Properties

Label 5668704.kl
Order \( 2^{5} \cdot 3^{11} \)
Exponent \( 2^{2} \cdot 3^{2} \)
Nilpotent no
Solvable yes
$\card{G^{\mathrm{ab}}}$ \( 2^{3} \)
$\card{Z(G)}$ \( 1 \)
$\card{\Aut(G)}$ \( 2^{6} \cdot 3^{12} \)
$\card{\mathrm{Out}(G)}$ \( 2 \cdot 3 \)
Perm deg. $36$
Trans deg. $36$
Rank $2$

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Show commands: Gap / Magma / Oscar / SageMath

Copy content comment:Construction of abstract group
 
Copy content magma:G := PermutationGroup< 36 | (1,8,26,19)(2,7,27,20)(3,9,25,21)(4,30,17,6,29,18)(5,28,16)(10,35,11,34,12,36)(13,32,15,31)(14,33)(22,24,23), (1,22,3,23,2,24)(4,32,16,21,29,7)(5,33,18,19,28,8)(6,31,17,20,30,9)(10,27)(11,26)(12,25)(13,36,14,34,15,35) >;
 
Copy content gap:G := Group( (1,8,26,19)(2,7,27,20)(3,9,25,21)(4,30,17,6,29,18)(5,28,16)(10,35,11,34,12,36)(13,32,15,31)(14,33)(22,24,23), (1,22,3,23,2,24)(4,32,16,21,29,7)(5,33,18,19,28,8)(6,31,17,20,30,9)(10,27)(11,26)(12,25)(13,36,14,34,15,35) );
 
Copy content sage:G = PermutationGroup(['(1,8,26,19)(2,7,27,20)(3,9,25,21)(4,30,17,6,29,18)(5,28,16)(10,35,11,34,12,36)(13,32,15,31)(14,33)(22,24,23)', '(1,22,3,23,2,24)(4,32,16,21,29,7)(5,33,18,19,28,8)(6,31,17,20,30,9)(10,27)(11,26)(12,25)(13,36,14,34,15,35)'])
 
Copy content sage_gap:G = gap.new('Group( (1,8,26,19)(2,7,27,20)(3,9,25,21)(4,30,17,6,29,18)(5,28,16)(10,35,11,34,12,36)(13,32,15,31)(14,33)(22,24,23), (1,22,3,23,2,24)(4,32,16,21,29,7)(5,33,18,19,28,8)(6,31,17,20,30,9)(10,27)(11,26)(12,25)(13,36,14,34,15,35) )')
 
Copy content oscar:G = @permutation_group(36, (1,8,26,19)(2,7,27,20)(3,9,25,21)(4,30,17,6,29,18)(5,28,16)(10,35,11,34,12,36)(13,32,15,31)(14,33)(22,24,23), (1,22,3,23,2,24)(4,32,16,21,29,7)(5,33,18,19,28,8)(6,31,17,20,30,9)(10,27)(11,26)(12,25)(13,36,14,34,15,35))
 

Group information

Description:$C_3^7.C_3:S_3^3:C_4$
Order: \(5668704\)\(\medspace = 2^{5} \cdot 3^{11} \)
Copy content comment:Order of the group
 
Copy content magma:Order(G);
 
Copy content gap:Order(G);
 
Copy content sage:G.order()
 
Copy content sage_gap:G.Order()
 
Copy content oscar:order(G)
 
Exponent: \(36\)\(\medspace = 2^{2} \cdot 3^{2} \)
Copy content comment:Exponent of the group
 
Copy content magma:Exponent(G);
 
Copy content gap:Exponent(G);
 
Copy content sage:G.exponent()
 
Copy content sage_gap:G.Exponent()
 
Copy content oscar:exponent(G)
 
Automorphism group:Group of order \(34012224\)\(\medspace = 2^{6} \cdot 3^{12} \)
Copy content comment:Automorphism group
 
Copy content gap:AutomorphismGroup(G);
 
