J20 Stealth Fighter

vishnugupt

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AN/APG-77 can track 1 sqm target from a range of 150 km which is mounted on a F22. So, for those canards do the math.
Now do the math again. whole aircraft is much bigger then canards so F35 is much bigger then J-20"s canards so you can detect F35 from 400km now.
Surprisingly here you forget what 1 sqm target is made off? steel, titanium, carbon fibre?? and what will be the shape ??
Sweeping statement it can detect all at 150km regardless its composition and shape or caoting of RAM
I am again repeating here, Canards do increase RCS but there are ways where you can compensate/reduce its signatures
 

abhay rajput

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You must be disciplined student of your time that's why you are applying more idealistic theory then what could be achieved in practical. We can't achieve absolute stealth so we applies degree of stealth. Canards itself cause little setback to stealth which you overcome by applying RAM/design Now its actually Canards movement which is the problem for stealth so by restricting Canards movement (when you are aggressor or as per mission) can help.
it might not be as stealthy as F22 or F35 but it is certainly stealth enough to take on F35 or any present day aircraft. Once you are in visual range you know stealth or non stealth doesn't matter
There is no such thing as absolute stealth. Stealth itself doesn't means invisibility. Infact uhv/VHF radars can detect stealth aircrafts from hundreds of miles with very huge inaccuracies. Please stop day dreaming that j20 can take on f35. Do you know since how long Americans are making aircrafts.? J20 as I said nice aircraft but it's definitely not stealthy. Infact I would rate su57 better than j20 simply because Russians are still ahead of Chinese. Whatever stealth j20 has can be compensated with aesa radar on su57 . J20 is a problem for 4++ aircrafts like - f18 block 3 and f16 block 70. Forget about f35 , even rafale will give j20 hard times
 

Bhurki

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Because I am an engineer and I know what reduces stealth or not. :). A simple Google search will give you your answer. Chinese wanted aircraft with maneuverability that's why canards was added in the first place. A proper stealthy aircraft is not stealthy if it has canards. Example - f35, f22. In front of aesa radars it's doesn't make much difference. Moreover it's not only shape reduces RCS but also materials which the plane is made of.
I think you didnt read this post.

Here's the concept that was put up by Northrop grumman to replace F14 tomcat with a stealth fighter.
The NATF-23 was a modified F23a which had canards, so i'm not sure if canards trade all that much of stealth characteristic to be unviable for a LO aircraft.
View attachment 47363

Moreover, a lot of designs considered for the underlying ATF project that required LO as a key performance factor had canards
View attachment 47364
 

vishnugupt

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There is no such thing as absolute stealth. Stealth itself doesn't means invisibility. Infact uhv/VHF radars can detect stealth aircrafts from hundreds of miles with very huge inaccuracies. Please stop day dreaming that j20 can take on f35. Do you know since how long Americans are making aircrafts.? J20 as I said nice aircraft but it's definitely not stealthy. Infact I would rate su57 better than j20 simply because Russians are still ahead of Chinese. Whatever stealth j20 has can be compensated with aesa radar on su57 . J20 is a problem for 4++ aircrafts like - f18 block 3 and f16 block 70. Forget about f35 , even rafale will give j20 hard times
I respect your emotions and i could agree that Su 57 can be better than J-20 but rest was not true at all.
 

