Fighter gun effectiveness

.30 cal HEI

13.2 mm HEI


Aircraft Weapons  -  Guns

Article

     
     
 

MODERN GUN FIGHTER EFFECTIVENESS

 
     
  Source : http://www.quarryhs.co.uk/modern_fighter_gun_effectiveness.htm
(minor alteration to the tables layout, not their content)
 
 

©Anthony G. Williams and Emmanuel Gustin

A version of this article (updated 3 April 2009) first appeared in the October 2004 issue of Air International.
It is based on material from :

Flying Guns - The Modern Era : Development of Aircraft Guns, Ammunitions and Installations since 1945

This is an attempt to compare the cartridge destructiveness, gun power and gun efficiency of post-WW2 fighter guns.  Fighter armament fits in three key periods are also considered.

Cartridge Destructiveness

There are two types of energy that may be transmitted to the target; kinetic and chemical. The kinetic energy is a function of the projectile weight and the velocity with which it hits the target. This velocity in turn depends on three factors: The muzzle velocity, the ballistic properties of the projectile, and the distance to the target. There are therefore two fixed elements in calculating the destructiveness of a projectile, its weight and chemical (high explosive or incendiary) content, and one variable element, its velocity. The key issue is the relationship between these three factors.

A high muzzle velocity will provide a short flight time, which is advantageous in increasing the hit probability and extending the effective range, and will also improve the penetration of AP rounds. However, it might not add much to destructiveness, as unless an AP projectile hits armour plate (and not much of the volume of an aircraft is protected by this), a higher velocity just ensures that a neater hole is punched through the aircraft; the extra kinetic energy is wasted. Also, if the projectile is primarily relying on HE blast or incendiary effect, the velocity with which it strikes the target is almost immaterial. Provided that it hits with sufficient force to penetrate the skin and activate the fuze, the damage inflicted will remain constant. In contrast, AP projectiles lose effectiveness with increasing distance.

It is sometimes argued that a projectile with a high muzzle velocity and a good ballistic shape (which reduces the rate at which the initial velocity is lost) provides a longer effective range. To some extent this is true, but the greatest limitation on range in air fighting remains the difficulty in hitting the target. The problem of hitting a target moving in three dimensions from another also moving in three dimensions (and probably at a different speed and on a different heading) requires a complex calculation of range, heading and relative speed, while bearing in mind the flight time and trajectory of the projectiles. Today, such a problem can easily be solved by a ballistic computer linked to a radar or laser rangefinder, but in the early years of this period the technical aids were far less sophisticated. And this was without considering the effects of air turbulence, G-forces when manoeuvring, and the stress of combat.

For all of these reasons muzzle energy (one half of the projectile weight multiplied by the square of the velocity) has not been used to calculate kinetic damage as this would overstate the importance of velocity. Instead, momentum (projectile weight multiplied by muzzle velocity) has been used as an estimate of the kinetic damage inflicted by the projectile. It might be argued that even this overstates the importance of velocity in the case of high-capacity HE shells, as noted above, but the effect of velocity in improving hit probability is one measure of effectiveness which needs acknowledging, so it is given equal weighting with projectile weight.

Chemical energy is generated by the high explosive or incendiary material carried by all air-fighting projectiles. First, there is the difference between HE and incendiary material, which are often mixed (in very varying proportions) in the same shell. HE delivers instant destruction by blast effect (plus possibly setting light to inflammable material within its blast radius), incendiaries burn on their passage through the target, setting light to anything inflammable they meet on the way. The relationship between the effectiveness of HE and incendiary material is difficult to assess. Bearing in mind that fire has been the big plane-killer, there appears to be no reason to rate HE as more important, so they have been treated as equal.

The comparison between kinetic and chemical energy is the most difficult and complicated subject to tackle. This complexity is revealed by the example of a strike by a delay-fuzed HEI cannon projectile. This will first inflict kinetic damage on the target as it penetrates the structure. Then it will inflict chemical (blast) damage as the HE detonates. Thirdly, the shell fragments sent flying by the explosion will inflict further kinetic damage (a thin-walled shell will distribute lots of small fragments, a thick-walled shell fewer but larger chunks), and finally the incendiary material distributed by the explosion may cause further chemical (fire) damage.

There will therefore always be a degree of arbitrariness in any attempt to compare kinetic and chemical energy, as it all depends on exactly where the projectile strikes, the detail design of the projectile and its fuze, and on the type of aircraft being attacked. To allow a simple comparison, we will reduce all these factors to an increase in effectiveness directly proportional to the chemical content of the projectile. We assign to projectiles that rely exclusively on kinetic energy an effectiveness factor of 100%. For projectiles with a chemical content, we increase this by the weight fraction of explosive or incendiary material, times ten. This chosen ratio is based on a study of many practical examples of gun and ammunition testing, and we will see below that it at least approximately corresponds with the known results of ammunition testing.

