User:Tomruen/polychoric groups

Conway[edit]

TEXT FROM (And extended tables by me for Coxeter's real notations, and group orders calculated)

Conway and Smith: On Quaternions and Octonions, Chapter 4, section 4.4 Coxeter's Notations for the Polyhedral Groups

Coxeter's notations (adapted from Schlafli) for regular polytopes and associated groups are widely used. Conway extended his system slightly to obtain a complete set of notations for the "polyhedral groups".

Coxeter uses [p,q,...,r,s] for the symmetry group of the n-dimensional polytope {p,q,...,r,s} - this is generated by reflections R1, ... Rn, corresponding to the nodes of the n-node Coxeter diagram: ....

This has an obvious subgroup [p,q,...,r,s]⁺ of index 2, consisting of the even length words in R1...Rn, i.e. those which "mention R1..Rn evenly."

When just one of the numbers p,q,...r,s is even say that between Rk and Rk+1, there exists two further subgroups, namely... [p⁺,q,...,r,s] and [p,q,...,r,s⁺] consisting of words that mention respectively R1...Rk, and Rk+1..Rn evenly, whose intersection is the index 4 subgroup [⁺p,q,...,r,s⁺] of words that mention both of these sets evenly. We've slightly modified Coxeter's notation - he writes [p⁺...] and uses only some special cases.

To obtain elegant names for all of the polyhedral groups in dimension 4, we supplement Coxeter's notation by writing G^o for the "opposite" group to G, obtained by replacing the element g of G by +g, or -g accordingly as det = +1 or -1. Finally an initial "2." indicates doubling the group by adjoining negatives, while a final ":2" or "2" indicates doubling in some other way, either split or non-split.

± implies central inversion (double rotation), trailing .2 implies reflective symmetry

Chiral I
Group	Order	DuV	Coxeter
±[I×O]	2880	#29	²/₅[5,3,3]⁺
±[I×T]	1440	#24	¹/₅[5,3,3]⁺
±[I×D_2n]	240n	#19	²ⁿ/₁₂₀[5,3,3]⁺
±[I×C_n]	120n	#9	ⁿ/₁₂₀[5,3,3]⁺
±[O×T]	576	#23	[[3⁺,4,3⁺]]
±[O×D_2n]	96n	#15
±¹/₂[O×D_2n]	48n	#16
±¹/₂[O×D_4n]	96n	#17
±¹/₆[O×D_6n]	48n	#18
±[O×C_n]	48n	#7
±¹/₂[O×C_2n]	48n	#8
±[T×D_2n]	48n	#14
±[T×C_n]	24n	#5
±¹/₃[T×C_3n]	24n	#6

