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Mid-Canada Line

August 31, 2023

The Mid-Canada Line (MCL), also known as the McGill Fence, was a line of radar stations running east–west across the middle of Canada, used to provide early warning of a Soviet bomber attack on North America. It was built to supplement the Pinetree Line, which was located farther south. The majority of Mid-Canada Line stations were used only briefly from the late 1950s to the mid-1960s, as the attack threat changed from bombers to ICBMs. As the MCL was closed down, the early warning role passed almost entirely to the newer and more capable DEW Line farther north.

Mid-Canada Line
A Piasecki H-21 drops supplies in front of a Mid-Canada Line radar tower. The antennas at the top and bottom of the stack link to the next stations in the line, the three in the middle send data southward to the air defense network.
Active1956–1965
CountryCanada
BranchRoyal Canadian Air Force
United States Air Force
TypeEarly-warning radar
RoleContinental Air Defence
Part ofNorth American Aerospace Defense Command

The MCL was based on the bistatic radar principle, using separated transmitters and receivers. An aircraft flying anywhere between the stations would reflect some of the transmitted signal towards the receiver, where it would mix with the signal travelling directly from the transmitter. The mixing of the two signals produces a pattern that is very easy to detect using simple electronics. As the transmitter is not pulsed, it does not require high voltages and is very simple as well. This leads to a very low-cost system that can cover huge areas, at the cost of providing no information about the precise location of the target, only its presence.

Throughout its history, the MCL suffered from a problem that was never solved; because of the way bistatic radar works, any object relatively close to either station produces a large signal, in contrast to conventional monostatic (single site) radars where this effect is limited to the area immediately around the site. In the case of the MCL, this caused problems when flocks of birds would fly anywhere near either station and swamp the signal of a more distant aircraft. Solving this problem using the Doppler effect was a major design criterion for the AN/FPS-23 "Fluttar" that filled a similar role in the DEW line.

History Edit

Impetus Edit

Construction of the Pinetree Line had only just started when air planners started to have concerns about its capabilities and siting. By the time it detected a potential attack by jet-powered aircraft, there would be little time to do anything before the attack reached Canadian or northern U.S. cities.[1] Additionally, the Pinetree systems used pulsed radars that were fairly easy to jam and were unable to detect targets close to the ground due to "clutter." Although expensive in terms of fuel use, it would be possible for Soviet bombers to evade detection by flying lower and plotting a course between the stations.

Bennett Lewis, head of the AECL Chalk River Laboratories and former Chief Superintendent of the UK Telecommunications Research Establishment (TRE) had proposed to the Defence Research Board (DRB) a system that avoided both of these problems.[2] Known today as a forward scatter bistatic radar, it used two antennas, a transmitter and receiver, separated by some distance. The antennas were positioned and aimed so that the signal from the transmitter filled the space above the line between the two stations. An aircraft flying into this region would reflect some signal back towards the receiver, allowing detection at altitudes as great as 65,000 ft.[1]

A major advantage of the system is that it requires much less power to operate effectively. In a conventional radar, the radio signal has to travel to the target and back again. As each leg of the journey is subject to the inverse square law, the resulting radar equation contains a fourth-power dependence. In contrast, a forward-scatter radar signal always travels about the same total distance, from the transmitter to the receiver, modified only by the altitude of the target. This means it is dependent on the square root of range and not the fourth root, and thus delivers considerably more energy onto the receiver than a conventional radar over the same range. Also, unlike a conventional "monostatic" radar, the transmitter did not have to turn off to allow the receiver to listen for the signal. Since the total amount of energy received at the receiver is a function of both the peak power and the length of the pulse, using a continual signal means the same total energy will be deposited using much lower peak transmitter power. As a result, Lewis' system would require smaller sites and much less power than conventional radars like those of the Pinetree Line.[3]

The major disadvantage of the system is that it did not indicate the aircraft's location within the beam, unlike a pulsed system where pulse timing can be used to determine range. This means the forward-scatter concept is useful for making a "radar fence" or "trip wire"[1] that indicates that something is approaching, but not exactly where it is. To help address locating the target to a degree, the proposal was to build two interlinked fences, so that each pair of stations was perhaps 30 kilometres (19 mi) apart, a short enough distance that the radar on an interceptor aircraft would be able to find the target within that area. Using two overlapping sets also allowed one pair to cover the dead zone directly above the towers of the other.

Lewis' initial concept was to place the transmitters and receivers on telephone poles and electric power transmission towers, which provided both a convenient location as well as the small amount of power needed to run the electronics. In the case of the telephone poles, the lines would also be used to send the data back to the tracking stations. This concept generated a considerable amount of interest, although it was abandoned for reasons that are not entirely clear. Willis and Griffiths speculate it might be the need for 1,000 such radars,[4] but it is also likely that the desired to locate the line further north than the heavily settled areas in southern Canada was likely significant as well. In any event, the simplicity of the concept helped bring it to the attention of air planners.[4]

Spider Web Edit

The DRB decided to pursue Lewis’ idea in 1950–51 by directing a research contract to the Eaton Electronics Research Laboratories of McGill University, headed by Professor Garfield Woonton. Lewis suggested to DRB and Woonton that he put the project in the hands of associate professor, J. Rennie Whitehead as project leader, a former colleague of his from the TRE days in the UK who had recently taken a position at the Lab. Some preliminary tests were made in 1952 with breadboard hardware built by a graduate student, Hugh Hamilton, in order to confirm the validity of the idea.[2]

In the meantime RCA Victor had been brought in by the DRB to design and produce the receivers, transmitters and antennas for tests on a substantial scale. The testing was performed in the summer of 1953, when Whitehead and his team of RCA Victor and RCAF personnel installed and operated a string of seven stations stretching from Ottawa to Mattawa[a] along the Ottawa River valley. Known under the code name of "Spider Web" at the suggestion of Hamilton, the tests were made with aircraft from CFB St. Hubert, near Montreal. All observations were transmitted to and made in the line HQ, which was set up in the equipment hut of one of the seven stations, located in Deep River.[2]

Flight Lieutenant Andrew Matthews of the 104 Communications Flight at RCAF St. Hubert arranged for a series of different aircraft to fly through the network, including an Auster light aircraft, a T-33 Shooting Star, an Avro Lancaster bomber and even a recently acquired de Havilland Comet jet transport. The tests revealed a great deal about the spectral ‘signatures’ of aircraft crossing the line at different points, and demonstrated the capability to detect all sizes of aircraft from 100 ft to over 40,000 ft in altitude. During this time Dr. Ross Warren of RCA Victor and Dr. Whitehead jointly developed the theoretical background for the work in a major report to DRB.[2]

The Spider Web trials were followed in 1954 by intensive tests on a single 30 miles (48 km) wide link, built in the Eastern Townships by Bell Canada, who had by this time been given the go-ahead for the implementation of the Mid-Canada Line. When Whitehead inquired why RCA had not been given the contract, a colleague replied "Who do you think runs Canada?"[2] The trials on this prototype link were also conducted by Whitehead and a small team in collaboration with Air Defence Command, St. Hubert, this time on behalf of Bell. The trials involved the flyover of numbers of B-52 bombers by arrangement with Strategic Air Command and a local bombplot unit. They also had full-time use of an Avro Lancaster from CFB Greenwood for the important low-level tests.[2]

Deployment studies Edit

 
Unknown MCL radar.

In February 1953 the Canada-U.S. Military Study Group (MSG) was asked "to study those aspects of the North American Air Defence System in general, and the early warning system in particular, which are of mutual concern to the two countries."[5] The MSG then asked the air defence commanders of Canada and the United States to prepare independent briefs on the subject. By July 1953, RCAF Air Defense Command had completed its brief, followed shortly thereafter by its USAF counterpart. Both reports suggested building a Doppler fence farther north, along the 55th parallel, roughly at the entrance of James Bay into Hudson Bay.[5]

In October 1953 the MSG recommended to both governments "that there be established at the earliest practicable date, an early warning line located generally along the 55th parallel between Alaska and Newfoundland",[5] and outlined their minimum operational requirements. By the end of November 1953, the Mid-Canada Line had been approved in principle. Unlike the jointly-operated Pinetree line and future DEW line, the Mid-Canada line would be funded and operated entirely by the RCAF. The DRB estimated that the system would cost about $69,700,000, while an independent RCAF report placed it at $85,000,000, equivalent to $219,200,000 in 2021.[5]

In December an effort started to try to understand what sort of problems would be encountered during construction. Several "trains" consisting of tractor-pulled sleighs set out cross-country. One, manned by the RCAF, set out eastward from Fort Nelson, BC in order to link up with a second moving west from Flin Flon, Manitoba, while a third crewed by the Army left Lake Nipigon near Thunder Bay, Ontario for Lansdowne House about 200 kilometres (120 mi) further north. The missions proved that it was possible to build the new line, but only during the winter when the muskeg was frozen solid.[5] These missions also inspired the U.S. Army to invest in purpose-built overland trains which they experimented with in the 1960s but never put into production.[6]

