Home Pentagonal quasigroups, their translatability and parastrophes
Article Open Access

Pentagonal quasigroups, their translatability and parastrophes

  • Wieslaw A. Dudek EMAIL logo and Robert A. R. Monzo
Published/Copyright: May 3, 2021
Download Article (PDF)
Open Mathematics
From the journal Open Mathematics Volume 19 Issue 1

Abstract

Any pentagonal quasigroup Q is proved to have the product x y = φ ( x ) + y φ ( y ) , where ( Q , + ) is an Abelian group, φ is its regular automorphism satisfying φ 4 φ 3 + φ 2 φ + ε = 0 and ε is the identity mapping. All Abelian groups of order n < 100 inducing pentagonal quasigroups are determined. The variety of commutative, idempotent, medial groupoids satisfying the pentagonal identity ( x y x ) y x = y is proved to be the variety of commutative, pentagonal quasigroups, whose spectrum is { 1 1 n : n = 0 , 1 , 2 , } . We prove that the only translatable commutative pentagonal quasigroup is x y = ( 6 x + 6 y ) ( mod 11 ) . The parastrophes of a pentagonal quasigroup are classified according to well-known types of idempotent translatable quasigroups. The translatability of a pentagonal quasigroup induced by the group Z n and its automorphism φ ( x ) = a x is proved to determine the value of a and the range of values of n .

Keywords: quasigroup; pentagonal quasigroup; translatability; idempotent
MSC 2010: 20N02; 20N05

1 Introduction

A latin square n × n is k -translatable if it is obtained by the following rule: if the first row is a 1 , a 2 , , a n , then the q th row is obtained from the ( q 1 ) -st row by taking the last k entries in the ( q 1 ) -st row and inserting them as the first k entries of the q th row and by taking the first n k entries of the ( q 1 ) -st row and inserting them as the last n k entries of the q th row, where q { 2 , 3 , , n } . An algebraic interpretation of translatable latin squares is translatable quasigroups.

Pentagonal quasigroups are medial idempotent quasigroups with a beautiful geometric interpretation. Any identity in the pentagonal quasigroup can be interpreted as a theorem of the Euclidean geometry which can be proved directly, but the theory of pentagonal quasigroups gives a better insight into the mutual relations of such theorems.

This paper was inspired by the work of Vidak in [1]. It is also a continuation of the ideas appearing in [2]. All results here follow from the main result, Theorem 2.1, which gives a new characterization of a pentagonal quasigroup ( Q , ) in terms of a regular automorphism φ on an Abelian group ( Q , + ) , where x y = φ ( x ) + y φ ( y ) , φ 4 φ 3 + φ 2 φ + ε = 0 and ε is the identity mapping on Q . We say then that ( Q , + ) induces the pentagonal quasigroup ( Q , ) .

Notice that x y = ( ε φ ) ( y ) + x ( ε φ ) ( x ) . The characterization of a pentagonal quasigroup ( Q , ) given by Vidak in [1] is that x y = ψ ( y ) + x ψ ( x ) for some automorphism ψ on an Abelian group ( Q , + ) , where ψ 4 3 ψ 3 + 4 ψ 2 2 ψ + ε = 0 . Now since, when φ 4 φ 3 + φ 2 φ + ε = 0 , ( ε φ ) 4 3 ( ε φ ) 3 + 4 ( ε φ ) 2 2 ( ε φ ) + ε = 0 , we can think of ψ as equal to ε φ .

In Theorem 3.3, we prove that a pentagonal quasigroup induced by the group Z n has the form x y = ( a x + ( 1 a ) y ) ( mod n ) , where ( a 4 a 3 + a 2 a + 1 ) = 0 ( mod n ) . Vidak’s identity gives the second component, namely, ψ ( x ) = ( 1 a ) x ( mod n ) .

As a consequence of our characterization, all Abelian groups of order n < 100 that induce pentagonal quasigroups are determined. Also, the variety of commutative, idempotent, medial groupoids satisfying the pentagonal identity ( x y x ) y x = y is proved in Corollary 3.10 to be the variety of commutative, pentagonal quasigroups, whose spectrum is { 1 1 n : n = 0 , 1 , 2 , } . The form of commutative pentagonal quasigroups is determined in Proposition 3.9 and as a corollary we prove that the only translatable commutative pentagonal quasigroup is x y = ( 6 x + 6 y ) ( mod 11 ) . In Theorem 4.2, we prove that the translatability of a pentagonal quasigroup induced by the group Z n and its automorphism φ ( x ) = a x determines the value of a and all the possible values of n . This characterizes translatable latin squares isotopic to the Cayley table of the cyclic group of order n .

Using results from [3] in the last table we classify the parastrophes of pentagonal quasigroups in terms of well-known types of idempotent translatable quasigroups and indirectly latin squares conjugates with an idempotent translatable latin square of certain types.

2 Existence of pentagonal quasigroups

All considered quasigroups are finite and have form Q = { 1 , 2 , , n } with the natural ordering, which is always possible by renumeration of elements. For simplicity, instead of ( x + y ) z ( mod n ) we write [ x + y ] n = [ z ] n . Also, in calculations modulo n we identify 0 with n .

According to [1] a quasigroup ( Q , ) is called pentagonal if it satisfies the following three identities:

(1) x x = x ,

(2) x y z u = x z y u ,

(3) ( x y x ) y x = y .

Let us recall that a mapping φ of a group ( Q , + ) onto ( Q , + ) is called regular if φ ( x ) = x holds only for x = 0 .

Below we present a full characterization of pentagonal quasigroups.

Theorem 2.1

A groupoid ( Q , ) is a pentagonal quasigroup if and only if on Q one can define an Abelian group ( Q , + ) and its regular automorphism φ such that

(4) x y = φ ( x ) + ( ε φ ) ( y ) ,

(5) φ 4 φ 3 + φ 2 φ + ε = 0 ,

where ε is the identity automorphism.

Proof

By the Toyoda theorem (see, for example, [4]), any quasigroup ( Q , ) satisfying (1) and (2) can be presented in the form (4), where ( Q , + ) is an Abelian group and φ is its automorphism. Applying this fact to (3) and putting y = 0 we obtain (5). From (5) it follows that the automorphism φ is regular.

Conversely, a groupoid ( Q , ) defined by (4), where φ is a regular automorphism of an Abelian group ( Q , + ) , is a quasigroup satisfying (1) and (2). Applying (5) to z = x y and using (4), after simple calculations, we obtain (3).□

This means that pentagonal quasigroups are isotopic to the group inducing them. Thus, pentagonal quasigroups are isotopic if and only if they are induced by isomorphic groups.

Example 2.2

Let ( C , + ) be the additive group of complex numbers. Then φ ( z ) = z e π 5 i is a regular automorphism of ( C , + ) satisfying (5). Thus, by Theorem 2.1, the set of complex numbers with multiplication defined by (4) is an infinite pentagonal quasigroup.

As a consequence of the aforementioned theorem we obtain:

Corollary 2.3

On a pentagonal quasigroup ( Q , ) one can define an Abelian group ( Q , + ) and its regular automorphism φ such that (4) holds and

φ 5 + ε = 0 and φ ε or φ = ε and exp ( Q , + ) = 5 ,

where ε is the identity automorphism.

Corollary 2.4

A finite Abelian group inducing a pentagonal quasigroup is the direct product of cyclic groups of order 5 or has a regular automorphism of order 10.

The converse statement is not true. The automorphism φ ( x ) = [ 4 x ] 25 of the group Z 25 is regular and satisfies the aforementioned condition, but Z 25 with the multiplication x y = [ 4 x + 22 y ] 25 is not a pentagonal quasigroup.

The following lemma is obvious.

Lemma 2.5

The direct product of pentagonal quasigroups is also a pentagonal quasigroup.

Corollary 2.6

For every t there is a pentagonal quasigroup of order 5 t .

Proof

For t = 0 it is trivial quasigroup. For t = 1 it is induced by the additive group Z 5 and has the form x y = [ 4 x + 2 y ] 5 . For t > 1 it is the direct product of t copies of the last quasigroup.□

Proposition 2.7

If finite Abelian groups G 1 and G 2 have relatively prime orders, then any pentagonal quasigroup induced by the group G 1 × G 2 is the direct product of pentagonal quasigroups induced by groups G 1 and G 2 .

Proof

If G 1 and G 2 have relatively prime orders, then, according to Lemma 2.1 in [5], Aut ( G 1 × G 2 ) Aut ( G 1 ) × Aut ( G 2 ) . So, each automorphism φ of G 1 × G 2 can be treated as an automorphism of the form φ = ( φ 1 , φ 2 ) , where φ 1 , φ 2 are automorphisms of G 1 and G 2 , respectively. Obviously, φ is regular if and only if φ 1 and φ 2 are regular. Moreover, φ satisfies (5) if and only if φ 1 and φ 2 satisfy (5). Thus, a pentagonal quasigroup induced by G 1 × G 2 is the direct product of pentagonal quasigroups induced by G 1 and G 2 .□

To determine Abelian groups that induce pentagonal quasigroups, we will need the following theorem proved in [5].

Theorem 2.8

The Abelian group G = Z p α 1 × Z p α 2 × × Z p α m has

Aut ( G ) = k = 1 m ( p d k p k 1 ) j = 1 m ( p α j ) m d j i = 1 m ( p α i 1 ) m + 1 c i ,

where d k = max { l : α l = α k } and c k = min { l : α l = α k } .

3 Construction of pentagonal quasigroups

We start with the characterization of pentagonal quasigroups induced by Z n .

Theorem 3.1

A groupoid ( Q , ) of order n > 2 is a pentagonal quasigroup induced by the group Z n if and only if there exist 1 < a < n such that ( a , n ) = ( a 1 , n ) = 1 , x y = [ a x + ( 1 a ) y ] n and

(6) [ a 4 a 3 + a 2 a + 1 ] n = 0 .

