Optical frequency shift device and method

What is claimed is: 1. An optical frequency shift device configured to shift a first optical signal of a first optical frequency to a second optical signal of a second optical frequency, the optical frequency shift device comprising: a splitter configured to split the first optical signal to an optical signal of a first polarization and an optical signal of a second polarization orthogonal to the first polarization; a generator configured to generate a first controlled light of the first polarization, a second controlled light of the second polarization, a third controlled light of the second polarization, and a fourth controlled light of the first polarization, each of frequency differences between the first controlled light and the second controlled light and between the third controlled light and the fourth controlled light having a frequency spacing equal to a difference between the first optical frequency and the second optical frequency; a nonlinear optical medium in which an idler light of the second polarization is created by causing cross phase modulation of the optical signal of the first polarization, the first controlled light, and the second controlled light, and in which an idler light of the first polarization is created by causing cross phase modulation of the optical signal of the second polarization, the third controlled light, and the fourth controlled light; and an optical combiner configured to combine the idler light of the second polarization and the idler light of the first polarization so as to generate the second optical signal. 2. The optical frequency shift device according to claim 1 , wherein the nonlinear optical medium includes: a first nonlinear optical medium in which the idler light of the second polarization is created by causing the cross phase modulation of the optical signal of the first polarization, the first controlled light, and the second controlled light; and a second nonlinear optical medium in which the idler light of the first polarization is created by causing the cross phase modulation of the optical signal of the second polarization, the third controlled light, and the fourth controlled light. 3. The optical frequency shift device according to claim 1 , wherein the generator includes: a light source configured to generate a first continuous wave, a second continuous wave, a third continuous wave, and a fourth continuous wave; and a processor configured to polarize: the first continuous wave to generate the first controlled light, the second continuous wave to generate the second controlled light orthogonal to the first controlled light, the third continuous wave to generate the third controlled light, and the fourth continuous wave to generate the fourth controlled light orthogonal to the third controlled light. 4. The optical frequency shift device according to claim 1 , wherein the generator includes: an optical comb generator configured to generate a plurality of continuous waves having predetermined frequency spacing according to an oscillation signal; and a processor configured to: select a first continuous wave, a second continuous wave, a third continuous wave, and a fourth continuous wave among the plurality of continuous waves generated by the optical comb generator, polarize: the first continuous wave to generate the first controlled light, the second continuous wave to generate the second controlled light orthogonal to the first controlled light, the third continuous wave to generate the third controlled light, and the fourth continuous wave to generate the fourth controlled light orthogonal to the third controlled light. 5. An optical frequency shift method of an optical frequency shift device configured to shift a first optical signal of a first optical frequency to a second optical signal of a second optical frequency, the optical frequency shift method comprising: splitting the first optical signal to an optical signal of a first polarization and an optical signal of a second polarization orthogonal to the first polarization; generating a first controlled light of the first polarization, a second controlled light of the second polarization, a third controlled light of the second polarization, and a fourth controlled light of the first polarization, each of frequency differences between the first controlled light and the second controlled light and between the third controlled light and the fourth controlled light having a frequency spacing equal to a difference between the first optical frequency and the second optical frequency; creating an idler light of the second polarization in a nonlinear optical medium by causing cross phase modulation of the optical signal of the first polarization, the first controlled light, and the second controlled light; creating idler light of the first polarization in the nonlinear optical medium by causing cross phase modulation of the optical signal of the second polarization, the third controlled light, and the fourth controlled light; combining the idler light of the second polarization and the idler light of the first polarization so as to generate the second optical signal.