Basics of Space Flight Units of Measure

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Units of Measure

If you don't find the term you're looking for here, look in the GLOSSARY.

In the Basics of Space Flight, most abbreviations for units of measure are not spelled out the first time they are used, unlike the way other abbreviations are. They are all listed on this page instead.

The first list contains abbreviations you'll find most frequently in the Basics of Space Flight. Below it you'll find some of the International System of Units, SI, and a link to the The National Institute of Standards for complete details. Next is a selection of formulas for converting SI to English measures, a link to a conversions engine, and a link to a comprehensive set of conversion tables.

1. Unit Abbreviations Frequently Found in the Text

AU	Astronomical Unit, a measure of distance, based on the mean sun-Earth distance. The International Astronomical Union defines the AU as the distance from the Sun at which a particle of negligible mass, in an unperturbed orbit, would have an orbital period of 365.2568983 days (a Gaussian year). The AU is thus defined as 1.4959787066E+11m (149,597,870.66 km). [More]
bps	Bits per second, a measure of data rate
c	Speed of light in a vacuum, 299,792,458 m/sec
G	Giga, a multiplier,* x10⁹ from the Latin "gigas" (giant). In the U.S., 10⁹ is a billion, while in other countries using SI, 10¹² is a billion. Giga means 10⁹ everywhere.
g	Gram, a unit of mass (see SI units below)
Hz	Hertz, the number of cycles per second
k	Kilo, a multiplier,* x10³ from the Greek "khilioi" (thousand)
LY	Light Year, a measure of distance, the distance light travels in one year; about 63,240 AU
M	Mega, a multiplier,* x10⁶ from the Greek "megas" (great)
m	Meter, a unit of length (USA spelling; elsewhere, metre) (see SI units below)
N	Newton, a unit of force (see SI units with special names, below)
s	Second, the SI unit of time (see this extensive definition)
W	Watt, a unit of power (see SI units with special names, below)

*The remaining multipliers are listed in the GLOSSARY.

2. International System of Units, SI

SI has long been the notation universally used in science and technology. It has also become the dominant language of international commerce and trade, except in the U.S.

Base quantity	Name	Symbol
	SI base unit
length	meter	m
mass	kilogram	kg
time	second	s
electric current	ampere	A
thermodynamic temperature	kelvin	K
amount of substance	mole	mol
luminous intensity	candela	cd

For a comprehensive and definitive reference on all aspects of SI, as well as many other quantities and standards, please visit the National Institute of Standards (NIST) website. Some of the information on this page has been obtained from there.

See also the Solar System Temperature Reference for examples and temperature comparisons of objects and conditions in space, from absolute zero through planet temperatures, to those of stars.

Some Derived SI Quantities

Selected from NIST website

Derived quantity	Name	Symbol
	SI derived unit
area	square meter	m²
volume	cubic meter	m³
speed, velocity	meter per second	m/s
acceleration	meter per second squared (meter per second per second)	m/s²
wave number	reciprocal meter	m^-1
mass density	kilogram per cubic meter	kg/m³
specific volume	cubic meter per kilogram	m³/kg
current density	ampere per square meter	A/m²
magnetic field strength	ampere per meter	A/m

SI Units with Special Names

Selected from NIST website

Derived quantity	Name	Symbol	Expression in terms of other SI units	Expression in terms of SI base units
	SI derived unit
plane angle	radian	rad	-	m·m^-1= 1
solid angle	steradian	sr	-	m²·m^-2= 1
frequency	hertz	Hz	-	s^-1
force	newton	N	-	m·kg·s^-2
pressure, stress	pascal	Pa	N/m²	m^-1·kg·s^-2
energy, work, quantity of heat	joule	J	N·m	m²·kg·s^-2
power, radiant flux	watt	W	J/s	m²·kg·s^-3
electric charge, quantity of electricity	coulomb	C	-	s·A
electric potential difference, electromotive force	volt	V	W/A	m²·kg·s^-3·A^-1
capacitance	farad	F	C/V	m^-2·kg^-1·s⁴·A²
electric resistance	ohm		V/A	m²·kg·s^-3·A^-2
electric conductance	siemens	S	A/V	m^-2·kg^-1·s³·A²
magnetic flux	weber	Wb	V·s	m²·kg·s^-2·A^-1
magnetic flux density	tesla	T	Wb/m²	kg·s^-2·A^-1
inductance	henry	H	Wb/A	m²·kg·s^-2·A^-2
Celsius temperature	degree Celsius	°C	-	K
luminous flux	lumen	lm	cd·sr	m²·m^-2·cd = cd
illuminance	lux	lx	lm/m²	m²·m^-4·cd = m^-2·cd

3. A Few Handy SI-to-English Conversions

Take the number of SI units and apply the conversion to get the number of English units. For example, 2 meters equals about 6.56 feet.

Millimeters to inches: mm x 0.0393700787401575 = in

Centimeters to inches: cm x 0.393700787401575 = in

Meters to feet: m x 3.28083989501312 = ft

Meters to yards: m x 1.09361329833771 = yds

Kilometers to miles: km x 0.621371192237334 = mi

Grams to ounces: g x 0.0352739907229404 = oz

Kilograms to pounds: kg x 2.20462262184878 = lbs

Celsius to Fahrenheit: (°C x 9/5) + 32 = °F

Newtons to Pounds Force: N x 0.224809024733489 = lbf

4. More Conversions

Follow this link to perform conversions in real time.

Here is a comprehensive set of conversion tables.

SECTION I
ENVIRONMENT
1 The Solar System
2 Reference Systems
3 Gravity & Mechanics
4 Trajectories
5 Planetary Orbits
6 Electromagnetics

SECTION II
FLIGHT PROJECTS
7 Mission Inception
8 Experiments
9 S/C Classification
10 Telecommunications
11 Onboard Systems
12 Science Instruments
13 Navigation

SECTION III
FLIGHT OPERATIONS
14 Launch
15 Cruise
16 Encounter
17 Extended Operations
18 Deep Space Network

Basics of Space Flight
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