Video:Limit: Difference between revisions

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oscillating with the minus 1 and 1. However,
oscillating within [-1,1]. However
smaller interval you
small an interval you


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the moves of the skeptic be right "for every"
the moves of the skeptic we write "for every"
"for all." Right? And
"for all." Right? And


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0:19:04.260,0:19:07.390
for all the moves of the prover it's "there
for all the moves of the prover we write
exists." Why do we do
"there exists." Why do we do


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Full timed transcript: <toggledisplay>
Full timed transcript: <toggledisplay>
0:00:15.530,0:00:21.640
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Vipul: Okay. So this talk is going to be about
Vipul: Okay. So this talk is going to be about
limit at infinity for
limit at infinity for functions on real numbers


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0:00:24.300,0:00:28.980
functions on real numbers and the concept
and the concept of limits of sequences, how
of limits of sequences, how
these definitions are essentially almost the


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these definitions are essentially almost the
same thing and how they differ.
same thing and how they differ.


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Okay. So let's begin by reviewing the
Okay. So let's begin by reviewing the definition
definition of the limit as x
of the limit as x approaches infinity of f(x).


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approaches infinity of f(x). Or rather what
Or rather what it means for that limit to
it means for that limit to
 
0:00:43.950,0:00:49.050
be a number L. Well, what it means is that
be a number L. Well, what it means is that
for every epsilon greater


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0:00:47.390,0:00:52.699
than zero, so we first say for every neighborhood
for every epsilon greater than zero, so we
of L, small
first say for every neighborhood of L, small


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0:00:52.699,0:00:59.429
neighborhood of L, given by radius epsilon
neighborhood of L, given by radius epsilon
there exists a neighborhood
there exists a neighborhood of infinity which


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0:00:59.429,0:01:03.010
of infinity which is specified by choosing
is specified by choosing some a such that
some a such that that is
that is


0:01:03.010,0:01:08.670
0:01:03.010,0:01:08.670
the interval (a,infinity) ...
the interval (a,infinity) ...


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0:01:08.670,0:01:15.220
... such that for all x in the interval from
... such that for all x in the interval from
a to infinity. That is
a to infinity. That is for all x within the


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for all x within the chosen neighborhood of
chosen neighborhood of infinity, the f(x)
infinity, the f(x) value
value is within the chosen neighborhood of


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is within the chosen neighborhood of L. Okay?
L. Okay?


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If you want to think about it in terms of
If you want to think about it in terms of
the game between the prover
the game between the prover and the skeptic,
 
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and the skeptic, the prover is claiming that
the limit as x approaches


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infinity of f(x) is L. The skeptic begins
the prover is claiming that the limit as x
by picking a neighborhood of
approaches infinity of f(x) is L. The skeptic


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L which is parameterized by its radius epsilon.
begins by picking a neighborhood of L which
The prover picks the
is parameterized by its radius epsilon. The


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0:01:38.930,0:01:41.619
prover picks the
neighborhood of infinity which is parameterized
neighborhood of infinity which is parameterized
by its lower end


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a. Then the skeptic picks a value x between
by its lower end a. Then the skeptic picks
a and infinity. Then they
a value x between a and infinity. Then they


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check whether absolute value f(x) minus L
check whether absolute value f(x) minus L
[symbolically: |f(x) - L|] is
[symbolically: |f(x) - L|] is less than epsilon.
 
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less than epsilon. That is they check whether
f(x) is in the chosen


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neighborhood of L (the neighborhood chosen
That is they check whether f(x) is in the
by the skeptic). If it is,
chosen neighborhood of L (the neighborhood


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chosen by the skeptic). If it is,
then the prover wins. The prover has managed
then the prover wins. The prover has managed
to trap the function: for


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x large enough, the prover has managed to
to trap the function: for x large enough,
trap the function within
the prover has managed to trap the function


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epsilon distance of L. If not, then the skeptic
within epsilon distance of L. If not, then
wins. The statement
the skeptic wins. The statement is true if


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is true if the prover has a winning the strategy
the prover has a winning the strategy for
for the game.
the game.


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Now, there is a similar definition which one
Now, there is a similar definition which one
has for sequences. So,
has for sequences. So, what's a sequence?


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what's a sequence? Well, it's just a function
Well, it's just a function from the natural
from the natural
 
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numbers. And, here, we're talking of sequences
numbers. And, here, we're talking of sequences
of real numbers. So,


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it's a function from the naturals to the reals
of real numbers. So, it's a function from
and we use the same
the naturals to the reals and we use the same


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letter f for a good reason. Usually we write
letter f for a good reason. Usually we write
sequences with
sequences with subscripts, a_n type of thing.