While that was taking place, efforts were underway to start primary siting studies. It quickly became clear that the areas in question, at least in eastern Canada, were so remote that there was no really accurate topographical information. A huge effort to map the area in a 15-mile wide strip across the entire country was started by Transport Command almost immediately, and ended by the spring of 1954. With this information in hand a construction division was set up, the Systems Engineering Group (SEG), in February 1954, tasked with producing a final report on the system to be submitted on June 1.[5]

Finalizing the plans Edit

As the experiments continued it became clear that by using taller masts, 350 feet (110 m) tall, the radar stations could be located further apart, up to 90 kilometres (56 mi). This reduced the number of stations required. Nevertheless, the price rose, now estimated at about $120,000,000. Although their final report was not yet ready, the SEG put in an interim report in June and it was approved by cabinet by the end of the month.[5]

In their report they outlined the system that would be built almost exactly. It called for eight major Sector Control Centres, numbered from 200 to 900, each of which control up to thirty unmanned radar sites for a total of 90 radar stations.[5] Each of the radar stations consisted of a single tall mast with a number of small dishes in fixed positions on top (typically four, two pointed in either direction), with power and electronics located in a building below the mast.

The sector control centres were linked using an advanced microwave communications system developed in part by CARDE, which scattered off the troposphere for long-distance communications. The southernmost site along the eastern portion of the line, at Cape Henrietta Maria on Hudson Bay, was used as the main communications point, and three additional repeater stations transferred data from the line southward to the NORAD command center in North Bay, Ontario. The easternmost station at Hopedale, Labrador was co-located with an existing Pinetree Line station in order to save construction costs.[5]

All aircraft transiting the line would have to file a flight plan through the Mid Identification Zone, or MIDIZ, centred on the fence. The plans also called for the construction of several airbases known as Line Clearance Aerodromes just to the north of the line, where interceptor aircraft could operate in times of heightened alert.[5]

At about this time another huge civil engineering project was underway in Canada, the construction of a cross-Canada microwave relay telephone system. Since many of the logistics problems were similar, the construction group, led by Bell Canada, was selected as a major contractor for the base construction. Detailed site selection started in 1955, with a major surveying effort running across Canada at the 55th parallel. The sites were so remote that the RCAF had to form up its first all-helicopter squadron in order to provide flight support for the survey teams.[5]

Construction and service Edit

 
Sikorsky H-19 Chickasaw at the Canadian Museum of Flight 1988. The aircraft is painted as it would have looked while working on the construction of the Mid-Canada Line

Construction started in 1956 and proceeded quickly. By April 1957 the eastern half was operational, and the line was declared fully operational on January 1, 1958. Operations were shortly integrated into the newly formed NORAD. Even the SEG's revised estimates turned out to be too low, and the fence's final cost is estimated at $224,566,830, equivalent to $2,092,000,000 in 2021.[5]

Almost as soon as the units went into operation, a serious problem was seen. Due to the large radar cross sections seen in forward-scattering radars, even small targets produced detectable signals. This was multiplied if the targets were roughly the same size as the wavelength of the radar, or in this case, tended to be spread out in patterns that were multiples of that wavelength. This problem was triggered by the large flocks of migrating waterfowl during the spring and fall, which created signals so powerful that it rendered the radars useless. Testing on the Spider Web and Eastern Townships systems had both been carried out during the summer, so this had not been noticed.[7]

Even before the line became operational, in a repeat of earlier history, a new and more capable line was already under study that would combine the plotting capability of the Pinetree system with the line-breaking capabilities of the MCL, and located much farther north to dramatically improve the detection and response times. Emerging as the Distant Early Warning Line, or DEW, construction started before the MCL had become operational. When the DEW line became operational in 1957, the value of the MCL was eroded, and the RCAF started pressing for it to be dismantled.[5]

Although technically capable, the MCL gave little information for vectoring interceptors to their targets, so these tasks still required the Pinetree radars much farther south. The extra time offered by the MCL was not considered worth the trouble of keeping the line operational. The USAF disagreed, but in spite of their objections, the western half of the line was shut down in January 1964, leaving the eastern half to help defend the industrial areas of Canada and the US. As the Soviet Union moved their offensive capability to ICBMs it became clear that both the MCL and Pinetree systems were of limited use, and the entire Mid-Canada line was shut down in April 1965. The operations site located at Cranberry Portage, Manitoba, for example, has been converted into a high school and residence since active operations at the site closed in the mid-1960s.[5]

The DEW line stations were sited to provide the best possible view of the horizon, but there remained a minimum detection angle below which aircraft could sneak by without being seen. During early planning, a system like the MCL's towers was considered as gap-fillers between the stations to prevent these sorts of intrusions. As the MCL came online and the problem with birds became clear, the original forward-scatter concept was replaced by one using Doppler filtering to ignore anything flying below 125 miles per hour (201 km/h). These AN/FPS-23 "Fluttar" systems did indeed filter out birds, but failed to filter out the general aviation aircraft flying in the area, including those flying base-to-base for servicing and crew rotations.[8] As a result, the false-alarm rate rendered it just as ineffective as the MCL, and it lasted even a shorter time, shut down in 1963.[9]

Stations Edit

From a December 1956 listing:[10]

