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This video is about infinite
sequences and their limits.
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We'll start by revising what a
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simple sequences. You should
have seen that a simple sequence
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is a finite list of numbers,
like this one.
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It could be something
like 135.
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So on up to 19
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say. Another possible
example would be something
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like four 916.
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Perhaps stopping it somewhere
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like 81? The numbers in the
sequence. I called the terms of
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the sequence. So in the second
example here, we would say that
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four is the first term.
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And nine is the second
term.
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And so on.
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An infinite sequence like simple
sequence is a list of numbers.
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But an infinite sequence goes on
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forever. So an infinite sequence
could be something like 258.
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And this time the terms just
keep on going.
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Now, if you see three
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dots. Followed by something that
just means I've left at some of
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the terms, so that will indicate
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a finite sequence. But if you
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see three dots. And nothing
after them that indicates
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the terms go on forever. So
that's an infinite sequence.
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We say two sequences at the same
if all the terms of the same.
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This means that the sequences
must contain the same numbers in
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the same places.
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So if I have an infinite
sequence like 1234 and so on.
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This is not the same
as the sequence that goes
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2143. And so on.
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Because even though the sequence
has the same numbers, the
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numbers aren't falling in the
same place is so these sequences
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are not the same.
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The first 2 sequences are
written here have nice
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obvious rules for getting the
NTH term of the sequence.
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So you get the first term in the
first sequence. You take 1 * 2
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and takeaway one that gives you
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one. To get the second term you
take 2 * 2 to get the four and
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take away one. And this rule
will work for every term of the
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sequence. So we say the NTH
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term. Is 2 N minus one.
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Similarly. The NTH term of
the second sequence here is N
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plus one all squared.
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The infinite sequence here
also has a rule for getting
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the NTH term.
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Here we take the number of the
term multiplied by three and
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take off 1.
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So the NTH term.
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Is 3 N minus one.
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But not all sequences have a
rule for getting the NTH term.
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We can have a sequence that
looks really random like.
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I'd say root 3
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on. Now, there's certainly no
obvious rule for getting the
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NTH term for the sequence, but
it's still a sequence.
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Now let's look at some
notation for sequences.
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A common way to the notice
sequence is to write the NTH
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term in brackets. So for the
finite sequence, the first one
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here. The NTH term
is 2 and minus one.
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So we write that in brackets.
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And we also need to show how
many terms the sequence has.
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So we say the sequence runs from
N equals 1.
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And the last term in the
sequence happens to be the
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10th term, so we put a tent
up here to show that the
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last term is the 10th term.
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Here. For the second sequence.
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The rule is N plus one squared,
so we want that all in brackets.
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And this time the sequence runs
from N equals 1.
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Up to that's the eighth term, so
we put Nate here.
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We denote the infinite sequence
in a similar way.
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Again, we put the NTH term in
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brackets. So that's three N
minus one, all in brackets.
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And again we started the first
time, so that's an equals 1.
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But to show that the
sequence goes on forever, we
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put an Infinity here.
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From now on will
just focus on infinite
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sequences. We're often very
interested in what happens to a
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sequence as N gets large. There
are three particularly
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interesting things will look at.
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We look at first of
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all sequences. That tends
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to Infinity.
Also
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sequences.
Not
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10s. Minus
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Infinity.
And
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finally,
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sequences. That
tends to a real limit.
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First we look at
sequences that tend to
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Infinity. We say a
sequence tends to Infinity.
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If however, large number I
choose, the sequence will
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eventually get bigger than that
number and stay bigger than that
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number. So for plot a graph to
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show you what I mean. You
can see a sequence tending
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to Infinity.
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So what I'll do here is.
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A put the values of N.
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On the X axis.
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And then I'll put the value of
the NTH term of the sequence on
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the Y axis.
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So a sequence that tends
to Infinity looks
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something like this.
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Now the terms here are
getting larger and larger and
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larger, and I've hit the
point from going off the
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page now, but.
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If I could draw a line anywhere
parallel to the X axis.
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Like this one.
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Then for the sequence to tend to
Infinity, we need the terms
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eventually to go above that and
stay above that. It doesn't
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matter how large number I
choose, these terms must go and
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stay above that number for the
sequence to tend to Infinity.
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Here's an example of a sequence
that tends to Infinity.
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Will have the sequence
that's an squared going from
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N equals 1 to Infinity.
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So that starts off going
1, four 916.
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And so on.
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So I can plot a graph of the
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sequence. I won't bother putting
in the valleys friend. I'll just
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plots the values of the terms of
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the sequence. So.
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The sequence. Will look
something like this.
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Now you can see that however
large number I choose, the terms
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of the sequence will definitely
go above and stay above it,
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because this sequence keeps on
increasing and it increases very
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fast. So this sequence
definitely tends to Infinity.
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Now, even if a sequence
sometimes goes down, it can
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still tend to Infinity.
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Sequence that looks a bit
like this.
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Starts of small goes up for
awhile, comes back down and then
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goes up for awhile again.
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Comes down not so far.
