Photonic integrated circuit (PIC) radio frequency oscillator

What is claimed is: 1. A photonic dual resonance Radio Frequency (RF) oscillator, comprising: an optical gain media coupled to a first mirror, the gain media configured to be coupled to a photonic integrated circuit (PIC); the PIC, comprising: a first optical cavity located within the PIC; a first tunable mirror to form a first optical cavity between the first mirror in the gain media and the first tunable mirror; a frequency tunable intra-cavity dual tone resonator positioned within the first optical cavity to constrain the first optical cavity to produce two primary laser tones with a tunable frequency spacing, the two primary laser tones having a common optical path within the first optical cavity; and one or more phase adjusters to provide the tunable frequency spacing; a photo detector optically coupled to the PIC and configured to receive the two primary laser tones from the first tunable mirror and mix the two primary laser tones to form an RF output signal with a frequency selected by the tunable frequency spacing of the two primary laser tones. 2. The photonic dual resonance RF oscillator of claim 1 , wherein the PIC further comprises: a second optical cavity within the PIC that is optically coupled to the first optical cavity; an intracavity element providing non-linear optical gain; a second tunable mirror to form a second optical path between the first mirror in the gain media and the second tunable mirror, the second optical path passing through the intracavity element; and one or more phase adjusters to dynamically adjust phase delays within one or more of the first or the second cavities; wherein the two primary laser tones are injected into the second optical cavity from the first optical cavity and the second optical cavity is configured to use the non-linear optical gain of the intracavity element to produce four wave mixing (FWM) to create at least two side tones from the two primary tones and reduce phase jitter and drift in the two primary tones to reduce a phase noise in the RF output signal. 3. The photonic dual resonance RF oscillator of claim 2 , wherein the phase noise in the RF output signal is less than −120 decibels relative to the carrier/Hertz (dBc/Hz) to −160 dBc/Hz. 4. The photonic dual resonance RF oscillator of claim 2 , wherein the intracavity element is located in one or more of the optical gain media, a waveguide optically coupled to the second tunable mirror, or a separate element optically coupled to the second tunable mirror. 5. The photonic dual resonance RF oscillator of claim 2 , further comprising an optical coupler configured to couple the two primary tones from the first optical cavity to the second optical cavity. 6. The photonic dual resonance RF oscillator of claim 2 , further comprising: a first waveguide implemented in the PIC that is optically coupled to the first mirror in the optical gain media and the second tunable mirror; a first resonant loop waveguide implemented in the PIC and spaced a selected distance from the first waveguide and configured to couple an optical laser signal from the first waveguide to the first resonant loop waveguide; a second resonant loop waveguide implemented in the PIC and spaced a selected distance from the first resonant loop waveguide and configured to couple the optical laser signal from the first resonant loop waveguide to the second resonant loop waveguide; and a second waveguide implemented in the PIC and spaced a selected distance from the second resonant loop waveguide and configured to couple the optical laser signal from the second resonant loop waveguide to the second waveguide, wherein the second waveguide is optically coupled to the first tunable mirror. 7. The photonic dual resonance RF oscillator of claim 6 , wherein the one or more phase adjusters comprises one or more of: a first phase adjuster coupled to the first waveguide and configured to tune an optical coupling between the first waveguide and the first resonant loop waveguide; or a third phase adjuster coupled to the second waveguide and configured to tune an optical coupling between the second waveguide and the second resonant loop waveguide; or a fourth phase adjuster coupled to the first resonant loop waveguide and configured to adjust resonance misalignment in the first resonant loop waveguide; or a fifth phase adjuster coupled to the second resonant loop waveguide and configured to adjust resonance misalignment in the second resonant loop waveguide; or a sixth phase adjuster coupled to the first waveguide and configured to adjust an intracavity phase of the second optical path; or a seventh phase adjuster coupled to the second waveguide and configured to adjust an intracavity phase of the first optical path; or an eighth phase adjuster coupled to the second adjustable mirror and configured to adjust a reflectivity of the second adjustable mirror; or a ninth phase adjuster coupled to the first adjustable mirror and configured to adjust a reflectivity of the first adjustable mirror. 8. The photonic dual resonance RF oscillator of claim 7 , wherein: one or more of the first, the third, the fourth, the fifth, the sixth, the seventh, the eighth, or the ninth phase adjusters are comprised of a metal micro-heater thermally coupled to one or more of the first waveguide, the first resonant loop waveguide, the second resonant loop waveguide or the second waveguide using a thermally conductive metal with a high heat capacity to drive a thermo-optic induced effective path length change in the respective waveguide; or one or more of the first, the third, the fourth, the fifth, the sixth, the seventh, the eighth, or the ninth phase adjusters are comprised of an electro-optic phase shifter used to adjust a phase in one or more of the first waveguide, the first resonant loop waveguide, the second resonant loop waveguide or the second waveguide. 9. The photonic dual resonance RF oscillator of claim 6 , wherein the one or more phase adjusters comprises one or more of: a first doublet phase adjuster coupled to the second resonant loop waveguide; and a second doublet phase adjuster coupled to the first resonant loop waveguide; wherein the first doublet phase adjuster and the second doublet phase adjuster are configured to tune an optical frequency spacing between the two primary laser tones to select the frequency of the RF output. 10. The photonic dual resonance RF oscillator of claim 9 , wherein: the first doublet phase adjuster and the second doublet phase adjuster are comprised of a metal micro-heater thermally coupled to one or more of the first resonator loop waveguide or the second resonator loop waveguide using a thermally conductive metal with a high heat capacity to drive a thermo-optic induced effective path length change in the respective waveguide; or the first doublet phase adjuster and the second doublet phase adjuster are each comprised of an electro-optic phase shifter to change a phase within the first resonator loop waveguide or the second resonator loop waveguide, respectively. 11. The photonic dual resonance RF oscillator of claim 1 , wherein: the photodetector is optically coupled to an output of the photonic dual resonance RF oscillator via a free-space coupling or a waveguide coupling; or the photodetector is resident on the PIC and optically coupled to the first tunable mirror. 12. The photonic dual resonance RF oscillator of claim 1 , wherein the frequency tunable intra-cavity dual tone resonator further comprises: a first optical resonator that is optically coupled to the second optical path, the first optical resonator including a first phase shifter; and a seco