Early work The Norden sight was designed by
Carl Norden, a Dutch engineer educated in
Switzerland who immigrated to the U.S. in 1904. In 1911, Norden joined
Sperry Gyroscope to work on ship gyrostabilizers, and then moved to work directly for the U.S. Navy as a consultant. At the Navy, Norden worked on a catapult system for a proposed
flying bomb that was never fully developed, but this work introduced various Navy personnel to Norden's expertise with gyro stabilization.
World War I bomb sight designs had improved rapidly, with the ultimate development being the
Course Setting Bomb Sight, or CSBS. This was essentially a large
mechanical calculator that directly represented the
wind triangle using three long pieces of metal in a triangular arrangement. The
hypotenuse of the triangle was the line the aircraft needed to fly along in order to arrive over the target in the presence of wind, which, before the CSBS, was an intractable problem. Almost all air forces adopted some variation of the CSBS as their standard inter-war bomb sight, including the U.S. Navy, who used a modified version known as the
Mark III. It was already realized that one major source of error in bombing was levelling the aircraft enough so the bombsight pointed straight down, even small errors in levelling could produce dramatic errors in accuracy. The US Army did not adopt the CSBS and instead used a simpler design, the
Estoppey D-series, as it automatically levelled the sight during use. Navy experiments showed these roughly doubled accuracy, so they began a series of developments to add a
gyroscopic stabilizer to their bombsights. In addition to new designs like the
Inglis (working with Sperry) and
Seversky, the Navy also asked Norden to provide an external stabilizer for the existing Mark III designs.
Mark III-A Although the CSBS and similar designs allowed the
calculation of the proper flight angle needed to correct for
windage, they did so by looking downward out of the aircraft. Very simple bombsights could be operated by the pilot, but as their sophistication grew they demanded full-time operators. This task was often given to the front or rear gunner. In Army aircraft they would sit near enough to the pilot to indicate any required directional adjustments using hand signals, or if they sat behind the pilot, using strings attached to the pilot's jacket. The Navy's first bombers were large
flying boats, where the pilot sat well away from the front of the
fuselage, and one could not simply cut a hole through the hull for the bombsight to view through. Instead, the bombs were normally aimed by an observer in the nose of the aircraft. This made communications with the pilot very difficult. To address this, the Navy developed the concept of the
pilot direction indicator, or PDI, an electrically-driven pointer that the observer used to indicate which direction to turn. The bombardier used switches to move the pointer on his unit to indicate the direction of the target, which was duplicated on the unit in front of the pilot so he could maneuver the aircraft to follow suit. Norden's attempt to fit a stabilizer to the Mark III, the Mark III-A, also included a separate contract to develop a new automatic PDI. Norden proposed removing the electrical switches used to move the pointer and using the entire bombsight itself as the indicator. Instead of the thin metal wires that formed the sights on the Mark III, a small low-power telescope would be used in its place. The bombardier would rotate the telescope left or right to follow the target. This motion would cause the gyros to
precess, and this signal would drive the PDI automatically. The pilot would follow the PDI as before. Norden initially delivered three prototypes of the stabilized bombsight without the automatic PDI. In testing, the Navy found that while the system did improve accuracy when it worked, it was complicated to use and often failed, leaving the real-world accuracy no better than before. They asked Norden for suggestions on ways to improve this. They were still interested in the PDI work, and the contract was allowed to continue.
Mark XI Norden suggested that the only solution to improve accuracy would be to directly measure the ground speed, as opposed to calculating it using the CSBS's wind triangle. To time the drop, Norden used an idea already in use on other bombsights, the "equal distance" concept. This was based on the observation that the time needed to travel a certain distance over the ground would remain relatively constant during the bomb run, as the wind would not be expected to change dramatically over a short period of time. If you could accurately mark out a distance on the ground, or in practice, an angle in the sky, timing the passage over that distance would give you all the information needed to time the drop. Norden's version of the system was very similar to the Army's Estoppey D-4 of the same era, differing largely in the physical details of the actual sights. The D-4 used thin wires as the sights, while Norden's would use the small telescope of the Mark III-A. To use the system, the bombardier looked up the expected time it would take for the bombs to fall from the current altitude. This time was set into a countdown
stopwatch, and the sights were set to the angle that the bombs would fall if there was no wind. The bombardier waited for the target to line up with a crosshair in the telescope. When it did, the timer was started, and the bombardier rotated the telescope around its vertical axis to track the target as they flew toward it. This movement was linked to a second crosshair through a gearing system. The bombardier continued moving the telescope until the timer ran out. The second crosshair was now at the correct aiming angle, or
range angle, after accounting for any difference between groundspeed and airspeed. The bombardier then waited for the target to pass through the second crosshair to time the drop. In 1924, the first prototype of this design, known to the Navy as the Mark XI, was delivered to the Navy's proving grounds in Virginia. In testing, the system proved disappointing. The
circular error probable (CEP), a circle into which 50% of the bombs would fall, was wide from only altitude. This was an error of over 3.6%, somewhat worse than existing systems. Moreover, bombardiers universally complained that the device was far too hard to use. Norden worked tirelessly on the design, and by 1928, the accuracy had improved to 2% of altitude. This was enough for the Navy's
Bureau of Ordnance to place a US$348,000 contract (equivalent to $ million in ) for 80 production examples. Norden was known for his confrontational and volatile nature. He often worked 16-hour days and thought little of anyone who did not. Navy officers began to refer to him as "Old Man Dynamite". During development, the Navy asked Norden to consider taking on a partner to handle the business and leave Norden free to develop the engineering side. They recommended former Army colonel Theodore Barth, an engineer who had been in charge of gas mask production during World War I. The match-up was excellent, as Barth had the qualities Norden lacked: charm, diplomacy, and a head for business. The two became close friends.
