vector area

Examples of vector area in the following topics:

• Scalars vs. Vectors

  • Vectors require both a magnitude and a direction.
  • The magnitude of a vector is a number for comparing one vector to another.
  • In the geometric interpretation of a vector the vector is represented by an arrow.
  • Some examples of these are: mass, height, length, volume, and area.
  • An example of a vector.

• Flow Rate and Velocity

  • In mathematical terms, the velocity of a fluid is the derivative of the position vector of the fluid with respect to time, and is therefore itself a vector quantity.
  • The velocity vector has non-zero components in any orthogonal direction along which motion of the fluid occurs.
  • Qualitatively, Figure 1 shows the notion of volumetric flow rate regarding a cross-sectional surface of area A.
  • If the surface area in question is a flat, plane cross-section, the surface integral reduces as shown in Equation 2 , where A is the surface area of the surface in question and v is the flow velocity of the fluid.
  • Thus, volumetric flow rate for a given fluid velocity and cross-sectional surface area increases as θ decreases, and is maximized when θ = 0.

• Components of a Vector

  • All vectors have a length, called the magnitude, which represents some quality of interest so that the vector may be compared to another vector.
  • Vectors, being arrows, also have a direction.
  • To visualize the process of decomposing a vector into its components, begin by drawing the vector from the origin of a set of coordinates.
  • This is the horizontal component of the vector.
  • He also uses a demonstration to show the importance of vectors and vector addition.

• Adding and Subtracting Vectors Graphically

  • Draw a new vector from the origin to the head of the last vector.
  • Since vectors are graphical visualizations, addition and subtraction of vectors can be done graphically.
  • This new line is the vector result of adding those vectors together.
  • Then, to subtract a vector, proceed as if adding the opposite of that vector.
  • Draw a new vector from the origin to the head of the last vector.

• Matter Exists in Space and Time

  • $(A - B)^2 = A^2 -2AB + B^2$: The areas of plane figures equal the sum of the areas of their parts.
  • Logically a beginning knowledge of vectors, vectors spaces and vector algebra is needed to understand his ideas.
  • Ladder Boom Rescue: Vector analysis is methodological.
  • Every vector has a component and a magnitude-direction form.
  • Newton used vectors and calculus because he needed that mathematics.

• Multiplying Vectors by a Scalar

  • Multiplying a vector by a scalar changes the magnitude of the vector but not the direction.
  • A scalar, however, cannot be multiplied by a vector.
  • To multiply a vector by a scalar, simply multiply the similar components, that is, the vector's magnitude by the scalar's magnitude.
  • Most of the units used in vector quantities are intrinsically scalars multiplied by the vector.
  • (i) Multiplying the vector $A$ by the scalar $a=0.5$ yields the vector $B$ which is half as long.

• Unit Vectors and Multiplication by a Scalar

  • In addition to adding vectors, vectors can also be multiplied by constants known as scalars.
  • When multiplying a vector by a scalar, the direction of the vector is unchanged and the magnitude is multiplied by the magnitude of the scalar .
  • Once you have the vector's components, multiply each of the components by the scalar to get the new components and thus the new vector.
  • A useful concept in the study of vectors and geometry is the concept of a unit vector.
  • A unit vector is a vector with a length or magnitude of one.

• Adding and Subtracting Vectors Using Components

  • Another way of adding vectors is to add the components.
  • If we were to add this to another vector of the same magnitude and direction, we would get a vector twice as long at the same angle.
  • This new line is the resultant vector.
  • Vector Addition Lesson 2 of 2: How to Add Vectors by Components
  • This video gets viewers started with vector addition using a mathematical approach and shows vector addition by components.

• Electric Field Lines: Multiple Charges

  • Electric fields created by multiple charges interact as do any other type of vector field; their forces can be summed.
  • More field lines per unit area perpendicular to the lines means a stronger field.
  • As vector fields, electric fields exhibit properties typical of vectors and thus can be added to one another at any point of interest.
  • Thus, given charges q1, q2 ,... qn, one can find their resultant force on a test charge at a certain point using vector addition: adding the component vectors in each direction and using the inverse tangent function to solve for the angle of the resultant relative to a given axis.

• Introduction to Scalars and Vectors

  • Given this information, is speed a scalar or a vector quantity?
  • Displacement is an example of a vector quantity.
  • In mathematics, physics, and engineering, a vector is a geometric object that has a magnitude (or length) and direction and can be added to other vectors according to vector algebra.
  • (A comparison of scalars vs. vectors is shown in . )
  • He also uses a demonstration to show the importance of vectors and vector addition.