Brian-M,
There is no simple pushing and pulling. Change the people to a stream of small table-tennis balls.
OK, so you want to abandon the simple analogy that illustrates the point perfectly in favour of a much more complicated one?
Do you think that there will always be a "gap" in front of you, or that that some of the balls to the left and right will not get knocked into your path?
The balls from behind, do not "push" you. They momentarily strike you, and bounce off, transferring some of their momentum to you. (They now lose momentum, which they must pick up from somewhere else.)
If they momentarily strike you, transferring some of their momentum to you, then they have pushed you. If a ball in front to you is going slower than you it will do the same, pushing you back. I'm using 'push' instead of 'transfer of momentum from collision' for simplicity.
Note: The momentum which they must pick up from somewhere else comes from the other balls/air molecules. When you use a sail to accelerate in the wind, you are
slowing down the wind, by a very, very, tiny amount.
You will be accelerated, little by little, and therefore must pass by others, but some will be much slower than you, (having lost almost all their momentum, in a previous collision) and you will lose some of yours if you hit them. Collision are not "equivalant" or you would not make progress at all.
Assuming this is random action...
If you are travelling in the same average direction the sideways collisions will cancel out exactly, with the same result as if there were no sideways collisions.
When you travelling at average velocity, all collisions will average out exactly, giving the same result as if there were no collisions.
When you are travelling at below average velocity, the collisions from behind will exceed the collisions from ahead, pushing you forward.
It requires
no energy to travel at windspeed. A bubble or balloon can do it with ease. It always requires energy to travel at
less than windspeed. If you are simply standing on the ground, you are using the earth's kinetic energy to travel at less than windspeed,
reducing the earth's kinetic energy, relative to the wind.
If you want to see what I mean, take a look at something that describes the movement of electron through a conductor. The electron stream has an average velocity, but individual particles (charges) may take a longer path, or move backwards. They rattle through the wire as if in a pinball machine. This causes heat to be generated, through the wires "resistance".
You haven't got a clue what you're talking about. The heat from electrical current is caused by the energy exerted in order to pass through the material. Collisions from electrons bouncing off each-other do not produce waste energy. Electrons still do all this when passing through a superconducter, but no heat is generated because no energy is required to pass through the material.
I meant not on a treadmill, but in reality, assuming the person to be a simple mass?
Ok, if you don't want a treadmill, to set asside the differences in the relative velocity of the ground, we'll assume the person doesn't hit the ground, but remains stuck on the bonnet of the car.
Ok, let's say the person is on a skateboard and hits a car (or is hit by a car) at 60mph.
If a skateboarder is travelling at 60 mph and hits a stationary car, he is decellerated by 60 mph.
If a skateboarder is stationary, and is hit by a car travelling 60 mph, he is acellerated backwards to 60 mph.
Decellerating 60 mph is
exactly the same thing as acellerating backwards to 60 mph.
The formula for kinetic energy is: E=1/2M(V^2)
In both cases the change of velocity is the same, and the velocity is the same (and the injuries are the same). The kinetic energy transferred is exactly the same in both cases.
There is no difference.
