Some additional notes to go with the 2026 HPAG lecture ====================================================== I am surprised to be here talking because Airglow was designed a long time ago, and we expected it to be destroyed in a crash within a few months. It turns out that these CFRP structures last a long time. I have chosen not to speak about Airglow for a long time because I thought I'd done enough talking and everyone knew what I had to say, but that is stupid because the young designers working now were not born when I last talked, and I have watched many avoidable mistakes being made so this lecture is about providing advice that I hope will prevent mistakes. It is also about learning from a new design that represents the present state of the art. When we built Airglow, it was not possible to buy CFRP tube, so we had to work out how to make tubes for ourselves. We knew the basic recipe from Gossamer Albatross and Solar Challenger: you wrap CFRP pre-preg around an aluminium mandrel, wrap that in heat shrink tape, and cure the laminate in an oven, but that leaves out a lot of important details. It took us some time and a good deal of trial and error to find out how to do it (see below). The point is that making your own CFRP tube is not difficult, the resulting tubes can be optimised for their intended use, and cost much less than buying it. Be humble Learn from what has been done before Test every component before flying Innovate only where it results in improvement and do so cautiously Learn to fly before flying, even if that is only stick time on a flight simulator I had also been thinking about how the technology of human-powered aircraft has not changed very much in thirty-five years compared with aeromodelling. I thought about illustrating this with pictures of a friend flying a power model in the 1955 world championships and another of Evgeny Verbitsky in 2015 with his free-flight power model. The skills were and are the same, of course, but the materials (balsa versus CFRP) and the configuration of the models have changed. I feel very strongly that aeromodelling teaches many useful skills and much understanding. That learning craft skills is valuable (in my view, essential). And that making things is a pleasure in and of itself. Slide 1 Airglow flying at Lasham in 2025 ---------------------------------------- It was not designed to win any of the Kremer prizes, only to be as we well built as we could manage and to fly. It contains few innovations. The configuration was copied from Bionic Bat and much of the detailed design from Daedalus. Nevertheless, I think its build contains some important lessons for new builders. Slides 2, 3, 4, 5, 6, 7 ----------------------- It is not too difficult to make your own CFRP tubes. We wrote an instruction book which can be downloaded from the human-powered flight website: https://www.humanpoweredflight.co.uk Very briefly, carbon fibre pre-preg is wrapped around a (teflon-waxed) aluminium mandrel and over-wrapped with peel ply and high shrink tape, and then cured in an oven at 120 degrees C. Making and extracting an 8m section of (wing) spar took us about two days. Since an HPA like Airglow has a 25m span wing, this translates to 6 days - 3 weekends work to make the wing spar. (Other tubes are simpler and faster to make.) The pictures show: 1. The tool we made for cutting pre-preg, which works exactly like a balsa stripper. 2. Wrapping the first layer of pre-preg onto the mandrel. If you know the mandrel diameter and wrap angle, it is easy to calculate the width of the pre-preg so that if it is put onto the mandrel with the edges touching, the angle will automatically be correct. 3. Wrapping high-shrink tape around the laminate 4. The oven we used to cure the tubes for Airglow I have drawn two designs for ovens to cure long tubes. The first is of the oven we used to cure tubes for Airglow, and the second is a variation on the ovens used to cure tubes for Man-Eagle. The pictures show: 1. Tube extraction 2. Cutting a tube intersection 3. Inserting foam/balsa sandwich bulkheads into one of the spar tubes to prevent buckling. Slide 8 shows the wing assembly and the in-plane truss ------------------------------------------------------ I have watched several aircraft come to the Icarus cup with no means to carry in-plane loads in the wing. For this reason, I have drawn two sketch plans that show how these loads are carried in the structures of Airglow and Velair. You do not need to tension the x-bracing with turn-buckles or use carabiners; simply pulling the x-bracing tight is enough. If you feel you absolutely must made adjustment possible, then tie a loop in the end of one bracing line and tie the other end through this. Aside 1 ======= It doesn't matter how efficient your aircraft is on paper if it is not carefully and accurately built, it will not fly well (or at all), so I encourage you to learn to use tools and to make things at every opportunity. Then test, test and test! ------------------------- BHI phantom =========== Slide 14 Phantom specification ------------------------------ There is a good deal that I have been able to figure out from the published pictures, but there is also a good deal that I don't know. For example, the wing area and the design lift coefficient, but knowing the weight, it is possible to estimate as follows. Design Wing area lift square m coefficient 1.1 12.81 1.0 14.09 If you want to design a similar aircraft for a heavier pilot, then you will need to scale the wing area to the actual pilot and airframe weight. For example, if you want to fly with a 75kg pilot, which implies a larger, heavier airframe (of say 25kg), then the wing area should be increased to 16 square meters. I do not know what Airfoil section was used, though I suspect it may be the blended FX76MP-140/DAE41 FX76MP-120/DAE31 used by Team-F My incomplete knowledge (of the Phantom) is not important because I am not suggesting an exact copy should be built, only that reducing weight, frontal area, and high build quality matter and that the overall configuration is the best that I have seen. In 2023, it flew 69.68 km with a power input of 184 W Wing spar CFRP D-box cantilever spar Propeller location Mid pusher Cockpit structure Cantilever beam Wingspan 25 m Length 6.7 m Empty weight Design: 21 kg Actual: 23 kg Pilot weight            63 kg Total weight 85 kg Wing area               14 square m, assuming a design CL of 1.0 Design speed 10 m/s Slide 20 gearbox ---------------- It is possible to reduce the weight (and build complexity) of the drive by gearing up to the gearbox from the pedals and using a smaller, lighter (and easier to make) 1:1 gearbox. I have drawn (my best guess/approximation) of the Phantom gearbox. Its dimensions are constrained by the known diameter of the tube it fits inside. Again, I am not suggesting an exact copy should be made, but that this design is a very good place to start. The gear ratio was worked out by counting gear teeth teeth dia. ratio mm Chain ring 82 157 Gearbox input 33 63 2.48 The bevel gears have 20 teeth Spiral bevel gears should be used because they have the highest efficiency but the gear forces and the direction of the forces need to be calculated so that the gears are being pushed apart as they rotate. Slide 26 Wing skins and spar webs --------------------------------- The original design for the wing structure of Airglow was for an I-beam spar and D-box similar to Phantom, so the problems worked out by its designers are familiar to me. We did some structural testing of joints and made a 4m spar section, which we load tested. It didn't break. We were copying Musculair II's spar but using pre-preg to make the spar caps and joints. In the end, I was too risk-averse to do what I first planned and copied the Daedalus spar instead. Slide 27 spar joints -------------------- I do not know what the pins and sleeves in the joints are made from in the Phantom wing. I have labelled them Titanium in my drawings because that is what I'd be tempted to make them from, though it may be that 7000 series aluminium would be satisfactory. You will need to calculate/trade the pin diameters and material from which they are made if you are making an I-beam spar like Phantom. I strongly recommend you use large-diameter pins to prevent bending. I'm sorry this talk contains quite a lot of unknowns. I do not know the layup of the D-box skins. I suspect they may be made from only two or three layers of CFRP pre-preg. Peer Frank's first wing for Velair 88 also had an I-beam spar, but the D-box was made from a Depron glass sandwich and suffered a torsional lateral buckling failure during test. Slide 32 drawing of the spar joints ----------------------------------- I do not know what material was used for the metal components of the spar joints. My first thought is to use titanium, so I have labelled the drawing accordingly. But be aware, this may be wrong. You should calculate the stresses and choose the lightest metal alloy that will work. Slide 33 Fly by AoA ------------------- While I was writing this lecture, which is about learning from an old and a new design, I found the following article by Jiro Horikoshi about designing the Zero. I thought it is worth including here because it explains how a good designer works - doing careful calculations but also using prior art where it exists. Airglow copies its configuration from Bionic Bat; the CFRP tubes construction can all be traced back to Gossamer Albatross. I have occasionally heard it said that the Japanese copy without innovating, and that is not true. I have a great respect for the beautiful work done by Japanese engineers, who do not simply copy, any more than anyone else. There is a film about Jiro Horikoshi that I enjoyed - The Wind Rises by Hayao Miyazaki. I Designed the Zeke By Jiro Horikoshi It might seem better if the man who designed the best-known fighter plane of the losing side kept his peace. However, by the mysterious channels through which back copies of publications travel, the April 1949 