ConcealedDreamer said:
If I drop 2 of the same object but different mass like a pocket book and a encylopedia, they drop at the same time. Why is that? Anyone can get a detailed explanation?
It's because the force that's pulling down on your objects is the gravitational force:
F=\frac{GM_em}{r^2}
That's Newton's Law of Gravity, where G is the gravitational constant, M
e is the mass of the earth, m is the mass of your pocketbook (or encyclopedia), and r is its distance from the center of the earth. What else do we know about forces? Well, Newton's Second Law of Motion says:
a=\frac{F}{m}
That is, an object's acceleration is equal to the force acting on it divided by its mass. I just said that the force acting on it was gravity, so that gives us
a=\frac{GM_em}{r^2m}=\frac{GM_e}{r^2}
This tells us that the acceleration an object experiences from gravity is equal to the gravitational constant times the mass of the Earth divided by its distance from the center squared. If your objects are accelerating at the same rate, it means this number is the same for both of them, and if you take a look, you'll see why that is. The gravitational constant is universal, so it won't vary from object to object. The mass of the Earth certainly doesn't depend on the object being used.
Now, you might say that the two objects have a slightly different distance from the center (and it's certainly possible that they do), but remember that we're
very far from the Earth's center. That is, the average distance to the Earth's center from the surface is around 6,380,000 meters, while the two books you're holding up probably won't have a difference in distance from the center that's more than a few centimeters. Thus, r=R
e, the radius of the earth, and their accelerations will be the same, for all intents and purposes. It's because this number is roughly constant on the Earth's surface that we talk about another constant, g:
g=\frac{GM_e}{R_e^2} \simeq 9.8 \thinspace\thinspace m/s^2
This is the acceleration you'd expect your books to have.
So, you may ask, why doesn't a feather hit the ground at the same time? The answer to this question is a bit more complicated and it has to do with "air resistance". It turns out that all falling objects experience a slight upward force from the air molecules that they're falling through, but you don't notice it unless you object has a high surface area and low mass (as with a feather). It's for this reason that your books wouldn't hit the ground at
exactly the same time, but the difference would be hard to measure without decent equipment.
I remember,sorry for the imprecision. 
It's the first thing taught in a classical mechanics course when introducing Newton's gravity theory...
