Inversion (discrete mathematics)

In computer science and discrete mathematics, a sequence has an inversion where two of its elements are out of their natural order.

Permutation with one of its inversions highlighted

It may be denoted by the pair of places (2, 4) or the pair of elements (5, 2).

Definitions

Inversion

Let be a permutation. If and , either the pair of places [1][2] or the pair of elements [3][4][5] is called an inversion of .

The inversion is usually defined for permutations, but may also be defined for sequences:
Let be a sequence (or multiset permutation[6]). If and , either the pair of places [6][7] or the pair of elements [8] is called an inversion of .

For sequences inversions according to the element-based definition are not unique, because different pairs of places may have the same pair of values.

The inversion set is the set of all inversions. A permutation's inversion set according to the place-based definition is that of the inverse permutation's inversion set according to the element-based definition, and vice versa,[9] just with the elements of the pairs exchanged.

Inversion number

The inversion number is the cardinality of inversion set. It is a common measure of the sortedness of a permutation[5] or sequence.[8]

It is the number of crossings in the arrow diagram of the permutation,[9] its Kendall tau distance from the identity permutation, and the sum of each of the inversion related vectors defined below.

It does not matter if the place-based or the element-based definition of inversion is used to define the inversion number, because a permutation and its inverse have the same number of inversions.

Other measures of (pre-)sortedness include the minimum number of elements that can be deleted from the sequence to yield a fully sorted sequence, the number and lengths of sorted "runs" within the sequence, the Spearman footrule (sum of distances of each element from its sorted position), and the smallest number of exchanges needed to sort the sequence.[10] Standard comparison sorting algorithms can be adapted to compute the inversion number in time O(n log n).[11]

Three similar vectors are in use that condense the inversions of a permutation into a vector that uniquely determines it. They are often called inversion vector or Lehmer code. (A list of sources is found here.)

This article uses the term inversion vector () like Wolfram.[12] The remaining two vectors are sometimes called left and right inversion vector, but to avoid confusion with the inversion vector this article calls them left inversion count () and right inversion count (). Interpreted as a factorial number the left inversion count gives the permutations reverse colexicographic,[13] and the right inversion count gives the lexicographic index.

Rothe diagram

Inversion vector :
With the element-based definition is the number of inversions whose smaller (right) component is .[3]

is the number of elements in greater than before .

Left inversion count :
With the place-based definition is the number of inversions whose bigger (right) component is .

is the number of elements in greater than before .

Right inversion count , often called Lehmer code:
With the place-based definition is the number of inversions whose smaller (left) component is .

is the number of elements in smaller than after .

Both and can be found with the help of a Rothe diagram, which is a permutation matrix with the 1s represented by dots, and an inversion (often represented by a cross) in every position that has a dot to the right and below it. is the sum of inversions in row of the Rothe diagram, while is the sum of inversions in column . The permutation matrix of the inverse is the transpose, therefore of a permutation is of its inverse, and vice versa.

Example: All permutations of four elements

The six possible inversions of a 4-element permutation

The following sortable table shows the 24 permutations of four elements with their place-based inversion sets, inversion related vectors and inversion numbers. (The small columns are reflections of the columns next to them, and can be used to sort them in colexicographic order.)

It can be seen that and always have the same digits, and that and are both related to the place-based inversion set. The nontrivial elements of are the sums of the descending diagonals of the shown triangle, and those of are the sums of the ascending diagonals. (Pairs in descending diagonals have the right components 2, 3, 4 in common, while pairs in ascending diagonals have the left components 1, 2, 3 in common.)

The default order of the table is reverse colex order by , which is the same as colex order by . Lex order by is the same as lex order by .

0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
p-b #
0123443210000000000000000000000000
1213443121000000100100100100000011
2132442310100001001000010010000101
3312442131100001101100110200000022
4231441322000000202000020110000112
5321441232100001202100120210000123
6124334210010010010000001001001001
7214334121010010110100101101001012
8142332410110011011000011020000202
9412332141110011111100111300000033
10241331422010010212000021120000213
11421331242110011212100121310000134
12134224310200002020000002011001102
13314224131200002120100102201001023
14143223410210012021000012021001203
15413223141210012121100112301001034
16341221432200002222000022220000224
17431221342210012222100122320000235
18234114323000000330000003111001113
19324114233100001330100103211001124
20243113423010010331000013121001214
21423113243110011331100113311001135
22342112433200002332000023221001225
23432112343210012332100123321001236

Weak order of permutations

Permutohedron of the symmetric group S4

The set of permutations on n items can be given the structure of a partial order, called the weak order of permutations, which forms a lattice.

