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1. Metric spaces
Denition 1.1. A metric space is a pair (X;d) consisting of a non-empty
set X and a map d :XX!R such that for all x;y;z2X,
(i) d(x;y) 0
(ii) d(x;y) = 0 if and only if x =y
(iii) d(x;y) =d(y;x)
(iv) d(x;z)d(x;y) +d(y;z) (the Triangle Inequality).
We will call the elements of X points. The mapping d is called a metric
and we can think of d(x;y) as the distance between two points x and y.
Our goal is to develop a theory for metric spaces which we can apply in a
variety of dierent situations. Our rst examples of metric spaces are the
Euclidean spacesR
n
.
Page 2


1. Metric spaces
Denition 1.1. A metric space is a pair (X;d) consisting of a non-empty
set X and a map d :XX!R such that for all x;y;z2X,
(i) d(x;y) 0
(ii) d(x;y) = 0 if and only if x =y
(iii) d(x;y) =d(y;x)
(iv) d(x;z)d(x;y) +d(y;z) (the Triangle Inequality).
We will call the elements of X points. The mapping d is called a metric
and we can think of d(x;y) as the distance between two points x and y.
Our goal is to develop a theory for metric spaces which we can apply in a
variety of dierent situations. Our rst examples of metric spaces are the
Euclidean spacesR
n
.
1.1. Euclidean spaces. We denote by R
n
the set of ordered n-tuples of
real numbers,
R
n
= f(x
1
;x
2
;:::;x
n
) :x
1
;x
2
;:::;x
n
2Rg
= R
 n!
 R
R
n
is a vector space (overR) with the following operations of addition and
scalar multiplication: If x = (x
1
;:::;x
n
) and y = (y
1
;:::;y
n
) are points in
R
n
then
x + y = (x
1
+y
1
;:::;x
n
+y
n
)
If 2R is a scalar then
 x = (x
1
;:::;x
n
)
The dot product of x and y is
x y =x
1
y
1
+ +x
n
y
n
The Euclidean norm of a point x = (x
1
;:::;x
n
) is
kxk =
p
x x
=
q
x
2
1
+ +x
2
n
Theorem 1.2. (Cauchy-Schwarz inequality) Let x = (x
1
;:::;x
n
) and y =
(y
1
;:::;y
n
) be points inR
n
. Then
jx yjkxkkyk
Corollary 1.3. Let x = (x
1
;:::;x
n
) and y = (y
1
;:::;y
n
) be points inR
n
.
Then
kx + ykkxk +kyk
Page 3


1. Metric spaces
Denition 1.1. A metric space is a pair (X;d) consisting of a non-empty
set X and a map d :XX!R such that for all x;y;z2X,
(i) d(x;y) 0
(ii) d(x;y) = 0 if and only if x =y
(iii) d(x;y) =d(y;x)
(iv) d(x;z)d(x;y) +d(y;z) (the Triangle Inequality).
We will call the elements of X points. The mapping d is called a metric
and we can think of d(x;y) as the distance between two points x and y.
Our goal is to develop a theory for metric spaces which we can apply in a
variety of dierent situations. Our rst examples of metric spaces are the
Euclidean spacesR
n
.
1.1. Euclidean spaces. We denote by R
n
the set of ordered n-tuples of
real numbers,
R
n
= f(x
1
;x
2
;:::;x
n
) :x
1
;x
2
;:::;x
n
2Rg
= R
 n!
 R
R
n
is a vector space (overR) with the following operations of addition and
scalar multiplication: If x = (x
1
;:::;x
n
) and y = (y
1
;:::;y
n
) are points in
R
n
then
x + y = (x
1
+y
1
;:::;x
n
+y
n
)
If 2R is a scalar then
 x = (x
1
;:::;x
n
)
The dot product of x and y is
x y =x
1
y
1
+ +x
n
y
n
The Euclidean norm of a point x = (x
1
;:::;x
n
) is
kxk =
p
x x
=
q
x
2
1
+ +x
2
n
Theorem 1.2. (Cauchy-Schwarz inequality) Let x = (x
1
;:::;x
n
) and y =
(y
1
;:::;y
n
) be points inR
n
. Then
jx yjkxkkyk
Corollary 1.3. Let x = (x
1
;:::;x
n
) and y = (y
1
;:::;y
n
) be points inR
n
.
