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how do you do ladies and gentlemen and
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boys and girls I am Julia Sumner Miller
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and physics is my business
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and our special business today is
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Newton's second law the second law now
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in an earlier program we discussed the
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first law and I showed you some dramatic
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demonstrations on the first part a body
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at rest and on the second part a body
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moving uniformly wants to do that now we
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come to Newton's second law this is a
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staggering thing in its implications and
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very very difficult really
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but what students of physics learn
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somewhere in their course is that
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Newton's second law says F equals MA and
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indeed that's what it says but that's
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powerful
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and not so easy let us see what Newton
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said for his second law in the Latin
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Utah ciona motors propulsion Allah Messi
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Wiimote RIS e but the Latin is a little
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old-fashioned so if we look at the
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English here it is change of motion is
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proportional to force applied and takes
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place in the direction of the straight
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line in which the force acts so let me
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demonstrate Newton's second law here I
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have two cops a heavy one a massive one
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and a less massive one and they are
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connected with a pseudo spring an array
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of rubber bands which are called elastic
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bands but which incidentally are
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inelastic now they are on wheels so that
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they move rather freely but we learned
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earlier that this one has less inertia
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than this one now when I pull them apart
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and stretch the spring between them the
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same force acts on both and let us see
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if we cannot at once predict what will
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happen if we apply Newton's second law
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to the forces acting on these cars
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clearly the big car will have a little
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acceleration and the little car will
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have a big acceleration that's an
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obvious thing to to speculate on watch
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it I'm going to pull them apart there is
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one in the same force acting on both
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cars and you will observe that the
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smaller one gets going the fastest
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sooner of course and so here is an
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expression mathematically that describes
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this and what can we learn from that
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remark we learn that the accelerations
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are inversely proportional to the masses
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the bigger the mass the less the
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acceleration now this experiment with
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the two cars very important for our
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concern later because we will talk in
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subsequent programs about the energy
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possessed by each car and about the
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momentum possessed by each car and we
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shall learn then that Newton's second
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law has enormous implications for later
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work in physics now more about the
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second law here is a scale on which I
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hang a weight and I don't care what the
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scale reads it reads something we say it
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reads the weight of the body but I
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really don't know what that means
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nor did Newton because as we believed
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gravitational forces the earth pulls on
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this stretches the scale but remember
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even Newton said I offer no hypothesis
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concerning gravitation not do we
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understand it today but anyway this
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scale reads the weight of this so I'm
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going to write Newton's second law
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saying that very fact here it is F
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equals mg where mg is the weight of the
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body now I'm going to accelerate this
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system upward and I want you to see what
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the scale does watch it now the scale
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read more and so I have to add here MA
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in other words the scale reads
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not only the rest mass of the body but
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an additional force which was required
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to accelerate it upward
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let me now start again in the zero
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position the system at rest the scale
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reading the so called weight of the body
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and let me accelerate downward watch it
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the scale reads less and so I write
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minus M a mg minus M a and this tells us
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a wonderful thing because if I work to
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go to the edge of my roof and hold this
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like this and then let go of it here and
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the whole thing fell down toward the
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earth a good question to ask is what
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would the scale read during the falling
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and the answer is obvious since the
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acceleration downward would be that of a
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freely falling body the scale would read
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zero so if I should jump off from my
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tabletop while I am in flight toward the
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earth I way I am weightless I'm
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weightless now this second law bears on
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the first one which I showed in an
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earlier program you remember that I had
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an enormous weight here which on which I
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pull gently with a string and the string
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held it but when I gave the system a
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sudden acceleration upward the string
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cannot endure it and I said then that
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the body wishes to remain at rest I now
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add an additional fact that the string
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must exert a force not only equal to the
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weight of the body but an additional one
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to accelerate it which it may not be
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able to do no it couldn't do it
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now what is the meaning of this for
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other things supposing I had an enormous
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sphere such as I have here a steel
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sphere two inches in diameter and then a
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teeny weensy one and I want to show you
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that I want to show you that in fact
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here I have several of different sizes
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there's one there's one very good now I
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have one
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yeah that is so tiny in fact that I
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can't see it without my glasses that
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shows you how tiny it is and I wonder if
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I get the other debris out of the way
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can the camera get that into one right
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right well it's there
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I assert it is there even though you
