Light fighter

 ( Fighter Aircraft ) 

Small fighters like the F-5 with a planform area of about or the F-16 at about , compared to about for the F-15,Sprey, 1982, pp. 88–89. have a much lower visual profile. The small fighter is typically invisible to opposing pilots beyond about , whereas a larger fighter such as the F-15 is visible to about . This is a non-linear advantage to the light fighter opposing a heavy fighter. Additionally, smaller targets take longer to visually acquire even if they are visible.Snyder, Harry, et al., “Air-To-Air Target Acquisition: Factors and Means of Improvement”, Virginia Polytechnic University, July 1979, prepared for USAF School of Aerospace Medicine, p. 15 (p. 18 as read on Adobe), http://oai.dtic.mil/oai/oai?verb=getRecord&metadataPrefix=html&identifier=ADA087848 These two factors together give the light fighter pilot much better statistical odds of seeing the heavy fighter first and setting up a decisive first shot.Stevenson, pp. 22–36. Once the small fighter sees and turns towards the opponent its very small frontal area reduces maximum visual detection range to about .Schallhorn et al., "Visual Search in Air Combat", Naval Aerospace Medical Research Laboratory and Naval Fighter Weapons School (TopGun), Oct. 1991, p. 6, http://oai.dtic.mil/oai/oai?verb=getRecord&metadataPrefix=html&identifier=ADA241347

Given similar technology, smaller fighters typically have about two thirds the radar range against the same target as heavy fighters. However, this cannot be counted upon to give the large fighter a winning advantage, as larger fighters with typical radar cross sectional area of about are detectable by a given radar at about 50% further range than the cross section of the light fighter.Sprey, 1982, p. 60. This approximately balances these trade-offs, and can sometimes favor the lightweight fighter. For example, from the front the F-15 actually presents about radar cross sectional area,Sprey, p. 93. and has been typically defeated by opposing F-16 forces not only in close dogfighting combat, but also in extensive Beyond Visual Range (BVR) trials.Sprey p. 149. Also, airborne fighter radars are limited: their coverage is only to the front, and are far from perfect in detecting enemy aircraft. Although radar was extensively used by the United States in the Vietnam War, only 18% of North Vietnamese fighters were first detected by radar, and only 3% by radar on fighter aircraft.Stevenson, p. 130. The other 82% were visually acquired.Stevenson, 1993, p. 35.

The modern trend to stealth aircraft is an attempt to maximize surprise in an era when Beyond Visual Range (BVR) missiles are becoming more effective than the quite low effectiveness BVR has had in the past. 2. Numerical superiority in the air, which implies the need for lower procurement cost, lower maintenance cost, and higher reliability. Not even taking into account the sometimes superior combat capability of lighter aircraft based on surprise and maneuverability, the pure numbers issue of lower cost and higher reliability (higher sortie rates) also tends to favor light fighters. It is a basic outcome of Lanchester's laws, or the salvo combat model, that a larger number of less-sophisticated units will tend to be successful over a smaller number of more advanced ones; the damage dealt is based on the square of the number of units firing, while the quality of those units has only a linear effect on the outcome. This non-linear relationship favors the light and lightweight fighter.Huenecke, p. 31.

Additionally, as pilot capability is actually the top consideration in maximizing total effectiveness of the pilot-aircraft system, the lower purchase and operational cost of light fighters permits more training, thus delivering more effective pilots.Sprey, p. 17. For example, as of 2013, total heavy F-15C operating cost is reported at US$41,900 per hour, and light F-16C cost at US$22,500 per hour. for hourly operating cost of USAF aircraft as reported by the USAF.