To illustrate how this works: a typical cannon shell consists of 10% HE or incendiary material by weight. Multiplying this by ten gives a chemical contribution of 100%, adding the kinetic contribution of 100% gives a total of 200%. In other words, an HE/I shell of a given weight that contains 10% chemicals will generate twice the destructiveness of a plain steel shot of the same weight and velocity. If the shell is a high-capacity one with 20% chemical content, it will be three times as destructive. If it only has 5% content, the sum will be 150%, so it will be 50% more destructive, and so on.

The following table for the most common cartridges and loadings used in aircraft guns shows the consequences of these assumptions and calculations. The first few columns should be self-explanatory, as these are basic statistics about the ammunition. The 'DAMAGE' column shows the results of the calculations described above. To run through an example, let us look at the case of the 30 x 113 B. The projectile weighs  270 g, (which equals 0.270 kg) and is fired at 720 m/s. Multiplying these gives 0.270 x 720 = 194.4, so you have a momentum factor of 194.4. As the bullet contains 17.2% by weight of incendiary material, the momentum is multiplied by 2.72 to give a destructive power score of 528.768 - rounded to 529.

In the last column – 'Power' – the 'Damage' result is divided by ten and rounded to the nearest whole number (except for the 12.7 x 99) to simplify later calculations.

Table 1: Cartridge Destructiveness   (Figures with a (*) are estimates:  

Cartridge

Type

Round
Weight

MV (m/s)

Projectile
Weight/gr

% HE/I
Content

Damage

Power

12.7x99

API

112

890

43

2.0%

46

4.6

20x102

HEI

263

1030

101

11.0%

218

22

20x110

HEI

257

830

129

8.8%

201

20

20x110 USN

HEI

270

1010

110

(*) 11.0%

(*) 233

(*) 23

23x115

HEI

325

740

175

10.8%

269

27

25x137

HEIT

492

1100

184

16.7%

540

54

27x145B

HEI

516

1023

260

(*) 15.0%

(*) 666

(*) 67

30x113B

HEI

550

720

270

17.2%

529

53

30x150B

HEI

530

1025

275

17.5%

775

77

30x155B

HEI

840

790

400

12.1%

695

69

30x165

HEI

830

860

390

12.4%

751

75

30x173

HEI

890

1080

360

15.0%

972

97

37x155

HEI

1300

690

729

6.7%

840

84

Comments on Table 1

Clearly, the resulting scores can only be approximate, and in particular will vary depending on the particular mix of types included in an ammunition belt. The power calculation takes a typical mix of ammunition, where known. They also take no account of the fact that some incendiary mixtures, and some types of HE, are more effective than others. However, they do provide a reasonable basis for comparison. There is no point in trying to be too precise, as the random factors involved in the destructive effects were considerable

Gun Power and Efficiency

The cartridge destructiveness table above only shows the relative effect of one hit. When comparing the guns that fired the cartridges, other factors come into play, namely the rate of fire (RoF) and the gun weight.

To calculate the destructive power of the gun, the 'POWER' factor from the above table has been multiplied by the RoF, expressed in the number of rounds fired per second. This gives the relative 'GUN POWER' figures in the table below.

To judge how efficient the gun was, the 'GUN POWER' result is divided by the weight of the gun in kilograms to provide the 'GUN EFFICIENCY' score in the last column. This is, in effect, a measure of the power-to-weight ratio of the gun and ammunition combination.

Table 2: Gun Power and Efficiency    (Figures with a (*) are estimates:

Gun

Cartridge

Rate of
fire (rps)

Rate of
fire (rpm)

Cartridge
Power

Gun
Power

Gun
Weight

Gun
efficiency

M3

12.7x99

20

1200

4.6

92

29

3.2

M39

20x102

27

1620

22

594

81

7.3

M61A1 [¹]

20x102

18/100

1080/6000

22

792/2200

114

19.2

M61A2 [¹]

20x102

30/100

1800/6000

22

1320/2200

93

14.2/23.7

Hispano V

20x110

12.5

750

20

250

42

6.0

Mk 12

20x110 USN

18

1080

(*) 23

(*) 414

46

(*) 9.0

NS-23

23x115

11.5

690

27

310

37

8.4

NR-23

23x115

15

900

27

405

39

10.4

GSh-23

23x115

54

3240

27

1460

50

29

GSh-6-23

23x115

150

9000

27

4050

76

53

GAU-12/U [¹]

