1. Driving force with no damping. When damping is not present a huge vibration known as resonance ocurs when the frequency of the disturbing force equals the natural frequency of vibration. As the amplitude is huge we can predict that the amplitude of oscillation must be inversely proportional to the difference in the frequencies. When f - F approaches zero A approaches infinity. A mathematical solution of the differential equation describing the system without damping gives A = 1/(f²-F²). How can a catastrophic vibration be avoided when f = F? Including a damping term in the equations removes some energy from the system allowing it to be unavailable to participate in a large vibration.

2. Driving force with damping. When a damping term is present the differential equation describing the system contains an additional term 2kv, where k is the damping coefficient and v is the velocity of the mass. The solution for A with damping is A = 1/√((f²-F²)²+ 4k²f² ). Notice the additional term in the denominator. When f = F we have A = 1/(4k²f²) giving a finite amount of vibration when f = F. Catastrophe is avoided! Let us examine the equation

   A = 1/√( (f²-F²)²+ 4k²f² )

If we plot A versus f we obtain the graph shown on the 2015 examination paper. By differentiating A with respect to f we find that A has a maximum value of A₀ when f has the value f₀

f₀ = √( F²-2k² )

A₀ =1/( 2k √(F²-k²) )

To answer the question, as k increases A₀ decreases and f₀ decreases so alternative B is the correct answer.