Elements of information theory
Elements of information theory
CDMA: principles of spread spectrum communication
CDMA: principles of spread spectrum communication
Quantum computation and quantum information
Quantum computation and quantum information
Fault-tolerant quantum computation
FOCS '96 Proceedings of the 37th Annual Symposium on Foundations of Computer Science
A First Course in Information Theory (Information Technology: Transmission, Processing and Storage)
A First Course in Information Theory (Information Technology: Transmission, Processing and Storage)
Quantum Error Correction and Fault Tolerant Quantum Computing
Quantum Error Correction and Fault Tolerant Quantum Computing
Quantum network communication: the butterfly and beyond
IEEE Transactions on Information Theory
Quantum convolutional coding with shared entanglement: general structure
Quantum Information Processing
Quantum accuracy threshold for concatenated distance-3 codes
Quantum Information & Computation
A flow-map model for analyzing pseudothresholds in fault-tolerant quantum computing
Quantum Information & Computation
A comparative code study for quantum fault tolerance
Quantum Information & Computation
A strong converse theorem for quantum multiple access channels
General Theory of Information Transfer and Combinatorics
Quantum error correction via codes over GF(4)
IEEE Transactions on Information Theory
The capacity of the quantum multiple-access channel
IEEE Transactions on Information Theory
The private classical capacity and quantum capacity of a quantum channel
IEEE Transactions on Information Theory
Entanglement-Assisted Capacity of Quantum Multiple-Access Channels
IEEE Transactions on Information Theory
IEEE Transactions on Information Theory
A Resource Framework for Quantum Shannon Theory
IEEE Transactions on Information Theory
IEEE Transactions on Information Theory
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We show how to convert an arbitrary stabilizer code into a bipartite quantum code. A bipartite quantum code is one that involves two senders and one receiver. The two senders exploit both nonlocal and local quantum resources to encode quantum information with local encoding circuits. They transmit their encoded quantum data to a single receiver who then decodes the transmitted quantum information. The nonlocal resources in a bipartite code are ebits and nonlocal information qubits, and the local resources are ancillas and local information qubits. The technique of bipartite quantum error correction is useful in both the quantum communication scenario described above and in fault-tolerant quantum computation. It has application in fault-tolerant quantum computation because we can prepare nonlocal resources offline and exploit local encoding circuits. In particular, we derive an encoding circuit for a bipartite version of the Steane code that is local and additionally requires only nearest-neighbor interactions. We have simulated this encoding in the CNOT extended rectangle with a publicly available fault-tolerant simulation software. The result is that there is an improvement in the "pseudothreshold" with respect to the baseline Steane code, under the assumption that quantum memory errors occur less frequently than quantum gate errors.