Title :
Quantum convolutional codes design and their encoder architectures
Author :
Kong, Jun Jin ; Parhi, Keshab K.
Author_Institution :
Dept. of Electr. & Comput. Eng., Minnesota Univ., USA
Abstract :
In this paper, design of quantum convolutional codes and their encoder architectures have been investigated. We claim that rate-1/(n+1) quantum systematic convolutional codes can be constructed from rate-1/n classical nonsystematic convolutional codes, where n is greater than or equal to 2. The free distances (dfree) of proposed rate-1/(n+1) quantum systematic convolutional codes are larger than that of original rate-1/n classical nonsystematic convolutional codes. A quantum convolutional code encoder can be implemented by using quantum linear feed-forward shift registers and quantum exclusive-OR (controlled-NOT: CNOT) gates. A quantum memory may be used as a quantum state delay element of a quantum register. It is also shown that different encoder architectures one needed for quantum nonsuperposition and superposition state inputs. For quantum superposition state input, additional Hadamard gates should be used in conjunction with a quantum convolutional code encoder for quantum nonsuperposition state input.
Keywords :
Hadamard codes; convolutional codes; delays; feedforward; quantum gates; shift registers; Hadamard gate; classical nonsystematic convolutional code; encoder architecture; quantum convolutional code design; quantum exclusive-OR gate; quantum linear feed-forward shift registers; quantum nonsuperposition; state delay element; superposition state input; Computer architecture; Convolutional codes; Delay effects; Feedback circuits; Flip-flops; Polynomials; Protection; Quantum computing; Shift registers; USA Councils;
Conference_Titel :
Signals, Systems and Computers, 2004. Conference Record of the Thirty-Eighth Asilomar Conference on
Print_ISBN :
0-7803-8622-1
DOI :
10.1109/ACSSC.2004.1399317