Chiral II					Achiral
Group	Order	DuV	Coxeter (Conway)	Coxeter (Real)	Group	Order	DuV	Coxeter (Conway)	Coxeter (Real)
±[I×I]	7200	#30	[3,3,5]⁺		±[I×I].2	14400	#50	[3,3,5]
±¹/₆₀[I×I]	120	#31	2.[3,5]⁺	[2,3,5]⁺	±¹/₆₀[I×I].2	240	#49	2.[3,5]	[2,3,5]
+¹/₆₀[I×I]	60	#31'	[3,5]⁺		+¹/₆₀[I×I].2₃	120	#49"	[3,5]
+¹/₆₀[I×I]	60	#31'	[3,5]⁺		+¹/₆₀[I×I].2₁	120	#49'	[3,5]^o	[2,(3,5)⁺]
±¹/₆₀[I×I]	120	#32	2.[3,3,3]⁺	[[3,3,3]]⁺	±¹/₆₀[I×I].2	240	#51	2.[3,3,3]	[[3,3,3]]
+¹/₆₀[I×I]	60	#32'	[3,3,3]⁺		+¹/₆₀[I×I].2₃	120	#51"	[3,3,3]^o	[[3,3,3]⁺]
+¹/₆₀[I×I]	60	#32'	[3,3,3]⁺		+¹/₆₀[I×I].2₁	120	#51'	[3,3,3]
±[O×O]	1152	#25	[3,4,3]⁺:2	[[3,4,3]]⁺	±[O×O].2	2304	#48	[3,4,3]:2	[[3,4,3]]
±¹/₂[O×O]	576	#28	[3,4,3]⁺		±¹/₂[O×O].2₃	1152	#45	[3,4,3]
±¹/₂[O×O]	576	#28	[3,4,3]⁺		±¹/₂[O×O].2	1152	#46	[3,4,3]⁺.2	[[3,4,3]⁺]
±¹/₆[O×O]	192	#27	[3,3,4]⁺		±¹/₆[O×O].2	384	#47	[3,3,4]
±¹/₂₄[O×O]	48	#26	2.[3,4]⁺	[2,3,4]⁺	±¹/₂₄[O×O].2	96	#44	2.[3,4]	[2,3,4]
+¹/₂₄[O×O]	24	#26'	[3,4]⁺		+¹/₂₄[O×O].2₃	48	#44"	[3,4]
+¹/₂₄[O×O]	24	#26'	[3,4]⁺		+¹/₂₄[O×O].2₁	48	#44'	[3,4]^o	[2,(3,4)⁺]
+¹/₂₄[O×O]	24	#26"	[2,3,3]⁺		+¹/₂₄[O×O].2₃	48	#40"	[2,3,3]
+¹/₂₄[O×O]	24	#26"	[2,3,3]⁺		+¹/₂₄[O×O].2₁	48	#40'	[2,3,3]^o	[(2,3)⁺,4]
±[T×T]	288	#20	[⁺3,4,3⁺]	[3⁺,4,3⁺]	±[T×T].2	576	#43	[3,4,3⁺]
±¹/₃[T×T]	96	#22	[⁺3,3,4⁺]	[(3,3)⁺,4,1⁺] =[3^1,1,1]⁺	±¹/₃[T×T].2	192	#41	[⁺3,3,4]	[(3,3)⁺,4]
≈ ±¹/₃[T×T]	96	#22	[⁺3,3,4⁺]	[(3,3)⁺,4,1⁺] =[3^1,1,1]⁺	±¹/₃[T×T].2	192	#42	[3,3,4⁺]	[3,3,4,1⁺]
±¹/₁₂[T×T]	24	#21	2.[3,3]⁺	[3⁺,4,2⁺]	±¹/₁₂[T×T].2	48	#39	2.[3⁺,4]	[3⁺,4,2]
≈ ±¹/₁₂[T×T]	24	#21	2.[3,3]⁺	[3⁺,4,2⁺]	±¹/₁₂[T×T].2	48	#39'	2.[3,3]	[3,4,2⁺]
+¹/₁₂[T×T]	12	#21'	[3,3]⁺		+¹/₁₂[T×T].2₃	24		[3⁺,4]
+¹/₁₂[T×T]					+¹/₁₂[T×T].2₁	24		[3⁺,4]^o	[(3,4)⁺,2⁺]
≈ +¹/₁₂[T×T]					+¹/₁₂[T×T].2₃	24	#39'	[3,3]^o	[(3,3)⁺,2]
≈ +¹/₁₂[T×T]					+¹/₁₂[T×T].2₁	24	#39"	[3,3]

Duoprismatic[edit]

Duoprismatic

Chiral I
Group	Order	DuV	Coxeter
±¹/₂[D_2m×D_4n]	8mn	#13
±[D_2m×C_n]	4mn
±¹/₂[D_2m×C_2n]	4mn
+¹/₂[D_2m×C_2n]	2mn
±¹/₂[D_4m×C_2n]	8mn

Chiral II				Achiral
Group	Order	DuV	Coxeter	Group	Order	DuV	Coxeter
±[D_2m×D_2n]	8mn		[2m⁺,2,2n⁺]	±[D_2n×D_2n].2	16n²
±¹/₂[D_4m×D_4n]	16mn			±¹/₂[D_4n×D_4n].2	32n²
±¹/₂[D_4m×D_4n]	16mn			±¹/₂[D_4n×D_4n].2	32n²
±¹/₄[D_4m×D_4n]	8mn			±¹/₄[D_4n×D_4n].2	16n²
±¹/₂[D_2m×D_2n]	4mn	#11	[4m⁺,2⁺,4n⁺]	±¹/₂[D_2n×D_2n].2	8n²
±¹/₂[D_2m×D_2n]	4mn	#11	[4m⁺,2⁺,4n⁺]	±¹/₂[D_2n×D_2n].2	8n²
±[C_m×C_n]	2mn	#1	[2m⁺,2⁺,2n⁺]	±[C_n×C_n].2	4n²
m,n odd
+¹/₄[D_4m×D_4n]	4mn			+¹/₄[D_4n×D_4n].2₃	8n²
+¹/₄[D_4m×D_4n]	4mn			+¹/₄[D_4nxD_4n].2₁	8n²
+¹/₂[D_2m×D_2n]	2mn	#11'	[4m⁺,2⁺,4n⁺]⁺	+¹/₂[D_2n×D_2n].2	4n²
+¹/₂[D_2m×D_2n]	2mn	#11'	[4m⁺,2⁺,4n⁺]⁺	+¹/₂[D_2n×D_2n].2	4n²
+[C_m×C_n]	mn	#1'	[2m⁺,2⁺,2n⁺]⁺	+[C_n×C_n].2	2n²

