AN/SPS-48

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AN/SPS-48
Radar antennas on USS Theodore Roosevelt CVN-71.jpg
An SPS-48E radar antenna (the large square panel) aboard USS Theodore Roosevelt (CVN-71).
Country of origin United States
Introduced21 February 1966
Type3D Air-search
Frequency E and F band
(2 to 4 GHz)
Range250 nmi (460 km)
Altitude100,000 ft (30,000 m)
Diameter17 ft (5.2 m) by 17 ft 6 in (5.33 m)
Azimuth 0-360°
Elevation0-65°
Precision690 ft (210 m) elevation
1/6° azimuth
Power35 kW (avg)
AN/SPS 48e on board the USS Ronald Reagan (CVN-76) . Ansps48e.jpg
AN/SPS 48e on board the USS Ronald Reagan (CVN-76) .

The AN/SPS-48 is a US naval electronically scanned array, air search three-dimensional radar system manufactured by ITT Exelis and deployed in the 1960s as the primary air search sensor for anti-aircraft warships. The deployment of the AN/SPY-1 and the end of the Cold War led to the decommissioning of many such ships, and many of these vessel's AN/SPS-48 sets were reused on aircraft carriers and amphibious ships where it is used to direct targets for air defense systems such as the Sea Sparrow and RIM-116 SAM missiles. Existing sets are being modernized under the ROAR program to AN/SPS-48G standard for better reliability and usability. [1]

Contents

Operation

A three-dimensional radar is mounted on a base that allows for 360 degrees of rotation. The target can be located at a given azimuth. The range of the target is also identified due to the time it takes the beam to go out and back to the receiver. What makes this radar system different is its ability to detect the height of the target above the surface of the water. With these three pieces of data the radar's central processor has the ability to place the target in an X,Y,Z, 3 dimensional space.

For the SPS-48 in particular, the antenna is mechanically rotated to scan azimuth, while beams are electronically steered to cover elevation by varying the transmitter frequency. [1] The 4,500 lb (2,000 kg) antenna is capable of rotating at 7.5 or 15 rpm.

According to ITT Exelis, [2] the system has a range exceeding 200 nmi (370 km) and can track targets up to 69 degrees in elevation. The AN/SPS-48E is capable of providing target range, bearing and altitude information using a frequency-scanning antenna using a range of different frequencies in E band and F band with three power modes: high, medium and low. SPS-48 radars stack multiple beams in a train of pulses at different frequencies. The beams scan different elevation areas, allowing the stack to cover up to 69 degrees of elevation.

History

The NTDS Technical and Operational Requirements, written in 1956, called for two radar systems: a three-dimensional search radar with a range of more than 200 miles that can turn over targets to missile and gun radars, and a two-dimensional long-range search radar able to detect relatively small targets at ranges over 250 miles, which can hand targets to the three-dimensional radar once they enter its range. The former eventually became the AN/SPS-48; the latter became the AN/SPS-49. [3] [4] [5] [6] :17

Development of the SPS-48 in particular started in 1960 in response to shortcomings of the AN/SPS-39. [4] [7] A development contract for two service models (XN-1 and XN-2) was awarded in June 1960. XN-1 completed system testing in April 1962 and was operated until December 1962 to collect reliability data ashore. XN-2 was delivered July 1962 and installed aboard USS Preble (DLG-15) for shipboard evaluation. [8]

A production contract of 13 radars was awarded in June 1963. Unit #6 was installed on USS Worden (DLG-18) between March and June 1965 for reliability testing by the Operational Test and Evaluation Force. Testing results were positive, and the AN/SPS-48 was formally approved for service use by the Chief of Naval Operations on 21 February 1966. [8] The AN/SPS-48 replaced AN/SPS-39 on the Belknap, Coontz and Leahy classes between 1967 and 1975 under the Guided Missile Frigate Anti-Air Warfare Modernization Program. [9]

Moving Target Indicator (MTI) capability, needed to see targets in clutter and weather, was added to the SPS-48 radar system with the upgrade to the SPS-48A. This upgrade was first evaluated with the USS Biddle (DLG-34) in 1968. [6] :94

The AN/SPS-48B is noted as being installed on the Nimitz class aircraft carriers prior to the USS Abraham Lincoln (CVN-72). [10] [11] The Spruance-class destroyer, known in development as the DX, was designed with accommodations for replacing the AN/SPS-40B radar with the AN/SPS-48B for the DXG variant. This variant eventually became the Kidd-class destroyer, though it is unclear if it received the SPS-48B variant in practice. [12] [13]

The AN/SPS-48C added Automatic Detection and Tracking to the AN/SPS-48 system. The first prototype with ADT capability was manufactured by Gilfillan for evaluation at Mare Island mid-1964. It contained a special-purpose "pipeline processor" that had large amounts of memory for scan-to-scan comparisons and to identify and save blips that seemed to persist near the same location. This processor also built clutter maps on each 360-degree scan and looked for changes in the map, which it saved as possible targets. These blips and clutter changes that may be possible targets were sent to the NTDS, which did further comparisons to determine which ones had motions characteristic of a ship or airplane. This system would go to sea for operational evaluation in 1967 and be incorporated into the Belknap-class cruisers by 1975. [5]

