Download - Lesson 11: Limits and Continuity
Section 11.2
Limits and Continuity
Math 21a
February 29, 2008
Announcements
I Problem Sessions: Mon, 8:30; Thur, 7:30; SC 103b
I Office hours Tuesday, Wednesday 2–4pm SC 323
I Midterm I Review Session 3/5, 6–7:30pm in SC Hall D
I Midterm I, 3/11, 7–9pm in SC Hall D
Image: kaet44
Outline
Introduction and definition
Rules of limits
ComplicationsShowing a limit doesn’t existShowing a limit does exist
Continuity
Worksheet
Where we’re going: derivatives of multivariable functions
Recall that if f is a function that takes real numbers to realnumbers,
f ′(x) = limh→0
f (x + h)− f (x)
h
We want to do the same thing in more than one variable. So weneed to take limits in more than one dimension.
Where we’re going: derivatives of multivariable functions
Recall that if f is a function that takes real numbers to realnumbers,
f ′(x) = limh→0
f (x + h)− f (x)
h
We want to do the same thing in more than one variable. So weneed to take limits in more than one dimension.
DefinitionWe write
lim(x ,y)→(a,b)
f (x , y) = L
and we say that the limit of f (x , y) as (x , y) approaches (a, b) isL if we can make the values of f (x , y) as close to L as we like bytaking the point (x , y) to be sufficiently close to (a, b).
easy limits
I lim(x ,y)→(a,b)
x = a
I lim(x ,y)→(a,b)
y = b
I lim(x ,y)→(a,b)
c = c
Outline
Introduction and definition
Rules of limits
ComplicationsShowing a limit doesn’t existShowing a limit does exist
Continuity
Worksheet
Like regular limits, limits of multivariable functions can be
I added
I subtracted
I multiplied
I composed
I divided, provided the limit of the denominator is not zero.
Limit of a Polynomial
Example
Find lim(x ,y)→(5,−2)
(x5 + 4x3y − 5xy2)
Solution
lim(x ,y)→(5,−2)
(x5 + 4x3y − 5xy2) = (5)5 + 4(5)3(−2)− 5(5)(−2)2
= 3125 + 4(125)(−2)− 5(5)(4)
= 2025.
Limit of a Polynomial
Example
Find lim(x ,y)→(5,−2)
(x5 + 4x3y − 5xy2)
Solution
lim(x ,y)→(5,−2)
(x5 + 4x3y − 5xy2) = (5)5 + 4(5)3(−2)− 5(5)(−2)2
= 3125 + 4(125)(−2)− 5(5)(4)
= 2025.
Limit of a Rational Expression
Example
Compute
lim(x ,y)→(1,2)
x2
x2 + y2.
Solution
lim(x ,y)→(1,2)
x2
x2 + y2=
(1)2
(1)2 + (2)2
=1
5
Limit of a Rational Expression
Example
Compute
lim(x ,y)→(1,2)
x2
x2 + y2.
Solution
lim(x ,y)→(1,2)
x2
x2 + y2=
(1)2
(1)2 + (2)2
=1
5
Outline
Introduction and definition
Rules of limits
ComplicationsShowing a limit doesn’t existShowing a limit does exist
Continuity
Worksheet
The only real problem is a limit where the denominator goes tozero.
I If the numerator goes to some number and the denominatorgoes to zero then the quotient cannot have a limit.
I If on the other hand the numerator and denominator both goto zero we have no clue. Most “interesting” limits come fromthis. e.g.,
f ′(x) = limh→0
f (x + h)− f (x)
h
The only real problem is a limit where the denominator goes tozero.
I If the numerator goes to some number and the denominatorgoes to zero then the quotient cannot have a limit.
I If on the other hand the numerator and denominator both goto zero we have no clue. Most “interesting” limits come fromthis. e.g.,
f ′(x) = limh→0
f (x + h)− f (x)
h
You probably remember this statement:
FactFor a function f (x) of one variable,
limx→a
f (x) = L ⇐⇒ limx→a+
f (x) = L and limx→a−
f (x) = L
For functions of two variables, “left-hand limits” and “right-handlimits” aren’t enough.
You probably remember this statement:
FactFor a function f (x) of one variable,
limx→a
f (x) = L ⇐⇒ limx→a+
f (x) = L and limx→a−
f (x) = L
For functions of two variables, “left-hand limits” and “right-handlimits” aren’t enough.
Showing a limit doesn’t exist
TheoremSuppose lim
(x ,y)→(a,b)f (x , y) = L. Then the limit of f as
(x , y)→ (a, b) is L along all paths through (a, b).
