Transcript AST-SONAR
Mk.VIII 2.85 www.itp101.com NPL Transducer Polar Plot (National Physical Laboratory) Acoustic Systems Trainer – SONAR R&D Platform Main Menu SONAR Signal Analyser(SSA) Doppler SSA Demo…..then click Scattering CW Oscillator CTFM SONAR Passive SONAR Formulae Active SONAR Dev & Underwater Sounds Range Resolution Acoustic Spectrum Transducer BeamWidth AST Console Transducer Beam Plot Installations Acoustic Systems Trainer – SONAR Britannia Royal Naval College : US Naval Academy – Weapons Engineering : Royal Norwegian Navy-SONAR Engineering : Royal Saudi Naval Force – Saudi Arabia : King Fahd Naval Academy – Saudi Arabia : Alenia Marconi Systems – Dundridge College : HMS Daedalus – RN Fleet Air Arm : HMS Collingwood – RN Maritime Warfare School : Britannia Royal Naval College – Dartmouth : University of Plymouth – Underwater Research : Texas A&M University – Marine Engineering : PLPE Kuala Lumpur - Malaysia : Singapore Navy – ASW School Acoustic Systems Trainer – SONAR R&D Platform Royal Navy – Maritime Warfare School – HMS Collingwood Acoustic Systems Trainer – SONAR R&D Platform Alenia Marconi Systems – Dundridge College Acoustic Systems Trainer – SONAR R&D Platform Royal Saudi Navy T.I.N.S Royal Saudi Navy – Technical Institute Naval Studies Acoustic Systems Trainer King Fahd Naval Academy Acoustic Systems Trainer – SONAR R&D Platform TAMUG – Texas A&M University Galveston Main Menu SONAR Signal Analyzer (SSA) SSA Menu Instrument Task Bar Oscilloscope SETUP Spectrum Analyzer Default Text Multi Meters AWG with Burst Transient Recorder Main Menu Acoustic Spectrum Sonic Regions Infra-Sonic Sonic (Audio) 30Hz 18kHz 2kHz Passive Sonar Towed Arrays Long Range Sonar Ultra-Sonic 9kHz 12kHz Active Dipping Search Sonar Sonar 50kHz 200kHz Torpedoes(Attack) AST Minehunting High Definition Oceanographic Sonar A.U.D.I – Acoustic Underwater Development Instrument Main Menu SSA Instrument Task Bar Dual Channel One Shot Memos Cursors Ref Channels Multi Trigger Maths Auto Set-up Configurable Peak-Peak RMS Mean Crest Frequency Maths Auto Freq.. Over 190 days Ref Channels Cursors Scroll Scan Memos Zoom Var Axis Dual Ch. Log Scale Averaging Cursors Windows Memos Harmonic Analyzer Sine Triangle Square DC White Noise Sweep Symmetry Attenuation Instrument Configuration Text Colours Start-up CAL files Duty Cycle Directories Exit Main Menu SSA Menu Oscilloscope Main Menu SSA Menu Multi Meters Main Menu SSA Menu Transient Recorder Main Menu SSA Menu Spectrum Analyzer Main Menu SSA Menu Function Generator AWG + Burst Main Menu SSA Menu SETUP Duty Cycle Colors Active Instruments Default Text Main Menu SSA Menu Doppler The Doppler effect is the frequency shift which occurs when a signal is transmitted from a moving platform towards a receiver, conversely, the transmitter could be stationary and the receiver could be in motion. In the most complex case, both transmitter and receiver could be moving with respect to each other. Whatever the case, there is a resultant change in frequency which can be detected and used to determine the speed and direction of motion. The following set-up is one method to enable the Doppler component to be extracted from a moving target echo. Use the Transient Recorder with the output from the Detector to record the Doppler shift. Main Menu Doppler Movie Observe the Phase change of the Doppler signal when the target changes direction, and the change in Signal Level as the target opens and closes Doppler Notes AUX O/P GAIN <50% TX2 O/P GAIN <50% Detector IN/OUT ? Align Receiver Vary Speed/Direction DC Coupling .04 Secs 1,000 Samples 20V Sensitivity. OUT IN Detector CW Transmitter Receiver Main Menu Range Resolution Movie Observe how both targets are resolved with optimum Pulse Width, and poor target discrimination with increasing PW. Range Resolution Notes Align ‘Grill’ Target Observe Two Echoes Vary PRF/PW SCOPE Reversible TX/RX Grill Target Main Menu Active SONAR Movie Observe the