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v • d • e Quantities of bytes
SI prefixes (decimal)			IEC prefixes (binary)
	Binary usage (often with KB for kB)
Value	Name		Value	Name
10001 = 103	kilobyte	(kB)	10241 = 210 = 1.024·103	kibibyte	(KiB)
10002 = 106	megabyte	(MB)	10242 = 220 ≈ 1.049·106	mebibyte	(MiB)
10003 = 109	gigabyte	(GB)	10243 = 230 ≈ 1.074·109	gibibyte	(GiB)
10004 = 1012	terabyte	(TB)	10244 = 240 ≈ 1.100·1012	tebibyte	(TiB)
10005 = 1015	petabyte	(PB)	10245 = 250 ≈ 1.126·1015	pebibyte	(PiB)
10006 = 1018	exabyte	(EB)	10246 = 260 ≈ 1.153·1018	exbibyte	(EiB)
10007 = 1021	zettabyte	(ZB)	10247 = 270 ≈ 1.181·1021	zebibyte	(ZiB)
10008 = 1024	yottabyte	(YB)	10248 = 280 ≈ 1.209·1024	yobibyte	(YiB)

In computer science a byte (pronounced "bite", IPA: /baɪt/) is a unit of measurement of information storage, most often consisting of eight bits. In many computer architectures it is a unit of memory addressing.

Originally, a byte was a small group of bits of a size convenient for data such as a single character from a Western character set. Its size was generally determined by the number of possible characters in the supported character set and was chosen to be a submultiple of the computer's word size; historically, bytes have ranged from five to twelve bits. The popularity of IBM's System/360 architecture starting in the 1960s and the explosion of microcomputers based on 8-bit microprocessors in the 1980s has made eight bits by far the most common size for a byte. The term octet is widely used as a more precise synonym where ambiguity is undesirable (for example, in protocol definitions).

There has been considerable confusion about the meanings of SI prefixes used with the word "byte", such as kilo- (k or K) and mega- (M), as shown in the chart Quantities of bytes. Since computer memory comes in powers of 2 rather than 10, the industry used binary estimates of the SI-prefixed quantities. Because of the confusion, a contract specifying a quantity of bytes must define what the prefixes mean in terms of the contract (i.e., the alternate binary equivalents or the actual decimal values, or a binary estimate based on the actual values).

A byte is one of the basic integral data types in some programming languages, especially system programming languages.

Contents 1 Meanings 2 History 3 Alternate words 4 Abbreviation/Symbol 5 Names for different units 6 See also 7 Notes

The word "byte" has numerous closely related meanings:

1. A contiguous sequence of a fixed number of bits (binary digits). The use of a byte to mean 8 bits has become nearly ubiquitous.
2. A contiguous sequence of bits within a binary computer that comprises the smallest addressable sub-field of the computer's natural word-size. That is, the smallest unit of binary data on which meaningful computation, or natural data boundaries, could be applied. For example, the CDC 6000 series scientific mainframes divided their 60-bit floating-point words into 10 six-bit bytes. These bytes conveniently held Hollerith data from punched cards, typically the upper-case alphabet and decimal digits. CDC also often referred to 12-bit quantities as bytes, each holding two 6-bit display code characters, due to the 12-bit I/O architecture of the machine. The PDP-10 used assembly instructions LDB and DPB to extract bytes — these operations survive today in Common Lisp. Bytes of six, seven, or nine bits were used on some computers, for example within the 36-bit word of the PDP-10. The UNIVAC 1100/2200 series computers (now Unisys) addressed in both 6-bit (Fieldata) and 9-bit (ASCII) modes within its 36-bit word.

The term byte was coined by Dr. Werner Buchholz in July 1956, during the early design phase for the IBM Stretch computer.^[1][2][3] Originally it was defined in instructions by a 4-bit byte-size field, allowing from one to sixteen bits (the production design reduced this to a 3-bit byte-size field, allowing from one to eight bits in a byte); typical I/O equipment of the period used six-bit units. A fixed eight-bit byte size was later adopted and promulgated as a standard by the System/360. The term "byte" comes from "bite," as in the smallest amount of data a computer could "bite" at once. The spelling change not only reduced the chance of a "bite" being mistaken for a "bit," but also was consistent with the penchant of early computer scientists to make up words and change spellings. However, back in the 1960s, the luminaries at IBM Education Department in the UK were teaching that a bit was a Binary digIT and a byte was a BinarY TuplE (from n-tuple, i.e. [quin]tuple, [sex]tuple, [sep]tuple, [oc]tuple ...), turning "byte" into a backronym.^{[citation needed]} A byte was also often referred to as "an 8-bit byte", reinforcing the notion that it was a tuple of n bits, and that other sizes were possible.