issue of Air Trails came into my possession. The American friend who gave it to me pointed out David A. Anderton's article, "The Great 'Zeke' Mystery," which indicated that the "Zero" fighter was progressively "borrowed" from a number of other contemporary aircraft. As the designer of the Zero, I would like to be permitted, for the benefit of history, to set the record straight. The Zero fighter, as the world got to know it, was no more copy than any other fighter used in the world today. All single-engined all-metal low-wing monoplanes are to some extent progressive "copies" of the original Junkers "Bleichsesel," the father of all these machines. There is a certain pool of common information from which all engineers draw. There is a certain reciprocal borrowing of detail ideas without permission during wartime, and by cross-licensing in times of peace. There have been few scientific studies of the Zero as an airplane published anywhere. In Japan, it was naturally praised; overseas. it was frequently subjected to certain ridicule, to dogma and to prejudice. I am grateful to Mr. Anderton for his prompt discounting of many of these false rumours and half-true reports. However, I can best prove the originality of the design of the Zero by relating its history and its background. Like people, airplanes have ancestors. They get to look as they do partly by heredity and partly because of the functions which they have to perform. This is, in essence, the story of Zeke, as seen through the informed albeit maybe slightly prejudiced eyes of its designer. Mr. Anderton, in his article, intimates that the world first saw Zeke on that day all Japanese would like the world to forget, Pearl Harbour Day. Had Mr. Anderton been given access to proper military information which I am sure must have been at the disposal of leading American military and naval intelligence personnel, he would have known that the Zero had been in action on the mainland of China for about a year and a half before the Pearl Harbour strike. In July of 1940, it began to replace the leading Army type, the Type 96-4 carrier fighter which had been a standard machine since 1936. Since the air phase of the operation in China was chiefly a Navy show, the Mitsubishi 96-4 (A5M4) had, up to then, been the leading single-place job. Here let me explain, again for the record, how the Japanese numbering system of identification worked. The 96 denotes the year that the plane was put into regular service, the 2596th year of the old Japanese era, 1936 AD. The figure 4 indicates the fourth modification or revision. The symbol A5 indicates that it is the fifth fighter prototype built by Mitsubishi, or M. This system was adopted by the Japanese in 1936, but was applied to planes built before that period also in reference files. The Army and Navy, which seldom got together on anything important, used somewhat different designations for everything but the year of service. As the war in China moved further inland, the Navy felt that they needed a fighter with a much longer range, in order to escort the bombers to and from the targets. It was this need for combination of speed, range and manoeuvrability that begat the Zeke. Mr. Anderton's knowledge of the early history of Japanese aviation is remarkably sound. As he stated, Japanese Naval aviation is chiefly British in its ancestry, while the Army aviation drew heavily from French and German sources. These were the easy old days, after I received my degree in aeronautics from the Imperial University in Tokyo and entered the Nagoya Aircraft Works of Mitsubishi Heavy Industries, Ltd., as a design calculator-or subordinate structures engineer, as one would be called in the United States. This was the period during which Japanese industry was trying to catch up with the more advanced technical status of certain Western powers by hiring experts and buying ideas and experience. By the time I entered Mitsubishi, at the age of 23, the noted American designer, Mr. Smith, and his party were no longer with the company. There were no Americans with the firm at the time. Prof. Baumann, the noted German designer, and Mr. Schade and Mr. Keil, both from Junkers, were with the company. The noted French designer, M. Vernisse, was employed in the outfit, as was Mr. Petty from Blackburn Aircraft Co. in England, and his assistants, Mr. Bolton and Mr. Wilkinson. These men stayed for contracts ranging from one to three years during the formative period between 1926 and 1931. They designed aircraft, taught other engineers the techniques of design, Unfortunately, I was in the lower echelon, my task was supervising stress calculations, and I had no opportunity to contact these foreign experts directly. This importation of foreign experts was universally practiced during this period when Japan's infant aviation industry was gathering momentum. Nakajima, Kawasaki, Aichi, Tachikawa - all of these had experts from abroad on their payrolls. Their influence during this period can be seen directly in the