Steven Rogers

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Now do the math again. whole aircraft is much bigger then canards so F35 is much bigger then J-20"s canards so you can detect F35 from 400km now.
Surprisingly here you forget what 1 sqm target is made off? steel, titanium, carbon fibre?? and what will be the shape ??
Sweeping statement it can detect all at 150km regardless its composition and shape or caoting of RAM
I am again repeating here, Canards do increase RCS but there are ways where you can compensate/reduce its signatures
Parts which don't align with the main wing/body of the stealth aircraft contributes in the RCS,if you see other stealth aircraft,their whole body and wings are aligned so as to minimise the reflecting point,Su47 has one this big disadvantage,her wing was not at all aligned with the body,this is also the reason why designers struggle to keep sensors internal,an IRST mounted on the front also contributes RCS and which can be many times bigger from a certain position than the whole aircraft from that position where the enemy radar waves incident. J20's canards are still not aligned to the wings that means they will still reflect(as they will become useless in creating lift and pitch maneuver if they are placed with the wings)how much measure they could apply the RCS won't gonna be as small as it is with out the canards..No amount of RAM/RAS could help if a peak is shining excluded of the main rcs,so that's how J20's RCS can't be the same with the canards as it is without...
 

abhay rajput

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I think you didnt read this post.
There are many concepts/prototypes that never works . Probably that's why the project was closed. And when we see f35 with canards then we will talk about the canards design in ATF . Stealth doesn't go well with canards. F35 sacrifice a lot for stealth which you see in su57/j20. Canards are a thing when maneuverability is the primary requirement Not stealth. The only 2 operational stealth fighter jets doesn't seems to have canards . So either you are wrong or those engineers share my concerns.
 

Blue Water Navy

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Now do the math again. whole aircraft is much bigger then canards so F35 is much bigger then J-20"s canards so you can detect F35 from 400km now.
Surprisingly here you forget what 1 sqm target is made off? steel, titanium, carbon fibre?? and what will be the shape ??
Sweeping statement it can detect all at 150km regardless its composition and shape or caoting of RAM
I am again repeating here, Canards do increase RCS but there are ways where you can compensate/reduce its signatures
For the sake of argument even if we do consider the fact that the canards are fully made of RAM. Still they are out of the alignment which is extremely important for a stealth plane. And being out of the proportion means no matter how good RAM is, still it will reflect radar waves.
 

vishnugupt

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For the sake of argument even if we do consider the fact that the canards are fully made of RAM. Still they are out of the alignment which is extremely important for a stealth plane. And being out of the proportion means no matter how good RAM is, still it will reflect radar waves.
Its like You are fear mongering against Canards. Tail, wings, turbines, Underbelly (f35) and other movable surface do not reflect radar but only Canards do. RAM works everywhere but not over canards. its same for all
 

Ajax01

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Its like You are fear mongering against Canards. Tail, wings, turbines, Underbelly (f35) and other movable surface do not reflect radar but only Canards do. RAM works everywhere but not over canards. its same for all
Its less about moving than its about blending. They certainly reflect when they move as do other parts which you mentioned. But canards are large that dont blend with the wingbody. That reflects both primary and secondary radar waves. You cant have a blended canard and still retain the extra aerodynamic advantage of the canard. Besides this has been discussed a lot in the AMCA thread where Assassin gave a US research document on contribution to RCS in front and sides by various parts might want to have a look at it.
 

vishnugupt

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Its less about moving than its about blending. They certainly reflect when they move as do other parts which you mentioned. But canards are large that dont blend with the wingbody. That reflects both primary and secondary radar waves. You cant have a blended canard and still retain the extra aerodynamic advantage of the canard. Besides this has been discussed a lot in the AMCA thread where Assassin gave a US research document on contribution to RCS in front and sides by various parts might want to have a look at it.
I have never said Canards does not increase RCS but having it in J20 also doesn't make it 4th generation level stealth aircraft.
 

MiG-29SMT

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I have never said Canards does not increase RCS but having it in J20 also doesn't make it 4th generation level stealth aircraft.
canards are not recommended for stealth aircraft for a single reason what is good for aerodynamics is not good for stealth all the time.

The first aerodynamic need of a canard is vertical position, a canard ideally positioned should be above wing level, example Rafale
1590362628705.png


On Eurofighter the canard has anhedral position so the canard reduces drag and it is position far from the wing.
1590362909017.png


The ideal close coupled canard should be above wing to give the best compromise of vortices inducing lift at high AoA over the wing.