Chiral II			Achiral
±¹/_2f[D_2f×D_2f^(s)]	4f	#11	±¹/_2f[D_2f×D_2f^(s)].2^(α,β)	8f
±¹/_2f[D_2f×D_2f^(s)]	4f	#11	±¹/_2f[D_2f×D_2f^(s)].2	8f
+¹/_2f[D_2f×D_2f^(s)]	2f	#11'	+¹/_2f[D_2f×D_2f^(s)].2^(α,β)	4f
+¹/_2f[D_2f×D_2f^(s)]	2f	#11'	+¹/_2f[D_2f×D_2f^(s)].2	4f
±¹/_f[C_f×C_f^(s)]	2f	#1	±¹/_f[C_f×C_f^(s)].2^(γ)	4f
+¹/_f[C_f×C_f^(s)]	f	#1'	+¹/_f[C_f×C_f^(s)].2^(γ)	2f

m,n odd
Chiral II			Achiral
±¹/_2f[D_2mf×D_2nf^(s)]	4mnf	#11	±¹/_2f[D_2nf×D_2nf^(s)].2^(α,β)	8n²f
±¹/_2f[D_2mf×D_2nf^(s)]	4mnf	#11	±¹/_2f[D_2nf×D_2nf^(s)].2	8n²f
+¹/_2f[D_2mf×D_2nf^(s)]	2mnf	#11'	+¹/_2f[D_2nf×D_2nf^(s)].2^(α,β)	4n²f
+¹/_2f[D_2mf×D_2nf^(s)]	2mnf	#11'	+¹/_2f[D_2nf×D_2nf^(s)].2	4n²f
±¹/_f[C_mf×C_nf^(s)]	2mnf	#1	±¹/_f[C_nf×C_nf^(s)].2^(γ)	4n²f
+¹/_f[C_mf×C_nf^(s)]	mnf	#1'	+¹/_f[C_nf×C_nf^(s)].2^(γ)	2n²f

Coxeter[edit]

From:

H.S.M. Coxeter: Kaleidoscopes: Selected Writings of H.S.M. Coxeter, edited by F. Arthur Sherk, Peter McMullen, Anthony C. Thompson, Asia Ivic Weiss, Wiley-Interscience Publication, 1995, ISBN 978-0-471-01003-6 [1]
(Paper 23) H.S.M. Coxeter, Regular and Semi-Regular Polytopes II, [Math. Zeit. 188 (1985) 559-591]

