Cartesian Vectors | Engineering Mechanics - Civil Engineering (CE) PDF Download

Cartesian Vectors

  • Cartesian vectors are like arrows in space that tell you two important things: which way to go and how far. Imagine three lines crossing each other at right angles, like a corner of a room. These lines are the x, y, and z axes. A vector is just a set of three numbers that tells you how much to move along each of these lines. 
  • So, if you have a vector like ⟨3, 2, -1⟩, it means you move 3 steps to the right, 2 steps up, and 1 step back. These little packages of numbers help us understand how things move and push in the world around us. Scientists and engineers use them to make machines work better and to figure out how things move in space.

Cartesian VectorCartesian Vector

Cartesian Force Vectors

  • Cartesian force vectors represent the directed forces acting on objects in space. In the Cartesian coordinate system, forces are described by their components along the x, y, and z axes, denoted as ⟨Fx, Fy, Fz⟩. These components indicate the magnitude and direction of the force along each axis.
  • For instance, a force vector of <i>⟨10, 5, -3⟩</i> signifies a force of 10 units along the positive x-axis, 5 units along the positive y-axis, and 3 units along the negative z-axis. 
  • Any force F can be written in the form of a Cartesian vector.  Such an expression uses the addition of the force’s component vectors in the x, y, and z directions of the axes of the right-hand coordinate.  If the magnitude of its component in the x direction is Fx, in the y direction Fy, an in the z direction Fz, then F is expressed as

F = Fxi +Fyj + Fzk

wherei, j, and k are the Cartesian unit vectors.

Expressing A Force Vector By Using Its Magnitude And Two Points On Its Line Of Action.  

  • The Cartesian vector expression for a force is often obtained by using the Cartesian position vector that gives the Cartesian unit vectors corresponding to the direction concerned.  For example, the force F has a line of action that passes through points P(x1,y1,z1) and Q(x2,y2,z2).
  • Let the position vector r that points from P to Q describes the relative position between P and Q.  From the diagram, we obtain the relationship
  • r = –r1 + r2
  • However, we can formulate the relationships  r1 = x1i + y1j + z1k and r2 = x2i + y2j + z2k.  By inserting these relationships into the terms for  r1 and r2 in the equation above, we get
  •  r = (x2x1)i + (y2y1)j + (z2z1)k          …..(2.2)
  • Hence the components of r in the x, y, and z directions are obtained by subtracting the coordinates of the tail from those of the heads. Note that if the coordinates of Q are subtracted from those of P, we will get the vector –r.
  • A force of magnitude F and having its line of action, direction, and sense corresponding to the unit vector s in Figure 2.3 can thus be expressed in the Cartesian vector form by writing F = Fand then expanding the expression on the right of the equal sign.
  • The coordinate direction angles for the line of action of F are obtained from the cosine direction relationship for s

Addition of Forces. 

The concept of force resultant can be applied to a concurrent force system which is written in the Cartesian vector form.  If P is the resultant of F1, F2, F3, … hence

PFi

=  (F1x + F2x + …)i + (F1y + F2y + …)j + (F1z + F2z + …)k

= ΣFixi + ΣFiyj + ΣFizk          (2.5)

whereΣFix, ΣFiy, and ΣFiz are the sums of the magnitudes of the forces in the corresponding direction.

Resolution of Forces

Any force can be resolved into its components. There are a number of methods that can be used to resolve a force. The method use depends on the problem at hand.  The different methods are described below.

2.8.1. Parallelogram Law

A force acting at any point can be resolved into components that act in two desired directions through the parallelogram law.  Force F in Figure 2.12(a), for example, can be replaced by two components acting in directions 1 and 2.  The resolution is implemented by drawing a parallelogram with F as the diagonal and its two non-parallel sides along directions 1 and 2,

Cartesian Vectors | Engineering Mechanics - Civil Engineering (CE)

Note that resolution is the reverse process of adding two forces into their resultant.  Hence the resolution involves six quantities, i.e. the magnitude and direction of F and of the two components, where two of them can be determined when the other four are known. 

Rectangular components.  When force F is resolved into perpendicular directions, we obtain the rectangular components.  This is shown in Figure 2.13 for a 2D case, where the respective perpendicular directions are represented by the x-axis and the y-axis.  In this case, we get

Fx = F cos θ

 Fy = F sin θ

where  θ = tan-1 (Fy/Fx)

Addition Of Forces.   Forces can be added by using their components, normally the rectangular components in the Cartesian directions. Consider forces F1 and F2 that are concurrent at O being added using the force polygon, Figure 2.14(a).  The resultant P is

P = F1 + F2

The document Cartesian Vectors | Engineering Mechanics - Civil Engineering (CE) is a part of the Civil Engineering (CE) Course Engineering Mechanics.
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FAQs on Cartesian Vectors - Engineering Mechanics - Civil Engineering (CE)

1. What are Cartesian vectors?
Ans. Cartesian vectors are quantities that have both magnitude and direction and are represented by a set of coordinates in a Cartesian coordinate system.
2. How are Cartesian vectors represented mathematically?
Ans. Cartesian vectors are represented as ordered pairs or triplets of real numbers in a Cartesian coordinate system, where each number corresponds to the magnitude of the vector along a specific axis.
3. What are the components of a Cartesian vector?
Ans. The components of a Cartesian vector are the projections of the vector onto each of the coordinate axes in a Cartesian coordinate system. These components determine the direction and magnitude of the vector.
4. How do you add or subtract Cartesian vectors?
Ans. To add or subtract Cartesian vectors, you simply add or subtract their corresponding components along each axis. This can be done by adding or subtracting the corresponding components of the vectors separately.
5. How are Cartesian vectors used in physics and engineering?
Ans. Cartesian vectors are commonly used in physics and engineering to represent physical quantities such as force, velocity, and acceleration. They provide a convenient way to analyze and solve problems involving direction and magnitude.
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