3. Superior maneuverability, which in maneuvering combat allows getting into superior position to fire and score the kill.Stevenson, pp. 43–47.Sprey, p. 49,52, pp. 67–75.Spick, 1995, p. 46.Gunston and Spick, 1983, pp. 190–191. This is a function of achieving lower wing loading, higher thrust to weight ratio, and superior aerodynamics.Stevenson, p. 28.Burton, Kindle locations 333–370.Spick, 1995, p. 47–48. This is sometimes described colloquially as “wrapping the smallest possible airframe around the most powerful available engine.” Professional analysis through 4th generation fighters shows that among heavier fighters only the F-15 has been generally competitive with lighter fighters, and its maneuvering performance is exceeded by several lighter fighters such as the F-16.Burton, Kindle locations 468–481.Sprey, pp. 98–107, p. 109, 131, pp. 147–149. Light fighters have no inherent aerodynamic advantage for speed and range, but when designed to be as simple as possible they do tend to have lower wing loading and higher thrust to weight ratio.Sprey, pp. 150–151. Additionally, smaller fighters are lower in inertia, allowing a faster transient response in maneuvering combat.Sprey, p. 156.

4. Weapon systems effectiveness.Sprey, 1982, pp. 48–54.Hammond, p. 36Stevenson, pp. 33–49. This area is one where the light fighter can be at a disadvantage, since the combat load of a single engine light fighter is typically about half of a twin engine heavy fighter. However, modern single engine light fighters such as the General Dynamics F-16 Fighting Falcon and the Saab JAS 39 Gripen generally carry similar cannon and air-to-air missile fighter weapons as heavier fighters. Actual aerial combat in the modern era is of short duration, typically about two minutes,Huenecke, p. 26. and as only a small fraction of this is spent actually firing, modest weapons load outs are generally effective. The ideal weapons load for a modern fighter is considered to be an internal gun and two to four guided missiles, a load that modern light fighters are fully capable of while maintaining high agility. For example, the JAS 39 Gripen, despite being the lightest major fighter in current production, carries a combat load of a 27mm cannon and up to six air-to-air missiles of the same types as carried by heavy fighters. Additionally, combat experience shows that weapons systems "effectiveness" has not been dominated by the amount of weaponry or "load out", but by the ability to achieve split second kills when in position to do so.Stevenson, p. 47.Sprey, p. 52.

The more general and often misunderstood argument for more technology that has been historically assumed to favor heavy fighters is not just better radar but better systems support for the fighter pilot in other ways as well. Examples include all weather capability, precise electronic navigation, electronic counter-measures, data-linking for improved information awareness, and automation to lighten pilot workload and keep the pilot focused on tasks essential to combat.Stevenson, 1993, pp. 120–121, 126–128. This was a compelling argument, as the greatest factor in the effectiveness of a fighter plane has always been the pilot. Quoting a prominent reference, "Throughout the history of air combat, a few outstanding fighter pilots, typically less than five percent of the whole, have run up large scores at the expense of their less gifted brethren. The numerical imbalance was such that a large number of high scorers was needed. The quest was on to turn each fighter pilot into an ace, and technology seemed the easiest, and the only way to achieve it. This was the idea underlying the first two American superfighters; the F-14 Tomcat and the F-15 Eagle.”Spick, Mike, “Designed for the Kill”, 1995, p. 32.

While the technology advantage for heavy fighters that better supported the pilot may well have been a valid point in the 1970s (when the F-14 and F-15 first entered service), this advantage has not been maintained over time. Engine performance improvements have improved load carry capability, and with more compact electronics, the lightweight fighter has, from the 1980s onwards, had similar pilot enhancing technical features.Ahlgren, Linner, and Wigert, 2002, pp. 22–40, pp. 94–105.Spick, 2000, pp. 30–41. The lightweight fighter carries equally effective weapons including BVR missiles, and has similar combat range and persistence. The modern lightweight fighter achieves these competitive features while still maintaining the classic advantages of better surprise, numbers, and maneuverability. Thus, the lightweight fighter natural advantages have remained in force despite the addition of more technology to air combat.