airplanes that were acquired by the Army and Navy. During this period, the Japanese companies went heavily into the purchase of patent licenses of all kinds. For example, the Handley-Page-Lachman leading edge wing slot was acquired jointly by Mitsubishi and Tachikawa for a hundred thousand pounds Licenses for accessories, engines, instruments and the like were purchased wholesale, to permit the infant industry to get into a competitive position. I was sent abroad to study during this period, and from June to December, 1929, I traveled in Europe. England, France, Germany and the Netherlands, visiting airplane factories. I stayed with the Junkers company for three months, studying their procedure in design. In December 1929 I embarked for the United States where I visited many plants. I stayed several months at the Curtiss Company's plant in Buffalo, where I acted as inspector for the P-6 pursuits that had been purchased by Mitsubishi. When I got home in the early fall of 1930, there was a new movement in the air. The Japanese designers had a feeling that they wanted to try their, own ideas in designing, by 1932, the Japanese government was about ready to listen. The Japanese Navy was particularly anxious to start a new line of aircraft, built entirely by Japanese. They ordered three important types under this program, a carrier-fighter, a carrier torpedo-bomber, and a reconnaissance seaplane. These were designated as the 7-Shi class since they were ordered during the seventh year of the Showa reign or era, 1932. Nakajima and Mitsubishi got orders for the carrier jobs, and I was appointed chief designer of the carrier fighter, chiefly on the basis of my experience and knowledge of fighters gained by contact with the P-6. By this time, the trend was definitely to monoplanes in fighters. By modern standards, the 7-Shi fighter was a clumsy, angular monoplane, but it was in the contemporary line of design. The wings were thick, full-cantilever structure, fabric covered, using the popular elliptical planform that was the current leader. The fuselage was dural semi-monocoque structure. The prototype had a three-strut landing gear. The second machine had a full-trousered leg. The tail was dural structure, fabric covered. The machine was conventional for its time, many of its characteristics having been dictated by the rigid demands for visibility and performance laid down by the Navy. None of the machines presented for the 7-Shi competition met the Navy's requirements. Nakajima had presented a carrier version of the old Army 91-type fighter, evolved by the French designer Marie. I don't know what happened to the other machines in the 7-Shi competition. Ours didn't fare too well. The original machine shed a stabiliser during a power dive test. Luckily, the pilot bailed out without any trouble. The second airplane went into a flat spin during an aerobatic test, the ship went in from a double roll. The pilot, Lt. Okamura, got out all right. Despite his bad experience with my first original design, Lt. Okamura stood by me, giving me ideas and encouragement for my further work. By 1934, the Navy eased up on size and range demands for their carrier fighters and dive bombers. By this time, I had a lot more experience and a few more original ideas. When the call came for the 9-Shi fighter, I conceived long, thin lines for the new ship instead of the thick, stubby ones. Most of the leading Navy pilots had most of their experience on the old biplane fighters. They conceded the need for speed and climb, but their tactical concept ideas still called for turning combat, the old dogfighting idea. To get the combination of speed and manoeuvrability into the airplane I desired, the answer was a light airplane. We retained the fixed landing gear in this design, since the gear constituted only 10 percent of the overall drag. A retractable gear would have raised the top speed from 400 to 410-15 km per hour. We did not figure that the increased weight and mechanical complexity of the retraction mechanism was worth the investment. The 9-Shi incorporated the use of tension-field spar webs, an idea that was brought to Japan from Rohrbach in Germany by Capt. Wada who later became Vice Admiral and Chief of the Navy's Air Headquarters. This system permitted great lightening of the wing structure. without sacrifice in strength. The 8-Shi was the first plane in Japan to use flush riveting and was probably the second design to the world to do so. The first, I believe, was Heinkel He-70. The first 9-Shi was test-flown at Kagamigahara Field in February 1935. It had a top speed of 280 mph. 03 kmph faster than the old 7-Shi and the Type 95 carrier fighter it was built to replace. The fabric-covered Nakajima machines built for the competition were sold to the local newspaper, "Asahi," to be used as liaison planes. The first 9-Shi was an inverted gull-wing job built without flaps. The ship developed a pitching motion at high angles of attack, due to the turbulent flow at the V-shaped concave part on the