Site Name Coordinates Radio Bcn Activated Deactivated
Site 200 Hopedale Air Station, Sector Control Station 55°27′52″N 60°13′58″W / 55.46448°N 60.23281°W / 55.46448; -60.23281 (Hopedale)
Site 201 Doppler Detection Station 55°27′52″N 60°13′58″W / 55.46448°N 60.23281°W / 55.46448; -60.23281
Site 203 Doppler Detection Station 55°25′48″N 60°58′50″W / 55.430000°N 60.980556°W / 55.430000; -60.980556
Site 206 Doppler Detection Station 55°18′45″N 61°49′28″W / 55.312500°N 61.824444°W / 55.312500; -61.824444
Site 209 Doppler Detection Station 55°24′28″N 62°25′00″W / 55.407778°N 62.416667°W / 55.407778; -62.416667
Site 212 Border Beacon, Doppler Detection Station 55°20′01″N 63°11′28″W / 55.33362508°N 63.1909903°W / 55.33362508; -63.1909903 (Border Beacon)
Site 215 Doppler Detection Station 55°21′40″N 64°01′30″W / 55.361239°N 64.025045°W / 55.361239; -64.025045
Site 218 Doppler Detection Station 55°16′16″N 64°49′11″W / 55.271217°N 64.819786°W / 55.271217; -64.819786
Site 218A Doppler Detection Station 55°15′52″N 64°17′36″W / 55.264416°N 64.293449°W / 55.264416; -64.293449
Site 221 Doppler Detection Station 55°18′04″N 65°24′04″W / 55.301236°N 65.401044°W / 55.301236; -65.401044
Site 221A Doppler Detection Station 55°17′54″N 65°20′19″W / 55.298332°N 65.338585°W / 55.298332; -65.338585
Site 224 Doppler Detection Station 55°15′38″N 66°04′06″W / 55.260512°N 66.068434°W / 55.260512; -66.068434
Site 224A Doppler Detection Station 55°16′23″N 66°13′14″W / 55.272999°N 66.220665°W / 55.272999; -66.220665
Site 227 Doppler Detection Station 55°18′47″N 66°42′18″W / 55.313057°N 66.705042°W / 55.313057; -66.705042
Site 300 RCAF Station Knob Lake, Sector Control Station 54°48′52″N 66°45′19″W / 54.81445°N 66.75540°W / 54.81445; -66.75540 (Knob Lake)
Site 303 Doppler Detection Station 55°19′02″N 66°41′38″W / 55.317112°N 66.693968°W / 55.317112; -66.693968
Site 303A Doppler Detection Station 55°11′17″N 67°24′22″W / 55.188168°N 67.406166°W / 55.188168; -67.406166
Site 306 Doppler Detection Station 55°15′58″N 68°20′42″W / 55.265999°N 68.345001°W / 55.265999; -68.345001
Site 306A Doppler Detection Station 55°11′25″N 68°06′22″W / 55.190166°N 68.106003°W / 55.190166; -68.106003
Site 309 Doppler Detection Station 55°11′32″N 69°01′18″W / 55.192282°N 69.021651°W / 55.192282; -69.021651
Site 309A Doppler Detection Station 55°09′11″N 68°47′32″W / 55.153°N 68.792168°W / 55.153; -68.792168
Site 312 Doppler Detection Station 55°14′07″N 69°44′29″W / 55.235195°N 69.741478°W / 55.235195; -69.741478
Site 312A Doppler Detection Station 55°12′11″N 69°31′29″W / 55.202999°N 69.524834°W / 55.202999; -69.524834
Site 315 Doppler Detection Station 55°10′53″N 70°34′47″W / 55.181337°N 70.579852°W / 55.181337; -70.579852
Site 315A Doppler Detection Station 55°10′00″N 70°40′13″W / 55.166586°N 70.670194°W / 55.166586; -70.670194
Site 318 Doppler Detection Station 55°14′52″N 71°20′28″W / 55.247815°N 71.341220°W / 55.247815; -71.341220
Site 318A Doppler Detection Station 55°16′00″N 71°19′00″W / 55.266666°N 71.316666°W / 55.266666; -71.316666
Site 321 Doppler Detection Station 55°14′46″N 72°12′02″W / 55.246032°N 72.200488°W / 55.246032; -72.200488
Site 321A Doppler Detection Station 55°15′33″N 72°12′13″W / 55.259167°N 72.203667°W / 55.259167; -72.203667
Site 324 Doppler Detection Station 55°20′21″N 73°01′01″W / 55.339030°N 73.016892°W / 55.339030; -73.016892
Site 324A Doppler Detection Station 55°20′00″N 73°01′27″W / 55.333332°N 73.02417°W / 55.333332; -73.02417
Site 327 Doppler Detection Station 55°14′58″N 73°44′42″W / 55.249568°N 73.744928°W / 55.249568; -73.744928
Site 327A Doppler Detection Station 55°17′52″N 73°44′50″W / 55.297832°N 73.747169°W / 55.297832; -73.747169
Site 330 Doppler Detection Station 55°19′15″N 74°34′17″W / 55.320926°N 74.571406°W / 55.320926; -74.571406
Site 330A Doppler Detection Station 55°17′41″N 74°33′26″W / 55.294666°N 74.557335°W / 55.294666; -74.557335
Site 333 Doppler Detection Station 55°17′37″N 75°16′25″W / 55.293534°N 75.273589°W / 55.293534; -75.273589
Site 333A Doppler Detection Station 55°20′20″N 75°24′29″W / 55.338823°N 75.408193°W / 55.338823; -75.408193
Site 336 Doppler Detection Station 55°21′33″N 76°06′05″W / 55.359209°N 76.101265°W / 55.359209; -76.101265
Site 336A Doppler Detection Station 55°16′00″N 75°59′00″W / 55.266666°N 75.98333°W / 55.266666; -75.98333
Site 339 Doppler Detection Station 55°16′21″N 76°47′29″W / 55.272633°N 76.791478°W / 55.272633; -76.791478
Site 339A Doppler Detection Station 55°15′00″N 76°50′00″W / 55.25°N 76.833336°W / 55.25; -76.833336
Site 342 Doppler Detection Station 55°14′33″N 77°38′15″W / 55.242466°N 77.637492°W / 55.242466; -77.637492
Site 400 RCAF Station Great Whale River, Sector Control Station 55°16′44″N 77°44′21″W / 55.2788°N 77.7391°W / 55.2788; -77.7391 (Great Whale River)
Site 401 Doppler Detection Station
Site 403 Doppler Detection Station 54°59′33″N 78°17′15″W / 54.992482°N 78.287418°W / 54.992482; -78.287418
Site 403A Doppler Detection Station 55°06′29″N 78°12′12″W / 55.108002°N 78.203331°W / 55.108002; -78.203331
Site 406 Doppler Detection Station 54°49′41″N 79°00′11″W / 54.828095°N 79.003071°W / 54.828095; -79.003071
Site 406A Doppler Detection Station 54°48′00″N 79°03′00″W / 54.799999°N 79.050003°W / 54.799999; -79.050003
Site 409A Doppler Detection Station 54°38′19″N 79°41′23″W / 54.6385°N 79.689835°W / 54.6385; -79.689835
Site 410 Cape Jones Relay Site 54°38′21″N 79°44′39″W / 54.639179°N 79.744042°W / 54.639179; -79.744042 (Cape Jones)
Site 412 Doppler Detection Station 54°19′47″N 81°05′49″W / 54.329657°N 81.096952°W / 54.329657; -81.096952 Remediated
Site 413 Doppler Detection Station 54°21′52″N 81°05′59″W / 54.364327°N 81.099790°W / 54.364327; -81.099790 Remediated
Site 415 Cape Henrietta Maria Relay Site 54°43′54″N 82°24′29″W / 54.731585°N 82.408135°W / 54.731585; -82.408135 (Cape Henrietta)
Site 416 Doppler Detection Station 54°46′45″N 82°22′52″W / 54.779104°N 82.381244°W / 54.779104; -82.381244 Remediated
Site 418 Doppler Detection Station 54°52′34″N 82°58′48″W / 54.876020°N 82.980113°W / 54.876020; -82.980113 Remediated
Site 421 Doppler Detection Station 54°51′37″N 83°24′49″W / 54.860346°N 83.413607°W / 54.860346; -83.413607
Site 424 Doppler Detection Station 55°04′33″N 84°18′39″W / 55.075916°N 84.310824°W / 55.075916; -84.310824
Site 427 Doppler Detection Station 55°04′00″N 84°51′04″W / 55.066613°N 84.851164°W / 55.066613; -84.851164
Site 500 RCAF Station Winisk, Sector Control Station 55°14′39″N 85°06′42″W / 55.2442°N 85.1117°W / 55.2442; -85.1117 (Winisk) Remediated
Site 503 Doppler Detection Station 55°17′05″N 85°42′30″W / 55.284721°N 85.708336°W / 55.284721; -85.708336
Site 506 Doppler Detection Station 55°17′17″N 86°25′25″W / 55.288032°N 86.423622°W / 55.288032; -86.423622
Site 509 Doppler Detection Station 55°29′25″N 87°04′26″W / 55.490167°N 87.074014°W / 55.490167; -87.074014
Site 512 Doppler Detection Station 55°35′26″N 87°51′54″W / 55.590647°N 87.865076°W / 55.590647; -87.865076
Site 515 Doppler Detection Station 55°52′51″N 88°35′01″W / 55.880790°N 88.583708°W / 55.880790; -88.583708
Site 518 Doppler Detection Station 55°58′28″N 89°13′11″W / 55.974316°N 89.219653°W / 55.974316; -89.219653
Site 521 Doppler Detection Station 56°13′30″N 89°53′22″W / 56.225037°N 89.889381°W / 56.225037; -89.889381
Site 524 Doppler Detection Station 56°17′25″N 90°40′01″W / 56.290352°N 90.666916°W / 56.290352; -90.666916
Site 527 Doppler Detection Station 56°24′41″N 91°27′39″W / 56.411439°N 91.460713°W / 56.411439; -91.460713
Site 530 Doppler Detection Station 56°22′49″N 92°11′21″W / 56.380230°N 92.189115°W / 56.380230; -92.189115
Site 533 Doppler Detection Station 56°27′58″N 92°48′28″W / 56.466152°N 92.807660°W / 56.466152; -92.807660
Site 536 Doppler Detection Station 56°23′43″N 93°20′05″W / 56.395274°N 93.334667°W / 56.395274; -93.334667
Site 600 RCAF Station Bird, Sector Control Station 56°30′26″N 94°12′48″W / 56.50725°N 94.21345°W / 56.50725; -94.21345 (Bird)
Site 603 Doppler Detection Station 56°10′00″N 94°42′05″W / 56.166667°N 94.701389°W / 56.166667; -94.701389
Site 606 Doppler Detection Station 56°01′33″N 95°25′20″W / 56.025833°N 95.422222°W / 56.025833; -95.422222
Site 609 Doppler Detection Station 55°48′25″N 96°05′17″W / 55.806944°N 96.088056°W / 55.806944; -96.088056
Site 612 Doppler Detection Station 55°39′40″N 96°42′40″W / 55.661111°N 96.711111°W / 55.661111; -96.711111
Site 615 Doppler Detection Station 55°19′00″N 97°15′30″W / 55.316667°N 97.258333°W / 55.316667; -97.258333
Site 618 Doppler Detection Station 55°10′49″N 97°51′37″W / 55.180278°N 97.860278°W / 55.180278; -97.860278
Site 621 Doppler Detection Station 54°54′47″N 98°30′38″W / 54.913056°N 98.510556°W / 54.913056; -98.510556
Site 624 Doppler Detection Station 54°47′55″N 99°16′38″W / 54.798611°N 99.277222°W / 54.798611; -99.277222
Site 627 Doppler Detection Station 54°38′10″N 99°52′50″W / 54.636111°N 99.880556°W / 54.636111; -99.880556
Site 630 Doppler Detection Station 54°39′57″N 100°38′40″W / 54.665833°N 100.644444°W / 54.665833; -100.644444
Site 700 RCAF Station Cranberry Portage, Sector Control Station 54°35′08″N 101°22′17″W / 54.58547°N 101.37139°W / 54.58547; -101.37139 (Cranberry Portage)
Site 701
Site 703 Doppler Detection Station 54°40′50″N 102°03′10″W / 54.680556°N 102.052778°W / 54.680556; -102.052778
Site 706 Doppler Detection Station 54°39′08″N 102°42′08″W / 54.652222°N 102.702222°W / 54.652222; -102.702222
Site 709 Doppler Detection Station 54°49′47″N 103°22′30″W / 54.829722°N 103.375000°W / 54.829722; -103.375000
Site 712 Doppler Detection Station 54°53′48″N 104°16′10″W / 54.896667°N 104.269444°W / 54.896667; -104.269444
Site 715 Doppler Detection Station 54°58′27″N 104°47′25″W / 54.974167°N 104.790278°W / 54.974167; -104.790278
Site 718 Doppler Detection Station 54°55′54″N 105°44′10″W / 54.931667°N 105.736111°W / 54.931667; -105.736111
Site 721 Doppler Detection Station 55°03′56″N 106°26′10″W / 55.065556°N 106.436111°W / 55.065556; -106.436111
Site 724 Doppler Detection Station 55°04′30″N 107°08′20″W / 55.075000°N 107.138889°W / 55.075000; -107.138889
Site 727 Doppler Detection Station 55°14′40″N 107°38′52″W / 55.244444°N 107.647778°W / 55.244444; -107.647778
Site 730 Doppler Detection Station 55°19′27″N 108°05′40″W / 55.324167°N 108.094444°W / 55.324167; -108.094444
Site 733 Doppler Detection Station 55°36′50″N 108°28′35″W / 55.613889°N 108.476389°W / 55.613889; -108.476389
Site 736 Doppler Detection Station 55°59′46″N 109°17′00″W / 55.996111°N 109.283333°W / 55.996111; -109.283333
Site 739 Doppler Detection Station 56°08′32″N 109°28′35″W / 56.142222°N 109.476389°W / 56.142222; -109.476389
Site 742 Doppler Detection Station 56°21′30″N 110°23′55″W / 56.358333°N 110.398611°W / 56.358333; -110.398611
Site 745 Doppler Detection Station 56°31′47″N 110°58′00″W / 56.529722°N 110.966667°W / 56.529722; -110.966667
Site 800 RCAF Station Stoney Mountain, Sector Control Station 56°26′59″N 111°02′02″W / 56.44973°N 111.0339°W / 56.44973; -111.0339 (Stoney Mountain)
Site 803 Doppler Detection Station 56°31′06″N 111°47′05″W / 56.518333°N 111.784722°W / 56.518333; -111.784722
Site 806 Doppler Detection Station 56°33′32″N 112°12′40″W / 56.558889°N 112.211111°W / 56.558889; -112.211111
Site 809 Doppler Detection Station 56°36′24″N 113°04′15″W / 56.606722°N 113.070833°W / 56.606722; -113.070833
Site 812 Doppler Detection Station 56°22′23″N 113°26′20″W / 56.373056°N 113.438889°W / 56.373056; -113.438889
Site 815 Doppler Detection Station 55°59′49″N 114°05′24″W / 55.996944°N 114.090000°W / 55.996944; -114.090000
Site 818 Doppler Detection Station 55°49′13″N 114°39′17″W / 55.820278°N 114.654722°W / 55.820278; -114.654722
Site 821 Doppler Detection Station 55°38′44″N 115°01′14″W / 55.645556°N 115.020556°W / 55.645556; -115.020556
Site 824 Doppler Detection Station 55°36′48″N 115°43′30″W / 55.613333°N 115.725000°W / 55.613333; -115.725000
Site 827 Doppler Detection Station 55°32′18″N 116°07′19″W / 55.538333°N 116.121944°W / 55.538333; -116.121944
Site 830 Doppler Detection Station 55°37′24″N 117°03′06″W / 55.623333°N 117.051667°W / 55.623333; -117.051667
Site 833 Doppler Detection Station 55°31′06″N 117°43′30″W / 55.518333°N 117.725000°W / 55.518333; -117.725000
Site 836 Doppler Detection Station 55°36′55″N 118°34′02″W / 55.615278°N 118.567222°W / 55.615278; -118.567222
Site 839 Doppler Detection Station 55°34′11″N 119°13′21″W / 55.569722°N 119.222500°W / 55.569722; -119.222500
Site 842 Doppler Detection Station 55°37′26″N 119°42′46″W / 55.623956°N 119.712778°W / 55.623956; -119.712778
Site 900 RCAF Station Dawson Creek, Sector Control Station 55°44′47″N 120°13′47″W / 55.74627°N 120.22968°W / 55.74627; -120.22968 (Dawson Creek)
Site 900R
Site 901
Site 903 Doppler Detection Station 55°36′45″N 120°25′30″W / 55.612500°N 120.425000°W / 55.612500; -120.425000
Site 050 Fort Albany Tropospheric Scatter Repeater 52°12′41″N 81°40′26″W / 52.21138°N 81.67393°W / 52.21138; -81.67393
Site 060 Relay Tropospheric Scatter Repeater 49°59′56″N 81°37′07″W / 49.9990°N 81.6187°W / 49.9990; -81.6187
Site 070 Mount Kempis Tropospheric Scatter Repeater 48°22′34″N 80°16′05″W / 48.37621°N 80.26805°W / 48.37621; -80.26805

