What are some common examples of vectors?

This is a vector:

Índice Show

Subtracting
Calculations
Adding Vectors
Subtracting Vectors
Magnitude of a Vector
Vector vs Scalar
Example: kb is actually the scalar k times the vector b.
Multiplying a Vector by a Vector (Dot Product and Cross Product)
More Than 2 Dimensions
Magnitude and Direction
What are Vectors?
Vectors in Euclidean Geometry- Definition
Vectors - Examples
Representation of Vectors
Magnitude of Vectors
Angle Between Two Vectors
Types of Vectors
Zero Vectors
Unit Vectors
Position Vectors
Equal Vectors
Negative Vector
Parallel Vectors
Orthogonal Vectors
Co-initial Vectors
Vectors Formulas
Operations on Vectors
Addition of Vectors
Subtraction of Vectors
Scalar Multiplication of Vectors
Scalar Triple Product of Vectors
Multiplication of Vectors
Components of Vectors
Scalars and Vectors
Difference Between Scalars and Vectors
Applications of Vectors
FAQs on Vectors
What are Examples of Vectors?
What are Vector Formulas?
What are the Properties of Vectors?
What are Collinear Vectors?
How are Vectors used in Real Life?
How are Vectors Linearly Independent?
What is the Difference Between Scalars and Vectors?
When are Two Vectors said to be Parallel Vectors?

A vector has magnitude (size) and direction:

The length of the line shows its magnitude and the arrowhead points in the direction.

We can add two vectors by joining them head-to-tail:

And it doesn't matter which order we add them, we get the same result:

The two vectors (the velocity caused by the propeller, and the velocity of the wind) result in a slightly slower ground speed heading a little East of North.

If you watched the plane from the ground it would seem to be slipping sideways a little.

Have you ever seen that happen? Maybe you have seen birds struggling against a strong wind that seem to fly sideways. Vectors help explain that.

Velocity, acceleration, force and many other things are vectors.

Subtracting

We can also subtract one vector from another:

first we reverse the direction of the vector we want to subtract,
then add them as usual:

a − b

Notation

A vector is often written in bold, like a or b.

A vector can also be written as the letters
of its head and tail with an arrow above it, like this:

Calculations

Now ... how do we do the calculations?

The most common way is to first break up vectors into x and y parts, like this:

The vector a is broken up into
the two vectors ax and ay

(We see later how to do this.)

Adding Vectors

We can then add vectors by adding the x parts and adding the y parts:

The vector (8, 13) and the vector (26, 7) add up to the vector (34, 20)

c = a + b

c = (8, 13) + (26, 7) = (8+26, 13+7) = (34, 20)

When we break up a vector like that, each part is called a component:

Subtracting Vectors

To subtract, first reverse the vector we want to subtract, then add.

a = v + −k

a = (12, 2) + −(4, 5) = (12, 2) + (−4, −5) = (12−4, 2−5) = (8, −3)

Magnitude of a Vector

The magnitude of a vector is shown by two vertical bars on either side of the vector:

|a|

OR it can be written with double vertical bars (so as not to confuse it with absolute value):

||a||

We use Pythagoras' theorem to calculate it:

|a| = √( x2 + y2 )

|b| = √( 62 + 82) = √( 36+64) = √100 = 10

A vector with magnitude 1 is called a Unit Vector.

Vector vs Scalar

A scalar has magnitude (size) only.

Scalar: just a number (like 7 or −0.32) ... definitely not a vector.

A vector has magnitude and direction, and is often written in bold, so we know it is not a scalar:

so c is a vector, it has magnitude and direction
but c is just a value, like 3 or 12.4

Example: kb is actually the scalar k times the vector b.

When we multiply a vector by a scalar it is called "scaling" a vector, because we change how big or small the vector is.

a = 3m = (3×7, 3×3) = (21, 9)

It still points in the same direction, but is 3 times longer

(And now you know why numbers are called "scalars", because they "scale" the vector up or down.)

