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===History===
The problem of aiming a [[torpedo]] has occupied military engineers since [[Robert Whitehead (engineer)|Robert Whitehead]] developed the modern torpedo in the 1860s. These early torpedoes ran at a preset depth on a straight course (consequently they are frequently referred to as "straight runners"). This was the state of the art in torpedo guidance until the development of the [[homing torpedo]] during the latter part of [[World War II]].<ref name=othertorps>There were other forms of torpedo guidance attempted throughout WWII. Notable are the Japanese human-guided ''[[Kaiten]]'' and German [[G7e#G7e/T3|pattern running]] and [[acoustic homing]] types for attacking convoys. Today, most submarine-launched torpedoes are wire-guided with terminal homing.</ref> The vast majority of submarine torpedoes during World War II were straight running, and these continued in use for many years after World War II.<ref name=USMk14his>{{cite web|url = http://www.geocities.com/Pentagon/1592/ustorp5.htm|title= Part Five: Post WW-II Submarine Launched/ Heavyweight Torpedoes|access-date=2006-07-26|author= Frederick J Milford|date= October 1997|work= US Navy Torpedoes|archive-url=https://web.archive.org/web/20060523064716/http://www.geocities.com/Pentagon/1592/ustorp5.htm|archive-date=2006-05-23}}</ref> In fact, two World War II-era straight running torpedoes — fired by the British nuclear-powered submarine {{HMS|Conqueror|S48|6}} — sank {{ship|ARA|General Belgrano}} in 1982.
During [[World War I]], computing a target intercept course for a torpedo was a manual process where the fire control party was aided by various [[slide rule]]s<ref name=fleetsub>{{cite web | title = Torpedo Data Computer | work = FleetSubmarine.com | year = 2002 | url = http://www.maritime.org/tdc.htm | access-date = 2006-07-03 | archive-date = 2012-07-17 | archive-url = https://web.archive.org/web/20120717035001/http://maritime.org/tech/tdc.htm | url-status = dead }}</ref> (the U.S. examples were the [[Mark VIII Angle Solver]] (colloquially called the "banjo", for its shape), and the "Is/Was" circular sliderule ([[Nasmith Director]]), for predicting where a target will be based on where it is now and was)<ref>Holwitt, Joel I. ''"Execute Against Japan"'', Ph.D. dissertation, Ohio State University, 2005, p.147; Beach, Edward L., Jr. ''Run Silent, Run Deep''.</ref> or mechanical calculator/sights.<ref name = dread>{{cite web |title = Firing a Torpedo Using A Mechanical Computing Sight |work=The Dreadnought Project |url =http://www.dreadnoughtproject.org/tfs/index.php/Torpedo_Director|year=2000
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In 1932, the [[Bureau of Ordnance]] (BuOrd) initiated development of the TDC with [[Arma Corporation]] and [[Ford Instruments]].<ref name="Holwitt, p.147">Holwitt, p.147.</ref> This culminated in the "very complicated" Mark 1 in 1938.<ref name="Holwitt, p.147"/> This was retrofitted into older boats, beginning with {{USS|Dolphin|SS-169|2}} and up through the newest {{sclass|Salmon|submarine|5}}s.<ref name="Holwitt, p.147"/>
The first submarine designed to use the TDC was {{USS|Tambor|SS-198|2}},<ref name=Tambor>{{cite web | last = Mohl | first = Michael | title = Tambor (SS-198) |
In 1943, the Torpedo Data Computer Mark IV was developed to support the [[Mark 18 torpedo|Mark 18]] torpedo.<ref name=Mk18>The Mark 18 was electric and therefore wakeless and difficult for surface forces to trace. On the downside, it was slower than the Mark 14. This made it more difficult to aim accurately because larger gyro angles were involved. Even so, thousands of them were fired during WWII.</ref><ref name=clearMk18>{{harvnb|O'Kane|1977|p=221}}</ref>
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===TDC functional description===
Since the TDC
*Angle solver: This computer calculates the required gyro angle. The TDC had separate angle solvers for the forward and aft torpedo tubes.
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