upper surface of the wing. Thus despite the better visibility and the weight saving afforded by this configuration, the second 9-Shi had a straight center section. The 9-Shi was undoubtedly, as the Americans call it, a "hot ship." A shallow approach was required, and the ship had a decided ballooning tendency on touchdown. It was thoroughly tested under the supervision of Lt. Comm. Yoshito Kobayashi, chief pilot of the flight test section. Its virtues were noted, particularly its speed. Its faults were analysed, and corrective measures taken. Then the ship was used for static testing. The second 9-Shi was fitted with a split flap and a larger engine, a direct-drive type, since the first machine had developed some trouble with the reduction gear system. This machine suited the rigid requirements of the Navy. On the basis of its performance, the Navy tried to cancel an order for French Dewoitine D-510's. They finally had to take two, which were kept, chiefly for the study of the motor cannon. The noted pilot Marcel Doret flew the planes on demonstration for us. We flew comparative tests against the 9-Shi at Kasumigaura Navy Field and the Mitsubishi machine proved superior on almost every point of performance. It is interesting to note that as early as 1927, Mr. Noda. then chief of the wind tunnel section and later assistant manager of Mitsubishi's Nagoya Works, filed patents on a simple split flap. Because the prophet is often without honour in his own country. Mr. Noda's flap was buried under the avalanche of foreign patents that were being purchased. It was several years before the idea was picked up and put to actual use. The gap between the final approval of the 9-Shi airframe and its final adoption as a military machine stemmed from our inability to produce a suitable power plant. A number of radial engines, varying from 800 to 900 hp were considered by the Navy. Finally, the smallest unit, the Nakajima Kotobuki 2-1 was adopted because it was the most reliable unit in production. The 9-Shi machine went into service as the Type 90-1 Carrier Fighter (A5M1). For the time being, the production machine's performance was lower than the prototype's, but it was put into production for use in the Sino-Japanese conflict which began in July of 1937. There were over a thousand of these fighters built; 800 by Mitsubishi and two hundred odd by the Sasibo Naval Arsenal and the Kyushu Aeroplane Company. Its power was progressively steeped up as better engines became available. What went into actual mass production was a type 96-4, powered with a 700 hp Kotobuki engine. During the time when the 96 was the leading Japanese fighter, we had the opportunity of running comparative tests against the Seversky P-35. We purchased ten of these for purposes of test and study, and found that the machines were heavy, unmanoeuvrable and did not compare with the performance of the Type 96 in virtually all major points. Actual combat against the Gloster Gladiator, the Curtis Model p-75, and the Russian I-15 and I-16 indicated that for most purposes, we had the superior machine. However the navy was not deluded into believing that these tests made us the tops in fighter design; It stood to reason that no country was going to export its best aircraft. For this reason, we were encouraged to improve our design and keep step with the world. The Navy determined that the next machine which was to be faster and have reasonably proportionate performance must retain greater manoeuvrability than opposing aircraft. In brief, the Navy air strategists wanted speed and climb, but they also still demanded a tight turning circle. These were exacting demands: the sole solution appeared to be in building the lightest possible airframe and keeping the wing loading as low as possible. We were forced therefore to eliminate such things as fire protection, self sealing tanks, armor plate and anything else that was weight consuming. The design specification laid down by Naval Air Command appeared impossible. We knew that Japan was a nation of limited resources. Therefore, it was important that we build what airplanes we did produce as superior machines. I had laid down three criteria for the design of a fighter: performance, producibility and ease of service. For a small country, performance was the major object - even at the cost of the other two or if need be, the safety of the crews. It was against this background of virtually impossible demands that we began work on the 12-Shi prototype in 1937. We estimated that it would take three years to produce the plane that Supreme Command wanted. Yet as the war retreated further inland in China, the range of the old 96 was proving inadequate. Even with drop tanks, it was getting more difficult as the Chinese moved the scene of battle further from the coast. The earliest designs in the 12-Shi project were built around the 875 hp 19-cylinder Mitsubishi Zue-sei engine swinging a Sumitomo two-position propeller, a Hamilton-Standard design. Later, the Nakajima Sakae, a