POL Supply Points Edit

Petroleums, Oils and Lubricants (POL) Supply Points were distribution centers for consumable petroleum materials used to fuel and maintain the Mid-Canada Line DDS sites. Co-located with Sector Control Stations when possible, petroleum products were received in bulk and shipped out by air from these locations. From the same December 1956 listing.[10]

Supply Point MCL Sites Serviced Coordinates
Hopedale, NF 201 55°27′52″N 60°13′58″W / 55.46448°N 60.23281°W / 55.46448; -60.23281
Goose Bay, NF 203, 206, 209, 212
Knob Lake, QC 215, 218, 221, 224, 227, 303, 306, 309, 312, 315, 318, 321 54°48′52″N 66°45′19″W / 54.81445°N 66.75540°W / 54.81445; -66.75540
Great Whale River, QC 324, 327, 330, 333, 336, 339, 342, 403, 406, 409, 410 55°16′44″N 77°44′21″W / 55.2788°N 77.7391°W / 55.2788; -77.7391
Bear Island, Nunavut 412, 413
Winisk, ON 415, 416, 418, 421, 424, 427, 503, 506, 509, 512, 515, 518 55°14′39″N 85°06′42″W / 55.2442°N 85.1117°W / 55.2442; -85.1117
Gillam, MB 600, 536, 533, 530, 527, 524, 521
Ilford, MB 606, 609
Thicket Portage, MB 615, 618, 612
Wabowden, MB 621
Wekusko, MB 624, 627, 630 54°30′12″N 99°45′04″W / 54.503333°N 99.751111°W / 54.503333; -99.751111
Cranberry Portage, MB 700, 701 54°35′08″N 101°22′17″W / 54.58547°N 101.37139°W / 54.58547; -101.37139
Flin Flon, MB 703, 706, 709
La Ronge, SK 712, 715, 718, 721
Meadow Lake, SK 724, 727, 730, 733, 736, 739
Anzac, AB 742, 745
Waterways, AB 803, 806
Slave Lake, AB 809, 812, 815, 816, 821
High Prairie, AB 824, 827
Falher, AB 830, 833
Sexsmith, AB 836, 839
Dawson Creek, BC 842, 900R, 903 55°44′47″N 120°13′47″W / 55.74627°N 120.22968°W / 55.74627; -120.22968

See also Edit

Notes Edit

  1. ^ Whitehead states the line stretched to North Bay, but lists stations only as far as Mattawa.[2]

References Edit

Citations Edit

  1. ^ a b c McCamley 2013, p. 34.
  2. ^ a b c d e f g Whitehead 1995.
  3. ^ Willis & Griffiths 2007, p. 37.
  4. ^ a b Willis & Griffiths 2007, p. 36.
  5. ^ a b c d e f g h i j k l m n Thorne 1979.
  6. ^ Orlemann, Eric (2001). LeTourneau Earthmovers. MBI Publishing. p. 66. ISBN 0-7603-0840-3.
  7. ^ Skolnik 2007, p. 38.
  8. ^ Skolnik 2007, p. 45.
  9. ^ Wolff, Christian. "AN/FPS-23".
  10. ^ a b "Mid Canada Line".

