 |
|
| If you can't view the Datasheet, Please click here to try to view without PDF Reader . |
|
|
|
| If you can't view the Datasheet, Please click here to try to view without PDF Reader . |
|
|
| Datasheet File OCR Text: |
| Man Portable Radar Warning Receiver For Covert and U.A.V. Applications Figure 1 RWR Unit Introduction The unit is designed for Radar Warning Receiver (RWR) applications where small size and low power consumption are of prime importance, with filtering, amplification, detection and frequency measurement being combined into one multi-function unit. Figure 2 shows a block diagram of the RWR and its three integral RF modules. Two amplitude measurement channels allow direction finding by amplitude comparison between adjacent antennas. One of these channels is also used in standby mode for detecting the presence of signals by polling round the antennas. A two-tier discriminator, fed from one of the amplitude channels via an SPDT switch, performs frequency measurement. Frequency resolution is nominally 160 MHz over an 8 to 18 GHz band. Linear Amplifier N S Video Output Limiting Amplifier Trigger Inputs E DLVA W Bandpass Filter Video Output IFM Digital Data Out Figure 2: Radar Warning Receiver Block Diagram Filtronic Components Ltd., Airedale House, Royal London Industrial Estate, Acorn Park, Shipley, West Yorkshire, BD17 7SW, United Kingdom. Tel: +44 (1274) 531602 Fax:+44 (1274) 539724 Email: sales@fcl.com Page 1 of 1 Man Portable Radar Warning Receiver Electrical Specifications Operating temperature range 0C to 70C Characterised at 25C. Table 1: Electrical Specifications Parameter Operating Frequency Operating Dynamic Range Frequency Measurement Resolution Frequency Measurement Accuracy Minimum Pulse Width Triggering Trigger to Data Delay Out of Band Rejection Tangential Signal Sensitivity (8 dB Video SNR) Logging Range Frequency Flatness (Video) Amplitude Tracking (Between any Two Modules at the Same Frequency and Temperature) Video Rise Time Video Output Slope Logging Linearity Video Coupling Maximum Duty Cycle RF Input Switch Isolation RF Input Switch Speed RF Input Switch Control Insertion Gain RF Input to RF Output Insertion Ripple Input Return Loss Power Supply Current (operating - no rf) Power Supply Current (standby) Power-up Time (standby to on) Power-up Time (cold start) Dimensions Weight 2 Microwave Input Connector 1 2 not including amplitude module gain plus 10 grams for the interconnect module Amplitude Module 8 to 18 GHz -73 to 0dBm d.c. to 7 GHz > 60 dB 20 to 26 GHz > 30 dB -73 dBm -70 to -30 dBm 2.5 dB 1 dB Typical 30ns Typ 70 ns Max 50 mV/dB 1 dB Active d.c. restored 50 % >30 dB Typ <5 s TTL 27dB nominal 2dB 7dB min (10dB typ) +6 V at 130 mA -6 V at 50 mA +6 V at 50 mA -6 V at 50 mA <100 s <30ms 4 x 1 x 0.25 inches 101.6 x 25.4 x 6.35 mm 50 grams SSMA Female +6 V at 200 mA -6 V at 30 mA +6 V at 120 mA -6 V at 30 mA <100 s <2ms 4 x 2 x 0.25 inches 101.6 x 50.8 x 6.35 mm 85 grams Dynawave Frequency Module 8 to 18 GHz -43 to -5 dBm 1 150 MHz nom. <200 MHz r.m.s. 100 ns External Command <100 ns max. >30 dB Typ <5 s TTL - Filtronic Components Ltd., Airedale House, Royal London Industrial Estate, Acorn Park, Shipley, West Yorkshire, BD17 7SW, United Kingdom. Tel: +44 (1274) 531602, Fax: +44 (1274) 539724, Email: sales@fcl.com Page 2 of 2 Man Portable Radar Warning Receiver System Timing The operation of the frequency measurement unit is as follows: When r.f. enters the discriminator circuits, the video voltages settle after a delay depending on the video bandwidth. The video signals are then stable and can be digitised by the comparators and ASIC. This digitization takes a maximum of 15 ns (ASIC worst case timing). Therefore valid raw frequency data is available 75 ns after the leading edge of the r.f. pulse. The raw frequency data is decoded in the EPROM look-up table which takes 55 ns. Figure 3: System Timing Diagram r.f. trfhld video out tlatch LATCH tlpw Raw Data tdig tlhold tdecode Frequency Data Out Data Valid tdechold tmeas Table 2: Timing Description time between latch edge and trailing edge of r.f time from leading edge of r.f. and latch edge Width of latch pulse time to digitise video time from latch disable and raw data invalid time to decode raw frequency data time to hold decoded frequency data time from start of r.f. to valid frequency out symbol trfhld tlatch tlpw tdig tlhold tdecode tdechold tmeas min 6 60 5 max units ns ns ns ns ns ns ns ns 15 10 55 7 130 The LATCH signal holds the digitised frequency data when it is in the logic high state. When the LATCH signal is low, the digitising circuits are transparent and the data buses may change state rapidly increasing current consumption, thus to reduce this effect the latch signal should be held high and digitising initiated by a narrow logic low pulse. In order to capture 100 ns pulses the rising edge of the LATCH signal must occur no later than 94 ns after the start of the r.f. pulse. Filtronic Components Ltd., Airedale House, Royal London Industrial Estate, Acorn Park, Shipley, West Yorkshire, BD17 