viggen
11,861 - 14,650 X 1 - J-7III

11,574 - 14,308 X 1 - Mig-21SM
21,164 - 21,164 X 1 - Su-17
11,795 - 14,308 X 1 - Mig-21MF
26,014 - 24,692 X 1 - Su-17M3
12,009 - 07,165 X 2 - Mig-19S*** (MTOW: 16,667lb)
15,443 - 08,318 X 2 - Yak-27K
26,810 - 24,692 X 1 - Su-17M4
14,082 - 15,600 X 1 - F-104G
12,507 - 07,165 X 2 - Mig-19P*** (MTOW: 17,042lb)
11,354 - 13,492 X 1 - Mig-21PF

23,962 - 11,250 X 2 - Supermarine Scimitar F.1
14,550 - 15,900 X 1 - Cheetah C
11,795 - 13,613 X 1 - Mig-21M
20,723 - 09,921 X 2 - Su-25SM
15,432 - 08,040 X 2 - Jaguar GR1
17,339 - 17,262 X 1 - J-35F Draken
10,624 - 12,654 X 1 - Mig-21F
10,739 - 12,654 X 1 - Mig-21 F-13
11,850 - 13,219 X 1 - J-7II
20,944 - 09,921 X 2 - Su-25 or Su-25T

28,393 - 24,500 X 1 - F-105F/G
15,763 - 15,870 X 1 - Mirage 50
11,629 - 13,219 X 1 - F-7M(or F-7MP or F-7MB) & F-7P
14,017 - 07,305 X 2 - F-1
16,024 - 16,000 X 1 - F4D-1/F-6 Skyray
16,314 - 15,873 X 1 - Mirage F-1
19,700 - 18,000 X 1 - F-8P
19,350 - 17,200 X 1 - F-102A
27,954 - 11,240 X 2 - Sea Vixen FAW.2
23,677 - 09,921 X 2 - Su-25TM or Su-39

15,395 - 07,165 X 2 - Yak-27
16,535 - 14,770 X 1 - Yak-38M (Lift Engines: 07,165lbf X 2)
14,550 - 13,669 X 1 - Mirage-5A
16,535 - 14,680 X 1 - J-32B Lansen
10,250 - 10,800 X 1 - A-4S1
15,540 - 13,669 X 1 - Mirage-III E & D
15,476 - 13,448 X 1 - Yak-38 (Lift Engines: 06,724lbf X 2)
16,061 - 13,669 X 1 - IAI Nesher
09,558 - 05,000 X 2 - F-5E Tiger-II
20,638 - 16,000 X 1 - F-100D

25,630 - 09,300 X 2 - A-6E
19,781 - 15,000 X 1 - A-7E
14,220 - 11,265 X 1 - Super Étendard
21,287 - 14,400 X 1 - F3H-2 Demon
29,000 - 09,065 X 2 - A-10A
13,810 - 10,500 X 1 - F-11A
14,837 - 11,030 X 1 - AMX
13,007 - 09,703 X 1 - Étendard-IV M
24,200 - 07,400 X 2 - F-89D
14,087 - 09,920 X 1 - Super Mystère B.2

14,121 - 10,146 X 1 - Hunter F 6
13,658 - 04,856 X 2 - Marut Mk.1
12,610 - 04,409 X 2 - Yak-25
12,708 - 08,750 X 1 - F-94C/F-97A
11,866 - 08,500 X 1 - F9F-8/F-9J Cougar
06,211 - 02,850 X 2 - A-37B
12,941 - 07,734 X 1 - Mystère IVA
13,210 - 07,700 X 1 - FJ-4 Fury
18,210 - 04,600 X 2 - F7U-3M
13,830 - 07,220 X 1 - F-84F

10,681 - 06,070 X 1 - J-29F Tunnan
08,420 - 05,400 X 1 - P-80C
08,426 - 05,100 X 1 - Supermarine Attacker F.1
13,183 - 03,250 X 2 - F2H-3 Banshee
09,132 - 04,991 X 1 - Ouragan M.D.450B
14,989 - 03,400 X 2 - F3D-2 Sky Night
09,200 - 04,856 X 1 - Venom FB.1
11,470 - 05,560 X 1 - F-84G