Due to their lower costs, modern light fighters equip the air forces of many smaller nations. However, as budgets have limits for all nations, the optimum selection of fighter aircraft weight, complexity, and cost is an important strategic issue even for wealthy nations. The budgetary and strategic significance of light fighters is illustrated by the defense investment at stake. As an example where well referenced data is available, though numerous trial and combat references consider the lightweight F-16 to be as good or better on a per plane as the excellent but expensive F-15,Sprey, 1982, p. 149.Lockheed Forth Worth Company (press release) http://www.thefreelibrary.com/F-16+TEAMS+DOMINATE+USAF+AIR-TO-AIR+COMPETITION-a015848749 , accessed June 27, 2016. fielding and maintaining a light fighter force based on the F-16 is approximately half the cost of the same number of F-15's. The US Air Force reports the total loaded cost per hour (as of 2013) of operating the F-16C to be ~US$22,500 per hour, while that of the heavy F-15C is $41,900 per hour. Numerous authoritative sources report that it takes about 200 to 400 flight hours per year to maintain fighter pilot proficiency.Brian Manes, Major, USAF, MS Thesis “Extending USAF F-16 Force Structure”, Air Command and Staff College, 2001, p. 17, downloadable from http://www.globalsecurity.org/military/library/report/2001/01-079.pdf

Lanchester's laws on military superiority suggest that any technical superiority of the heavy fighter on a unit basis will not always translate to winning wars. For example, late in WWII the greatly superior German Messerschmitt Me 262 jet fighter, flown by the finest pilots Germany had left, many of them very high scoring aces with kill counts far in excess of Allied pilots, in its relatively small numbers suffered heavy losses and was unable to fundamentally alter the air war over Germany.Sprey, 1982, p. 23–25. Such issues are relevant to future military planning and deployments.The Rand Corporation, "Air Combat, Past, Present, and Future" /ref>

One early light fighter project was the French Air Force's 'Jockey' interceptor program of 1926. Several aircraft, including the Nieuport-Delage NiD 48 and Amiot 110, were trialed without much success as they offered little over aircraft already in productionGreen and Swanborough (1994), p.439. In the late 1920s the British similarly issued specification F.20/27 for a short-range fast-climbing daylight interceptor. The de Havilland DH.77 and Vickers Jockey monoplanes were among seven designs tendered to meet the specification but neither went into production, the heavier but faster biplane Hawker Fury being preferred.

Despite the failure of their Jockey program, the French returned to lightweight fighters during the 1930s as a means to expand France's fleet of aircraft and counter the buildup of the German air force. This focused on light wooden fighters that could be built quickly without affecting production of other aircraft. A mid-thirties specification requiring fixed undercarriage produced two prototypes and in 1936 a revised requirement for retractable gear resulted in three prototypes. The most numerous of the two designs which went into production was the Caudron C.714. Delivery began in early 1940, but less than 100 had been built before the fall of France.Green and Swanborough (1994), pp.18, 19, 30, 71-2, 111-2. Although underpowered, it was of necessity used by Polish air force pilots serving in France.

The Spitfire, designed by R. J. Mitchell, entered service in 1938 and remained in production throughout the war. The empty weight of the Battle of Britain-era Spitfire IIA was , increasing to in a later variant. It was highly maneuverable and was generally a match for its German opponents. Most Spitfires had a Rolls-Royce Merlin engine, but later variants used one of the most powerful engines of the war – the Rolls-Royce Griffon. The Spitfire was produced and improved throughout the war but was complex to build and had limited range. In other respects it was considered an outstanding fighter.

The Hawker Hurricane played an important role in the Battle of Britain, but its performance was inferior to the Spitfire and during the war was removed from frontline duty as a fighter and used for ground attack. Production ceased in mid-1944. The Hurricane IIC weighed empty.