However F-15 like J-20 have high position wing so the canard can not be above the wing so it has dihedral in order to put at least the canard tips outboard parts above wing level, this is not as good as Rafale but ensures a better lift ratio
1590364017636.png


1590362965390.png


However this breaks planform alignment on J-20, thus the J-20 has too much contradictions in the canard position.

ideally the back tail is better because frontally is hidden by the wing, it does not kill lift of the wing by downwash and has no need for dihedral as the canard.

conclusion

J-20 used the F-15 design solution by adding dihedral to increase vertical distance between wing and canard but broke stealth.


backtails and foretails do have a problem and it is they need to deflect, solution use thrust vectoring to reduce deflection and use no tail at all.


Practically the best for stealth is no tail at all, later it is backtail like F-22 and worse for stealth is canard


1590363359202.png


The coplanar canard has aerodynamic disadvantages such a very low vertical position reducing lift at high AoA with respect high canard. It generates drag at low AoA reducing wing lift and pushes the wing aft viewing from the longitudinal axis, a canard like the one on rafale allows for the wing to be position forward since the canard is above the wing; X-36 has coplanar canard

On the Eurofighter the canard was moved ahead on the aircraft nose but it was not the best position compared to aircraft like Gripen or Rafale.
1590363713385.png


On Lavi the canard is above the wing in fact the canard trailing edge is above the wing leading edge, so its wing was able to be positioned forward allowing for a wing with higher longitudinal instability enjoying an ideal canard wing position.

The J-20 was designed with very little innovation and basically to many contradictions
 

MiG-29SMT

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1590364536495.png

on the IAI lavi the canard allows the wing to be positioned farther ahead allowing for higher statically unstability

1590364555284.png


on J-20 the canard pushes the wing father aft reducing statically unstability and making it a more statically stable aircraft and increasing the need for a bigger canard
1590364762457.png



In fact the J-20 is closer to the Viggen AJ-37 than to JAS-39 gripen in wing position
1590364840531.png
 

MiG-29SMT

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1590381640740.png


The J-20 also produces low pressure vortices to increase lift ahead of the wing and center of gravity, this is not unique since even MiG-29 or X-31 can do it
1590381951074.png



1590381786330.png



Despite proponents of stealth aircraft say these vortex systems increase lift, stealth aircraft are heavier

let us see

Weight empty:8.57 t13.2 t

F-16 weighs almost 5 tones less than F-35; and F-35 weighs as much as F-15 and more than MiG-29 and Eurofighter or Rafale, stealth aircraft when increase in wing Area does not mean lower wing loading thus J-20 and F-22 need Thrust vectoring to really enhance agility due to a heavier fuselage



 

MiG-29SMT

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1590385265810.png


On the radome MiG-29 has two plates working as vortex generators, J-20 uses the Chines to do that

1590385424368.png

Eurofighter has also vortex generators on the fuselage bellow the canopy and behind the canards



The fact Eurofighter shows F-22 kills shows J-20 will struggle even more without thrust vectoring against like Eurofighter or Rafale in close combat


J-20 added a small LEX ala Rafale on the wing
 

MiG-29SMT

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1590386073922.png



as basics physics show, as the angles gets close to 0, the force projection reduces, in few works a V tail or a canted vertical fin limit rudder and tailplane effectiveness.


On F-22 and Su-57 their tailplanes give horizontal uncompromised force effect.

The reduced effect as rudder, due to canting the vertical tails of stealth aircraft, forces canting to angles higher than 45 degrees and closer to 90 degrees

1590386452351.png


On J-20 the canting and small area of the dorsal vertical fins forced ventral vertical fins to be fitted on J-20, also a long fuselage blanketing the tails reduced their effectiveness.

ventral fins increased radar waves diffraction on other elements of the aircraft

1590386620449.png


Thus other aircraft did not use ventral fins nor canards, the Chinese copied Rafale basic wing and MiG-1.44 basic configuration with F-35 basic forebody fuselage.


diffraction can deteriorate RCS from some angles and the back part of J-20 is not the best in terms of stealth
 

MiG-29SMT

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Bottom line is J20 may be a great plane in terms of fighter jet. But it's just not stealthy.
is not that great, it is a more difficult aircraft to beat, harder than J-11 due to some degree of stealth, but is not that great, of course is one of the best 10 fighter aircraft, probably at least between F-35 and Su-57.


