What Is A Tensor Lesson #1: Elementary vector spaces
Summary
TLDRThis lecture delves into the foundational concepts of vectors and tensors, starting from scratch by redefining vectors beyond their common physical interpretations. It emphasizes the mathematical construct of a vector as an element of a vector space, outlining properties such as vector addition and scalar multiplication that differentiate a vector space from other sets. The lecture then progresses to explaining the significance of dimensions within vector spaces, touching upon the notions of linearity and isomorphism. By challenging the audience to discard preconceived notions about vectors, it sets the stage for understanding the complexity and beauty of tensor calculus, crucial for fields like general relativity.
Takeaways
- 💡 The foundational concept starts with redefining vectors from a mathematical perspective, distinct from their common understanding in physics.
- 📖 A vector is defined as an element of a set within a vector space, emphasizing the abstraction away from physical concepts.
- ✍️ Vector space properties are crucial: it must allow vector addition and scalar multiplication, following specific rules to qualify as a vector space.
- ❓ Dimensionality is a key characteristic of vector spaces, determining the minimal set of basis vectors needed to represent any vector in the space.
- 📈 The lecture introduces the concept of real vector spaces, using real numbers for scalar multiplication, as the focus for general relativity studies.
- ✔️ Essential operations for vector spaces include vector addition, which must result in another vector within the same space, ensuring closure.
- ⚡ Scalar multiplication involves combining a vector with a real number, producing another vector within the same space, highlighting the linear structure.
- 🖥 Linearity and the principle of superposition are underscored as fundamental properties, enabling the construction of vectors through addition and scalar multiplication.
- ⭕ The absence of operations like dot and cross products in elementary vector spaces is highlighted, distinguishing pure vector spaces from more complex structures.
- 📚 The discussion prepares for future topics on mapping between vector spaces, indicating a deeper exploration of mathematical structures in relativity.
Q & A
What initial misconception about vectors is highlighted in the lecture?
-The lecture highlights the misconception that many students think they fully understand vectors based on their familiarity with them from physics and basic electromagnetism and mechanics, such as vector addition, dot products, and cross products.
Why does the lecture suggest forgetting everything known about vectors?
-It suggests forgetting everything known about vectors in order to start fresh with the mathematical concept of a vector, which is fundamentally different from the practical applications of vectors commonly taught.
What defines a vector space, according to the lecture?
-A vector space is defined as a set in which every element is a vector. It must have an operation called vector addition, where adding two vectors results in another vector within the same set, indicating closure under addition.
What is the significance of scalar multiplication in a vector space?
-Scalar multiplication, the process of multiplying a vector by a real number (scalar) to produce another vector within the same space, is significant because it along with vector addition, helps define the structure and properties of a vector space.
How does the lecture differentiate between real and complex vector spaces?
-The differentiation is based on the type of numbers used for scalar multiplication. If a vector space uses real numbers, it's a real vector space; if it uses complex numbers, it's a complex vector space.
What is linearity in the context of vector spaces?
-Linearity refers to the property that allows the combination of scalar multiplication and vector addition in such a way that if two vectors are scaled and then added, the result is the same as adding the vectors first and then scaling the result.
Why must every vector in a vector space have an opposite?
-Every vector must have an opposite to ensure that the vector space is closed under addition. This opposite vector, when added to the original vector, results in the zero vector, maintaining the structural integrity of the space.
How is the dimension of a vector space determined?
-The dimension of a vector space is determined by the minimum number of basis vectors needed to linearly combine them to form any vector in the space. This minimal set of vectors captures the essence of the vector space's structure.
What does it mean for two vector spaces to be isomorphic?
-Two vector spaces are isomorphic if there is a one-to-one correspondence between their elements and their operations, meaning they are structurally the same in terms of addition and scalar multiplication, differing only in nomenclature.
Why are certain operations like the dot product and magnitude not initially considered part of a vector space?
-These operations are not part of the fundamental definition of a vector space. They are advanced concepts added to enrich the structure of a vector space, making it more sophisticated than just the basic requirements of vector addition and scalar multiplication.
Outlines
🧠 Introduction to Vectors and Vector Spaces
This section introduces the fundamental shift from the physical concept of vectors, commonly encountered in physics, to the mathematical concept integral to understanding tensors. The physical operations familiar to students, such as vector addition, dot product, and cross product, are set aside to focus on the mathematical definition of a vector as an element of a set known as a vector space (VS). A vector space is defined by two key properties: the ability to add two vectors within the space (vector addition) and the ability to multiply vectors by real numbers (scalar multiplication), maintaining closure within the set. The narrative emphasizes that these operations are exclusive to vectors within the same vector space, underlining the specificity of vector space operations and the foundational role these concepts play in progressing towards understanding tensors.
