Germany patent drawing from March 1944 jet engines is due to the area rule. The area rule was discovered by when comparing a swept wing with a w-wing with extreme high wave drag while working on a transonic wind tunnel at
Junkers works in Germany between 1943 and 1945. He wrote a description on 17 December 1943, with the title
Anordnung von Verdrängungskörpern beim Hochgeschwindigkeitsflug ("Arrangement of Displacement Bodies in High-Speed Flight"); this was used in a patent filed in 1944. The results of this research were presented to a wide circle in March 1944 by Theodor Zobel at the
Deutsche Akademie der Luftfahrtforschung (German Academy of Aeronautics Research) in the lecture "Fundamentally new ways to increase performance of high speed aircraft." Subsequent German wartime aircraft design took account of the discovery, evident in slim mid-fuselage of aircraft including the
Messerschmitt P.1112,
P.1106 and
Focke-Wulf 1000x1000x1000 type A long-range bomber, but also apparent in delta wing designs including the
Henschel Hs 135. Several other researchers came close to developing a similar theory, notably
Dietrich Küchemann who designed a tapered fighter that was dubbed the "Küchemann Coke Bottle" when it was discovered by US forces in 1946. In this case Küchemann arrived at the theory by studying airflow, notably the interference, or local flow streamlines, at the junction between a fuselage and
swept wing. The fuselage was contoured, or waisted, to match the flow. The shaping requirement of this "near field" approach would also result from Whitcomb's later "far field" approach to drag reduction using his Sonic area rule.
United States Wallace D. Hayes, a pioneer of
supersonic flight, developed the transonic area rule in publications beginning in 1947 with his PhD thesis at the
California Institute of Technology.
Richard T. Whitcomb, after whom the rule is named, independently discovered this rule in 1952, while working at the
National Advisory Committee for Aeronautics (NACA). While using the new High-Speed Tunnel, a
wind tunnel with performance up to Mach 0.95 at NACA's
Langley Research Center, he was surprised by the increase in drag due to shock wave formation. Whitcomb realized that, for analytical purposes, an airplane could be reduced to a streamlined body of revolution, elongated as much as possible to mitigate abrupt discontinuities and, hence, equally abrupt drag rise. The shocks could be seen using
Schlieren photography, but the reason they were being created at speeds far below the speed of sound, sometimes as low as Mach 0.70 remained a mystery. In late 1951, the lab hosted a talk by
Adolf Busemann, a famous German aerodynamicist who had moved to Langley after
World War II. He talked about the behavior of airflow around an airplane as its speed approached the critical Mach number. Whereas engineers were used to thinking of air flowing smoothly around the body of the aircraft, at high speeds it simply did not have time to "get out of the way", and instead started to flow as if it were rigid pipes of flow, a concept Busemann referred to as "streampipes", as opposed to
streamlines, and jokingly suggested that engineers had to consider themselves "pipefitters". Several days later Whitcomb had a "
Eureka" moment. The reason for the high drag was that the "pipes" of air were interfering with each other in three dimensions. One does not simply consider the air flowing over a 2D cross-section of the aircraft as others could in the past; now they also had to consider the air to the "sides" of the aircraft which would also interact with these streampipes. Whitcomb realized that the shaping had to apply to the aircraft
as a whole, rather than just to the fuselage. That meant that the extra cross-sectional area of the wings and tail had to be accounted for in the overall shaping, and that the fuselage should actually be narrowed where they meet to more closely match the ideal. ==Applications==