A Venn diagram may also be called a set diagram or logic diagram. It is a diagram that shows all possible logical relations between a finite collection of different sets. These diagrams depict elements as points in the plane, and sets as regions inside closed curves. A Venn diagram consists of multiple overlapping closed curves, usually circles, each representing a set. The points inside a curve labelled S represent elements of the set S, while points outside the boundary represent elements not in the set S. This lends itself to intuitive visualizations; for example, the set of all elements that are members of both sets S and T, denoted S ∩ T and read "the intersection of S and T", is represented visually by the area of overlap of the regions S and T.^[1]

In Venn diagrams, the curves are overlapped in every possible way, showing all possible relations between the sets. They are thus a special case of Euler diagrams, which do not necessarily show all relations. Venn diagrams were conceived around 1880 by John Venn. They are used to teach elementary set theory, as well as illustrate simple set relationships in probability, logic, statistics, linguistics, and computer science.

A Venn diagram in which the area of each shape is proportional to the number of elements it contains is called an area-proportional (or scaled) Venn diagram.

This example involves two sets of creatures, represented here as colored circles. The orange circle represents all types of creatures that have two legs. The blue circle represents creatures that can fly. Each separate type of creature can be imagined as a point somewhere in the diagram. Living creatures that have two legs and can fly—for example, parrots—are then in both sets, so they correspond to points in the region where the blue and orange circles overlap. This overlapping region would only contain those elements (in this example, creatures) that are members of both the orange set (two-legged creatures) and the blue set (flying creatures).

Humans and penguins are bipedal, and so are in the orange circle, but since they cannot fly, they appear in the left part of the orange circle, where it does not overlap with the blue circle. Mosquitoes can fly, but have six, not two, legs, so the point for mosquitoes is in the part of the blue circle that does not overlap with the orange one. Creatures that are neither two-legged nor able to fly (for example, whales and spiders) would all be represented by points outside both circles.

The combined region of the two sets is called their union, denoted by A ∪ B, where A is the orange circle and B the blue.^[2] The union in this case contains all living creatures that either are two-legged or can fly (or both). The region included in both A and B, where the two sets overlap, is called the intersection of A and B, denoted by A ∩ B.^[2]

Venn diagrams were introduced in 1880 by John Venn in a paper entitled "On the Diagrammatic and Mechanical Representation of Propositions and Reasonings"^[3] in the Philosophical Magazine and Journal of Science,^[4] about the different ways to represent propositions by diagrams.^[5][6][7] The use of these types of diagrams in formal logic, according to Frank Ruskey and Mark Weston, predates Venn but are "rightly associated" with him as he "comprehensively surveyed and formalized their usage, and was the first to generalize them".^[8]

Venn diagrams are very similar to Euler diagrams, which were invented by Leonhard Euler in the 18th century.^{[note 1][9][10]} Margaret Baron has noted that Leibniz (1646–1716) produced similar diagrams before Euler in the 17th century, but much of it was unpublished.^[11] She also observes even earlier Euler-like diagrams by Ramon Llull in the 13th Century.^[12]

Venn did not use the term "Venn diagram" and referred to the concept as "Eulerian Circles".^[7] He became acquainted with Euler diagrams in 1862 and wrote that Venn diagrams did not occur to him "till much later", while attempting to adapt Euler diagrams to Boolean logic.^[13] In the opening sentence of his 1880 article Venn wrote that Euler diagrams were the only diagrammatic representation of logic to gain "any general acceptance".^[5][6]

Venn viewed his diagrams as a pedagogical tool, analogous to verification of physical concepts through experiment. As an example of their applications, he noted that a three-set diagram could show the syllogism: 'All A is some B. No B is any C. Hence, no A is any C.'^[13]

Charles L. Dodgson (Lewis Carroll) includes "Venn's Method of Diagrams" as well as "Euler's Method of Diagrams" in an "Appendix, Addressed to Teachers" of his book Symbolic Logic (4th edition published in 1896). The term "Venn diagram" was later used by Clarence Irving Lewis in 1918, in his book A Survey of Symbolic Logic.^[8][14]

