91Ó°ÊÓ

In order to determine the acceleration of the elevator, we need to find the difference in the force experienced by Ian. To do this, we will use the formula: \(\Delta F = m \cdot \Delta a\). Since we know the weight of Ian on the ground is \(640 N\), and his apparent weight on the elevator is \(700 N\), the difference in force (\(\Delta F\)) is \(700 - 640 = 60 N\). Now, let's find the mass of Ian. We know that the weight is given by the formula \(W = m \cdot g\), where \(g\) represents the gravitational acceleration (approximately \(9.8 m/s^2\)). We can rearrange this formula to find the mass: \(m = \frac{W}{g}\). Hence, Ian's mass is \(\frac{640}{9.8} \approx 65.31 kg\) Now, we can find the change in acceleration, \(\Delta a\), using the formula \(\Delta F = m \cdot \Delta a\). Rearranging we get \(\Delta a = \frac{\Delta F}{m} = \frac{60}{65.31} \approx 0.92 m/s^2\). Now that we have the acceleration of the elevator, we can move on to the next step.

Now that we have the acceleration of the elevator, we can find the net force on the whole system (Ian and the elevator). The system experiences a net force given by Newton's second law, which states that the net force is equal to the mass of the system multiplied by the acceleration: \(F_{net} = m_{total} \cdot a\). We are given the combined mass of Ian and the elevator as \(1050 kg\), and we calculated the acceleration to be approximately \(0.92 m/s^2\). Therefore, we can find the net force on the system: \(F_{net} = 1050 \cdot 0.92 \approx 966 N\) So, the net force acting on the system (Ian and the elevator) is approximately \(966 N\).