Multiplying a Vector by a Vector (Dot Product and Cross Product)

How do we multiply two vectors together? There is more than one way!

(Read those pages for more details.)

More Than 2 Dimensions

Vectors also work perfectly well in 3 or more dimensions:

The vector (1, 4, 5)

c = a + b

c = (3, 7, 4) + (2, 9, 11) = (3+2, 7+9, 4+11) = (5, 16, 15)

|w| = √( 12 + (−2)2 + 32 ) = √( 1+4+9) = √14

Here is an example with 4 dimensions (but it is hard to draw!):

(3, 3, 3, 3) + −(1, 2, 3, 4) = (3, 3, 3, 3) + (−1,−2,−3,−4) = (3−1, 3−2, 3−3, 3−4)

= (2, 1, 0, −1)

Magnitude and Direction

We may know a vector's magnitude and direction, but want its x and y lengths (or vice versa):

	<=>
Vector a in Polar Coordinates		Vector a in Cartesian Coordinates

You can read how to convert them at Polar and Cartesian Coordinates, but here is a quick summary:

From Polar Coordinates (r,θ) to Cartesian Coordinates (x,y)		From Cartesian Coordinates (x,y) to Polar Coordinates (r,θ)
x = r × cos( θ ) y = r × sin( θ )		r = √ ( x2 + y2 ) θ = tan-1 ( y / x )

An Example

Sam and Alex are pulling a box.

Sam pulls with 200 Newtons of force at 60°
Alex pulls with 120 Newtons of force at 45° as shown

What is the combined force, and its direction?

Let us add the two vectors head to tail:

First convert from polar to Cartesian (to 2 decimals):

Sam's Vector:

x = r × cos( θ ) = 200 × cos(60°) = 200 × 0.5 = 100
y = r × sin( θ ) = 200 × sin(60°) = 200 × 0.8660 = 173.21

Alex's Vector:

x = r × cos( θ ) = 120 × cos(−45°) = 120 × 0.7071 = 84.85
y = r × sin( θ ) = 120 × sin(−45°) = 120 × -0.7071 = −84.85

Now we have:

Add them:

(100, 173.21) + (84.85, −84.85) = (184.85, 88.36)

That answer is valid, but let's convert back to polar as the question was in polar:

r = √ ( x2 + y2 ) = √ ( 184.852 + 88.362 ) = 204.88
θ = tan-1 ( y / x ) = tan-1 ( 88.36 / 184.85 ) = 25.5°

And we have this (rounded) result:

And it looks like this for Sam and Alex:

They might get a better result if they were shoulder-to-shoulder!

Vectors are geometrical entities that have magnitude and direction. A vector can be represented by a line with an arrow pointing towards its direction and its length represents the magnitude of the vector. Therefore, vectors are represented by arrows, they have initial points and terminal points. The concept of vectors was evolved over a period of 200 years. Vectors are used to represent physical quantities such as displacement, velocity, acceleration, etc.

Further, the use of vectors started in the late 19th century with the advent of the field of electromagnetic induction. Here, we will study the definition of vectors along with properties of vectors, formulas of vectors, operation of vectors along using solved examples for a better understanding.

What are Vectors?

A vector is a Latin word that means carrier. Vectors carry a point A to point B. The length of the line between the two points A and B is called the magnitude of the vector and the direction of the displacement of point A to point B is called the direction of the vector AB. Vectors are also called Euclidean vectors or Spatial vectors. Vectors have many applications in maths, physics, engineering, and various other fields.

Vectors in Euclidean Geometry- Definition

Vectors in math is a geometric entity that has both magnitude and direction. Vectors have an initial point at the point where they start and a terminal point that tells the final position of the point. Various operations can be applied to vectors such as addition, subtraction, and multiplication. We will study the operations on vectors in detail in this article.

Vectors - Examples

Vectors play an important role in physics. For example, velocity, displacement, acceleration, force are all vector quantities that have a magnitude as well as a direction.

