# ISO 216

C Series | |
---|---|

C0 | 917 × 1297 |

C1 | 648 × 917 |

C2 | 458 × 648 |

C3 | 324 × 458 |

C4 | 229 × 324 |

C5 | 162 × 229 |

C6 | 114 × 162 |

C7/6 | 81 × 162 |

C7 | 81 × 114 |

C8 | 57 × 81 |

C9 | 40 × 57 |

C10 | 28 × 40 |

DL | 110 × 220 |

A Series | B Series | |||
---|---|---|---|---|

A0 | 841 × 1189 | B0 | 1000 × 1414 | |

A1 | 594 × 841 | B1 | 707 × 1000 | |

A2 | 420 × 594 | B2 | 500 × 707 | |

A3 | 297 × 420 | B3 | 353 × 500 | |

A4 | 210 × 297 | B4 | 250 × 353 | |

A5 | 148 × 210 | B5 | 176 × 250 | |

A6 | 105 × 148 | B6 | 125 × 176 | |

A7 | 74 × 105 | B7 | 88 × 125 | |

A8 | 52 × 74 | B8 | 62 × 88 | |

A9 | 37 × 52 | B9 | 44 × 62 | |

A10 | 26 × 37 | B10 | 31 × 44 |

**ISO 216** specifies international standard (ISO) paper sizes used in most countries in the world today. The standard defines the "A" and "B" series of paper sizes, including A4, the most commonly available size. Two supplementary standards, ISO 217 and ISO 269, define related paper sizes; the ISO 269 "C" series is commonly listed alongside the A and B sizes.

All ISO 216, ISO 217 and ISO 269 paper sizes (except DL) have the same aspect ratio, 1:√2, at least to within the rounding to whole numbers of millimetres. This ratio has the unique property that when cut or folded in half widthwise, the halves also have the same aspect ratio. Each ISO paper size is one half of the area of the next larger size.

## Contents

## History

The advantages of basing a paper size upon an aspect ratio of √2 were already noted in 1786 by the German scientist Georg Christoph Lichtenberg, in a letter to Johann Beckmann.^{[1]} The formats that became A2, A3, B3, B4 and B5 were developed in France, and published in 1798 during the French Revolution.^{[2]}

Early in the twentieth century, Dr Walter Porstmann turned Lichtenberg's idea into a proper system of different paper sizes. Porstmann's system was introduced as a DIN standard (DIN 476) in Germany in 1922, replacing a vast variety of other paper formats. Even today the paper sizes are called "DIN A*x*" in everyday use in Germany, Austria, Spain and Portugal.

The main advantage of this system is its scaling: if a sheet with an aspect ratio of √2 is divided into two equal halves parallel to its shortest sides, then the halves will again have an aspect ratio of √2. Folded brochures of any size can be made by using sheets of the next larger size, e.g. A4 sheets are folded to make A5 brochures. The system allows scaling without compromising the aspect ratio from one size to another – as provided by office photocopiers, e.g. enlarging A4 to A3 or reducing A3 to A4. Similarly, two sheets of A4 can be scaled down to fit exactly one A4 sheet without any cutoff or margins.

The weight of each sheet is also easy to calculate given the basis weight in grams per square metre (g/m^{2} or "gsm"). Since an A0 sheet has an area of 1 m^{2}, its weight in grams is the same as its basis weight in g/m^{2}. A standard A4 sheet made from 80 g/m^{2} paper weighs 5 g, as it is ^{1}⁄_{16} (four halvings) of an A0 page. Thus the weight, and the associated postage rate, can be easily calculated by counting the number of sheets used.

ISO 216 and its related standards were first published between 1975 and 1995:

- ISO 216:2007, defining the A and B series of paper sizes
- ISO 269:1985, defining the C series for envelopes
- ISO 217:2013, defining the RA and SRA series of raw ("untrimmed") paper sizes

## A series

Paper in the A series format has a 1:√2 ≈ 1.414 aspect ratio, although this is rounded to the nearest millimetre. A0 is defined so that it has an area of 1 square metre, prior to the rounding. Successive paper sizes in the series (A1, A2, A3, etc.) are defined by halving the preceding paper size, cutting parallel to its shorter side so that the long side of A(*n* + 1) is the same length as the short side of A*n* prior to rounding.

The most frequently used of this series is the size A4 which is 210 mm × 297 mm (8.27 in × 11.7 in). For comparison, the letter paper size commonly used in North America (8.5 in × 11 in (216 mm × 279 mm)) is approximately 6 mm (0.24 in) wider and 18 mm (0.71 in) shorter than A4.

The geometric rationale behind the square root of 2 is to maintain the aspect ratio of each subsequent rectangle after cutting or folding an A series sheet in half, perpendicular to the larger side. Given a rectangle with a longer side, *x*, and a shorter side, *y*, ensuring that its aspect ratio, <templatestyles src="Sfrac/styles.css" />*x*/*y*, will be the same as that of a rectangle half its size, <templatestyles src="Sfrac/styles.css" />*y*/*x*/2, means that <templatestyles src="Sfrac/styles.css" />*x*/*y* = <templatestyles src="Sfrac/styles.css" />*y*/*x*/2, which reduces to <templatestyles src="Sfrac/styles.css" />*x*/*y* = √2; in other words, an aspect ratio of 1:√2.

The formula that gives the larger border of the paper size A*n* in metres and without rounding off is the geometric sequence: . The paper size A*n* thus has the dimension *a*_{n} × *a*_{n + 1} and area (prior to rounding off) 2^{−n} m^{2}.