Transducer Ringdown, and the smaller amplitude echoes which appear to ‘follow’ the large target echo. Active SONAR Movie Observe how Pulse Width + Ringdown Time determines the Minimum Range, and the Pulse Repetition Frequency or PRF, sets Maximum Range of the SONAR. Active SONAR Notes Align Small Target Vary Speed/Direction Identify Echoes Vary PRF/PW/TX FREQ SCOPE Reversible TX/RX Target Main Menu Passive SONAR (Pulse) Movie Observe how the Active SONAR transmission, and the Target Echo are detected by the Passive SONAR Hydrophone. Passive SONAR (Pulse) Notes Align TX and Hydrophone Vary TX FREQ See Spectrum Analyzer SCOPE Projector TX Hydrophone RX Main Menu Volume Scattering Notes Align Target Vary Speed/Direction Scatter Salt SCOPE Reversible Tx/Rx Target Main Menu Beam Plot Movie Observe the smaller Sidelobes either side of the Mainlobes. These manual plots are only intended to give an approximation of the transducer’s Beam Pattern. See the NPL Plot on the next screen which was recorded in a very large, acoustically damped tank under ideal conditions. Side Lobes BW = 8º at-3dB Main Lobe National Physical Laboratory Transducer Polar Plot – 192kHz Beam Plot Notes Acoustic Damping AUX O/P GAIN <50% Detector IN/OUT ? Rotate Test Transducer… CW…then CCW DC Coupling .04 Secs 1,000 Samples 20V Sensitivity. OUT IN Detector Rotate Handle Projector Acoustic Damping Test Transducer Main Menu Beam Width Notes Acoustic Damping Observe Spectrum Analyzer Slide Test Transducer… Set 0dB Slide to first –3dB point… Back to 0dB… Slide to second –3dB point Calculate BW SPECTRUM CW Signal Source Acoustic Damping Test Transducer Main Menu Passive SONAR (CW) Notes Observe SCOPE… Slide Hydrophone… Vary TX FREQ Observe SPECTRUM Resonant Frequency? SCOPE Projector TX Hydrophone RX Main Menu Continuous Wave (CW) Oscillator Movie Observe the change in Frequency displayed in the Time Domain on the Oscilloscope. Continuous Wave (CW) Oscillator Movie Observe the change in Fundamental Frequency displayed in the Frequency Domain on the Spectrum Analyzer. Continuous Wave (CW) Oscillator Movie Observe the Fundamental (1st harmonic) and related Harmonics in the Frequency Domain. Continuous Wave (CW) Oscillator Notes Observe SCOPE… Slide Hydrophone… Vary TX FREQ Observe SPECTRUM Resonant Frequency? SCOPE Projector TX Hydrophone RX Main Menu CTFM SONAR Notes •AUX O/P GAIN <50% •TX2 O/P GAIN <20% •Detector IN/OUT ? •Align Target •Vary Range of Target •Select- Preset 1 OUT IN Detector CTFM Tx and Rx Acoustic Damping Main Menu Development Suggested development projects*Underwater communications. Depth finder. Air curtains. Cavitation investigation. Vortex activity. Bottom profiling. CTFM SONAR. Refraction. Signature analysis. Parametric SONAR. Target bearing detection. Tracking MAD – Magnetic Anomaly Detector Shallow Water Back Scattering *Some projects have already been completed. Underwater Sound Analysis Acoustic Systems Trainer-Sonar Add-on Underwater Sound Analysis Features- Sound Library- Low Frequency Hydrophone Torpedo Strike Dolphins Whales Snapping Shrimp Cracking Ice Diesel Engine Cavitation Warship Tug Pump Explosion Sonarbuoy US Navy LFAS Earthquake Sound Card compatible Headphones Roaming Passive Target Spectrogram Software Selectable FFT Points Scroll Plot Spectrum Analyzer Scope Display Underwater Sound Analysis Spectrogram Movie Dolphins Main Menu Formulae Power Gain = 10 log10 Pout decibels Pin Passive SONAR equation SE = (SL-PL) – N - DT Active SONAR equation SE = (SL+TS-2PL) – N - DT Speed of Sound in Sea Water (Wilson) C = 1449+4.6T-0.055T2+0.0003T3+(1.39-0.012T)(S-25)+0.017D Doppler Shift f = + 0.69Hz per knot per kHz f = + 1.33Hz per metre per second per kHz See reference text ‘SONAR FOR PRACTISING ENGINEERS’ Main Menu AST Mk VIII Console SONAR Signal Analyzer PRF TX Frequency Pulse Width Controls Echo Threshold Target Speed Controls General Purpose & AUX Amps Array Beam Steering Power Supply Outputs Main Menu