Representation of Vectors

Vectors are usually represented in bold lowercase such as a or using an arrow over the letter as \(\vec{a}\). Vectors can also be denoted by their initial and terminal points with an arrow above them, for example, vector AB can be denoted as \(\overrightarrow{AB}\). The standard form of representation of a vector is \(\vec{A}=a \hat{i}+b\hat{j}+c\hat{k}\). Here, a,b,c are real numbers and \(\hat{i}, \hat{j}, \hat{k}\) are the unit vectors along the x-axis, y-axis, and z-axis respectively.

The initial point of a vector is also called the tail whereas the terminal point is called the head. Vectors describe the movement of an object from one place to another. In the cartesian coordinate system, vectors can be denoted by ordered pairs. Similarly, vectors in 'n' dimensions can be denoted by an 'n' tuple. Vectors are also identified with a tuple of components which are the scalar coefficients for a set of basis vectors. The basis vectors are denoted as: e1 = (1,0,0), e2 = (0,1,0), e3 = (0,0,1)

Magnitude of Vectors

The magnitude of a vector can be calculated by taking the square root of the sum of the squares of its components. If (x,y,z) are the components of a vector A, then the magnitude formula of A is given by,

|A| = √ (x2+y2+z2)

The magnitude of a vector is a scalar value.

Angle Between Two Vectors

The angle between two vectors can be calculated using the dot product formula. Let us consider two vectors a and b and the angle between them to be θ. Then, the dot product of two vectors is given by a·b = |a||b| cosθ. We need to determine the value of the angle θ. The angle between two vectors also indicates the directions of the two vectors. θ can be evaluated using the following formula:

θ = cos-1[(a·b)/|a||b|]

Types of Vectors

The vectors are termed as different types based on their magnitude, direction, and their relationship with other vectors. Let us explore a few types of vectors and their properties:

Zero Vectors

Vectors that have 0 magnitude are called zero vectors, denoted by \(\overrightarrow{0}\) = (0,0,0). The zero vector has zero magnitudes and no direction. It is also called the additive identity of vectors.

Unit Vectors

Vectors that have magnitude equals to 1 are called unit vectors, denoted by \(\hat{a}\). It is also called the multiplicative identity of vectors. The magnitude of a unit vectors is 1. It is generally used to denote the direction of a vector.

Position Vectors

Position vectors are used to determine the position and direction of movement of the vectors in a three-dimensional space. The magnitude and direction of position vectors can be changed relative to other bodies. It is also called the location vector.

Equal Vectors

Two or more vectors are said to be equal if their corresponding components are equal. Equal vectors have the same magnitude as well as direction. They may have different initial and terminal points but the magnitude and direction must be equal.

Negative Vector

A vector is said to be the negative of another vector if they have the same magnitudes but opposite directions. If vectors A and B have equal magnitude but opposite directions, then vector A is said to be the negative of vector B or vice versa.

Parallel Vectors

Two or more vectors are said to be parallel vectors if they have the same direction but not necessarily the same magnitude. The angles of the direction of parallel vectors differ by zero degrees. The vectors whose angle of direction differs by 180 degrees are called antiparallel vectors, that is, antiparallel vectors have opposite directions.

Orthogonal Vectors

Two or more vectors in space are said to be orthogonal if the angle between them is 90 degrees. In other words, the dot product of orthogonal vectors is always 0. a·b = |a|·|b|cos90° = 0.

Co-initial Vectors

Vectors that have the same initial point are called co-initial vectors.

Vectors Formulas

Different mathematical operations can be applied to vectors such as addition, subtraction, and multiplication. In this section, we will explore the vector formulas for vector addition, subtraction, dot-product, cross-product and angle between the vectors.