Proof

Automorphisms of the group Z n have the form φ ( x ) = a x , where ( a , n ) = 1 . Since ε φ also is an automorphism, ( a 1 , n ) = 1 . Moreover, the equation ( a 1 ) x = 0 ( mod n ) has d = ( a 1 , n ) solutions (cf. [6]). So, ( a 1 , n ) = 1 means that the automorphism φ ( x ) = a x is regular. Theorem 2.1 completes the proof.□

Theorem 3.2

If a regular automorphism φ of an Abelian group ( Q , + ) satisfies (5), then ( Q , ) , ( Q , ) and ( Q , ) with the operations

x y = φ 2 ( y x ) + y , x y = φ 3 ( x y ) + y , x y = φ 4 ( y x ) + y

are pentagonal quasigroups.

Proof

If φ and ( Q , + ) are as in the assumption, then, by Theorem 2.1, ( Q , ) with the operation x y = φ ( x y ) + y is a pentagonal quasigroup. From Vidak’s results presented in [1] it follows that also ( Q , ) , ( Q , ) and ( Q , ) , where x y = y ( y x x ) x , x y = ( y x y ) x and x y = ( x y x ) y , are pentagonal quasigroups. Applying (4) and (5) to these operations we obtain our thesis.□

Theorem 3.3

A pentagonal quasigroup induced by the group Z n has one of the following forms:

x y = [ a x + ( 1 a ) y ] n , x y = [ a 2 x + ( 1 + a 2 ) y ] n , x y = [ a 3 x + ( 1 a 3 ) y ] n , x y = [ a 4 x + ( 1 + a 4 ) y ] n ,

where 1 < a < n 1 satisfy (6) and ( a , n ) = ( a 1 , n ) = 1 .

When a = n 1 there is only one pentagonal quasigroup. It is induced by Z 5 and has the form x y = [ 4 x + 2 y ] 5 .

Proof

Equation (6) has no more than four solutions, so Z n induces no more than four pentagonal quasigroups. Theorems 3.1 and 3.2 complete the proof for 1 < a < n 1 . The case a = n 1 is obvious.□

Note that for [ a + 1 ] n 0 the equation (6) implies [ a 5 + 1 ] n = 0 . Since it is also valid for a = 1 in a pentagonal quasigroup with x y = [ a x + ( 1 a ) y ] n we have

(7) [ a 5 ] n = n 1 .

Proposition 3.4

Let ( Q , ) be a pentagonal quasigroup induced by the group Z n , where n > 5 . If m n , then ( Q , ) contains a pentagonal subquasigroup of order m .

Proof

If m n , then the group Z n contains a subgroup isomorphic to Z m . Let x y = [ a x + ( 1 a ) y ] n . Since 1 < a < n 1 , ( a , n ) = ( a 1 , n ) = 1 , also ( a , m ) = ( a 1 , m ) = 1 and [ a 4 a 3 + a 2 a + 1 ] m = 0 . Let a = [ a ] m . Then, as it is not difficult to see, Z m with the multiplication x y = [ a x + ( 1 a ) y ] m is a pentagonal quasigroup.□

Proposition 3.5

If an Abelian group G inducing a pentagonal quasigroup has an element of order k > 1 , then the number of such elements is greater than 3.

Proof

An automorphism preserves the order of elements of G . So, if only one x G has order k > 1 , then φ ( x ) = x , which contradicts to the assumption on φ . If only two elements x y have order k > 1 , then φ ( x ) = y and φ 2 ( x ) = x . Using (5) we get 3 x = 2 y and 3 y = 2 x . Therefore, 2 x = 3 y = y + 3 x , which implies that x = y . But k ( 2 x ) = 2 ( k x ) = 0 . Also 2 x 0 or else x = x = y , a contradiction. Thus, 2 x has order k . Then 2 x = x or 2 x = y . The first case is impossible. In the second 2 x = y = 3 y implies 2 y = 0 , so y = y = x , a contradiction. Therefore, G has at least three elements of order k .

If G has three distinct elements x , y , z of order k > 1 , then φ ( x ) = y , φ 2 ( x ) = φ ( y ) = z , φ 3 ( x ) = φ ( z ) = x . Obviously, φ ( x ) x , because φ ( x ) = x implies x = φ 2 ( x ) = z , which is impossible. Thus, by Corollary 2.3, 0 = φ 5 ( x ) + x = z + x and 0 = φ ( z ) + φ ( x ) = x + y . So, x + z = x + y , a contradiction. Hence, G has more than three elements of order k > 1 .□

Corollary 3.6

Abelian groups of order n , where

  1. 2 n and 4 n or

  2. 3 n and 9 n or

  3. 4 n and 8 n ,

do not induce pentagonal quasigroups.

Proof

In the first case, a group has one element of order 2; in the second – two elements of order 3; in third case – one or three elements of order 2.□

Theorem 3.7

A finite pentagonal quasigroup has order 5 s or 5 s + 1 .

Proof

Suppose that a pentagonal quasigroup ( Q , ) is induced by the group ( Q , + ) , where Q = { 0 , e 2 , e 3 , , e n } . Each automorphism ψ of this group can be identified with a permutation φ of the set { e 2 , e 3 , , e n } . Each such permutation is a cycle or can be decomposed into disjoint cycles. Since, by Corollary 2.3, φ 2 = ε or φ 10 = ε , a permutation φ can be decomposed into disjoint cycles of the length 2, 5 or 10. If φ contains a cycle of the length 2, then for some e i Q we have φ ( e i ) = e j e i and φ 2 ( e i ) = e i . If e j e i , then by Corollary 2.3, e i = φ 5 ( e i ) = φ ( e i ) , a contradiction. Thus, e j = e i and consequently 5 e i = 0 , by (5). So, in this case 5 is a divisor of n . Hence, if φ is decomposed into k cycles of the length 2, then ( Q , + ) has the order n = 2 k + 1 = 5 t . Since t must be odd, we see that in this case n = 10 s + 5 .

If φ contains a cycle of the length 5, then for some e i Q we have φ 5 ( e i ) = e i and φ ( e i ) e i . This, by Corollary 2.3, implies 2 e i = 0 . Thus, 2 is a divisor of n and n > 5 . Moreover, each element of this cycle has order 2. Therefore, in the case when φ is decomposed into disjoint cycles of the length 5, the group ( Q , + ) has 5 s + 1 elements and all non-zero elements have order 2. So, ( Q , + ) is the direct product of copies of Z 2 . Thus, n = 2 k = 5 t + 1 . So, t is odd and, as in the previous case, n = 10 s + 6 . If φ is decomposed into cycles of the length 10, then obviously n = 10 s + 1 .

Now, if φ is decomposed into cycles of the length 2 and 5, then 10 divides n . Thus, n = 10 s . If φ is decomposed into p > 0 cycles of the length 2 and q > 0 cycles of the length 10, then n = 2 p + 10 q + 1 and 5 divides n . Hence, n = 10 s + 5 . If φ is decomposed into p > 0 cycles of the length 5 and q > 0 cycles of the length 10, then n = 5 p + 10 q + 1 and 2 divides n . Hence, n = 10 s + 6 . Finally, if φ is decomposed into p > 0 cycles of the length 2, q > 0 cycles of the length 5 and r cycles of the length 10, then n = 2 p + 5 q + 10 r + 1 and 5 divides n . Hence, n = 10 s + 5 .□

Corollary 3.8

The smallest pentagonal quasigroup is induced by the group Z 5 and has the form x y = [ 4 x + 2 y ] 5 .

Proof

Indeed, by Theorem 3.7, Z 5 is the smallest group that can be used in the construction of a pentagonal quasigroup. In this group only a = 4 satisfies (6). Thus, the multiplication of this quasigroup is defined by x y = [ 4 x + 2 y ] 5 .□

Proposition 3.9

A groupoid ( Q , ) is a commutative pentagonal quasigroup if and only if there exists an Abelian group ( Q , + ) of exponent 11 such that x y = 6 x + 6 y for all x , y Q .

Proof

By Theorem 2.1 for a commutative pentagonal quasigroup there exists an Abelian group ( Q , + ) and its automorphism φ such that φ = ε φ . Thus, ε = 2 φ . This, by (5), gives φ ( φ 3 φ 2 + φ + ε ) = 0 . Therefore, φ ( φ 2 φ + 3 ε ) = 0 , and consequently, φ 2 + 5 φ = 0 , so φ + 5 ε = 0 . Hence, 11 φ = 0 . Thus, 11 x = 0 for each x Q . Moreover, from 11 φ = 0 we obtain φ ( x ) = 10 φ ( x ) = 5 x = 6 x and ( ε φ ) ( x ) = x 6 x = 5 x = 6 x . So, exp ( Q , + ) = 11 and x y = 6 x + 6 y for all x , y Q .

The converse statement is obvious.□

Corollary 3.10

The variety of commutative, idempotent, medial groupoids satisfying the pentagonal identity is the variety of commutative, pentagonal quasigroups, whose spectrum is { 1 1 n : n = 0 , 1 , 2 , } .

Proof

It follows from Proposition 3.9 that the spectrum of the variety of commutative pentagonal quasigroups is { 1 1 n : n = 0 , 1 , 2 , } . So, we need to only prove that a commutative, idempotent, medial groupoid ( Q , ) satisfying the pentagonal identity is a quasigroup. Let a , b Q . Then the pentagonal identity ensures that the equations x a = b and a x = b have a solution x = ( a b a ) b . Suppose that z a = b . Then z = ( a z a ) z a = ( b a z ) a = ( a b z ) a a = ( a b a ) b = x and the solution is unique.□

4 Translatable pentagonal quasigroups

Recall a quasigroup ( Q , ) , with Q = { 1 , 2 , , n } and 1 k < n , is k -translatable if its multiplication table is obtained by the following rule: if the first row of the multiplication table is a 1 , a 2 , , a n , then the q -th row is obtained from the ( q 1 ) -st row by taking the last k entries in the ( q 1 ) -st row and inserting them as the first k entries of the q -th row and by taking the first n k entries of the ( q 1 ) -st row and inserting them as the last n k entries of the q th row, where q { 2 , 3 , , n } . The multiplication in a k -translatable quasigroup is given by the formula i j = [ i + 1 ] n [ j + k ] n = a k k i + j n (cf. [2,7] or [3]). Moreover, Lemma 9.1 in [7] shows that a quasigroup of the form x y = [ a x + b y ] n is k translatable only for k such that [ a + k b ] n = 0 . Thus, a pentagonal quasigroup induced by Z n can be k -translatable only for k { 2 , 3 , , n 2 } .

