Method and system for parity-time symmetric optics and nonreciprocal light transmission

What is claimed is: 1. An optical assembly comprising; a first dissipative optical system; a second optical system coupled in an energy transfer communication with said first optical system, said second optical system configured to receive a flow of energy from an external source, said second optical system configured to transfer at least a portion of the received flow of energy to said first optical system through the energy transfer communication wherein the received flow of energy of said second optical system is approximately equal to a dissipated energy of the first optical system; said first dissipative optical system and said second optical system are configured to operate below or above a transitional coupling strength thereby configured to effect phase transition from operating in a linear unbroken parity-time symmetry operation to a broken parity-time symmetry operation thereby inducing a non-reciprocal energy transmission, where the at least a portion of the received flow of energy transferred to said first optical system from said second optical system is selectable using at least one of an amount of couple between said first optical system and said second optical system and a gain of said second optical system. 2. The optical assembly of claim 1 , wherein said first optical system and said second optical system each comprise micro-resonator systems. 3. The optical assembly of claim 1 , further comprising: a first wave guide coupled in light communication to said first optical system; and a second wave guide coupled in light communication to said second. 4. The optical assembly of claim 1 , wherein said first optical system and said second optical system exhibit nonreciprocal light transmission based on optical nonlinearity when operating in a broken parity-time symmetry regime based on at least one of the amount of couple and the gain. 5. The optical assembly of claim 1 , wherein said first optical system and said second optical system are configured to operate in parity-time symmetry when the gain of said second optical system is approximately equal to the loss in the first optical system, and where the coupling in the energy transfer communication is above a critical value. 6. The optical assembly of claim 1 , wherein said first optical system and said second optical system are configured to operate in a broken parity-time symmetric phase when at least one of an amount of couple between the first optical system exceeds a predetermined threshold range and a gain applied to said second optical system exceeds a predetermined threshold amount. 7. The optical assembly of claim 6 , wherein the amount of couple between the first optical system is selectable based on a physical distance between said first optical system and said second optical system and a position of a coupling medium associated with said first optical system and said second optical system. 8. The optical assembly of claim 6 , wherein said second optical system further comprises a pump laser configured to pump predetermined ions into said second optical system, an amount of gain added by the pumped ions based on a wavelength of photons emitted by the pumped ions. 9. The optical assembly of claim 8 , wherein the pumped ions comprise at least one of rare earth ions, fluorescent dyes, optical dyes, quantum dots, an optically active medium embedded into a resonator structure of said second optical system, Raman gain, and parametric gain from a material said second optical system is formed of. 10. The optical assembly of claim 6 , wherein said gain is electrically pumped. 11. The optical assembly of claim 1 , further comprising more than two optical systems, at least some of the more than two optical systems coupled together in energy transfer communication wherein a portion of the more than two optical systems are dissipative systems and are coupled to others of the more than two optical systems that are at least one of optically and electrically pumped to add a predetermined gain to the others of the more than two optical systems. 12. The optical assembly of claim 1 , wherein a structure of at least one of said first optical system and said second optical system comprises at least one of a micro-scale resonator and nano-scale resonator, including one or more of a photonic crystal resonator, a Fabry-Pérot resonator, micro-bottle, a micro-toroid, a micro-disk, a micro-ring, a micro-sphere. 13. A method of nonreciprocal light transmission in a micro resonator system, said method comprising: coupling a first micro resonator optical system in energy communication to a second micro resonator optical system; operating the second micro resonator optical system in a dissipative mode wherein the second micro resonator optical system loses energy during the operation; adding gain to the first micro resonator optical system; transferring energy from the first micro resonator optical system to the second micro resonator optical system through the couple where the couple is sufficiently strong whereby the gain of the first micro-resonator and the losses of the second micro resonator are approximately equal and the first micro resonator and the second micro resonator form an unbroken linear PT-symmetric reciprocal micro resonator system; transitioning the unbroken linear PT-symmetric reciprocal micro resonator system to a broken non-linear PT-symmetric non-reciprocal micro resonator system; and operating the first micro resonator optical system and second micro resonator optical system in a broken parity-time symmetry regime based on at least one of the amount of couple and the amount of gain added such that the micro resonator system exhibits nonreciprocal light transmission. 14. The method of claim 13 , wherein coupling a first micro resonator optical system in energy communication to a second micro resonator optical system comprises controlling a strength of the coupling using a distance between the first micro resonator optical system and the second micro resonator optical system. 15. The method of claim 13 , wherein controlling a strength of the coupling comprises controlling a strength of the coupling between the first micro resonator optical system and the second micro resonator optical system such that energy in the first micro resonator optical system flows at a rate that compensates for the losses in the second micro resonator optical system. 16. The method of claim 13 , wherein adding gain to the first micro resonator optical system comprises pumping predetermined ions into the first micro resonator optical system wherein an amount of gain added by the pumped ions is a function of a wavelength of photons emitted by the pumped ions. 17. The method of claim 13 , wherein the first micro resonator optical system comprises an active resonator formed of silica doped with erbium 3+ ions (Er 3+ ), the second micro resonator optical system comprises a passive resonator formed of silica without dopants, the method comprises optically pumping the first micro resonator optical system with Er 3+ ions to add gain. 18. The method of claim 13 , wherein adding gain to the first micro resonator optical system comprises optically pumping at least one of rare earth ions, fluorescent dyes, optical dyes, and quantum dots into the first micro resonator optical system. 19. The method of claim 13 , wherein adding gain to the first micro resonator optical system comprises using at least one of an optically active medium embedded into a resonator structure of the first micro resonator optical sys