The list of vectors formulas that we will be studying in detail further is as follows:

(a1\(\hat i\) + b1 \( \hat j\) + c1 \(\hat k\)) + (a2 \(\hat i\) + b2 \(\hat j\) + c2 \(\hat k\)) = (a1 + a2) \( \hat i\) + (b1 + b2) \(\hat j\) + (c1 + c2) \(\hat k\)
(a1\(\hat i\) + b1 \( \hat j\) + c1 \(\hat k\)) - (a2 \(\hat i\) + b2 \(\hat j\) + c2 \(\hat k\)) = (a1 - a2) \( \hat i\) + (b1 - b2) \( \hat j\) + (c1 - c2) \(\hat k\)
(a1\(\hat i\) + b1 \( \hat j\) + c1 \( \hat k\)) . (a2 \(\hat i\) + b2 \( \hat j\) + c2 \(\hat k\)) = (a1·a2) + (b1·b2) + (c1·c2)
\(\overrightarrow{A} \times \overrightarrow{B}\) = \(\hat i\) (a2b3 - a3b2) - \(\hat j\) (a1b3 - a3b1) + \(\hat k\) (a1b2 - a2b1)
θ = cos-1 (a·b/|a||b|)

The following properties of vectors help in better understanding of vectors and are useful in performing numerous arithmetic operations involving vectors.

The addition of vectors is commutative and associative.
\(\vec A . \vec B = \vec B. \vec A \)
\( \vec A \times \vec B\neq \vec B \times \vec A \)
\(\hat i .\hat i =\hat j.\hat j = \hat k.\hat k = 1 \)
\(\hat i .\hat j =\hat j.\hat k = \hat k.\hat i = 0 \)
\(\hat i \times \hat i =\hat j\times \hat j = \hat k\times \hat k = 0 \)
\(\hat i \times \hat j = \hat k~;~ \hat j\times \hat k = \hat i~;~ \hat k\times \hat i = \hat j \)
\(\hat j \times \hat i = -\hat k~;~ \hat k \times \hat j = -\hat i~;~ \hat i \times \hat k = -\hat j \)
The dot product of two vectors is a scalar and lies in the plane of the two vectors.
The cross product of two vectors is a vector, which is perpendicular to the plane containing these two vectors.

Operations on Vectors

Some basic operations on vectors can be performed geometrically without taking any coordinate system as a reference. These vector operations are given as addition, subtraction, and multiplication by a scalar. Also, there are two different ways to multiply two vectors together, the dot product and the cross product. These are briefly explained as given below,

Addition of Vectors
Subtraction of Vectors
Scalar Multiplication
Scalar Triple Product of Vectors
Multiplication of Vectors

Addition of Vectors

Adding vectors is similar to adding scalars. The individual components of the respective vectors are added to get the final value:

a + b = (a1 \( \hat i\) + b1 \( \hat j\) + c1 \( \hat k\)) + (a2 \( \hat i\) + b2 \( \hat j\) + c2 \( \hat k\)) = (a1, b1, c1) + (a2, b2, c2) = (a1 + a2, b1 + b2, c1 + c2) = (a1 + a2) \( \hat i\) + (b1 + b2) \( \hat j\) + (c1 + c2) \( \hat k\)

The addition of vectors is commutative and associative. There are two laws of vector addition:

Triangle Law of Addition of Vectors: The law states that if two sides of a triangle represent the two vectors (both in magnitude and direction) acting simultaneously on a body in the same order, then the third side of the triangle represents the resultant vector.

Parallelogram Law of Addition of Vectors: The law states that if two co-initial vectors acting simultaneously are represented by the two adjacent sides of a parallelogram, then the diagonal of the parallelogram represents the sum of the two vectors, that is, the resultant vector starting from the same initial point.

