Imaging device, an imaging system and a method for wavelength dependent imaging

What is claimed is: 1. An imaging device for wavelength dependent imaging, the imaging device comprising: a detector comprising a plurality of light sensitive elements, wherein each light sensitive element is configured to generate an electric signal dependent on an intensity of light incident onto the light sensitive element; a plurality of light propagating units, wherein each light propagating unit of the plurality of the light propagating units comprises: a funnel element having a collecting end and a transmitting end, and defining a central funnel axis extending from the collecting end to the transmitting end, the funnel element being configured to collect light incident at the collecting end and to propagate the light to the transmitting end, wherein a cross-section of the collecting end is larger than a cross-section of the transmitting end; a waveguide having a receiving end and a distributing end, and defining a central waveguide axis extending from the receiving end to the distributing end, the waveguide being configured to receive the light from the transmitting end at the receiving end and to propagate the light to the distributing end, wherein the waveguide is a multimode waveguide configured to propagate the light through the waveguide in dependence of wavelength such that a spatial distribution of the light at the distributing end is dependent on wavelength of the light; wherein, for a first light propagating unit, the funnel element and the waveguide have a first asymmetric coupling such that the central funnel axis at the transmitting end has a first displacement with respect to the central waveguide axis at the receiving end, and, for a second light propagating unit, the funnel element and the waveguide have a second asymmetric coupling such that the central funnel axis at the transmitting end has a second displacement with respect to the central waveguide axis at the receiving end, wherein the second displacement is different from the first displacement; wherein, for each light propagating unit, the light propagating unit is arranged with respect to the detector such that the light at the distributing end is incident onto at least two light sensitive elements of the plurality of light sensitive elements. 2. The imaging device according to claim 1 , wherein the plurality of light sensitive elements is arranged in a planar fashion in a detector plane, wherein the collecting ends of the funnel elements of all light propagating units of the plurality of light propagating units are arranged in a common plane parallel to the detector plane, and wherein, for each light propagating unit, the central funnel axis is arranged to be perpendicular to the detector plane. 3. The imaging device according to claim 1 , wherein, for each light propagating unit, the waveguide is configured to propagate the light through the waveguide in dependence of wavelength such that the light at the distributing end is distributed into at least two wavelength bands linearly distributed along the distributing end, and wherein each of the at least two wavelength bands is associated with a mutually unique light sensitive element of the at least two light sensitive elements. 4. The imaging device according to claim 3 , wherein the plurality of light sensitive elements is arranged in a planar fashion in a detector plane, wherein the collecting ends of the funnel elements of all light propagating units of the plurality of light propagating units are arranged in a common plane parallel to the detector plane, and wherein, for each light propagating unit, the central funnel axis is arranged to be perpendicular to the detector plane. 5. The imaging device according to claim 3 , wherein, for each light propagating unit, the wavelength bands are ordered along the distributing end in a descending manner with respect to wavelength. 6. The imaging device according to claim 5 , wherein the plurality of light sensitive elements is arranged in a planar fashion in a detector plane, wherein the collecting ends of the funnel elements of all light propagating units of the plurality of light propagating units are arranged in a common plane parallel to the detector plane, and wherein, for each light propagating unit, the central funnel axis is arranged to be perpendicular to the detector plane. 7. The imaging device according to claim 6 , wherein the plurality of light propagating units is arranged in at least a central zone arranged at a central portion of the detector, and a peripheral zone arranged at a peripheral portion of the detector, wherein, for light propagating units arranged in the central zone, the funnel element and the waveguide have the first asymmetric coupling, and for light propagating units arranged in the peripheral zone, the funnel element and the waveguide have the second asymmetric coupling. 8. The imaging device according to claim 7 , wherein the first displacement is larger than the second displacement. 9. The imaging device according to claim 1 , wherein the plurality of light propagating units is arranged in at least a central zone arranged at a central portion of the detector, and a peripheral zone arranged at a peripheral portion of the detector, wherein, for light propagating units arranged in the central zone, the funnel element and the waveguide have the first asymmetric coupling, and for light propagating units arranged in the peripheral zone, the funnel element and the waveguide have the second asymmetric coupling. 10. The imaging device according to claim 9 , wherein the plurality of light propagating units is further arranged in one or more intermediate zones arranged between the central zone and the peripheral zone; and wherein, for light propagating units arranged in the central zone, the one or more intermediate zones and the peripheral zone, a size of a displacement of the central funnel axis at the transmitting end with respect to the central waveguide axis at the receiving end gradually transitions from the first displacement for light propagating units arranged in the central zone towards the second displacement for light propagating units arranged in the peripheral zone with decreasing size of the displacement from the central zone, through the one or more intermediate zones towards the peripheral zone. 11. The imaging device according to claim 10 , wherein the plurality of light propagating units is arranged to present a symmetry axis such that an asymmetric coupling of the light propagating units on a first side of the symmetry axis, is configured to be mirrored with respect to an asymmetric coupling of the light propagating units on a second side of the symmetry axis, the second side being opposite to the first side with respect to the symmetry axis. 12. The imaging device according to claim 1 , wherein the plurality of light propagating units is arranged to present a symmetry axis such that an asymmetric coupling of the light propagating units on a first side of the symmetry axis, is configured to be mirrored with respect to an asymmetric coupling of the light propagating units on a second side of the symmetry axis, the second side being opposite to the first side with respect to the symmetry axis. 13. The imaging device according to claim 11 , wherein, for each light propagating unit, the waveguide is further configured to propagate the light through the waveguide in dependence of polarization such that a spatial distribution of the light at the distributing end is dependent on wavelength and polarization of the light. 14. The imaging device according to claim 1 , wherein, for each light propagating unit, the wavegui