LMFDB - Abstract group 1280.1116446: $C_2^6:D

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This project is supported by grants from the US National Science Foundation, the UK Engineering and Physical Sciences Research Council, and the Simons Foundation.

Show commands: Gap / Magma / SageMath

magma:G := SmallGroup(1280, 1116446);

gap:G := SmallGroup(1280, 1116446);

sage_gap:G = libgap.SmallGroup(1280, 1116446)

comment:Define the group as a permutation group

sage:G = PermutationGroup(['(2,4)(5,8)(6,7)(9,10)(11,12)(13,14)', '(1,2,5,8,4)(3,6,9,10,7)', '(1,3)(8,10)', '(1,3)(4,7)(5,9)(8,10)', '(1,3)(2,6)', '(2,6)(4,7)', '(1,3)(2,6)(4,7)(5,9)(8,10)', '(1,3)(2,6)(4,7)(5,9)(8,10)(12,14)', '(11,13)(12,14)'])

Description:	$C_2^6:D_{10}$
Order:	$1280$$\medspace = 2^{8} \cdot 5 $	comment:Order of the group magma:Order(G); gap:Order(G); sage:G.order() sage_gap:G.Order()
Exponent:	$20$$\medspace = 2^{2} \cdot 5 $	comment:Exponent of the group magma:Exponent(G); gap:Exponent(G); sage:G.exponent() sage_gap:G.Exponent()
Automorphism group:	$F_{16}.C_2^4.C_2^3$, of order $30720$$\medspace = 2^{11} \cdot 3 \cdot 5 $	comment:Automorphism group gap:AutomorphismGroup(G); magma:AutomorphismGroup(G); sage_gap:G.AutomorphismGroup()
Composition factors:	$C_2$ x 8, $C_5$	comment:Composition factors of the group magma:CompositionFactors(G); gap:CompositionSeries(G); sage:G.composition_series() sage_gap:G.CompositionSeries()
Derived length:	$3$	comment:Derived length of the group magma:DerivedLength(G); gap:DerivedLength(G); sage_gap:G.DerivedLength()

This group is nonabelian and monomial (hence solvable).

comment:Determine if the group G is abelian

magma:IsAbelian(G);

gap:IsAbelian(G);

sage:G.is_abelian()

sage_gap:G.IsAbelian()

comment:Determine if the group G is cyclic

magma:IsCyclic(G);

gap:IsCyclic(G);

sage:G.is_cyclic()

sage_gap:G.IsCyclic()

comment:Determine if the group G is nilpotent

magma:IsNilpotent(G);

gap:IsNilpotentGroup(G);

sage:G.is_nilpotent()

sage_gap:G.IsNilpotentGroup()

comment:Determine if the group G is solvable

magma:IsSolvable(G);

gap:IsSolvableGroup(G);

sage:G.is_solvable()

sage_gap:G.IsSolvableGroup()

comment:Determine if the group G is supersolvable

gap:IsSupersolvableGroup(G);

sage:G.is_supersolvable()

sage_gap:G.IsSupersolvableGroup()

comment:Determine if the group G is simple

magma:IsSimple(G);

gap:IsSimpleGroup(G);

sage_gap:G.IsSimpleGroup()

comment:Compute statistics for the group G

magma:// Magma code to output the first two rows of the group statistics table element_orders := [Order(g) : g in G]; orders := Set(element_orders); printf "Orders: %o\n", orders; printf "Elements: %o %o\n", [#[x : x in element_orders | x eq n] : n in orders], Order(G); cc_orders := [cc[1] : cc in ConjugacyClasses(G)]; printf "Conjugacy classes: %o %o\n", [#[x : x in cc_orders | x eq n] : n in orders], #cc_orders;

gap:# Gap code to output the first two rows of the group statistics table element_orders := List(Elements(G), g -> Order(g)); orders := Set(element_orders); Print("Orders: ", orders, "\n"); element_counts := List(orders, n -> Length(Filtered(element_orders, x -> x = n))); Print("Elements: ", element_counts, " ", Size(G), "\n"); cc_orders := List(ConjugacyClasses(G), cc -> Order(Representative(cc))); cc_counts := List(orders, n -> Length(Filtered(cc_orders, x -> x = n))); Print("Conjugacy classes: ", cc_counts, " ", Length(ConjugacyClasses(G)), "\n");

