Before HF/DF Radio direction finding was a widely used technique even before
World War I, used for both naval and aerial navigation. The basic concept used a
loop antenna, in its most basic form simply a circular loop of wire with a circumference decided by the frequency range of the signals to be detected. When the loop is aligned at right angles to the signal, the signal in the two halves of the loop cancels out, producing a sudden drop in output known as a "null". Early DF systems used a loop antenna that could be mechanically rotated. The operator would tune in a known radio station and then rotate the antenna until the signal disappeared. This meant that the antenna was now at right angles to the broadcaster, although it could be on either side of the antenna. By taking several such measurements, or using some other form of navigational information to eliminate one of the ambiguous directions, the
bearing to the broadcaster could be determined. In 1907, an improvement was introduced by Ettore Bellini and Alessandro Tosi that greatly simplified the DF system in some setups. The single loop antenna was replaced by two antennas, arranged at right angles. The output of each was sent to its own looped wire, or as they are referred to in this system, a "field coil". Two such coils, one for each antenna, are arranged close together at right angles. The signals from the two antennas generated a
magnetic field in the space between the coils, which was picked up by a rotating
solenoid, the "search coil". The maximum signal was generated when the search coil was aligned with the magnetic field from the field coils, which was at the angle of the signal in relation to the antennas. This eliminated any need for the antennas to move. The
Bellini–Tosi direction finder (B-T) was widely used on ships, although rotating loops remained in use on aircraft as they were normally smaller. All of these devices took time to operate. Normally the radio operator would first use conventional radio tuners to find the signal in question, either using the DF antenna(s) or on a separate
non-directional antenna. Once tuned, the operator rotated the antennas or
goniometer looking for peaks or nulls in the signal. Although the rough location could be found by spinning the control rapidly, for more accurate measurements the operator had to "hunt" with increasingly small movements. With periodic signals like
Morse code, or signals on the fringe of reception, this was a difficult process. Fix times on the order of one minute were commonly quoted. Some work on automating the B-T system was carried out just prior to the opening of World War II, especially by French engineers
Maurice Deloraine and
Henri Busignies, working in the French division of the American
Corporation. Their system motorized the search coil as well as a circular display card, which rotated in sync. A lamp on the display card was tied to the output of the goniometer, and flashed whenever it was in the right direction. When spinning quickly, about 120 RPM, the flashes merged into a single (wandering) dot that indicated the direction. The team destroyed all of their work in the French office and left France in 1940, just before Germany invaded, and continued the development in the US.
Watson-Watt It had long been known that
lightning emits radio signals. The signal is spread across many frequencies but is particularly strong in the
longwave spectrum, which was one of the primary radio frequencies for long-range naval communications.
Robert Watson-Watt had demonstrated that measurements of these radio signals could be used to track
thunderstorms and provide useful long-range warning for pilots and ships. In some experiments he was able to detect thunderstorms over Africa, away. The lightning strikes lasted such a short time that traditional RDF systems using loop antennas could not determine the
bearing before they vanished. but did not have the ability to test this. Watt worked at the
RAF's Met Office in
Aldershot, but in 1924 they decided to return the location for use by other units in the RAF. In July 1924 Watt moved to a new site at
Ditton Park near
Slough. This site already hosted the
National Physical Laboratory (NPL) Radio Section research site. Watt was involved in the Atmospherics branch, making basic studies in the propagation of radio signals through the atmosphere, while the NPL were involved in field strength measurements in the field and direction finding investigations. NPL had two devices used in these studies that would prove critical to the development of huff-duff, an
Adcock antenna and a modern
oscilloscope. The Adcock antenna is an arrangement of four monopole masts connected electrically to act as two virtual loop antennas arranged at right angles. By comparing the signals received on the two virtual loops, the direction to the signal can be determined using existing RDF techniques. Researchers had set up the antenna in 1919 but had been neglecting it in favour of smaller designs. These were found to have very poor performance due to the electrical characteristics of the Slough area, which made it difficult to determine if a signal was being received on a straight line or down from the sky. Smith-Rose and Barfield turned their attention back to the Adcock antenna, which had no horizontal component and thus filtered out the "skywaves". In a series of follow-up experiments they were able to accurately determine the location of transmitters around the country. It was Watt's continuing desire to capture the location of individual lightning strikes that led to the final major developments in the basic huff-duff system. The lab had recently taken delivery of a WE-224 oscilloscope from
Bell Labs, which provided easy hook-up and had a persistent
phosphor. Working with Jock Herd, in 1926 Watt added an amplifier to each of the two arms of the antenna, and sent those signals into the X and Y channels of the oscilloscope. As hoped, the radio signal produced a pattern on the screen that indicated the direction of the strike, and the slow-decay phosphor gave the operator ample time to measure it before the display faded. Watt and Herd wrote an extensive paper on the system in 1926, referring to it as "an instantaneous direct-reading radiogoniometer" and stating that it could be used to determine the direction of signals lasting as little as 0.001 seconds. The paper describes the device in depth, and goes on to explain how it could be used to improve radio direction finding and navigation. Despite this public demonstration, and films showing it being used to locate lightning, the concept apparently remained unknown outside the UK. This allowed it to be developed into practical form in secret.