There are two contrapositives to this statement:
I If there is a path through (a, b) along which the limit does notexist, the two-dimensional limit does not exist
I If there are two paths through (a, b) along which the limitsexist but disagree, the two-dimensional limit does not exist
Showing a limit doesn’t exist
TheoremSuppose lim
(x ,y)→(a,b)f (x , y) = L. Then the limit of f as
(x , y)→ (a, b) is L along all paths through (a, b).
There are two contrapositives to this statement:
I If there is a path through (a, b) along which the limit does notexist, the two-dimensional limit does not exist
I If there are two paths through (a, b) along which the limitsexist but disagree, the two-dimensional limit does not exist
Showing a limit doesn’t exist
TheoremSuppose lim
(x ,y)→(a,b)f (x , y) = L. Then the limit of f as
(x , y)→ (a, b) is L along all paths through (a, b).
There are two contrapositives to this statement:
I If there is a path through (a, b) along which the limit does notexist, the two-dimensional limit does not exist
I If there are two paths through (a, b) along which the limitsexist but disagree, the two-dimensional limit does not exist
Showing a limit doesn’t exist
TheoremSuppose lim
(x ,y)→(a,b)f (x , y) = L. Then the limit of f as
(x , y)→ (a, b) is L along all paths through (a, b).
There are two contrapositives to this statement:
I If there is a path through (a, b) along which the limit does notexist, the two-dimensional limit does not exist
I If there are two paths through (a, b) along which the limitsexist but disagree, the two-dimensional limit does not exist
Example
Show lim(x ,y)→(0,0)
x
x2 + y2does not exist.
SolutionFollow a path towards (0, 0) along the line y = 0.
limx→0
f (x , 0) = limx→0
x
x2 + 02= lim
x→0
1
x
which does not exist. So lim(x ,y)→(0,0)
x
x2 + y2does not exist.
Example
Show lim(x ,y)→(0,0)
x
x2 + y2does not exist.
SolutionFollow a path towards (0, 0) along the line y = 0.
limx→0
f (x , 0) = limx→0
x
x2 + 02= lim
x→0
1
x
which does not exist. So lim(x ,y)→(0,0)
x
x2 + y2does not exist.
Example
Show lim(x ,y)→(0,0)
x
x2 + y2does not exist.
SolutionFollow a path towards (0, 0) along the line y = 0.
limx→0
f (x , 0) = limx→0
x
x2 + 02= lim
x→0
1
x
which does not exist. So lim(x ,y)→(0,0)
x
x2 + y2does not exist.
We can see the problems in a graph.
x
x2 + y2= c ⇐⇒
(x − 1
c
)2
+ y2 =
(1
2c
)2
-1 -0.5 0 0.5 1-1
-0.5
0
0.5
1
-1
-0.5
0
0.5
1 -1
-0.5
0
0.5
1
-10
-5
0
5
10
-1
-0.5
0
0.5
We can see the problems in a graph.
x
x2 + y2= c ⇐⇒
(x − 1
c
)2
+ y2 =
(1
2c
)2
-1 -0.5 0 0.5 1-1
-0.5
0
0.5
1
-1
-0.5
0
0.5
1 -1
-0.5
0
0.5
1
-10
-5
0
5
10
-1
-0.5
0
0.5
We can see the problems in a graph.
x
x2 + y2= c ⇐⇒
(x − 1
c
)2
+ y2 =
(1
2c
)2
-1 -0.5 0 0.5 1-1
-0.5
0
0.5
1
-1
-0.5
0
0.5
1 -1
-0.5
0
0.5
1
-10
-5
0
5
10
-1
-0.5
0
0.5
Example
Show lim(x ,y)→(0,0)
x2
x2 + y2does not exist.
SolutionFollow a path towards (0, 0) along the line y = 0:
limx→0
f (x , 0) = limx→0
x2
x2 + 02= lim
x→01 = 1
Now follow a path towards (0, 0) along the line x = 0:
limy→0
f (0, y) = limx→0
02
02 + y2= lim
x→00 = 0
So the limit as (x , y)→ (0, 0) cannot exist.
Example
Show lim(x ,y)→(0,0)
x2
x2 + y2does not exist.
SolutionFollow a path towards (0, 0) along the line y = 0:
limx→0
f (x , 0) = limx→0
x2
x2 + 02= lim
x→01 = 1
Now follow a path towards (0, 0) along the line x = 0:
limy→0
f (0, y) = limx→0
02
02 + y2= lim
x→00 = 0
So the limit as (x , y)→ (0, 0) cannot exist.
Example
Show lim(x ,y)→(0,0)
x2
x2 + y2does not exist.