Pure Interceptors
48,281 - 36,376 X 2 - Mig-31M
48,115 - 36,376 X 2 - Mig-31BM
45,569 - 34,171 X 2 - Mig-31B
49,383 - 36,376 X 2 - Mig-31FE
46,297 - 34,171 X 2 - Mig-31E
48,104 - 34,171 X 2 - Mig-31
41,667 - 29,762 X 2 - Mig-25M
41,447 - 24,684 X 2 - Mig-25 P & PD
45,415 - 24,684 X 2 - Mig-25BM
54,013 - 22,706 X 2 - Tu-128


# Data from Official Company & Military sites, Aerospaceweb.org, Airwar.ru, Globalsecurity.org, Fas.org, Warfare.ru, Wikipedia.org & its References, and Other Sources.
# Weight in lb, and Thrust in lbf.
# 3505 kg = 7727 lb
# Not all of them are Fighter Planes.
# Some of the Fighters' data couldn't be obtained, and hence could not be included in the above list.
# Individual engines' SFC(Specific Fuel Consumption) & Individual aircrafts' standard Air-Air payload weight, based TWR cannot be determined due to unavaliability of SFC data for Older Engines. Even in the case of some Newer Engines, SFC data is not avaliable.
# It's likely that the 35,000lbf thrust for F119(F-22's engine) doesn't include flat nozzles. For an engine thrust decrease of 14%, which accompanies flat nozzles, F-22's TWR would drop down to 1.18. It's known that Flat nozzles reduces the thrust of an engine from 14%-17%. Given the fact that the F-35's engine, which is a derivative of the F-22's engine, but newer & bigger than the F119 engine, has a thrust of 39,900lbf with round nozzles, it's likely the 35,000lbf fig for F119 is also for round nozzles.

* Klimov States that Thrust as "Take-off emergency mode"
** The conditions for 21,829lbf Emergency Thrust are limited to 3 Minutes and Altitude less than 4000m.
*** Empty weight + 7727 lb exceeds max takeoff weight. Except Mig-19 all other less MTOW(Maximum Take-Off Weight) fighter planes are omitted.


http://dc221.*******.com/img/381103594/91774d24/0.4547731168312661/thrustweightratio.jpg


== Thurst to Weight Ratios of all Fighters ==


http://www.defence.pk/forums/military-aviation/72354-thrust-weight-ratios-all-fighter-planes.html
http://www.defence.pk/forums/military-aviation/118218-engines-used-different-fighters.html
http://www.defence.pk/forums/military-aviation/94948-radar-ranges-different-fighters.html
http://www.defence.pk/forums/military-forum/20908-rcs-different-fighters.html
 
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If your thrust to weight ratio is below 1 you can't increase speed when pointing directly vertical.

Because alot of people thinks that when fighter jets turn upwards they just change the angle while having the same velocity that the plane nose is pointed at, but infact when you turn upwards your vertical speed starts at zero, so larger T\W ratio means you can change velocity faster, while better aerodynamic design (and TVC) means the plane can change it's pointing direction faster (but both are important).
 
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Hmm I guess it makes more sense how it can be valuable asset to a plane to climb up faster then his/her adversary in air.

But don't the modern day missiles neutralize this advantage in a dog fight situation ?
 
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Thrust to weight usually determines acceleration and climb performance. Top sprint speed is largely dictated by thrust to drag and intake design.

"The speed of air entering the compressor of a normal jet engine must be subsonic, even for supersonic aircraft. While this doesn't affect subsonic aircraft, supersonic aircraft face a problem. This is because present design jet engines would be unable to handle the shock waves associated with supersonic airflow, and might be damaged.

Thus, for an aircraft travelling above Mach 1 speed, the airflow must be slowed down to subsonic speeds. In modern jet aircraft, this is done in a variety of ways through design of the Inlet. The complexity of these inlets increases with an increase in top speed. Planes with top speeds over Mach 2 require much more elaborate inlet designs. Thus, most modern aircrafts today rarely exceed the Mach 2 speed, usually limiting their top speed to Mach 1.8-2.0."

Some air inlets feature a biconic centrebody to form two conic shock waves, both focused on the lip of the intake. This improves pressure recovery. Some aircraft (Joint Strike Fighter, Mirage III) use a semi-conic centrebody.