25x137

13/70

780/4200

54

1404/3780

123

11.4/30.7

BK 27

27x145B

28

1680

(*) 67

(*) 1876

100

18.8

Aden

30x113B

22

1320

53

1170

87

13.4

Defa 552

30x113B

22

1320

53

1170

87

13.4

30M554

30x113B

30

1800

53

1590

85

18.7

30M791

30x150B

42

2520

77

3234

120

26.9

NR-30

30x155B

15

900

69

1035

66

15.7

GSh-301

30x165

27

1620

75

2025

45

45.0

GSh-30

30x165

50

3000

75

3750

105

35.7

KCA

30x173

22

1320

97

2134

136

15.7

N-37

37x155

6.7

400

84

563

103

5.5

NN37

37x155

10.8

650

84

909

103

8.8

Comments on Table 2

[¹] The figures for the power-driven rotaries are for the full RoF. In practice, the figures in air combat will be lower because of the time taken to accelerate. For example, the M61A1 only fires 18 rounds in the first 0.5 seconds, and 68 rounds in the first full second of firing. In the first second, the gun power figure will be 1,496 and the efficiency 13.1. If only the first half-second of firing is counted, then the (full-second equivalent) figures become 792 for gun power and 6.9 for efficiency. The GAU-12/U has the same spin-up time as the M61A1, 0.4 sec, so will be affected about as much by this factor, with full-second scores of 2,592 and an efficiency of 21, and half-second scores of 1404 and 11.4. The gas-powered GSh-6-23 and GSh-6-30 will be affected far less, and spin-up time has been reduced to 0.25 sec for the lighter M61A2, improving its scores accordingly

Two factors not included are gun reliability and total ammunition weight. The former is simply not available in most cases. The latter involves too many variables. First, the ammunition supply for most guns varied according to the installation. Furthermore, in searching for comparators, there would be the problem of which measures to take: the weight of the number of rounds fired per second, or the weight of the number required to inflict a certain amount of damage? There would be a case for either of these, but they would produce very different results. This issue is however addressed in the next table.

Fighter Firepower

Finally, a consideration of how the firepower of fighters compared with each other. The aircraft have been grouped in early postwar, 1954-1970, 1970-1990 and 1990+ fighters, and have been chosen to be representative of their period.

Table 3: Fighter Firepower

Aircraft

Name

Q

Guns

Cal

RPG

Weight
(kg)

Ammo
Power

Gun
Power

Time to fire 2320

1945-53

 

 

 

 

 

 

 

 

 

DH100

Vampire

Hispano MkV

20mm

150

322

12000

1000

2.32

F-86A

Savre

Browning 

.50

267

353

7370

552

4.20

F9F-2

Panther

Hispano M3

20mm

190

363

15200

1000

2.32

Yak23

Flora

NR23

23mm

60

117

3240

810

2.86

MiG15

Fagot


N37D
NR23

37mm
23mm

40
80

285

7680

1373

1.69

J29

Tunnan

M47C[HS804]

20mm

180

393

14400

1120

2.07

P1067

Hunter

Aden

30mm

150

648

31800

4680

0.50

1954-70

 

 

 

 

 

 

 

 

 

MiG19S

Farmer

NR30

30mm

120

500

24840

3105

0.75

F-100A

Super Sabre

M39

20mm

275

613

24200

2376

0.98

F8U

Crusader

Mk12

20mm

144

340

13248

1656

1.40

F-104G

Starfighter

M61A1

20mm

725

305

15950

2200

1.05-1.37

J35A

Draken

M55[Aden]

30mm

90

264

9540

2340

0.99

MiG21F

Fishbed

NR30

30mm

30

91

2070

1035

2.24

F-5A

Freedom

M39

20mm

280

309

12320

1188

1.95

Mig21PFM

Fishbed

GSh-23L

23mm

200

115

5400

1460

1.59

MD550

Mirage IIIC

Defa 552

30mm

125

299

13250

2340

0.99

F6

Lightning

Aden Mk4

30mm

130

304

13780

2340

0.99

1970-90

 

 

 

 

 

 

 

 

 

F-14A

Tomcat

M61A1

20mm

767

315

16874

2200

1.05-1.37

F-5E

Freedom

M39A2

20mm

280

309

12320

1188

1.95

Mig23M

Flogger

GSh-23L

23mm

250

131

6570

1460

1.59

Dassault

Mirage F1

Defa 553

30mm

125

299

13250

2340

0.99

F-16A

Falcon

M61A1

20mm

511

248

11242

2200

1.05-1.37

JA37

Viggen

KCA

30mm

150

270

14550

2134

1.09

Mig29

Fulcrum

GSh-301

30mm

150

170

11250

2025

1.15

Dassault

Mirage 2000C

Defa 554

30mm

125

299

13250

2340

0.99

Panavia

Tornado ADV

BK27

27mm

180

193

9900

1876

1.24

Su27

Flanker

GSh-301

30mm

150

170

11250

2640

1.15

1990-

 