Then
kx + ykkxk +kyk
Corollary 1.4. The mapping d :R
n
R
n
!R dened by
d(x; y) =kx yk
is a metric onR
n
.
The metric d dened in Corollary 1.4 is called the Euclidean metric on
R
n
. We calld(x; y) the Euclidean distance between the points x and y. The
metric space (R
n
;d) will be called n-dimensional Euclidean space. Unless
otherwise stated it can be assumed thatR
n
denotesn-dimensional Euclidean
space.
Note that by expanding out the Euclidean norm we get
d(x; y) = kx yk
=
p
(x
1
y
1
)
2
+ (x
2
y
2
)
2
+ + (x
n
y
n
)
2
Example 1.5. (a) The Euclidean metric onR. For real numbers x;y2R
the Euclidean distance is expressed in terms of absolute value
d(x;y) =jxyj
(b) The Euclidean metric on R
2
. We can think of the elements of R
2
as
coordinates for points in the plane. The Euclidean distance between
two points x = (x
1
;x
2
) and y = (y
1
;y
2
) is
d(x; y) =
p
(x
1
y
1
)
2
+ (x
2
y
2
)
2
(c) The Euclidean metric on R
3
. We can think of the elements of R
3
as
coordinates for points in space. The Euclidean distance between two
points x = (x
1
;x
2
;x
3
) and y = (y
1
;y
2
;y
3
) is
d(x; y) =
p
(x
1
y
1
)
2
+ (x
2
y
2
)
2
+ (x
3
y
3
)
2
Page 4


1. Metric spaces
Denition 1.1. A metric space is a pair (X;d) consisting of a non-empty
set X and a map d :XX!R such that for all x;y;z2X,
(i) d(x;y) 0
(ii) d(x;y) = 0 if and only if x =y
(iii) d(x;y) =d(y;x)
(iv) d(x;z)d(x;y) +d(y;z) (the Triangle Inequality).
We will call the elements of X points. The mapping d is called a metric
and we can think of d(x;y) as the distance between two points x and y.
Our goal is to develop a theory for metric spaces which we can apply in a
variety of dierent situations. Our rst examples of metric spaces are the
Euclidean spacesR
n
.
1.1. Euclidean spaces. We denote by R
n
the set of ordered n-tuples of
real numbers,
R
n
= f(x
1
;x
2
;:::;x
n
) :x
1
;x
2
;:::;x
n
2Rg
= R
 n!
 R
R
n
is a vector space (overR) with the following operations of addition and
scalar multiplication: If x = (x
1
;:::;x
n
) and y = (y
1
;:::;y
n
) are points in
R
n
then
x + y = (x
1
+y
1
;:::;x
n
+y
n
)
If 2R is a scalar then
 x = (x
1
;:::;x
n
)
The dot product of x and y is
x y =x
1
y
1
+ +x
n
y
n
The Euclidean norm of a point x = (x
1
;:::;x
n
) is
kxk =
p
x x
=
q
x
2
1
+ +x
2
n
Theorem 1.2. (Cauchy-Schwarz inequality) Let x = (x
1
;:::;x
n
) and y =
(y
1
;:::;y
n
) be points inR
n
. Then
jx yjkxkkyk
Corollary 1.3. Let x = (x
1
;:::;x
n
) and y = (y
1
;:::;y
n
) be points inR
n
.
Then
kx + ykkxk +kyk
Corollary 1.4. The mapping d :R
n
R
n
!R dened by
d(x; y) =kx yk
is a metric onR
n
.
The metric d dened in Corollary 1.4 is called the Euclidean metric on
R
n
. We calld(x; y) the Euclidean distance between the points x and y. The
metric space (R
n
;d) will be called n-dimensional Euclidean space. Unless
otherwise stated it can be assumed thatR
n
denotesn-dimensional Euclidean
space.
