Answer to Question #164334 in Optics for Iron rose

In this particular case the engine is the observer in motion moving towards the source where the driver hears the echo coming from the tunnel which is our given stationary source. Therefore, we apply the Doppler's effect equation:

When observer is approaching stationary source: "f_o=f_s\\left(\\frac{v+v_o}{v}\\right)"

Where:

"f_o" = Frequency of observer(engine)=400Hz

"f_s" =Frequency of the source(tunnel)=500Hz

"v" =speed of sound in air=340m/s

"v_o" =speed of observer(engine)=?

"400=500\\left(\\frac{340+v_o}{340}\\right)"

"\\frac{400\\times 340}{500}=340+v_o\\:\\:\\:\\:"

"272=340+v_o"

"v_o= 68ms^{-1}"

The negative value of speed is ignored since it has no significance. Therefore,

Speed of the engine"=" "68ms^{-1}"

Distance of the the tunnel from where the driver heard the echo.

We take the formula:"\\:Distance=speed\\:\\times time"

Since the engine was also moving with some speed when the sound was produced to give back an echo we take cumulative speed to be: "speed=(340+68)ms^{-1}"

"Time=2s"

"\\:Distance=\\left(340+68\\right)\\:\\times 2"

"Distance=408\\:\\times 2"

"Distance=816m"