Concorde, F-15, Foxbat, A-5 Vigilante use so-called 2D inlets, where the nacelle is rectangular and a flat inlet ramp replaces the dual cones just described. These allow good pressure recovery without spillover through the full range of speeds by matching their angle to the mach angle, but have problems with seals at high speed that is high pressure and temperature (like in a diesel engine). Inlet ramps allow for swept inlet cowls (F-22 Raptor, Joint Strike Fighter) to avoid shocks. They are sealed by viton or a metal sheet bend in direction of the higher pressure. At least one supersonic and one subsonic ramp is used, but for improved seal multiple supersonic ramps can be used. The boundary layer (something which the subsonic pitote inlet avoids by external compression) tends to separate and the smaller boundary layer of the ramp inlet is an advantage compared to the inlet cone. To avoid separation vortex generators are used, which mix the boundary layer with the free flow (or the boundary layer is sucked away through a porous surface, leading to drag). After the fan the hot slow intermixed air is passed by the engine, while the fast cold air is delivered to the engine.

After the engine the comparatively cold bypass air is used as an isolation between the engine exhaust and the walls. Again two ramps can be used to form a variable supersonic nozzle. Often a mirror-symmetric set-up is used with ramps on top and on the bottom.

There is one possibility for a stable, shockless supersonic to subsonic transition. This is used in transonic wings and would ultimately mean to send the air into a looping, forming a vortex: Then the final shock to subsonic speed is oblique with the subsonic region moving from the outside of the vortex to the inside.

Many supersonic aircraft (Eurofighter Typhoon,F-16) dispense with the conical centrebody and employ a simple pitot intake. A detached, strong normal shock appears directly in front of inlet at supersonic flight speeds, which leads to a poor pressure recovery.

Also NASA adds a gap through the whole compressor. Supersonic flow jumps over it by means of ramps, while subsonic flow is able to turn and exit through the gap. In this way a stall is easier to remove [1]. Also there are plans to measure the air in front of the inlet to detect turbulences and adjust the inlet in real-time.--wiki
 
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I guess this explains why Jf-17 is rated at 1.8.

Does anyone know the maximum tested speed?
 
. . . .
IT IS THE BEST THREAD ON PDF GOING ON.
IT GIVES INFO. OF ALMOST EVERY MODERN PLANE.

I HAVE A QUESTION.PLEASE HELP.
WE HAVE A PROBLEM IN DEVELOPING ENGINE OF LCA.
HERE T/W RATIO OF LCA IS 0.87(I SUPPOSE THIS IS THE RATIO BY KAVERI ENGINE)
ALSO MIRAGE-2000H HAS T/W RATIO 0.88. IAF INITIALLY INTRESTED IN THIS PLANE FOR MMRCA COMPETITION.:undecided:
DON'T YOU GUYS THINK IAF IS BIASED ABOUT OUR INDEGENOUS TECHNOLOGY AS THEY WANT LCA'S T/W RATIO >1 WHILE THEY WERE INTRESTED IN MIRAGE-2000H?:angry:

ALSO JF-17 HAS A LESS T/W RATIO THAN LCA.SO WHAT IS THE POINT IN IMPORTING ENGINES WHICH IS LEADING IN LATE INDUCTION OF LCA ? NOTE THAT LCA IS NOT GOING TO BE A FRONT-LINE FIGHTER IN IAF.
REGARDS......
 
Last edited:
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JF is 0.83 n LCA 0.87 ......not a hude difference...
1 or above 1 is the demand of modren AC's

and the munition lodaing would play a role in determining the actual ttw ratio in combat...
nice to know that the new GE engines have taken care of the LCA being overweight problem...
 
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Hi, I wanted to start of by saying this is a very informative and good thread.

Currently the LCA is powered by the F404 engine (19,000 lbf/85 kN), but it will be powered in the future by the stronger thrust F414 engine (22,000 lbf/98 kN). This will require a slight redesign of the fuselage, but it is a much more powerful engine. This should crank up the T/W ratio for the LCA.

I was under the impression the JF-17 had a T/W ratio close to 1, with the RD-93 engine. However, this might be in a completely clean configuration though, with no ordanance and/or fuel tanks. Please look at the statistics at the bottom of the attached link. Maybe the WS-13 (when completed?), combined with using composites, will increase the JF-17's T/W ratio. Thanks!

JF-17 Thunder - Wikipedia, the free encyclopedia
 
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I can see why people say the Su30 HAVE BRUTE POWER AND speed as well as TVC agility on the SU35 & SU30MKI would make it a beast of a plane.

Also very surprised that PAF are not bothered about the under power of the Thunder compared to both F16 & J10 and more importantly the current LCA (WHICH THE INDIANS ARE REAL BOTHERED ABOUT) and the mk2 tejas which will be close to 0.95 thust ie 10% better than mk1..
 
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JF-17's Thrust to weight ratio is disappointing,and that alone drops it from my "Cool list"...
 
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