Construction of Binary Quantum Error-Correcting Codes from Orthogonal Array

Abstract: By using difference schemes, orthogonal partitions and a replacement method, some new methods to construct pure quantum error-correcting codes are provided from orthogonal arrays. As an application of these methods, we construct several infinite series of quantum error-correcting codes including some optimal ones. Compared with the existing binary quantum codes, more new codes can be constructed, which have a lower number of terms (i.e., the number of computational basis states) for each of their basis states.

“…One example in this direction could be analyzing encoding isometries of the QECCs obtained with OAs, for instance, the ones from Ref. [25]. This could potentially lead to new OA and MOA constructions.…”

“…In the present paper we concentrate on construction of r-uniform subspaces, mostly for heterogeneous systems, i. e., those having different local dimensions. There are a number of tools for constructing r-uniform states in homogeneous systems: graph states [19], elements of combinatorial design such as Latin squares [20], symmetric matrices [21], orthogonal arrays (OAs) [22] and their variations [23][24][25]. For construction of r-uniform states in heterogeneous systems OAs were extended to mixed orthogonal arrays (MOAs) [26].…”

On generating r-uniform subspaces with the isometric mapping method

“…One example in this direction could be analyzing encoding isometries of the QECCs obtained with OAs, for instance, the ones from Ref. [25]. This could potentially lead to new OA and MOA constructions.…”

“…In the present paper we concentrate on construction of r-uniform subspaces, mostly for heterogeneous systems, i. e., those having different local dimensions. There are a number of tools for constructing r-uniform states in homogeneous systems: graph states [19], elements of combinatorial design such as Latin squares [20], symmetric matrices [21], orthogonal arrays (OAs) [22] and their variations [23][24][25]. For construction of r-uniform states in heterogeneous systems OAs were extended to mixed orthogonal arrays (MOAs) [26].…”

On generating r-uniform subspaces with the isometric mapping method

“…., (q Proof: An IrOA (4 8 , 16, 4, 5) with MD = 6 obtained by using product of two OA (2 8 , 16, 2, 5)s in [49] and an IrOA (4 12 , 24, 4, 7) with MD = 8 obtained by using product of two OA (2 12 , 24, 2, 7)s in [49] can generate two new QECCs ((16,1,6)) 4 and ((24,1,8)) 4 respectively. By using product of two OA (4608,23,2,4)s obtained from the ((23,9,5)) QECC in Example 7 in [15], we can get an OA (4608 2 , 23, 4, 4) (20,256,4)) 4 respectively. In particular, an IrOA (64,6,4,3) in [48] yields an optimal QECC ((6,1,4)) 4 in [50].…”

“…They play an important role in quantum information tasks, such as in entanglement purification, quantum key distribution, fault-tolerant quantum computation, and so on [6][7][8]. Since its discovery, code construction has come a long way [9][10][11][12][13][14][15][16]. Plenty of binary QECCs have been obtained, some of which from classical error-correcting codes (CECCs) [16][17][18][19].…”

Construction of quaternary quantum error-correcting codes via orthogonal arrays

“…The construction of OAs has been made new progress recently. New construction methods are constantly proposed in Pang et al [29], Wang et al [30], Pang et al [31], Pang et al [32], Zhang et al [33], Pang et al [34], Du et al [35], Pang et al [36] and Pang et al [37], which could facilitate the construction of related structures to OAs. Moreover, communications and computer sciences often benefit from OAs and related structures.…”

On the Construction of Variable Strength Orthogonal Arrays