Subtraction of Vectors

The subtraction of vectors is similar to the addition of vectors. But here only the sign of one of the vectors is changed in direction and added to the other vector.

a - b = (a1 \( \hat i\) + b1 \( \hat j\) + c1 \( \hat k\)) - (a2 \( \hat i\) + b2 \( \hat j\) + c2 \( \hat k\)) = (a1, b1, c1) - (a2, b2, c2) = (a1 - a2, b1 - b2, c1 - c2) = (a1 - a2) \( \hat i\) + (b1 - b2) \( \hat j\) + (c1 - c2) \( \hat k\)

Scalar Multiplication of Vectors

A scalar is a real number that has no direction. When a scalar is multiplied by a vector, we multiply the scalar by each component of the vector. The operation of multiplying a vector by a scalar is called scalar multiplication. When a vector a = (a1, a2, a3) = a1 \( \hat i\) + a2 \( \hat j\) + a3 \( \hat k\) is multiplied by a scalar r, the resultant vector is:

ra = (ra1, ra2, ra3) = (ra1)e1 + (ra2)e2 + (ra3)e3

If r is negative, then the direction of the resultant vector changes direction by 180 degrees.
Scalar multiplication is distributive over vector addition, that is, r(a+b) = ra + rb

The multiplication of vectors with any scalar quantity is defined as 'scaling'. Scaling in vectors only alters the magnitude and does not affect the direction. Some properties of scalar multiplication in vectors are given as,

k(a + b) = ka + kb
(k + l)a = ka + la
a·1 = a
a·0 = 0
a·(-1) = -a

Scalar Triple Product of Vectors

Scalar triple product of vectors is the dot of one vector with the cross product of the other two vectors. If any two vectors in a scalar triple product are equal, then the scalar triple product is zero. If the scalar triple product is equal to zero, then the three vectors a, b, and c are said to be coplanar.

Also, a·(b × c) = b·(c × a) = c·(a × b)

Multiplication of Vectors

Vectors can be multiplied but their methods of multiplication are slightly different from that of real numbers. There are two different ways to multiply vectors:

Dot Product of Vectors:

The individual components of the two vectors to be multiplied are multiplied and the result is added to get the dot product of two vectors.
a·b = (a1 \( \hat i\) + b1 \( \hat j\) + c1 \( \hat k\)) ·(a2 \( \hat i\) + b2 \( \hat j\) + c2 \( \hat k\)) = (a1, b1, c1)·(a2, b2, c2) = (a1·a2) + (b1·b2) + (c1·c2) Another way to determine the dot product of two vectors A and B is to determine the product of the magnitudes of the two vectors and the cosine of the angle between them. \(\vec{A} ·\vec{B}\) = |A||B| cosθ

The resultant of a dot product of two vectors is a scalar value, that is, it has no direction.

Cross Product of vectors:

The vector components are represented in a matrix and a determinant of the matrix represents the result of the cross product of the vectors.

\(\vec{A} \times \vec{B}\) = (b1c2 - c1b2, a1c2 - c1a2, a1b2 - b1a2) Another way to determine the cross product of two vectors A and B is to determine the product of the magnitudes of the two vectors and the sine of the angle between them.

\(\vec{A} \times \vec{B}\) = |A||B| sinθ \(\hat{n}\)

Components of Vectors

A vector quantity has two characteristics, magnitude, and direction, such that both the quantities are compared while comparing two vector quantities of the same type. Any vector, in a two-dimensional coordinate system, can be broken into x-component, and y-component. In the figure given below, we can observe these components - x-component, V\(_x\) and y-component, V\(_y\) for a vector,v in coordinate plane.

The values of V\(_x\) and V\(_y\) can be given as,

V\(_x\) = V·cosθ, and V\(_y\) = V.sinθ

|V| = √[V\(_x\)2 + V\(_y\)2]

Scalars and Vectors

Physical quantities that do not have any direction are called scalars. Scalars are nothing but real numbers, sometimes accompanied by unit measurements. On the other hand, vectors are physical quantities that have magnitudes as well as directions. Basic operations of addition, subtraction, and multiplication are applicable on both scalars and vectors.

