Vectors

Here we introduce vectors and the notation that we use for vectors. We then give some facts about real vectors before discussing the complex vectors used in quantum mechanics.

Vectors Defining and Representing

You may have heard of the definition of a vector as a quantity with both magnitude and direction. While this is true and often used in science classes, our purpose is different. So we will simply define a vector as a set of numbers that is written in an row or a column. When the vector is written as a row of numbers, it is called a row vector and when it is written as a set of numbers in a column, it is called a column vector. As we will see, these two can have the same set of numbers, but each can be used in a slightly different way.

Examples

This is an example of a row vector ${\displaystyle {\vec {v}}=(2,4,3).}$

This is an example of a column vector ${\displaystyle {\vec {w}}=\left({\begin{array}{c}1\\5\\4\end{array}}\right).}$

Real Vectors

If you are familiar with vectors, the simple definition of a vector --- an object that has magnitude and direction --- is helpful to keep in mind even when dealing with complex vectors (vectors with complex, i.e., imaginary numbers as entries) as we will here. However, this is not necessary and we will see how to perform all of the operations that we need just using arrays of numbers that we call vectors. In three dimensional space, a vector is often written as

${\displaystyle {\vec {v}}=v_{x}{\hat {x}}+v_{y}{\hat {y}}+v_{z}{\hat {z}},}$

where the hat (${\displaystyle {\hat {\cdot }}\,\!}$) denotes a unit vector and the components ${\displaystyle v_{i}\,\!}$, ${\displaystyle i=x,y,z\,\!}$ are just numbers. The unit vectors are also known as basis vectors. This is because any vector in real three-dimensional space can be written in terms of these unit/basis vectors. In this vector, one can associate a point where the coordinate of the point is ${\displaystyle (x,y,z)}$. That is, a point a distance ${\displaystyle x}$ from the origin along the ${\displaystyle x}$-axis, a distance ${\displaystyle y}$ from the origin along the ${\displaystyle y}$-axis, and a distance ${\displaystyle z}$ from the origin along the ${\displaystyle z}$-axis. In some sense, unit vectors are the basic components of any vector. Other basis vectors could be used. But this will be discussed elsewhere.

Vector Operations

To illustrate vector operations, let

${\displaystyle {\vec {v}}=\left({\begin{array}{c}v_{1}\\v_{2}\end{array}}\right),{\mbox{ and }}{\vec {w}}=\left({\begin{array}{c}w_{1}\\w_{2}\end{array}}\right).}$

Vector Addition

Vectors can be added. To do this, each element of one vector is added to the corresponding element of the other vector. In general, for a row vector, they add as

${\displaystyle {\vec {v}}+{\vec {w}}=\left({\begin{array}{c}v_{1}\\v_{2}\end{array}}\right)+\left({\begin{array}{c}w_{1}\\w_{2}\end{array}}\right)=\left({\begin{array}{c}v_{1}+w_{1}\\v_{2}+w_{2}\end{array}}\right).}$

The addition of row vectors is similar. They are added component by component. Suppose we had

${\displaystyle {\vec {s}}=\left(s_{1},s_{2}\right),{\mbox{ and }}{\vec {u}}=\left(u_{1},u_{2}\right).}$

Then

${\displaystyle {\vec {s}}+{\vec {u}}=\left(s_{1},s_{2}\right)+\left(u_{1},u_{2}\right)=\left(s_{1}+u_{1},s_{2}+u_{2}\right).}$

Since the way vectors are added is component to corresponding component, it is important to note that you can only add vectors if they are the same type. (No adding "apples and oranges" so to speak.) So you can add two vectors that are both column vectors and have three entries. You can't add a column vector to a row vector and you can't add a vector with two components to a vector with three components.

Example

Adding two vectors ${\displaystyle {\vec {v}}_{1}\,\!}$ and ${\displaystyle {\vec {w}}_{1}\,\!}$ with

${\displaystyle {\vec {v}}_{1}=\left({\begin{array}{c}1\\5\end{array}}\right),\;\;{\vec {w}}_{1}=\left({\begin{array}{c}4\\2\end{array}}\right),\,\!}$

we get

${\displaystyle {\vec {v}}_{1}+{\vec {w}}_{1}=\left({\begin{array}{c}1\\5\end{array}}\right)+\left({\begin{array}{c}4\\2\end{array}}\right)=\left({\begin{array}{c}5\\7\end{array}}\right).\,\!}$

Multiplication by a Number

When a vector is multiplied by a number, each component is multiplied by that same number. For example, suppose

