Speed

Speed can be thought of as the rate at which an object covers distance. A fastmoving object has a high speed and covers a relatively large distance in a given amount of time, while a slowmoving object covers a relatively small amount of distance in the same amount of time.

Common symbols

v

SI unit

m/s, m s^{−1}

In everyday use and in kinematics, the speed of an object is the magnitude of its velocity (the rate of change of its position); it is thus a scalar quantity.^{[1]} The average speed of an object in an interval of time is the distance travelled by the object divided by the duration of the interval;^{[2]} the instantaneous speed is the limit of the average speed as the duration of the time interval approaches zero.
Like velocity, speed has the dimensions of a length divided by a time; the SI unit of speed is the metre per second, but the most usual unit of speed in everyday usage is the kilometre per hour or, in the US and the UK, miles per hour. For air and marine travel the knot is commonly used.
The fastest possible speed at which energy or information can travel, according to special relativity, is the speed of light in a vacuum c = 299792458. metres per second (approximately 1079000000. km/h or 671000000. mph). Matter cannot quite reach the speed of light, as this would require an infinite amount of energy. In relativity physics, the concept of rapidity replaces the classical idea of speed.
Definition
The Italian physicist Galileo Galilei is credited with being the first to measure speed by considering the distance covered and the time it takes. Galileo defined speed as the distance covered per unit of time.^{[3]} In equation form, this is

v = \frac{d}{t},
where v is speed, d is distance, and t is time. A cyclist who covers 30 metres in a time of 2 seconds, for example, has a speed of 15 metres per second. Objects in motion often have variations in speed (a car might travel along a street at 50 km/h, slow to 0 km/h, and then reach 30 km/h).
In mathematical terms, the speed v is defined as the magnitude of the velocity \boldsymbol{v}, that is, the derivative of the position \boldsymbol{r} with respect to time:

v = \left\boldsymbol v\right = \left\dot {\boldsymbol r}\right = \left\frac{d\boldsymbol r}{dt}\right\,.
If s is the length of the path travelled until time t, the speed equals the time derivative of s:

v = \frac{ds}{dt}.
In the special case where the velocity is constant (that is, constant speed in a straight line), this can be simplified to v=s/t. The average speed over a finite time interval is the total distance travelled divided by the time duration.
Instantaneous speed
By looking at a speedometer, one can read the speed of a car at any instant, or its instantaneous speed.^{[3]} A car travelling at 50 km/h generally goes for less than one hour at a constant speed, but if it did go at that speed for a full hour, it would travel 50 km. If the vehicle continued at that speed for half an hour, it would cover half that distance (25 km). If it continued for only one minute, it would cover about 833 m.
Average speed
Different from instantaneous speed, average speed is defined as the total distance covered over the time interval. For example, if a distance of 80 kilometres is driven in 1 hour, the average speed is 80 kilometres per hour. Likewise, if 320 kilometres are travelled in 4 hours, the average speed is also 80 kilometres per hour. When a distance in kilometres (km) is divided by a time in hours (h), the result is in kilometres per hour (km/h). Average speed does not describe the speed variations that may have taken place during shorter time intervals (as it is the entire distance covered divided by the total time of travel), and so average speed is often quite different from a value of instantaneous speed.^{[3]} If the average speed and the time of travel are known, the distance travelled can be calculated by rearranging the definition to

d = \boldsymbol{\bar{v}}t\,.
Using this equation for an average speed of 80 kilometres per hour on a 4hour trip, the distance covered is found to be 320 kilometres.
Expressed in graphical language, the slope of a tangent line at any point of a distancetime graph is the instantaneous speed at this point, while the slope of a chord line of the same graph is the average speed during the time interval covered by the chord.
Tangential speed
Linear speed is the distance traveled per unit of time, while tangential speed (or tangential velocity) is the linear speed of something moving along a circular path.^{[4]} A point on the outside edge of a merrygoround or turntable travels a greater distance in one complete rotation than a point nearer the center. Travelling a greater distance in the same time means a greater speed, and so linear speed is greater on the outer edge of a rotating object than it is closer to the axis. This speed along a circular path is known as tangential speed because the direction of motion is tangent to the circumference of the circle. For circular motion, the terms linear speed and tangential speed are used interchangeably, and both use units of m/s, km/h, and others.
Rotational speed (or angular speed) involves the number of revolutions per unit of time. All parts of a rigid merrygoround or turntable turn about the axis of rotation in the same amount of time. Thus, all parts share the same rate of rotation, or the same number of rotations or revolutions per unit of time. It is common to express rotational rates in revolutions per minute (RPM) or in terms of the number of "radians" turned in a unit of time. There are little more than 6 radians in a full rotation (2π radians exactly). When a direction is assigned to rotational speed, it is known as rotational velocity or angular velocity. Rotational velocity is a vector whose magnitude is the rotational speed.
Tangential speed and rotational speed are related: the greater the RPMs, the larger the speed in metres per second. Tangential speed is directly proportional to rotational speed at any fixed distance from the axis of rotation.^{[4]} However, tangential speed, unlike rotational speed, depends on radial distance (the distance from the axis). For a platform rotating with a fixed rotational speed, the tangential speed in the centre is zero. Towards the edge of the platform the tangential speed increases proportional to the distance from the axis.^{[5]} In equation form:

v \propto \!\, r \omega\,,
where v is tangential speed and ω (Greek letter omega) is rotational speed. One moves faster if the rate of rotation increases (a larger value for ω), and one also moves faster if movement farther from the axis occurs (a larger value for r). Move twice as far from the rotational axis at the centre and you move twice as fast. Move out three times as far and you have three times as much tangential speed. In any kind of rotating system, tangential speed depends on how far you are from the axis of rotation.
When proper units are used for tangential speed v, rotational speed ω, and radial distance r, the direct proportion of v to both r and ω becomes the exact equation

