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Transmission Loss

Transmission Loss. Review of Passive Sonar Equation. L S/N = L S - L N > DT. Terminology. Signal to Noise Detection Threshold ( DT ). The ratio of received echo from target to background noise produced by everything else.

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Transmission Loss

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  1. Transmission Loss Review of Passive Sonar Equation

  2. LS/N= LS - LN> DT Terminology • Signal to Noise • Detection Threshold (DT) The ratio of received echo from target to background noise produced by everything else. The measure of return signal required for an operator using installed equipment to detect a target 50% of the time.

  3. Terminology • Source Level (SL) • For ACTIVE sonar operations: • The SONAR’s sonic transmission (transducer generated) • For PASSIVE sonar operations: • Noise generated by target • Noise Level (NL = NLs  NLA) • Self (NLs) • Generated by own ship at the frequency of interest. • Ambient (NLA) • Shipping (Ocean Traffic), Wind and Weather - Sea State (Hydrodynamic) • Biologic and Seismic obtained from other methods

  4. Terminology • Directivity Index (DI) • Receiver directional sensitivity. • LN = NL - DI • Transmission Loss (TL) • Amount the Source Level is reduced due to spreading and attenuation (absorption, scattering).

  5. Passive SONAR Equation(Signal Radiated by the Target) • SNR required for detection = DT • To achieve detection > 50% of the time… • SNR > DT • LS – LN > DT • LS = SL – TL (one way) • LN = NL – DI • Remember NL = NLs NLa • Therefore… LS/N=SL - TL – (NL – DI) > DT

  6. Passive Sonar Equation LS/N=SL - TL – (NL – DI) > DT

  7. The Passive Sonar Equation

  8. Making the Sonar Equations Useful Passive Example Known Can Measure Function of Equipment Can Measure Experimentally SL - TL - NL + DI > DT ONLY UNKNOWN

  9. Figure of Merit • Often a detection threshold is established such that a trained operator should be able to detect targets with that LS/N half of the time he hears them. Called “Recognition Differential.” (RD) • Passive sonar equation is then solved for TL allowable at that threshold. Called “Figure of Merit.” (FOM) TLallowable = Figure of Merit = SL- LS/NThreshold - (NL-DI) • Since TL logically depends on range, this could provide an estimate of range at which a target is likely to be detected. Called “Range of the Day.” (ROD) • Any LS/N above the Recognition Differential is termed “Signal Excess.” (SE) Signal Excess allows detection of targets beyond the Range of the Day.

  10. Range ??? • FOM helps to predict RANGE. • The higher the FOM, the higher the signal loss that can be suffered and, therefore, the greater the expected detection range. • Probability of Detection • Passive • If FOM > TL then > 50% prob det • If FOM < TL then < 50% prob det • Use Daily Transmission Loss (Prop Loss/FOM) curve provided by Sonar Technicians

  11. HW Example • A submarine is conducting a passive barrier patrol against a transiting enemy submarine. The friendly sub has a directivity index of 15 dB and a detection threshold of 8 dB. The enemy sub has a source of 140 dB. Environmental conditions are such that the transmission loss is 60 dB and the equivalent isotropic noise level is 65 dB. • What is the received signal level? • What is the signal to noise ratio in dB? • What is the figure of merit? • Can the sub be detected? Why?

  12. Prop Loss Curve Max Range DP Max Range BB FOM = 70 dB

  13. Prop Loss Curve Max Range DP Max Range CZ FOM = 82 dB

  14. Transmission Loss • Sound energy in water suffers two types of losses: • Spreading • Attenuation Combination of these 2 losses: TRANSMISSION LOSS (TL)

  15. Spherical component Spreading • Spreading • Due to divergence • No loss of energy • Sound spread over wide area • Two types: • Spherical • Short Range: ro < 1000 m • Cylindrical • Long Range: ro> 1000 m

  16. r1 r2 r3 Spherical Spreading

  17. Cylindrical Spreading cylindrical spherical r5 r4 Can be approximated as the sides of a cylinder with a surface area of 2r5H H r1 r2 r3 r4 r5 ro transition range

  18. Spherical to Cylindrical Transition Range in a Mixed Layer

  19. Attenuation • 2 Types • Absorption • Process of converting acoustic energy into heat. • Viscosity • Change in Molecular Structure • Heat Conduction • Increases with higher frequency. • Scattering and Reverberation • All components lumped into Transmission Loss Anomaly (A). • Components: • Volume: Marine life, bubbles, etc. • Surface: Function of wind speed. • Bottom Loss. • Not a problem in deep water. • Significant problem in shallow water; combined with refraction and absorption into bottom.

  20. Absorption • Decrease in intensity, proportional to: • Intensity • Distance the wave travels • Constant of Proportionality, a

  21. Absorption Coefficient Has units of dB/yard a Has units of dB/kiloyard

  22. Example • Spherical Spreading • Absorption coefficient, a = 2.5 dB/kyd • Find the TL from a source to 10,000 yards • Find the TL from 10,000 yards to 20,000 yards

  23. General Form of the Absorption Coefficient fr = relaxation frequency. It is the reciprocal of the relaxation time. This is the time for a pressure shifted equilibrium to return to 1/e of the final position when pressure is released f = frequency of the sound When f << fr,

  24. Estimating Absorption Coefficient • Viscosity – Classical Absorption - Stokes Shear and volume viscosity For seawater, dB/m, f in kHz

  25. Chemical Equilibrium Magnesium Sulfate: f in kHz Boric Acid: f in kHz

  26. Scattering • Scattering from inhomogeneities in seawater • Other scattering from other sources must be independently estimated All lumped together as Transmission Loss Anomaly

  27. Attenuation Summary Note that below 10000Hz, attenuation coefficient is extremely small and can be neglected,

  28. Transmission Loss Equations TL = 10 log R + 30 + a R + A Range  1000 meters Transmission Loss Anomaly Absorption Cylindrical Spreading TL = 20 log R + a R + A Range < 1000 meters Spherical Spreading Absorption TLA

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