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subscripts, a_n type of thing. But I'm using
But I'm using it as a function just to highlight
it as a function just to
the similarities. So, limit as n approaches


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highlight the similarities. So, limit as n
infinity, n restricted to the natural numbers
approaches infinity, n
... Usually if it's clear we're talking of


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restricted to the natural numbers ... Usually
a sequence, we can remove this part [pointing
if it's clear we're
to the n in N constraint specification] just


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talking of a sequence, we can remove this
say limit n approaches infinity f(n),
part [pointing to the n in N
but since we want to be really clear here,


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constraint specification] just say limit n
approaches infinity f(n),
 
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but since we want to be really clear here,
I have put this line. Okay?
I have put this line. Okay?


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So, this limit equals L means "for every epsilon
So, this limit equals L means "for every epsilon
greater than 0 ..."
greater than 0 ..." So, it starts in the same


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0:03:02.709,0:03:09.170
So, it starts in the same way. The skeptic
way. The skeptic picks a neighborhood of L.
picks a neighborhood of
Then the next line is a little different but


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L. Then the next line is a little different
that's not really the crucial part. The skeptic
but that's not really the
is choosing epsilon. The prover picks n_0,


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0:03:18.799,0:03:22.830
crucial part. The skeptic is choosing epsilon.
a natural number. Now, here the prover is
The prover picks n_0, a
picking a real number. Here the prover is


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natural number. Now, here the prover is picking
picking a natural number. That's not really
a real number. Here
the big issue. You could in fact change this


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0:03:26.700,0:03:33.659
the prover is picking a natural number. That's
line to match. You could interchange these
not really the big
lines. It wouldn't affect either definition.


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issue. You could in fact change this line
to match. You could
 
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interchange these lines. It wouldn't affect
either definition.
 
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The next line is the really important one
The next line is the really important one
which is different. In here
which is different. In here [pointing to real-sense


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[pointing to real-sense limit], the condition
limit], the condition has to be valid for
has to be valid for all
all x, for all real numbers x which are bigger


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x, for all real numbers x which are bigger
than the threshold which the prover has chosen.
than the threshold which
Here on the other hand [pointing to the sequence


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0:03:51.900,0:03:56.970
the prover has chosen. Here on the other hand
limit] the condition has to be valid for all
[pointing to the
natural numbers which are bigger than the


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0:03:56.970,0:04:00.659
sequence limit] the condition has to be valid
threshold the prover has chosen. By the way,
for all natural numbers
 
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which are bigger than the threshold the prover
has chosen. By the way,
 
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some of you may have seen the definition with
some of you may have seen the definition with
an equality sign


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here. It doesn't make a difference to the
an equality sign here. It doesn't make a difference
definition. It does affect
to the definition. It does affect what n_0


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0:04:09.010,0:04:12.019
what n_0 you can choose, it will go up or
you can choose, it will go up or down by one,
down by one, but that's not
but that's not


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0:04:12.019,0:04:17.310
really a big issue. The big issue, the big
really a big issue. The big issue, the big
difference between these
difference between these two definitions is


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0:04:17.310,0:04:23.050
two definitions is that in this definition
that in this definition you are insisting
you are insisting that the
that the condition here is valid for all real


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0:04:23.050,0:04:30.050
condition here is valid for all real x. So,
x. So, you are insisting or rather the game
you are insisting or
is forcing the prover to figure out how to


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0:04:31.650,0:04:36.940
rather the game is forcing the prover to figure
trap the function values for all real x. Whereas
out how to trap the
here, the game is only requiring the prover


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0:04:36.940,0:04:39.639
function values for all real x. Whereas here,
to trap the function values for all large
the game is only
enough


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0:04:39.639,0:04:42.880
requiring the prover to trap the function
values for all large enough
 
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natural numbers. So, here [real-sense limit]
natural numbers. So, here [real-sense limit]
it's all large enough
it's all large enough real numbers. Here [sequence


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0:04:42.880,0:04:49.250
real numbers. Here [sequence limit] it's all
limit] it's all large enough natural numbers.
large enough natural
Okay?
 
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numbers. Okay?