The exact millimetre measurement of the long side of A*n* is given by , in which the modified brackets represent the floor function.

## B series

The B series is defined in the standard as follows: "A subsidiary series of sizes is obtained by placing the geometrical means between adjacent sizes of the A series in sequence." The use of the geometric mean means that each step in size: B0, A0, B1, A1, B2 … is smaller than the previous by an equal scaling. As with the A series, the lengths of the B series have the ratio 1:√2, and folding one in half gives the next in the series. The shorter side of B0 is exactly 1 metre.

There is also an incompatible Japanese B series which the JIS defines to have 1.5 times the area of the corresponding JIS A series (which is identical to the ISO A series).^{[3]} Thus, the lengths of JIS B series paper are √1.5 ≈ 1.22 times those of A-series paper. By comparison, the lengths of ISO B series paper are ^{4}√2 ≈ 1.19 times those of A-series paper.

For the ISO B series, the exact millimetre measurement of the long side of B*n* is given by .

## C series

The C series formats are geometric means between the B series and A series formats with the same number (e.g., C2 is the geometric mean between B2 and A2). The width to height ratio is as in the A and B series. The C series formats are used mainly for envelopes. An A4 page will fit into a C4 envelope. C series envelopes follow the same ratio principle as the A series pages. For example, if an A4 page is folded in half so that it is A5 in size, it will fit into a C5 envelope (which will be the same size as a C4 envelope folded in half). The lengths of ISO C series paper are therefore ^{8}√2 times those of A-series paper – i.e., about 9% larger.

A, B, and C paper fit together as part of a geometric progression, with ratio of successive side lengths of ^{8}√2, though there is no size half-way between B*n* and A(*n* − 1): A4, C4, B4, "D4", A3, …; there is such a D-series in the Swedish extensions to the system.

The exact millimetre measurement of the long side of C*n* is given by .

## Tolerances

The tolerances specified in the standard are:

- ±1.5 mm for dimensions up to 150 mm,
- ±2.0 mm for dimensions in the range 150 to 600 mm, and
- ±3.0 mm for dimensions above 600 mm.

## A, B, C comparison

Size | A series formats | B series formats | C series formats | |||
---|---|---|---|---|---|---|

(mm) | (in) | (mm) | (in) | (mm) | (in) | |

0 | 841 × 1189 | 33.1 × 46.8 | 1000 × 1414 | 39.4 × 55.7 | 917 × 1297 | 36.1 × 51.1 |

1 | 594 × 841 | 23.4 × 33.1 | 707 × 1000 | 27.8 × 39.4 | 648 × 917 | 25.5 × 36.1 |

2 | 420 × 594 | 16.5 × 23.4 | 500 × 707 | 19.7 × 27.8 | 458 × 648 | 18.0 × 25.5 |

3 | 297 × 420 | 11.7 × 16.5 | 353 × 500 | 13.9 × 19.7 | 324 × 458 | 12.8 × 18.0 |

4 | 210 × 297 | 8.3 × 11.7 | 250 × 353 | 9.8 × 13.9 | 229 × 324 | 9.0 × 12.8 |

5 | 148 × 210 | 5.8 × 8.3 | 176 × 250 | 6.9 × 9.8 | 162 × 229 | 6.4 × 9.0 |

6 | 105 × 148 | 4.1 × 5.8 | 125 × 176 | 4.9 × 6.9 | 114 × 162 | 4.5 × 6.4 |

7 | 74 × 105 | 2.9 × 4.1 | 88 × 125 | 3.5 × 4.9 | 81 × 114 | 3.2 × 4.5 |

8 | 52 × 74 | 2.0 × 2.9 | 62 × 88 | 2.4 × 3.5 | 57 × 81 | 2.2 × 3.2 |

9 | 37 × 52 | 1.5 × 2.0 | 44 × 62 | 1.7 × 2.4 | 40 × 57 | 1.6 × 2.2 |

10 | 26 × 37 | 1.0 × 1.5 | 31 × 44 | 1.2 × 1.7 | 28 × 40 | 1.1 × 1.6 |

## Application

The ISO 216 formats are organized around the ratio 1:√2; two sheets next to each other together have the same ratio, sideways. In scaled photocopying, for example, two A4 sheets reduced to A5 size fit exactly onto one A4 sheet, and an A4 sheet in magnified size onto an A3 sheet; in each case, there is neither waste nor want.

The principal countries not generally using the ISO paper sizes are the United States and Canada, which use the Letter, Legal and Executive system. Although they have also officially adopted the ISO 216 paper format, Mexico, Panama, Venezuela, Colombia, the Philippines, and Chile also use mostly U.S. paper sizes.

Rectangular sheets of paper with the ratio 1:√2 are popular in paper folding, such as origami, where they are sometimes called "A4 rectangles" or "silver rectangles".^{[4]} In other contexts, the term "silver rectangle" can also refer to a rectangle in the proportion 1:(1 + √2), known as the silver ratio.

## See also

- ANSI/ASME Y14.1
- International standard envelope sizes
- ISO 128 (relating to technical drawing)
- Letter (paper size)
- Metric Pixel Canvas
- Paper density
- Paper size

## References

## External links

Wikimedia Commons has media related to .DIN EN ISO 216 |

- International standard paper sizes: ISO 216 details and rationale
- ISO 216 at iso.org