Initial U.S. Army interest In the December of 1927, the
United States Department of War was granted permission to use a bridge over the
Pee Dee River in North Carolina for target practice, as it would soon be sunk in the waters of a new dam. The
1st Provisional Bombardment Squadron, equipped with
Keystone LB-5 bombers, attacked the bridge over a period of five days, flying 20 missions a day in perfect weather and attacking at altitudes from . After this massive effort, the middle section of the bridge finally fell on the last day. However, the effort as a whole was clearly a failure in any practical sense. About the same time as the operation was being carried out, General
James Fechet replaced General
Mason Patrick as commander of the USAAC. He received a report on the results of the test, and on 6 January 1928 sent out a lengthy memo to Brigadier General William Gillmore, chief of the Material Division at
Wright Field, stating: He went on to request information on every bombsight then used at Wright, as well as "the Navy's newest design". However, the Mark XI was so secret that Gillmore was not aware Fechet was referring to the Norden. Gilmore produced contracts for twenty-five examples of an improved version of the Seversky C-1, the C-3, and six prototypes of a new design known as the Inglis L-1. The L-1 never matured, and Inglis later helped Seversky to design the improved C-4. The wider Army establishment became aware of the Mark XI in 1929 and was eventually able to buy an example in 1931. Their testing mirrored the Navy's experience; they found that the gyro stabilization worked and the sight was accurate, but it was also "entirely too complicated" to use. The Army turned its attention to further upgraded versions of their existing prototypes, replacing the older vector bombsight mechanisms with the new synchronous method of measuring the proper dropping angle.
Fully automatic bombsight While the Mk. XI was reaching its final design, the Navy learned of the Army's efforts to develop a synchronous bombsight, and asked Norden to design one for them. Norden was initially unconvinced this was workable, but the Navy persisted and offered him a development contract in June 1929. Norden retreated to his mother's house in
Zürich and returned in 1930 with a working prototype. Lieutenant Frederick Entwistle, the Navy's chief of bombsight development, judged it revolutionary. The new design, the Mark XV, was delivered in production quality in the summer of 1931. In testing, it proved to eliminate all of the problems of the earlier Mk. XI design. From altitude the prototype delivered a CEP of , while even the latest production Mk. XI's were . At higher altitudes, a series of 80 bomb runs demonstrated a CEP of . In a test on 7 October 1931, the Mk. XV dropped 50% of its bombs on a static target, the
USS Pittsburgh, while a similar aircraft with the Mk. XI had only 20% of its bombs hit. Moreover, the new system was dramatically simpler to use. After locating the target in the sighting system, the bombardier simply made fine adjustments using two control wheels throughout the bomb run. There was no need for external calculation, lookup tables or pre-run measurementseverything was carried out automatically through an internal
wheel-and-disc calculator. The calculator took a short time to settle on a solution, with setups as short as six seconds, compared to the 50 needed for the Mk. XI to measure its ground speed. In most cases, the bomb run needed to be only 30 seconds long. Despite this success, the design also demonstrated several serious problems. In particular, the gyroscopic platform had to be levelled out before use using several
spirit levels, and then checked and repeatedly reset for accuracy. Worse, the gyros had a limited degree of movement, and if the plane banked far enough the gyro would reach its limit and have to be re-set from scratch – something that could happen even due to strong
turbulence. If the gyros were found to be off, the levelling procedure took as long as eight minutes. Other minor problems were the
direct current electric motors which drove the gyroscopes, whose brushes wore down quickly and left carbon dust throughout the interior of the device, and the positioning of the control knobs, which meant the bombardier could only adjust side-to-side or up-and-down aim at a time, not both. But despite all of these problems, the Mark XV was so superior to any other design that the Navy ordered it into production. The Carl L. Norden Company was incorporated in 1931, supplying the sights under a dedicated source contract. In effect, the company was owned by the Navy. In 1934 the newly-forming GHQ Air Force, the purchasing arm of the
U.S. Army Air Corps, selected the Norden for their bombers as well, referring to it as the M-1. However, due to the dedicated source contract, the Army had to buy the sights from the Navy. This was not only annoying for inter-service rivalry reasons, but the Air Corps' higher-speed bombers demanded several changes to the design, notably the ability to aim the sighting telescope further forward to give the bombardier more time to set up. The Navy was not interested in these changes, and would not promise to work them into the production lines. Worse, Norden's factories were having serious problems keeping up with demand for the Navy alone, and in January 1936, the Navy suspended all shipments to the Army.