🔢 From Vector Spaces to Complex and Real Vector Spaces
The narrative continues by distinguishing between real and complex vector spaces based on the type of numbers used for scalar multiplication, highlighting the use of real vector spaces for general relativity. The script delves into the mathematical properties that define a vector space: the addition and scalar multiplication operations, which ensure closure and linear combination within the space. A vector space must also include the zero vector and allow for inverse vectors, ensuring every vector has a counterpart that sums to zero. This foundation prepares for the exploration of vector space dimensions, emphasizing the distinction between vector spaces through the concept of dimensionality rather than their operational definitions, which remain consistent across vector spaces.
🌌 Dimensionality and Basis Vectors in Vector Spaces
Expanding on the concept of dimensionality, this section explains how to determine the dimension of a vector space by finding the minimum number of basis vectors needed to express any vector within the space through linear combination. The narrative clarifies the non-uniqueness of basis vectors but underscores the significance of the minimal set required for complete vector space representation, known as the dimension of the space. Using the dimensionality concept, the text sets the stage for discussing vector spaces in the context of space-time, specifically adopting a four-dimensional perspective for the study of general relativity. This focus on dimensionality serves as a critical step towards understanding complex concepts within physics and mathematics.
🔀 Distinguishing Vector Spaces and Isomorphism
The final segment addresses the differentiation of vector spaces through the lens of isomorphism, emphasizing that vector spaces of the same dimensionality are fundamentally similar, barring their nomenclature. Isomorphism is defined as the ability to establish a one-to-one correspondence between elements (and operations) of two vector spaces, rendering their differences superficial. The script also highlights that vector spaces are limited to operations within their elements and that advanced concepts like dot products, cross products, and magnitudes are not inherent to basic vector space theory. This distinction sets the groundwork for further exploration of mappings between vector spaces, indicating a transition towards more complex mathematical structures and their applications.
Mindmap
Keywords
💡Vector
💡Vector Space
💡Scalar Multiplication
💡Real Vector Spaces
💡Linearity
💡Dimension
💡Basis Vectors
💡Isomorphic
💡Addition Operation
💡Scalar
Highlights
Introduction to tensors starting with basic vector concepts.
Clearing misconceptions about vectors learned in physics.
Definition of a vector as an element of a vector space.
Explanation of vector spaces and their properties.
The necessity of vector addition for a set to qualify as a vector space.
Scalar multiplication and its role in vector spaces.
Distinction between real vector spaces and complex vector spaces.
Introduction to the concept of linearity in vector spaces.
The requirement of an additive inverse for every vector in a vector space.
The concept of dimensionality in vector spaces.
Illustration of basis vectors and their significance in defining vector spaces.
The isomorphic nature of vector spaces with the same dimensionality.
Clarification that vector spaces fundamentally only support addition within the same space.
Elaboration on the absence of dot product, cross product, and magnitude in pure vector spaces.
Transitioning from basic vector space properties to mapping between vector spaces.
Transcripts
we were going to a pro
tensor is by starting with the concept
of a vector and we're going to begin
from the very very basics and we're
going to clear up how to get from the
concept of a vector to the concept of a
tensor so we're going to start this
lecture with an elementary understanding
of what a vector is and I don't want you
to think that that's going to be
something familiar because in your mind
or in the mind of many students who
approach the subject they think they
know all about vectors because they've
made their bones because they have in
physics and in basic electromagnetism
and mechanics they know how vectors work
they know how to add two vectors
together they know how to take the dot
product between two vectors right they
know how to take the cross product
between two vectors to produce a third
vector they know all kinds of things
about vectors and they're very good with
them you know how to translate them and
move them around they know how to scale
them right that's they know how to they
have a very good understanding of how
vectors function the problem is is all
of that stuff we need to forget we need
to actually delete from our mind because
we are going to start with the
mathematical concept of a vector which
is not the same thing so everything you
know about vectors we erase and we're
going to start fresh and where do we
begin we begin with the notion that a
vector is an element of a set and that
set is called a vector space and I'll
call it V s for vector space and a
vector space is a set and every element
in it is a vector so if you come out of
this vector space say you're out here
the element W or you're the element V or
you're the element s you are a vector
and now since there are many different
types of sets in the world we have to
understand what kind of set makes a
vector space what is it that actually
makes because there are many sets that
you can have it's not just every set as
a vector space you have to have a
certain set of properties associated
with
the set and those properties are what's
going to distinguish a vector space set
from any other set and the first key
property is that it must have in
addition to the set itself it must have
an operation called addition and it's
vector addition the idea between for
vector addition is that with if you put
a vector on the left and vector on the
right you're going to get a vector
result so here we might put W V and
we're going to get another vector out
and we could call it t the vector
addition allows you to add two vectors
together and what's important about it
is that is that it only works for
vectors in the set it's not a general