Bibliography Edit

  • Thorne, D.H. (1979). "The Mid Canada Line, 1958 – 1965". {{cite magazine}}: Cite magazine requires |magazine= (help)
  • Lester, Alex (2019). (PDF). St. Francis Xavier University. ISBN 9781989537008. Archived from the original (PDF) on 24 June 2021. Retrieved 21 June 2021.
  • Whitehead, James Rennie (1995). Memoirs of a Boffin – Ch. 7.
  • Willis, Nicholas; Griffiths, Hugh (2007). Advances in bistatic radar. SciTech Publishing. ISBN 978-1-891121-48-7.
  • McCamley, Nick (2013). Cold War Secret Nuclear Bunkers: The Passive Defence of the Western World. Pen and Sword. ISBN 9781844155088.
  • Skolnik, Merrill (2007). "Fluttar DEW-Line Gap-Filler". In Willis, Nicholas; Griffiths, Hugh (eds.). Advances in Bistatic Radar. SciTech Publishing. pp. 35–46. ISBN 9781891121487.

External links Edit

  • The Mid-Canada Line: includes maps and photos from most of the stations

August 31, 2023
canada, line, also, known, mcgill, fence, line, radar, stations, running, east, west, across, middle, canada, used, provide, early, warning, soviet, bomber, attack, north, america, built, supplement, pinetree, line, which, located, farther, south, majority, st. The Mid Canada Line MCL also known as the McGill Fence was a line of radar stations running east west across the middle of Canada used to provide early warning of a Soviet bomber attack on North America It was built to supplement the Pinetree Line which was located farther south The majority of Mid Canada Line stations were used only briefly from the late 1950s to the mid 1960s as the attack threat changed from bombers to ICBMs As the MCL was closed down the early warning role passed almost entirely to the newer and more capable DEW Line farther north Mid Canada LineA Piasecki H 21 drops supplies in front of a Mid Canada Line radar tower The antennas at the top and bottom of the stack link to the next stations in the line the three in the middle send data southward to the air defense network Active1956 1965CountryCanadaBranchRoyal Canadian Air ForceUnited States Air ForceTypeEarly warning radarRoleContinental Air DefencePart ofNorth American Aerospace Defense Command Map all coordinates using OpenStreetMapDownload coordinates as KML GPX all coordinates GPX primary coordinates GPX secondary coordinates The MCL was based on the bistatic radar principle using separated transmitters and receivers An aircraft flying anywhere between the stations would reflect some of the transmitted signal towards the receiver where it would mix with the signal travelling directly from the transmitter The mixing of the two signals produces a pattern that is very easy to detect using simple electronics As the transmitter is not pulsed it does not require high voltages and is very simple as well This leads to a very low cost system that can cover huge areas at the cost of providing no information about the precise location of the target only its presence Throughout its history the MCL suffered from a problem that was never solved because of the way bistatic radar works any object relatively close to either station produces a large signal in contrast to conventional monostatic single site radars where this effect is limited to the area immediately around the site In the case of the MCL this caused problems when flocks of birds would fly anywhere near either station and swamp the signal of a more distant aircraft Solving this problem using the Doppler effect was a major design criterion for the AN FPS 23 Fluttar that filled a similar role in the DEW line Contents 1 History 1 1 Impetus 1 2 Spider Web 1 3 Deployment studies 1 4 Finalizing the plans 2 Construction and service 3 Stations 4 POL Supply Points 5 See also 6 Notes 7 References 7 1 Citations 7 2 Bibliography 8 External linksHistory EditImpetus Edit Construction of the Pinetree Line had only just started when air planners started to have concerns about its capabilities and siting By the time it detected a potential attack by jet powered aircraft there would be little time to do anything before the attack reached Canadian or northern U S cities 1 Additionally the Pinetree systems used pulsed radars that were fairly easy to jam and were unable to detect targets close to the ground due to clutter Although expensive in terms of fuel use it would be possible for Soviet bombers to evade detection by flying lower and plotting a course between the stations Bennett Lewis head of the AECL Chalk River Laboratories and former Chief Superintendent of the UK Telecommunications Research Establishment TRE had proposed to the Defence Research Board DRB a system that avoided both of these problems 2 Known today as a forward scatter bistatic radar it used two antennas a transmitter and receiver separated by some distance The antennas were positioned and aimed so that the signal from the transmitter filled the space above the line between the two stations An aircraft flying into this region would reflect some signal back towards the receiver allowing detection at altitudes as great as 65 000 ft 1 A major advantage of the system is that it requires much less power to operate effectively In a conventional radar the radio signal has to travel to the target and back again As each leg of the journey is subject to the inverse square law the resulting radar equation contains a fourth power dependence In contrast a forward scatter radar signal always travels about the same total distance from the transmitter to the receiver modified only by the altitude of the target This means it is dependent on the square root of range and not the fourth root and thus delivers considerably more energy onto the receiver than a conventional radar over the same range Also unlike a conventional monostatic radar the transmitter did not have to turn off to allow the receiver to listen for the signal Since the total amount of energy received at the receiver is a function of both the peak power and the length of the pulse using a continual signal means the same total energy will be deposited using much lower peak transmitter power As a result Lewis system would require smaller sites and much less power than conventional radars like those of the Pinetree Line 3 The major disadvantage of the system is that it did not indicate the aircraft s location within the beam unlike a pulsed system where pulse timing can be used to determine range This means the forward scatter concept is useful for making a radar fence or trip wire 1 that indicates that something is approaching but not exactly where it is To help address locating the target to a degree the proposal was to build two interlinked fences so that each pair of stations was perhaps 30 kilometres 19 mi apart a short enough distance that the radar on an interceptor aircraft would be able to find the target within that area Using two overlapping sets also allowed one pair to cover the dead zone directly above the towers of the other Lewis initial concept was to place the transmitters and receivers on telephone poles and electric power transmission towers which provided both a convenient location as well as the small amount of power needed to run the electronics In the case of the telephone poles the lines would also be used to send the data back to the tracking stations This concept generated a considerable amount of interest although it was abandoned for reasons that are not entirely clear Willis and Griffiths speculate it might be the need for 1 000 such radars 4 but it is also likely that the desired to locate the line further north than the heavily settled areas in southern Canada was likely significant as well In any event the simplicity of the concept helped bring it to the attention of air planners 4 Spider Web Edit The DRB decided to pursue Lewis idea in 1950 51 by directing a research contract to the Eaton Electronics Research Laboratories of McGill University headed by Professor Garfield Woonton Lewis suggested to DRB and Woonton that he put the project in the hands of associate professor J Rennie Whitehead as project leader a former colleague of his from the TRE days in the UK who had recently taken a position at the Lab Some preliminary tests were made in 1952 with breadboard hardware built by a graduate student Hugh Hamilton in order to confirm the validity of the idea 2 In the meantime RCA Victor had been brought in by the DRB to design and produce the receivers transmitters and antennas for tests on a substantial scale The testing was performed in the summer of 1953 when Whitehead and his team of RCA Victor and RCAF personnel installed and operated a string of seven stations