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0:04:49.250,0:04:56.250
So, that's the only difference essentially.
So, that's the only difference essentially.
Now, you can see from the
Now, you can see from the way we have written


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way we have written this that this [real-sense
this that this [real-sense limit] is much
limit] is much
 
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stronger. So, if you do have a function which
stronger. So, if you do have a function which
is defined on real so


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that both of these concepts can be discussed.
is defined on real so that both of these concepts
If it were just a
can be discussed. If it were just a sequence


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0:05:06.880,0:05:10.080
sequence and there were no function to talk
and there were no function to talk about then
about then obviously, we
obviously, we can't even talk about this.


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0:05:10.080,0:05:16.860
can't even talk about this. If there's a function
If there's a function defined on the reals
defined on the reals
 
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or on all large enough reals, then we can
or on all large enough reals, then we can
try taking both of


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these. The existence of this [pointing at
try taking both of these. The existence of
the real-sense limit] and
this [pointing at the real-sense limit] and


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0:05:21.470,0:05:24.580
[said "or", meant "and"] it's being equal
[said "or", meant "and"] it's being equal
to L as much stronger than
to L as much stronger than this [the sequence


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0:05:24.580,0:05:27.250
this [the sequence limit] equal to L. If this
limit] equal to L. If this is equal to L then
is equal to L then
definitely this [the sequence limit] is equal


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0:05:27.250,0:05:29.330
definitely this [the sequence limit] is equal
to L. Okay?
to L. Okay?


0:05:29.330,0:05:31.139
0:05:29.330,0:05:32.080
But maybe there are situations where this
But maybe there are situations where this
[the sequence limit] is
[the sequence limit] is equal to some number


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0:05:32.080,0:05:38.240
equal to some number but this thing [the real-sense
but this thing [the real-sense limit] doesn't
limit] doesn't
 
0:05:35.330,0:05:39.180
exist. So, I want to take one example here.
exist. So, I want to take one example here.
I have written down an


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0:05:38.240,0:05:45.240
example and we can talk a bit about that is
I have written down an example and we can
this. So, here is a
talk a bit about that is this. So, here is


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0:05:45.509,0:05:52.509
function. f(x) = sin(pi x). This is sin (pi
a function. f(x) = sin(pi x). This is sin
x) and the corresponding
(pi x) and the corresponding


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0:05:55.630,0:06:00.530
function if you just restrict [it] to the
function if you just restrict [it] to the
natural numbers is just sin
natural numbers is just sin (pi n). Now, what


0:05:58.930,0:06:04.440
0:06:00.530,0:06:06.759
(pi n). Now, what does sin (pi n) look like
does sin (pi n) look like for a natural number
for a natural number then?
n? In fact for any integer n? pi times


0:06:04.440,0:06:09.810
0:06:06.759,0:06:13.759
In fact for any integer n? pi times n is an
n is an integer multiple of pi. sin of integer
integer multiple of
multiples of pi is zero. Let's make a picture


0:06:09.810,0:06:16.810
0:06:18.370,0:06:25.370
pi. sin of integer multiples of pi is zero.
of sin ...
Let's make a picture of sin ...


0:06:22.830,0:06:27.289
0:06:27.289,0:06:33.360
 
0:06:27.289,0:06:31.800
It's oscillating. Right? Integer multiples
It's oscillating. Right? Integer multiples
of pi are precisely the
of pi are precisely the ones where it's meeting


0:06:31.800,0:06:38.800
0:06:33.360,0:06:40.330
ones where it's meeting the axis. So, in fact
the axis. So, in fact we are concerned about
we are concerned about
 
0:06:39.750,0:06:41.300
the positive one because we are talking of
the positive one because we are talking of
the sequence (natural


0:06:41.300,0:06:45.840
0:06:40.330,0:06:45.840
number [inputs]). Okay? And so, if you are
the sequence (natural number [inputs]). Okay?
looking at this sequence,
And so, if you are looking at this sequence,


0:06:45.840,0:06:50.810
0:06:45.840,0:06:51.090
all the terms here are zero. So, the limit
all the terms here are zero. So, the limit
is also zero. So, this
is also zero. So, this limit [the sequence


0:06:50.810,0:06:53.030
0:06:51.090,0:06:53.030
limit [the sequence limit] is zero.
limit] is zero.


0:06:53.030,0:07:00.030
0:06:53.030,0:07:00.030
Okay. What about this limit? Well, we have
Okay. What about this limit? Well, we have
the picture again. Is it
the picture again. Is it going anywhere? No.
 