addition rule that allows you to add
vectors from different vector spaces or
different spaces altogether
it only allows you to take two vectors
in the set know some of these or
whatever still back here you can take
two vectors put on the left and right
and you get a third member and that
member is also in the set so in this
case T would also have to be part of the
vector space because it must be closed
you must be able to add any two vectors
and you look and the one thing that you
get as a result is in the vector space
it's in the vector space itself you
can't do that you don't have a vector
space so you have to define this concept
of addition then the next thing you need
is you need to be able to reach in to a
bucket of numbers and that bucket of
numbers are the bucket of real numbers
all the real numbers live in this little
bucket say and you need to be able to
pull out any real number we'll call it a
and you need to have an a sense of how
to multiply a vector from the vector
space any a vector in the vector space
by this real number and that
multiplication is called scalar
multiplication and so we symbolize that
by the real number times the vector and
that is an element of the vector space
we'll call the vector space here say W
double using the vector space so so any
scalar times
a vector is also a vector in W and this
process here is called scalar
multiplication and the objects that come
out of the real numbers these the real
number bumps bin are called scalars now
vector spaces use this real number bin
if they use the real number bin they are
called real vector spaces it's a real
vector space if it uses a bin of real
numbers if it used a bin of say complex
numbers then it would be called the
complex vector space so you you almost
have to distinguish if you're going to
create a vector space you have to assert
not only this addition property but you
have to make a decision is it going to
be real numbers or complex numbers
obviously the complex numbers includes
the real numbers so but you still have
to choose and for general relativity we
will always always choose real vector
spaces for now there is some complex
vector spaces in general relativity but
not anything we're going to talk about
in these lectures so we don't worry
about complex vector spaces just real
vector spaces so now once we've done
this once we've got our we've got our
addition property we've got our scalar
multiplication property then what we're
going to do is we're going to work on
the combination of the two and this
should be very simple if I take a if and
this is what I'll do I'll show you this
is my vector space right it's the vector
space we're going to call it V it's got
its addition property it's got the real
numbers the scalars from the real
numbers and if I take one vector that's
scaled by a real number and add it to
another vector that's scaled by a real
number and both of these vectors come
from V I should be able to get another
vector in the vector space and this
makes perfect sense of course because
this is a
during the vector space this is a vector
in the vector space this is the addition
property the vector addition property
associated with this vector space
therefore it must be that the sum of
those two is also in the vector space
and once I've asserted this then I just
need to assert the simple point of
linearity where if I did aw plus a t I
get a times W plus T which means which
means that the scalar does the scaled
prata
the scalar product with W plus the
scalar product with T is the same as
adding W plus T and multiplying by the
scalar and this is simply a very
critical property called linearity and
it means that our vector space is linear
and this didn't have to be that way by
the way it could have been that this
equaled say a squared W plus T that does
happen for some exotic forms of spaces
but not the ones we're talking about
this is not what we're using so we've
got this we've got several things we've
got our um our linearity property which
encompasses both our vector addition
property and our scalar multiplication
property and then one last thing that
defines a vector space unambiguously is
we need to make sure that any vector W
that is an element of this vector space
say our vector space is V if W is if if
W is an element of V then there's
another vector in the vector space V
called - W and that is characterized by
the fact that W with a vector addition
of minus W equals zero and sure enough
zero therefore is always a vector in
every vector space zero must be a vector
in the vector space and every vector
must have its opposite and yes the
opposite is if I take from my bin of
real numbers if I take minus one and I
use that to multiply by a vector W that
product
is in fact - W and it's always part of
the vector space so so far so good we've
got we've got our vector space V and
we've got the vector addition property
we've got the scalar multiplication
property from the real numbers so this
is a real vector space and we know that
it's linear and that is our vector space
now an interesting thing is that we have
to be able to answer to one or two
important questions about in elementary
vector space we've already answered one
is it a real vector space or complex
vector space there's actually two other
kinds it could be quatrain yannick or it
could be octi onic but there's only four
there's four different kinds of vector
spaces and and anything other than those
four is a more of a mathematical
generalization of the concept but when
we talk about vector spaces we're almost
always talking about we're almost always
talking about real or complex vector
spaces complex vector spaces are
important in quantum mechanics but in
general relativity we're dealing with
real vector spaces but if I did this
again I could create another vector
space W and it'll also have be a real
vector space and it will have its own
vector addition property now I can pull
out vectors from W say I pulled out well
let's let's say I called it our I pulled
out a vector s and I pulled out a vector
T and from V let's say I pulled out a
vector a little W a little Q and how
about little P right so these are
vectors from W these are vectors from W
these are vectors I'm sorry these are
vectors from W and these are vectors
from Q now the vector addition property
of W is such that I can take any of
