Learning objectives

1. Understand the concept of energy
2. Understand the concept of lift vector
3. Understand the concept of the corner speed (turn radius vs turn rate)
4. Know the different pursuit curves. (Lead, lag and pure pursuit)
5. know the high and low yoyo maneuvers
6. know the difference between one circle and two circles turns and when to employ them
7. know the flat and rolling scissors
8. understand the concept of flying the elbow
9. understand the concept of the egg (god's G)
10. know how to use the dogfight mode, the HMCS and the radar modes linked to them
11. know the brevity words usualy used in dogfight

Learning files

• Shaw's Fighter Combat Tactics and Maneuvering
• How to be a Good Stick

Geometry of Air Combat

Positional Geometry

Angle-off, range and aspect angle are terms used in BFM discussions to describe the relative advantage or disadvantage that one aircraft has in realtion to another

Angle-off

Angle-off is the difference measured in degrees, between your heading and the bandit's. This angle provides information about the relative fuselage alignment between the pilot's jet and the bandit's.
For example, if the angle-off between you and a bandit were 0°, you would be on a parallel heading with the bandit and the two fuselages would be aligned.

Aspect Angle

Aspect angle is the number of degrees measured from the tail of the target to your aircraft. Aspect angle is important because it indicates how far away your aircraft is from the target's 6 o'clock position.
Aspect angle has nothing to do with your heading. Note that the aspect angle stays the same regardless of wich way your aircraft is heading (see figure)
Along with a measure in degrees from the target's tail aspect angles are also described either right or left aspect.
Aspect angle is important because, if you know the aspect angle and range to the target you then know his lateral displacement or turning room from the target and lateral displacement is very important in BFM.

Attack Geometry

Attack geometry describes the path that the offensive fighter takes as he converges on the bandit. When you start an attack on the bandit, there are three distinct path or pursuit courses you can follow. These pursuit courses are lag pursuit, pure pursuit and lead pursuit.
If you are pointing your aircraft behind the bandit, you are in lag pursuit. if you are pointing directly at the bandit, you are in pure pursuit. If you are pointing in front of the bandit, you are in lead pursuit.

Lag Pursuit

Lag pursuit is used primarly on the approach to the bandit. Lag is also used any time an attacking fighter maneuvers out of plane (not in the same plane of motion as the fighter under attack)
You must have the ability to out-turn the bandit in order to fly lag pursuit for any length of time. The reason ?
In order to shoot a missile or the gun at the ennemy, you must pull your nose out of lag. If the bandit can turn at a higher rate, he can keep your nose stuck in lag and keep you from shooting him.

Pure Pursuit

Pure pursuit is used to shoot missiles at the enemy. Flying a pure pursuit course all the way into the bandit will lead to an overshoot.
For this reason, you should only point at the bandit when you are going to shoot.

Lead Pursuit

Lead pursuit is used to close on the bandit and is also used for gun shots. Flying a lead pursuit course if the fatest way to get to the bandit because you cut him off in the sky. The problem with establishing a lead pursuit course too early is that you will overshoot the bandit when you get in close unless you have a significant turn rate advantage.
If you're fighting a similar aircraft, such as the Mig29, you will not normally be able to stay in lead and will be forced into an overshoot.
It is important however to establish lead pursuit at the proper time in the fight because it is the only way that you can get into the gun envelope.

Offensive BFM

Power for position

Power for position is a concept that is an integral part of BFM. Fighters have two types of energy : Kinetic and potential.

• Kinetic energy is simply the velocity or speed at which the jet is traveling.
  
• Potential energy is directly related to aircraft altitude. If a jet is at high altitude, its potential energy is high. If the same jet is flying at low altitude, its potential energy is low.
  

Always remember that you can trade altitude (potential energy) for speed. Likewise you can convert aircraft speed back into altitude or potential energy.

You can also exchange energy for nose position. Anytime you maneuver or turn a fighter, it "costs" energy. When you turn in a jet at high G, you "spend" or lose energy. That's the bad news. The good news is that the defensive fighter also gives up energy to turn and defend himself.

Turn radius and Turn rate

The first two characteristics of turns are turn radius and turn rate.

Turn radius is simply a measure of how tight your jet is turning. If you are looking down on the aircraft as it turns, the turn radius is the distance from the center of your turn circle to the aircraft.

You have to realize that velocity is squared in the turn radius equation, meaning that turn radius will grow exponentially based on velocity. The equation also includes aircraft Gs. The more Gs that you pull, the tighter the turn.

Still velocity is sqared, so airspeed has a greater effect on turn radius than G.

Turn rate is the second important factor for turning the jet. Turn rate indicates how fast the aircraft moves around the turn radius or circle we just talked about.

It is also described as how fast an aircraft can change is nose position. Turn rate is measured in degrees per second and is also dependant on Gs and airspeed.

The higher the G in the above equation, the faster the turn rate. Velocity still remains an important factor. Notice that G is divided by velocity. If G remains at maximum, a higher velocity will cause turn rate to decrease. The reverse is true: a lower velocity will yield a higher turn rate.

Corner Velocity

You may think that slowing down to minimum airspeed and pulling as hard as you can is the best course of action in order to achieve a high turn rate. Not so fast ...
There is a relationship between airspeed and Gs. at lower airspeeds, you have less G available. Less lift is produced by the wings of your aircraft at slower speed and as a result there is less force available to turn the aircraft. If you get going really fast (above Mach 1) you also lose G availability.
For every fighter there is an optimum airspeed for achieving the hightest turn rate. The airspeed where the jet has the quickest turn rate with the smaller turn radius is called corner speed.
In most modern fighters it is between 400 to 500 kts. The F16 has a corner velocity of about 450 kt (CAS)

The airspeed of a jet can be controlled by the pilot in the following four ways:

• Throttle position
• Drag devices (speedbrakes)
• Nose position in relation to the horizon
• Aircraft G

Don't forget G force causes airspeed to bleed off. No modern fighter flying at medium altitude can stay at corner velocity while pulling max Gs for long. As you pull Gs, you will get slower. It is important however to start maneuvering close to corner velocity because the first turn you make is usually the most important in the fight.

Fighter pilots should think in terms of both turn rate and turn radius. A fighter with a superior turn rate can outmaneuver a fighter that as a poor turn rate but a tighter turn radius.
Fighter pilots have a simple two-words saying: "Rate kills". What this means is that the ability to move (or rate) your nose is the primary means of employing weapons (which is what offensive BFM is all about)
A Bandit may have a tight turn circle but if you can rate your nose on him and shoot the fight is over.

Let's have a look at the F16 turn performances diagram on the right.

• At 0.6 Mach, the jet can pull 9 Gs and turn at a rate of 24° per seconde. At 0.6 Mach, the jet can also turn in a radius of 1 500 feet. This is the best (tightest) radius the jet can achieve at the highest turn rate possible.
  
• At 0.4 Mach, the jet can turn with a radius of 1 500 feet but the turn rate falls from 24° to 16 ° a second. Just to put this figure in perspective, a 2° per second turn rate advantage will allow you to dominate an adversary !!!

Vertical turns

Turning rooms

Defensive BFM

Bandit outside your turn circle

Bandit inside your turn circle

overshoots

Guns Defense

Energy

• 0.55 Mach is around 366 knots
• Don’t pull back hard on the stick and unnecessarily bleed off energy

Video Examples

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