Lecture2 1 Chapter 1 Limits and Continuitypioneer.netserv.chula.ac.th/~ksujin/slide02(ISE).pdf ·...
Transcript of Lecture2 1 Chapter 1 Limits and Continuitypioneer.netserv.chula.ac.th/~ksujin/slide02(ISE).pdf ·...
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Chapter 1 Limits and Continuity
Outline 5. Limit Laws 6. Continuity
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5. Limit Laws We had formulated the idea that
using tables or graphs.
The value is called the limit and is denoted
However, we need a quick and precise way to calculate the limits.
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Limit Laws Suppose is a constant, are functions such that
Then
1. (Sum)
2. (Subtraction)
3. (Constant multiplication)
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4. (Product)
5. (Quotient)
provided Remark The limit laws are easily seen to be true. For example, if is close to and is closed to , then is close to . So it is intuitively clear that the sum law is true.
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6. (Power)
where 7. (Root)
where If (even), we assume that .
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8. (Special)
and
where If (even) we assume .
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EX Evaluate the limit
Remark Every polynomial
has the direct substitution property at every , i.e.
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EX Evaluate the limit
Remark Every rational function
has the direct substitution property at every such that , i.e.
provided .
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EX Evaluate the limits
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EX (The limit laws are true for one-sided limits) Evaluate the limits
Remark In (3), the function stays positive as , so the root law is true.
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EX (Do some preliminary algebra) Evaluate the limit
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EX Evaluate the limits
Remark
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EX (Absolute value functions) Evaluate the limit
by simplifying the function
as .
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Remark
For finding a limits with , we can assume and close to . For finding a limit with , we can assume and close to .
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EX Show that the limit
does not exist.
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EX (Rationalization) Evaluate the limit
Remark
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EX Find
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Theorem (Squeeze) If when is close to and
then
Proof
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EX Let be a function such that
for close to . Evaluate the limit
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EX Show that
by verifying that
Remark
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6. Continuity Def A function is continuous at if
I.e. the DSP is true for at .
If is not continuous at , we say that
is discontinuous at .
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To be continuous at , all the
following conditions must be true:
Failing to satisfy at least one of the
above conditions implies that the function is discontinuous at .
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EX Determine whether the function
is continuous at ? Find the set of all points where is continuous.
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EX For the following graph of a function, is the function continuous at ?
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EX Explain why the function is discontinuous at the given number ?
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Def A function is continuous from the right at if
and is continuous from the left at if
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Def is continuous on if is cont. at every . is continuous on if is cont. on and it is cont. from the right at . is continuous on if is cont. on and it is cont. from the left at . is continuous on if is cont. on , is cont. from the right at , and is cont. from the from the left at .
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EX Show that
is continuous on .
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EX Show that
is continuous on .
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Rule 1 Assume and are continuous at . Let be a constant. The following functions are cont. at :
and
Remark The rule is true by the limit laws. For example, since are continuous at , it follows that is close to and is close to . So is close to .
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Rule 2 Functions which are continuous at every number in their domains: 1. Polynomials
2. Rational functions
3. Power functions
4. Root functions
If , the function is continuous on . 5. Trig functions
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EX Find the domain for each of the following functions. Explain why they are continuous on their domains?
(1)
(2) (3)
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EX (Use the continuity to find limits) Evaluate
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Def Let and be functions. Define the function by
is called the composite function of and . It is denoted by
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EX with
with
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Limits of composite functions If has the limit as and is a continuous function, then
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EX Evaluate the limit
where
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Continuity of composite functions If is continuous at and is continuous at , then the composite function is continuous at .
Remark This fact follows directly from the definition. In fact, since is cont. at and is cont. at , we get is close to as and is close to
as . So is close
to . Thus is cont. at .
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EX Where are the following functions continuous?
(a)
(b)