these two and add them and I can get
another vector
inside inside V so W plus Q equals say M
likewise I can take R plus s and I can
get another vector out of
out of w and say that one was called
i'll say say it was t right the thing
that's very important to know is this
vector addition property only works for
these vectors in this vector addition
property only works for those vectors
this is not the same plus sign as this
and the only thing that gives it away is
knowing that r and s are elements of W
and W and Q are elements of V if you
didn't know that you might think that
these represent the same operation but
these are different operations you can
never never write W plus R because W
comes from V and R comes from W and
there is no defined operation that adds
elements of V to elements of W it just
doesn't exist we have not defined it now
you could define something like that
there it is possible but that's not what
we're doing we're creating nothing all
we're creating is addition properties
for individual vector spaces so but it
is also now an important question to ask
what's the difference between this
vector space in this vector space other
than the name and they're both real
vector spaces so you could imagine this
is a complex vector space that would be
different from a real vector space but
symbolically or mathematically is there
a way of distinguishing these two and
the answer is often there is not well
there is one key characteristic that can
distinguish between two vector spaces
that's the dimension of the vector space
so the way we learn about dimensions is
we're going to ask the very fundamental
question I draw a random vector any
vector any arbitrary vector out of V out
of this space V let's say we pick them q
if I draw drew an arbitrary vector out
of V I want to know what's the minimum
number of other vectors I would need to
be able to linearly combine them to
create Q so say there's a vector a W
plus B
the P plus C let's say n plus D Oh about
Oh and then we could go on and on and on
and the question is is I need to find a
minimal set of vectors a P and O that
multiplied by real numbers will give me
any Q in the vector space and if I can
find a minimal set of those vectors in
this case the minimal set might be WP N
and O let's say I can find that minimal
set I know that I can express any vector
any vector in V as a linear combination
of these four basis vectors and that's
what these are called these are called
basis vectors and basis vectors they
they are not unique inside the vector
space you can obviously see why they
wouldn't be unique because if W is a
basis vector than a W would also be a
basis vector because you could just
rescale it by choosing another real
number so clearly basis vectors aren't
unique but what is important is the
number of them I need the minimal number
that can capture every vector in the
vector space and in this case I've said
that the minimal number is four and so I
what I'm saying and now is that the
dimension of V equals four and we're
going to use four dimensional four for
all of our work because four is the
dimensions of space time and space time
is what we're going to talk about we're
trying to shoot for general relativity
so we're going to talk about four
dimensional vector spaces but if V is a
dimension of four and I could put that
right here say make a little circle
around it
what about W well if W has the same
number dimensions then W and V are only
different because they're named
differently there's got to be something
to distinguish them so it's got to be
the name but otherwise if they're the
same dimension they're actually so
similar that the difference is between
these two vector spaces is entirely
superficial and we call that isomorphic
two vector spaces are isomorphic if
they're in
if you can establish a one-to-one
correspondence between the two and if
operations in this vector space are in
correspondence to operations in that
vector space we're not going to talk too
much about it but the point is is that
other than the name these two vector
spaces are mathematically very very very
similar and you really have to come up
with ways of distinguishing them okay so
where we're at now is we've covered the
elementary properties that all vector
spaces must have and those elementary
properties are our they must be defined
with a vector addition they must be
defined with a scalar multiplication
generally for real numbers for what
we're going to do they must be linear
and they must have a dimension and in
our case the dimension is 4 now
understand the only operation we have
between two vectors in one vector space
is if V and if W whoops if V and W are
members of the vector space V I can add
them but I can't do anything else notice
we have not discussed this concept this
is a totally different concept remember
dot product between two little pointy
things that we learned in physics that's
an element of the real numbers right we
have not learned how to take two vectors
and turn them into a real number that
this does not exist in a vector space
there's no notion of a cross product in
a vector space by the way a cross
product produces another vector but not
necessarily in the same vector space as
these two so we don't have a notion of a
cross product we don't have a notion of
a magnitude right which remember that
was V dot V right we do not have a
notion of a magnitude or a squared
magnitude I should say that doesn't
exist none of these things exist in real
pure elementary vector spaces all of
this stuff is advanced in a weird way
right it's it's not very complicated but
it is stuff that's added to vector
spaces that make
the more sophisticated than the
elementary vector space very few things
out there in the world are actually
purely elementary vector spaces but but
all vector spaces are in fact elementary
vector spaces at least and if they don't
have these properties they're not vector
spaces at all but they can have other
properties like dot products and cross
products and magnitudes and things like
that but this is what we're going to
start talking about next
but right now understand this is the
core element of a vector space this is
what makes a vector space so our next
lecture is going to be a little bit more
about how to now start building maps
between vector spaces
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