New Radar TechnologyNew Radar Technology8 500-10 500 MHz Band8 500-10 500 MHz Band
Presented byPresented by
Mr. Frank Sanders
National Telecommunications & Information Administration
Mr. Thomas Fagan
Raytheon
Technical CharacteristicsTechnical Characteristics• 8 500-10 500 MHz radars exist on land-based, transportable, 8 500-10 500 MHz radars exist on land-based, transportable, shipboard, and airborne platforms.shipboard, and airborne platforms.
• Radiodetermination functions include airborne, space & Radiodetermination functions include airborne, space & surface search, ground-mapping, terrain-following, navigation surface search, ground-mapping, terrain-following, navigation (both aeronautical and maritime), and target-identification.(both aeronautical and maritime), and target-identification.
• Major differences among radar designs include: transmitter Major differences among radar designs include: transmitter output devices, transmit duty cycles, emission bandwidths, output devices, transmit duty cycles, emission bandwidths, presence and types of intra-pulse modulation, frequency-agile presence and types of intra-pulse modulation, frequency-agile capabilities of some, transmitter peak and average powers, and capabilities of some, transmitter peak and average powers, and types of transmitter RF power devices.types of transmitter RF power devices.
• These characteristics, individually and in combination, all These characteristics, individually and in combination, all have major bearing on the compatibility of the radars with other have major bearing on the compatibility of the radars with other radio systems in their environment.radio systems in their environment.
More Technical CharacteristicsMore Technical Characteristics
• Many radiolocation radars in this band are primarily Many radiolocation radars in this band are primarily used for detection of airborne objects.used for detection of airborne objects.
• The purpose is to measure target altitude as well as The purpose is to measure target altitude as well as range and bearing.range and bearing.
– Some of the airborne targets are small and at long ranges as great as 555 km (300 nautical miles).– These radiolocation radars must have high sensitivity and must provide a high degree of suppression to all forms of clutter return, including that from sea, land, and precipitation.
• In some cases, the radar emissions in this band are In some cases, the radar emissions in this band are required to trigger radar beacons.required to trigger radar beacons.
Mission Requirements Dictate Mission Requirements Dictate General Design CharacteristicsGeneral Design Characteristics
Basic radar design parameters are as follows:Basic radar design parameters are as follows:– Minimum target size (cross section) and maximum range requirements
– Maximum available space for antenna (constrained, for ex., by platform size)
– Spectrum band (driven by propagation needs & maximum possible antenna size)
– Required (minimum acceptable) signal-to-noise ratio (SNR) for target echoes
– Minimum number of pulses (N), echoed from each target to achieve minimum SNR
– Antenna scan rate and beam scanning pattern, determined by the values of N and PRI
– Pulse repetition interval (PRI), determined by maximum radar range
– Pulse width and shape, determined by need for best possible location resolution
Mission Requirements Dictate Mission Requirements Dictate General Design Characteristics General Design Characteristics (cont.)(cont.)
• Basic radar design parameters continued:Basic radar design parameters continued:– Pulse peak power, determined by target size (cross section) and maximum range– Pulse modulation (coding), which can allow pulses to be transmitted at lower peak power, but with proportionately longer length. (i.e., average power tends to stay constant).– Selection of radar transmitter output device is determined by needs for peak power, pulse modulation (if any), size, weight, cost, reliability, and spectrum characteristics.
• 8 500-10 500 MHz radars often have small platform-size (and 8 500-10 500 MHz radars often have small platform-size (and thus small antenna) constraints.thus small antenna) constraints.• 8 500-10 500 MHz radars often need to observe small targets 8 500-10 500 MHz radars often need to observe small targets at relatively long ranges using designs that have reasonable at relatively long ranges using designs that have reasonable cost, reliability, and maintainability.cost, reliability, and maintainability.• These constraints feed back into all of the design parameters These constraints feed back into all of the design parameters listed on the previous slide.listed on the previous slide.
Mission Requirements Dictate Mission Requirements Dictate General Design Characteristics General Design Characteristics (cont.)(cont.)
