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A Survey of Five Years' Progress in Marine Radar

Published online by Cambridge University Press:  18 January 2010

F. J. Wylie
F. J. Wylie
Affiliation:
(Radio Advisory Service)
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Extract

In describing progress in the development of a functional equipment, it would be quite normal to begin by defining the technical targets at which the engineers are aiming and the operational uses to which it will be put. In the case of marine radar, however, it is not possible to be precise in either of these matters. It might be said that the ultimate target is to make port, coastal and open sea work as safe and straightforward in poor visibility as in good; or, put in another way, to replace direct human vision in poor visibility and to improve upon it at any time when the distance of targets is to be measured with accuracy.

Type
Research Article
Information
The Journal of Navigation , Volume 7 , Issue 1 , January 1954 , pp. 59 - 77
Copyright
Copyright © The Royal Institute of Navigation 1954

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References

REFERENCES

1Wylie, F. J., and Kaye, M. W. (1949). The operational value of shipborne radar. This Journal, 2, 127.Google Scholar
2Perry, R. E. (1953). A record of radar performance in ice conditions. This Journal, 6, 74.Google Scholar
Le Page, L. S., and Milwright, A. L. P. (1953). Radar and ice. This Journal, 6, 113.Google Scholar
3Home Dickson, J. (1952). Radar chart-matching devices. This Journal, 5, 42.Google Scholar
4Radar and charts: a discussion (1950). This Journal, 3, 156.Google Scholar
5Wylie, F. J. (1952). Admiralty chart 2649 (letter). This Journal, 5, 429.Google Scholar
6Day, A. (1953). Navigation and hydrography. This Journal, 6, 1.Google Scholar
7 The Institute of Navigation (1952). The Use of Radar at Sea. Hollis & Carter.Google Scholar
8 Ministry of Transport (1948). Marine Radar: Performance Standards, H.M.S.O.Google Scholar
9Kiely, D. G. (1948). Note on side-lobe amplitude in a cheese aerial. A.S.R.E. Tech. Note TX/48/5.Google Scholar
10Wylie, F. J., and Welch, T. W. (1952). Progress in the development of marine radar. Journal of the Honourable Company of Master Mariners, 5, 222.Google Scholar
11National Research Council of Canada, Radio and Electrical Engineering Division (1953). Progress Reports.Google Scholar
12Milwright, A. L. P. (1950). Radar reflectors for lighthouses. A.S.R.E. Tech. Note TX/50/17.Google Scholar
13Stemp, V. P. (1949). Collapsible radar reflector. A.S.R.E. Tech. Note TX/49/18.Google Scholar
Stemp, V. P. (1950). Range trials of collapsible reflector. A.S.R.E. Tech. Note TX/50/14.Google Scholar
Ministry of Transport and Civil Aviation (28 August 1953). Demonstration of radar beacons and collapsible radar reflector.Google Scholar
14National Research Council of Canada (1953). Collapsible radar reflector. Press Notice No. 10.Google Scholar
15Bell, N. (1949). Experimental ramarks in lighthouses. A.S.R.E. Tech. Note TX/49/7.Google Scholar
16Le Page, L. S. (1952). A survey of requirements for port radar. This Journal, 5, 285.Google Scholar
17Wylie, F. J. (1951). Port approach and berthing in fog. This Journal, 4, 156.Google Scholar
18 Port of New York Authority (1953). Shore-based radar Jor New York Harbour.Google Scholar
19 Ministry of Transport and Civil Aviation (22 July 1953). Portable 3-cm. black-gap responder beacon.Google Scholar