sage:# Sage code to output the first two rows of the group statistics table element_orders = [g.order() for g in G] orders = sorted(list(set(element_orders))) print("Orders:", orders) print("Elements:", [element_orders.count(n) for n in orders], G.order()) cc_orders = [cc[0].order() for cc in G.conjugacy_classes()] print("Conjugacy classes:", [cc_orders.count(n) for n in orders], len(cc_orders))

comment:Compute statistics about the characters of G

magma:// Outputs [<d_1,c_1>, <d_2,c_2>, ...] where c_i is the number of irr. complex chars. of G with degree d_i CharacterDegrees(G);

gap:# Outputs [[d_1,c_1], [d_2,c_2], ...] where c_i is the number of irr. complex chars. of G with degree d_i CharacterDegrees(G);

sage:# Outputs [[d_1,c_1], [d_2,c_2], ...] where c_i is the number of irr. complex chars. of G with degree d_i character_degrees = [c[0] for c in G.character_table()] [[n, character_degrees.count(n)] for n in set(character_degrees)]

sage_gap:G.CharacterDegrees()

Dimension	1	2	4	5	8	10
Irr. complex chars.	8	18	0	24	0	6	56
Irr. rational chars.	8	2	4	24	2	6	46

Permutation degree:	$14$
Transitive degree:	$40$
Rank:	$3$
Inequivalent generating triples:	$21420$

	Over $\mathbb{C}$	Over $\mathbb{R}$	Over $\mathbb{Q}$
Irreducible	none	none	none
Arbitrary	not computed	not computed	not computed