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And carries on going up.
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Now this sequence does sometimes
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come down. But it always goes
up again and it would always
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get above any number I choose
and it will always stay above
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that as well. So this sequence
also tends to Infinity, even
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though it decreases sometimes.
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Now here's a sequence that
doesn't tend to Infinity, even
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though it always gets bigger.
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Will start off with
the first time, the
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sequence being 0.
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And then a lot of 100. So this
is a very big scale here.
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But here. Then I'll add on half
of the hundreds or out on 50.
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Aladdin half of 50 which is 25.
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It'll keep adding on half the
previous Mount I did.
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And this sequence.
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Does this kind of thing?
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And The thing is, it never ever
gets above 200.
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So we found a number here that
the sequence doesn't go above
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and stay above, so that must
mean the sequence doesn't tend
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to Infinity. And finally, here's
an example of a sequence that
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doesn't tend to Infinity, even
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though. It gets really,
really big.
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Will start off with the first
time being 0 again, then one,
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then zero, then two, then zero,
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then 3. And so on.
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Now eventually the sequence will
get above any number I choose.
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But it never stays above because
it always goes back to zero, and
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because it doesn't stay above
any number, I choose, the
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sequence doesn't tend to
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Infinity. Now we look at
sequences that tends to
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minus Infinity.
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We say a sequence tends to
minus Infinity If however
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large as negative a number,
I choose the sequence goes
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below it and stays below it.
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So a good example is something
like the sequence minus N cubed.
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From N equals 1 to Infinity.
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I can sketch a graph of this.
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This starts off
at minus one.
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And then falls really rapidly.
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So however low an
umbrella choose.
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The sequence goes below it and
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stays below it. So this sequence
tends to minus Infinity.
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Just cause sequence goes
below any number doesn't mean
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it tends to minus Infinity.
It has to stay below it. So
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a sequence like this.
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Which goes minus 1 + 1 -
2 + 2 and so on.
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Now, even though the terms of
the sequence go below any large
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negative number I choose, they
don't stay below because we
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always get a positive term
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again. So this sequence doesn't
tend to minus Infinity.
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In fact, the sequence doesn't
tend to any limit at all.
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If the sequence tends to
minus Infinity, we write it
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like this. We
write XN Arrow Minus
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Infinity. As end tends
to Infinity or the limit of
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XN. As I intend to
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Infinity. Equals minus Infinity.
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Finally, we'll look at
sequences that tend to
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a real limit.
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We say a sequence tends to a
real limit if there's a number,
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which I'll call L.
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So that's.
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The sequence gets closer and
closer to L and stays very
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close to it, so a sequence
tending to L might look
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something like this.
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Now what I mean by getting
closer and staying close to L is
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however small an interval I
choose around all. So let's say
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I pick this tiny interval.
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The sequence must eventually get
inside that interval and stay
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inside the interval. It doesn't
even matter if the sequence
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doesn't actually ever hit al, so
long as it gets as close as we
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like to. Ellen stays as close as
we like, then that sequence
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tends to L. Here's an
example of a sequence that
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has a real limit.
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Will have the sequence
being one over N for N
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equals 1 to Infinity.
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I'll sketch a graph of this.
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The first time the sequence
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is one. Then it goes 1/2,
then it goes to 3rd in the
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quarter and so on.
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I can see this sequence gets
closer and closer to 0.
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And if I pick any tiny
number, the sequence will
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eventually get that close to
0 and it will stay that
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close 'cause it keeps going
down. So this sequence has a
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real limit and that real
limit is 0.
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Allow autograph of a
sequence that tends to
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real limit 3.
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So
put
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three
here.
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And I'll show you the intervals
I can choose.
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Now I can choose a sequence.
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That sometimes goes away from 3.
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But eventually see it
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gets trapped. And this
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larger interval. Then it gets
trapped in the smaller interval.
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And whatever interval I drew.
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It would eventually get trapped.
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That close to 3.
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So even though this sequence
seems to go all over the place.
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It eventually gets as close
as we like to three and stays
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that close, so this sequence
tends to three.
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But if a sequence tends to
real limit L, we write it
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like this. We say XN
tends to L.
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As an tends to Infinity or
the limit of XN equals L.
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A Zen tends to Infinity.
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If a sequence doesn't tend
to a real limit, we
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say it's divergent.
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So sequences that tend to
Infinity and minus Infinity
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are all divergent.
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But there are some sequences
that don't tend to either plus
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or minus Infinity that are still
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divergent. Here's an example.
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Will have the sequence going
012, one 0 - 1
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- 2 - 1 zero
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and then. Repeating
itself like that.
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And so on.
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Now, this sequence certainly
doesn't get closer and stay
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closer to any real number, so it
doesn't have a real limit.
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But it doesn't go off to plus or
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minus Infinity either. So
this sequence is divergent,
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but doesn't tend to plus or
minus Infinity.
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Now this sequence keeps on
repeating itself will repeat
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itself forever. The sequence
like this is called periodic.
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And periodic sequences are
a good example of divergent
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sequences.