• 8 500 10 500 MHz radars often need high transmitter 8 500 10 500 MHz radars often need high transmitter peak and average powerpeak and average power• Master-oscillator-power-amplifier transmitters may Master-oscillator-power-amplifier transmitters may be preferred over power oscillators.be preferred over power oscillators.• Tunability and frequency-agility are sometimes Tunability and frequency-agility are sometimes requiredrequired• Some require pulse modulation such as a linear (or Some require pulse modulation such as a linear (or non-linear) FM chirp or phase codes.non-linear) FM chirp or phase codes.• Antenna mainbeams often need to be steerable in Antenna mainbeams often need to be steerable in one or both angular dimensions, sometimes using one or both angular dimensions, sometimes using electronic beam steering.electronic beam steering.
Mission Requirements Dictate Mission Requirements Dictate General Design Characteristics General Design Characteristics (cont.)(cont.)
• Driven by mission requirements, individual 8 500-10 500 MHz Driven by mission requirements, individual 8 500-10 500 MHz radars need a wide variety of pulse widths & pulse repetition radars need a wide variety of pulse widths & pulse repetition frequencies. Chirp radars need a variety of chirp bandwidths. frequencies. Chirp radars need a variety of chirp bandwidths. Some frequency-agile radars need a variety of agile-frequency Some frequency-agile radars need a variety of agile-frequency modes. Such design flexibilities can provide useful tools for modes. Such design flexibilities can provide useful tools for performing missions while maintaining compatibility with other performing missions while maintaining compatibility with other radars in the environment.radars in the environment.• Versatile receiving and processing capabilities are also often Versatile receiving and processing capabilities are also often needed forneeded for8 500-10 500 MHz radars to include:8 500-10 500 MHz radars to include:
– Auxiliary sidelobe‑blanking receive antennas;– Processing of coherent-carrier pulse trains to suppress clutter return by means of moving-target-indication (MTI):– Constant-false-alarm-rate (CFAR) techniques:– Adaptive selection of operating frequencies based on sensing of interference on various frequencies (some cases).
Marine RadarMarine RadarU.S. Department of CommerceU.S. Department of Commerce
• Typical X-Band maritime radionavigation radar
• Magnetron Output
• Integrated Platform (receiver & transmitter contained in small mast- mounted package)
• Typically found onboard pleasure craft and commercial ships
8 500-10 500 MHz Marine Radar8 500-10 500 MHz Marine Radar
Mk-2 Pathfinder (marine)Mk-2 Pathfinder (marine)
RaytheonRaytheon
Mission Requirements Dictate Mission Requirements Dictate Frequency RangeFrequency Range
• Atmospheric attenuation and water vapor absorption help determine radar operational frequencies.
• Weather radars use frequencies where water vapor absorption is high.
• Radiolocation radars use frequencies where water vapor absorption is low.– Only certain frequency bands have low water
vapor absorption.
8 500-10 500 MHz Radar8 500-10 500 MHz RadarDesign TradeoffsDesign Tradeoffs
• Except for some ground-based systems, 8 500-10 500 Except for some ground-based systems, 8 500-10 500 MHz platform dimensions typically restrict the maximum MHz platform dimensions typically restrict the maximum possible size of transmitter antennae, both for present and possible size of transmitter antennae, both for present and future systems.future systems.
• Small antenna sizes tend to force high pulse peak power Small antenna sizes tend to force high pulse peak power levels for adequate target detection. Alternatively, if lower levels for adequate target detection. Alternatively, if lower peak power levels are used then longer pulse widths are peak power levels are used then longer pulse widths are required to expose targets to enough total energy to detect required to expose targets to enough total energy to detect them.them.
• But, if longer pulses are used, then additional pulse But, if longer pulses are used, then additional pulse modulation (coding) is required to achieve adequate range modulation (coding) is required to achieve adequate range resolution.resolution.
8 500-10 500 MHz Radar8 500-10 500 MHz RadarDesign Tradeoffs Design Tradeoffs (cont.)(cont.)