0:07:03.110,0:07:07.270
going anywhere? No. It's oscillating between
minus one and one


0:07:07.270,0:07:08.970
0:07:05.349,0:07:07.650
It's oscillating between minus one and one
[symbolically: oscillating in [-1,1]]. It's
[symbolically: oscillating in [-1,1]]. It's
not settling down to any


0:07:08.970,0:07:11.669
0:07:07.650,0:07:11.669
number. It's not... You cannot trap it near
not settling down to any number. It's not...
any particular number
You cannot trap it near any particular number


0:07:11.669,0:07:15.970
0:07:11.669,0:07:17.280
because it's all over the map between minus
because it's all over the map between minus
one and one. For the same
one and one. For the same reason that sin(1/x)
 
0:07:15.970,0:07:19.610
reason that sin(1/x) doesn't approach anything
as x approaches zero,


0:07:19.610,0:07:23.949
0:07:17.280,0:07:22.840
the same reason sin x or sin(pi x) doesn't
doesn't approach anything as x approaches
approach anything as x
zero, the same reason sin x or sin(pi x) doesn't


0:07:23.949,0:07:30.949
0:07:22.840,0:07:29.840
approaches infinity. So, the limit for the
approach anything as x approaches infinity.
real thing, this does not
So, the limit for the real thing, this does


0:07:31.419,0:07:37.370
0:07:31.099,0:07:37.539
exist. So, this gives an example where the
not exist. So, this gives an example where
real thing [the real-sense
the real thing [the real-sense limit] doesn't


0:07:37.370,0:07:41.590
0:07:37.539,0:07:44.539
limit] doesn't exist and the sequence thing
exist and the sequence thing [sequence limit]
[sequence limit] does
does exist and so here is the overall summary.


0:07:41.590,0:07:45.580
0:07:44.690,0:07:46.979
exist and so here is the overall summary.
If the real sense limit,
If the real sense limit,
0:07:45.580,0:07:47.430
that is this one [pointing to definition of
that is this one [pointing to definition of
real sense limit] exists,
0:07:47.430,0:07:51.150
[then] the sequence limit also exists and
they're both equal. On the


0:07:51.150,0:07:53.819
0:07:46.979,0:07:51.039
other hand, you can have a situation with
real sense limit] exists, [then] the sequence
the real sense limit, the
limit also exists and they're both equal.


0:07:53.819,0:07:57.440
0:07:51.039,0:07:54.419
limit for the function of reals doesn't exist
On the other hand, you can have a situation
but the sequence limit
with the real sense limit, the limit for the


0:07:57.440,0:08:00.819
0:07:54.419,0:08:00.819
still exists like this set up. Right?
function of reals doesn't exist but the sequence
limit still exists like this set up. Right?


0:08:00.819,0:08:03.590
0:08:00.819,0:08:05.569
Now, there is a little caveat that I want
Now, there is a little caveat that I want
to add. If the real sense
to add. If the real sense limit doesn't exist


0:08:03.590,0:08:08.729
0:08:05.569,0:08:11.069
limit doesn't exist as a finite number but
as a finite number but it's say plus infinity
it's say plus infinity then
then the sequence limit also has to be plus


0:08:08.729,0:08:12.009
0:08:11.069,0:08:16.150
the sequence limit also has to be plus infinity.
infinity. If the real sense limit is minus
If the real sense
infinity, then the sequence limit also has


0:08:12.009,0:08:16.990
0:08:16.150,0:08:20.330
limit is minus infinity, then the sequence
to be minus infinity. So, this type of situation,
limit also has to be minus
where the real sense limit doesn't exist but


0:08:16.990,0:08:19.740
0:08:20.330,0:08:26.840
infinity. So, this type of situation, where
the sequence exists, well, will happen in
the real sense limit
kind of oscillatory type of situations. Where


0:08:19.740,0:08:24.539
0:08:26.840,0:08:31.409
doesn't exist but the sequence exists, well,
the real sense you have an oscillating thing
will happen in kind of
and in the sequence thing on the other hand


0:08:24.539,0:08:28.169
0:08:31.409,0:08:36.330
oscillatory type of situations. Where the
you somehow manage to pick a bunch of points
real sense you have an
where that oscillation doesn't create a problem.


0:08:28.169,0:08:31.639
0:08:36.330,0:08:36.789
oscillating thing and in the sequence thing
Okay?
on the other hand you


0:08:31.639,0:08:34.570
0:08:36.789,0:08:43.630
somehow manage to pick a bunch of points where
that oscillation
 
0:08:34.570,0:08:36.789
doesn't create a problem. Okay?
 