Battle of Britain During the rush to install the
Chain Home (CH)
radar systems prior to the
Battle of Britain, CH stations were located as far forward as possible, along the shoreline, in order to provide maximum warning time. This meant that the inland areas over the
British Isles did not have radar coverage, relying instead on the
Observer Corps (later Royal Observer Corps) for visual tracking in this area. While
the Observer Corps were able to provide information on large raids, fighters were too small and too high to be positively identified. As the entire
Dowding system of air control relied on ground direction, some solution to locating their own fighters was needed. The expedient solution to this was the use of huff-duff stations to tune in on the fighter's radios. Every Sector Control, in charge of a selection of fighter squadrons, was equipped with a huff-duff receiver, along with two other sub-stations located at distant points, about away. These stations would listen for broadcasts from the fighters, compare the angles to
triangulate their location, and then relay that information to the control rooms. Comparing the positions of the enemy reported by the Observer Corps and the fighters from the huff-duff systems, the Sector Commanders could easily direct the fighters to intercept the enemy. To aid in this process, a system known as "
pip-squeak" was installed on some of the fighters, at least two per section (with up to four sections per squadron). Pip-squeak automatically sent out a steady tone for 14 seconds every minute, offering ample time for the huff-duff operators to track the signal. It had the drawback of tying up the aircraft's radio while broadcasting its DF signal. The need for DF sets was so acute that the
Air Ministry initially was unable to supply the numbers requested by
Hugh Dowding, commander of
RAF Fighter Command. In simulated battles during 1938 the system was demonstrated to be so useful that the Ministry responded by providing
Bellini-Tosi systems with the promise that CRT versions would replace them as soon as possible. This could be accomplished in the field, simply by connecting the existing antennas to a new receiver set. By 1940 these were in place at all 29 Fighter Command "sectors", and were a major part of the system that won the battle.
Battle of the Atlantic from-which signals are received - red numerals for to
port of the ship, green for to
starboard Along with
sonar ("ASDIC"),
intelligence from breaking German codes, and
radar, "Huff-Duff" was a valuable part of the Allies' armoury in detecting German U-boats and
commerce raiders during the
Battle of the Atlantic. The
Kriegsmarine knew that radio direction finders could be used to locate its ships at sea when those ships transmitted messages. Consequently, they developed a system that turned routine messages into short-length messages. The resulting "
kurzsignale" was then encoded with the
Enigma machine (for security) and transmitted quickly. An experienced radio operator might take about 20 seconds to transmit a typical message. Had the UK been using B-T systems, the only system known to the Germans at the time, determining the location of such a transmission would have required considerable luck. With huff-duff, these messages were more than long enough to easily measure. At first, the UK's detection system consisted of a number of shore stations in the British Isles and North Atlantic, which would coordinate their interceptions to determine locations. The distances involved in locating U-boats in the Atlantic from shore-based DF stations were so great, and DF accuracy was relatively inefficient, so the fixes were not particularly accurate. In 1944, a new strategy was developed by Naval Intelligence where localized groups of five shore-based DF stations were built so the bearings from each of the five stations could be averaged to gain a more reliable bearing. Four such groups were set up in Britain: at
Ford End in Essex,
Anstruther in Fife, Bower in the Scottish Highlands and
Goonhavern in Cornwall. It was intended that other groups would be set up in Iceland, Nova Scotia and Jamaica. Simple averaging was found to be ineffective, and statistical methods were later used. Operators were also asked to grade the reliability of their readings so that poor and variable ones were given less weight than those that appeared stable and well-defined. Several of these DF groups continued into the 1970s as part of the
Composite Signals Organisation. Land-based systems were used because there were severe technical problems operating on ships, mainly due to the effects of the superstructure on the wavefront of arriving radio signals. These problems were overcome under the technical leadership of the Polish engineer
Wacław Struszyński, working at the Admiralty Signal Establishment. As ships were equipped, a complex measurement series was carried out to determine these effects, and cards were supplied to the operators to show the required corrections at various frequencies. By 1942, the availability of CRTs improved and was no longer a limit on the number of huff-duff sets that could be produced. At the same time, improved sets were introduced that included continuously motor-driven tuning, to scan the likely frequencies and sound an automatic alarm when any transmissions were detected. Operators could then rapidly fine-tune the signal before it disappeared. These sets were installed on convoy escorts, enabling them to get fixes on U-boats transmitting from over the horizon, beyond the range of radar. This allowed hunter-killer ships and aircraft to be dispatched at high speed in the direction of the U-boat, which could be located by radar if still on the surface or ASDIC if submerged. From August 1944, Germany was working on the
Kurier system, which would transmit an entire
kurzsignale in a
burst not longer than 454 milliseconds, too short to be located, or intercepted for decryption, but the system had not become operational by the end of the war. ==Description==