The initial bearing is the direction in which the aircraft begins its journey. It is crucial to understand this as it sets the reference point for any subsequent directional changes.

In this problem, the aircraft departs with an initial bearing of \(\text{N } 40^{\text{∘}} \text{ E} \). This means the plane is heading 40 degrees towards the east from the north. Visualize a compass: starting at the North (0 degrees), we move 40 degrees clockwise to get the initial bearing direction.

Think of a clock: if 12 o'clock is north, then 1:20 would point you to the direction the aircraft initially follows.

In aviation, pilots often need to change directions to follow air traffic control instructions or alter their flight paths.

Here, the aircraft makes a significant change in direction by turning 90 degrees. Understanding the plane's movement after this turn requires knowledge of both the initial bearing and the aviation navigation system.

After the \(90^{\text{∘}}\) turn, the aircraft heads southeast. In standard aviation terms, this is equivalent to \(135^{\text{∘}}\) when measured clockwise from north. Remember, southeast can also be broken down as halfway between south and east, giving us a 45-degree addition to directly south, leading to the final direction.

The final bearing is the direction the plane ends up heading after all turns and adjustments.

In this exercise, after the plane turns 90 degrees from its initial bearing, it heads towards the direction known as \( \text{S } 50^{\text{∘}} \text{ E} \). We achieve this angle by first moving 40 degrees from north to east, then adding an additional 90 degrees. This calculation results in \(50^{\text{∘}}\) south from east, which translates to \( \text{S } 50^{\text{∘}} \text{ E} \).

This final bearing is what the control tower will use to locate the aircraft, ensuring safe and accurate tracking of its position.