Its aerodynamics are "modern" but if detected Rafale is a better machine, Eurofighter the same, they have lower wing loading, better aerodynamics as pure fighters.


In my opinion Tempest is far far better for stealth
1590387978041.png


it is truly revolutionary and Su-57 is far more agile and innovative.

The Chinese made a good aircraft, but it is highly hyped, i hope better sensors beat all these crap of stealth propaganda
1590388120044.png


I hope Rafale beats that batman 1950s looking J-20
 

Blue Water Navy

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is not that great, it is a more difficult aircraft to beat, harder than J-11 due to some degree of stealth, but is not that great, of course is one of the best 10 fighter aircraft, probably at least between F-35 and Su-57.


Its aerodynamics are "modern" but if detected Rafale is a better machine, Eurofighter the same, they have lower wing loading, better aerodynamics as pure fighters.


In my opinion Tempest is far far better for stealth
View attachment 48636

it is truly revolutionary and Su-57 is far more agile and innovative.

The Chinese made a good aircraft, but it is highly hyped, i hope better sensors beat all these crap of stealth propaganda
View attachment 48637

I hope Rafale beats that batman 1950s looking J-20
I am not an aviation expert. And its my sole opinion. J20 aircraft's body looks way bigger.
 

J20!

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Thus other aircraft did not use ventral fins nor canards, the Chinese copied Rafale basic wing and MiG-1.44 basic configuration with F-35 basic forebody fuselage.


diffraction can deteriorate RCS from some angles and the back part of J-20 is not the best in terms of stealth
This discussion has been had repeatedly on this forum since the first J20 prototype surfaced in 2011. My main point is always this: An aircraft's configuration is defined by the performance parameters set for it.

The Rafale, Mig 1.44 and F35 all had different performance requirements defined for them. Two of 'em are medium weight fighters and the other is a heavy weight fighter that was never produced aside from a prototype or two. How could any aerospace engineer simply lift or "copy" design aspects from each, mash them together into some kind of Frankenstein airframe and hope it flies? That's not really realistic from an engineering standpoint.

I've enjoyed your posts since you've joined mate. However. There are some serious flaws in your analysis though. You're not really taking into consideration the J20's performance requirements. All aircraft are compromises dictated by the performance parameters set at the beginning of each programme.

There isn't much open source data on the J20 programme; however a goldmine of data on the aircraft's aerodynamic layout and the reasoning behind it can be found in the the paper published by the late Song Wencong. He was the chief designer for the J10 programme and the mentor to Yang Wei, the Chief desiner for the J20 programme.

Here is a link to the paper, titled "Aerodynamic configuration study of a small aspect ratio, high lift aircraft,"

https://wenku.baidu.com/view/1aae34a6f524ccbff12184b3.html

I posted a translation by SiegeCrossbow from SDF on this thread 8 years ago

This paper analyzes the main design conflicts of the future fighter's stealth, high maneuverability, and supercruise characteristics while proposing specific design solutions for trans-sonic lift to drag characteristics, low speed high AOA characteristics, and supersonic drag characteristics. The author believes that in-depth study of fluid dynamics, exploration of the full practical potential of current aerodynamic designs, development of new design concepts, employment of corresponding systematic and control measures, and necessary compromise among numerous design proposals will allow us to achieve our design goals.