Theorem 4.1

Every pentagonal quasigroup induced by Z n is k -translatable for some k > 1 such that ( k , n ) = 1 . If it has the form x y = [ a x + ( 1 a ) y ] n , then is k -translatable for k = [ 1 a 3 a ] n .

Proof

Indeed, by Theorem 3.3, x y = [ a x + ( 1 a ) y ] n and [ a 4 a 3 + a 2 a + 1 ] n = 0 . Thus, [ a + ( a 3 a + 1 ) ( 1 a ) ] n = 0 , which, by Lemma 9.1 from [7], means that this quasigroup is k -translatable. Since k + n t = 1 a ( a 2 + 1 ) = a 2 ( a 2 + 1 ) and ( a , n ) = 1 , each prime divisor of k and n is a divisor of a , which is impossible. So, ( k , n ) = 1 .□

Theorem 4.2

A groupoid ( Q , ) of order n is a k -translatable pentagonal quasigroup, k > 1 , if and only if it is of the form x y = [ a x + ( 1 a ) y ] n , where

(8) n m = k 4 2 k 3 + 4 k 2 3 k + 1 and a = [ k 3 + k 2 3 k + 1 ] n .

Proof

Suppose that ( Q , ) is a k -translatable pentagonal quasigroup of order n . By Theorem 4.2 of [3] and Lemma 9.1 of [7] it is of the form x y = [ a x + ( 1 a ) y ] n and [ a + ( 1 a ) k ] n = 0 , where 1 < a < n , ( a , n ) = ( a 1 , n ) = 1 . Thus,

(9) [ a + k ] n = [ k a ] n and k = [ ( k 1 ) a ] n .

By Theorem 4.1, k = [ 1 a 3 a ] n . Therefore, [ a 3 ] n = [ 1 a k ] n . So,

(10) [ k a 3 ] n = [ k k a k 2 ] n = [ a k 2 ] n .

By (7), we also have [ a 5 ] n = [ 1 ] n . Thus,

[ k a 3 ] n = ( 9 ) [ ( k 1 ) a 4 ] n , [ k a 4 ] n = [ 1 k ] n , [ k a ] n = [ ( k 1 ) a 2 ] n , [ k a 2 ] n = [ ( k 1 ) a 3 ] n .

Therefore, using pentagonality and the aforementioned identities, we obtain

0 = [ ( k 1 ) ( a 4 a 3 + a 2 a + 1 ) ] n = [ ( k 1 ) a 4 ( k 1 ) a 3 + ( k 1 ) a 2 ( k 1 ) a + ( k 1 ) ] n = [ k a 3 a 2 1 ] n = ( 9 ) [ a k 2 a 2 1 ] n .

Hence, [ a 2 ] n = [ a k 2 1 ] n , and as a consequence

[ a + k ] n = [ k a ] n = [ ( k 1 ) a 2 ] n = [ ( k 1 ) ( a k 2 1 ) ] n = [ k 3 + k 2 2 k + 1 ] n ,

which implies the second equation of (8).

The first equation follows from the fact that

0 = [ a + k k a ] n = [ k 4 2 k 3 4 k 2 3 k + 1 ] n .

Conversely, let ( Q , ) be a groupoid of order n > 1 with x y = [ a x + ( 1 a ) y ] n , where n and a are as in (8). Then ( a , n ) = ( a 1 , n ) = 1 . Indeed, each a prime divisor p of a and n is a divisor of m a = k 2 ( k 2 k + 3 ) . If p k , then, by (8), p 1 , a contradiction. So, p ( k 2 k + 3 ) and p n , but then p k ( k 2 k + 3 ) = 1 a . This is also impossible. Hence, ( a , n ) = 1 . Similarly, ( a 1 , n ) = 1 . Thus, 1 < a < n and, as a consequence, ( Q , ) is a quasigroup. Since [ a + k ( 1 a ) ] n = 0 , by Lemma 9.1 from [7], it is k -translatable. This implies (9).

Now, using (9) and (8), we obtain

(11) [ k 2 a ] n = [ k ( k a ) ] n = [ k ( k + a ) ] n = [ k 2 + k + a ] n = ( 8 ) [ k 3 + 2 k 2 2 k + 1 ] n

and

[ k 2 a 2 ] n = [ ( k 2 a ) a ] n = ( 11 ) [ k 2 ( k + a ) + 2 k ( k + a ) 2 k a + a ] n = [ k 3 k 2 a + 2 k 2 + a ] n = ( 11 ) [ k 3 k 2 k a + 2 k 2 + a ] n = [ k 3 + k 2 k ] n .

That is,

[ k 2 a 2 ] n = [ k 3 + k 2 k ] n and [ k 3 a 2 ] n = [ k 4 + k 3 k 2 ] n .

Then

[ a 2 ] n = ( 8 ) [ k k 2 a + k 2 a 3 k a + a ] n = ( 10 ) , ( 9 ) [ ( k 4 2 k 3 + 2 k 2 k ) + ( k 3 + 2 k 2 2 k + 1 ) + ( 3 k 3 a + a ) ] n = ( 8 ) [ k 3 3 k 2 a ] n = ( 8 ) [ k 3 2 k 2 + 3 k 2 ] n .

Consequently,

[ k a 2 ] n = [ k 4 2 k 3 + 3 k 2 2 k ] n = ( 8 ) [ k 2 + k 1 ] n .

Now, using the aforementioned identities, we obtain

[ a 3 ] n = [ k 3 a 2 + k 2 a 2 3 k a 2 + a 2 ] n = [ k 3 k 2 + 2 k ] n = ( 8 ) [ 1 a k ] n .

Therefore, [ a 4 ] n = [ a a 2 a k ] n and

[ a 4 a 3 + a 2 a + 1 ] n = [ 1 a k a 3 ] n = [ a + k ( 1 a ) ] n = 0 ,

which, by Theorem 3.3, shows that ( Q , ) is a pentagonal quasigroup.□

Corollary 4.3

For every k > 1 there exists at least one k -translatable pentagonal quasigroup.

Proof

One k -translatable pentagonal quasigroup is defined by Theorem 4.2. In this quasigroup a and n are as in (8). If m is a divisor of n and a = [ b ] n , then a = [ b ] m . Thus, ( Z m , ) with x y = [ a x + ( 1 a ) y ] m , a = [ k 3 + k 2 3 k + 1 ] m , also is a k -translatable pentagonal quasigroup.□

According to Theorem 4.2 for k = 2 , we have n = m = 11 and a = 2 . So for k = 2 there is only one k -translatable pentagonal quasigroup induced by Z n . It has the form x y = [ 2 x + 10 y ] 11 . For k = 3 , m = 55 , a = [ 29 ] n and n m , there are three k -translatable pentagonal quasigroups induced by Z n . They have the form: x y = [ 29 x + 27 y ] 55 , x y = [ 7 x + 5 y ] 11 and x y = [ 4 x + 2 y ] 5 . Other calculations for k 20 are presented as follows:

k x y
2 [ 2 x + 10 y ] 11
3 [ 4 x + 2 y ] 5 , [ 7 x + 5 y ] 11 , [ 29 x + 27 y ] 55
4 [ 122 x + 60 y ] 181
5 [ 347 x + 115 ] 461
6 [ 794 x + 198 y ] 991
7 [ 27 x + 5 y ] 31 , [ 52 x + 10 y ] 61 , [ 1577 x + 315 ] 1891
8 [ 190 x + 472 y ] 661 , [ 2834 x + 472 y ] 3305
9 [ 8 x + 4 y ] 11 , [ 308 x + 184 y ] 491 , [ 4727 x + 675 y ] 5401
10 [ 6 x + 6 y ] 11 , [ 593 x + 169 y ] 761 , [ 7442 x + 930 y ] 8371
11 [ 29 x + 3 y ] 31 , [ 362 x + 40 ] 401 , [ 11189 x + 1243 y ] 12431
12 [ 14 x + 58 y ] 71 , [ 138 x + 114 y ] 251 , [ 16202 x + 1620 y ] 17821
13 [ 25 x + 17 y ] 41 , [ 24 x + 32 y ] 55 , [ 112 x + 10 y ] 121 , [ 189 x + 17 y ] 205 ,
[ 354 x + 252 y ] 605 , [ 189 x + 2067 y ] 2255 , [ 2895 x + 2067 y ] 4961 , [ 22739 x + 2076 ] 24805
14 [ 472 x + 2590 y ] 3061 , [ 31082 x + 2590 y ] 33671
15 [ 4 x + 38 y ] 41 , [ 79 x + 1013 y ] 1091 , [ 41537 x + 3195 y ] 44731
16 [ 54434 x + 3888 y ] 58321
17 [ 42 x + 90 y ] 131 , [ 465 x + 107 y ] 571 , [ 70127 x + 4675 y ] 74801
18 [ 13350 x + 5562 y ] 18911 , [ 88994 x + 5562 y ] 94555
19 [ 111437 x + 6555 y ] 117991
20 [ 17 x + 85 y ] 101 , [ 70 x + 62 y ] 131 , [ 118 x + 994 y ] 1111 , [ 987 x + 455 y ] 1441 ,
[ 5572 x + 7660 y ] 13231 , [ 137882 x + 7660 y ] 145541

Let Z 11 be the pentagonal quasigroup with the multiplication x y = [ 6 x + 6 y ] 11 . By the aforementioned result, a finite commutative pentagonal quasigroup is the direct product of m copies of Z 11 but for m > 1 , as it is shown below, they are not translatable.

Theorem 4.4

Z 11 is the only translatable commutative pentagonal quasigroup.

Proof

Let ( Q , ) be a commutative pentagonal quasigroup. By definition, an infinite quasigroup cannot be translatable. So, ( Q , ) must be finite. By Proposition 3.9 its order is n = 1 1 m .

If m = 1 , then, by Proposition 3.9, the multiplication of ( Q , ) has the form x y = [ 6 x + 6 y ] 11 . From the multiplication table of this quasigroup, it follows that it is k -translatable for k = 10 = n 1 . So, for m = 1 , our theorem is valid.