7SW, United Kingdom. Tel: +44 (1274) 531602, Fax: +44 (1274) 539724, Email: sales@fcl.com Page 3 of 3 Man Portable Radar Warning Receiver Application Information The Amplitude Measurement Module and the Frequency Measurement Module are designed to be used together as the front end for a Radar Warning Receiver. The configuration described here has two Amplitude Modules facilitating direction of approach measurement from 4 directional antennae. If desired, only one Amplitude Module can be used in conjunction with an omni directional antenna forming a simple Radar Warning Receiver for simple classification of the threat signal. The unused input ports must be terminated with 50 loads. Both modules feature a power saving standby mode that turns off the bias to the microwave amplifiers. The power supply can be removed completely for better power efficiency but there is a penalty to pay in start-up time as the modules incorporate switch mode DC-DC converters that take time to stabilise. The amplitude module also incorporates a CW removal circuit which can take up to 30ms to stabilise. The frequency measurement module requires an externally generated latch signal to hold the frequency data word on the digital output. This can be derived from the amplitude measurement video output or from some other source. The responsibility for generating the latch rests with the application circuit. Refer to figure 3 for timing information for the latch generation. Options and Future Developments Other configurations may be possible, e.g., SMA connectors instead of SSMA, custom outline, different logging range, etc. In addition Filtronic is developing this product further to provide extended frequency range and a back end control system to integrate the trigger, direction of approach and emitter characterisation functions. Please contact the factory for further details. While every effort is made to ensure the accuracy this release, please check with the factory for the latest information. Filtronic Components Ltd., Airedale House, Royal London Industrial Estate, Acorn Park, Shipley, West Yorkshire, BD17 7SW, United Kingdom. Tel: +44 (1274) 531602, Fax: +44 (1274) 539724, Email: sales@fcl.com Page 4 of 4 Man Portable Radar Warning Receiver Typical Performance Data Figure 4: Log plot at 8 GHz Figure 5: Log plot at 13 GHz Figure 6: Log plot at 18 GHz Figure 7: Frequency Flatness at -50dBm input Figure 8: Cell size distribution - CW Figure 9: Frequency accuracy - CW Figure 10: Cell size distribution - 100ns pulse Figure 11: Frequency accuracy - 100ns pulse Filtronic Components Ltd., Airedale House, Royal London Industrial Estate, Acorn Park, Shipley, West Yorkshire, BD17 7SW, United Kingdom. Tel: +44 (1274) 531602, Fax: +44 (1274) 539724, Email: sales@fcl.com Page 5 of 5 Man Portable Radar Warning Receiver Connector Details The Frequency Measurement Module connector is a 15 way Nanonics(R) Dualobe(R) single row receptacle. The mating part is a 15 way single row plug with wire leads. Example part number: SSM015PC2DC012N Table 4: Frequency Measurement Module Connector Designations Pin 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Type POWER POWER POWER POWER IN TTL OUT TTL OUT TTL OUT TTL OUT TTL OUT TTL OUT TTL IN TTL IN TTL POWER POWER Signal +6V +6V -6V DGND Input Select D0 D1 D2 D3 D4 D5 Trigger Standby (active low) GND GND The Amplitude Measurement Module connector is a 9 way Nanonics(R) Dualobe(R) single row receptacle. The mating part is a 9 way single row plug with wire leads. Example part number: SSM009PC2DC012N Table 5: Amplitude Measurement Module Connector Designations Pin 1 2 3 4 5 6 7 8 9 Type POWER POWER POWER GND IN TTL IN TTL GND OUTPUT GND Signal +6V +6V -6V Power Ground Antenna Select Standby (active low) Digital Ground Video Output Video Ground The mating connectors are available from: Nanonics(R) Corporation Call (623) 581-6188 or Fax (623) 581-8242 21644 North 14th Ave., Phoenix, Arizona 85027-2840 email: info@nanonics.com www.nanonics.com Filtronic Components Ltd., Airedale House, Royal London Industrial Estate, Acorn Park, Shipley, West Yorkshire, BD17 7SW, United Kingdom. Tel: +44 (1274) 531602, Fax: +44 (1274) 539724, Email: sales@fcl.com Page 6 of 6 Man Portable Radar Warning Receiver Figure 12: Outline and fixing details (c) Filtronic Components Ltd - All rights reserved. Unauthorised reproduction prohibited. Man Portable Radar Warning Receiver - rev 1.1 - March 2001 Specifications subject to variation without notice. Check with factory for latest. E&OE Filtronic Components Ltd., Airedale House, Royal London Industrial Estate, Acorn Park, Shipley, West Yorkshire, BD17 7SW, United Kingdom. Tel: +44 (1274) 531602, Fax: +44 (1274) 539724, Email: sales@fcl.com Page 7 of 7 |
Price & Availability of RWR
 |
|
|
|
|
All Rights Reserved © IC-ON-LINE 2003 - 2022 |
| [Add Bookmark] [Contact Us] [Link exchange] [Privacy policy] |
|
Mirror Sites : [www.datasheet.hk]
[www.maxim4u.com] [www.ic-on-line.cn]
[www.ic-on-line.com] [www.ic-on-line.net]
[www.alldatasheet.com.cn]
[www.gdcy.com]
[www.gdcy.net] |