1. Introduction:
The future fighter, aside from satisfying low and mid-altitude maneuverability performance of modern 4th gen. fighters, must have the capability to supercruise and perform unconventional maneuvers such as poststall maneuvers. As a result, the aerodynamic configuration of the future fighter must not only satisfy the design constraints of RCS reduction but also lower supersonic drag, improve lift characteristics, and improve stability and controllability under high AOA conditions whilel accounting for trans-sonic lift to drag characteristics. The high number of design requirements provide new challenges to the aerodynamic layout. The design must employ new aerodynamic concepts and approaches, take necessary systematic and control measures, and compromise amongst the numerous design points in order to obtain the necessary design solution.

2. Main design conflicts:

The design requirement for stealth brings new difficulties to the aerodynamic design. Frontal stealth capability imposes new restrictions on both the sweep angle of the leading edge and air intake configuration. Lateral stealth requires the proper alignment of the aircraft's cross sectional shaping and the vertical stabilisor configuration. These restrictions and requirements must be considered during the earliest phase of designing the aerodynamic configuration.

Trans-sonic lift to drag ratio and supersonic drag are traditional design conflicts. Modern Fourth gen. fighters successfully solved this dilemma by relaxing aircraft stability and employing wing bending mechanisms. Future fighters, however, have stricter requirements for supersonic drag characteristics. At the same time, conventional design maximizing low speed lift characteristics contradicts the pursuit for lower supersonic drag. Since current aerodynamic measures don't offer satisfactory solutions to these conflicts the design team must explore new design paths.

Post stall maneuvers require the aircraft to have good controllability and stability. After the plane enters the post stall region, however, the decrease in stability and control efficiency of conventional rudder surfaces become irrecoverable. One must carefully design an aircraft to enable sustained controllability at high AOA. Although it is possible to solve the problem of post-stall controllability through the use of thrust vectoring nozzles, the aerodynamic configuration itself must provide enough pitch down control capability to guarantee the aircraft to safely recover from post-stall AOA should the thrust vectoring mechanism malfunction. As a result, it is vitally important to study unconventional aerodynamic control mechanisms for high AOA flights.

3. Trans-sonic lift to drag characteristics

Trans-sonic lift to drag characteristics determine an aircraft's maximum range and sustained turn capability. The future fighter's demands for these characteristics will exceed those of modern 4th gen. fighters. Modern fighters employ the strategies of relaxing longitudinal stability, adapting wings with medium sweep and aspect ratio, twisting the wing, and adding wing-bending mechanisms to greatly improve the lift-to-drag characteristics. Due to the future fighter's requirement for supercruise, supersonic drag characteristic is a critical design point and designers must avoid using aerodynamic measures that may potentially increase supersonic drag. As a result, the wing shape and wing twist coefficient can't be selected based on trans-sonic lift to drag characteristics alone. It is necessary to employ wing-bending mechanisms but its aerodynamic efficiency has already been exhausted.

Further decreasing the aircraft's longitudinal relaxed stability is an excellent solution to this problem. Diagram 1 shows how the variation tendency of trim-drag coefficients against longitudinal instability of a conventional fighter aircraft in a tight, sustained turn. Modern fighters fix their longitudinal instability at 3% the average aerodynamic chord length. The future fighter could enjoy a significant improvement in lift-to-drag if the longitudinal instability could be increased to a magnitude of around 10%.

Further relaxing the longitudinal instability could not only enhance trans-sonic lift to drag characteristics but also improve super sonic lift to drag capabilities, increase take-off and landing characteristics, and maximize low-speed lift characteristics. This is akin to killing three birds with a single stone. Yet a increase in longitudinal instability will also increase the burden on high AOA pitch down control and subsequently increase flight control complexities. As a result the design team should not "over-relax" the longitudinal stability.

4. Low speed high AOA characteristics

4.1 Lift-body LERX Canard configuration

Advanced modern fighters utilized research on detached vortices from the 1960s and 70s to gain excellent lift characteristics with their max lift coefficient peaking at around 1.6. They either employ conventional LERX configuration or canard configuration to accomplish this. The future fighter has higher requirements for max lift coefficient and the situation is further complicated by the fact that the use of twin vertical stabilizers is detrimental to lift (see figure 4.2). As a result the design team must raise the max lift coefficient to a whole new level. It will be difficult to realize this goal simply employing conventional LERX configuration or canard configuration.

