An airplane has a mass of 3.41 × 104 kg and takes off under the influence of a constant net force of 3.58 × 104 N. What is the net force that acts on the plane's 89.0-kg pilot?

F= ma. F= ma

m= 3.41×10^4kg. m= 89kg
F= 3.58 × 10^4N. a =1.05m/s^2
from F= ma. F= 89×1.05
3.58 × 10^ 4= 3.41 × 10^4a. = 93.45N
a= 1.05m/s^2

Mplane = 34100kg

Fnet= 35800N
Mpilot = 89kg
Note: The net force of on the pilot from the plane=0..(Non-inertia). The net force from the ground before takeoff can be calculated below:

Fnet = ma
a = Fnet/Mplane; a = 35800N/34100kg....a =1.05m/s/s.

Fpilot =Mpilot (a); Fpilot = 89kg (1.05m/s/s)= 93.45N.
Therefore, the net force (Fnet) acting on the pilot is 93.45N.

To find the net force acting on the pilot, we will first assume that the mass of the plane and the mass of the pilot are at the same point and therefore experience the same net force.

Given:
Mass of the plane (m1) = 3.41 × 10^4 kg
Net force acting on the plane (F1) = 3.58 × 10^4 N

We are looking for:
Net force acting on the pilot (F2)

Since the plane and pilot are assumed to experience the same net force, we can set up the following equation:

(m1)(a1) = (m2)(a2)

Where:
m1 = mass of the plane
m2 = mass of the pilot
a1 = acceleration of the plane
a2 = acceleration of the pilot

We know that the net force acting on an object is equal to the mass of the object multiplied by its acceleration (F = ma). Therefore, we can rewrite the equation as:

(F1) = (m2)(a2)

Rearranging the equation, we can solve for the net force acting on the pilot:

F2 = (F1) / (m1 / m2)

Substituting the given values:

F2 = (3.58 × 10^4 N) / (3.41 × 10^4 kg / 89.0 kg)

Simplifying the expression, we get:

F2 ≈ 938.06 N

Therefore, the net force acting on the 89.0 kg pilot is approximately 938.06 N.

To find the net force acting on the pilot, we need to use Newton's second law of motion, which states that the net force on an object is equal to the mass of the object multiplied by its acceleration.

In this case, the mass of the pilot is given as 89.0 kg. However, the mass of the airplane is not relevant to finding the net force acting on the pilot. The net force depends on the force applied to the airplane, not its mass.

The given net force acting on the airplane is 3.58 × 10^4 N. This force causes the airplane to accelerate, but to find the acceleration, we need to know the mass of the airplane. Since it is not provided, we cannot calculate the acceleration or the net force acting on the pilot accurately.

If we assume that the mass of the airplane includes the mass of the pilot, we can use this value to estimate the net force acting on the pilot. In this case, the mass of the airplane would be the sum of the pilot's mass (89.0 kg) and the given mass of the airplane (3.41 × 10^4 kg).

Therefore, the total mass would be:

Total Mass = 89.0 kg + 3.41 × 10^4 kg

Once you find the total mass of the airplane, you can use Newton's second law to calculate the net force acting on the pilot:

Net Force = Mass × Acceleration

However, keep in mind that this is an estimation since we are assuming the mass of the airplane includes the pilot's mass.