Autopilot Mk. XV's were initially installed with the same automatic PDI as the earlier Mk. XI. In practice, it was found that the pilots had a very difficult time keeping the aircraft stable enough to match the accuracy of the bombsight. Starting in 1932 and proceeding in fits and starts for the next six years, Norden developed the Stabilized Bombing Approach Equipment (SBAE), a mechanical autopilot that attached to the bombsight. However, it was not a true "autopilot", in that it could not fly the aircraft by itself. By rotating the bombsight in relationship to the SBAE, the SBAE could account for wind and turbulence and calculate the appropriate directional changes needed to bring the aircraft onto the bomb run far more precisely than a human pilot. The minor adaptations needed on the bombsight itself produced what the Army referred to as the M-4 model. In 1937 the Army, faced with the continuing supply problems with the Norden, once again turned to
Sperry Gyroscope to see if they could come up with a solution. Their earlier models had all proved unreliable, but they had continued working with the designs throughout this period and had addressed many of the problems. By 1937, Orland Esval had introduced a new AC-powered electrical gyroscope that spun at 30,000 RPM, compared to the Norden's 7,200, which dramatically improved the performance of the inertial platform. The use of three-phase AC power and inductive pickup eliminated the carbon brushes, and further simplified the design. Carl Frische had developed a new system to automatically level the platform, eliminating the time-consuming process needed on the Norden. The two collaborated on a new design, adding a second gyro to handle heading changes, and named the result the
Sperry S-1. Existing supplies of Nordens continued to be supplied to the USAAC's B-17s, while the S-1 equipped the B-24Es being sent to the 15th Air Force. Some B-17s had been equipped with a simple heading-only autopilot, the Sperry A-3. The company had also been working on an all-electronic model, the A-5, which stabilized in all three directions. By the early 1930s, it was being used in a variety of Navy aircraft to excellent reviews. By connecting the outputs of the S-1 bombsight to the A-5 autopilot, Sperry produced a system similar to the M-4/SBAE, but it reacted far more quickly. The combination of the S-1 and A-5 so impressed the Army that on 17 June 1941 they authorized the construction of a factory and noted that "in the future all production models of bombardment airplanes be equipped with the A-5 Automatic Pilot and have provisions permitting the installation of either the M-Series [Norden] Bombsight or the S-1 Bombsight".
British interest, Tizard mission By 1938, information about the Norden had worked its way up the
Royal Air Force chain of command and was well known within that organization. The British had been developing a tachometric bombsight of their own known as the Automatic Bomb Sight, but combat experience in 1939 demonstrated the need for it to be stabilized. Work was underway as the
Stabilized Automatic Bomb Sight (SABS), but it would not be available until 1940 at the earliest, and likely later. Even then, it did not feature the autopilot linkage of the Norden, and would thus find it difficult to match the Norden's performance in anything but smooth air. Acquiring the Norden became a major goal. The RAF's first attempt, in the spring of 1938, was rebuffed by the U.S. Navy. Air Chief Marshal
Edgar Ludlow-Hewitt, commanding
RAF Bomber Command, demanded
Air Ministry action. They wrote to
George Pirie, the British air attaché in Washington, suggesting he approach the U.S. Army with an offer of an information exchange with their own SABS. Pirie replied that he had already looked into this, and was told that the U.S. Army had no licensing rights to the device as it was owned by the U.S. Navy. The matter was not helped by a minor diplomatic issue that flared up in July when a French
air observer was found to be on board a crashed
Douglas Aircraft Company bomber, forcing
President Roosevelt to promise no further information exchanges with foreign powers. Six months later, after a change of leadership within the U.S. Navy's
Bureau of Aeronautics, on 8 March 1939, Pirie was once again instructed to ask the U.S. Navy about the Norden, this time enhancing the deal with offers of British power-operated turrets. However, Pirie expressed concern as he noted the Norden had become as much political as technical, and its relative merits were being publicly debated in Congress weekly while the U.S. Navy continued to say the Norden was "the United States' most closely guarded secret". The RAF's desires were only further goaded on 13 April 1939, when Pirie was invited to watch an air demonstration at
Fort Benning where the painted outline of a battleship was the target: The three following B-17s also hit the target, and then a flight of a dozen