 

 

 

 

 

 

 

 

JAS30

Grippen

BK27

27mm

120

162

6600

1876

1.24

Dassault

Rafale

20M791

30mm

125

186

9625

3234

0.72

Eurofighter

Typhoon

BK27

27mm

150

177

825

1540

1.26

F-22A

Raptor

M61A2

20mm

480

219

10560

2640

1.05-1.25

Comments on Table 3

The armament installations are listed in the second column. The specified weight is the weight of the bare guns and the ammunition. It does not include belt links, ammunition tanks, gun mounting points and recoil buffers, et cetera. The ammunition power value is the cartridge power value from Table 1, multiplied by the number of cartridges carried. The gun power value is the sum of the gun powers as in Table 2. The final column gives the time in seconds, needed to fire the equivalent of an ammunition power of 2320. The choice of this value is somewhat arbitrary; it was selected simply because the heaviest armed WW2 fighter – the Me 262 – was capable of delivering this firepower in one second, so it enables easy comparisons to be made. 'Two 'Time to Fire' figures are given for the American rotaries; the slower time is from a standing start, the faster one assumes that it is spinning at maximum rate throughout.

The fighters are here divided into four groups. The first group, which entered service in the late 1940s and early 1950s, was subsonic in level flight and had guns as main armament. Most of these fighters carried an improved form of WWII armament, with guns that were technically refined and had a higher rate of fire. One fundamental change in comparison with WWII is that, with the exception of the hugely successful MiG-15 (and the improved MiG-17) all had homogenous armament. The practice of fitting multiple types of gun to a fighter was abandoned by most nations.

In 1953 the Hawker Hunter entered service with an armament of four Aden cannon. With a power rating of 4680, this is the most powerful gun armament listed here. All later fighters carried substantially less cannon firepower. Most air forces were satisfied with lighter gun armament than the RAF, and the introduction of homing air-to-air missiles in service soon led to a reduction of gun armament. Not listed here are the Gloster Javelin and the early models of the BAC Lightning, which could carry four Aden cannon, or two Aden cannon and missiles.

The next group, from the late 1950 to 1970, contains the first supersonic and Mach 2+ fighters. In this time period many interceptor fighters entered service without cannon armament. Although multi-role and air superiority fighters often retained cannon, attempts to improve their firepower were limited. Guns fell victim to weight reduction programmes, or were (as in the case of the F-104 and Mirage III) installed as optional equipment packages. The Lightning F.6 entered service as a missile-only fighter, but cannon were retrofitted from 1970 onwards.

The third group, from 1970 to 1990, all had guns designed into them, under influence of the US experience in Vietnam. Despite the introduction of several new types of cannon, none of these fighters exceeds the gun firepower of the Me 262 by a substantial margin – and the total weight of the guns plus ammunition is only about 300 kg or less. The same figure for the Me 262 was 413 kg, but one also has to consider that the ballistic performance of modern fighter cannon is much superior and the performance of sighting systems has been much improved. This allowed for some weight reduction; the Soviet fighters clearly have the lightest gun installations.

Finally, the last group includes four fighters that are currently entering service. Here we see again an improvement in firepower, although the 30M791 and M61A2 are both direct descendants of older guns, rather than innovative designs. On the other hand the destructive capacity of the ammunition carried is decreasing again, to levels that are actually somewhat inferior to the better armed of the WWII fighters. This is defended with the argument that modern sighting systems are so accurate, that the hit probability is far higher than the 2% typically achieved during WWII, when aiming was mostly dependent on the skill of the pilot. Despite a reduced ammunition capacity and a gun redesigned to reduce the weight, the installation of the F-22 remains heavy in comparison with that of other fighters, without benefiting much in firepower.

For the smaller JSF, Lockheed Martin at first selected the BK 27 revolver, then changed to the GAU-12/U five-barrel rotary, then finally to a four-barrel version of the GAU-12/U, designated GAU-22/A. This will only be fitted internally in the Air Force F-35A version; the STOVL F-35B and naval F-35C will have the option of carrying one in a gunpod under the rear fuselage. The GAU-22/A's maximum RoF of 3,000 rpm delivers a gun power of 2,700. The spin-up rate is not yet clear, but assuming it is the same as the GAU-12/U (0.4 secs), the gun power  varies from about 1,000 (the half-second standing-start rate) through 1,850 (the full-second standing start). The length of time to reach the '2320 score' will be 1.17 seconds from a standing start and 0.86 seconds at maximum rate.

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