Now let m > 1 and ( Q , ) be ( n 1 ) -translatable. According to Lemma 2.7 in [2], we can assume that Q is ordered in the following way: x ( 1 ) , x ( 2 ) , x ( 3 ) , , x ( n ) , where x ( 1 ) = ( 1 , 0 , 0 , , 0 ) . Then the multiplication table of ( Q , ) has the following form:

x ( 1 ) x ( 2 ) x ( 3 ) x ( n )
x ( 1 ) x ( 1 ) x ( 1 ) x ( 1 ) x ( 2 ) x ( 1 ) x ( 3 ) x ( 1 ) x ( n )
x ( 2 ) x ( 2 ) x ( 1 ) x ( 2 ) x ( 2 ) x ( 2 ) x ( 3 ) x ( 2 ) x ( n )
x ( 3 ) x ( 3 ) x ( 1 ) x ( 3 ) x ( 2 ) x ( 3 ) x ( 3 ) x ( 3 ) x ( n )

Since ( Q , ) is ( n 1 ) -translatable, x ( 2 ) x ( t ) = x ( 1 ) x ( t + 1 ) for all t Z n .

Let x ( 2 ) = ( a 1 , a 2 , , a m ) . We will prove by induction that

x ( t + 1 ) = ( t a 1 ( t 1 ) , t a 2 , t a 3 , , t a m ) t Z n .

The induction hypothesis is clearly true, by definition, for t = 1 . Assume that the induction hypothesis is true for all s t . Then

x ( t ) = ( ( t 1 ) a 1 ( t 2 ) , ( t 1 ) a 2 , ( t 1 ) a 3 , , ( t 1 ) a m ) .

Suppose that x ( t + 1 ) = ( z 1 , z 2 , z 3 , , z m ) . Since x ( 2 ) x ( t ) = x ( 1 ) x ( t + 1 ) , we have 6 x ( 2 ) + 6 x ( t ) = 6 x ( 1 ) + 6 x ( t + 1 ) . The last expression means that

( 6 a 1 + 6 ( t 1 ) a 1 6 ( t 2 ) , 6 t a 2 , 6 t a 3 , , 6 t a m ) = ( 6 + 6 z 1 ( t ) , 6 z 2 ( t ) , 6 z 3 ( t ) , , 6 z m ( t ) ) .

Hence, 6 z 1 ( t ) = 6 ( t a 1 ( t 1 ) ) , which implies z 1 ( t ) = t a 1 ( t 1 ) . Also z s ( t ) = t a s for all s = 2 , 3 , , m . So, x ( t + 1 ) = ( t a 1 ( t 1 ) , t a 2 , t a 3 , , t a m ) , as required.

Now, x ( 12 ) = ( 11 a 1 10 , 11 a 2 , 11 a 3 , , 11 a m ) = ( 10 , 0 , 0 , , 0 ) = x ( 1 ) , a contradiction because all x ( 1 ) , x ( 2 ) , x ( 3 ) , , x ( n ) are different. So, for m > 1 a quasigroup ( Q , ) cannot be ( n 1 ) -translatable.□

Suppose that ( G , ) is a commutative pentagonal quasigroup and a , b are two distinct elements of G . Then it is straighforward to prove that a and b generate the subquasigroup

a , b = { a , b , a b , a b a , b a b , a b a a , a b a b , b a b a , b a b b , ( a b a a ) b , ( b a b b ) a }

and that a , b is isomorphic to Z 11 . Then we take c a , b , if c exists.

Lemma 4.5

a , b b , c = { b } .

Proof

From the multiplication table of Z 11 we see that any two distinct elements generate Z 11 . Hence, a , b b , c cannot contain b and another element of a , b b , c , or else c a , b = b , c , a contradiction.□

Theorem 4.6

H = a , b b , c is a commutative pentagonal subquasigroup of ( G , ) isomorphic to Z 11 × Z 11 .

Proof

Since ( G , ) is medial, ( a , b b , c ) ( a , b b , c ) a , b b , c . Note that a , b a , b b a , b b , c and b , c b b , c a , b b , c . Hence, the commutative pentagonal quasigroup H = a , b b , c a , b { c } has more than 11 elements and less than or equal to 121 elements. Therefore, as we have already seen, H has 121 elements and is isomorphic to Z 11 × Z 11 . This completes the proof.□

Corollary 4.7

Z 11 × Z 11 is generated by three distinct elements.

Corollary 4.8

If x y = z w a , b b , c , then x = z and y = w .

Corollary 4.9

If d a , b b , c , then ( a , b b , c ) b , d is a commutative pentagonal quasigroup of order 1 1 3 and is isomorphic to Z 11 × Z 11 × Z 11 .

Corollary 4.10

Z 11 × Z 11 × Z 11 is generated by four distinct elements.

Corollary 4.11

The direct product of n copies of Z 11 is generated by n + 1 distinct elements.

5 Groups inducing pentagonal quasigroups

Pentagonal quasigroups are very large. Using Theorem 4.2 we can determine all pentagonal quasigroups induced by Z n . Below we present several such quasigroups. For a = 3 there is only one such quasigroup. It is induced by the group Z 61 . Its multiplication is defined by x y = [ 3 x 2 y ] 61 = [ 3 x + 59 y ] 61 . This quasigroup is 32-translatable. For a = 4 there are three such quasigroups. They are induced by Z 5 , Z 41 , Z 205 and are 3-, 15-, 138-translatable, respectively.

a 2 3 4 5 6 7 8 9
n 11 61 5, 41, 205 521 11, 101, 1111 11, 191, 2101 11, 331, 3641 1181, 5905
k 2 32 3, 15, 138 392 10, 82, 890 3, 33, 1752 9, 143, 3122 444, 5168
a 10 11 12 13 14 15 16
n 9091 13421 19141 2411 71, 101, 355, 505, 7171, 35855 31, 1531, 47461 61681
k 8082 12080 17402 202 83, 71, 83, 273, 4414, 33098 21, 1204, 44072 57570
a 17 18 19 20
n 71, 101, 781, 1111, 7171, 78881 9041, 99451 55, 2251, 11255, 24761, 123805 152381
k 41, 19, 538, 625, 2242, 73952 3192, 93602 53, 2127, 4378, 17884, 116928 144362
a 21 22 23 24
n 185641 224071 31, 41, 211, 1271, 6541, 8651, 268181 55, 5791, 28955, 63701, 318505
k 176360 213402 25, 28, 48, 521, 893, 5113, 255992 13, 2267, 15108, 49854, 304658

The aforementioned table shows that from groups Z n for n < 24 only groups Z 5 and Z 11 determine pentagonal quasigroups. To determine other groups of order n < 100 inducing pentagonal quasigroups observe that from Corollary 2.3 and Theorem 3.7 it follows that an Abelian group inducing a pentagonal quasigroup is the direct product of several copies of the group Z 5 or has a regular automorphism φ ε of order 10. Observe that from Proposition 2.7, Corollary 3.6, Theorem 3.7 and the above table the possible values of n < 100 are n { 5 , 11 , 16 , 25 , 31 , 40 , 41 , 45 , 55 , 56 , 61 , 71 , 80 , 81 } .

For n = 5 we have one pentagonal quasigroup, and for n = 11 there are four such quasigroups (see the aforementioned table). For n = 16 we have five Abelian groups of order 16: Z 16 , Z 2 × Z 8 , Z 2 × Z 2 × Z 4 , Z 4 × Z 4 and Z 2 4 . From the aforementioned table it follows that the group Z 16 does not induce any pentagonal quasigroup. Groups Z 2 × Z 8 , Z 2 × Z 2 × Z 4 , Z 4 × Z 4 do not have automorphisms of order 10 (Theorem 2.8), so they cannot be considered as a group inducing pentagonal quasigroups. The group Z 2 4 can be treated as a vector space V over Z 2 . Then, by Corollary 2.3, automorphisms φ interesting for us are linear endomorphisms of V for which λ = 1 is an eigenvalue of φ 5 . From these endomorphisms we select those satisfying (5). There is 1,344 such endomorphisms, so the group Z 2 4 induces 1,344 pentagonal quasigroups.

The group Z 25 has four elements of order 5, namely, 5, 10, 15 and 20. Thus, φ ( 5 ) { 10 , 15 , 20 } . Therefore, φ restricted to the set { 5 , 10 , 15 , 20 } has the form φ ( x ) = a x , where a { 2 , 3 , 4 } , but such φ does not satisfy (5). Hence, Z 25 does not induce a pentagonal quasigroup. The group Z 5 × Z 5 induces 24 pentagonal quasigroups. These quasigroups are induced by matrices

A 0 1 4 3 , 0 2 2 3 , 0 3 3 3 , 0 3 1 2 , 0 4 1 3 , 4 0 1 4

and A 2 , A 3 , A 4 .

Pentagonal quasigroups of order 31 are induced by the group Z 31 . They are determined by an automorphism φ ( x ) = a x , where a { 15 , 23 , 27 , 29 } (see table below).

From Abelian groups of order 40 the groups Z 40 , Z 2 × Z 20 and Z 4 × Z 10 have one or three elements of order 2, so they cannot induce pentagonal quasigroups. In the group Z 2 × Z 2 × Z 10 only elements ( 0 , 0 , 2 ) , ( 0 , 0 , 4 ) , ( 0 , 0 , 6 ) , ( 0 , 0 , 8 ) have order 5. Thus, φ ( 0 , 0 , 2 ) { ( 0 , 0 , 4 ) , ( 0 , 0 , 6 ) , ( 0 , 0 , 8 ) } . But then φ 5 ( 0 , 0 , 2 ) + ( 0 , 0 , 2 ) ( 0 , 0 , 0 ) , a contradiction. Therefore, there are no pentagonal quasigroups of order 40.

Pentagonal quasigroups of order 41 can be calculated by solution of the equation (6) or (7). The solutions are a = 4 , 23 , 25 , 31 . So there are four such quasigroups.

For n = 45 there are two Abelian groups: Z 45 and Z 3 × Z 15 . The first group has two elements of order 3, so by Proposition 3.5 it cannot induce pentagonal quasigroups. The second group has four elements of order 5. The smallest is ( 0 , 3 ) . Thus, φ ( 0 , 3 ) = ( 0 , 3 a ) for a = 2 , 3 , 4 . But then φ 5 ( 0 , 3 ) + ( 0 , 3 ) ( 0 , 0 ) . Thus, pentagonal quasigroups of order 45 do not exist.

