Definitions

Radio proximity fuze

Proximity fuze

A proximity fuze (also called a VT fuze, for "variable time") is a fuze that is designed to detonate an explosive device automatically when the distance to target becomes smaller than a predetermined value or when the target passes through a given plane. There are different sensing principles:

  • radio frequency sensing
  • optical sensing
  • acoustic sensing
  • magnetic sensing
  • pressure sensing

Radio frequency sensing

Radio frequency sensing is the main sensing principle for shells and this is mostly in mind when one speaks of "proximity fuzes".

The WWII patent works as follows: The shell contains a micro-transmitter which uses the shell body as an antenna and emits a continuous wave of roughly 180 - 220 MHz. As the shell approaches a reflecting object, an interference pattern is created. This pattern changes with shrinking distance: every half wavelength in distance (a half wavelength at this frequency is about 0.7 meters), the transmitter is in or out of resonance. This causes a small oscillation of the radiated power and consequently the oscillator supply current of about 200 - 800 Hz, the Doppler frequency. This signal is sent through a band pass filter, amplified, and triggers the detonation when it exceeds a given amplitude.

History

Before the fuze's invention, detonation had to be induced by direct contact, a timer set at launch, or an altimeter. All of these have disadvantages. The probability of a direct hit with a relatively small moving target is low; to set a time- or height-triggered fuze one must measure the height of the target (or even predict the height of the target at the time one will be able to get a shell or missile in its neighbourhood). With a proximity fuze, all one has to worry about is getting a shell or missile on a trajectory that, at some time, will pass close by the target. This is still not a trivial task, but it is much easier to execute than previous methods.

Use of timing to produce air bursts against ground targets requires observers to provide information for adjusting the timing. This is not practical in many situations and is slow in any event. Proximity fuzes fitted to such weapons as artillery and mortar shells solve this problem by having a range of pre-set burst heights (e.g. 2, 4 or 10 metres) above ground, which can be selected by gun crews prior to firing.

The radio frequency proximity fuze concept was proposed to the British Air Defense Establishment in a May, 1940, memo from William A. S. Butement, Edward S. Shire, and Amherst F.H. Thompson. A breadboard circuit was constructed by the inventors and the concept was tested in the laboratory by moving a sheet of tin at various distances. Early field testing connected the circuit to a thyratron trigger operating a tower-mounted camera which photographed passing aircraft to determine distance of fuze function. Prototype fuzes were then constructed in June, 1940, and installed in unrotated projectiles fired at targets supported by balloons. The details of these experiments were passed to the United States Naval Research Laboratory and National Defense Research Committee (NDRC) in September, 1940, in accordance with an informal agreement between Winston Churchill and Franklin D. Roosevelt to exchange scientific information of potential military value.

Following receipt of details from the British, the experiments were successfully duplicated by Richard B. Roberts, Henry H. Porter, and Robert B. Brode under the direction of NDRC section T chairman Merle Tuve. Lloyd Berkner of Dr. Tuve's staff devised an improved fuze using separate tubes for transmission and reception. In December, 1940, Dr. Tuve invited Harry Diamond and Wilford S. Hinman, Jr, of the United States National Bureau of Standards (NBS) to investigate Berkner's improved fuze. The NBS team built six fuzes which were placed in air-dropped bombs and successfully tested over water on 6 May 1941.

Parallel NDRC work focused on anti-aircraft fuzes. Major problems included microphonic difficulties and tube failures attributed to vibration and acceleration in gun projectiles. The T-3 fuze had a 52 percent success against a water target when tested in January, 1942. The United States Navy accepted that failure rate and USS Cleveland (CL-55) tested proximity fuzed ammunition against drone aircraft targets over Chesapeake Bay in August 1942. The tests were so successful that all target drones were destroyed before testing was complete. Proximity fuzes promptly went into large scale production.

Vannevar Bush, head of the U.S. Office of Scientific Research and Development (OSRD) during this war, credited it with three significant effects. It was important in defense from Japanese Kamikaze attacks in the Pacific. It was an important part of the radar-controlled anti-aircraft batteries that finally neutralized the German V-1 bomb attacks on England. Third, it was released for use in land warfare for use in the Battle of the Bulge, where it decimated German divisions caught in the open. The Germans felt safe from timed fire because the weather prevented accurate observation. Bush cites an estimated seven times increase in the effect of artillery with this innovation.

Optical sensing

Optical sensing was also developed first in WWII, mainly for anti-aircraft missiles. It used then a toroidal lens, that concentrated all light out of a plane perpendicular to the missile's main axis onto a photo cell. When the cell current changed a certain amount in a certain time interval, the detonation was triggered.

Some modern air-to-air missiles make use of lasers. They project narrow beams of laser light perpendicular to the flight of the missile. As the missile cruises towards the target the laser energy simply beams out into space. However, as the missile passes its target some of the laser energy strikes the target and is reflected back towards the missile where detectors sense the reflected laser energy and trigger the missile warhead.

Acoustic sensing

Acoustic sensing used a microphone in a missile. The characteristic frequency of an aircraft engine is filtered and triggered the detonation. This principle was applied in German anti-aircraft missiles, which were mostly still in development when the war ended.

Naval mines can also use acoustic sensing, with modern versions able to be programmed to "listen" for the signature of a specific ship.

Magnetic sensing

Magnetic sensing can only be applied to detect huge masses of iron such as ships. It is used in mines and torpedoes. Fuzes of this type can be defeated by degaussing, using non-metal hulls for ships (especially minesweepers) or by magnetic induction loops fitted to aircraft or towed buoys.

Pressure sensing

Some naval mines are able to detect the pressure wave of a ship passing overhead.

References

Further reading

  • Pieces of the Action by Vannevar Bush, William Morrow and Co., inc. 1970
  • An account of the development and initial introduction of proximity fuzes is given in The Deadly Fuze by Ralph B Baldwin (UK Edition published by Janes, 1980. ISBN 0-354-01243-6. Dr Baldwin was a member of the Johns Hopkins University Applied Physics Laboratory (APL) team headed by Merle A Tuve that did most of the work.

See also

  • M734 proximity fuze

Images

External links

  • http://www.history.navy.mil/faqs/faq96-1.htm
  • http://www.amc.army.mil/amc/ho/studies/fuze.html
  • http://www.smecc.org/radio_proximity_fuzes.htm
  • http://www.microworks.net/pacific/equipment/vt_fuze.htm
  • http://www.smecc.org/pfuze.htm
  • http://www.tubedata.org/unknown_sylvania/050123CL/US3166015.pdf
  • http://www.tubedata.org/unknown_sylvania/050123CL/US3113235.pdf
  • http://www.jhuapl.edu/aboutapl/heritage/default.asp

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