First we need to find the speed of the dolphin sound wave in the water. We can use the following relationship between frequency and wavelength of a wave:
[tex]v=\lambda f[/tex]
where
v is the wave speed
[tex]\lambda[/tex] its wavelength
f its frequency
UsingĀ [tex]\lambda = 2 cm = 0.02 m[/tex] andĀ [tex]f=22 kHz = 22000 Hz[/tex], we get
[tex]v=(0.02 m)(22000 Hz)=440 m/s[/tex]
We know that the dolphin sound wave takes t=0.42 s to travel to the tuna and back to the dolphin. If we call L the distance between the tuna and the dolphin, the sound wave covers a distance of S=2 L in a time t=0.42 s, so we can write the basic relationship between space, time and velocity for a uniform motion as:
[tex]v= \frac{S}{t}= \frac{2L}{t} [/tex]
and since we know both v and t, we can find the distance L between the dolphin and the tuna:
[tex]L= \frac{vt}{2}= \frac{(440 m/s)(0.42 s)}{2}=92.4 m [/tex]