Copy content magma:AutomorphismGroup(G);
 
Copy content sage:libgap(G).AutomorphismGroup()
 
Copy content sage_gap:G.AutomorphismGroup()
 
Copy content oscar:automorphism_group(G)
 
Composition factors:$C_2$ x 5, $C_3$ x 11
Copy content comment:Composition factors of the group
 
Copy content magma:CompositionFactors(G);
 
Copy content gap:CompositionSeries(G);
 
Copy content sage:G.composition_series()
 
Copy content sage_gap:G.CompositionSeries()
 
Copy content oscar:composition_series(G)
 
Derived length:$4$
Copy content comment:Derived length of the group
 
Copy content magma:DerivedLength(G);
 
Copy content gap:DerivedLength(G);
 
Copy content sage:libgap(G).DerivedLength()
 
Copy content sage_gap:G.DerivedLength()
 
Copy content oscar:derived_length(G)
 

This group is nonabelian and solvable. Whether it is monomial has not been computed.

Copy content comment:Determine if the group G is abelian
 
Copy content magma:IsAbelian(G);
 
Copy content gap:IsAbelian(G);
 
Copy content sage:G.is_abelian()
 
Copy content sage_gap:G.IsAbelian()
 
Copy content oscar:is_abelian(G)
 
Copy content comment:Determine if the group G is cyclic
 
Copy content magma:IsCyclic(G);
 
Copy content gap:IsCyclic(G);
 
Copy content sage:G.is_cyclic()
 
Copy content sage_gap:G.IsCyclic()
 
Copy content oscar:is_cyclic(G)
 
Copy content comment:Determine if the group G is nilpotent
 
Copy content magma:IsNilpotent(G);
 
Copy content gap:IsNilpotentGroup(G);
 
Copy content sage:G.is_nilpotent()
 
Copy content sage_gap:G.IsNilpotentGroup()
 
Copy content oscar:is_nilpotent(G)
 
Copy content comment:Determine if the group G is solvable
 
Copy content magma:IsSolvable(G);
 
Copy content gap:IsSolvableGroup(G);
 
Copy content sage:G.is_solvable()
 
Copy content sage_gap:G.IsSolvableGroup()
 
Copy content oscar:is_solvable(G)
 
Copy content comment:Determine if the group G is supersolvable
 
Copy content gap:IsSupersolvableGroup(G);
 
Copy content sage:G.is_supersolvable()
 
Copy content sage_gap:G.IsSupersolvableGroup()
 
Copy content oscar:is_supersolvable(G)
 
Copy content comment:Determine if the group G is simple
 
Copy content magma:IsSimple(G);
 
Copy content gap:IsSimpleGroup(G);
 
Copy content sage:G.is_simple()
 
Copy content sage_gap:G.IsSimpleGroup()
 
Copy content oscar:is_simple(G)
 

Group statistics

Copy content comment:Compute statistics for the group G
 
Copy content 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;
 
Copy content 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");
 
Copy content 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))
 
Copy content sage_gap:# Sage code (using the GAP interface) to output the first two rows of the group statistics table element_orders = [g.Order() for g in G.Elements()] orders = sorted(list(set(element_orders))) print("Orders:", orders) print("Elements:", [element_orders.count(n) for n in orders], G.Order()) cc_orders = [cc.Representative().Order() for cc in G.ConjugacyClasses()] print("Conjugacy classes:", [cc_orders.count(n) for n in orders], len(cc_orders))
 
Copy content oscar:# Oscar code to output the first two rows of the group statistics table element_orders = [order(g) for g in elements(G)] orders = sort(unique(element_orders)) println("Orders: ", orders) element_counts = [count(==(n), element_orders) for n in orders] println("Elements: ", element_counts, " ", order(G)) ccs = conjugacy_classes(G) cc_orders = [order(representative(cc)) for cc in ccs] cc_counts = [count(==(n), cc_orders) for n in orders] println("Conjugacy classes: ", cc_counts, " ", length(ccs))
 