In the 20th century, Venn diagrams were further developed. David Wilson Henderson showed, in 1963, that the existence of an n-Venn diagram with n-fold rotational symmetry implied that n was a prime number.^[15] He also showed that such symmetric Venn diagrams exist when n is five or seven. In 2002, Peter Hamburger found symmetric Venn diagrams for n = 11 and in 2003, Griggs, Killian, and Savage showed that symmetric Venn diagrams exist for all other primes. These combined results show that rotationally symmetric Venn diagrams exist, if and only if n is a prime number.^[16]

Venn diagrams and Euler diagrams were incorporated as part of instruction in set theory, as part of the new math movement in the 1960s. Since then, they have also been adopted in the curriculum of other fields such as reading.^[17]

A Venn diagram is constructed with a collection of simple closed curves drawn in a plane. According to Lewis,^[14] the "principle of these diagrams is that classes [or sets] be represented by regions in such relation to one another that all the possible logical relations of these classes can be indicated in the same diagram. That is, the diagram initially leaves room for any possible relation of the classes, and the actual or given relation, can then be specified by indicating that some particular region is null or is not-null".^[14]: 157

Venn diagrams normally comprise overlapping circles. The interior of the circle symbolically represents the elements of the set, while the exterior represents elements that are not members of the set. For instance, in a two-set Venn diagram, one circle may represent the group of all wooden objects, while the other circle may represent the set of all tables. The overlapping region, or intersection, would then represent the set of all wooden tables. Shapes other than circles can be employed as shown below by Venn's own higher set diagrams. Venn diagrams do not generally contain information on the relative or absolute sizes (cardinality) of sets. That is, they are schematic diagrams generally not drawn to scale.

Venn diagrams are similar to Euler diagrams. However, a Venn diagram for n component sets must contain all 2ⁿ hypothetically possible zones, that correspond to some combination of inclusion or exclusion in each of the component sets.^[18] Euler diagrams contain only the actually possible zones in a given context. In Venn diagrams, a shaded zone may represent an empty zone, whereas in an Euler diagram, the corresponding zone is missing from the diagram. For example, if one set represents dairy products and another cheeses, the Venn diagram contains a zone for cheeses that are not dairy products. Assuming that in the context cheese means some type of dairy product, the Euler diagram has the cheese zone entirely contained within the dairy-product zone—there is no zone for (non-existent) non-dairy cheese. This means that as the number of contours increases, Euler diagrams are typically less visually complex than the equivalent Venn diagram, particularly if the number of non-empty intersections is small.^[19]

The difference between Euler and Venn diagrams can be seen in the following example. Take the three sets:

• ${\displaystyle A=\{1,\,2,\,5\}}$ 
• ${\displaystyle B=\{1,\,6\}}$ 
• ${\displaystyle C=\{4,\,7\}}$ 

The Euler and the Venn diagram of those sets are:

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  Euler diagram

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  Venn diagram

Venn diagrams typically represent two or three sets, but there are forms that allow for higher numbers. Shown below, four intersecting spheres form the highest order Venn diagram that has the symmetry of a simplex and can be visually represented. The 16 intersections correspond to the vertices of a tesseract (or the cells of a 16-cell, respectively).

For higher numbers of sets, some loss of symmetry in the diagrams is unavoidable. Venn was keen to find "symmetrical figures ... elegant in themselves,"^[9] that represented higher numbers of sets, and he devised an elegant four-set diagram using ellipses (see below). He also gave a construction for Venn diagrams for any number of sets, where each successive curve that delimits a set interleaves with previous curves, starting with the three-circle diagram.

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  Venn's construction for four sets (use Gray code to compute, the digit 1 means in the set, and the digit 0 means not in the set)

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  Venn's construction for five sets

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  Venn's construction for six sets

•  

  Venn's four-set diagram using ellipses

•  

  Non-example: This Euler diagram is not a Venn diagram for four sets as it has only 14 regions as opposed to 2⁴ = 16 regions (including the white region); there is no region where only the yellow and blue, or only the red and green circles meet.

•  

  Five-set Venn diagram using congruent ellipses in a five-fold rotationally symmetrical arrangement devised by Branko Grünbaum. Labels have been simplified for greater readability; for example, A denotes A ∩ B^c ∩ C^c ∩ D^c ∩ E^c, while BCE denotes A^c ∩ B ∩ C ∩ D^c ∩ E.

