Initial flights The use of the Wellington with ASV Mark III coincided with the move of the Leigh Light from the wing of the aircraft to a retractable "dustbin" arrangement that extended down through the former belly gun turret ring. This meant the radar scanner could not be placed in that location, as it was on H2S aircraft. The radome was instead moved to the nose. This blocked scanning to the rear, about 40 degrees on either side of the
fuselage, and meant the nose guns had to be removed; the
nose gunner typically fired on the U-boats to suppress their anti-aircraft gunners and losing this capability was unpopular. By the end of the year, a small number of units were available and in December 1942 two were sent to No. 30 Maintenance Unit for fitting to Wellington VIIIs, which began testing at the Coastal Command Development Unit in January. There was little difference between the H2S and ASV except for the name. Both included two CRTs displays, a 6" tube for the main scanner display and a smaller 3" "height scope" below it. The latter was used to measure altitude and for use with
Eureka radio beacons and in ASV, it also became used as a timing system for the illumination of the Leigh Light. The priority given to Coastal Command was short-lived and on 8 January 1943, priority reverted to Bomber Command. It became clear that there were not enough fitters to keep the units working and in addition to local recruits, a class from the recently formed
RAF Station Clinton in
Ontario, Canada sent another 110 technicians. The technicians first had a short stay in the US to train on the similar US-designed
DMS-1000. The first operational patrol using one of the two aircraft was carried out on the night of 1943. The aircraft returned from Biscay without having spotted submarines. During the patrol, the aircraft was attacked by German
night fighters and the radar operator was able to give the pilot instructions to evade them. Similar patrols also returned empty-handed until the night of 17 March, when H538 spotted a submarine at but their Leigh Light failed and they could not press the attack. The next night the same aircraft spotted a submarine at and
depth charged it. Supplies of the magnetron began to improve at the start of March 1943 and on 12 March it was decided to split the deliveries equally between the two commands. A serious limitation of spare parts then became a problem but was eventually solved by sending more spares to Bomber Command, to make up for their higher loss rates.
Into service Enough units arrived by the end of March for
No. 172 Squadron RAF at
RAF Chivenor to convert their Wellington XIIs to the Mark III. The squadron was soon pressing attacks every week and in April the number of sightings in the Bay shot up. Calculations demonstrated that the aircraft were at least sighting every submarine in service at that time. Around the time of the introduction of Mark III, the first similar US radar units were arriving, built using magnetron technology introduced to them during the
Tizard Mission in late 1940. These DMS-1000s were mounted on the
Consolidated B-24 Liberator, one of the very few aircraft with enough range to enable it to fly patrols over the
Mid-Atlantic gap and thereby allow aircraft to provide cover over convoys all the way from
Halifax to ports in the UK. A B-24 with DMS-1000 was sent to the UK in January 1942 and used operationally by
No. 224 Squadron RAF, where the system was referred to as the ASV Mark IV. For reasons unknown, the
US Army Air Corps decided to cancel development of the DMS-1000 in favour of the
Western Electric SCR-517, although it proved to be far less sensitive. The RAF learned of another unit intended for mounting in
US Coast Guard blimps, the
Philco ASG, that was comparable to the original DMS-1000. They asked that the ASG be used on their Liberator order instead, referring to it as ASV Mark V. In March, a shipment of Liberators with a mix of DMS-1000, SCR-517 and ASG arrived and were put into service in June. These aircraft lacked the Leigh Light and were generally unable to press the attack but they were invaluable for upsetting the U-boats' approach and calling in ships to attack them.
The tide turns By May, the U-boats were subjected to attacks from the time they entered the Bay of Biscay to time they returned. Even if they escaped into the Atlantic, boats were being attacked hundreds of miles from the convoys while they tried to assemble in
wolfpacks. This was combined with the arrival of new
frigates mounting microwave radars and
huff-duff receivers, further hindering U-boat operations; attacking convoys proved almost impossible.