Order 1 2 3 4 6 9 12 18 36
Elements 1 10611 54674 288684 835758 122472 2309472 1102248 944784 5668704
Conjugacy classes   1 5 68 5 66 28 35 28 6 242
Divisions 1 5 49 3 49 19 13 19 1 159
Autjugacy classes 1 5 27 3 37 20 12 23 1 129

Minimal presentations

Permutation degree:$36$
Transitive degree:$36$
Rank: $2$
Inequivalent generating pairs: not computed

Minimal degrees of faithful linear representations

Over $\mathbb{C}$ Over $\mathbb{R}$ Over $\mathbb{Q}$
Irreducible 24 not computed not computed
Arbitrary not computed not computed not computed

Constructions

Show commands: Gap / Magma / Oscar / SageMath


Presentation: ${\langle a, b, c, d, e, f, g, h, i, j \mid b^{12}=d^{9}=e^{3}=f^{9}=g^{3}= \!\cdots\! \rangle}$ Copy content Toggle raw display
Copy content comment:Define the group with the given generators and relations
 
Copy content magma:G := PCGroup([16, 2, 2, 2, 2, 3, 2, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 32, 45113873, 172306754, 103503282, 130, 258032131, 56912147, 179, 451701764, 102678420, 208094981, 126381333, 48873637, 52724213, 29253669, 277, 390297606, 115739926, 125271590, 75143094, 19445062, 3184374, 68247559, 77709335, 89109543, 12326455, 3375431, 3549783, 2054503, 503, 60466184, 839848, 31160, 5272, 823080969, 246758425, 128590121, 103737, 17147609, 8985705, 955722250, 256075802, 174594858, 117355450, 32931434, 2195514, 9936538, 363418, 698, 1007769611, 4479003, 82987, 1119803, 186715, 630789132, 12130588, 50993324, 78848700, 707708, 202284, 430716, 142444, 387085, 293932845, 11757373, 593671694, 131777310, 251994286, 107801342, 6419614, 1635230, 699966, 373838, 123294, 1039343631, 567447583, 80732207, 68732991, 17054303, 5167983, 2052991, 479391, 159151]); a,b,c,d,e,f,g,h,i,j := Explode([G.1, G.3, G.6, G.8, G.10, G.11, G.13, G.14, G.15, G.16]); AssignNames(~G, ["a", "a2", "b", "b2", "b4", "c", "c2", "d", "d3", "e", "f", "f3", "g", "h", "i", "j"]);
 
Copy content gap:G := PcGroupCode(3833734778369222872812919356482099046980243267616708503353087633673680264247129403418919499462761588190218121780482294044496231021215456012565532995866154505567384727399847365505483757315757881358290997987566411094152979365138887296756948328586331512998302338589253371981862222567311575547535119204367711989264706447856735540009064253626477228443122859813377905066892144132699843498559243449950092751197689542000109628975246426903784546947014098996628813538732444830039564857133606257470083598362319405260521881094427831017148450902400820263700502406984100631416587468399764393182637578015087854029823,5668704); a := G.1; b := G.3; c := G.6; d := G.8; e := G.10; f := G.11; g := G.13; h := G.14; i := G.15; j := G.16;
 
Copy content sage:# This uses Sage's interface to GAP, as Sage (currently) has no native support for PC groups G = gap.new('PcGroupCode(3833734778369222872812919356482099046980243267616708503353087633673680264247129403418919499462761588190218121780482294044496231021215456012565532995866154505567384727399847365505483757315757881358290997987566411094152979365138887296756948328586331512998302338589253371981862222567311575547535119204367711989264706447856735540009064253626477228443122859813377905066892144132699843498559243449950092751197689542000109628975246426903784546947014098996628813538732444830039564857133606257470083598362319405260521881094427831017148450902400820263700502406984100631416587468399764393182637578015087854029823,5668704)'); a = G.1; b = G.3; c = G.6; d = G.8; e = G.10; f = G.11; g = G.13; h = G.14; i = G.15; j = G.16;
 