For n = 55 there exists only one Abelian group: Z 55 . Its automorphisms have form φ ( x ) = a x , where ( a , 55 ) = 1 . The automorphisms inducing pentagonal quasigroups should satisfy (7). It is easily to see, that for k = 0 , 1 , 2 , , 9 the last digit of k 5 is k . So, for a = m k the last digit of a 5 is also k . Since a 5 + 1 must be divided by 5, a = m 4 or a = m 9 . The aforementioned table shows that the smallest possible value of a is 19. Because 44 is divided by 11, 4 4 5 + 1 cannot be divided by 11. Thus, 44 should be omitted. Also, 54 = ( 1 ) ( mod 55 ) should be omitted. By direct calculation we can see that from other a < 54 acceptable are 24, 29 and 39. Hence, there are four pentagonal quasigroups of order 55. They are isomorphic to the direct product of pentagonal quasigroups induced by Z 5 and Z 11 .

From Abelian groups of order 56 groups Z 56 , Z 2 × Z 28 , Z 4 × Z 14 have one or three elements of order 2. Thus, they cannot induce pentagonal quasigroups. The group Z 2 × Z 2 × Z 14 has six elements of order 7. In the same manner as in the case of groups of order 45, we can prove that this group cannot induce pentagonal quasigroups.

Pentagonal quasigroups of prime orders 61 and 71 can be calculated in the same way as for n = 41 . Results are presented in the table below.

An Abelian group G of order 80 can be decomposed into the direct product of two groups H and Z 5 , where H is a group of order 16. From groups of order 16 only Z 2 4 induces pentagonal quasigroups. So, by Proposition 2.7, from groups of order 81 only Z 2 4 × Z 5 induces pentagonal quasigroups. We have 1,344 such quasigroups.

The group Z 81 has only two elements of order 2, so, by Proposition 3.5, this group cannot be inducing group for a pentagonal quasigroup. Theorem 2.8 shows that from other Abelian groups of order 81 only the group Z 3 4 can have an automorphism of order 10. Using a computer software we calculate 303,264 of such automorphisms satisfying (5). So, Z 3 4 induces 303,264 pentagonal quasigroups.

In this way, we have proved the following:

Theorem 5.1

The groups of order n < 100 that induce pentagonal quasigroups are Z 5 , Z 11 , Z 2 4 , Z 5 2 , Z 31 , Z 41 , Z 55 , Z 61 , Z 71 , Z 2 4 × Z 5 and Z 3 4 .

For n < 100 pentagonal quasigroups induced by Z n are as follows:

n = 5 4 x + 2 y
n = 11 2 x + 10 y 6 x + 6 y 7 x + 5 y 8 x + 4 y
n = 31 15 x + 17 y 23 x + 9 y 27 x + 5 y 29 x + 3 y
n = 41 4 x + 38 y 23 x + 19 y 25 x + 17 y 31 x + 11 y
n = 55 19 x + 37 y 24 x + 32 y 29 x + 27 y 39 x + 17 y
n = 61 3 x + 59 y 27 x + 35 y 41 x + 21 y 52 x + 10 y
n = 71 14 x + 58 y 17 x + 55 y 46 x + 26 y 66 x + 6 y

6 Parastrophes of pentagonal quasigroups

Each quasigroup ( Q , ) determines five new quasigroups Q i = ( Q , i ) with the operations i defined as follows:

x 1 y = z x z = y , x 2 y = z z y = x , x 3 y = z z x = y , x 4 y = z y z = x , x 5 y = z y x = z .

Such defined (not necessarily distinct) quasigroups are called parastrophes or conjugates of Q .

Parastrophes of each quasigroup can be divided into separate classes containing isotopic parastrophes. The number of such classes is always 1, 2, 3 or 6 (cf. [8]). In some cases (described in [9]), parastrophes of a given quasigroup Q are pairwise equal. Parastrophes do not save properties of the initial quasigroup. Parastrophes of an idempotent quasigroup are idempotent quasigroups, but parastrophes of a pentagonal quasigroup are not pentagonal quasigroups, in general.

Let ( Q , ) be a pentagonal quasigroup induced by the group Z n . Then x y = [ a x + ( 1 a ) y ] n and [ a 4 a 3 + a 2 a + 1 ] n = 0 . Such quasigroup is k -translatable for k = [ 1 a 3 a ] n . Since [ a ( 1 a + a 2 a 3 ) ] n = 1 = [ ( 1 a ) ( a 3 + a ) ] n , from Theorems 5.1 and 5.3 in [3] we obtain the following characterization of parastrophes of pentagonal quasigroups.

Proposition 6.1

If ( Q , ) is a pentagonal quasigroup with multiplication x y = [ a x + ( 1 a ) y ] n , then its parastrophe

x 1 y = [ ( 1 a 3 a ) x + ( a 3 + a ) y ] n is k - translatable for k = a , x 2 y = [ a 4 x + ( a 4 + 1 ) y ] n is k - translatable for k = [ a 3 + a ] n , x 3 y = [ ( a 4 + 1 ) x + ( a 4 ) y ] n is k - translatable for k = [ 1 a ] n , x 4 y = [ ( a 3 + a ) x + ( 1 a a 3 ) y ] n is k - translatable for k = [ a 4 ] n , x 5 y = [ ( 1 a ) x + ( a ) y ] n is k - translatable for k = [ a 4 + 1 ] n .

Using Proposition 6.1 we can show for which values of a and n parastrophes of a pentagonal quasigroup with the multiplication x y = [ a x + ( 1 a ) y ] n are pentagonal, quadratical ( x y x = z x y z ), hexagonal ( x y x = y ), GS-quasigroups ( x ( x y z ) z = y ), ARO-quasigroups ( x y y = y x x ), Stein quasigroups ( x x y = y x ), right modular ( x y z = z y x ) and C3 quasigroups ( ( x y y ) y = x ).

We start with the lemma that is a consequence of our results proved in [3].

Lemma 6.2

Let ( Q , ) be a quasigroup of the form x y = [ a x + ( 1 a ) y ] n . Then

  • [ 2 a 2 2 a + 1 ] n = 0 if it is quadratical (Theorem 4.8 in [10]),

  • [ a 2 a + 1 ] n = 0 if it is hexagonal,

  • [ a 2 a 1 ] n = 0 if it is a G S -quasigroup,

  • [ 2 a 2 ] n = 1 if it is an A R O -quasigroup,

  • [ a 2 3 a + 1 ] n = 0 if it is a Stein quasigroup,

  • [ a 2 + a 1 ] n = 0 if it is right modular,

  • [ a 3 ] n = 1 if it is a C 3 quasigroup.

Using the aforementioned characterization and the fact that a quasigroup of the form x y = [ a x + ( 1 a ) y ] n is k -translatable if and only if [ a + ( 1 a ) k ] n = 0 (cf. [2,7] or [3]) we obtain:

Lemma 6.3

A quasigroup of the form x y = [ a x + ( 1 a ) y ] n is

  • [ 1 2 a ] n -translatable if and only if it is quadratical,

  • [ 1 a ] n -translatable if and only if it is hexagonal,

  • [ a + 1 ] n -translatable if and only if it is a G S -quasigroup,

  • [ 2 a 1 ] n -translatable if and only if if it is an A R O -quasigroup,

  • [ a 1 ] n -translatable if and only if it is a Stein quasigroup,

  • [ 1 a ] n -translatable if and only if it is right modular.

A C 3 quasigroup is k -translatable for k such that [ ( 1 a 2 ) k ] n = 1 .

Using these two lemmas we can determine properties of parastrophes of pentagonal quasigroups induced by Z n . We start with Q 1 .

  • Suppose that Q 1 is pentagonal. Then a = [ 1 ( 1 a 3 a ) 3 ( 1 a 3 a ) ] n , from translatability, and [ ( 1 a 3 a ) 2 ] n = [ a 2 a 1 ] n , from (6). Then we have [ ( 1 a 3 a ) 3 ] n = [ ( a 2 a 1 ) ( 1 a 3 a ) ] n = [ a 4 + 2 a 3 2 ] n = ( 6 ) [ 3 a 3 a 2 + a 3 ] n . Therefore, a = [ 1 ( 1 a 3 a ) 3 ( 1 a 3 a ) ] n = [ 2 a 3 + a 2 + 3 ] n , whence, multiplying by a 2 , we obtain [ a 4 a 3 ] n = [ 3 a 2 2 ] n . This, by (6), shows that [ 2 a 2 + a + 1 ] n = 0 . Multiplying this equation by a 3 and applying (6) we get [ a 4 + a 3 ] n = 2 . Adding this equation to [ a 4 a 3 ] n = [ 3 a 2 2 ] n we obtain [ 2 a 4 ] n = [ 3 a 2 ] n . Thus, [ 2 a 2 ] n = [ 3 ] n and consequently, [ a 4 a 3 ] n = [ a 2 2 a 2 2 ] n = [ a 2 + 1 ] n . Hence, [ a 4 a 3 + a 2 ] n = 1 , which by (6) implies a = 2 and n = 11 .

  • Suppose that Q 1 is quadratical. Then, a = [ 1 2 ( 1 a 3 a ) ] n by Lemmas 6.2 and 6.3. Hence, [ 2 a 3 ] n = [ 1 a ] n . Also 0 = [ 2 ( 1 a 3 a ) 2 2 ( 1 a 3 a ) + 1 ] n = [ 2 a 4 2 a 1 ] n . So, [ 2 a + 1 ] n = [ 2 a 3 a ] n = [ ( 1 a ) a ] n = [ a a 2 ] n . Consequently, [ a 2 ] n = [ a 1 ] n and 0 = [ 2 a 4 2 a 3 + 2 a 2 2 a + 2 ] n = [ ( 2 a + 1 ) ( 1 a ) + 2 ( a 1 ) 2 a + 2 ] n = [ a ] n , a contradiction. So, Q 1 cannot be quadratical.

  • Q 1 is never hexagonal. Indeed, Q 1 is a -translatable and [ a 3 + a ] n -translatable as a hexagonal quasigroup. Hence, a = [ a 3 + a ] n , which implies [ a 3 ] n = 0 . Thus, 0 = [ a 5 ] n = [ 1 ] n , a contradiction.

