1. Home
  2. Calculus volume 3
  3. Vector-valued functions
  4. Motion in space

3.4 Motion in space  (Page 46/17)

<< Chapter < Page
  Calculus volume 3     Page 1 / 17
Chapter >> Page >
  • Describe the velocity and acceleration vectors of a particle moving in space.
  • Explain the tangential and normal components of acceleration.
  • State Kepler’s laws of planetary motion.

We have now seen how to describe curves in the plane and in space, and how to determine their properties, such as arc length and curvature. All of this leads to the main goal of this chapter, which is the description of motion along plane curves and space curves. We now have all the tools we need; in this section, we put these ideas together and look at how to use them.

Motion vectors in the plane and in space

Our starting point is using vector-valued functions to represent the position of an object as a function of time. All of the following material can be applied either to curves in the plane or to space curves. For example, when we look at the orbit of the planets, the curves defining these orbits all lie in a plane because they are elliptical. However, a particle traveling along a helix moves on a curve in three dimensions.

Definition

Let r ( t ) be a twice-differentiable vector-valued function of the parameter t that represents the position of an object as a function of time. The velocity vector     v ( t ) of the object is given by

Velocity = v ( t ) = r ( t ) .

The acceleration vector     a ( t ) is defined to be

Acceleration = a ( t ) = v ( t ) = r″ ( t ) .

The speed is defined to be

Speed = v ( t ) = v ( t ) = r ( t ) = d s d t .

Since r ( t ) can be in either two or three dimensions, these vector-valued functions can have either two or three components. In two dimensions, we define r ( t ) = x ( t ) i + y ( t ) j and in three dimensions r ( t ) = x ( t ) i + y ( t ) j + z ( t ) k . Then the velocity, acceleration, and speed can be written as shown in the following table.

Formulas for position, velocity, acceleration, and speed
Quantity Two Dimensions Three Dimensions
Position r ( t ) = x ( t ) i + y ( t ) j r ( t ) = x ( t ) i + y ( t ) j + z ( t ) k
Velocity v ( t ) = x ( t ) i + y ( t ) j v ( t ) = x ( t ) i + y ( t ) j + z ( t ) k
Acceleration a ( t ) = x ( t ) i + y ( t ) j a ( t ) = x ( t ) i + y ( t ) j + z ( t ) k
Speed v ( t ) = ( x ( t ) ) 2 + ( y ( t ) ) 2 v ( t ) = ( x ( t ) ) 2 + ( y ( t ) ) 2 + ( z ( t ) ) 2

Studying motion along a parabola

A particle moves in a parabolic path defined by the vector-valued function r ( t ) = t 2 i + 5 t 2 j , where t measures time in seconds.

  1. Find the velocity, acceleration, and speed as functions of time.
  2. Sketch the curve along with the velocity vector at time t = 1 .
  1. We use [link] , [link] , and [link] :
    v ( t ) = r ( t ) = 2 t i t 5 t 2 j a ( t ) = v ( t ) = 2 i 5 ( 5 t 2 ) 3 2 j v ( t ) = r ( t ) = ( 2 t ) 2 + ( t 5 t 2 ) 2 = 4 t 2 + t 2 5 t 2 = 21 t 2 4 t 4 5 t 2 .
  2. The graph of r ( t ) = t 2 i + 5 t 2 j is a portion of a parabola ( [link] ). The velocity vector at t = 1 is
    v ( 1 ) = r ( 1 ) = 2 ( 1 ) i 1 5 ( 1 ) 2 j = 2 i 1 2 j

    and the acceleration vector at t = 1 is
    a ( 1 ) = v ( 1 ) = 2 i 5 ( 5 ( 1 ) 2 ) 3 / 2 j = 2 i 5 8 j .

    Notice that the velocity vector is tangent to the path, as is always the case.
    This figure is the graph of a curve in the first quadrant. The curve begins on the y axis slightly above y=2 and decreases to the x-axis at x=5. On the curve is a tangent vector labeled “v(1)” and is pointing towards the x-axis.
    This graph depicts the velocity vector at time t = 1 for a particle moving in a parabolic path.
Got questions? Get instant answers now!
Got questions? Get instant answers now!

A particle moves in a path defined by the vector-valued function r ( t ) = ( t 2 3 t ) i + ( 2 t 4 ) j + ( t + 2 ) k , where t measures time in seconds and where distance is measured in feet. Find the velocity, acceleration, and speed as functions of time.

v ( t ) = r ( t ) = ( 2 t 3 ) i + 2 j + k a ( t ) = v ( t ) = 2 i v ( t ) = r ( t ) = ( 2 t 3 ) 2 + 2 2 + 1 2 = 4 t 2 12 t + 14

The units for velocity and speed are feet per second, and the units for acceleration are feet per second squared.

Got questions? Get instant answers now!

Questions & Answers

1. Discuss the processes involved during exchange of fluids between intra and extracellular space.
Mustapha Reply
what are components of cells
ofosola Reply
twugzfisfjxxkvdsifgfuy7 it
Sami
58214993
Sami
what is a salt
John
the difference between male and female reproduction
John
what is computed
IBRAHIM Reply
what is biology
IBRAHIM
what is the full meaning of biology
IBRAHIM
what is biology
Jeneba
what is cell
Kuot
425844168
Sami
what is biology
Inenevwo
what is cytoplasm
Emmanuel Reply
structure of an animal cell
Arrey Reply
what happens when the eustachian tube is blocked
Puseletso Reply
what's atoms
Achol Reply
discuss how the following factors such as predation risk, competition and habitat structure influence animal's foraging behavior in essay form
Burnet Reply
cell?
Kuot
location of cervical vertebra
KENNEDY Reply
What are acid
Sheriff Reply
define biology infour way
Happiness Reply
What are types of cell
Nansoh Reply
how can I get this book
Gatyin Reply
what is lump
Chineye Reply
what is cell
Maluak Reply
what is biology
Maluak
what is vertibrate
Jeneba
Got questions? Join the online conversation and get instant answers!
Jobilize.com Reply
<< Chapter < Page Page > Chapter >>
Practice Key Terms 6

Read also:

Get Jobilize Job Search Mobile App in your pocket Now!

Get it on Google Play Download on the App Store Now




Source:  OpenStax, Calculus volume 3. OpenStax CNX. Feb 05, 2016 Download for free at http://legacy.cnx.org/content/col11966/1.2
Google Play and the Google Play logo are trademarks of Google Inc.

Notification Switch

Would you like to follow the 'Calculus volume 3' conversation and receive update notifications?

Ask