Instead, the US developed a number of standard pursuit fighters, the most efficient being the relatively lightweight North American P-51 Mustang. The P-51 was more economical, costing less per air-to-air kill than any other American aircraft.Paul Ludwig, “Development of the P-51 Long-Range Escort Fighter”, p. 34.Ray Wagner, “Mustang Designer”, pp. 139-146, p. 196."Fighter aircraft like the P-51, F8F Bearcat, and F-16 are examples of fighters that are lighter than their contemporaries, are less expensive, and have greater performance. Because fighter aircraft of lower weight can have increased performance, can cost less, and can create a larger force, these three benefits are embodied in the term lightweight fighter." James Stevenson, "The Pentagon Paradox", Naval Institute Press, 1993, p. 62.

The United States Navy, also made aware of lightweight advantages by combat results,Stevenson, 1993, p. 70 specifically and pp. 68–72 in general. ordered a lighter version of the Grumman F6F Hellcat, which at empty weight had limited maneuverability and rate of climb. The planned Grumman F8F Bearcat replacement used the same engine, but with empty weight reduced to had excellent performance. It entered production too late to see combat in World War II. Postwar, it equipped 24 fighter squadrons in the Navy and a smaller number in the Marines. Navy author James Perry Stevenson called the Bearcat "the quintessential lightweight fighter".Stevenson, 1993, p. 70.

Similar in size to the F-5, the Russian Mikoyan-Gurevich MiG-21 entered service in 1959, was produced until 1985, and is still in widespread use today. The late Generation 2 to Generation 3, Mach 2 MiG-21 has an empty weight of , and has served nearly 60 nations. It shot down 37 to 104 US Phantoms, in the Vietnam War, with the Phantoms shooting down 54 to 66 MiG-21s in return."MiG-21 Against the Phantom", http://survincity.com/2013/01/mig-21-against-the-phantom/ In December 1966 the MiG-21 pilots of the 921st FR downed 14 F-105s without any losses. Its weaknesses include poor visibility and relatively short range, but has otherwise proven to be a capable fighter.

The US's Vought F-8 Crusader used in Vietnam weighed , as compared with for an F-4 Phantom. It was a simple, supersonic, single engine, gun- and heat-seeker armed fighter in front-line service from 1957 to 1976. It had no radar except a simple ranging gunsite radar. The US claims the Crusader (up to 1968) shot down six enemy aircraft for every loss, compared with 2.4 for every Phantom lost.Stevenson, 1993, p. 89. The three F-8s shot down in air-to-air were all lost to MiG-17 cannon fire.

The first few decades of the jet fighter era showed a combat history similar in general trend to that of the propeller fighters of World War II. So long as lighter fighters are of sufficient power-to-weight ratio and airframe sophistication, and flown by similarly skilled pilots, they tend to dominate over heavier fighters using surprise, numbers, and maneuverability. However, one significant difference did emerge in design strategy in the early jet fighter era. In World War II fighter design was strongly influenced by the seeking of higher speeds that were valuable in combat in order to close with the enemy or to escape. This trend was instinctively continued in some jet fighters through the 3rd generation (F-4 at Mach 2.23) and into the 4th generation (F-14 at Mach 2.35 and F-15 at Mach 2.5+). The aerodynamic requirements to operate at such speeds add considerable complexity, weight, and cost to the airframe.Hammond, 2001, p. 78. But, these Mach 2 and above class speeds have zero utility in combat.Stuart, 1978, pp. 65–79. Combat speeds never exceed Mach 1.7 and seldom 1.2, for two reasons. First, it requires extensive use of the afterburner, which typically increases fuel consumption by about a factor of three or even four, Military Turbojet/Turbofan Specifications jet-engine.net and rapidly reduces operational radius. Second, speeds even above about Mach 0.7 to Mach 1 (depending on circumstances) so widen the turn radius in maneuvering combat that the fighter is thrown too wide to get a tracking solution on an opponent. Speed had reached the limit of its practical combat value, such that optimum fighter design required understanding the penalties the endless search for higher speed was imposing, and sometimes deliberately choosing not to accept those penalties.