stretching from Ottawa to Mattawa a along the Ottawa River valley Known under the code name of Spider Web at the suggestion of Hamilton the tests were made with aircraft from CFB St Hubert near Montreal All observations were transmitted to and made in the line HQ which was set up in the equipment hut of one of the seven stations located in Deep River 2 Flight Lieutenant Andrew Matthews of the 104 Communications Flight at RCAF St Hubert arranged for a series of different aircraft to fly through the network including an Auster light aircraft a T 33 Shooting Star an Avro Lancaster bomber and even a recently acquired de Havilland Comet jet transport The tests revealed a great deal about the spectral signatures of aircraft crossing the line at different points and demonstrated the capability to detect all sizes of aircraft from 100 ft to over 40 000 ft in altitude During this time Dr Ross Warren of RCA Victor and Dr Whitehead jointly developed the theoretical background for the work in a major report to DRB 2 The Spider Web trials were followed in 1954 by intensive tests on a single 30 miles 48 km wide link built in the Eastern Townships by Bell Canada who had by this time been given the go ahead for the implementation of the Mid Canada Line When Whitehead inquired why RCA had not been given the contract a colleague replied Who do you think runs Canada 2 The trials on this prototype link were also conducted by Whitehead and a small team in collaboration with Air Defence Command St Hubert this time on behalf of Bell The trials involved the flyover of numbers of B 52 bombers by arrangement with Strategic Air Command and a local bombplot unit They also had full time use of an Avro Lancaster from CFB Greenwood for the important low level tests 2 Deployment studies Edit Unknown MCL radar In February 1953 the Canada U S Military Study Group MSG was asked to study those aspects of the North American Air Defence System in general and the early warning system in particular which are of mutual concern to the two countries 5 The MSG then asked the air defence commanders of Canada and the United States to prepare independent briefs on the subject By July 1953 RCAF Air Defense Command had completed its brief followed shortly thereafter by its USAF counterpart Both reports suggested building a Doppler fence farther north along the 55th parallel roughly at the entrance of James Bay into Hudson Bay 5 In October 1953 the MSG recommended to both governments that there be established at the earliest practicable date an early warning line located generally along the 55th parallel between Alaska and Newfoundland 5 and outlined their minimum operational requirements By the end of November 1953 the Mid Canada Line had been approved in principle Unlike the jointly operated Pinetree line and future DEW line the Mid Canada line would be funded and operated entirely by the RCAF The DRB estimated that the system would cost about 69 700 000 while an independent RCAF report placed it at 85 000 000 equivalent to 219 200 000 in 2021 5 In December an effort started to try to understand what sort of problems would be encountered during construction Several trains consisting of tractor pulled sleighs set out cross country One manned by the RCAF set out eastward from Fort Nelson BC in order to link up with a second moving west from Flin Flon Manitoba while a third crewed by the Army left Lake Nipigon near Thunder Bay Ontario for Lansdowne House about 200 kilometres 120 mi further north The missions proved that it was possible to build the new line but only during the winter when the muskeg was frozen solid 5 These missions also inspired the U S Army to invest in purpose built overland trains which they experimented with in the 1960s but never put into production 6 While that was taking place efforts were underway to start primary siting studies It quickly became clear that the areas in question at least in eastern Canada were so remote that there was no really accurate topographical information A huge effort to map the area in a 15 mile wide strip across the entire country was started by Transport Command almost immediately and ended by the spring of 1954 With this information in hand a construction division was set up the Systems Engineering Group SEG in February 1954 tasked with producing a final report on the system to be submitted on June 1 5 Finalizing the plans Edit As the experiments continued it became clear that by using taller masts 350 feet 110 m tall the radar stations could be located further apart up to 90 kilometres 56 mi This reduced the number of stations required Nevertheless the price rose now estimated at about 120 000 000 Although their final report was not yet ready the SEG put in an interim report in June and it was approved by cabinet by the end of the month 5 In their report they outlined the system that would be built almost exactly It called for eight major Sector Control Centres numbered from 200 to 900 each of which control up to thirty unmanned radar sites for a total of 90 radar stations 5 Each of the radar stations consisted of a single tall mast with a number of small dishes in fixed positions on top typically four two pointed in either direction with power and electronics located in a building below the mast The sector control centres were linked using an advanced microwave communications system developed in part by CARDE which scattered off the troposphere for long distance communications The southernmost site along the eastern portion of the line at Cape Henrietta Maria on Hudson Bay was used as the main communications point and three additional repeater stations transferred data from the line southward to the NORAD command center in North Bay Ontario The easternmost station at Hopedale Labrador was co located with an existing Pinetree Line station in order to save construction costs 5 All aircraft transiting the line would have to file a flight plan through the Mid Identification Zone or MIDIZ centred on the fence The plans also called for the construction of several airbases known as Line Clearance Aerodromes just to the north of the line where interceptor aircraft could operate in times of heightened alert 5 At about this time another huge civil engineering project was underway in Canada the construction of a cross Canada microwave relay telephone system Since many of the logistics problems were similar the construction group led by Bell Canada was selected as a major contractor for the base construction Detailed site selection started in 1955 with a major surveying effort running across Canada at the 55th parallel The sites were so remote that the RCAF had to form up its first all helicopter squadron in order to provide flight support for the survey teams 5 Construction and service Edit Sikorsky H 19 Chickasaw at the Canadian Museum of Flight 1988 The aircraft is painted as it would have looked while working on the construction of the Mid Canada LineConstruction started in 1956 and proceeded quickly By April 1957 the eastern half was operational and the line was declared fully operational on January 1 1958 Operations were shortly integrated into the newly formed NORAD Even the SEG s revised estimates turned out to be too low and the fence s final cost is estimated at 224 566 830 equivalent to 2 092 000 000 in 2021 5 Almost as soon as the units went into operation a serious problem was seen Due to the large radar cross sections seen in forward scattering radars even small targets produced detectable signals This was multiplied if the targets were roughly the same size as the wavelength of the radar or in this case tended to be spread out in patterns that were multiples of that wavelength This problem was triggered by the large flocks of migrating waterfowl during the spring and fall which created signals so powerful that it rendered the radars useless Testing on the Spider Web and Eastern Townships systems had both been carried out during the summer so this had not been noticed 7 Even before the line became operational in a repeat of earlier history a new and more capable line was already under study that would combine the plotting capability of the Pinetree system with the line breaking capabilities of the MCL and located much farther north to dramatically improve the detection and response times Emerging as the Distant Early Warning Line or DEW construction started before the MCL had become operational When the DEW line became operational in 1957 the value of the MCL was eroded and the RCAF started pressing for it to be dismantled 5 Although technically capable the MCL gave little