slightly larger and more powerful engine became available, and was incorporated into the third machine. The bulk of the production Zeros carried this engine. Later, when most of the Zeros were land based, the Mitsubishi Kinsei engine was used. To achieve the performance demanded by the Navy, weight conservation was the prime order in the 12-Shi design. We built the wing in one piece, thus eliminating heavy center-section fittings. We used the smallest possible fittings to join the wing to the fuselage. The flanges of the main wing spars were made of a new type aluminium alloy called ESD. The fuselage was built in two sections for convenience in storing and for easier transport on trains. The entire structural philosophy of the 12-Shi design was aimed at lightening the structure. The plane itself was built for minimum air resistance, good control and stability. The wing area was determined on the basis of keeping the wing loading below 21.5 lbs. per square foot, in order to satisfy the take-off climb and turn requirements. The 12-Shi model used a new wing curve that was specially created for it. It has the same thickness ratio as the B-9, which had the best polar curve at the time and a similar camber line as the NACA 23012 series with a maximum camber of two percent. The new airfoil was designated as the Mitsubishi 118. Its polar curve was about the same as the B-9, but it had only about half the movement of the center of pressure. This same wing curve was used in the Type l land-based bomber. known in the U.S. as Betty. To prevent tip stall the wing was given a 2 degree washout angle. The tail surfaces of the Zeke were designed to give maximum longitudinal and directional stability. The original planforms were laid out to match that of the wing. This system used a removable tail cone. Which, we believed, would be useful for structural maintenance. This system was used in the 7-Shi series fighters. A later experimental model used a flat-sided fuselage. fairing into the rudder. Most of the Zeke series used the tail cone configuration. The vertical stabiliser and rudder on this first configuration was set above the center line and well forward of the end of the fuselage. This plane had fine spinning characteristics. Toward the end of the Zeke run. the flat-sided fuselage was used for the sake of producibility, and was also used on the later types that I designed the Raiden and Reppu. The effect of our general effort toward aerodynamic refinement showed up well in our competition with other fighters which emerged later in the war. In comparative runs with the Army fighter "Hayabusa" (Oscar) and 'Shoki' (Tojo), our design showed itself to be a prime design despite certain mechanical advantages enjoyed by the newer ones. For example. the Oscar. with its more powerful engine was equal in speed and climb and was a less manoeuvrable machine. Its gross weight and useful load was the same. In its general structural features. the Zero and the model 96 were quite similar. Aside from the obvious use of the retractable landing Rear and other improvements previously mentioned. the major change was the extensive use of the ESD high-strength aluminium alloy which was developed by the Somitomo Co. This alloy is rich to zinc and chrome. and was generally similar to other high-strength alloys. Sumitomo pioneered this held ant] their product had 30-40 per cent greater tensile strength and 70-80 per cent higher yield point than the alloys previously used. This alloy, however, had definite limitations; it has a tendency to develop cracks when rolled or extruded. Heavy extrusions had to be clad heavily with pure aluminium. and proved reliable only when these were furnished by the original supplier and were usable without bending or drawing, This limited the efficient use of the alloy to relatively small aircraft and in such applications as main spar flanges. I used the alloy only for this portion of the main beams. but they did effect a considerable weight saving. This philosophy of lightness in structure which characterised the 12-Shi or Zero was basic in its nature; we knew that we were going to have certain problems at the outset, and we were willing to take those chances in order to achieve the result we wanted. The first Zero was flown by Navy test pilots at Kagamigahara Field in July 1939. and was accepted be the Navy after 119 hours had been put in on the prototype by the company's personnel and 43 by the Navy The second machine was accepted in September 1939, and the prototype was used for static testing. there was no great pressure put on the Mitsubishi Company to produce the 12-Shi model until early in 1940, since the old 96 was held adequate for use in the Sino-Japanese operation. As a matter of fact, the first machine to be termed a Zero model was our 12-Shi land-based bomber (designated as Betty by the Americans). Performance tests were held with a number of power plants. There was a general beefing up of the airplane, especially in the power section, and minor changes were