•  

  Six-set Venn diagram made of only triangles (interactive version)

Edwards–Venn diagrams

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  Three sets

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  Four sets

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  Five sets

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  Six sets

Anthony William Fairbank Edwards constructed a series of Venn diagrams for higher numbers of sets by segmenting the surface of a sphere, which became known as Edwards–Venn diagrams.^[20] For example, three sets can be easily represented by taking three hemispheres of the sphere at right angles (x = 0, y = 0 and z = 0). A fourth set can be added to the representation, by taking a curve similar to the seam on a tennis ball, which winds up and down around the equator, and so on. The resulting sets can then be projected back to a plane, to give cogwheel diagrams with increasing numbers of teeth—as shown here. These diagrams were devised while designing a stained-glass window in memory of Venn.^[20]

Other diagrams

Edwards–Venn diagrams are topologically equivalent to diagrams devised by Branko Grünbaum, which were based around intersecting polygons with increasing numbers of sides. They are also two-dimensional representations of hypercubes.

Henry John Stephen Smith devised similar n-set diagrams using sine curves^[20] with the series of equations

Charles Lutwidge Dodgson (also known as Lewis Carroll) devised a five-set diagram known as Carroll's square. Joaquin and Boyles, on the other hand, proposed supplemental rules for the standard Venn diagram, in order to account for certain problem cases. For instance, regarding the issue of representing singular statements, they suggest to consider the Venn diagram circle as a representation of a set of things, and use first-order logic and set theory to treat categorical statements as statements about sets. Additionally, they propose to treat singular statements as statements about set membership. So, for example, to represent the statement "a is F" in this retooled Venn diagram, a small letter "a" may be placed inside the circle that represents the set F.^[21]

Venn diagrams correspond to truth tables for the propositions ${\displaystyle x\in A}$ , ${\displaystyle x\in B}$ , etc., in the sense that each region of Venn diagram corresponds to one row of the truth table.^[22][23] This type is also known as Johnston diagram. Another way of representing sets is with John F. Randolph's R-diagrams.

• Existential graph (by Charles Sanders Peirce)
• Logical connectives
• Information diagram
• Marquand diagram (and as further derivation Veitch chart and Karnaugh map)
• Spherical octahedron – A stereographic projection of a regular octahedron makes a three-set Venn diagram, as three orthogonal great circles, each dividing space into two halves.
• Stanhope Demonstrator
• Three circles model
• Triquetra
• Vesica piscis

• Mahmoodian, Ebadollah S.; Rezaie, M.; Vatan, F. (March 1987). (PDF). Eighteenth Annual Iranian Mathematics Conference. Tehran and Isfahan, Iran. Archived from the original (PDF) on 2017-05-01. Retrieved 2017-05-01.
• Edwards, Anthony William Fairbank (1989-01-07). "Venn diagrams for many sets". New Scientist. 121 (1646): 51–56.
• Watkinson, John (1990). "4.10. Hamming distance". Coding for Digital Recording. Stoneham, MA, USA: Focal Press. pp. 94–99, foldout in backsleeve. ISBN 978-0-240-51293-8. (NB. The book comes with a 3-page foldout of a seven-bit cylindrical Venn diagram.)
• Stewart, Ian (June 2003) [1992]. "Chapter 4. Cogwheels of the Mind". Another Fine Math You've Got Me Into (reprint of 1st ed.). Mineola, New York, USA: Dover Publications, Inc. (W. H. Freeman). pp. 51–64. ISBN 978-0-486-43181-9.
• Glassner, Andrew (2004). "Venn and Now". Morphs, Mallards, and Montages: Computer-Aided Imagination. Wellesley, MA, USA: A. K. Peters. pp. 161–184. ISBN 978-1568812311.
• Mamakani, Khalegh; Ruskey, Frank (2012-07-27). "A New Rose: The First Simple Symmetric 11-Venn Diagram". p. 6452. arXiv:1207.6452. Bibcode:2012arXiv1207.6452M. from the original on 2017-05-01. Retrieved 2017-05-01.

• "Venn diagram", Encyclopedia of Mathematics, EMS Press, 2001 [1994]
• Lewis Carroll's Logic Game – Venn vs. Euler at Cut-the-knot
• Six sets Venn diagrams made from triangles
• Interactive seven sets Venn diagram
• VBVenn a free open source program for calculating and graphing quantitative two-circle Venn diagrams