  • If Q 1 is a GS-quasigroup, then a = [ ( 1 a 3 a ) + 1 ] n . Hence, [ a 3 ] n = [ 2 2 a ] n , [ a 4 ] n = [ 2 a 2 a 2 ] n , [ 1 ] n = [ a 5 ] n = [ 2 a 2 2 a 3 ] n = [ 2 a 2 + 4 a 4 ] n , [ 2 a 2 ] n = [ 3 4 a ] n , [ a 4 ] n = [ 6 a 3 ] n . Then 0 = [ 2 a 4 2 a 3 + 2 a 2 2 a + 2 ] n = [ 10 a 5 ] n . So, [ 5 a ] n = [ 10 a 2 ] n = [ 15 20 a ] n , i.e., [ 25 a ] n = [ 15 ] n . Thus, [ 5 a ] n = 5 and 5 = [ 10 a ] n = [ 5 a + 5 a ] n = [ 10 ] n . Therefore, n = 5 and x y = [ 4 x + 2 y ] 5 .

  • If Q 1 is an ARO-quasigroup, then [ 2 ( 1 a 3 a ) 2 ] n = 1 , so [ 2 a 2 ] n = [ 2 a 3 ] n . Also a = [ 2 ( 1 a 3 a ) 1 ] n . Thus, [ 2 a 3 ] n = [ 3 a ] n , [ 2 a 4 ] n = [ 3 a a 2 ] n and 0 = [ 2 a 4 2 a 3 + 2 a 2 2 a + 2 ] n = [ a 2 4 ] n , i.e., [ a 2 ] n = [ 4 ] n . Hence, [ 8 ] n = [ 2 a 2 ] n = [ 2 a 3 ] n which gives [ 2 a ] n = 5 . So, [ 16 ] n = [ 4 a 2 ] n = [ 25 ] n . Therefore, n = 41 , a = 23 .

  • If Q 1 is a Stein quasigroup, then a = [ ( 1 a 3 a ) ] n . So, [ a 3 ] n = [ 2 a ] n , [ a 3 ] n = [ 2 a ] n , [ a 4 ] n = [ 2 a 2 ] n , [ 1 ] n = [ a 5 ] n = [ 2 a 3 ] n , a = [ 2 a 4 ] n , [ a 2 ] n = [ 2 ] n , a = [ 2 a 4 ] n = [ 8 ] n , [ a 3 ] n = [ 4 a 4 ] n = [ 16 ] n . Thus, by (6), we obtain [ 11 ] n = 0 . Hence, n = 11 and a = 8 .

  • If Q 1 is right modular, then a = [ 1 ( 1 a 3 a ) ] n . Hence, [ a 3 ] n = 2 , [ a 4 ] n = [ 2 a ] n , [ 1 ] n = [ a 5 ] n = [ 2 a 2 ] n , a = [ 2 a 3 ] n = [ 4 ] n . This by (6) implies n = 11 , a = 7 .

  • If Q 1 is a C 3 quasigroup, then 1 = [ ( 1 ( 1 a 3 a ) 2 ) a ] n . Hence, [ a 3 + a 2 + 2 a 1 ] n = 0 , which, by (6), gives [ a 4 + 2 a 2 + a ] n = 0 . So, [ 1 + 2 a 3 + a 2 ] n = 0 . Comparing this equation with [ a 3 + a 2 + 2 a 1 ] n = 0 we obtain [ a 3 ] n = [ 2 a ] n . So, [ 1 ] n = [ 2 a 3 ] n = [ 4 a ] n and 1 = [ 2 a 3 + a 2 ] n = [ 1 + a 2 ] n . Thus, [ a 2 ] n = 2 and [ a ] n = [ 4 a 2 ] n = 8 . Therefore, 2 = [ a 2 ] n = [ 64 ] n . Consequently, n = 31 , a = 23 .

In other cases the proof is very similar, so we omit it.

The result of calculations is presented in the table below. In this table, the intersection of the ARO-row with the Q 3 -column means that for a pentagonal quasigroup Q its parastrophe Q 3 is an ARO-quasigroup only in the case when x y = [ 14 x + 58 y ] 71 .

Q Q 1 Q 2 Q 3 Q 4 Q 5
pentaq. [ 2 x + 10 y ] 11 always never [ 6 x + 6 y ] 11 [ 6 x + 6 y ] 11
quadrat. [ 4 x + 2 y ] 5 never [ 4 x + 2 y ] 5 [ 4 x + 2 y ] 5 never [ 4 x + 2 y ] 5
hexag. never never never never never never
GS [ 8 x + 4 y ] 11 [ 4 x + 2 y ] 5 [ 7 x + 5 y ] 11 [ 7 x + 5 y ] 11 [ 4 x + 2 y ] 5 [ 8 x + 4 y ] 11
ARO [ 27 x + 5 y ] 31 [ 23 x + 19 y ] 41 [ 23 x + 9 y ] 31 [ 14 x + 58 y ] 71 [ 25 x + 17 y ] 41 [ 66 x + 6 y ] 71
Stein [ 4 x + 2 y ] 5 [ 8 x + 4 y ] 11 never [ 8 x + 4 y ] 11 [ 7 x + 5 y ] 11 [ 7 x + 5 y ] 11
r. mod. [ 7 x + 5 y ] 11 [ 7 x + 5 y ] 11 never [ 4 x + 2 y ] 5 [ 8 x + 4 y ] 11 [ 4 x + 2 y ] 5
C3 never [ 23 x + 9 y ] 31 never [ 23 x + 9 y ] 31 [ 27 x + 5 y ] 31 [ 27 x + 5 y ] 31

  1. Funding information: This research was partially supported by Wroclaw University of Science and Technology, grant 8201003902 MPK: 9130730000.

  2. Conflict of interest: The authors declare that they have no conflict of interest.

References

[1] S. Vidak , Pentagonal quasigroups, Quasigroups Relat. Syst. 22 (2014), 147–158. Search in Google Scholar

[2] W. A. Dudek and R. A. R. Monzo , Translatability and translatable semigroups, Open Math. 16 (2018), 1266–1282. 10.1515/math-2018-0106Search in Google Scholar

[3] W. A. Dudek and R. A. R. Monzo , The structure of idempotent translatable quasigroups, Bull. Malays. Math. Sci. Soc. 43 (2020), 1603–1621. 10.1007/s40840-019-00761-5Search in Google Scholar

[4] V. Shcherbacov , Elements of Quasigroup Theory and Applications, CRC Press, Boca Raton, 2017. 10.1201/9781315120058Search in Google Scholar

[5] Ch. J. Hillar and D. L. Rhea , Automorphisms of finite Abelian groups, Amer. Math. Monthly 114 (2007), 917–923. 10.1080/00029890.2007.11920485Search in Google Scholar

[6] I. M. Vinogradov , Foundations of the theory of numbers, (Russian), Nauka, Moscow, 1965. Search in Google Scholar

[7] W. A. Dudek and R. A. R. Monzo , Translatable quadratical quasigroups, Quasigroups Relat. Syst. 28 (2020), 203–228. Search in Google Scholar

[8] W. A. Dudek , Parastrophes of quasigroups, Quasigroups Relat. Syst. 23 (2015), 221–230. Search in Google Scholar

[9] C. C. Lindner and D. Steedly , On the number of conjugates of a quasigroups, Algebra Univers. 5 (1975), 191–196. 10.1007/BF02485252Search in Google Scholar

[10] W. A. Dudek and R. A. R. Monzo , The fine structure of quadratical quasigroups, Quasigroups Relat. Syst. 24 (2016), 205–218. Search in Google Scholar
Received: 2020-08-21
Accepted: 2020-11-16
Published Online: 2021-05-03

© 2021 Wieslaw A. Dudek and Robert A. R. Monzo, published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