${\displaystyle {\vec {v}}=\left({\begin{array}{c}v_{1}\\v_{2}\end{array}}\right).}$

Then

${\displaystyle a{\vec {v}}=a\left({\begin{array}{c}v_{1}\\v_{2}\end{array}}\right)=\left({\begin{array}{c}av_{1}\\av_{2}\end{array}}\right).}$

Notice that if ${\displaystyle a}$ is positive, then the magnitude of the vector is

${\displaystyle |a{\vec {v}}|={\sqrt {(av_{1})^{2}+(av_{1})^{2}}}={\sqrt {a^{2}(v_{1}^{2}+v_{2}^{2})}}=a|{\vec {v}}|.}$

So multiplying a vector by a number just changes the length, or magnitude, of the vector is ${\displaystyle a}$ is positive. If ${\displaystyle a}$ is negative, it changes the directions of the components and therefore of the vector itself and also changes the magnitude.

Products of Vectors

The inner product, or dot product, for two real three-dimensional vectors,

${\displaystyle {\vec {v}}=v_{x}{\hat {x}}+v_{y}{\hat {y}}+v_{z}{\hat {z}},\;\;{\vec {w}}=w_{x}{\hat {x}}+w_{y}{\hat {y}}+w_{z}{\hat {z}},}$

can be computed as follows:

${\displaystyle {\vec {v}}\cdot {\vec {w}}=v_{x}w_{x}+v_{y}w_{y}+v_{z}w_{z}.}$

For the inner product of ${\displaystyle {\vec {v}}\,\!}$ with itself, we get the square of the magnitude of ${\displaystyle {\vec {v}}\,\!}$, denoted ${\displaystyle |{\vec {v}}|^{2}\,\!}$:

${\displaystyle |{\vec {v}}|^{2}={\vec {v}}\cdot {\vec {v}}=v_{x}v_{x}+v_{y}v_{y}+v_{z}v_{z}=v_{x}^{2}+v_{y}^{2}+v_{z}^{2}.}$

If we want a unit vector in the direction of ${\displaystyle {\vec {v}}\,\!}$, we can simply divide it by its magnitude:

${\displaystyle {\hat {v}}={\frac {\vec {v}}{|{\vec {v}}|}}.}$

Now, of course, ${\displaystyle {\hat {v}}\cdot {\hat {v}}=1\,\!}$, which can easily be checked.

There are several ways to represent a vector. The ones we will use most often are column and row vector notations. So, for example, we could write the vector above as

${\displaystyle {\vec {v}}=\left({\begin{array}{c}v_{x}\\v_{y}\\v_{z}\end{array}}\right).}$

In this case, our unit vectors are represented by the following:

${\displaystyle {\hat {x}}=\left({\begin{array}{c}1\\0\\0\end{array}}\right),\;\;{\hat {y}}=\left({\begin{array}{c}0\\1\\0\end{array}}\right),\;\;{\hat {z}}=\left({\begin{array}{c}0\\0\\1\end{array}}\right).\,\!}$

We next turn to the subject of complex vectors and the relevant notation. We will see how to compute the inner product later, since some other definitions are required.

Complex Vectors

For complex vectors in quantum mechanics, Dirac notation is used most often. This notation uses a ${\displaystyle \left\vert \cdot \right\rangle \,\!}$, called a ket, for a vector. So our vector ${\displaystyle {\vec {v}}\,\!}$ would be

${\displaystyle \left\vert v\right\rangle =\left({\begin{array}{c}v_{x}\\v_{y}\\v_{z}\end{array}}\right).}$

For qubits, i.e. two-state quantum systems, complex vectors will often be used:

	${\displaystyle {\begin{aligned}\left\vert \psi \right\rangle &=\left({\begin{array}{c}\alpha \\\beta \end{array}}\right)\\&=\alpha \left\vert 0\right\rangle +\beta \left\vert 1\right\rangle ,\end{aligned}}}$	(C.1)

where

${\displaystyle \left\vert 0\right\rangle =\left({\begin{array}{c}1\\0\end{array}}\right),\;\;{\mbox{and}}\;\;\left\vert 1\right\rangle =\left({\begin{array}{c}0\\1\end{array}}\right)}$

are the basis vectors. The two numbers ${\displaystyle \alpha \,\!}$ and ${\displaystyle \beta \,\!}$ are complex numbers, so the vector is said to be a complex vector. Recall from Chapter 1 - Introduction that quantum states are represented by complex vectors, such as the quantum particle being in one of two different wells.