Note that by expanding out the Euclidean norm we get
d(x; y) = kx yk
=
p
(x
1
y
1
)
2
+ (x
2
y
2
)
2
+ + (x
n
y
n
)
2
Example 1.5. (a) The Euclidean metric onR. For real numbers x;y2R
the Euclidean distance is expressed in terms of absolute value
d(x;y) =jxyj
(b) The Euclidean metric on R
2
. We can think of the elements of R
2
as
coordinates for points in the plane. The Euclidean distance between
two points x = (x
1
;x
2
) and y = (y
1
;y
2
) is
d(x; y) =
p
(x
1
y
1
)
2
+ (x
2
y
2
)
2
(c) The Euclidean metric on R
3
. We can think of the elements of R
3
as
coordinates for points in space. The Euclidean distance between two
points x = (x
1
;x
2
;x
3
) and y = (y
1
;y
2
;y
3
) is
d(x; y) =
p
(x
1
y
1
)
2
+ (x
2
y
2
)
2
+ (x
3
y
3
)
2
1.2. More examples of metric spaces.
Example 1.6. Let X be any non-empty set.
The discrete metric on X is dened by
d(x;y) =
8
<
:
0 if x =y
1 if x6=y
for all points x;y in X.
Example 1.7. Let x = (x
1
;x
2
) and y = (y
1
;y
2
) be points inR
2
.
(a) The taxi-cab metric onR
2
is dened by
d(x; y) =jx
1
y
1
j +jx
2
y
2
j
(b) The Irish rail metric onR
2
is dened by
d
0
(x; y) =
8
<
:
0 if x = y
d(x; 0) +d(0; y) if x6= y
where 0 = (0; 0) is the origin inR
2
andd is the Euclidean metric onR
2
.
Example 1.8. The complex numbers.
(C;d) is a metric space where d is dened by
d(z;w) =jzwj; 8z;w2C
Example 1.9. A function space.
Let C[0; 1] be the set of all continuous functions f : [0; 1]!R.
The following dene two dierent metrics on C[0; 1],
(a) d(f;g) = sup
x2[0;1]
jf(x)g(x)j
(b) d(f;g) =
R
1
0
jf(x)g(x)jdx
for all f;g2C[0; 1].
Page 5


1. Metric spaces
Denition 1.1. A metric space is a pair (X;d) consisting of a non-empty
set X and a map d :XX!R such that for all x;y;z2X,
(i) d(x;y) 0
(ii) d(x;y) = 0 if and only if x =y
(iii) d(x;y) =d(y;x)
(iv) d(x;z)d(x;y) +d(y;z) (the Triangle Inequality).
We will call the elements of X points. The mapping d is called a metric
and we can think of d(x;y) as the distance between two points x and y.
Our goal is to develop a theory for metric spaces which we can apply in a
variety of dierent situations. Our rst examples of metric spaces are the
Euclidean spacesR
n
.
1.1. Euclidean spaces. We denote by R
n
the set of ordered n-tuples of
real numbers,
R
n
= f(x
1
;x
2
;:::;x
n
) :x
1
;x
2
;:::;x
n
2Rg
= R
 n!
 R
R
n
is a vector space (overR) with the following operations of addition and
scalar multiplication: If x = (x
1
;:::;x
n
) and y = (y
1
;:::;y
n
) are points in
R
n
then
x + y = (x
1
+y
1
;:::;x
n
+y
n
)
If 2R is a scalar then
 x = (x
1
;:::;x
n
)
The dot product of x and y is
x y =x
1
y
1
+ +x
n
y
n
The Euclidean norm of a point x = (x
1
;:::;x
n
) is
kxk =
p
x x
=
q
x
2
1
+ +x
2
n
Theorem 1.2. (Cauchy-Schwarz inequality) Let x = (x
1
;:::;x
n
) and y =
(y
1
;:::;y
n
) be points inR
n
. Then
jx yjkxkkyk
Corollary 1.3. Let x = (x
1
;:::;x
n
) and y = (y
1
;:::;y
n
) be points inR
n
.
Then
kx + ykkxk +kyk
Corollary 1.4. The mapping d :R
n
R
n
!R dened by
d(x; y) =kx yk
is a metric onR
n
.
The metric d dened in Corollary 1.4 is called the Euclidean metric on
R
n
. We calld(x; y) the Euclidean distance between the points x and y. The
metric space (R
n
;d) will be called n-dimensional Euclidean space. Unless
otherwise stated it can be assumed thatR
n
denotesn-dimensional Euclidean
space.