It is beneficial to choose canard configuration from a high AOA pitch down control stand point(see figure 4.3). Blending lift body LERX characteristics with the conventional canard configuration to form a "lift body LERX canard configuration" will greatly enhance the max lift characteristics. Exploration of the lift body LERX canard configuration will solve three important technical issues. The first problem is the aerodynamic coupling between canards and medium sweep, medium aspect ratio wings. The second problem is the coupling between the canards, the LERX, and detached vortices generated by the wings. The third problem concerns the gains and losses of employing body lift on a canard configuration aircraft.

Traditionally close coupled canard configuration aircraft utilize constructive coupling between the canards and detached wing vortices to enhance the max lift coefficient. Only wings with large back-sweep angle and small aspect ratio could generate detached vortices that are powerful enough for the task. As a result most modern canard configuration fighter aircraft have a leading edge backsweep angle of around 55 degrees and an aspect ratio of around 2.5. For these aircraft, the canards could generate around a 3 to 4 times increase in max lift coefficient with respect to their wing areas. Ideally we hope to employ wings with medium leading edge backsweep angle and medium aspect ratio in order to improve lift characteristics over the entire AOA range. This wing shape, however, could not effectively generate leading edge detached vortices. Could the canards still attain their original lift enhancing effects? The answer is yes according to wind-tunnel tests. As the slope of the aircraft's lift curve increases, the lift enhancing capabilities of the canards are the same as those on traditional close coupled canard configuration aircraft (see figure 2). The key influence on aerodynamic coupling between the canards and medium back-sweep, medium aspect ratio wings should not be interference among detached vortices. Preliminary studies indicate that down-wash on the wings generated by the canards play a far greater role.

It is a well known fact that LERX could improve the max lift characteristics on medium back sweep, medium aspect ratio wings. In order to obtain even better lift characteristics, we should consider using both canards and LERX to create a canard-LERX configuration. Study shows that employing both canards and LERX not only retain the lift enhancing effects of the two mechanisms when they are used separately but also help achieve higher lift-coefficient (see figure 3). This means that there is beneficial coupling among the canards, LERX, and the wings.

Blended wing lift body configurations could utilize lift generated by the aircraft's body to increase internal load and enhance stealth characteristics at relatively low costs to drag. Lift-body configurations have been adapted by many conventional configuration aircraft and achieved excellent results. Yet until now now canard configuration fighter utilized lift-body configuration. This isn't because aerodynamic experts failed to realize the tremendous advantage of the lift body configuration but the result of a canard configuration aircraft's need to place the canards above the aircraft's wings. It is difficult for lift-body configuration aircraft to satisfy this demand. Our experimental results indicate that although the canards on a canard-LERX configuration aircraft employing lift-body suffered a decrease in lift-enhancing effects, the overal lift characteristic of the aircraft was still superior to that of a canard-LERX aircraft not employing lift-body (see figure 4). Figure 5 shows the vortex generation on the wings and body of a lift-body canard configuration aircraft observed using laser scanning. It demonstrates that planes employing this configuration derive excellent lift characteristics not only from coupling among the canards, LERX, and detached vortices but beneficial interaction between the left and right detached vortices. The latter contribute to significant lift on the body of the plane and greatly contributed to the enhancement of lift characteristics. Figure 5 also indicates that the detached vortices primarily contribute to lift on the body and inner portions of the wings. Consequently, most of the lift produced under high AOA conditions are generated in the corresponding areas.

