Relation of operator Schmidt decomposition and CNOT complexity
Quantum Information Processing
Exact canonical decomposition of two-qubit operators in terms of CNOT
Quantum Information Processing
Operator-Schmidt decomposition and the geometrical edges of two-qubit gates
Quantum Information Processing
Quantum circuits for incompletely specified two-qubit operators
Quantum Information & Computation
A discrete local invariant for quantum gates
Quantum Information & Computation
Robustness of Shor's algorithm
Quantum Information & Computation
On the CNOT-cost of TOFFOLI gates
Quantum Information & Computation
Matrix rearrangement approach for the entangling power with hybrid qudit systems
Quantum Information & Computation
Quantum Information & Computation
Encoded universality from a single physical interaction
Quantum Information & Computation
Universal sets of quantum information processing primitives and their optimal use
General Theory of Information Transfer and Combinatorics
Universal quantum computation and leakage reduction in the 3-qubit decoherence free subsystem
Quantum Information & Computation
Entanglement dynamics of two-qubit pure state
Quantum Information Processing
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Entanglement of two parts of a quantum system is a nonlocal property unaffected by local manipulations of these parts. It can be described by quantities invariant under local unitary transformations. Here we present, for a system of two qubits, a set of invariants which provides a complete description of nonlocal properties. The set contains 18 real polynomials of the entries of the density matrix. We prove that one of two mixed states can be transformed into the other by single-qubit operations if and only if these states have equal values of all 18 invariants. Corresponding local operations can be found efficiently. Without any of these 18 invariants the set is incomplete. Similarly, nonlocal, entangling properties of two-qubit unitary gates are invariant under single-qubit operations. We present a complete set of 3 real polynomial invariants of unitary gates. Our results are useful for optimization of quantum computations since they provide an effective tool to verify if and how a given two-qubit operation can be performed using exactly one elementary two-qubit gate, implemented by a basic physical manipulation (and arbitrarily many single-qubit gates).PACS: 03.67-a; 03.67.Lx