Answer:
[tex]\frac{ 112.5}{15+m_{A}}=v_{f}[/tex]
(we need the mass of the astronaut A)
Explanation:
We can solve this by using the conservation law of the linear momentum P. First we need to represent every mass as a particle. Also we can simplify this system of particles by considering only the astronaut A with an initial speed [tex]v_{iA}[/tex] of 0 m/s and a mass [tex]m_{A}[/tex] and the IMAX camera with an initial speed [tex]v_{ic}[/tex] of 7.5 m/s and a mass [tex]m_{c}[/tex] of 15.0 kg.
The law of conservation says that the linear momentum P (the sum of the products between all masses and its speeds) is constant in time. The equation for this is:
[tex]P_{i}=p_{ic}+p_{iA}\\P_{i}=m_{c}v_{ic}+m_{A} v_{iA}\\P_{i}=15*7.5 + m_{A}*0\\P_{i}=112.5 \frac{kg.m}{s}[/tex]
By the law of conservation we know that [tex]P_{i} =P_{f}[/tex]
For [tex]P_{f}[/tex] (final linear momentum) we need to treat the collision as a plastic one (the two particles stick together after the encounter).
So:
[tex]P_{i} =P_{f}=112.5\\[/tex]
[tex]112.5=(m_{c}+m_{A})v_{f}\\\frac{ 112.5}{m_{c}+m_{A}}=v_{f}\\\frac{ 112.5}{15+m_{A}}=v_{f}[/tex]