Articles in the same Issue

  1. Regular Articles
  2. Sharp conditions for the convergence of greedy expansions with prescribed coefficients
  3. Range-kernel weak orthogonality of some elementary operators
  4. Stability analysis for Selkov-Schnakenberg reaction-diffusion system
  5. On non-normal cyclic subgroups of prime order or order 4 of finite groups
  6. Some results on semigroups of transformations with restricted range
  7. Quasi-ideal Ehresmann transversals: The spined product structure
  8. On the regulator problem for linear systems over rings and algebras
  9. Solvability of the abstract evolution equations in Ls-spaces with critical temporal weights
  10. Resolving resolution dimensions in triangulated categories
  11. Entire functions that share two pairs of small functions
  12. On stochastic inverse problem of construction of stable program motion
  13. Pentagonal quasigroups, their translatability and parastrophes
  14. Counting certain quadratic partitions of zero modulo a prime number
  15. Global attractors for a class of semilinear degenerate parabolic equations
  16. A new implicit symmetric method of sixth algebraic order with vanished phase-lag and its first derivative for solving Schrödinger's equation
  17. On sub-class sizes of mutually permutable products
  18. Asymptotic solution of the Cauchy problem for the singularly perturbed partial integro-differential equation with rapidly oscillating coefficients and with rapidly oscillating heterogeneity
  19. Existence and asymptotical behavior of solutions for a quasilinear Choquard equation with singularity
  20. On kernels by rainbow paths in arc-coloured digraphs
  21. Fully degenerate Bell polynomials associated with degenerate Poisson random variables
  22. Multiple solutions and ground state solutions for a class of generalized Kadomtsev-Petviashvili equation
  23. A note on maximal operators related to Laplace-Bessel differential operators on variable exponent Lebesgue spaces
  24. Weak and strong estimates for linear and multilinear fractional Hausdorff operators on the Heisenberg group
  25. Partial sums and inclusion relations for analytic functions involving (p, q)-differential operator
  26. Hodge-Deligne polynomials of character varieties of free abelian groups
  27. Diophantine approximation with one prime, two squares of primes and one kth power of a prime
  28. The equivalent parameter conditions for constructing multiple integral half-discrete Hilbert-type inequalities with a class of nonhomogeneous kernels and their applications
  29. Boundedness of vector-valued sublinear operators on weighted Herz-Morrey spaces with variable exponents
  30. On some new quantum midpoint-type inequalities for twice quantum differentiable convex functions
  31. Quantum Ostrowski-type inequalities for twice quantum differentiable functions in quantum calculus
  32. Asymptotic measure-expansiveness for generic diffeomorphisms
  33. Infinitesimals via Cauchy sequences: Refining the classical equivalence
  34. The (1, 2)-step competition graph of a hypertournament
  35. Properties of multiplication operators on the space of functions of bounded φ-variation
  36. Disproving a conjecture of Thornton on Bohemian matrices
  37. Some estimates for the commutators of multilinear maximal function on Morrey-type space
  38. Inviscid, zero Froude number limit of the viscous shallow water system
  39. Inequalities between height and deviation of polynomials
  40. New criteria-based ℋ-tensors for identifying the positive definiteness of multivariate homogeneous forms
  41. Determinantal inequalities of Hua-Marcus-Zhang type for quaternion matrices
  42. On a new generalization of some Hilbert-type inequalities
  43. On split quaternion equivalents for Quaternaccis, shortly Split Quaternaccis
  44. On split regular BiHom-Poisson color algebras
  45. Asymptotic stability of the time-changed stochastic delay differential equations with Markovian switching
  46. The mixed metric dimension of flower snarks and wheels
  47. Oscillatory bifurcation problems for ODEs with logarithmic nonlinearity
  48. The B-topology on S-doubly quasicontinuous posets
  49. Hyers-Ulam stability of isometries on bounded domains
  50. Inhomogeneous conformable abstract Cauchy problem
  51. Path homology theory of edge-colored graphs
  52. Refinements of quantum Hermite-Hadamard-type inequalities
  53. Symmetric graphs of valency seven and their basic normal quotient graphs
  54. Mean oscillation and boundedness of multilinear operator related to multiplier operator
  55. Numerical methods for time-fractional convection-diffusion problems with high-order accuracy
  56. Several explicit formulas for (degenerate) Narumi and Cauchy polynomials and numbers
  57. Finite groups whose intersection power graphs are toroidal and projective-planar
  58. On primitive solutions of the Diophantine equation x2 + y2 = M
  59. A note on polyexponential and unipoly Bernoulli polynomials of the second kind
  60. On the type 2 poly-Bernoulli polynomials associated with umbral calculus
  61. Some estimates for commutators of Littlewood-Paley g-functions
  62. Construction of a family of non-stationary combined ternary subdivision schemes reproducing exponential polynomials
  63. On the evolutionary bifurcation curves for the one-dimensional prescribed mean curvature equation with logistic type
  64. On intersections of two non-incident subgroups of finite p-groups
  65. Global existence and boundedness in a two-species chemotaxis system with nonlinear diffusion
  66. Finite groups with 4p2q elements of maximal order
  67. Positive solutions of a discrete nonlinear third-order three-point eigenvalue problem with sign-changing Green's function
  68. Power moments of automorphic L-functions related to Maass forms for SL3(ℤ)
  69. Entire solutions for several general quadratic trinomial differential difference equations
  70. Strong consistency of regression function estimator with martingale difference errors
  71. Fractional Hermite-Hadamard-type inequalities for interval-valued co-ordinated convex functions
  72. Montgomery identity and Ostrowski-type inequalities via quantum calculus
  73. Universal inequalities of the poly-drifting Laplacian on smooth metric measure spaces
  74. On reducible non-Weierstrass semigroups
  75. so-metrizable spaces and images of metric spaces
  76. Some new parameterized inequalities for co-ordinated convex functions involving generalized fractional integrals
  77. The concept of cone b-Banach space and fixed point theorems
  78. Complete consistency for the estimator of nonparametric regression model based on m-END errors
  79. A posteriori error estimates based on superconvergence of FEM for fractional evolution equations
  80. Solution of integral equations via coupled fixed point theorems in 𝔉-complete metric spaces
  81. Symmetric pairs and pseudosymmetry of Θ-Yetter-Drinfeld categories for Hom-Hopf algebras
  82. A new characterization of the automorphism groups of Mathieu groups
  83. The role of w-tilting modules in relative Gorenstein (co)homology
  84. Primitive and decomposable elements in homology of ΩΣℂP
  85. The G-sequence shadowing property and G-equicontinuity of the inverse limit spaces under group action
  86. Classification of f-biharmonic submanifolds in Lorentz space forms
  87. Some new results on the weaving of K-g-frames in Hilbert spaces
  88. Matrix representation of a cross product and related curl-based differential operators in all space dimensions
  89. Global optimization and applications to a variational inequality problem
  90. Functional equations related to higher derivations in semiprime rings
  91. A partial order on transformation semigroups with restricted range that preserve double direction equivalence
  92. On multi-step methods for singular fractional q-integro-differential equations
  93. Compact perturbations of operators with property (t)
  94. Entire solutions for several complex partial differential-difference equations of Fermat type in ℂ2
  95. Random attractors for stochastic plate equations with memory in unbounded domains
  96. On the convergence of two-step modulus-based matrix splitting iteration method
  97. On the separation method in stochastic reconstruction problem
  98. Robust estimation for partial functional linear regression models based on FPCA and weighted composite quantile regression
  99. Structure of coincidence isometry groups
  100. Sharp function estimates and boundedness for Toeplitz-type operators associated with general fractional integral operators
  101. Oscillatory hyper-Hilbert transform on Wiener amalgam spaces
  102. Euler-type sums involving multiple harmonic sums and binomial coefficients
  103. Poly-falling factorial sequences and poly-rising factorial sequences
  104. Geometric approximations to transition densities of Jump-type Markov processes
  105. Multiple solutions for a quasilinear Choquard equation with critical nonlinearity
  106. Bifurcations and exact traveling wave solutions for the regularized Schamel equation
  107. Almost factorizable weakly type B semigroups
  108. The finite spectrum of Sturm-Liouville problems with n transmission conditions and quadratic eigenparameter-dependent boundary conditions
  109. Ground state sign-changing solutions for a class of quasilinear Schrödinger equations
  110. Epi-quasi normality
  111. Derivative and higher-order Cauchy integral formula of matrix functions
  112. Commutators of multilinear strongly singular integrals on nonhomogeneous metric measure spaces
  113. Solutions to a multi-phase model of sea ice growth
  114. Existence and simulation of positive solutions for m-point fractional differential equations with derivative terms
  115. Bernstein-Walsh type inequalities for derivatives of algebraic polynomials in quasidisks
  116. Review Article
  117. Semiprimeness of semigroup algebras
  118. Special Issue on Problems, Methods and Applications of Nonlinear Analysis (Part II)
  119. Third-order differential equations with three-point boundary conditions
  120. Fractional calculus, zeta functions and Shannon entropy
  121. Uniqueness of positive solutions for boundary value problems associated with indefinite ϕ-Laplacian-type equations
  122. Synchronization of Caputo fractional neural networks with bounded time variable delays
  123. On quasilinear elliptic problems with finite or infinite potential wells
  124. Deterministic and random approximation by the combination of algebraic polynomials and trigonometric polynomials
  125. On a fractional Schrödinger-Poisson system with strong singularity
  126. Parabolic inequalities in Orlicz spaces with data in L1
  127. Special Issue on Evolution Equations, Theory and Applications (Part II)
  128. Impulsive Caputo-Fabrizio fractional differential equations in b-metric spaces
  129. Existence of a solution of Hilfer fractional hybrid problems via new Krasnoselskii-type fixed point theorems
  130. On a nonlinear system of Riemann-Liouville fractional differential equations with semi-coupled integro-multipoint boundary conditions
  131. Blow-up results of the positive solution for a class of degenerate parabolic equations
  132. Long time decay for 3D Navier-Stokes equations in Fourier-Lei-Lin spaces
  133. On the extinction problem for a p-Laplacian equation with a nonlinear gradient source
  134. General decay rate for a viscoelastic wave equation with distributed delay and Balakrishnan-Taylor damping
  135. On hyponormality on a weighted annulus
  136. Exponential stability of Timoshenko system in thermoelasticity of second sound with a memory and distributed delay term
  137. Convergence results on Picard-Krasnoselskii hybrid iterative process in CAT(0) spaces
  138. Special Issue on Boundary Value Problems and their Applications on Biosciences and Engineering (Part I)
  139. Marangoni convection in layers of water-based nanofluids under the effect of rotation
  140. A transient analysis to the M(τ)/M(τ)/k queue with time-dependent parameters
  141. Existence of random attractors and the upper semicontinuity for small random perturbations of 2D Navier-Stokes equations with linear damping
  142. Degenerate binomial and Poisson random variables associated with degenerate Lah-Bell polynomials
  143. Special Issue on Fractional Problems with Variable-Order or Variable Exponents (Part I)
  144. On the mixed fractional quantum and Hadamard derivatives for impulsive boundary value problems
  145. The Lp dual Minkowski problem about 0 < p < 1 and q > 0
https://doi.org/10.1515/math-2021-0004
Keywords for this article
quasigroup; pentagonal quasigroup; translatability; idempotent
Creative Commons
BY 4.0