SolutionFollow a path towards (0, 0) along the line y = 0:
limx→0
f (x , 0) = limx→0
x2
x2 + 02= lim
x→01 = 1
Now follow a path towards (0, 0) along the line x = 0:
limy→0
f (0, y) = limx→0
02
02 + y2= lim
x→00 = 0
So the limit as (x , y)→ (0, 0) cannot exist.
Example
Show lim(x ,y)→(0,0)
x2
x2 + y2does not exist.
SolutionFollow a path towards (0, 0) along the line y = 0:
limx→0
f (x , 0) = limx→0
x2
x2 + 02= lim
x→01 = 1
Now follow a path towards (0, 0) along the line x = 0:
limy→0
f (0, y) = limx→0
02
02 + y2= lim
x→00 = 0
So the limit as (x , y)→ (0, 0) cannot exist.
Example
Show lim(x ,y)→(0,0)
x2
x2 + y2does not exist.
SolutionFollow a path towards (0, 0) along the line y = 0:
limx→0
f (x , 0) = limx→0
x2
x2 + 02= lim
x→01 = 1
Now follow a path towards (0, 0) along the line x = 0:
limy→0
f (0, y) = limx→0
02
02 + y2= lim
x→00 = 0
So the limit as (x , y)→ (0, 0) cannot exist.
Again, we can see the problems in a graph.
x2
x2 + y2= c ⇐⇒ y = ±
√1− c
cx
-1 -0.5 0 0.5 1-1
-0.5
0
0.5
1
-1
-0.5
0
0.5
1 -1
-0.5
0
0.5
1
0
0.25
0.5
0.75
1
-1
-0.5
0
0.5
Again, we can see the problems in a graph.
x2
x2 + y2= c ⇐⇒ y = ±
√1− c
cx
-1 -0.5 0 0.5 1-1
-0.5
0
0.5
1
-1
-0.5
0
0.5
1 -1
-0.5
0
0.5
1
0
0.25
0.5
0.75
1
-1
-0.5
0
0.5
Again, we can see the problems in a graph.
x2
x2 + y2= c ⇐⇒ y = ±
√1− c
cx
-1 -0.5 0 0.5 1-1
-0.5
0
0.5
1
-1
-0.5
0
0.5
1 -1
-0.5
0
0.5
1
0
0.25
0.5
0.75
1
-1
-0.5
0
0.5
Showing a limit does existThis is often harder. No single method always works.
Example
Show
lim(x ,y)→(0,0)
x3
x2 + y2= 0.
SolutionFrom the last problem we know that
0 ≤ x2
x2 + y2≤ 1
for all x and y, not both 0. So if x > 0,
0 ≤ x3
x2 + y2≤ x .
As x → 0+, the fraction in the middle must go to 0!
Showing a limit does existThis is often harder. No single method always works.
Example
Show
lim(x ,y)→(0,0)
x3
x2 + y2= 0.
SolutionFrom the last problem we know that
0 ≤ x2
x2 + y2≤ 1
for all x and y, not both 0.
So if x > 0,
0 ≤ x3
x2 + y2≤ x .
As x → 0+, the fraction in the middle must go to 0!
Showing a limit does existThis is often harder. No single method always works.
Example
Show
lim(x ,y)→(0,0)
x3
x2 + y2= 0.
SolutionFrom the last problem we know that
0 ≤ x2
x2 + y2≤ 1
for all x and y, not both 0. So if x > 0,
0 ≤ x3
x2 + y2≤ x .
As x → 0+, the fraction in the middle must go to 0!
Showing a limit does existThis is often harder. No single method always works.
Example
Show
lim(x ,y)→(0,0)
x3
x2 + y2= 0.
SolutionFrom the last problem we know that
0 ≤ x2
x2 + y2≤ 1
for all x and y, not both 0. So if x > 0,
0 ≤ x3
x2 + y2≤ x .
As x → 0+, the fraction in the middle must go to 0!
Another way
Switch to polar coordinates!
lim(x ,y)→(0,0)
x3
x2 + y2= lim
(r ,θ)→(0,0)
(r cos θ)3
(r cos θ)2 + (r sin θ)2
= lim(r ,θ)→(0,0)
r3 cos3 θ
r2 cos2 θ + r2 sin2 θ
= lim(r ,θ)→(0,0)
r cos3 θ = 0 · 1 = 0.
Outline
Introduction and definition
Rules of limits
ComplicationsShowing a limit doesn’t existShowing a limit does exist
Continuity
Worksheet
Continuity
DefinitionA function f of two variables is called continuous at (a, b) if
lim(x ,y)→(a,b)
f (x , y) = f (a, b).
We say f is continuous on D if f is continuous at every point(a, b) in D.
Outline
Introduction and definition
Rules of limits
ComplicationsShowing a limit doesn’t existShowing a limit does exist
Continuity
Worksheet