• The choice of 8 500-10 500 MHz transmitter output The choice of 8 500-10 500 MHz transmitter output device technology is a major design decision. It device technology is a major design decision. It significantly affects radar performance, cost, and spectrum significantly affects radar performance, cost, and spectrum out-of-band and spurious emission levels. Tradeoffs out-of-band and spurious emission levels. Tradeoffs between all these parameters must be carefully balanced between all these parameters must be carefully balanced by designers of X-band radars.by designers of X-band radars.
• Some 8 500-10 500 MHz radar designs may be driven Some 8 500-10 500 MHz radar designs may be driven primarily by cost and size factors, and may therefore need primarily by cost and size factors, and may therefore need to use cheaper and lighter tubes, such as magnetrons. to use cheaper and lighter tubes, such as magnetrons. Conversely, more advanced transmitter output devices Conversely, more advanced transmitter output devices (eg; solid state), may be more costly, heavier, and more (eg; solid state), may be more costly, heavier, and more complex. But they may offer better-controlled pulse complex. But they may offer better-controlled pulse shaping and thus possibly improved spectrum out-of-band shaping and thus possibly improved spectrum out-of-band and spurious emission characteristics.and spurious emission characteristics.
8 500-10 500 MHz Airborne Radar8 500-10 500 MHz Airborne Radar
AN/APG-73 radarAN/APG-73 radar
RaytheonRaytheon
• Typical example of an Airborne Radar where it must fit into the nosecone of an aircraft• Note that the antenna is small to fit into the limited amount of space available
8 500-10 500 MHz Airborne Radar8 500-10 500 MHz Airborne Radar
AN/APG-70 radarAN/APG-70 radar
RaytheonRaytheon
8 500-10 500 MHz Surface 8 500-10 500 MHz Surface Surveillance RadarSurveillance Radar
Advanced Surface Movement RadarAdvanced Surface Movement Radar(ASMR)(ASMR)
RaytheonRaytheon
Used for monitoring ground traffic (airplanes, service vehicles, baggage vehicles, security vehicles) at airports
Future 8 500-10 500 MHz Radar Future 8 500-10 500 MHz Radar Design Trends Design Trends (cont.)(cont.)
• More flexibility will be needed, including the capacity to operate different More flexibility will be needed, including the capacity to operate different modes in different azimuth and elevation sectors.modes in different azimuth and elevation sectors.
• Capability to operate in a wide bandwidth will be needed.Capability to operate in a wide bandwidth will be needed.
• Electronically-steerable antennae will become more common.Electronically-steerable antennae will become more common.
• Current technology makes phase steering a practical and attractive Current technology makes phase steering a practical and attractive alternative to frequency steering.alternative to frequency steering.
– Radars in other bands have employed phase steering in both azimuth and elevation, and can steer any fundamental frequency in the radar’s operating band to any arbitrary azimuth and elevation within its angular coverage area.– Phase steering may enhance electromagnetic compatibility in many circumstances.
• Reduction of unwanted emissions below those of the existing radars that Reduction of unwanted emissions below those of the existing radars that employ magnetrons or crossed-field amplifiers may occur through the use of employ magnetrons or crossed-field amplifiers may occur through the use of linear beam and solid-state output devices.linear beam and solid-state output devices.
Future 8 500-10 500 MHz Radar Future 8 500-10 500 MHz Radar Design Trends Design Trends (cont.)(cont.)
• Radar designs will continue to evolve– Towards solid-state output devices; – Radar bandwidth will increase (instantaneous and
operational); – Peak power will increase on some radars; – Average power will increase on some radars; – Pulse Repetition Frequency (PRF) and pulse width
will increase; – Amount of coding modulation (phase and chirp) will
increase due to the trend towards solid-state output devices;
– Use of this radar frequency band will increase.
SummarySummary
• Development of radars in this band is an ongoing process that continue to evolve as technology advances.
• Working Party 8B will continue to follow these technology trends and their consequences and impact on the use of the radio spectrum.
• Thank You for your attention!
