Answer:
a) Ym = 3.29 mm
b) ∅_R=85.5°=1.5 rad
c) If a third wave is also to be sent along the string in the same direction as
the first two waves,then its phase angle must be in same as the resultant
of the first 2 to maximise the amplitude.
Step-by-step explanation:
Givens:
Ym_1= 4.6 mm
Ym_2 = 5.6 min,
∅_1 = 0
∅_2 = 0.8 π
Remark:
remember the cosine ans sin rule we will use them as follows in cases of 2 waves only
Ym^2=Ym_1^2+Ym_2^2-2*Ym_1*Ym_2*cos(π-∅_2)
sin(π-∅)/Ym=sin(∅_R)/Ym_2
So by substitution in both rules we got
Part(a)
Ym^2= 4.62^2 + 5.62^2 -2 x 5.6 x 4.6 cos(π—∅_2) = 10.83 mm
Ym = 3.29 mm
part (b)
sin(π-0.8 π)/3.29=sin(∅_R)/5.6
Solving for ∅_R we have
∅_R=5.6*0.587/3.29
∅_R=85.5°=1.5 rad
Part(c)
If a third wave is also to be sent along the string in the same direction as the first two waves,then its phase angle must be in same as the resultant of the first 2 to maximize the amplitude.