Secondary Effects of Controls

Easy4 min readPrinciple of Flight (A)
Occasionally Examined

The secondary effects of controls describe how moving one flight control not only produces its intended (primary) effect, but also causes additional, often unintended, aircraft responses. For example, using ailerons to roll the aircraft also induces a yaw in the opposite direction—known as adverse yaw. Understanding these effects is crucial for coordinated and safe flying, especially during manoeuvres and at low speeds where control authority is reduced.

In depth

Explanation

Primary vs Secondary Effects

Each control surface is designed for a primary effect:

  • Ailerons: Roll (longitudinal axis)
  • Elevator: Pitch (lateral axis)
  • Rudder: Yaw (vertical axis)

However, moving a control surface almost always causes at least one secondary effect due to aerodynamic interactions and changes in airflow.

Aileron Secondary Effects

When you deflect the ailerons, the aircraft rolls, but the downward-moving aileron increases lift and drag on that wing. The increased drag causes the nose to yaw in the opposite direction of the roll—this is adverse yaw. Pilots must use coordinated rudder input to counteract this yaw and maintain balanced flight.

Rudder Secondary Effects

Applying rudder primarily yaws the aircraft, but this also causes the outer wing (in the direction of the yaw) to move faster, generating more lift and causing the aircraft to roll in the same direction as the yaw. To keep the wings level during rudder input, opposite aileron may be needed.

Elevator Secondary Effects

Elevator input mainly changes pitch, with negligible secondary effects under normal conditions. However, at high angles of attack or low speeds, elevator-induced pitch changes can alter airflow over the wings and tail, potentially affecting stability and control.

Operational Importance

Secondary effects become more pronounced at low speeds and high angles of attack, where control effectiveness is reduced and larger control inputs are needed. Pilots must anticipate and counteract these effects to avoid uncoordinated flight, especially during take-off, landing, and slow flight.

The essentials

Key Points

Aileron input causes roll and adverse yaw (secondary yaw opposite to roll).
Rudder input causes yaw and a secondary roll in the same direction.
Elevator input mainly affects pitch, with minimal secondary effects.
Secondary effects are more noticeable at low speeds and high angles of attack.
Coordinated use of controls is essential to counteract secondary effects.
Adverse yaw must be balanced with rudder during turns.
Uncoordinated control use can lead to sideslip and loss of control.
Watch out

Common Exam Traps

Confusing primary and secondary effects (e.g., thinking ailerons primarily cause yaw).
Assuming elevator has significant secondary effects in normal flight.
Believing rudder input only causes yaw without any rolling effect.
Overlooking the need for rudder to counteract adverse yaw during roll.
Misinterpreting sideslip as a primary effect of control input rather than a result of uncoordinated flight.
Test yourself

Example Exam Questions

Question 1Easy

What is the secondary effect when ailerons are used to roll the aircraft to the right?

Question 2Easy

Applying right rudder will primarily cause yaw to the right. What is the secondary effect?

Question 3Easy

Which control surface has negligible secondary effects under normal flight conditions?

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