Symbol	Order.index	Du Val's symbol	Conway	Structure
[3,3,2]⁺	24.10	(T/C₂;T/C₂)	+¹/₂₄[O×O]	C₂×A₄
[(3,3)⁺,2]	24.10	(T/C₁;T/C₁)_c^*	±¹/₁₂[T×T].2₁	C₂×A₄
[[3,2,3]⁺]	36.14	(D₃/C₃;D₃/C₃)^*		(4,4\|2,3)
[4,3,2]⁺	48.36	(O/C₂;O/C₂)	±¹/₂₄[O×O]	C₂×S₄
[3,3,2]	48.36	(O/C₁;O/C₁)^*	+¹/₂₄[O×O].2₃	C₂×S₄
[(4,3)⁺,2]	48.36	(O/C₁;O/C₁)_-^*	+¹/₂₄[O×O].2₁	C₂×S₄
[3⁺,4,2]	48.22	(T/C₂;T/C₂)_c^*	±¹/₁₂[T×T].2	D₂×A₄
[3,3,3]⁺	60.13	(I^†/C₁;I/C₁)^†	+¹/₆₀[I×I]	A₅
[1⁺,4,3,3]⁺	96.1	(T/V;T/V)	±¹/₃[T×T]	?
[4,3,2]	96.5	(O/C₂;O/C₂)^*	±¹/₂₄[O×O].2	D₂×S₄
[3,3,3]	120.1	(I^†/C₁;I/C₁)^†*	+¹/₆₀[I×I].2₃	S₅=(4,6\|2,3)
[[3,3,3]⁺]	120.1	(I^†/C₁;I/C₁)_-^†*	+¹/₆₀[I×I].2₁	S₅
[[3,3,3]]⁺	120.2	(I^†/C₂;I/C₂)^†	±¹/₆₀[I×I]	C₂×A₅
[5,3,2]⁺	120 (non-c)	(I/C₂;I/C₂)	±¹/₆₀[I×I]	C₂×A₅
[(5,3)⁺,2]	120 (non-c)	(I/C₁;I/C₁)^*	+¹/₆₀[I×I].2₁	C₂×A₅
[4,3,3]⁺	192.3	(O/V;O/V)	±¹/₆[O×O]	?
[(3,3)⁺,4]	192.1	(T/V;T/V)^*	±¹/₃[T×T].2	?
[3,3,4,1⁺]	192.2	(T/V;T/V)_-^*	±¹/₃[T×T].2	?
[[3,3,3]]	240.1	(I^†/C₂;I/C₂)^†*	±¹/₆₀[I×I].2	C₂×S₅
[5,3,2]	240 (non-c.)	(I/C₂;I/C₂)^*	±¹/₆₀[I×I].2	D₂×A₅
[3⁺,4,3⁺]	288.1	(T/T;T/T)	±[T×T]	?
[4,3,3]	384.1	(O/V;O/V)^*	±¹/₆[O×O].2	C₂^S₄
[3,4,3]⁺	576.2	(O/T;O/T)	±¹/₂[O×O]	?
[3⁺,4,3]	576.1	(T/T;T/T)^*	±[T×T].2	?
[[3⁺,4,3⁺]]	576 (non-c)	(T/T;O/O)	±[O×T]	?
[3,4,3]	1152.1	(O/T;O/T)^*	[O×O].2₃	?
[[3,4,3]⁺]	1152 (non-c)	(O/T;O/T)_-^*	±¹/₂[O×O].2	(4,8\|2,3)
[[3,4,3]]⁺	1152 (non-c)	(O/O;O/O)	±[O×O]	?
[[3,4,3]]	2304 (non-c)	(O/O;O/O)^*	±[O×O].2	?
[5,3,3]⁺	7200 (non-c)	(I/I;I/I)	±[I×I]	?
[5,3,3]	14400 (non-c)	(I/I;I/I)^*	±[I×I].2	?

(non-c) = noncrystalographic (4-space symmetry)

By reflective groups[edit]

Finite groups

[ ]:
Symbol	Order
[1]⁺	1.1
[1] = [ ]	2.1

[2]:
Symbol	Order
[1⁺,2]⁺	1.1
[2]⁺	2.1
[2]	4.1

[2,2]:
Symbol	Order
[2⁺,2⁺]⁺ = [(2⁺,2⁺,2⁺)]	1.1
[2⁺,2⁺]	2.1
[2,2]⁺	4.1
[2⁺,2]	4.1
[2,2]	8.1

[2,2,2]:
Symbol	Order
[(2⁺,2⁺,2⁺,2⁺)] = [2⁺,2⁺,2⁺]⁺	1.1
[2⁺,2⁺,2⁺]	2.1
[2⁺,2,2⁺]	4.1
[(2,2)⁺,2⁺]	4
[[2⁺,2⁺,2⁺]]	4
[2,2,2]⁺	8
[2⁺,2,2]	8.1
[(2,2)⁺,2]	8
[[2⁺,2,2⁺]]	8.1
[2,2,2]	16.1
[[2,2,2]]⁺	16
[[2,2⁺,2]]	16
[[2,2,2]]	32

[p]:
Symbol	Order
[p]⁺	p
[p]	2p

[p,2]:
Symbol	Order
[p,2]⁺	2p
[p,2]	4p

[2p,2⁺]:
Symbol	Order
[2p,2⁺]	4p
[2p⁺,2⁺]	2p

[p,2,2]:
Symbol	Order
[p⁺,2,2⁺]	2p
[(p,2)⁺,2⁺]	2p
[p,2,2]⁺	4p
[p,2,2⁺]	4p
[p⁺,2,2]	4p
[(p,2)⁺,2]	4p
[p,2,2]	8p

[2p,2⁺,2]:
Symbol	Order
[2p⁺,2⁺,2⁺]⁺	p
[2p⁺,2⁺,2⁺]	2p
[2p⁺,2⁺,2]	4p
[2p⁺,(2,2)⁺]	4p
[2p,(2,2)⁺]	8p
[2p,2⁺,2]	8p

[p,2,q]:
Symbol	Order
[p⁺,2,q⁺]	pq
[p,2,q]⁺	2pq
[p⁺,2,q]	2pq
[p,2,q]	4pq
Symbol	Order
[(p,2)⁺,2q⁺]	2pq
[(p,2)⁺,2q]	4pq

