To determine the wind speed, we can use the concept of relative velocity. Let's assume that the wind speed is represented by 'v' km/hr.
When the plane is flying into the headwind, its effective speed (airspeed - wind speed) is reduced. Therefore, the time taken to cover a certain distance increases. On the return journey, the wind is now assisting the plane, so its effective speed (airspeed + wind speed) is increased, resulting in a decrease in travel time.
Let's calculate the distances covered during the two legs of the journey first:
Distance = Speed × Time
For the first leg (against the wind): Distance = 300 km/hr × (48/60) hr Distance = 240 km
For the return leg (with the wind): Distance = 300 km/hr × (42/60) hr Distance = 210 km
Now, using the concept of relative velocity:
When flying against the wind: Effective speed = Airspeed - Wind speed 240 km = (300 km/hr - v km/hr) × (48/60) hr
Simplifying the equation: 240 = (5/6) × (300 - v)
When flying with the wind: Effective speed = Airspeed + Wind speed 210 km = (300 km/hr + v km/hr) × (42/60) hr
Simplifying the equation: 210 = (7/10) × (300 + v)
Now we have a system of two equations:
- 240 = (5/6) × (300 - v)
- 210 = (7/10) × (300 + v)
We can solve this system of equations to find the value of 'v,' which represents the wind speed.
Multiplying both sides of equation 1 by 6/5: 6/5 × 240 = 300 - v 288 = 300 - v v = 300 - 288 v = 12 km/hr
Therefore, the wind speed is 12 km/hr.