Douglas B-18 Bolos placed most of their bombs in a separate square outlined on the ground. Another change of management within the Bureau of Aeronautics had the effect of making the U.S. Navy more friendly to British overtures, but no one was willing to fight the political battle needed to release the design. The Navy brass was concerned that giving the Norden to the RAF would increase its chances of falling into German hands, which could put the U.S.'s own fleet at risk. The UK Air Ministry continued increasing pressure on Pirie, who eventually stated there was simply no way for him to succeed, and suggested the only way forward would be through the highest diplomatic channels in the Foreign Office. Initial probes in this direction were also rebuffed. When a report stated that the Norden's results were three to four times as good as their own bombsights, the Air Ministry decided to sweeten the pot and suggested they offer information on
radar in exchange. This too was rebuffed. The matter eventually worked its way to the Prime Minister,
Neville Chamberlain, who wrote personally to President Roosevelt asking for the Norden, but even this was rejected. The reason for these rejections was more political than technical, but the U.S. Navy's demands for secrecy were certainly important. They repeated that the design would be released only if the British could demonstrate the basic concept was common knowledge, and therefore not a concern if it fell into German hands. The British failed to convince them, even after offering to equip their examples with a variety of self-destruct devices. This may have been ameliorated by the winter of 1939, at which point a number of articles about the Norden appeared in the U.S. popular press with reasonably accurate descriptions of its basic workings. But when these were traced back to the press corps at the U.S. Army Air Corps, the U.S. Navy was apoplectic. Instead of accepting it was now in the public domain, any discussion about the Norden was immediately shut down. This drove both the British Air Ministry and
Royal Navy to increasingly anti-American attitudes when they considered sharing their own developments, notably newer
ASDIC systems. By 1940 the situation on scientific exchange was entirely deadlocked as a result. Looking for ways around the deadlock,
Henry Tizard sent
Archibald Vivian Hill to the U.S. to take a survey of U.S. technical capability in order to better assess what technologies the U.S. would be willing to exchange. This effort was the start on the path that led to the famous
Tizard Mission in late August 1940. Ironically, by the time the Mission was being planned, the Norden had been removed from the list of items to be discussed, and Roosevelt personally noted this was due largely to political reasons. Ultimately, although Tizard was unable to convince the U.S. to release the design, he was able to request information about its external dimensions and details on the mounting system so it could be easily added to British bombers if it were released in the future.
Production, problems, and Army standardization , Kansas, now listed on the National Register for Historic Places. The conversion of Norden Laboratories Corporation's New York City engineering lab to a production factory was a long process. Before the war, skilled craftsmen, most of them German or Italian immigrants, hand-made almost every part of the 2,000-part machine. Between 1932 and 1938, the company produced only 121 bombsights per year. During the first year after the
Attack on Pearl Harbor, Norden produced 6,900 bombsights, three-quarters of which went to the U.S. Navy. When Norden heard of the U.S. Army's dealings with Sperry, Theodore Barth called a meeting with the U.S. Army and U.S. Navy at their factory in New York City. Barth offered to build an entirely new factory just to supply the U.S. Army, but the U.S. Navy refused this. Instead, the U.S. Army suggested that Norden adapt their sight to work with Sperry's A-5, which Barth refused. Norden actively attempted to make the bombsight incompatible with the A-5. It was not until 1942 that the impasse was finally solved by farming out autopilot production to
Honeywell Regulator, who combined features of the Norden-mounted SBAE with the aircraft-mounted A-5 to produce what the U.S. Army referred to as "Automatic Flight Control Equipment" (AFCE); the unit would later be redesigned as the C-1. The Norden, now connected with the aircraft's built-in autopilot, allowed the bombardier alone to fully control minor movements of the aircraft during the bombing run. By May 1943 the U.S. Navy was complaining that they had a surplus of devices, with full production turned over to the USAAF. After investing more than $100 million (equivalent to $ billion in ) in Sperry bombsight manufacturing plants, the USAAF concluded that the Norden M-series was far superior in accuracy, dependability, and design. Sperry contracts were cancelled in November 1943. When production ended a few months later, 5,563 Sperry bombsight-autopilot combinations had been built, most of which were installed in
Consolidated B-24 Liberator bombers. Expansion of Norden bombsight production to a final total of six factories took several years. The USAAF demanded additional production to meet their needs, and eventually arranged for the
Victor Adding Machine company to gain a manufacturing license, and then
Remington Rand. Ironically, during this period the U.S. Navy abandoned the Norden in favor of dive bombing, reducing the demand. By the end of the war, Norden and its subcontractors had produced 72,000 M-9 bombsights for the U.S. Army Air Force alone, costing $8,800 each (). ==Description and operation==