The AN/SPS-48E was first introduced 1987. The component count was reduced compared to the -48C (126,000 versus 280,000) and Built-In Test (BIT) capabilities were added, reducing the MTBF and manpower requirements. Performance improvements included improved resistance to jamming and ECM, better detection of smaller targets and targets on the horizon, high-angle tracking, and the ability to accept and execute commands from external air defense or shipboard combat systems. It was included as part of the New Threat Upgrade. [14] [6]

The AN/SPS-48G program addresses problems of long-term obsolescence through a system redesign that improves the radar's reliability, maintainability, and supportability through technology improvements, open architecture (OA) design, and improved logistics processes while reducing lifecycle cost. It only affects the layout of the below-deck units. The plan is to back-fit the existing AN/SPS-48E population from 2011 through 2020, with the SPS-48G units. They will support fleet 3D air search requirements through 2050 and beyond for the ship classes that have SPS-48G. The earlier 1st and 2nd stage RF amplifiers are replaced with a solid state transmitter and the receiver, processor, and Auxiliary Detection Processor, formerly housed in individual equipment cabinets, are combined into a single cabinet. The number of Lowest Replaceable Units is reduced by 87%, and mean time between critical failure is improved over the AN/SPS-48E(V) by 104%. The new commercial off-the-shelf (COTS) radar processor's computing capabilities will be sustained through a planned tech-refresh program. More intuitive and interactive built-in-test and embedded maintenance and operator training makes available all radar technical, engineering, and logistics data and allows remote monitoring and distance support, while ensuring accurate and timely configuration management. [1] [15]

Uses

With the air targets exact 3D location it is available for interception/removal via either the ship's weapon system or through linked weapons platforms located elsewhere. It is the predecessor of the AEGIS system currently in use on Arleigh Burke-class destroyers and Ticonderoga-class cruisers. The AEGIS AN/SPY-1B/D radars are electronically scanned phased arrays, while the SPS-48E is frequency scanned in elevation, and mounted on a rotating joint that spins the radar in azimuth. The AN/SPS-48 is carried by US Navy ships such as Nimitz-class aircraft carriers, Wasp-class amphibious assault ships, Tarawa-class amphibious assault ships and San Antonio-class amphibious transport docks.

Variants

Masts of USS Macdonough (DDG-39) showing an SPS-48 radar near the center of the image USS MacDonough (DDG-39) radar.jpg
Masts of USS Macdonough (DDG-39) showing an SPS-48 radar near the center of the image

See also

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References

  1. 1 2 3 4 "United States Navy Factfile AN/SPS-48G". Naval Sea Systems Command. 24 October 2012. Archived from the original on 22 Jun 2018.
  2. "ITT Exelis - The Power of Ingenuity". Exelisinc.com. 2011-10-27. Archived from the original on 2013-03-02. Retrieved 2012-10-01.
  3. Boslaugh, David L. (12 May 2021). "Building the U.S. Navy's First Seagoing Digital System - Chapter 4 of the Story of the Naval Tactical Data System". ethw.org.
  4. 1 2 Boslaugh, David L. (13 Jan 2015). "Moving the Firing Key to NTDS - Chapter 6 of the Story of the Naval Tactical Data System". ethw.org.
  5. 1 2 Boslaugh, David L. (April 2003). When Computers Went to Sea: The Digitization of the United States Navy. Wiley-IEEE Computer Society Press. pp. 319–320, 340–341.
  6. 1 2 3 Treadway, James A. (2005). Hard Charger! The Story of the USS Biddle (DLG-34).
  7. Boslaugh, David L. (April 2003). When Computers Went to Sea: The Digitization of the United States Navy. Wiley-IEEE Computer Society Press. pp. 319–320.
  8. 1 2 Bailey, Donald C. (September 1966). "AN/SPS-48 Radar Development". Naval Ship Systems Command Technical News. 15 (9): 16–18.
  9. Cockell, Jr., William A. (1 January 1972). "Professional Notes". Proceedings of the U.S. Naval Institute. 98 (1). Retrieved 13 February 2023.
  10. Chant, Christopher (2014). A Compendium of Armaments and Military Hardware. p. 189. ISBN   9781134646685.
  11. Terzibaschitsch, Stefan (1985). "The U.S. Navy's Aircraft Carriers: A Pictorial Report". Warship International. 22 (1): 43.
  12. Collins, John T. (April 1975). "USS SPRUANCE (DD963) CLASS, DESIGNED FOR CHANGE—THE PAYOFF IS NOW". Naval Engineers Journal. 87 (2): 27–31. doi:10.1111/j.1559-3584.1975.tb03712.x.
  13. Friedman, Norman. U.S. Destroyers : an illustrated design history. pp. 374–377. ISBN   1-68247-757-6. OCLC   1250511698.
  14. Roulette, Jay F.; Skrivseth, Kenneth A. (1997). "Coherent Data Collection and Analysis Capability for the AN/SPS-48E Radar" (PDF). Johns Hopkins APL Technical Digest. 18 (3): 388–397.
  15. Quigley, Daniel; Walters, Lance; Caitlin, McInnes; Gorby, Christopher. "The AN/SPS-48G Radar System Sustainability Upgrade" (PDF). Leading Edge. 7 (2): 104–109. Retrieved 13 February 2023.
  16. Truver, Scott C. (April 1989). "Losing Out on Carrier Radar Improvements". Proceedings of the U.S. Naval Institute. 115 (4).
  17. Friedman, Norman (1989). The Naval Institute Guide to World Naval Weapons Systems. Naval Institute Press. ISBN   9780870217937.