Copy content sage_gap:# This uses Sage's interface to GAP, as Sage (currently) has no native support for PC groups G = gap.new('PcGroupCode(3833734778369222872812919356482099046980243267616708503353087633673680264247129403418919499462761588190218121780482294044496231021215456012565532995866154505567384727399847365505483757315757881358290997987566411094152979365138887296756948328586331512998302338589253371981862222567311575547535119204367711989264706447856735540009064253626477228443122859813377905066892144132699843498559243449950092751197689542000109628975246426903784546947014098996628813538732444830039564857133606257470083598362319405260521881094427831017148450902400820263700502406984100631416587468399764393182637578015087854029823,5668704)'); a = G.1; b = G.3; c = G.6; d = G.8; e = G.10; f = G.11; g = G.13; h = G.14; i = G.15; j = G.16;
 
Permutation group:Degree $36$ $\langle(1,8,26,19)(2,7,27,20)(3,9,25,21)(4,30,17,6,29,18)(5,28,16)(10,35,11,34,12,36) \!\cdots\! \rangle$ Copy content Toggle raw display
Copy content comment:Define the group as a permutation group
 
Copy content magma:G := PermutationGroup< 36 | (1,8,26,19)(2,7,27,20)(3,9,25,21)(4,30,17,6,29,18)(5,28,16)(10,35,11,34,12,36)(13,32,15,31)(14,33)(22,24,23), (1,22,3,23,2,24)(4,32,16,21,29,7)(5,33,18,19,28,8)(6,31,17,20,30,9)(10,27)(11,26)(12,25)(13,36,14,34,15,35) >;
 
Copy content gap:G := Group( (1,8,26,19)(2,7,27,20)(3,9,25,21)(4,30,17,6,29,18)(5,28,16)(10,35,11,34,12,36)(13,32,15,31)(14,33)(22,24,23), (1,22,3,23,2,24)(4,32,16,21,29,7)(5,33,18,19,28,8)(6,31,17,20,30,9)(10,27)(11,26)(12,25)(13,36,14,34,15,35) );
 
Copy content sage:G = PermutationGroup(['(1,8,26,19)(2,7,27,20)(3,9,25,21)(4,30,17,6,29,18)(5,28,16)(10,35,11,34,12,36)(13,32,15,31)(14,33)(22,24,23)', '(1,22,3,23,2,24)(4,32,16,21,29,7)(5,33,18,19,28,8)(6,31,17,20,30,9)(10,27)(11,26)(12,25)(13,36,14,34,15,35)'])
 
Copy content sage_gap:G = gap.new('Group( (1,8,26,19)(2,7,27,20)(3,9,25,21)(4,30,17,6,29,18)(5,28,16)(10,35,11,34,12,36)(13,32,15,31)(14,33)(22,24,23), (1,22,3,23,2,24)(4,32,16,21,29,7)(5,33,18,19,28,8)(6,31,17,20,30,9)(10,27)(11,26)(12,25)(13,36,14,34,15,35) )')
 
Copy content oscar:G = @permutation_group(36, (1,8,26,19)(2,7,27,20)(3,9,25,21)(4,30,17,6,29,18)(5,28,16)(10,35,11,34,12,36)(13,32,15,31)(14,33)(22,24,23), (1,22,3,23,2,24)(4,32,16,21,29,7)(5,33,18,19,28,8)(6,31,17,20,30,9)(10,27)(11,26)(12,25)(13,36,14,34,15,35))
 
Transitive group: 36T54995 more information
Copy content magma:G := TransitiveGroup(36, 54995);
 
Copy content gap:G := TransitiveGroup(36, 54995);
 
Copy content sage:G = TransitiveGroup(36, 54995)
 
Copy content sage_gap:G = libgap.TransitiveGroup(36, 54995)
 
Copy content oscar:G = transitive_group(36, 54995)
 
Direct product: not isomorphic to a non-trivial direct product
Semidirect product: not computed
Trans. wreath product: not isomorphic to a non-trivial transitive wreath product
Possibly split product: $(C_3^6.C_3.S_3^3)$ . $D_6$ $(C_3^7.C_3:S_3^3)$ . $C_4$ $C_3^7$ . $(C_3:S_3^3:C_4)$ $C_3^6$ . $(C_3^2:S_3^3:C_4)$ all 21

Elements of the group are displayed as permutations of degree 36.

