Navy asks Raytheon to build two AMDR advanced shipboard radar systems for newest Burke-class destroyers

Jan. 16, 2020
The AMDR will supersede the AN/SPY-1 radar, and improve the Burke-class destroyer's ability to detect aircraft, surface ships, and ballistic missiles.

WASHINGTON – Shipboard radar experts at the Raytheon Co. will build two new advanced AN/SPY-6(V) Air and Missile Defense Radar (AMDR) for late-model Arleigh Burke-class (DDG 51) Aegis destroyers under terms of a $249.9 million U.S. Navy order announced last month.

Officials of the Naval Sea Systems Command in Washington are asking the Raytheon Integrated Defense Systems segment in Marlborough, Mass., to produce two AMDR low-rate initial production systems. Raytheon prevailed over Northrop Grumman Corp. and Lockheed Martin Corp. to build the AMDR in 2013.

The Raytheon AN/SPY-6(V) radar will improve the Burke-class destroyer's ability to detect hostile aircraft, surface ships, and ballistic missiles, Raytheon officials say. The AMDR will supersede the AN/SPY-1 radar, which has been standard equipment on Navy Burke-class Aegis destroyers and Ticonderoga-class cruisers.

The new radar will go aboard Flight III Burke-class destroyers. Thus far two Flight III Burke-class destroyers are under contract: the USS Jack H. Lucas (DDG 125); and the USS Louis H. Wilson Jr. (DDG 126).

Related: Lockheed Martin to integrate Aegis combat system with Raytheon shipboard missile defense radar system

The new Flight III versions of the Burke-class destroyers are under construction at Huntington Ingalls Inc. in Pascagoula, Miss., and at the General Dynamics Corp. Bath Iron Works segment in Bath, Me. Flight III is the latest version of the Burke-class guided missile destroyer.

The AN/SPY-6(V) missile-defense radar will provide greater detection ranges, increased discrimination accuracy, higher reliability and sustainability, and lower costs, compared to the AN/SPY-1D(V) radar onboard today’s Burke-class destroyers.

The system is built with individual building blocks called radar modular assemblies (RMAs), Raytheon officials say. Each RMA is a self-contained radar in a two-cubic-foot box; RMAs can stack together to form any size array to fit ship mission requirements.

The inherent scalability of the AN/SPY-6(V) AMDR also could enable new instantiations, such as backfits on existing Burke-class destroyers and installation on aircraft carriers, amphibious warfare ships, frigates, the littoral combat ship, and Zumwalt-class land-attack destroyers without significant new radar development costs, Raytheon officials say.

Related: Raytheon to continue building and maintaining AN/SPY-6(V) AMDR shipboard radar for Burke-class destroyers

For the Flight III Burke-class destroyer's SPY-6(V) AMDR will feature 37 RMAs. The new radar will be able to see targets half the size at twice the distance of today’s SPY-1 radar. The AMDR will have four array faces to provide full-time, 360-degree situational awareness. Each 14-by-14-foot face is about the same size as today’s SPY-1D(V) radar.

The AN/SPY-6(V) AMDR will 30 times more sensitive than the AN/SPY-1D(V) in the Flight III configuration, and is being designed to counter large and complex raids, Raytheon officials say. The new radar will have adaptive digital beamforming and radar signal processing for dealing with high-clutter and jamming environments.

The AN/SPY-6(V) radar also is reprogrammable to adapt to new missions or emerging threats. It uses high-powered gallium nitride (GaN) semiconductors, distributed receiver exciters, adaptive digital beamforming, and Intel processors for digital signal processing.

Related: Raytheon to build radar fire-control for Navy Flight III Burke-class destroyers in $123.5 million deal

The new radar will feature S-band radar coupled with X-band horizon-search radar, and a radar suite controller (RSC) to manage radar resources and integrate with the ship’s combat management system.

On this order Raytheon will do the work in Marlborough, Mass., and should be finished by June 2023. For more information contact Raytheon Integrated Defense Systems online at www.raytheon.com, or Naval Sea Systems Command at www.navsea.navy.mil.

About the Author

John Keller | Editor-in-Chief

John Keller is the Editor-in-Chief, Military & Aerospace Electronics Magazine--provides extensive coverage and analysis of enabling electronics and optoelectronic technologies in military, space and commercial aviation applications. John has been a member of the Military & Aerospace Electronics staff since 1989 and chief editor since 1995.

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