Show commands: Gap / Magma / SageMath

Presentation:	${\langle a, b, c, d, e, f, g \mid a^{2}=b^{4}=c^{10}=d^{2}=e^{2}=f^{2}=g^{2}= \!\cdots\! \rangle}$ < a, b, c, d, e, f, g \| a^2,b^4,c^10,d^2,e^2,f^2,g^2,[a,f],[a,g],[b,f],[b,g],[d,e],[d,f],[d,g],[e,f],[e,g],[f,g], b^3a^-1b^-1a, c^9a^-1c^-1a, dfa^-1d^-1a, ega^-1e^-1a, c^9b^-1c^-1b, dfb^-1d^-1b, egb^-1e^-1b, fgc^-1d^-1c, dc^-1e^-1c, efc^-1f^-1c, dec^-1g^-1c >
comment:Define the group with the given generators and relations magma:G := PCGroup([9, -2, -2, -2, -2, -5, -2, 2, 2, 2, 109, 46, 2595, 1308, 102, 2884, 1453, 21605, 10814, 6512, 1391, 50406, 25215, 663, 3822, 4354, 2563, 2465, 5309]); a,b,c,d,e,f,g := Explode([G.1, G.2, G.4, G.6, G.7, G.8, G.9]); AssignNames(~G, ["a", "b", "b2", "c", "c2", "d", "e", "f", "g"]); gap:G := PcGroupCode(3926868250457796261799072650750498679059581417775997642558862758595806102272,1280); a := G.1; b := G.2; c := G.4; d := G.6; e := G.7; f := G.8; g := G.9; sage:# This uses Sage's interface to GAP, as Sage (currently) has no native support for PC groups G = gap.new('PcGroupCode(3926868250457796261799072650750498679059581417775997642558862758595806102272,1280)'); a = G.1; b = G.2; c = G.4; d = G.6; e = G.7; f = G.8; g = G.9; sage_gap:# This uses Sage's interface to GAP, as Sage (currently) has no native support for PC groups G = gap.new('PcGroupCode(3926868250457796261799072650750498679059581417775997642558862758595806102272,1280)'); a = G.1; b = G.2; c = G.4; d = G.6; e = G.7; f = G.8; g = G.9;
Permutation group:	Degree $14$ $\langle(2,4)(5,8)(6,7)(9,10)(11,12)(13,14), (1,2,5,8,4)(3,6,9,10,7), (1,3)(8,10) \!\cdots\! \rangle$ (2,4)(5,8)(6,7)(9,10)(11,12)(13,14), (1,2,5,8,4)(3,6,9,10,7), (1,3)(8,10), (1,3)(4,7)(5,9)(8,10), (1,3)(2,6), (2,6)(4,7), (1,3)(2,6)(4,7)(5,9)(8,10), (1,3)(2,6)(4,7)(5,9)(8,10)(12,14), (11,13)(12,14)
comment:Define the group as a permutation group magma:G := PermutationGroup< 14 \| (2,4)(5,8)(6,7)(9,10)(11,12)(13,14), (1,2,5,8,4)(3,6,9,10,7), (1,3)(8,10), (1,3)(4,7)(5,9)(8,10), (1,3)(2,6), (2,6)(4,7), (1,3)(2,6)(4,7)(5,9)(8,10), (1,3)(2,6)(4,7)(5,9)(8,10)(12,14), (11,13)(12,14) >; gap:G := Group( (2,4)(5,8)(6,7)(9,10)(11,12)(13,14), (1,2,5,8,4)(3,6,9,10,7), (1,3)(8,10), (1,3)(4,7)(5,9)(8,10), (1,3)(2,6), (2,6)(4,7), (1,3)(2,6)(4,7)(5,9)(8,10), (1,3)(2,6)(4,7)(5,9)(8,10)(12,14), (11,13)(12,14) ); sage:G = PermutationGroup(['(2,4)(5,8)(6,7)(9,10)(11,12)(13,14)', '(1,2,5,8,4)(3,6,9,10,7)', '(1,3)(8,10)', '(1,3)(4,7)(5,9)(8,10)', '(1,3)(2,6)', '(2,6)(4,7)', '(1,3)(2,6)(4,7)(5,9)(8,10)', '(1,3)(2,6)(4,7)(5,9)(8,10)(12,14)', '(11,13)(12,14)'])