Homology

Abelianization: $C_{2} \times C_{4} $
Copy content comment:The abelianization of the group
 
Copy content magma:quo< G | CommutatorSubgroup(G) >;
 
Copy content gap:FactorGroup(G, DerivedSubgroup(G));
 
Copy content sage:G.quotient(G.commutator())
 
Copy content sage_gap:G.FactorGroup(G.DerivedSubgroup())
 
Copy content oscar:quo(G, derived_subgroup(G)[1])
 
Schur multiplier: $C_{2}^{2}$
Copy content comment:The Schur multiplier of the group
 
Copy content gap:AbelianInvariantsMultiplier(G);
 
Copy content sage:G.homology(2)
 
Copy content sage_gap:G.AbelianInvariantsMultiplier()
 
Commutator length: $1$
Copy content comment:The commutator length of the group
 
Copy content gap:CommutatorLength(G);
 
Copy content sage_gap:G.CommutatorLength()
 

Subgroups

Copy content comment:List of subgroups of the group
 
Copy content magma:Subgroups(G);
 
Copy content gap:AllSubgroups(G);
 
Copy content sage:G.subgroups()
 
Copy content sage_gap:G.AllSubgroups()
 
Copy content oscar:subgroups(G)
 

There are 26 normal subgroups, and all normal subgroups are characteristic.

Characteristic subgroups are shown in this color.

Special subgroups

Center: $Z \simeq$ $C_1$ $G/Z \simeq$ $C_3^7.C_3:S_3^3:C_4$
Copy content comment:Center of the group
 
Copy content magma:Center(G);
 
Copy content gap:Center(G);
 
Copy content sage:G.center()
 
Copy content sage_gap:G.Center()
 
Copy content oscar:center(G)
 
Commutator: $G' \simeq$ $C_3^6.C_3^5.C_2^2$ $G/G' \simeq$ $C_2\times C_4$
Copy content comment:Commutator subgroup of the group G
 
Copy content magma:CommutatorSubgroup(G);
 
Copy content gap:DerivedSubgroup(G);
 
Copy content sage:G.commutator()
 
Copy content sage_gap:G.DerivedSubgroup()
 
Copy content oscar:derived_subgroup(G)
 
Frattini: $\Phi \simeq$ $C_3^6$ $G/\Phi \simeq$ $C_3^2:S_3^3:C_4$
Copy content comment:Frattini subgroup of the group G
 
Copy content magma:FrattiniSubgroup(G);
 
Copy content gap:FrattiniSubgroup(G);
 
Copy content sage:G.frattini_subgroup()
 
Copy content sage_gap:G.FrattiniSubgroup()
 
Copy content oscar:frattini_subgroup(G)
 
Fitting: $\operatorname{Fit} \simeq$ $C_3^7.C_3^4$ $G/\operatorname{Fit} \simeq$ $C_2^3:C_4$
Copy content comment:Fitting subgroup of the group G
 
Copy content magma:FittingSubgroup(G);
 
Copy content gap:FittingSubgroup(G);
 
Copy content sage:G.fitting_subgroup()
 
Copy content sage_gap:G.FittingSubgroup()
 
Copy content oscar:fitting_subgroup(G)
 
Radical: $R \simeq$ $C_3^7.C_3:S_3^3:C_4$ $G/R \simeq$ $C_1$
Copy content comment:Radical of the group G
 
Copy content magma:Radical(G);
 
Copy content gap:SolvableRadical(G);
 
Copy content sage_gap:G.SolvableRadical()
 
