Sound Transmission and Echolocation Core Course No ZOOA

Sound Transmission and Echolocation Core Course No. ZOOA – P 2 T, Group-A, Unit: 1, Topic No. 14

Properties of sound Sound is produced by changes in pressure

Frequency and wavelength Wavelength of a sound is the distance traveled in one cycle. Frequency (in cps or Hertz) = 1/period, (f =1/T)

Wavelength depends on media Wavelength depends on the speed of propagation (c) Wavelength = c. T or c/f ◦ Speed of sound in air = 340 m/s, so wavelength of 340 Hz = 1 m ◦ Speed of sound in water = 1450 m/s , wavelength of 340 Hz = 4. 3 m

Wavelength problem Which sound has a shorter wavelength: 1 k. Hz in air or 3 k. Hz in water? Wavelength = speed of sound / frequency Air: 340 m/s / 1000 cycle/s = 0. 34 m/cycle Water: 1500 m/s / 3000 cycle/s = 0. 5 m/cycle Therefore, the answer is 1 k. Hz in air

Source movement When the sound source is moving, the frequency of the sound will be altered. This is known as the Doppler shift Approaching sounds are higher in frequency Departing sounds are lower in frequency

Amplitude measurement Peak, peak-to-peak, RMS (root-meansquared) Sound pressure is measured in decibels (d. B) on a log 10 scale relative to a reference level d. B = 20 log 10 P 1/Pr where Pr is a reference pressure level, usually the threshold of human hearing at 4 k. Hz. This is referred to as sound pressure level (SPL) A sound with twice the SPL is 6 d. B louder (log 10 (2) = 0. 3)

Sample sound pressure levels soft whisper nearby songbird, office hum barking dog roaring lion , heavy truck echolocating bat jet take-off 20 d. B 50 d. B 70 d. B 90 d. B 100 d. B 120 d. B

Amplitude problems If sound A has 10 times the SPL of sound B, how much louder is A than B in d. B? d. B = 20 log 10 10 = 20 d. B louder If sound A is 100 db and sound B is 80 db, how much louder is A than B? 20 db If an 80 db sound is combined with a 40 db sound, how loud is the sound (approximately)? 80 db

Phase shifts Sounds that arrive out of phase cancel each other out (negative interference) Sounds that arrive in phase increase in amplitude (positive interference) Sounds partially out of phase create varying amplitudes (beats)

Harmonic series Harmonic frequencies are integer multiples of the fundamental frequency, i. e. w, 2 w, 3 w, 4 w … Dirichlet’s rule states that the energy in higher harmonics falls off exponentially with the frequency of the harmonic Note, however, that some bats alter the amplitude of harmonics by selective filtering during sound production

Nose leaf and ear diversity

Sound attenuation Spherical spreading Absorption ◦ Temperature and humidity effects Scattering ◦ Reflection, refraction, diffraction

Sound transmission varies with habitat • • Summary AM signals are better in open environments FM signals resist degradation and can be detected in noise Lower frequencies travel farther Tonal signals travel farther

Bat echolocation 60 k. Hz pulse 19 mm target at 3 m

Echolocation call design FM = frequency modulated CF = constant frequency

FM calls during prey capture Big brown bat Eptesicus fuscus Low duty cycle

CF calls during prey capture Greater horseshoe bat, Rhinolophus ferrumequinum High duty cycle

Pulse duration declines with frequency for FM bats Suggests that species that use high frequency must hunt closer to prey and, therefore, need to use shorter calls to avoid pulse-echo overlap

How do bats estimate time delay? Could compare pulse and echo at a single frequency, but echo frequency depends on object size Better to compare pulse and echo at all frequencies and average. This would provide the best estimate of time delay. Can use cross-correlation for this purpose

Cross-correlation function can be used to measure echo delay time in FM bats If bats cannot detect phase, then the correlation function is the envelope

Autocorrelation and bandwidth Narrow band; 1 ms, 25 -20 k. Hz pulse Broad band; 1 ms, 50 -20 k. Hz pulse, should permit better range resolution

Call bandwidth and target ranging

Why produce constant frequency calls? More energy at a single frequency will carry further Target shape change will cause amplitude fluctuations in echoes Movement of target will cause frequency shift of echo due to the Doppler shift Need to overlap pulse and echo to measure frequency shift accurately

CF bats exhibit doppler-shift compensation

Information decoded from echos Range pulse-echo time delay Velocity pulse-echo frequency change Target size frequency of echo Location ear amplitude difference

Range of detection Detection range depends on amplitude at source and frequency If range information is needed, signals should incorporate features that degrade predictably with distance, i. e. wide bandwidth

Signal design parameters Bandwidth Frequency Duration Modulation type and rate

Call design fits foraging strategy

References Sinha A. K. , Adhikari S. , Ganguly B. B. and Goswami B. C. B. (2005). Biology of Animals. 6 th Edition, Volume- II. New Central Book Agency. Sherwood L. , Klandorf H. and Yancey P. H. (2011). Animal Physiology. 2 nd Edition. BROOK/COLE CENGAGE Learning. Agarwal V. K. (2018). Animal Behavior (Ethology). 1 st Edition. S. Chand Higher Academic.