Matrix group:	$\left\langle \left(\begin{array}{llll}\alpha^{2} & \alpha^{2} & 1 & 1 \\ 0 & 1 & 0 & 0 \\ \alpha^{2} & 1 & \alpha^{2} & \alpha \\ 0 & 0 & 0 & 1 \\ \end{array}\right), \left(\begin{array}{llll}\alpha & \alpha & 1 & 1 \\ 1 & 0 & 0 & 0 \\ 1 & 1 & 1 & 0 \\ \alpha^{2} & 1 & \alpha & \alpha^{2} \\ \end{array}\right), \left(\begin{array}{llll}1 & 0 & 0 & 0 \\ \alpha & \alpha & 1 & 1 \\ 1 & \alpha & \alpha & \alpha^{2} \\ 0 & 0 & 0 & 1 \\ \end{array}\right), \left(\begin{array}{llll}0 & \alpha & \alpha^{2} & \alpha \\ 0 & 1 & 0 & 0 \\ \alpha & \alpha^{2} & 0 & \alpha^{2} \\ 0 & 0 & 0 & 1 \\ \end{array}\right), \left(\begin{array}{llll}0 & \alpha & \alpha^{2} & \alpha^{2} \\ \alpha^{2} & 0 & \alpha & \alpha^{2} \\ 0 & 0 & 1 & \alpha^{2} \\ 0 & 0 & 0 & 1 \\ \end{array}\right), \left(\begin{array}{llll}\alpha^{2} & 0 & \alpha & \alpha \\ 1 & \alpha^{2} & 0 & \alpha^{2} \\ \alpha^{2} & 0 & 0 & \alpha^{2} \\ 1 & \alpha & \alpha^{2} & 0 \\ \end{array}\right), \left(\begin{array}{llll}1 & 0 & 0 & \alpha \\ 0 & 1 & 0 & 0 \\ 0 & 0 & 1 & \alpha^{2} \\ 0 & 0 & 0 & 1 \\ \end{array}\right), \left(\begin{array}{llll}0 & \alpha & \alpha^{2} & \alpha^{2} \\ \alpha & \alpha & 1 & \alpha \\ \alpha^{2} & 1 & \alpha^{2} & 0 \\ 0 & 0 & 0 & 1 \\ \end{array}\right), \left(\begin{array}{llll}1 & 0 & 0 & 0 \\ \alpha & \alpha & 1 & 0 \\ 1 & \alpha & \alpha & 0 \\ 0 & 0 & 0 & 1 \\ \end{array}\right) \right\rangle \subseteq \GL_{4}(\F_{4}) = \GL_{4}(\F_{2}[\alpha]/(\alpha^{2} + \alpha + 1))$
comment:Define the group as a matrix group with coefficients in GLFq magma:F:=GF(4); al:=F.1; G := MatrixGroup< 4, F \| [[al^2, al^2, 1, 1], [0, 1, 0, 0], [al^2, 1, al^2, al^1], [0, 0, 0, 1]],[[al^1, al^1, 1, 1], [1, 0, 0, 0], [1, 1, 1, 0], [al^2, 1, al^1, al^2]],[[1, 0, 0, 0], [al^1, al^1, 1, 1], [1, al^1, al^1, al^2], [0, 0, 0, 1]],[[0, al^1, al^2, al^1], [0, 1, 0, 0], [al^1, al^2, 0, al^2], [0, 0, 0, 1]],[[0, al^1, al^2, al^2], [al^2, 0, al^1, al^2], [0, 0, 1, al^2], [0, 0, 0, 1]],[[al^2, 0, al^1, al^1], [1, al^2, 0, al^2], [al^2, 0, 0, al^2], [1, al^1, al^2, 0]],[[1, 0, 0, al^1], [0, 1, 0, 0], [0, 0, 1, al^2], [0, 0, 0, 1]],[[0, al^1, al^2, al^2], [al^1, al^1, 1, al^1], [al^2, 1, al^2, 0], [0, 0, 0, 1]],[[1, 0, 0, 0], [al^1, al^1, 1, 0], [1, al^1, al^1, 0], [0, 0, 0, 1]] >; gap:G := Group([[[Z(4)^2, Z(4)^2, Z(4)^0, Z(4)^0], [0Z(4), Z(4)^0, 0Z(4), 0Z(4)], [Z(4)^2, Z(4)^0, Z(4)^2, Z(4)^1], [0Z(4), 0Z(4), 0Z(4), Z(4)^0]],[[Z(4)^1, Z(4)^1, Z(4)^0, Z(4)^0], [Z(4)^0, 0Z(4), 0Z(4), 0Z(4)], [Z(4)^0, Z(4)^0, Z(4)^0, 0Z(4)], [Z(4)^2, Z(4)^0, Z(4)^1, Z(4)^2]],[[Z(4)^0, 0Z(4), 0Z(4), 0Z(4)], [Z(4)^1, Z(4)^1, Z(4)^0, Z(4)^0], [Z(4)^0, Z(4)^1, Z(4)^1, Z(4)^2], [0Z(4), 0Z(4), 0Z(4), Z(4)^0]],[[0Z(4), Z(4)^1, Z(4)^2, Z(4)^1], [0Z(4), Z(4)^0, 0Z(4), 0Z(4)], [Z(4)^1, Z(4)^2, 0Z(4), Z(4)^2], [0Z(4), 0Z(4), 0Z(4), Z(4)^0]],[[0Z(4), Z(4)^1, Z(4)^2, Z(4)^2], [Z(4)^2, 0Z(4), Z(4)^1, Z(4)^2], [0Z(4), 0Z(4), Z(4)^0, Z(4)^2], [0Z(4), 0Z(4), 0Z(4), Z(4)^0]],[[Z(4)^2, 0Z(4), Z(4)^1, Z(4)^1], [Z(4)^0, Z(4)^2, 0Z(4), Z(4)^2], [Z(4)^2, 0Z(4), 0Z(4), Z(4)^2], [Z(4)^0, Z(4)^1, Z(4)^2, 0Z(4)]],[[Z(4)^0, 0Z(4), 0Z(4), Z(4)^1], [0Z(4), Z(4)^0, 0Z(4), 0Z(4)], [0Z(4), 0Z(4), Z(4)^0, Z(4)^2], [0Z(4), 0Z(4), 0Z(4), Z(4)^0]],[[0Z(4), Z(4)^1, Z(4)^2, Z(4)^2], [Z(4)^1, Z(4)^1, Z(4)^0, Z(4)^1], [Z(4)^2, Z(4)^0, Z(4)^2, 0Z(4)], [0Z(4), 0Z(4), 0Z(4), Z(4)^0]],[[Z(4)^0, 0Z(4), 0Z(4), 0Z(4)], [Z(4)^1, Z(4)^1, Z(4)^0, 0Z(4)], [Z(4)^0, Z(4)^1, Z(4)^1, 0Z(4)], [0Z(4), 0Z(4), 0*Z(4), Z(4)^0]]]); sage:F = GF(4); al = F.0; MS = MatrixSpace(F, 4, 4) G = MatrixGroup([MS([[al^2, al^2, 1, 1], [0, 1, 0, 0], [al^2, 1, al^2, al^1], [0, 0, 0, 1]]), MS([[al^1, al^1, 1, 1], [1, 0, 0, 0], [1, 1, 1, 0], [al^2, 1, al^1, al^2]]), MS([[1, 0, 0, 0], [al^1, al^1, 1, 1], [1, al^1, al^1, al^2], [0, 0, 0, 1]]), MS([[0, al^1, al^2, al^1], [0, 1, 0, 0], [al^1, al^2, 0, al^2], [0, 0, 0, 1]]), MS([[0, al^1, al^2, al^2], [al^2, 0, al^1, al^2], [0, 0, 1, al^2], [0, 0, 0, 1]]), MS([[al^2, 0, al^1, al^1], [1, al^2, 0, al^2], [al^2, 0, 0, al^2], [1, al^1, al^2, 0]]), MS([[1, 0, 0, al^1], [0, 1, 0, 0], [0, 0, 1, al^2], [0, 0, 0, 1]]), MS([[0, al^1, al^2, al^2], [al^1, al^1, 1, al^1], [al^2, 1, al^2, 0], [0, 0, 0, 1]]), MS([[1, 0, 0, 0], [al^1, al^1, 1, 0], [1, al^1, al^1, 0], [0, 0, 0, 1]])])
Transitive group:	40T1002	40T1013	40T1019	40T1040	all 10
Direct product:	$C_2$ $\, \times\, $ $(C_2^6:D_5)$
Semidirect product:	$C_2^7$ $\,\rtimes\,$ $D_5$	$C_2^6$ $\,\rtimes\,$ $D_{10}$	$(C_2\wr C_5)$ $\,\rtimes\,$ $D_4$	$C_2^5$ $\,\rtimes\,$ $(C_5:D_4)$	all 14
Trans. wreath product:	not isomorphic to a non-trivial transitive wreath product
Non-split product:	$C_2^6$ . $D_{10}$	$C_2^5$ . $(C_2\times D_{10})$	$C_2$ . $(C_2^5:D_{10})$	$C_2^2$ . $(C_2\wr D_5)$	all 6