Copy content oscar:solvable_radical(G)
 
Socle: $\operatorname{soc} \simeq$ $C_3^4$ $G/\operatorname{soc} \simeq$ $(C_3^4.S_3^3):C_4$
Copy content comment:Socle of the group G
 
Copy content magma:Socle(G);
 
Copy content gap:Socle(G);
 
Copy content sage:G.socle()
 
Copy content sage_gap:G.Socle()
 
Copy content oscar:socle(G)
 
2-Sylow subgroup: $P_{ 2 } \simeq$ $C_2^3:C_4$
3-Sylow subgroup: $P_{ 3 } \simeq$ $C_3^7.C_3^4$

Subgroup diagram and profile

Series

Derived series $C_3^7.C_3:S_3^3:C_4$ $\rhd$ $C_3^6.C_3^5.C_2^2$ $\rhd$ $C_3^6.C_3^4$ $\rhd$ $C_3^6$ $\rhd$ $C_1$
Copy content comment:Derived series of the group G
 
Copy content magma:DerivedSeries(G);
 
Copy content gap:DerivedSeriesOfGroup(G);
 
Copy content sage:G.derived_series()
 
Copy content sage_gap:G.DerivedSeriesOfGroup()
 
Copy content oscar:derived_series(G)
 
Chief series $C_3^7.C_3:S_3^3:C_4$ $\rhd$ $C_3^6.C_3^5.C_2^2:C_4$ $\rhd$ $C_3^6.C_3^5.C_2^3$ $\rhd$ $C_3^6.C_3^5.C_2^2$ $\rhd$ $C_3^6.C_3^5.C_2$ $\rhd$ $C_3^7.C_3^4$ $\rhd$ $C_3^6.C_3^4$ $\rhd$ $C_3^6$ $\rhd$ $C_3^4$ $\rhd$ $C_1$
Copy content comment:Chief series of the group G
 
Copy content magma:ChiefSeries(G);
 
Copy content gap:ChiefSeries(G);
 
Copy content sage:libgap(G).ChiefSeries()
 
Copy content sage_gap:G.ChiefSeries()
 
Copy content oscar:chief_series(G)
 
Lower central series $C_3^7.C_3:S_3^3:C_4$ $\rhd$ $C_3^6.C_3^5.C_2^2$ $\rhd$ $C_3^6.C_3^5.C_2$ $\rhd$ $C_3^7.C_3^4$
Copy content comment:The lower central series of the group G
 
Copy content magma:LowerCentralSeries(G);
 
Copy content gap:LowerCentralSeriesOfGroup(G);
 
Copy content sage:G.lower_central_series()
 
Copy content sage_gap:G.LowerCentralSeriesOfGroup()
 
Copy content oscar:lower_central_series(G)
 
Upper central series $C_1$
Copy content comment:The upper central series of the group G
 
Copy content magma:UpperCentralSeries(G);
 
Copy content gap:UpperCentralSeriesOfGroup(G);
 
Copy content sage:G.upper_central_series()
 
Copy content sage_gap:G.UpperCentralSeriesOfGroup()
 
Copy content oscar:upper_central_series(G)
 

Supergroups

This group is a maximal subgroup of 2 larger groups in the database.

This group is a maximal quotient of 0 larger groups in the database.

Character theory

Copy content comment:Character table
 
Copy content magma:CharacterTable(G); // Output not guaranteed to exactly match the LMFDB table
 
Copy content gap:CharacterTable(G); # Output not guaranteed to exactly match the LMFDB table
 
Copy content sage:G.character_table() # Output not guaranteed to exactly match the LMFDB table
 
Copy content sage_gap:G.CharacterTable() # Output not guaranteed to exactly match the LMFDB table
 
Copy content oscar:character_table(G) # Output not guaranteed to exactly match the LMFDB table
 

Complex character table

The $242 \times 242$ character table is not available for this group.

Rational character table

The $159 \times 159$ rational character table is not available for this group.