Multimode Josephson parametric converter: coupling Josephson ring modulator to metamaterial

What is claimed is: 1. A method of operating a multimode Josephson parametric converter as a multimode quantum limited amplifier, the method comprising: receiving, by the multimode Josephson parametric converter, multiple quantum signals simultaneously at different resonance frequencies such that a first group of the multiple quantum signals is received at a first multimode resonator and a second group of the multiple quantum signals is received at a second multimode resonator; receiving, by the multimode Josephson parametric converter, pump signals; amplifying simultaneously, by the multimode Josephson parametric converter, the multiple quantum signals, wherein the multimode Josephson parametric converter operates in reflection; and reflecting the multiple quantum signals having been amplified at the different resonance frequencies. 2. The method of claim 1 , wherein the first group of the different resonance frequencies are of resonance modes of the first multimode resonator; wherein the first multimode resonator is a first left-handed transmission line; wherein the second group of the different resonance frequencies are of resonance modes of the second multimode resonator; and wherein the second multimode resonator is a second left-handed transmission line. 3. The method of claim 2 , wherein each of the pump signals is a frequency sum of one of the different resonance frequencies in the first group and one of the different resonance frequencies in the second group, such that the multiple quantum signals at the one of the first group and the one of the second group are amplified. 4. The method of claim 2 , wherein a first pump signal is a first frequency sum of a first resonance frequency in the first group plus a first resonance frequency in the second group, a second pump signal is a second frequency sum of a second resonance frequency in the first group plus a second resonance frequency in the second group, through a last pump signal that is a last frequency sum of a last resonance frequency in the first group plus a last resonance frequency in the second group. 5. The method of claim 4 , wherein at least one of the first through last resonance frequencies in the first group and the first through last resonance frequencies in the second group is a same. 6. The method of claim 4 , wherein at least one of the first through last resonance frequencies in the first group and the first through last resonance frequencies in the second group is different. 7. The method of claim 1 , wherein the multiple quantum signals at the different frequencies range from about 5-15 GHz. 8. The method of claim 1 , wherein the multimode Josephson parametric converter is configured to amplify simultaneously the multiple quantum signals at the different resonance frequencies via a first multimode resonator and a second multimode resonator, the first and second multimode resonators being connected to a dispersive nonlinear medium. 9. A method of operating a multimode Josephson parametric converter to generate multiple pairs of entangled photons, the method comprising: receiving, by a first multimode resonator in the multimode Josephson parametric converter, a first group of signals at different resonance frequencies of the resonance modes of the first multimode resonator, wherein the first multimode resonator is a first left-handed transmission line; receiving, by a second multimode resonator in the multimode Josephson parametric converter, a second group of signals at different resonance frequencies of the resonance modes of the second multimode resonator, wherein the second multimode resonator is a second left-handed transmission line; receiving pump signals, by the second multimode resonator; and generating simultaneously, by the multimode Josephson parametric converter, pairs of entangled photons. 10. The method of claim 9 , wherein the pump signals are a first frequency sum through a last frequency sum; wherein the pairs of entangled photons include a first pair through a last pair; wherein the first frequency sum is a summation of one resonance frequency of the first group plus one resonance frequency of the second group, wherein a second frequency sum is a summation of another resonance frequency of the first group plus another resonance frequency of the second group, and wherein the last frequency sum is a summation of yet another resonance frequency of the first group plus yet another resonance frequency of the second group. 11. The method of claim 10 , wherein the first pair of the entangled photons corresponds to a first photon at the one resonance frequency of the first group and a first photon at the one resonance frequency of the second group, in response to energy of the first frequency sum of the pump signals being down-converted via interaction with a dispersive nonlinear medium; wherein a second pair of the entangled photons corresponds to a second photon at the another resonance frequency of the first group and a second photon at the another resonance frequency of the second group, in response energy to the second frequency sum of the pump signals being down-converted via interaction with the dispersive nonlinear medium; and wherein the last pair of the entangled photons corresponds to a last photon at the yet another resonance frequency of the first group and a last photon at the yet another resonance frequency of the second group, in response to energy of the third frequency sum of the pump signals being down-converted via interaction with the dispersive nonlinear medium. 12. The method of claim 9 , wherein the first group of signals and the second group of signals at the different resonance frequencies range from about 5-15 GHz.