v = r\omega\,.
Thus, tangential speed will be directly proportional to r when all parts of a system simultaneously have the same ω, as for a wheel, disk, or rigid wand. (The direct proportionality of v to r is not valid for planets, because planets have different rotational speeds).
Units
Units of speed include:
Conversions between common units of speed

m/s

km/h

mph

knot

ft/s

1 m/s =

1

3.6

2.236936

1.943844

3.280840

1 km/h =

0.277778

1

0.621371

0.539957

0.911344

1 mph =

0.44704

1.609344

1

0.868976

1.466667

1 knot =

0.514444

1.852

1.150779

1

1.687810

1 ft/s =

0.3048

1.09728

0.681818

0.592484

1

(Values in
bold face are exact.)
Examples of different speeds
Speed

m/s

ft/s

km/h

mph

Notes

Approximate rate of continental drift

0.00000001

0.00000003

0.00000004

0.00000002

4 cm/year. Varies depending on location.

Speed of a common snail

0.001

0.003

0.004

0.002

1 millimetre per second

A brisk walk

1.7

5.5

6.1

3.8


A typical road cyclist

4.4

14.4

16

10

Varies widely by person, terrain, bicycle, effort, weather

A fast martial arts kick

7.7

25.2

27.7

17.2

Fastest kick recorded at 130 milliseconds from floor to target at 1 meter distance. Average velocity speed across kick duration^{[6]}

Sprint runners

12.2

40

43.92

27

Usain Bolt's 100 metre record.

Approximate average speed of road cyclists

12.5

41.0

45

28

On flat terrain, will vary

Typical suburban speed limit in most of the world

13.8

45.3

50

30


Taipei 101 observatory elevator

16.7

54.8

60.6

37.6

1010 m/min

Typical rural speed limit

24.6

80.66

88.5

56


British National Speed Limit (single carriageway)

26.8

88

96.56

60


Category 1 hurricane

33

108

119

74

Minimum sustained speed over 1 minute

Speed limit on a French autoroute

36.1

118

130

81


Highest recorded humanpowered speed

37.02

121.5

133.2

82.8

Sam Whittingham in a recumbent bicycle^{[7]}

Muzzle velocity of a paintball marker

90

295

320

200


Cruising speed of a Boeing 7478 passenger jet

255

836

917

570

Mach 0.85 at 35000 ft (10668 m) altitude

The official land speed record

341.1

1119.1

1227.98

763


The speed of sound in dry air at sealevel pressure and 20 °C

343

1125

1235

768

Mach 1 by definition. 20 °C = 293.15 kelvins.

Muzzle velocity of an AK47 assault rifle bullet

710

2330

2600

1600


Official flight airspeed record for jet engined aircraft

980

3215

3530

2194

Lockheed SR71 Blackbird

Space shuttle on reentry

7800

25600

28000

17,500


Escape velocity on Earth

11200

36700

40000

25000

11.2 km·s^{1}

Voyager 1 relative velocity to the Sun in 2013

17000

55800

61200

38000

Fastest heliocentric recession speed of any humanmade object.^{[8]} (11 mi/s)

Average orbital speed of planet Earth around the Sun

29783

97713

107218

66623


Speed of light in vacuum (symbol c)

299792458.

983571056.

1079252848.

670616629.

Exactly 299792458. m/s, by definition of the metre

Vehicles often have a speedometer to measure the speed they are moving.
See also
References

^ Wilson, Edwin Bidwell (1901). Vector analysis: a textbook for the use of students of mathematics and physics, founded upon the lectures of J. Willard Gibbs. p. 125. This is the likely origin of the speed/velocity terminology in vector physics.

^ "Speed & Velocity".

^ ^{a} ^{b} ^{c} Hewitt (2006), p. 42

^ ^{a} ^{b} Hewitt (2006), p. 131

^ Hewitt (2006), p. 132

^ http://www.kickspeed.com.au/Improvemeasurekickingspeed.html

^ http://www.wisil.recumbents.com/wisil/whpsc2009/results.htm

^ Darling, David. "Fastest Spacecraft". Retrieved August 19, 2013.


Linear/translational quantities


Angular/rotational quantities

time: t
s



time: t
s




displacement, position: x
m



angular displacement, angle: θ
(rad)


frequency: f
s^{−1}, Hz

speed: v, velocity: v
ms^{−1}


frequency: f
s^{−1}, Hz

angular velocity: ω
(rad)s^{−1}



acceleration: a
ms^{−2}



angular acceleration: α
(rad)s^{−2}



jerk: j
ms^{−3}



angular jerk: ζ
(rad)s^{−3}








mass: m
kg



moment of inertia: I
kgm^{2}(rad^{−2})




momentum: p, impulse: J
kgms^{−1}, Ns



angular momentum: L, angular impulse: ΔL
kgm^{2}s^{−1}(rad^{−1})



force: F, weight: F_{g}
kgms^{−2}, N

energy: E, work: W
kgm^{2}s^{−2}, J


torque: τ, moment: M
kgm^{2}s^{−2}(rad^{−1}), Nm

energy: E, work: W
kgm^{2}s^{−2}, J


yank: Y
kgms^{−3}, Ns^{−1}

power: P
kgm^{2}s^{−3}, W


rotatum: P
kgm^{2}s^{−3}(rad^{−1})

power: P
kgm^{2}s^{−3}, W



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