Karl Dönitz was convinced this was due to a new detection system but remained baffled to its nature. In a mid-May 1943 report to
Hitler, he stated: Attempting to address the continual attacks in the Bay of Biscay, Dönitz ordered the U-boats to leave port during the day when they could attempt to shoot down the aircraft and
day fighter cover could be provided. Coastal Command responded by forming up "Strike Wings" using high-speed aircraft like the
Bristol Beaufighter which travelled in small packs and made hit-and-run attacks, overwhelming the U-boats' defences while also proving difficult for the German fighters to attack as they made one run and then disappeared at high speed. While the U-boats did manage to shoot down several aircraft, the losses of boats continued to climb. In June, U-boats were seen leaving port in flotillas of five or more, providing a higher density of anti-aircraft fire to the point where it was dangerous to approach them, while also reducing the chance of detection per boat. The RAF responded by having the aircraft stand off from the U-boats and call in
destroyers, who could sink them with ease. If the U-boats attempted to dive, the aircraft would pounce. For the boats that managed to evade attack in the Bay, operations against the convoys were proving almost impossible. Every attempt to form up was disrupted long before the convoys approached, sometimes hundreds of miles away, when hunter-killer groups tracked them down. Shipping losses to the U-boats plummeted; in June less shipping was lost than any time since 1941. By the end of the month, 30 per cent of the U-boat force at sea had been lost, a catastrophe. Dönitz was forced to recall the fleet from the North Atlantic, sending them to secondary theatres while some sort of solution was developed.
British lie, German confusion In late February 1943,
German submarine U-333 was attacked by a Mk. III-equipped Wellington. The gunners were already on high alert and managed to shoot the aircraft down, but as it fell it managed to drop charges around the boat. The submarine survived and reported that the Metox gave no warning of the approach and the Leigh Light was not used. The aircraft simply appeared out of the murk and dropped a string of depth charges. On 7 March,
U-156 was attacked in a similar fashion, and radioed in that they believed a new radar was being used. Despite this early warning of a new system, German efforts were hampered by one of the most effective bits of misinformation of the war. A Coastal Command captain who had been captured after crashing told a plausible story, apparently entirely of his own creation, that threw the Germans off the scent for months. He stated that they no longer used Mk. II for the initial detection, and instead used a new receiver that listened for the slight leakage of the
intermediate frequency used in the Metox's tuner. He claimed that it could detect the Metox at ranges as great as . The radar was now only turned on during the last minutes of the approach to check the range and aid the Leigh Light operation. At first, the Germans were skeptical of this claim, but a series of experiments in the lab soon demonstrated this was indeed possible. The equipment was then installed in an aircraft and demonstrated its ability to detect a Metox at a distance of while flying at altitude. The extra originally claimed was attributed to the UK's superiority in electronics. From that point, the false information was "treated as gospel", in spite of much evidence to the contrary. This included reports from boats that were attacked while their Metox was turned off, and one report from an enterprising radio operator in
U-382 who had been experimenting with a visual display with the Metox and detected signals that were well outside the normal range. In spite of these reports, on 15 August 1943 a radio message was sent to the entire fleet telling them to turn off their Metox. The most surprising aspect of this confusion was that the Germans were aware of the magnetron and that it was being used for new high-frequency radars. An intact example had fallen into German hands during its second operational use when a
Short Stirling carrying H2S was shot down over Rotterdam on the night of 2/3 February 1943. For reasons unknown, the possibility of this system being used for anti-submarine work either never reached the Navy or was dismissed as impossible by Navy engineers.
German countermeasures Believing the issue was leakage from Metox, boats returning to port were fit with the
Wanze radar detector that was originally designed to detect signals in the 120 to 150 cm range but due to its new design also had lower signal leakage and greater sensitivity and range. Despite , U-boat sinkings continued and on 5 November 1943, the use of was prohibited as well, as they believed it too might be tracked. A new version, 2, reduced signal leakage even more at the cost of shorter range and produced no improvement. was introduced in the summer of 1943. was much less sensitive than but further reduced leakage to the point that command felt it was safe to use under any circumstance. Sensitive between 75 and 300 cm was still outside the range where it might detect the Mk. III. The sinkings continued unabated. Only in September 1943 did the German navy consider the possibility of 10 cm signals. At that time the
Luftwaffe was introducing the
Naxos radar detector to allow their night fighters to track H2S radars. The receiver was adapted to a new antenna and introduced that month. offered very short-range detection, on the order of , so even if it detected the Mk. III, it offered very little time to dive to safety. Further, the Naxos antenna was a fragile device and had to be removed to dive; the commander of
U-625 drowned while he struggled to remove the antenna. Several improvements to the Naxos were introduced during 1944, notably the new antenna that did not have to be removed to dive. offered not only reception but also reasonable directivity, allowing it to provide initial aiming for the anti-aircraft guns. A further improved antenna, , added antennas to detect 3 cm signals when an H2S unit working on the frequency had been recovered from an RAF bomber. Coastal Command never moved to this frequency on any large scale. Further efforts to understand the British radars led to missions with highly instrumented submarines,
U-406 and
U-473, both of which were sunk. Naxos was never a convincing solution to the Mark III problem. ==Improved versions==