4.2 Canted vertical stabilizers

Vertical stabilizer design is an important consideration when it comes to future fighter configuration design. From a lateral stealth stand point, the vertical stabilizers should cant inward or outward to reflect incoming radar waves in other directions. The future fighter must be long and thin to accommodate for supercruise and as a result, the space between the vertical stabilizers couldn't be too wide. The twin stabilizers should cant outward in order to decrease destructive interference between the vertical stabilizers. Since the future fighter will fully utilize detached vortices to improve max lift coefficient, forward vortices will generate relatively high outward facing velocity airflow on the vertical stabilizers. Figure 6 shows the calculation results of a type of lift body LERX canard configuration fighter using n-s time average function. It indicates the limiting flow rate on the aircraft's rear once the vertical stabilizers are removed. The results indicate that the regional side slip angle at the location where vertical stabilizers are usually installed reaches around 15 degrees when the AOA is 24 degrees and the side slip angle is 0 degrees. If the back-sweep angles of the vertical stabilizers are sufficiently large, the enormous regional side slip angles could generate leading edge shed vortices on the external faces of the stabilizers and form low pressure regions. Regional sideslip angles will also increase the static pressure on the inner portions of the vertical stabilizers. As a result, the vertical stabilizers will become highly efficient lateral force surfaces which direct the lateral forces outwards. The lateral forces are projected in the direction of lift, with respect to the outward canting vertical stabilizers, and generate negative lift. Negative lift acting on the vertical stabilizers and rear body will both contribute to the undesirable pitch up torque. The high pressure region between the vertical stabilizers will form adverse pressure gradients on the body of the plane and negatively impact the stability of leading edge detached vortices. Since the vertical stabilizers are already highly loaded at 0 degree side slip angle, the yaw/roll stabilization efficiency of the vertical stabilizers will be decreased.

The negative impacts of vertical stabilizers as described above are closely associated with lift-enhancing measures and are, as a result, difficult to root out. Yet adjustment of the vertical stabilizer's area, position, cant angle, and placement angle and improvement measures such as making slots on the rear body can minimize the negative impact of the vertical stabilizers. Ordinarily, the max lift reduction coefficient generated by the vertical stabilizers could reach around 0.4. We've managed to successfully lower it below 0.1 through experimentation.

Decreasing the vertical stabilizers' area or even employing tailless configuration are directions worth studying. Their significance not only include improving low speed high AOA performance but also help improve stealth characteristics, lower drag within the entire flight envelope, decrease weight, and reduce cost. Implementing the tailless configuration requires the tackling of three major technical difficulties: replacing the stabilizers with another yaw control mechanism, installing sensitive and reliable side slip sensors, and implementing new flight control technology. As of now, these difficulties are being tackled one at a time. Relatively speaking, decreasing vertical stabilizers' area and relaxing static yaw stability are more realistic options. Generally speaking, the relative size of the vertical stabilizers is around 20% to 25%. In or studies, utilizing all moving vertical stabilizers with 10% to 13% could still maintain basic yaw stability while retaining the vertical stabilizers' function as yaw control mechanisms.

4.3 Aerodynamic control mechanisms

The requirement for high AOA pitch down control capability is closely related to the longitudinal static instability requirement. The greater the longitudinal static instability, the higher the demands for pitch down control capabilities. As described in chapter 3, the future fighter will hopefully increase its longitudinal static instability to around 10% its average aerodynamic chord length to enhance the trim's lift to drag and lift characteristics. As a result there should be a corresponding improvement in the pitch down control capability. We can categorize two types of control surfaces based on the relative position of the pitch control surfaces with respect to the aircraft's center of mass: positive load pitch down control surface and negative pitch down control surface. Control surfaces placed behind the center of mass, including the vertical stabilizers and trailing edge flaps, generate pitch down control torque by increasing lift. They are considered positive load control surfaces. Control surfaces placed in front of the center of mass, like the canards, are negative load control surfaces. Since the main wing's ability to generate lift tends to saturate under high AOA conditions, the positive load control surfaces' pitch down control capabilities tend to saturate under high AOA as well. Therefore it will be wise to employ negative load control surfaces for pitch down control under high AOA conditions. Figure 7 compares the pitch down control capabilities of the canards and horizontal stabilizers. From the high AOA pitch down control stand point, it will be wise to use canards on the future fighter. Canards on close coupled canard configuration aircraft have relative short lever arms. Employing the LERX canard configuration can increase the canards' lever arms while retaining the benefits of positive canard coupling. Considering the overall lift enhancement effect and pitch down control capabilities, we can set the canards' maximum relative area to around 15% and the maximum canard deflection to 90 degrees.