Difference Between Scalars and Vectors

The only difference between scalars and vectors is that a scalar is a quantity that does not depend on direction whereas a vector is a physical quantity that has magnitude as well as direction. The common examples of scalars are distance, speed, time, etc. These are real values accompanied by their units of measurements. Common examples of vectors are displacement, velocity, acceleration, force, etc. which indicate the direction of the quantity and its magnitude.

Scalars and Vectors Examples:

Scalar: Speed as 40 mph, Time as 4 hours which do not indicate any direction

Vector: Displacement as -4 ft, velocity -40 mph indicate the direction. Negative velocity and displacement imply that the object is moving in the opposite direction.

Applications of Vectors

Vectors are very useful in the field of Physics and Mathematics. They are used to represent the position, displacement, velocity, and acceleration of objects and physical quantities. Some applications of vectors are,

Vectors play a very crucial role in the study of partial differential equations and in differential geometry.
Vectors are used in physics and engineering, especially in the areas including use of electromagnetic fields, gravitational fields, and fluid flow.

Related Topics on Vectors:

Please check the following links to help us easily learn vectors.

Important Notes on Vectors:

The following important points are helpful to better understand the concepts of vectors.

Dot product of orthogonal vectors is always zero.
Cross product of parallel vectors is always zero.
Two or more vectors are collinear if their cross product is zero.

Example 1: Find the angle between the two vectors 2\( \hat i\) + \( \hat j\) -3\( \hat k\) and 3 \( \hat i\) -\( \hat j\) + \( \hat k\)?

Solution:

Given two vectors a = 2\( \hat i\) + \( \hat j\) - 3 \( \hat k\) and b = 3 \( \hat i\) -\( \hat j\) + \( \hat k\)

We need to determine the angle between the vectors a and b using the formula cosθ = a.b / |a||b|

a·b = (2 \( \hat i\) + \( \hat j\) – 3 \( \hat k\))·(3\( \hat i\) – \( \hat j\) + \( \hat k\))

= (2 × 3) + (1 × -1) + (-3 × 1)

= 6 - 1 - 3

= 2

|a| = √(22 + 12 + (-3)2)

= √(4 + 1 + 9)

= √14

|b| = √(32 + (-1)2 + (1)2)

= √(9 + 1 + 1)

= √11

cosθ = 2 / (√14 × √11)

cosθ = 2 / 12.409

cosθ = 0.161

θ = cos-1(0.161)

θ = 80.73°

Answer: The angle between the two vectors is 80.73°.
Example 2: Find the sum of two vectors a = 4 \( \hat i\) + 2 \( \hat j\) – 5 \( \hat k\) and b = 3 \( \hat i\) – 2\( \hat j\) + \( \hat k\) ?

Solution:

Given two vectors a = 4 \( \hat i\) + 2 \( \hat j\) – 5\( \hat k\) and b = 3\( \hat i\) – 2\( \hat j\) + \( \hat k\)

a + b = (4\( \hat i\) + 2\( \hat j\) – 5\( \hat k\)) + (3\( \hat i\) – 2\( \hat j\) + \( \hat k\))

= (4 + 3)\( \hat i\) + (2 - 2)\( \hat j\) + (-5 + 1)\( \hat k\)

= 7\( \hat i\) + 0 \( \hat j\) - 4\( \hat k\)

= 7\( \hat i\) - 4 \( \hat k\)

Therefore, the sum of two vectors is 7 \( \hat i\) - 4 \( \hat k\)

Answer: 7 \( \hat i\) - 4 \( \hat k\)
Example 3: Find the cross product of two vectors a = 4 \( \hat i\) + 2\( \hat j\) -5\( \hat k\) and b = 3 \( \hat i\) -2\( \hat j\) + \( \hat k\) and verify it using cross product calculator?

