[1] Nielsen M A,Chuang I L. Quantum Computation and Quantum Information [M].Cambridge University Press,2000.

[2] Rabitz H,Vivie-Riedle R D,Motzkus M,et al. Whither the future of controlling quantum phenomena [J].Science,2000,288(5467): 824-828.

[4] Schirmer S G,Greentree A D,et al. Quantum control using sequences of simple control pluses [OL].2001,quant-ph/0105155v1.

[5] Ramakrishna V,Ober R. Explicit generation of unitary transformation in a single atom or molecule [J].Phys.Rev. A,2000,61: 032106(1-6).

[6] Barenco A,Bennett C H,Clever R,et al. Elementary gates for quantum computation [J].Phys. Rev. A,1995,52: 3457-3467.

[7] Helgason S. Differential Geometry,Lie Groups and Symmetric Spaces [M].New York: Academic Press,1978.182-186,515-519.

[8] Khaneja N,Glaser S J. Cartan decomposition of and constructive control of spin systems [J].J. Chem. Phys.,2001,267(1): 11-23.

[9] Bullock S S,Brennen G K. Canonical decompositions of n-qubit quantum computations and concurrence [J].J.Math. Phys.,2004,45(6): 2447-2467.

[10] Bullock S S,Brennen G K,O'Leary D P. Time reversal and n-qubit canonical decompositions [J].J. Math. Phys.,2005,46(6): 062104(1-19).

[11] Dagli M,D'Alessandro D,Smith J D H. A recursive decomposition of unitary operators on n qubits [OL].2007,quant-ph/ 0701193v1.

[12] Sa' Earp H N,Pachos J K. A constructive algorithm for the Caxtan decomposition of SU(2n)[J].J. Math. Phys.,2005,46: 082108(1-11).

[13] D'Alessandro D,Albertini F. Quantum symmetries and Cartan decomposition in arbitrary dimensions [J].J.Phys. A: Math. Theor,2007,40: 2439-2453.

[14] D'Alessandro D,Romano R. Decompositions of unitaxy evolutions and entanglement dynamics of bipartite quantum systems [J].J. Math. Phys.,2006,47: 082109(1-13).

[15] Paige C C,Wei M. History and generality of the CS decomposition [J].Linear Algebra and Appl.,1994,208/209:303-326.

[16] Tucci R R. A rudimentary quantum compiler(2nd Ed)[OL].1999,quant-ph/ 9902062.

[17] Bullock S S. Note on the khaneja glaster decomposition [J].Quantum Information and Computation,2004,4(5):396-400.

[18] Shende V,Bullck S,Markov I. Synthesis of quantum logic circuits [J].IEEE Transactions on Computer Aided Design,2006,25: 1000-1010.

[19] M tt nen M,Vartiainen J J,Bergholm V,et al. Quantum circuits for general multi-qubit gates [J].Rhys. Rev.Lett.,2004,93: 130502(1-4).

[20] Kraus B,et al. Optimal creation of entanglement using two-qubit gate [J].Phys. Rev. A,2001,63: 062309(1-9).

[21] Leifer M S,Henderson L,Linden N. Optimal entanglement generation from quantum operator [J].Phys. Rev. A,2003,67: 012306(1-7).

[22] Ye M Y,Sun D,Zhang Y S,et al. Entanglement changing power of two-qubit unitary operatons [J].Phys. Rev.A,2004,70: 022326(1-5).

[23] Zhang Yong,Cao Wancang,Long'Guilu. Creation of entanglement with nonlocal operations [J].Commun. Theor.Phys.,2005,44(10): 625-630.

[24] Hu Baolin,et al. Entanglement capacity of two-qubit unitary operator with the help of auxiliary system [J].Commun. Theor. Phys.,2007,47(6): 1029-1032.

[26] Dü W,Vidal G,Cirac J I,et al. Entanglement capabilities of nonlocal Hamiltonians [J].Phys. Rev. Lett.,2001,87: 137901(1-4).

[27] Khaneja N,Brockett R,Glaser S J. Time optimal control in spin systems [J].Phys. Rev. A,2001,63(3):032308(1-13).

[28] Swoboda J. Time-optimal control of spin systems [OL].2006,quant-ph/0601131v1.

[29] Romano R,D'Alessandro D. Incoherent control and entanglement for two-dimensional coupled systems [J].Phys.Rev. A,2006,73: 022323(1-8).

[30] Vatan F,et al. Optimal quantum circuits for general two-qubit gates [J].Phys. Rev. A,2004,69: 032315(1-5).

[31] Shende V V,Markov I L,Bullock S S. Minimal universal two-qubit controlled-NOT-based circuits [J].Phys. Rev.A,2004,69: 062321(1-8).

[32] Zhang J,Vala J,Sastry S,et al. Minimum construction of two-qubit quantum operations [J].Phys. Rev. Lett.,2004,93: 020502(1-4).

[33] Vidal G,et al. Universal quantum circuit for two-qubit transformations with three controlled-NOT gates [J].Phys. Rev. A,2004,69: 010301(R)(1-4).

[34] Zhang Y S,Ye M Y,Guo G C. Conditions for optimal construction of two-qubit nonlocal gates [J].Phys. Rev.A,2005,71:062331(1-6).

[35] Vatan F,Williams C P. Realization of a General three-qubit quantum gate [OL].2004,quant-ph/ 0401178v2.

[37] Wong A,Christensen N. Potential multiparticle entanglement measure [J].Phys. Rev. A,2001,63: 044301(1-4).

[38] M tt nen M,Vartiainen J J. Decompositions of general quantum gates [OL].2005,quint-ph/0504100v1.

[39] Liu Y,Long G L,Sun Y. Analytic constructions of general n-qubit controlled gates [OL].2007,quant-ph/0708.3274.

[40] Khan F S,Perkowski M A. Synthesis of ternary quantum logic circuits by decomposition [C].Proceedings of the 7th International Symposium on Representations and Methodology of Future Computing Technologies,RM2005,Tokyo,Japan.

[41] Bullock S S,O'Leary D P,Brennen G K. Asymptotically optimal quantum circuits for d-level systems [J].Phys.Rev. Lett.,2005,94: 230502(1-18).

[42] Brennen G K,Bullock S S,O'Leary D P. Efficient circuits for exact-universal computation with qudits [J].Quantum Information and Computation,2006,6: 436(1-16).

[43] Khan F S,et al. Synthesis of multi-qudit hybrid and d-valued quantum logic circuits by decomposition [J].Theoretical Computer Science,2006,367(3): 336-346.