information for vectoring interceptors to their targets so these tasks still required the Pinetree radars much farther south The extra time offered by the MCL was not considered worth the trouble of keeping the line operational The USAF disagreed but in spite of their objections the western half of the line was shut down in January 1964 leaving the eastern half to help defend the industrial areas of Canada and the US As the Soviet Union moved their offensive capability to ICBMs it became clear that both the MCL and Pinetree systems were of limited use and the entire Mid Canada line was shut down in April 1965 The operations site located at Cranberry Portage Manitoba for example has been converted into a high school and residence since active operations at the site closed in the mid 1960s 5 The DEW line stations were sited to provide the best possible view of the horizon but there remained a minimum detection angle below which aircraft could sneak by without being seen During early planning a system like the MCL s towers was considered as gap fillers between the stations to prevent these sorts of intrusions As the MCL came online and the problem with birds became clear the original forward scatter concept was replaced by one using Doppler filtering to ignore anything flying below 125 miles per hour 201 km h These AN FPS 23 Fluttar systems did indeed filter out birds but failed to filter out the general aviation aircraft flying in the area including those flying base to base for servicing and crew rotations 8 As a result the false alarm rate rendered it just as ineffective as the MCL and it lasted even a shorter time shut down in 1963 9 Stations EditFrom a December 1956 listing 10 Site Name Coordinates Radio Bcn Activated DeactivatedSite 200 Hopedale Air Station Sector Control Station 55 27 52 N 60 13 58 W 55 46448 N 60 23281 W 55 46448 60 23281 Hopedale Site 201 Doppler Detection Station 55 27 52 N 60 13 58 W 55 46448 N 60 23281 W 55 46448 60 23281Site 203 Doppler Detection Station 55 25 48 N 60 58 50 W 55 430000 N 60 980556 W 55 430000 60 980556Site 206 Doppler Detection Station 55 18 45 N 61 49 28 W 55 312500 N 61 824444 W 55 312500 61 824444Site 209 Doppler Detection Station 55 24 28 N 62 25 00 W 55 407778 N 62 416667 W 55 407778 62 416667Site 212 Border Beacon Doppler Detection Station 55 20 01 N 63 11 28 W 55 33362508 N 63 1909903 W 55 33362508 63 1909903 Border Beacon Site 215 Doppler Detection Station 55 21 40 N 64 01 30 W 55 361239 N 64 025045 W 55 361239 64 025045Site 218 Doppler Detection Station 55 16 16 N 64 49 11 W 55 271217 N 64 819786 W 55 271217 64 819786Site 218A Doppler Detection Station 55 15 52 N 64 17 36 W 55 264416 N 64 293449 W 55 264416 64 293449Site 221 Doppler Detection Station 55 18 04 N 65 24 04 W 55 301236 N 65 401044 W 55 301236 65 401044Site 221A Doppler Detection Station 55 17 54 N 65 20 19 W 55 298332 N 65 338585 W 55 298332 65 338585Site 224 Doppler Detection Station 55 15 38 N 66 04 06 W 55 260512 N 66 068434 W 55 260512 66 068434Site 224A Doppler Detection Station 55 16 23 N 66 13 14 W 55 272999 N 66 220665 W 55 272999 66 220665Site 227 Doppler Detection Station 55 18 47 N 66 42 18 W 55 313057 N 66 705042 W 55 313057 66 705042Site 300 RCAF Station Knob Lake Sector Control Station 54 48 52 N 66 45 19 W 54 81445 N 66 75540 W 54 81445 66 75540 Knob Lake Site 303 Doppler Detection Station 55 19 02 N 66 41 38 W 55 317112 N 66 693968 W 55 317112 66 693968Site 303A Doppler Detection Station 55 11 17 N 67 24 22 W 55 188168 N 67 406166 W 55 188168 67 406166Site 306 Doppler Detection Station 55 15 58 N 68 20 42 W 55 265999 N 68 345001 W 55 265999 68 345001Site 306A Doppler Detection Station 55 11 25 N 68 06 22 W 55 190166 N 68 106003 W 55 190166 68 106003Site 309 Doppler Detection Station 55 11 32 N 69 01 18 W 55 192282 N 69 021651 W 55 192282 69 021651Site 309A Doppler Detection Station 55 09 11 N 68 47 32 W 55 153 N 68 792168 W 55 153 68 792168Site 312 Doppler Detection Station 55 14 07 N 69 44 29 W 55 235195 N 69 741478 W 55 235195 69 741478Site 312A Doppler Detection Station 55 12 11 N 69 31 29 W 55 202999 N 69 524834 W 55 202999 69 524834Site 315 Doppler Detection Station 55 10 53 N 70 34 47 W 55 181337 N 70 579852 W 55 181337 70 579852Site 315A Doppler Detection Station 55 10 00 N 70 40 13 W 55 166586 N 70 670194 W 55 166586 70 670194Site 318 Doppler Detection Station 55 14 52 N 71 20 28 W 55 247815 N 71 341220 W 55 247815 71 341220Site 318A Doppler Detection Station 55 16 00 N 71 19 00 W 55 266666 N 71 316666 W 55 266666 71 316666Site 321 Doppler Detection Station 55 14 46 N 72 12 02 W 55 246032 N 72 200488 W 55 246032 72 200488Site 321A Doppler Detection Station 55 15 33 N 72 12 13 W 55 259167 N 72 203667 W 55 259167 72 203667Site 324 Doppler Detection Station 55 20 21 N 73 01 01 W 55 339030 N 73 016892 W 55 339030 73 016892Site 324A Doppler Detection Station 55 20 00 N 73 01 27 W 55 333332 N 73 02417 W 55 333332 73 02417Site 327 Doppler Detection Station 55 14 58 N 73 44 42 W 55 249568 N 73 744928 W 55 249568 73 744928Site 327A Doppler Detection Station 55 17 52 N 73 44 50 W 55 297832 N 73 747169 W 55 297832 73 747169Site 330 Doppler Detection Station 55 19 15 N 74 34 17 W 55 320926 N 74 571406 W 55 320926 74 571406Site 330A Doppler Detection Station 55 17 41 N 74 33 26 W 55 294666 N 74 557335 W 55 294666 74 557335Site 333 Doppler Detection Station 55 17 37 N 75 16 25 W 55 293534 N 75 273589 W 55 293534 75 273589Site 333A Doppler Detection Station 55 20 20 N 75 24 29 W 55 338823 N 75 408193 W 55 338823 75 408193Site 336 Doppler Detection Station 55 21 33 N 76 06 05 W 55 359209 N 76 101265 W 55 359209 76 101265Site 336A Doppler Detection Station 55 16 00 N 75 59 00 W 55 266666 N 75 98333 W 55 266666 75 98333Site 339 Doppler Detection Station 55 16 21 N 76 47 29 W 55 272633 N 76 791478 W 55 272633 76 791478Site 339A Doppler Detection Station 55 15 00 N 76 50 00 W 55 25 N 76 833336 W 55 25 76 833336Site 342 Doppler Detection Station 55 14 33 N 77 38 15 W 55 242466 N 77 637492 W 55 242466 77 637492Site 400 RCAF Station Great Whale River Sector Control Station 55 16 44 N 77 44 21 W 55 2788 N 77 7391 W 55 2788 77 7391 Great Whale River Site 401 Doppler Detection StationSite 403 Doppler Detection Station 54 59 33 N 78 17 15 W 54 992482 N 78 287418 W 54 992482 78 287418Site 403A Doppler Detection Station 55 06 29 N 78 12 12 W 55 108002 N 78 203331 W 55 108002 78 203331Site 406 Doppler Detection Station 54 49 41 N 79 00 11 W 54 828095 N 79 003071 W 54 828095 79 003071Site 406A Doppler Detection Station 54 48 00 N 79 03 00 W 54 799999 N 79 050003 W 54 799999 79 050003Site 409A Doppler Detection Station 54 38 19 N 79 41 23 W 54 6385 N 79 689835 W 54 6385 79 689835Site 410 Cape Jones Relay Site 54 38 21 N 79 44 39 W 54 639179 N 79 744042 W 54 639179 79 744042 Cape Jones Site 412 Doppler Detection Station 54 19 47 N 81 05 49 W 54 329657 N 81 096952 W 54 329657 81 096952 RemediatedSite 413 Doppler Detection Station 54 21 52 N 81 05 59 W 54 364327 N 81 099790 W 54 364327 81 099790 RemediatedSite 415 Cape Henrietta Maria Relay Site 54 43 54 N 82 24 29 W 54 731585 N 82 408135 W 54 731585 82 408135 Cape Henrietta Site 416 Doppler Detection Station 54 46 45 N 82 22 52 W 54 779104 N 82 381244 W 54 779104 82 381244 RemediatedSite 418 Doppler Detection Station 54 52 34 N 82 58 48 W 54 876020 N 82 980113 W 54 876020 82 980113 RemediatedSite 421 Doppler Detection Station 54 51 37 N 83 24 49 W 54 860346 N 83 413607 W 54 860346 83 413607Site 424 Doppler Detection Station 55 04 33 N 84 18 39 W 55 075916 N 84 310824 W 55 075916 84 310824Site 427 Doppler Detection Station 55 04 00 N 84 51 04 W 55 066613 N 84 851164 W 55 066613 84 851164Site 500 RCAF Station Winisk Sector Control Station 55 14 39 N 85 06 42 W 55 2442 N 85 1117 W 55 2442 85 1117 Winisk RemediatedSite 503 Doppler Detection Station 55 17 05 N 85 42 30 W 55 284721 N 85 708336 W 55 284721 85 708336Site 506 Doppler Detection Station 55 17 17 N 86 25 25 W 55 288032 N 86 423622 W 55 288032 86 423622Site 509 Doppler Detection Station 55 29 25 N 87 04 26 W 55 490167 N 87 074014 W 55 490167 87 074014Site 512 Doppler Detection Station 55 35 26 N 87 51 54 W 55 590647 N 87 865076 W 55 590647 87 865076Site 515 Doppler Detection Station 55 52 51 N 88 35 01 W 55 880790 N 88 583708 W 55 880790 88 583708Site 518 Doppler Detection Station 55 58 28 N 89 13 11 W 55 974316 N 89 219653 W 55 974316 89 219653Site 521 Doppler Detection Station 56 13 30 N 89 53 22 W 56 225037 N 89 889381 W 56 225037 89 889381Site 524 Doppler Detection Station 56 17 25 N 90 40 01 W 56 290352 N 90 666916 W 56 290352 90 666916Site 527 Doppler Detection