The Hasse diagram of the inversion sets ordered by the subset relation forms the skeleton of a permutohedron.

If a permutation is assigned to each inversion set using the place-based definition, the resulting order of permutations is that of the permutohedron, where an edge corresponds to the swapping of two elements with consecutive values. This is the weak order of permutations. The identity is its minimum, and the permutation formed by reversing the identity is its maximum.

If a permutation were assigned to each inversion set using the element-based definition, the resulting order of permutations would be that of a Cayley graph, where an edge corresponds to the swapping of two elements on consecutive places. This Cayley graph of the symmetric group is similar to its permutohedron, but with each permutation replaced by its inverse.

gollark: Why? You could simulate mechanical faults and train the system on them.
gollark: Once again, I would be fine with that if their autopilot was good, which it isn't.
gollark: We could probably have a lot more automated stuff now if it wasn't for the difficulty of coordinating everyone on redesigning things at the same time.
gollark: ALL PROBLEMS can be solved with sufficient computer.
gollark: Wrong.

See also

Sequences in the OEIS:

References

  1. Aigner 2007, pp. 27.
  2. Comtet 1974, pp. 237.
  3. Knuth 1973, pp. 11.
  4. Pemmaraju & Skiena 2003, pp. 69.
  5. Vitter & Flajolet 1990, pp. 459.
  6. Bóna 2012, pp. 57.
  7. Cormen et al. 2001, pp. 39.
  8. Barth & Mutzel 2004, pp. 183.
  9. Gratzer 2016, pp. 221.
  10. Mahmoud 2000, pp. 284.
  11. Kleinberg & Tardos 2005, pp. 225.
  12. Weisstein, Eric W. "Inversion Vector" From MathWorld--A Wolfram Web Resource
  13. Reverse colex order of finitary permutations (sequence A055089 in the OEIS)

Source bibliography

  • Aigner, Martin (2007). "Word Representation". A course in enumeration. Berlin, New York: Springer. ISBN 3642072534.CS1 maint: ref=harv (link)
  • Bóna, Miklós (2012). "2.2 Inversions in Permutations of Multisets". Combinatorics of permutations. Boca Raton, FL: CRC Press. ISBN 1439850518.CS1 maint: ref=harv (link)
  • Gratzer, George (2016). "7-2 Basic objects". Lattice theory. special topics and applications. Cham, Switzerland: Birkhäuser. ISBN 331944235X.CS1 maint: ref=harv (link)
  • Kleinberg, Jon; Tardos, Éva. Algorithm Design. ISBN 0-321-29535-8.CS1 maint: ref=harv (link)
  • Knuth, Donald (1973). "5.1.1 Inversions". The art of computer programming. Addison-Wesley Pub. Co. ISBN 0201896850.CS1 maint: ref=harv (link)
  • Mahmoud, Hosam Mahmoud (2000). "Sorting Nonrandom Data". Sorting: a distribution theory. Wiley-Interscience series in discrete mathematics and optimization. 54. Wiley-IEEE. ISBN 978-0-471-32710-3.CS1 maint: ref=harv (link)
  • Pemmaraju, Sriram V.; Skiena, Steven S. (2003). "Permutations and combinations". Computational discrete mathematics: combinatorics and graph theory with Mathematica. Cambridge University Press. ISBN 978-0-521-80686-2.CS1 maint: ref=harv (link)
  • Vitter, J.S.; Flajolet, Ph. (1990). "Average-Case Analysis of Algorithms and Data Structures". In van Leeuwen, Jan (ed.). Algorithms and Complexity. 1 (2nd ed.). Elsevier. ISBN 978-0-444-88071-0.CS1 maint: ref=harv (link)

Further reading

  • Margolius, Barbara H. (2001). "Permutations with Inversions". Journal of Integer Sequences. 4.CS1 maint: ref=harv (link)

Presortedness measures

This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.