Note that by expanding out the Euclidean norm we get
d(x; y) = kx yk
=
p
(x
1
y
1
)
2
+ (x
2
y
2
)
2
+ + (x
n
y
n
)
2
Example 1.5. (a) The Euclidean metric onR. For real numbers x;y2R
the Euclidean distance is expressed in terms of absolute value
d(x;y) =jxyj
(b) The Euclidean metric on R
2
. We can think of the elements of R
2
as
coordinates for points in the plane. The Euclidean distance between
two points x = (x
1
;x
2
) and y = (y
1
;y
2
) is
d(x; y) =
p
(x
1
y
1
)
2
+ (x
2
y
2
)
2
(c) The Euclidean metric on R
3
. We can think of the elements of R
3
as
coordinates for points in space. The Euclidean distance between two
points x = (x
1
;x
2
;x
3
) and y = (y
1
;y
2
;y
3
) is
d(x; y) =
p
(x
1
y
1
)
2
+ (x
2
y
2
)
2
+ (x
3
y
3
)
2
1.2. More examples of metric spaces.
Example 1.6. Let X be any non-empty set.
The discrete metric on X is dened by
d(x;y) =
8
<
:
0 if x =y
1 if x6=y
for all points x;y in X.
Example 1.7. Let x = (x
1
;x
2
) and y = (y
1
;y
2
) be points inR
2
.
(a) The taxi-cab metric onR
2
is dened by
d(x; y) =jx
1
y
1
j +jx
2
y
2
j
(b) The Irish rail metric onR
2
is dened by
d
0
(x; y) =
8
<
:
0 if x = y
d(x; 0) +d(0; y) if x6= y
where 0 = (0; 0) is the origin inR
2
andd is the Euclidean metric onR
2
.
Example 1.8. The complex numbers.
(C;d) is a metric space where d is dened by
d(z;w) =jzwj; 8z;w2C
Example 1.9. A function space.
Let C[0; 1] be the set of all continuous functions f : [0; 1]!R.
The following dene two dierent metrics on C[0; 1],
(a) d(f;g) = sup
x2[0;1]
jf(x)g(x)j
(b) d(f;g) =
R
1
0
jf(x)g(x)jdx
for all f;g2C[0; 1].
Example 1.10. A sequence space.
Letc
0
be the set of all sequences (x
k
)
1
k=1
of real numbers which converge to
0. Then (c
0
;d) is a metric space where we dene
d(x; y) = sup
k
jx
k
y
k
j
for all points x = (x
k
)
1
k=1
and y = (y
k
)
1
k=1
in c
0
.
Example 1.11. Subspaces.
If (X;d) is a metric space and A is a subset of X then (A;d
A
) is a metric
space where we dene
d
A
(x;y) =d(x;y) 8x;y2A
(A;d
A
) is called a subspace of (X;d) and d
A
is called the induced metric.
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FAQs on Metric Spaces - Linear Functional Analysis - 1 - Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

1. What is a metric space?
Ans. A metric space is a mathematical structure that consists of a set of elements and a distance function, called a metric, that defines the distance between any two elements in the set. The metric satisfies certain properties, such as non-negativity, symmetry, and the triangle inequality.
2. How is linear functional analysis related to metric spaces?
Ans. Linear functional analysis is a branch of mathematics that deals with vector spaces and linear transformations. It is closely related to metric spaces because many concepts and results in metric spaces, such as convergence, continuity, and compactness, can be studied using tools from linear functional analysis.
3. What are some applications of metric spaces?
Ans. Metric spaces have various applications in different fields of mathematics and beyond. Some examples include: - In computer science, metric spaces are used in algorithms for clustering, pattern recognition, and data analysis. - In physics, metric spaces are used to describe the distances between physical objects or states in certain models. - In optimization, metric spaces are used to define distances between solutions and to measure convergence. - In economics, metric spaces are used to model consumer preferences and analyze decision-making processes.
4. What is the importance of the triangle inequality in metric spaces?
Ans. The triangle inequality is a fundamental property of metric spaces. It states that the distance between any two points in a metric space is always less than or equal to the sum of the distances between those points and a third point. This property allows us to define and study concepts such as convergence, continuity, and compactness, which are crucial in analysis and many other areas of mathematics.
5. Can all metric spaces be studied using linear functional analysis?
Ans. No, not all metric spaces can be studied using linear functional analysis. Linear functional analysis is a powerful tool for studying certain classes of metric spaces, such as normed spaces and Banach spaces. However, there are metric spaces that do not possess the necessary algebraic structure or properties for being analyzed using linear functional analysis. In such cases, other mathematical tools and techniques may be more suitable.
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