Editing Radar (section)

====Phased array====
[[File:PAVE PAWS Radar Clear AFS Alaska.jpg|thumb|right|[[Phased array]]: Not all radar antennas must rotate to scan the sky.]]
{{Main|Phased array}}
Another method of steering is used in a [[phased array]] radar.

Phased array antennas are composed of evenly spaced similar antenna elements, such as aerials or rows of slotted waveguide. Each antenna element or group of antenna elements incorporates a discrete phase shift that produces a phase gradient across the array. For example, array elements producing a 5 degree phase shift for each wavelength across the array face will produce a beam pointed 5 degrees away from the centerline perpendicular to the array face. Signals travelling along that beam will be reinforced. Signals offset from that beam will be cancelled. The amount of reinforcement is [[antenna gain]]. The amount of cancellation is side-lobe suppression.<ref>{{cite web|url=http://mit.edu/6.933/www/Fall2000/mode-s/sidelobe.html|title=Side-Lobe Suppression|publisher=MIT|access-date=11 September 2012|archive-date=31 March 2012|archive-url=https://web.archive.org/web/20120331085410/http://mit.edu/6.933/www/Fall2000/mode-s/sidelobe.html|url-status=dead}}</ref>

Phased array radars have been in use since the earliest years of radar in World War II ([[Mammut radar]]), but electronic device limitations led to poor performance. Phased array radars were originally used for missile defence (see for example [[Safeguard Program]]). They are the heart of the ship-borne [[Aegis Combat System]] and the [[MIM-104 Patriot|Patriot Missile System]]. The massive redundancy associated with having a large number of array elements increases reliability at the expense of gradual performance degradation that occurs as individual phase elements fail. To a lesser extent, phased array radars have been used in [[weather]] [[surveillance]]. As of 2017, NOAA plans to implement a national network of multi-function phased array radars throughout the United States within 10 years, for meteorological studies and flight monitoring.<ref>{{cite web|url=http://www.nssl.noaa.gov/projects/mpar/|title=Multi-function Phased Array Radar (MPAR) Project|author=National Severe Storms Laboratory|publisher=NOAA|access-date=8 February 2017|author-link=National Severe Storms Laboratory|archive-date=2 February 2017|archive-url=https://web.archive.org/web/20170202073609/http://www.nssl.noaa.gov/projects/mpar/|url-status=live}}</ref>

Phased array antennas can be built to conform to specific shapes, like missiles, infantry support vehicles, ships, and aircraft.

As the price of electronics has fallen, phased array radars have become more common. Almost all modern military radar systems are based on phased arrays, where the small additional cost is offset by the improved reliability of a system with no moving parts. Traditional moving-antenna designs are still widely used in roles where cost is a significant factor such as air traffic surveillance and similar systems.

Phased array radars are valued for use in aircraft since they can track multiple targets. The first aircraft to use a phased array radar was the [[B-1B Lancer]]. The first fighter aircraft to use phased array radar was the [[Mikoyan MiG-31]]. The MiG-31M's SBI-16 [[Zaslon]] [[passive electronically scanned array]] radar was considered to be the world's most powerful fighter radar,{{citation needed|date=January 2023}} until the [[AN/APG-77]] [[active electronically scanned array]] was introduced on the [[Lockheed Martin F-22 Raptor]].

Phased-array [[interferometry]] or [[aperture synthesis]] techniques, using an array of separate dishes that are phased into a single effective aperture, are not typical for radar applications, although they are widely used in [[radio astronomy]]. Because of the [[thinned array curse]], such multiple aperture arrays, when used in transmitters, result in narrow beams at the expense of reducing the total power transmitted to the target. In principle, such techniques could increase spatial resolution, but the lower power means that this is generally not effective.

[[Synthetic aperture radar|Aperture synthesis]] by post-processing motion data from a single moving source, on the other hand, is widely used in space and [[airborne radar system]]s.