Articles in the same Issue

  1. Regular Articles
  2. Sharp conditions for the convergence of greedy expansions with prescribed coefficients
  3. Range-kernel weak orthogonality of some elementary operators
  4. Stability analysis for Selkov-Schnakenberg reaction-diffusion system
  5. On non-normal cyclic subgroups of prime order or order 4 of finite groups
  6. Some results on semigroups of transformations with restricted range
  7. Quasi-ideal Ehresmann transversals: The spined product structure
  8. On the regulator problem for linear systems over rings and algebras
  9. Solvability of the abstract evolution equations in Ls-spaces with critical temporal weights
  10. Resolving resolution dimensions in triangulated categories
  11. Entire functions that share two pairs of small functions
  12. On stochastic inverse problem of construction of stable program motion
  13. Pentagonal quasigroups, their translatability and parastrophes
  14. Counting certain quadratic partitions of zero modulo a prime number
  15. Global attractors for a class of semilinear degenerate parabolic equations
  16. A new implicit symmetric method of sixth algebraic order with vanished phase-lag and its first derivative for solving Schrödinger's equation
  17. On sub-class sizes of mutually permutable products
  18. Asymptotic solution of the Cauchy problem for the singularly perturbed partial integro-differential equation with rapidly oscillating coefficients and with rapidly oscillating heterogeneity
  19. Existence and asymptotical behavior of solutions for a quasilinear Choquard equation with singularity
  20. On kernels by rainbow paths in arc-coloured digraphs
  21. Fully degenerate Bell polynomials associated with degenerate Poisson random variables
  22. Multiple solutions and ground state solutions for a class of generalized Kadomtsev-Petviashvili equation
  23. A note on maximal operators related to Laplace-Bessel differential operators on variable exponent Lebesgue spaces
  24. Weak and strong estimates for linear and multilinear fractional Hausdorff operators on the Heisenberg group
  25. Partial sums and inclusion relations for analytic functions involving (p, q)-differential operator
  26. Hodge-Deligne polynomials of character varieties of free abelian groups
  27. Diophantine approximation with one prime, two squares of primes and one kth power of a prime
  28. The equivalent parameter conditions for constructing multiple integral half-discrete Hilbert-type inequalities with a class of nonhomogeneous kernels and their applications
  29. Boundedness of vector-valued sublinear operators on weighted Herz-Morrey spaces with variable exponents
  30. On some new quantum midpoint-type inequalities for twice quantum differentiable convex functions
  31. Quantum Ostrowski-type inequalities for twice quantum differentiable functions in quantum calculus
  32. Asymptotic measure-expansiveness for generic diffeomorphisms
  33. Infinitesimals via Cauchy sequences: Refining the classical equivalence
  34. The (1, 2)-step competition graph of a hypertournament
  35. Properties of multiplication operators on the space of functions of bounded φ-variation
  36. Disproving a conjecture of Thornton on Bohemian matrices
  37. Some estimates for the commutators of multilinear maximal function on Morrey-type space
  38. Inviscid, zero Froude number limit of the viscous shallow water system
  39. Inequalities between height and deviation of polynomials
  40. New criteria-based ℋ-tensors for identifying the positive definiteness of multivariate homogeneous forms
  41. Determinantal inequalities of Hua-Marcus-Zhang type for quaternion matrices
  42. On a new generalization of some Hilbert-type inequalities
  43. On split quaternion equivalents for Quaternaccis, shortly Split Quaternaccis
  44. On split regular BiHom-Poisson color algebras
  45. Asymptotic stability of the time-changed stochastic delay differential equations with Markovian switching
  46. The mixed metric dimension of flower snarks and wheels
  47. Oscillatory bifurcation problems for ODEs with logarithmic nonlinearity
  48. The B-topology on S-doubly quasicontinuous posets
  49. Hyers-Ulam stability of isometries on bounded domains
  50. Inhomogeneous conformable abstract Cauchy problem
  51. Path homology theory of edge-colored graphs
  52. Refinements of quantum Hermite-Hadamard-type inequalities
  53. Symmetric graphs of valency seven and their basic normal quotient graphs
  54. Mean oscillation and boundedness of multilinear operator related to multiplier operator
  55. Numerical methods for time-fractional convection-diffusion problems with high-order accuracy
  56. Several explicit formulas for (degenerate) Narumi and Cauchy polynomials and numbers
  57. Finite groups whose intersection power graphs are toroidal and projective-planar
  58. On primitive solutions of the Diophantine equation x2 + y2 = M
  59. A note on polyexponential and unipoly Bernoulli polynomials of the second kind
  60. On the type 2 poly-Bernoulli polynomials associated with umbral calculus
  61. Some estimates for commutators of Littlewood-Paley g-functions
  62. Construction of a family of non-stationary combined ternary subdivision schemes reproducing exponential polynomials
  63. On the evolutionary bifurcation curves for the one-dimensional prescribed mean curvature equation with logistic type
  64. On intersections of two non-incident subgroups of finite p-groups
  65. Global existence and boundedness in a two-species chemotaxis system with nonlinear diffusion
  66. Finite groups with 4p2q elements of maximal order
  67. Positive solutions of a discrete nonlinear third-order three-point eigenvalue problem with sign-changing Green's function
  68. Power moments of automorphic L-functions related to Maass forms for SL3(ℤ)
  69. Entire solutions for several general quadratic trinomial differential difference equations
  70. Strong consistency of regression function estimator with martingale difference errors
  71. Fractional Hermite-Hadamard-type inequalities for interval-valued co-ordinated convex functions
  72. Montgomery identity and Ostrowski-type inequalities via quantum calculus
  73. Universal inequalities of the poly-drifting Laplacian on smooth metric measure spaces
  74. On reducible non-Weierstrass semigroups
  75. so-metrizable spaces and images of metric spaces
  76. Some new parameterized inequalities for co-ordinated convex functions involving generalized fractional integrals
  77. The concept of cone b-Banach space and fixed point theorems
  78. Complete consistency for the estimator of nonparametric regression model based on m-END errors
  79. A posteriori error estimates based on superconvergence of FEM for fractional evolution equations
  80. Solution of integral equations via coupled fixed point theorems in 𝔉-complete metric spaces
  81. Symmetric pairs and pseudosymmetry of Θ-Yetter-Drinfeld categories for Hom-Hopf algebras
  82. A new characterization of the automorphism groups of Mathieu groups
  83. The role of w-tilting modules in relative Gorenstein (co)homology
  84. Primitive and decomposable elements in homology of ΩΣℂP
  85. The G-sequence shadowing property and G-equicontinuity of the inverse limit spaces under group action
  86. Classification of f-biharmonic submanifolds in Lorentz space forms
  87. Some new results on the weaving of K-g-frames in Hilbert spaces
  88. Matrix representation of a cross product and related curl-based differential operators in all space dimensions
  89. Global optimization and applications to a variational inequality problem
  90. Functional equations related to higher derivations in semiprime rings
  91. A partial order on transformation semigroups with restricted range that preserve double direction equivalence
  92. On multi-step methods for singular fractional q-integro-differential equations
  93. Compact perturbations of operators with property (t)
  94. Entire solutions for several complex partial differential-difference equations of Fermat type in ℂ2
  95. Random attractors for stochastic plate equations with memory in unbounded domains
  96. On the convergence of two-step modulus-based matrix splitting iteration method
  97. On the separation method in stochastic reconstruction problem
  98. Robust estimation for partial functional linear regression models based on FPCA and weighted composite quantile regression
  99. Structure of coincidence isometry groups
  100. Sharp function estimates and boundedness for Toeplitz-type operators associated with general fractional integral operators
  101. Oscillatory hyper-Hilbert transform on Wiener amalgam spaces
  102. Euler-type sums involving multiple harmonic sums and binomial coefficients
  103. Poly-falling factorial sequences and poly-rising factorial sequences
  104. Geometric approximations to transition densities of Jump-type Markov processes
  105. Multiple solutions for a quasilinear Choquard equation with critical nonlinearity
  106. Bifurcations and exact traveling wave solutions for the regularized Schamel equation
  107. Almost factorizable weakly type B semigroups
  108. The finite spectrum of Sturm-Liouville problems with n transmission conditions and quadratic eigenparameter-dependent boundary conditions
  109. Ground state sign-changing solutions for a class of quasilinear Schrödinger equations
  110. Epi-quasi normality
  111. Derivative and higher-order Cauchy integral formula of matrix functions
  112. Commutators of multilinear strongly singular integrals on nonhomogeneous metric measure spaces
  113. Solutions to a multi-phase model of sea ice growth
  114. Existence and simulation of positive solutions for m-point fractional differential equations with derivative terms
  115. Bernstein-Walsh type inequalities for derivatives of algebraic polynomials in quasidisks
  116. Review Article
  117. Semiprimeness of semigroup algebras
  118. Special Issue on Problems, Methods and Applications of Nonlinear Analysis (Part II)
  119. Third-order differential equations with three-point boundary conditions
  120. Fractional calculus, zeta functions and Shannon entropy
  121. Uniqueness of positive solutions for boundary value problems associated with indefinite ϕ-Laplacian-type equations
  122. Synchronization of Caputo fractional neural networks with bounded time variable delays
  123. On quasilinear elliptic problems with finite or infinite potential wells
  124. Deterministic and random approximation by the combination of algebraic polynomials and trigonometric polynomials
  125. On a fractional Schrödinger-Poisson system with strong singularity
  126. Parabolic inequalities in Orlicz spaces with data in L1
  127. Special Issue on Evolution Equations, Theory and Applications (Part II)
  128. Impulsive Caputo-Fabrizio fractional differential equations in b-metric spaces
  129. Existence of a solution of Hilfer fractional hybrid problems via new Krasnoselskii-type fixed point theorems
  130. On a nonlinear system of Riemann-Liouville fractional differential equations with semi-coupled integro-multipoint boundary conditions
  131. Blow-up results of the positive solution for a class of degenerate parabolic equations
  132. Long time decay for 3D Navier-Stokes equations in Fourier-Lei-Lin spaces
  133. On the extinction problem for a p-Laplacian equation with a nonlinear gradient source
  134. General decay rate for a viscoelastic wave equation with distributed delay and Balakrishnan-Taylor damping
  135. On hyponormality on a weighted annulus
  136. Exponential stability of Timoshenko system in thermoelasticity of second sound with a memory and distributed delay term
  137. Convergence results on Picard-Krasnoselskii hybrid iterative process in CAT(0) spaces
  138. Special Issue on Boundary Value Problems and their Applications on Biosciences and Engineering (Part I)
  139. Marangoni convection in layers of water-based nanofluids under the effect of rotation
  140. A transient analysis to the M(τ)/M(τ)/k queue with time-dependent parameters
  141. Existence of random attractors and the upper semicontinuity for small random perturbations of 2D Navier-Stokes equations with linear damping
  142. Degenerate binomial and Poisson random variables associated with degenerate Lah-Bell polynomials
  143. Special Issue on Fractional Problems with Variable-Order or Variable Exponents (Part I)
  144. On the mixed fractional quantum and Hadamard derivatives for impulsive boundary value problems
  145. The Lp dual Minkowski problem about 0 < p < 1 and q > 0
Sign up now to receive a 20% welcome discount
Institutional Access
How does access work?
Have an idea on how to improve our website?
Please write us.
© 2025 De Gruyter Brill
Downloaded on 7.9.2025 from https://www.degruyterbrill.com/document/doi/10.1515/math-2021-0004/html
Scroll to top button