[2p,2,2q]:
Symbol	Order
[2p⁺,2⁺,2q⁺]⁺= [(2p⁺,2⁺,2q⁺,2⁺)]	pq
[2p⁺,2⁺,2q⁺]	2pq
[2p,2⁺,2q⁺]	4pq
[((2p,2)⁺,(2q,2)⁺)]	4pq
[2p,2⁺,2q]	8pq

[[p,2,p]]:
Symbol	Order
[[p⁺,2,p⁺]]	2p²
[[p,2,p]]⁺	4p²
[[p,2,p]⁺]	4p²
[[p,2,p]]	8p²

[[2p,2,2p]]:
Symbol	Order
[[(2p⁺,2⁺,2p⁺,2⁺)]]	2p²
[[2p⁺,2⁺,2p⁺]]	4p²
[[((2p,2)⁺,(2p,2)⁺)]]	8p²
[[2p,2⁺,2p]]	16p²

[3,3,2]:
Symbol	Order
[(3,3)^Δ,2,1⁺] ≅ [2,2]⁺	4
[(3,3)^Δ,2] ≅ [2,(2,2)⁺]	8
[(3,3)^⅄,2,1⁺] ≅ [4,2⁺]	8
[(3,3)⁺,2,1⁺] = [3,3]⁺	12.5
[(3,3)^⅄,2] ≅ [2,4,2⁺]	16
[3,3,2,1⁺] = [3,3]	24
[(3,3)⁺,2]	24.10
[3,3,2]⁺	24.10
[3,3,2]	48.36

[4,3,2]:
Symbol	Order
[1⁺,4,3⁺,2,1⁺] = [3,3]⁺	12
[3⁺,4,2⁺]	24
[(3,4)⁺,2⁺]	24
[1⁺,4,3⁺,2] = [(3,3)⁺,2]	24.10
[3⁺,4,2,1⁺] = [3⁺,4]	24.10
[(4,3)⁺,2,1⁺] = [4,3]⁺	24.15
[1⁺,4,3,2,1⁺] = [3,3]	24
[1⁺,4,(3,2)⁺] = [3,3,2]⁺	24
[3,4,2⁺]	48
[4,3⁺,2]	48.22
[4,(3,2)⁺]	48
[(4,3)⁺,2]	48.36
[1⁺,4,3,2] = [3,3,2]	48.36
[4,3,2,1⁺] = [4,3]	48.36
[4,3,2]⁺	48.36
[4,3,2]	96.5

[5,3,2]:
Symbol	Order
[(5,3)⁺,2,1⁺] = [5,3]⁺	60.13
[5,3,2,1⁺] = [5,3]	120.2
[(5,3)⁺,2]	120.2
[5,3,2]⁺	120.2
[5,3,2]	240 (nc)

[3^1,1,1]:
Symbol	Order
[3^1,1,1]^Δ ≅[[4,2⁺,4]]⁺	32
[3^1,1,1]^⅄	64
[3^1,1,1]⁺	96.1
[3^1,1,1]	192.2
<[3,3^1,1]> = [4,3,3]	384.1
[3[3^1,1,1]] = [3,4,3]	1152.1

[3,3,3]:
Symbol	Order
[3,3,3]⁺	60.13
[3,3,3]	120.1
[[3,3,3]]⁺	120.2
[[3,3,3]⁺]	120.1
[[3,3,3]]	240.1

[4,3,3]:
Symbol	Order
[1⁺,4,(3,3)^Δ] = [3^1,1,1]^Δ ≅[[4,2⁺,4]]⁺	32
[4,(3,3)^Δ] = [2⁺,4[2,2,2]⁺] ≅[[4,2⁺,4]]	64
[1⁺,4,(3,3)^⅄] = [3^1,1,1]^⅄	64
[1⁺,4,(3,3)⁺] = [3^1,1,1]⁺	96.1
[4,(3,3)^⅄] ≅ [[4,2,4]]	128
[1⁺,4,3,3] = [3^1,1,1]	192.2
[4,(3,3)⁺]	192.1
[4,3,3]⁺	192.3
[4,3,3]	384.1

[3,4,3]:
Symbol	Order
[3⁺,4,3⁺]	288.1
[3,4,3^⅄] = [4,3,3]	384.1
[3,4,3]⁺	576.2
[3⁺,4,3]	576.1
[[3⁺,4,3⁺]]	576 (nc)
[3,4,3]	1152.1
[[3,4,3]]⁺	1152 (nc)
[[3,4,3]⁺]	1152 (nc)
[[3,4,3]]	2304 (nc)

[5,3,3]:
Symbol	Order
[5,3,3]⁺	7200 (nc)
[5,3,3]	14400 (nc)