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cannot see it
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oh yeah it's awful tiny and what am I
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going to say about it
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supposing I hold these two I won't hold
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the tiny one cos you can't see it
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supposing I hold these two at the same
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horizontal level above the level of the
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earth equally and I let them go they
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fall with the same acceleration proof
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Newton's second law
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proof F equals MA is the generic
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expression for Newton's second law now
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what is the F acting on this body the F
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acting on that body is its weight and
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when I let it go what is its
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acceleration it has a certain Assam its
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acceleration is G so these two equations
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you see this the generic one F equals MA
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all over the universe so we think and W
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equals mg for earth-dwelling creatures
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who wish to look at the weight of a body
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so you can see that if I double the mass
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of anybody I would once double its
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weight and its acceleration remains
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unaltered which is a sort of explanation
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why all bodies have the same freefall
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acceleration as Galileo showed in the
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17th century now this is quite
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remarkable because one is led to think
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why I can't believe that this one will
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not fall faster than this one and this
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subject is taken up very excellently by
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Galileo in his dialogues concerning two
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Sciences where I urge you to read the
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discussion between segredo and Salvati
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and simply keo now there are some
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further implications of the second law
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which
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have some levity I like physics in
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cartoons and here is a cartoon that I
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recently saw here is a little boy and
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there is a bathroom scale and here is
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another little boy and they way by all
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looks of things about 70 pounds now it's
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obvious what has happened this one jumps
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down onto the scale and what is the
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caption under the picture Wow he says
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Wow
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a hundred and forty you can see that
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this is Newton's second law F equals mg
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plus MA because of the force delivered
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through his acceleration to the scale
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and I think that's terrific
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let's consider another such problem here
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is a smooth pulley fix a - a solid beam
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up there and here is a rope over the
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pulley and here one man stands holding
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the rope and here an identical weighted
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man stands holding this rope and they
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are both on the ground question the man
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a climbs the rope B just holds on he
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just stays there question what happens
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to be answer B gets a free ride for
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whatever a does is felt by the rope and
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in turn by the man and so this is really
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Newton's second law
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two men on a pulley now a more dramatic
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event much more dramatic here is a scale
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which reads from 0 to 2,000 grams and I
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put a thousand on it and clearly the
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scale reads a thousand if I put two
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thousand on it at rest remember at rest
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the scale reads two thousand now what am
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I going to do I am going to put the
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scale on a horizontal plane on that
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board in such a fashion with a pulley
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here and a rope and a pulley
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here and a rope and I'm going to put a
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thousand there and a thousand right
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there so that I have a thousand pulling
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to the right and a thousand pulling to
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the left I'm going to do that right now
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there's a thousand on the right and I've
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got to hold that now I get over here and
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I put a thousand on the left and then I
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cover it over as I like to say for my
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students so that evil eyes do not see it
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and remember now we asked the classic
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question
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hmm when I had a thousand on the scale
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in the vertical line it read a thousand
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when I put two thousand on it in a
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vertical line that read two thousand we
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want to know what does the scale now
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read thousand pulling to the right
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thousand pulling to left several answers
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one all says somebody it reads zero
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since the forces are null each other
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no no says somebody else a thousand to
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the right a thousand left and reach two
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thousand and I must tell you that
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whatsoever your point of view these are
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both wrong so I could leave it as an
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exercise for you to do but since I have
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a kind heart I will tell you that the
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scale reads 1,000 grams but having told
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you this I urge you very seriously to
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explore why that is so one further
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little comment oh I want you to see
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another picture of Newton I showed an
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earlier photograph in his later years
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and here is one as a young man 17 years
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old when he entered Trinity College in
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Cambridge a genius the light of which
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the human race has not yet again seen
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one last experiment Newton's second law
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here I am going into an elevator on the
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ground floor the push of the floor of
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the elevator when at rest is my weight
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plus the weight of the bag now the
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elevator accelerates upward you know
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what happens your knees buckle and the
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load is pulled out of your hand no no no
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not pulled it wanted to stay at rest it
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wasn't rest and that's what
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tried to do but what is the explanation
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of the added tension in my arm and the
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bending of my knees answer f equals mg
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plus MA now the elevators on an
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uppermost floor and starts down you know
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what happens your belly feels empty f
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equals mg minus MA and so we have a
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better understanding of the laws that
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envelop us by applying the laws of
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Newton and I thank you for your
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attention
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you
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you