Elements of the group are displayed as permutations of degree 14.

Abelianization:	$C_{2}^{3} $	comment:The abelianization of the group magma:quo< G \| CommutatorSubgroup(G) >; gap:FactorGroup(G, DerivedSubgroup(G)); sage:G.quotient(G.commutator())
Schur multiplier:	$C_{2}^{5}$	comment:The Schur multiplier of the group gap:AbelianInvariantsMultiplier(G); sage:G.homology(2) sage_gap:G.AbelianInvariantsMultiplier()
Commutator length:	$1$	comment:The commutator length of the group gap:CommutatorLength(G); sage_gap:G.CommutatorLength()

comment:List of subgroups of the group

magma:Subgroups(G);

gap:AllSubgroups(G);

sage:G.subgroups()

sage_gap:G.AllSubgroups()

There are 46862 subgroups in 4827 conjugacy classes, 35 normal (15 characteristic).

Characteristic subgroups are shown in this color. Normal (but not characteristic) subgroups are shown in this color.

Center:	$Z \simeq$ $C_2^2$	$G/Z \simeq$ $C_2\wr D_5$	comment:Center of the group magma:Center(G); gap:Center(G); sage:G.center() sage_gap:G.Center()
Commutator:	$G' \simeq$ $C_2\wr C_5$	$G/G' \simeq$ $C_2^3$	comment:Commutator subgroup of the group G magma:CommutatorSubgroup(G); gap:DerivedSubgroup(G); sage:G.commutator() sage_gap:G.DerivedSubgroup()
Frattini:	$\Phi \simeq$ $C_2$	$G/\Phi \simeq$ $C_2^5:D_{10}$	comment:Frattini subgroup of the group G magma:FrattiniSubgroup(G); gap:FrattiniSubgroup(G); sage:G.frattini_subgroup() sage_gap:G.FrattiniSubgroup()
Fitting:	$\operatorname{Fit} \simeq$ $C_2^7$	$G/\operatorname{Fit} \simeq$ $D_5$	comment:Fitting subgroup of the group G magma:FittingSubgroup(G); gap:FittingSubgroup(G); sage:G.fitting_subgroup() sage_gap:G.FittingSubgroup()
Radical:	$R \simeq$ $C_2^6:D_{10}$	$G/R \simeq$ $C_1$	comment:Radical of the group G magma:Radical(G); gap:SolvableRadical(G); sage_gap:G.SolvableRadical()
Socle:	$\operatorname{soc} \simeq$ $C_2^6$	$G/\operatorname{soc} \simeq$ $D_{10}$	comment:Socle of the group G magma:Socle(G); gap:Socle(G); sage:G.socle() sage_gap:G.Socle()
2-Sylow subgroup:	$P_{ 2 } \simeq$ $C_2^5:D_4$
5-Sylow subgroup:	$P_{ 5 } \simeq$ $C_5$

For the default diagram, subgroups are sorted vertically by the number of prime divisors (counted with multiplicity) in their orders.
To see subgroups sorted vertically by order instead, check this box.

Click on a subgroup in the diagram to see information about it.

See a full page version of the diagram

Derived series

$C_2^6:D_{10}$

$\rhd$

$C_2\wr C_5$

$\rhd$

$C_2^4$

$\rhd$

$C_1$

comment:Derived series of the group GF

magma:DerivedSeries(G);

gap:DerivedSeriesOfGroup(G);

sage:G.derived_series()

sage_gap:G.DerivedSeriesOfGroup()

Chief series

$C_2^6:D_{10}$

$\rhd$

$C_2^6:C_{10}$

$\rhd$

$C_2^5:C_{10}$

$\rhd$

$C_2\wr C_5$

$\rhd$

$C_2^4:C_5$

$\rhd$

$C_2^4$

$\rhd$

$C_1$

comment:Chief series of the group G

magma:ChiefSeries(G);

gap:ChiefSeries(G);

sage_gap:G.ChiefSeries()

Lower central series

$C_2^6:D_{10}$

$\rhd$

$C_2\wr C_5$

$\rhd$

$C_2^4:C_5$

comment:The lower central series of the group G

magma:LowerCentralSeries(G);

gap:LowerCentralSeriesOfGroup(G);

sage:G.lower_central_series()

sage_gap:G.LowerCentralSeriesOfGroup()

Upper central series

$C_1$

$\lhd$

$C_2^2$

$\lhd$

$C_2^3$

comment:The upper central series of the group G

magma:UpperCentralSeries(G);

gap:UpperCentralSeriesOfGroup(G);

sage:G.upper_central_series()

sage_gap:G.UpperCentralSeriesOfGroup()

This group is a maximal subgroup of 39 larger groups in the database.

This group is a maximal quotient of 24 larger groups in the database.

comment:Character table

magma:CharacterTable(G); // Output not guaranteed to exactly match the LMFDB table

gap:CharacterTable(G); # Output not guaranteed to exactly match the LMFDB table

sage:G.character_table() # Output not guaranteed to exactly match the LMFDB table

sage_gap:G.CharacterTable() # Output not guaranteed to exactly match the LMFDB table

See the $56 \times 56$ character table. Alternatively, you may search for characters of this group with desired properties.

See the $46 \times 46$ rational character table.

Overview	Random
Universe	Knowledge

Classical	Maass
Hilbert	Bianchi

Elliptic curves over $\Q$
Elliptic curves over $\Q(\alpha)$
Genus 2 curves over $\Q$
Higher genus families
Abelian varieties over $\F_{q}$
Belyi maps

Label	1280.1116446
Order	\( 2^{8} \cdot 5 \)
Exponent	\( 2^{2} \cdot 5 \)

Nilpotent	no
Solvable	yes
$\card{G^{\mathrm{ab}}}$	\( 2^{3} \)
$\card{Z(G)}$	\( 2^{2} \)
$\card{\Aut(G)}$	\( 2^{11} \cdot 3 \cdot 5 \)
$\card{\mathrm{Out}(G)}$	\( 2^{5} \cdot 3 \)
Perm deg.	$14$
Trans deg.	$40$
Rank	$3$

Conjugacy classes

Autjugacy classes