CONTROL METHOD OF QUANTUM BIT AND QUANTUM COMPUTER

Abstract

Provided is a control method of a quantum bit including, when a two-quantum bit computation is performed on a plurality of pairs of quantum bits by a plurality of barrier transistors controlled collectively, selectively performing a one-quantum bit computation on a quantum bit selected from the plurality of pairs of quantum bits to selectively perform a two-quantum bit computation on a desired quantum bit pair selected from the plurality of pairs of quantum bits.

Description

Claims

1. A control method of a quantum bit, comprising: when a two-quantum bit computation is performed on a plurality of pairs of quantum bits by a plurality of barrier transistors controlled collectively,selectively performing a one-quantum bit computation on a quantum bit selected from the plurality of pairs of quantum bits to selectively perform a two-quantum bit computation on a desired quantum bit pair selected from the plurality of pairs of quantum bits.

2. The control method of a quantum bit according to claim 1, the method further comprising: effectively performing an even number of times of exchange logic computations on the plurality of pairs of quantum bits to perform a one-quantum bit computation on at least one quantum bit of the desired quantum bit pair.

3. The control method of a quantum bit according to claim 2, the method further comprising: decomposing one time of the exchange logic computation into a plurality of two-quantum bit computations and executing the plurality of two-quantum bit computations to effectively perform two times of exchange logic computations.

4. The control method of a quantum bit according to claim 3, the method further comprising: decomposing one time of the exchange logic computation into a plurality of two-quantum bit computations and executing the plurality of two-quantum bit computations to effectively perform two times of exchange logic computations.

5. The control method of a quantum bit according to claim 2, wherein the one-quantum bit computation is obtained by decomposing a predetermined one-quantum bit computation.

6. The control method of a quantum bit according to claim 5, wherein the predetermined one-quantum bit computation is an inversion computation.

7. The control method of a quantum bit according to claim 6, further comprising: selectively performing a two-quantum bit computation on a desired quantum bit pair selected from the plurality of pairs of quantum bits by a control phase rotating gate operation.

8. A quantum computer that includes a quantum processor, a drive unit that drives the quantum processor, and a computer that controls the quantum processor and the drive unit, and performs a quantum gate operation on a quantum bit, wherein the quantum processor includes a transistor for performing the quantum gate operation,in the transistor, a gate electrode is common to each of a plurality of transistors,the quantum gate operation is controlled by an electric signal applied to the gate electrode and microwave radiation,at least one of the computer and the drive unit has a function of decomposing a desired quantum gate operation into element quantum gate operations, andthe element quantum gate operation is performed on the quantum bit to realize a desired quantum gate operation.

9. The quantum computer according to claim 8, wherein when the quantum gate operation is performed on a plurality of pairs of quantum bits by the transistor having the common gate electrode,realizing a first quantum gate operation by performing a first element quantum gate operation on a first quantum bit pair selected from the plurality of pairs of quantum bits; andrealizing a second quantum gate operation by performing a second element quantum gate operation on a second quantum bit pair selected from the plurality of pairs of quantum bits.

10. The quantum computer according to claim 9, wherein the first element quantum gate operation is a decomposition of a SWAP gate operation on the first quantum bit pair and a decomposition of a one-quantum bit gate operation on any quantum bit of the first quantum bit pair, andthe second element quantum gate operation is a decomposition of a SWAP gate operation on the second quantum bit pair, and the second quantum gate operation does not change a state of the second quantum bit pair.

11. The quantum computer according to claim 10, wherein in the quantum gate operation obtained by decomposing the SWAP gate operation, the quantum gate operation is performed by the transistor having a common gate electrode, andin the quantum gate operation obtained by decomposing the one-quantum bit gate operation, the quantum gate operation is performed by application of an electromagnetic field to any quantum bit of the first quantum bit pair and the microwave radiation.

12. The quantum computer according to claim 11, wherein the one-quantum bit gate operation is an inversion gate operation.

13. The quantum computer according to claim 12, wherein the first quantum gate operation is a control phase rotating gate operation on the first quantum bit pair.

14. The quantum computer according to claim 13, wherein the application of the electromagnetic field to any quantum bit of the first quantum bit pair is performed by a current flowing through a gate electrode that two-dimensionally surrounds the quantum bit.

15. The quantum computer according to claim 8, wherein in the quantum processor, the transistors for performing the quantum gate operation are arranged in a two-dimensional matrix.