0:08:36.789,0:08:42.780
Now, why is this important? Well, it's important
Now, why is this important? Well, it's important
because in a lot of
because in a lot of cases when you have to


0:08:42.780,0:08:47.120
0:08:43.630,0:08:50.630
cases when you have to calculate limits of
calculate limits of sequences, you just calculate
sequences, you just
them by doing, essentially, just calculating


0:08:47.120,0:08:54.120
0:08:53.230,0:09:00.230
calculate them by doing, essentially, just
the limits of the function defining the sequence
calculating the limits of the
as a limit of a real valued function. Okay?


0:08:54.640,0:08:59.190
0:09:00.230,0:09:03.460
function defining the sequence as a limit
So, for instance if I ask you what is limit
of a real valued
...
 
0:08:59.190,0:09:03.460
function. Okay? So, for instance if I ask
you what is limit ...


0:09:03.460,0:09:10.460
0:09:03.460,0:09:10.460
Okay. I'll ask you what is limit [as] n approaches
Okay. I'll ask you what is limit [as] n approaches
infinity of n^2(n + 1)/(n^3 + 1)
infinity of n^2(n + 1)/(n^3 + 1) or something
 
0:09:10.510,0:09:17.510
or something like that. Right?
Some rational function.
 
0:09:21.720,0:09:25.980
You just do this calculation as
if you were just doing a


0:09:25.980,0:09:29.430
0:09:15.200,0:09:22.200
limit of a real function, function of real
like that. Right? Some rational function.
numbers, right? The answer
You just do this calculation as if you were


0:09:29.430,0:09:32.100
0:09:25.430,0:09:29.720
you get will be the correct one. If it's a
just doing a limit of a real function, function
finite number it will be
of real numbers, right? The answer you get


0:09:32.100,0:09:35.790
0:09:29.720,0:09:33.060
the same finite number. In this case it will
will be the correct one. If it's a finite
just be one. But any
number it will be the same finite number.


0:09:35.790,0:09:38.840
0:09:33.060,0:09:37.850
In this case it will just be one. But any
rational function, if the answer is finite,
rational function, if the answer is finite,
same answer for the


0:09:38.840,0:09:44.070
0:09:37.850,0:09:44.070
sequence. If it is plus infinity, same answer
same answer for the sequence. If it is plus
for the sequence. If
infinity, same answer for the sequence. If


0:09:44.070,0:09:46.250
0:09:44.070,0:09:46.250
Line 4,830: Line 4,729:
sequence.
sequence.


0:09:46.250,0:09:51.420
0:09:46.250,0:09:53.250
However, if the answer you get for the real-sense
However, if the answer you get for the real-sense
limit is oscillatory
limit is oscillatory type of non existence,
 
0:09:51.420,0:09:57.540
type of non existence, then that's inconclusive
as far as the sequence


0:09:57.540,0:10:00.410
0:09:54.660,0:09:59.410
then that's inconclusive as far as the sequence
is concerned. You actually have to think about
is concerned. You actually have to think about
the sequence case and


0:10:00.410,0:10:05.700
0:09:59.410,0:10:05.520
figure out for yourself what happens to the
the sequence case and figure out for yourself
limit. Okay? If might in
what happens to the limit. Okay? If might


0:10:05.700,0:10:08.040
0:10:05.520,0:10:07.230
in
fact be the case that the sequence limit actually
fact be the case that the sequence limit actually
does exist even


0:10:08.040,0:10:11.380
0:10:07.230,0:10:11.380
though the real sense [limit] is oscillatory.
does exist even though the real sense [limit]
Okay.</toggledisplay>
is oscillatory. Okay.</toggledisplay>


===Real-valued functions of multiple variables case===
===Real-valued functions of multiple variables case===


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Latest revision as of 22:29, 29 August 2013

ORIGINAL FULL PAGE: Limit
STUDY THE TOPIC AT MULTIPLE LEVELS:
ALSO CHECK OUT: Quiz (multiple choice questions to test your understanding) |Page with videos on the topic, both embedded and linked to

The videos below are all taken from certain playlists. Instead of watching the videos on this page, you may prefer to watch the entire playlists on YouTube. Below are the playlist links:

Motivation and general idea

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Definition for finite limit for function of one variable

Two-sided limit

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Left hand limit

Right hand limit

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Relation between the limit notions

Definition of finite limit for function of one variable in terms of a game

Two-sided limit

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Non-existence of limit

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Misconceptions

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Conceptual definition and various cases

Formulation of conceptual definition

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Functions of one variable case

This covers limits at and to infinity.

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Limit of sequence versus real-sense limit

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Real-valued functions of multiple variables case

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