Yaw control ability under high AOA is another noteworthy problem. Control surface efficiency deteriorate rapidly with an increase in AOA for tailless and even conventional configuration fighters. Therefore it is necessary to consider control mechanisms other than conventional control surfaces. Studies on differential LERX, drag rudder, differential wingtips, and all moving vertical stabilizers indicate that differential LERX and drag maintained relatively high yaw control efficiency under high AOA conditions (see figure 8).

5. Supersonic drag characteristics

The key to lowering supersonic drag is to minimize the max cross sectional area of the aircraft.Accomplishing this requires excellent high level design skills. Placement of the engines, engine intakes, landing gears, cartridge receiver, weapons bay, and main structural support all influence the max cross sectional area of the aircraft. Attention to details and careful considerations are necessary to design decision making.

Wingshape has profound effects on supersonic drag characteristics. Small aspect ratio wings with large backsweep have low supersonic drag but are detrimental to low speed lift and trans-sonic lift to drag characteristics. If we select the liftbody LERX canard configuration we can expect to retain relatively good lift to drag characteristics while using medium backsweep wings. Under high AOA conditions, liftbody LERX canard configuration aircraft concentrate lift on the body and inner portions of the wings so moderately lowering the aspect ratio will not only not lower the max lift coefficient but raise it (see figure 10). Because of this, employing small aspect ratio wings on a lift-body LERX canard configuration aircraft will settle the conflicts among supersonic drag characteristics, low speed lift characteristics, and trans-sonic drag characteristics.

6. Air Intake design

Air intakes are one of three major sources of radar scattering. In order to lower intake radar reflection area, the design team must place a series of limitations on intake design due to stealth considerations. These limitations will significantly influence intake aerodynamic design.

Caret intakes have oblique intake openings and fixed intake ramps and could effectively lower radar cross section and structural weight. The future fighter may implement this technology. Preliminary studies indicate that when compared with conventional adjustable intakes, Caret intakes' total pressure recovery coefficient surpasses its conventional counterpart in supersonic and trans-sonic regimes and is only slightly lower in the low-subsonic regime. It also offers excellent total pressure distortion performances. Radar absorbing deflectors minimize the air-intake's radar reflection and could significantly improve its stealth characteristics. Aerodynamically speaking, the radar absorbing deflectors would slightly decrease the overall pressure recovery and flow coefficients but have no ill-effects on static or dynamic distortion coefficients.

7. A comprehensive study of a design example

The design team made a future fighter proposal based on the points raised by this article. The proposal employs lift-body LERX canard configuration. It is unstable in both the lateral and yaw directions. The proposal employs small aspect ratio wings with medium back sweep angle, relatively large dihedral canards, all moving vertical stabilizers far smaller than those on conventional fighter aircraft, and S-shaped belly intakes. According to our assessment, the proposed aircraft will have excellent supersonic drag characteristics, high AOA lift characteristics, high AOA stability and controllability, and excellent stealth characteristics.

8. Conclusion

The aerodynamic design for the future fighter, compared with that of advanced modern fighters, will require more design features and subsequently pose greater challenges. Only in-depth study of fluid dynamics, exploration of the full practical potential of current aerodynamic designs, development of new design concepts, employment of corresponding systematic and control measures, and necessary compromise among numerous design proposals will allow us to achieve our design goals.

The original text is in Chinese, this is the only English text I could find.
 

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