Generating optical pulses via a soliton state of an optical microresonator

The invention claimed is: 1. A light pulse source adapted for generating repetitive optical pulses, comprising: a continuous wave (cw) laser arranged for providing cw laser light, an optical microresonator comprising a resonator material, which has a third order (Kerr) nonlinearity and an anomalous resonator dispersion, wherein the cw laser is arranged for coupling the cw laser light into the optical microresonator, which, at a predetermined relative detuning of the cw laser and the optical microresonator, is capable of including a light field in a soliton state, wherein soliton shaped pulses can be coupled out of the optical microresonator for providing the repetitive optical pulses, and a tuning device arranged for creating and maintaining the predetermined relative detuning of the cw laser and the optical microresonator based on a tuning time profile selected in dependency on a thermal time constant of the optical microresonator such that the soliton state is achieved in a thermal equilibrium state of the optical microresonator. 2. The light pulse source according to claim 1 , further comprising a monitoring device arranged for sensing a resonator output created in response to coupling the cw laser light into the optical microresonator and capable of detecting the soliton state, and the tuning device is adapted for adjusting the tuning time profile in dependency on an output signal of the monitoring device. 3. The light pulse source according to claim 2 , wherein the monitoring device comprises at least one of a transmission detector arranged for a detection of a discontinuous step in a resonator transmission when reaching the soliton state of the optical microresonator, an amplitude noise detector arranged for a detection of an amplitude noise of a resonator output, an RF beatnote detector arranged for a detection of RF beatnotes between adjacent frequency components of the optical spectrum of the light field coupled out of the optical microresonator, and an intensity detector arranged for a detection of a generated light frequency different from the frequency of the cw laser. 4. The light pulse source according to claim 3 , wherein the monitoring device and the tuning device are coupled with each other so that the tuning device can be controlled in response to detecting the soliton state of the optical microresonator by the monitoring device. 5. The light pulse source according to claim 1 , wherein the tuning time profile comprises a pre-stored scan time pattern. 6. The light pulse source according to claim 1 , wherein the tuning device is capable of reversing a tuning direction of the tuning time profile when the soliton state of the optical microresonator is achieved. 7. The light pulse source according to claim 1 , wherein the tuning device is capable of repeatedly creating the predetermined relative detuning of the cw laser and the optical microresonator with changing tuning time profiles, until a soliton state of the optical microresonator is reached. 8. The light pulse source according to claim 1 , wherein the tuning device comprises at least one of a wavelength tuning device capable of changing a wavelength of the cw laser, an intensity tuning device capable of changing an intensity of the cw laser light, a coupling tuning device capable of changing a coupling efficiency of coupling the cw laser light into the optical microresonator, a strain tuning device capable of changing at least one of a mechanical strain and a geometrical extend of the optical microresonator, a temperature tuning device capable of changing a temperature of the optical microresonator by at least one of laser induced heating and electrical resistor heating, and a wavelength and intensity simultaneous tuning device capable of changing an intensity and wavelength of the cw laser light simultaneously in a coordinated fashion. 9. The light pulse source according to claim 1 , further comprising at least one of an input waveguide arranged for coupling the cw laser light into the optical microresonator, and an output waveguide arranged for coupling the optical pulses out of the optical microresonator. 10. The light pulse source according to claim 9 , wherein the input waveguide and the output waveguide comprise a common waveguide. 11. The light pulse source according to claim 9 , wherein the output waveguide is adapted for a dispersion compensation. 12. The light pulse source according to claim 9 , wherein the optical microresonator and at least one of the input waveguide and the output waveguide are integrally formed in a chip. 13. The light pulse source according to claim 1 , further comprising a laser pump stabilizing/controlling mechanism arranged for at least one of stabilizing and controlling at least one of a pump power and a pump frequency of the cw laser once the soliton state is reached in order to stabilize the soliton state, wherein the stabilizing/controlling mechanism uses an intensity measured by the monitoring device or a separate detector device or uses an RF beatnote frequency measured by the monitoring device. 14. The light pulse source according to claim 1 , wherein the tuning device is capable of changing the resonance frequency of the optical microresonator such that the optical microresonator approaches the soliton state within a tuning period below 100 ms. 15. The light pulse source according to claim 1 , further comprising at least one of the features the optical microresonator comprises a polished circular crystalline preform selected from the group consisting of quartz, MgF 2 , CaF 2 and BaF 2 , supporting whispering gallery optical modes, and the optical microresonator further comprises materials suitable for micro-fabrication selected from the group consisting of SiN, AlN, SiO, and Si, whereby the optical microresonator and a waveguide are arranged on a common chip substrate. 16. The light pulse source according to claim 1 , wherein the tuning device is capable of rapidly modulating at least one of the intensity and frequency of the cw laser with a modulation frequency corresponding to an anticipated rate of the repetitive pulses to seed soliton states. 17. The light pulse source according to claim 1 , wherein the tuning device is capable of reducing the pump power of the cw laser for a time period shorter or on an order of an optical build-up time constant of the resonator to induce transitions between different soliton states. 18. A method of generating repetitive optical pulses, comprising the steps of: providing cw laser light with a continuous wave (cw) laser, coupling the cw laser light into an optical microresonator comprising a resonator material, which has a third order (Kerr) nonlinearity and an anomalous resonator dispersion, wherein the optical microresonator, at a predetermined relative detuning of the cw laser and the optical microresonator, is capable of including a light field in a soliton state, creating and maintaining the predetermined relative detuning of the cw laser and the optical microresonator with a tuning device based on a tuning time profile selected in dependency on a thermal time constant of the optical microresonator such that the soliton state is achieved in a thermal equilibrium state of the optical microresonator, and coupling soliton shaped pulses out of the optical microresonator, which provide the repetitive optical pulses. 19. The method according to claim 18 , further comprising the steps of sensing a resonator output created in respon