Station 56 24 41 N 91 27 39 W 56 411439 N 91 460713 W 56 411439 91 460713Site 530 Doppler Detection Station 56 22 49 N 92 11 21 W 56 380230 N 92 189115 W 56 380230 92 189115Site 533 Doppler Detection Station 56 27 58 N 92 48 28 W 56 466152 N 92 807660 W 56 466152 92 807660Site 536 Doppler Detection Station 56 23 43 N 93 20 05 W 56 395274 N 93 334667 W 56 395274 93 334667Site 600 RCAF Station Bird Sector Control Station 56 30 26 N 94 12 48 W 56 50725 N 94 21345 W 56 50725 94 21345 Bird Site 603 Doppler Detection Station 56 10 00 N 94 42 05 W 56 166667 N 94 701389 W 56 166667 94 701389Site 606 Doppler Detection Station 56 01 33 N 95 25 20 W 56 025833 N 95 422222 W 56 025833 95 422222Site 609 Doppler Detection Station 55 48 25 N 96 05 17 W 55 806944 N 96 088056 W 55 806944 96 088056Site 612 Doppler Detection Station 55 39 40 N 96 42 40 W 55 661111 N 96 711111 W 55 661111 96 711111Site 615 Doppler Detection Station 55 19 00 N 97 15 30 W 55 316667 N 97 258333 W 55 316667 97 258333Site 618 Doppler Detection Station 55 10 49 N 97 51 37 W 55 180278 N 97 860278 W 55 180278 97 860278Site 621 Doppler Detection Station 54 54 47 N 98 30 38 W 54 913056 N 98 510556 W 54 913056 98 510556Site 624 Doppler Detection Station 54 47 55 N 99 16 38 W 54 798611 N 99 277222 W 54 798611 99 277222Site 627 Doppler Detection Station 54 38 10 N 99 52 50 W 54 636111 N 99 880556 W 54 636111 99 880556Site 630 Doppler Detection Station 54 39 57 N 100 38 40 W 54 665833 N 100 644444 W 54 665833 100 644444Site 700 RCAF Station Cranberry Portage Sector Control Station 54 35 08 N 101 22 17 W 54 58547 N 101 37139 W 54 58547 101 37139 Cranberry Portage Site 701Site 703 Doppler Detection Station 54 40 50 N 102 03 10 W 54 680556 N 102 052778 W 54 680556 102 052778Site 706 Doppler Detection Station 54 39 08 N 102 42 08 W 54 652222 N 102 702222 W 54 652222 102 702222Site 709 Doppler Detection Station 54 49 47 N 103 22 30 W 54 829722 N 103 375000 W 54 829722 103 375000Site 712 Doppler Detection Station 54 53 48 N 104 16 10 W 54 896667 N 104 269444 W 54 896667 104 269444Site 715 Doppler Detection Station 54 58 27 N 104 47 25 W 54 974167 N 104 790278 W 54 974167 104 790278Site 718 Doppler Detection Station 54 55 54 N 105 44 10 W 54 931667 N 105 736111 W 54 931667 105 736111Site 721 Doppler Detection Station 55 03 56 N 106 26 10 W 55 065556 N 106 436111 W 55 065556 106 436111Site 724 Doppler Detection Station 55 04 30 N 107 08 20 W 55 075000 N 107 138889 W 55 075000 107 138889Site 727 Doppler Detection Station 55 14 40 N 107 38 52 W 55 244444 N 107 647778 W 55 244444 107 647778Site 730 Doppler Detection Station 55 19 27 N 108 05 40 W 55 324167 N 108 094444 W 55 324167 108 094444Site 733 Doppler Detection Station 55 36 50 N 108 28 35 W 55 613889 N 108 476389 W 55 613889 108 476389Site 736 Doppler Detection Station 55 59 46 N 109 17 00 W 55 996111 N 109 283333 W 55 996111 109 283333Site 739 Doppler Detection Station 56 08 32 N 109 28 35 W 56 142222 N 109 476389 W 56 142222 109 476389Site 742 Doppler Detection Station 56 21 30 N 110 23 55 W 56 358333 N 110 398611 W 56 358333 110 398611Site 745 Doppler Detection Station 56 31 47 N 110 58 00 W 56 529722 N 110 966667 W 56 529722 110 966667Site 800 RCAF Station Stoney Mountain Sector Control Station 56 26 59 N 111 02 02 W 56 44973 N 111 0339 W 56 44973 111 0339 Stoney Mountain Site 803 Doppler Detection Station 56 31 06 N 111 47 05 W 56 518333 N 111 784722 W 56 518333 111 784722Site 806 Doppler Detection Station 56 33 32 N 112 12 40 W 56 558889 N 112 211111 W 56 558889 112 211111Site 809 Doppler Detection Station 56 36 24 N 113 04 15 W 56 606722 N 113 070833 W 56 606722 113 070833Site 812 Doppler Detection Station 56 22 23 N 113 26 20 W 56 373056 N 113 438889 W 56 373056 113 438889Site 815 Doppler Detection Station 55 59 49 N 114 05 24 W 55 996944 N 114 090000 W 55 996944 114 090000Site 818 Doppler Detection Station 55 49 13 N 114 39 17 W 55 820278 N 114 654722 W 55 820278 114 654722Site 821 Doppler Detection Station 55 38 44 N 115 01 14 W 55 645556 N 115 020556 W 55 645556 115 020556Site 824 Doppler Detection Station 55 36 48 N 115 43 30 W 55 613333 N 115 725000 W 55 613333 115 725000Site 827 Doppler Detection Station 55 32 18 N 116 07 19 W 55 538333 N 116 121944 W 55 538333 116 121944Site 830 Doppler Detection Station 55 37 24 N 117 03 06 W 55 623333 N 117 051667 W 55 623333 117 051667Site 833 Doppler Detection Station 55 31 06 N 117 43 30 W 55 518333 N 117 725000 W 55 518333 117 725000Site 836 Doppler Detection Station 55 36 55 N 118 34 02 W 55 615278 N 118 567222 W 55 615278 118 567222Site 839 Doppler Detection Station 55 34 11 N 119 13 21 W 55 569722 N 119 222500 W 55 569722 119 222500Site 842 Doppler Detection Station 55 37 26 N 119 42 46 W 55 623956 N 119 712778 W 55 623956 119 712778Site 900 RCAF Station Dawson Creek Sector Control Station 55 44 47 N 120 13 47 W 55 74627 N 120 22968 W 55 74627 120 22968 Dawson Creek Site 900RSite 901Site 903 Doppler Detection Station 55 36 45 N 120 25 30 W 55 612500 N 120 425000 W 55 612500 120 425000Site 050 Fort Albany Tropospheric Scatter Repeater 52 12 41 N 81 40 26 W 52 21138 N 81 67393 W 52 21138 81 67393Site 060 Relay Tropospheric Scatter Repeater 49 59 56 N 81 37 07 W 49 9990 N 81 6187 W 49 9990 81 6187Site 070 Mount Kempis Tropospheric Scatter Repeater 48 22 34 N 80 16 05 W 48 37621 N 80 26805 W 48 37621 80 26805Map all coordinates using OpenStreetMapDownload coordinates as KML GPX all coordinates GPX primary coordinates GPX secondary coordinates POL Supply Points EditPetroleums Oils and Lubricants POL Supply Points were distribution centers for consumable petroleum materials used to fuel and maintain the Mid Canada Line DDS sites Co located with Sector Control Stations when possible petroleum products were received in bulk and shipped out by air from these locations From the same December 1956 listing 10 Supply Point MCL Sites Serviced CoordinatesHopedale NF 201 55 27 52 N 60 13 58 W 55 46448 N 60 23281 W 55 46448 60 23281Goose Bay NF 203 206 209 212Knob Lake QC 215 218 221 224 227 303 306 309 312 315 318 321 54 48 52 N 66 45 19 W 54 81445 N 66 75540 W 54 81445 66 75540Great Whale River QC 324 327 330 333 336 339 342 403 406 409 410 55 16 44 N 77 44 21 W 55 2788 N 77 7391 W 55 2788 77 7391Bear Island Nunavut 412 413Winisk ON 415 416 418 421 424 427 503 506 509 512 515 518 55 14 39 N 85 06 42 W 55 2442 N 85 1117 W 55 2442 85 1117Gillam MB 600 536 533 530 527 524 521Ilford MB 606 609Thicket Portage MB 615 618 612Wabowden MB 621Wekusko MB 624 627 630 54 30 12 N 99 45 04 W 54 503333 N 99 751111 W 54 503333 99 751111Cranberry Portage MB 700 701 54 35 08 N 101 22 17 W 54 58547 N 101 37139 W 54 58547 101 37139Flin Flon MB 703 706 709La Ronge SK 712 715 718 721Meadow Lake SK 724 727 730 733 736 739Anzac AB 742 745Waterways AB 803 806Slave Lake AB 809 812 815 816 821High Prairie AB 824 827Falher AB 830 833Sexsmith AB 836 839Dawson Creek BC 842 900R 903 55 44 47 N 120 13 47 W 55 74627 N 120 22968 W 55 74627 120 22968See also EditDistant Early Warning Line List of Royal Canadian Air Force stations Pinetree LineNotes Edit Whitehead states the line stretched to North Bay but lists stations only as far as Mattawa 2 References EditCitations Edit a b c McCamley 2013 p 34 a b c d e f g Whitehead 1995 Willis amp Griffiths 2007 p 37 a b Willis amp Griffiths 2007 p 36 a b c d e f g h i j k l m n Thorne 1979 Orlemann Eric 2001 LeTourneau Earthmovers MBI Publishing p 66 ISBN 0 7603 0840 3 Skolnik 2007 p 38 Skolnik 2007 p 45 Wolff Christian AN FPS 23 a b Mid Canada Line Bibliography Edit Thorne D H 1979 The Mid Canada Line 1958 1965 a href Template Cite magazine html title Template Cite magazine cite magazine a Cite magazine requires magazine help Lester Alex 2019 Special Contract A Story of Defence Communications in Canada PDF St Francis Xavier University ISBN 9781989537008 Archived from the original PDF on 24 June 2021 Retrieved 21 June 2021 Whitehead James Rennie 1995 Memoirs of a Boffin Ch 7 Willis Nicholas Griffiths Hugh 2007 Advances in bistatic radar SciTech Publishing ISBN 978 1 891121 48 7 McCamley Nick 2013 Cold War Secret Nuclear Bunkers The Passive Defence of the Western World Pen and Sword ISBN 9781844155088 Skolnik Merrill 2007 Fluttar DEW Line Gap Filler In Willis Nicholas Griffiths Hugh eds Advances in Bistatic Radar SciTech Publishing pp 35 46 ISBN 9781891121487 External links EditThe Mid Canada Line includes maps and photos from most of the stations Retrieved from https en wikipedia org w index php title Mid Canada Line amp oldid 1169356612, wikipedia, wiki, book, books, library,

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