11 Forces and Newton's Laws

11 Forces and Newton's Laws

The construction and use of free-body diagrams are key to approaching problems involving forces.

The net force is determined by the forces acting in the same direction and in opposite directions.

The force is parallel to the surface.

A force is a pull applied by one object to another.

The force in the laboratory can be measured by a spring scale.
AP physics 1 requires us to understand two aspects of forces.

The net force acting on an object has to be connected to the object's change in velocity.

An object can experience a force, but it cannot have a force.

Don't say that Ball A has a bigger force than Ball B.

A free-body diagram is a method of describing forces on an object.

A car that is moving to the right on the freeway applies the brakes to stop.

The Earth's force on the object is known as the object's weight.

"gravity" is an ambiguous term, so don't call it that.
Weight acts downward and doesn't require any contact with the Earth in order to exist.

Chapter 15 explains how to find the weight of an object in a field.

The contact with the car must be the cause of any other forces.

It is touching the ground.
The ground exerts a normal force when the car is touching it.

The ground exerts a force when the car is sliding.

The car skids right along the ground if the force of motion is to the left.
We're done because the car is not in contact with anything else.

All forces must be exerted by an object and all nongravitational and non electrical forces must be a result of contact.

The car isn't in contact with anything that pushes it forward.

There are no questions about what happened before the problem started.

The car might have been pushed by the engine or pulled by a team of donkeys to start moving.
When we watch the action, the car is moving right and slowing down.

The force of the donkeys on the free-body would appear if they pulled the car.

The donkeys might not have existed after they let go of the car.

Don't make up forces.

Unless you can clearly identify the source of the force, don't include it.

It doesn't matter what you label the arrow as long as you define it in a list.

Be my guest.

The force of the ground on the car is listed as the normal force.

Try drawing a free-body diagram for each object in the problem, or for a system with multiple objects.

Even if you aren't asked to make one, a free-body diagram will still be useful.

The net force on an object can be determined by treating each direction differently.

Add forces that point in the same direction and subtract forces that point in opposite directions.

The net force to the surface is zero.

The normal force minus the weight is equal to the net force.

The vertical net force on the car is zero since the car is moving along the surface.

We can conclude that the force on the car is the same as the weight.

The normal force can be different from the weight if more vertical forces are acting.

The second car skids to a stop over a longer distance.

The surfaces in contact have a coefficient of friction.

Since a wet road is less sticky than a dry road, the coefficient of friction has gone down.
The normal force of the surface on the car is the same as before since the second car is identical to the first.

A larger distance to stop is caused by a smaller acceleration.

If the object is moving, use the coefficient of static friction.

If a book sits on a table, it doesn't need to be moved.

The book won't slide if you apply a very small hori zontal pushing force to it.

The weight is the same as the normal force and opposite in direction.

The companion force can be found by looking at the description of the force in the free-body dia gram.

The force of the ground on the car is the normal force.
The force of the car on the ground is the third law companion force.

The magnitude of the net force and the direction of the net force can be determined using the Pythagorean theorem.

Net force will be zero in one or both directions in most AP problems.

Chances are it would ask about the connection between the net force and the object's speed if it were an AP problem.

We will revisit this example later.

A force at an angle is drawn on a free-body diagram.

Break the force into components when you're ready to do an analysis on the free-body diagram.

Sometimes, this is called a third law force pair.

There is a pair of fuzzy dice hanging from your mirror.

You speed up.

The dice have a mass.

It means the force of a string.

The car is not in contact with the dice.

The string is applying the force to the dice.

The net force on these dice is likely to be determined by you.

Break the individual forces into horizontal and vertical components to find the net force.

The weight is already vertical.

You are ready to answer any questions.

You won't get full credit.

All forces should be drawn at whatever angle is appropriate.

I'm stuck to solve for anything because the problem didn't give me an acceleration or tension.

The problem is not likely to besolvable.

You can't ask College Board questions on the AP exam.
If you're absolutely certain that the exam is messed up, you can just state where you think the problem is and do your best.
Chances are you need to find an alternative way to solve the problem.

The dice have a mass of 0.10 kilogram.

The weight of the dice is 1.0 N.7 since they are only moving in a horizontal direction.
The net force is determined by the forces in opposite directions.

That's all that's needed to calculate.

It's tempting to use this equation in a lot of different situations.

I'm sitting in a chair.
The force of the Earth on me is equal to my weight.

I'm in free fall because of the 10 m/s per second value.

I experience more forces than the Earth.

The chair is on me.
The chair pushes up on me because I know my acceleration is zero.

The AP exam doesn't like to ask for calculations.

One kilo of mass weighs 10 N on the Earth.

The best way to answer this type of question is to make the calculation, and then explain what part of the calculation leads to the correct answer.

The method of answering questions that involve qualitative-quantitative translation is discussed in Chapter 8.

If you want a bigger angle, call it 60deg from the vertical.

The weight of the dice is still 1.0 N and the vertical acceleration is still zero, which means we can set the up force equal to the down force.

The answer is that the tension increases.

The weight remains the same and the vertical component of tension must stay the same since a smaller angle from the horizontal gives a bigger tension.

If you are asked if something increases, decreases, or stays the same, you might want to make a calculation to see what happens.

You don't use horizontal and vertical components for the forces.

You don't look at the forces parallel to the incline and the forces parallel to the incline.

As long as the object is moving up or down the incline, the normal force won't have to be broken into components.

It won't have to be broken into components if the force is parallel to the incline.
The force of the Earth will be broken into components.

There are examples of problems and drills in Chapter 18.

We had to measure from the horizontal according to the fact on the previous page.

The easiest way to start is to consider both objects as a single system.

If you need to talk about one of the two connected objects, or if you need to find the tension in the connecting rope, draw a new free-body diagram for that object.

An alternative approach is to draw two diagrams for each object.

The tension and acceleration are the same in each equation.

A car goes up a plane.

Above the horizontal is 30deg.

The normal force must be equal to the car's speed in order for the block to work.

The block would be allowed to slow down.

They are talking about the second law.

The freeway has better gas mileage.

The car is speeding up and slowing down in town.

Unless the rope is connected over a mass, this is not true.

The rope can have different tensions on each side of the pulley if the pulley had mass.
That shouldn't require any calculation because it's a rare occurrence.

The freeway has better gas mileage.

Better gas mileage can only be achieved by the force of the engine.

In town, gas mileage is better.

The speed of the car doesn't have to be accelerated because the town speed is slower than the constant speed.
The acceleration in town is smaller because the force of the engine must be greater than the time.

The 11 m/s per second is here.

If the net force is 8,800 N, the motion is to the right.

When the car changes its speed by 11 m/s, 1cos is less.

The car experiences a greater net force than the block.

It will work here if it's less than a bit over 1.4 N.

Oscar has an answer about how is correct.

The answer is way off.

The driver would fall out of the car.

When an object moves along a surface, it must have zero acceleration.

The net force to the surface is zero.

The amount and direction of the force of object A and object B are the same.

The third law companion forces are the two forces that act on different objects.

If the net force has both a vertical and a horizontal component, the Pythagorean theorem can be used to determine the magnitude of the net force.

One rope has one tension.