1. A contiguous sequence of binary bits in a serial data stream, such as in modem or satellite communications, or from a disk-drive head, which is the smallest meaningful unit of data. These bytes might include start bits, stop bits, or parity bits, and thus could vary from 7 to 12 bits to contain a single 7-bit ASCII code.
2. A datatype or synonym for a datatype in certain programming languages. C and C++, for example, defines byte as "addressable unit of data storage large enough to hold any member of the basic character set of the execution environment" (clause 3.6 of the C standard). Since the C char integral data type must contain at least 8 bits (clause 5.2.4.2.1), a byte in C is at least capable of holding 256 different values (signed or unsigned char does not matter). Various implementations of C and C++ define a "byte" as 8, 9, 16, 32, or 36 bits[1][2]. The actual number of bits in a particular implementation is documented as CHAR_BIT in that implemtation's limits.h file. Java's primitive byte data type is always defined as consisting of 8 bits and being a signed data type, holding values from −128 to 127.

Early microprocessors, such as Intel 8008 (the direct predecessor of the 8080, and then 8086) could perform a small number of operations on four bits, such as the DAA (decimal adjust) instruction, and the "half carry" flag, that were used to implement decimal arithmetic routines. These four-bit quantities were called "nybbles," in homage to the then-common 8-bit "bytes."

Following "bit," "byte," and "nybble," there have been some analogical attempts to construct unambiguous terms for bit blocks of other sizes.^[4] All of these are strictly jargon, and not very common.

• 2 bits: crumb, quad, quarter, tayste, tydbit
• 4 bits: nibble, nybble
• 5 bits: nickle
• 10 bits: deckle
• 16 bits: playte, chawmp (on a 32-bit machine)
• 18 bits: chawmp (on a 36-bit machine)
• 32 bits: dynner, gawble (on a 32-bit machine)
• 48 bits: gawble (under circumstances that remain obscure)

IEEE 1541 and Metric-Interchange-Format specify "B" as the symbol for byte (e.g. MB means megabyte), whilst IEC 60027 seems silent on the subject. Furthermore, B means bel (see decibel), another (logarithmic) unit used in the same field. The use of B to stand for bel is consistent with the metric system convention that capitalized symbols are for units named after a person (in this case Alexander Graham Bell); usage of a capital B to stand for byte is not consistent with this convention. The unit symbol "kb" with a lowercase "b" is also commonly understood to stand for "kilobyte."

IEEE 1541 specifies "b" as the symbol for bit; however the IEC 60027 and Metric-Interchange-Format specify "bit" (e.g. Mbit for megabit) for the symbol, achieving maximum disambiguation from byte.

French-speaking countries sometimes use an uppercase "o" for "octet". This is not consistent with SI because of the risk of confusion with the zero, and the convention that capitals are reserved for unit names derived from proper names, e.g., A=ampere, J=joule versus s=second, m=metre.

Lowercase "o" for "octet" is a commonly used symbol in several non-English-speaking countries, and is also used with metric prefixes (for example, "ko" and "Mo").

The prefixes used for byte measurements are usually the same as the SI prefixes used for other measurements, but have slightly different values. The former are based on powers of 1,024 (2¹⁰), a convenient binary number, while the SI prefixes are based on powers of 1,000 (10³), a convenient decimal number. The table below illustrates these differences. See binary prefix for further discussion.

Prefix	Name	SI Meaning	Binary meaning	Size difference
K or k	kilo	103   = 10001	210 = 10241	2.40%
M	mega	106   = 10002	220 = 10242	4.86%
G	giga	109   = 10003	230 = 10243	7.37%
T	tera	1012 = 10004	240 = 10244	9.95%
P	peta	1015 = 10005	250 = 10245	12.59%
E	exa	1018 = 10006	260 = 10246	15.29%

In 1998, the IEC, then the IEEE, published a new standard describing binary prefixes:

Prefix	Name
Kibi	binary kilo	1 kibibyte (KiB)	210 bytes	1024 bytes
Mebi	binary mega	1 Mebibyte (MiB)	220 bytes	1024 KiB
Gibi	binary giga	1 Gibibyte (GiB)	230 bytes	1024 MiB
Tebi	binary tera	1 Tebibyte (TiB)	240 bytes	1024 GiB
Pebi	binary peta	1 Pebibyte (PiB)	250 bytes	1024 TiB
Exbi	binary exa	1 Exbibyte (EiB)	260 bytes	1024 PiB

Fractional information is usually measured in bits, nibbles, nats, or bans, where the later two are used especially in the context of information theory and not generally with computing in general.

• Bit
• Word (computing)