Is There Any Net Force Acting on an Athlete Moving at Constant Velocity?

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An athlete moving at a constant velocity of 5 m/s experiences no net force acting on him, as he is not accelerating. According to Newton's second law, if acceleration is zero, the net force is also zero. While gravitational force acts on the athlete, it is balanced by other forces, resulting in no net force. This means that all forces acting on him must cancel each other out. Therefore, the conclusion is that there is no net force affecting his motion.
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An athlete (mass of 50 kg) is moving with a constant velocity of 5ms. Determine the resultant force acting on him.

If it's a constant velocity he is not acclerating? Therefore a = 0 m/s/s; F=ma F=50 X 0 = 0N?

But there has to be a force dosent there? Would the force be equal to the mass affcted by gravity f=mg = 50 490.5N or is it 0N?
 
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bionut said:
But there has to be a force dosent there?

Why?
 
So if he's moving at a constant velocity --- he's not accerating therefore threre is no force affecting his velocity?
 
bionut said:
So if he's moving at a constant velocity --- he's not accerating therefore threre is no force affecting his velocity?

No NET force, yes. Meaning all the forces that are acting on him (if any) must cancel each other out. That's Newton's second law. No net force means no acceleration.
 
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