Laser to chip coupler

What is claimed is: 1. A method comprising the steps of: coupling to a primary photonic chip defining a first optical element an input beam incoming from a photonic device of a second optical element at an input interface of the primary photonic chip, wherein the photonic device is adapted to emit the input beam; the primary photonic chip comprises a coupling apparatus configured to receive the input beam, having a plurality of single mode optical paths, the single mode optical paths are strongly coupled to each other at the input interface of the primary photonic chip, such that regions of said strongly coupled single mode optical paths correspond to one of (i) distinct but highly coupled waveguides forming a multi-mode section and (ii) waveguides fully merged into a multi-mode section; wherein the primary photonic chip further comprises a section beyond the input interface in which the plurality of single mode optical paths is singulated into independent single mode optical paths, and the coupling step comprises coupling light from the input beam to the coupling apparatus; wherein the power coupled to each of the independent single mode optical paths is substantially equal. 2. The method of claim 1 , further comprising positioning a third optical element according to the amount of light coupled to each of the single mode optical paths from the input beam so as to directly or indirectly couple a subset of, but not all of, the single mode optical paths to the third optical element, wherein the subset varies depending on the amount of light coupled to each of the single mode optical paths from the input beam when the second optical element and primary photonic chip are coupled. 3. The method of claim 2 , wherein the primary photonic chip includes output ports thereon corresponding to the subset of single mode optical paths coupled to the third optical element that are adjacent to each other, and further comprising the step of selecting the subset to include a fixed number of single mode optical paths such that (i) a minimum power transmitted from any of the corresponding output ports is either maximized or larger than a minimum power required for the single mode optical paths to be functional. 4. The method of claim 1 , further comprising connecting a subset of the single mode optical paths to an adaptive waveguide combiner comprising at least one phase shifting element whose settings are either dynamically or statically determined according to power and phase of the light transported by the subset of single mode optical paths. 5. The method of claim 1 , wherein a subset of the single mode optical paths are part of independent parallel data lines and further comprising the step of one of (i) powering up or (ii) at least partially powering down receiver subsystems coupled to said data lines via corresponding output ports of the primary photonic chip according to (i) the amount of light arriving at the receiver subsystems or (ii) the amount of light coupled out of the corresponding output ports. 6. The method of claim 1 , wherein the coupling apparatus is configured to butt-couple with the input beam, and the coupling step comprises butt-coupling light from the input beam to the coupling apparatus. 7. A photonic apparatus comprising: a first optical element defined by a primary photonic chip and a second optical element comprising a photonic device adapted to emit an input beam, wherein the primary photonic chip comprises a coupling apparatus including an input interface which is configured to receive the input beam, and further including a plurality of single mode optical paths strongly coupled to each other at the input interface of the primary photonic chip, such that regions of said strongly coupled single mode optical paths correspond to either (i) distinct but highly coupled waveguides forming a multi-mode section or (ii) waveguides fully merged into a multi-mode section; wherein the primary photonic chip further comprises a section beyond the input interface in which the plurality of single mode optical paths is singulated into independent single mode optical paths, and wherein the power coupled to each of the independent single mode optical paths is substantially equal. 8. The apparatus of claim 7 , wherein the input interface of the primary photonic chip is defined by a partial etch of the primary photonic chip. 9. The apparatus of claim 7 , wherein the single mode optical paths are coupled to a third optical element via grating couplers. 10. The apparatus of claim 7 , wherein: the primary photonic chip further comprises a multi-mode interferometer having said multi-mode section connected to an array of single mode optical paths at an end of the multi-mode section and to the input interface with an arrangement such that light does not pass through a unique single mode optical path creating a bottleneck between the input interface and the multi-mode section, wherein, as measured starting from the input interface of the primary photonic chip, (i) the effective length of the multi-mode interferometer or (ii) the length of the multi-mode interferometer is longer than L π /4. 11. The apparatus of claim 7 , further comprising said multi-mode section, wherein: the input interface of the primary photonic chip is connected to the multi-mode section, the multi-mode section is singulated into several waveguides at the input interface such that a width of said waveguides is smaller than 70% of a maximum single mode waveguide width at the input interface, the distance between 50% intensity points of waveguide modes of adjacent waveguides of said several waveguides at the input interface is less than 100% of a smaller full width at half maximum of the waveguide modes of said adjacent waveguides at the input interface, and the multi-mode section is connected to an array of the single mode optical paths at an end thereof. 12. The apparatus of claim 7 , wherein light intensity at an end of the multi-mode section is larger than 35% of the maximum of an intensity distribution at the end of the multi-mode section over a topologically connected portion of the multi-mode section that is wider than 35% of the multi-mode section and centered on a center axis of the multi-mode section, and wherein a full width at half maximum of the input beam in a horizontal direction along the input interface is at least 1.5/10 of a width of the multi-mode section. 13. The apparatus of claim 12 , wherein the light intensity at the end of the multi-mode section is larger than 50% of the maximum of the intensity distribution at the end of the multi-mode section over a topologically connected portion of the multi-mode section that is wider than 50% of the multi-mode section and centered on the center axis of the multi-mode section. 14. The apparatus of claim 7 , wherein at least one of the single mode optical paths is coupled to an end of the multi-mode section and carries light such that at least 20% of said light corresponds to one image created by the multi-mode section and at least 20% of said light corresponds to another image created by the multi-mode section, and configured such that images can be distinguished from each other in that said images would be spatially separated from each other when the input optical beam defined a thinner width but the same optical axis. 15. The apparatus of claim 7 , wherein light intensity at an end of the multi-mode section is larger than 35% of the maximum of an intensity distribution at the end of the multi-mode section over a topologically connected portion of the multi-mode section that is wider than 35% o