made in the control system to augment manoeuvrability. During the trial period, we lost two experimental aircraft. Out of these accidents, we learned that the ESD spars had certain structural limits, and the wing structure. particularly the spar caps, were redesigned. One of the victims was 1st Lt. Shimokawa, who was investigating flutter during a dive. Again there were structural revisions in the wing. The Zero went into service fn China, as previously stated, in mid-1940. However, there were progressive improvements in the design. Actually, no Zeros were produced after August of 1945, the end of the war, although my later designs, the Raiden and Reppu, were then being readied for production. The Zeke, as the war went on, was altered. Armament and power were varied, armor and self-sealing tanks were added. On one modification the wings were clipped to improve the rate-of-roll, general structural concessions were made to permit better diving speeds. However, we suffered to a great degree from an ultraconservative topside, who were slow to put into effective practice such changes. In summing up the defence of the design originality of the Zero, I will give credit where credit is due. As I stated previously, and as virtually all competent airplane designers will hold with me, the business of creating any new airplane is a process of adapting the existing art and science to the problem at hand. For example, I will state that the undercarriage retraction design on the Zero was inspired by the Vought 143, and that the system for fastening the engine cowl and the method of mounting the engine came from other foreign planes. Any designer who fails. out of vanity, to adapt the best techniques available to him, fails at his job. All engineers are influenced by their teachers. by their experience and by the constant stream of scientific information that is placed at their disposal. In the case of accessories, many of these were built under license from abroad; wheels were manufactured by Okomato Engineering Company under license from Bendix and Palmer, instruments were built by the Tokyo Instrument Company under license, or later in the war, by direct copy from Sperry. Pioneer and Kollsman. Sumitomo built hydromatic propellers under a license from Hamilton Standard, as well as the German VDM propeller. The Nihon Musical Instrument Co. built the Bunkers and Schwarz propellers, while the Kogusi Aircraft Company built the French Ratier propeller. We built 20-mm cannon licensed by Oerlikon of Switzerland and copies of the 13-mm (.50 cal.) Browning. In the matter of communications radio, our. material was adequate. but not in the class of the U.S. equipment. Our radar never reached full-scale use. although we had excellent research along these lines. Our power-plant development was consistently behind the U. S. and England. For example, we never developed a successful turbo-supercharger, despite the obvious need for a high-altitude power-plant. We did do a lot of early work in water-methanol injection, but this was an attempt in the direction of improving power output with 91 octane fuel. It was no match for water with 100 octane. Probably the major contribution of the Japanese during the war to the field of aviation was the ESD prime material, and the production technique developed for its proper use. I can claim, in the study of the Zero, its ancestors and descendants, that it was original to the same degree as other planes are, and that while it contains certain special features that were all its own, it serves as a prime example of a special design created to suit an unusual set of circumstances. From Air Trails, November 1950. Notes on the ESD alloy ---------------------- Almost 85 years have passed since the development of Al–Zn–Mg–Cu Extra Super Duralumin in Japan in 1936. This alloy was developed by Dr. Igarashi in response to the Japanese Navy’s order to Sumitomo to develop an alloy with tensile strength of 588 MPa (60 kg/mm2) or higher, exceeding Alcoa’s super duralumin 24S. This alloy was then adopted for use in the Zero fighter. Based on this alloy, Alcoa’s 75S was developed in 1943. This paper describes the history of the development of Extra Super Duralumin, starting with Duralumin. The paper also discusses the issues that are considered important for the future development of the aluminum alloys based on the historical review and our study. One is the relationship between quench sensitivity and age-hardening properties of Al–Zn–Mg alloys and the second is the occurrence of shear fracture in the Al–Zn–Mg–(Cu)–Zr alloys. This is the points to be noted in the development of high strength and high toughness Al–Zn–Mg–Cu alloys. See: https://www.jstage.jst.go.jp/article/matertrans/64/2/64_MT-LA2022019/_pdf/-char/en ESD alloy has a tensile yield strength of 588 MPa. For comparison 2014-T6 alloy has a tensile yield strength of 414 MPa and the 2024-T851 alloy has a tensile yield strength of 393-400 MPa. I think the 2000 series alloys where the best available in 1940.