Solution:

Given two vectors a = 4 \( \hat i\) + 2\( \hat j\) – 5\( \hat k\) and b = 3 \( \hat i\) – 2\( \hat j\) + \( \hat k\)

Comparing these to the vector notations we have.

a = \(a_1 \hat i + a_2 \hat j + a_3 \hat k\) and b = \(b_1 \hat i + b_2 \hat j + b_3\hat k\)

Applying cross product formula,

a × b = \( \hat i\)(a2b3 − a3b2) − \( \hat j\)(a1b3 − a3b1) + \( \hat k\)(a1b2 − a2b1)

= \( \hat i\)((2 × 1) - (-5) × (-2)) - \( \hat j\)((4 × 1 - (-5) × (3)) + \( \hat k\)((4) × (-2) - (2 × 3))

= \( \hat i\)(2 - 10) - \( \hat j\)(4 + 15) + \( \hat k\)(-8 - 6)

= -8\( \hat i\) - 19\( \hat j\) - 14\( \hat k\)

Therefore, the cross product of two vectors is -8\( \hat i\) - 19\( \hat j\) - 14\( \hat k\)

Answer: -8\( \hat i\) - 19\( \hat j\) - 14\( \hat k\)

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FAQs on Vectors

Vectors are geometrical or physical quantities that possess both magnitude and direction in which the object is moving. The magnitude of a vector indicates the length of the vector. It is generally represented by an arrow pointing in the direction of the vector. A vector a is denoted as a1 \( \hat i\) + b1 \( \hat j\) + c1 \( \hat k\), where a1, b1, c1 are its components.

What are Examples of Vectors?

The physical quantities that are specified completely by the magnitude and direction are called vector quantities. For example, physical quantities like displacement, velocity, position, force, torque, etc are vector quantities.

What are Vector Formulas?

There are different formulas that can be used to perform operations on vectors. Some of are as given below,

\( \hat A = \frac{\vec A}{|\vec{A}|}\)
\( \vec A·\vec B = |\vec{A}||\vec{B}|cos\theta\)
\( \vec A \times \vec B = | \vec{A}||\vec{B}|sin \theta \times \hat n\)
Projection of Vector\( \vec {A} \ \text{on Vector} \vec{B} = \dfrac{\vec{A}. \vec{B}}{| \vec{B}|}\)

What are the Properties of Vectors?

There are several properties of vectors, few of them are:

Addition of vectors is commutative and associative, that is, ab = ba and a(bc) = (ab)c
The additive identity of vectors is the zero vector, that is, a + 0 = a
The additive inverse of a vector is the negative of the vector, that is, a + (-a) = 0
The scalar multiplication of vectors is associative. r(ab) = (ra)b

What are Collinear Vectors?

Collinear vectors are vectors that are parallel/antiparallel to the same each other irrespective of their magnitude. The cross-product of collinear vectors is always zero.

How are Vectors used in Real Life?

In our daily life, you may think of vectors being used to represent the velocity of an aircraft, where both the speed and the direction of movement of the aircraft are to be known. Electromagnetic induction involves an interplay of electric forces and magnetic forces.

How are Vectors Linearly Independent?

Vectors are said to be linearly independent if there exists a non-trivial linear combination of vectors that is equal to zero. If no such linear combination exists, the vectors are said to be linear dependent. In other words, a set of vectors {v1, v2, v3, ..., vn} are linearly independent if there exists nontrivial scalars k1, k2, k3, ..., know, such that k1v1 + k2v2 + k3v3 + ... + knvn = 0

What is the Difference Between Scalars and Vectors?

The scalars are entities with magnitude, that do not depend on direction whereas vectors are objects that have magnitude as well as direction. Scalars are usually real values with units of measurement. Vectors indicate the direction in which the object is moving. For example, time 4 hours is a scalar as it does not give any direction whereas the velocity 40 mph is a vector as it tells that the object is moving in one direction.

When are Two Vectors said to be Parallel Vectors?

Two or more vectors are parallel if they are moving in the same direction. Also, the cross-product of parallel vectors is always zero. The angle between two parallel vectors is either 0° or 180°, and the cross product of parallel vectors is equal to zero. a.b = |a|.|b|Sin0° = 0.