Video: Cartesian Vector Notation

Consider a vector A with its x and y components represented in terms of unit vectors, i and j. Here the unit vectors have dimensionless magnitude of one.

Since the magnitude of any vector component is always a positive quantity, represented by scalars, A can be expressed as a Cartesian vector.

Here, a right-handed, rectangle coordinate system is used. The right-hand thumb points toward the positive z-axis, and the fingers curl from the positive x-axis toward the positive y-axis.

A 3-dimensional vector can be represented in rectangular cartesian coordinates using i, j, and k unit vectors. The direction of these vectors are represented depending on the positive or negative axes.

A vector is represented as the vector sum of its individual components, and its magnitude is expressed as the positive square root of the sum of the squares of its components.

Vector algebra operations are simplified by representing vector in the Cartesian form. It separates its magnitude and direction along the axes using unit vector notation.

Cartesian vector notation is a valuable tool in mechanical engineering for representing vectors in three-dimensional space, performing vector operations such as determining the gradient, divergence, and curl, and expressing physical quantities such as the displacement, velocity, acceleration, and force. By using Cartesian vector notation, engineers can more easily analyze and solve problems in various areas of mechanical engineering, including dynamics, kinematics, and fluid mechanics. This notation represents a vector in terms of three components along the x, y, and z axes, respectively.

For example, suppose we have a vector A pointing in the direction (3, −4, 5). In that case, it can be represented using Cartesian vector notation as A = 3i - 4j + 5k, where i, j, and k are unit vectors along the x, y, and z axes, respectively. The unit vectors are defined as i = (1, 0, 0), j = (0, 1, 0), and k = (0, 0, 1).

Cartesian vector notation can be used to perform various vector operations, such as addition, subtraction, and scalar multiplication. For example, if we have two vectors, A = 3i - 4j + 5k and B = 2i + 7j - 3k, we can add them using Cartesian vector notation as follows:

Equation 1

We can also subtract them as follows:

Equation 2

Tags

Cartesian Vector Notation Mechanical Engineering Vector Operations Gradient Divergence Curl Displacement Velocity Acceleration Force Dynamics Kinematics Fluid Mechanics Unit Vectors Vector Addition Vector Subtraction Scalar Multiplication

From Chapter 2:

article

Now Playing

2.9 : Cartesian Vector Notation

Force Vectors

546 Views

article

2.1 : Scalar and Vectors

Force Vectors

1.0K Views

article

2.2 : Vector Operations

Force Vectors

945 Views

article

2.3 : Introduction to force

Force Vectors

347 Views

article

2.4 : Force Classification

Force Vectors

946 Views

article

2.5 : Vector Addition of Forces

Force Vectors

459 Views

article

2.6 : Two-Dimensional Force System

Force Vectors

737 Views

article

2.7 : Two-Dimensional Force System: Problem Solving

Force Vectors

445 Views

article

2.8 : Scalar Notation

Force Vectors

558 Views

article

2.10 : Direction Cosines of a Vector

Force Vectors

287 Views

article

2.11 : Three-Dimensional Force System

Force Vectors

1.7K Views

article

2.12 : Three-Dimensional Force System:Problem Solving

Force Vectors

504 Views

article

2.13 : Position Vectors

Force Vectors

574 Views

article

2.14 : Force Vector along a Line

Force Vectors

370 Views

article

2.15 : Dot Product

Force Vectors

218 Views

See More

Copyright © 2025 MyJoVE Corporation. All rights reserved