An optical device includes an optical port array, an optical arrangement, a dispersion element, a focusing element and a programmable optical phase modulator. The optical port array has at least one optical input port for receiving an optical beam and a plurality of optical output ports. The optical arrangement allows optical coupling between the input port and each of the output ports and prevents optical coupling between any one of the plurality of optical output ports and any other of the plurality of optical output ports. The dispersion element receives the optical beam from the input port after traversing the optical arrangement and spatially separates the optical beam into a plurality of wavelength components. The focusing element focuses the plurality of wavelength components. The programmable optical phase modulator receives the focused plurality of wavelength components and steers them to a selected one of the optical outputs.

An optical device includes an optical port array, an optical arrangement, a dispersion element, a focusing element and a programmable optical phase modulator. The optical port array has at least one optical input port for receiving an optical beam and a plurality of optical output ports. The optical arrangement allows optical coupling between the input port and each of the output ports and prevents optical coupling between any one of the plurality of optical output ports and any other of the plurality of optical output ports. The dispersion element receives the optical beam from the input port after traversing the optical arrangement and spatially separates the optical beam into a plurality of wavelength components. The focusing element focuses the plurality of wavelength components. The programmable optical phase modulator receives the focused plurality of wavelength components and steers them to a selected one of the optical outputs.

An optical switching apparatus is provided. The apparatus includes one or more input ports, a dispersion assembly, a first lens assembly, a redirection assembly, and one or more output ports. The input ports are configured to input a first beam into a dispersion assembly at a first angle of incidence in a first direction, and to input a second beam into the dispersion assembly at a second angle of incidence in the first direction. A difference between absolute values of the first angle of incidence and the second angle of incidence is not zero, and enables a first region in which spots of the first beam are arranged and a second region in which spots of the second beam are arranged to be separated from each other in the first direction, and enables the first region and the second region to at least partially overlap in a second direction.

Aspects of the present disclosure describe large scale steerable optical switched arrays that may be fabricated on a common substrate including many thousands or more emitters that may be arranged in a curved pattern at the focal plane of a lens thereby allowing the directional control of emitted light and selective reception of reflected light suitable for use in imaging, ranging, and sensing applications including accident avoidance.

Aspects of the present disclosure describe large scale steerable optical switched arrays that may be fabricated on a common substrate including many thousands or more emitters that may be arranged in a curved pattern at the focal plane of a lens thereby allowing the directional control of emitted light and selective reception of reflected light suitable for use in imaging, ranging, and sensing applications including accident avoidance.

A LCOS routing device, comprising: an optical input and plurality of optical outputs; a spatial light modulator (SLM) between said input and output, for displaying a kinoform; a data processor, configured to provide kinoform data for displaying said kinoform on said SLM. Said data processor inputs routing and calculates said kinoform data. Said data processor calculates kinoform data by: determining an initial phase pattern for said kinoform; calculating a replay field of said phase pattern; modifying an amplitude component of said replay field, retaining a phase component of said replay field to provide an updated replay field; performing a space-frequency transform on said updated replay field to determine an updated phase pattern for said kinoform; and repeating said calculating and updating of said replay field and said performing of said space-frequency transform until said kinoform for display is determined; and outputting said kinoform data for display on said LCOS SLM.

A wavelength selective switch includes an attenuation liquid crystal cell array and a switching liquid crystal cell array, the attenuation liquid crystal cell array is configured to select a region where a light is incident on the switching liquid crystal cell array; the switching liquid crystal cell array includes a first ECB liquid crystal cell array, which is divided into a plurality of pixel units, a phase of each pixel unit is adjusted by setting different voltages so that a phase pattern formed by the pixel units exhibits a lens property, and the light passing through the switching liquid crystal cell array is deflected by changing a center of the lens formed by the phase pattern, so as to select an outgoing port.

A beam branching device capable of suppressing an increase in the cost and the like even when the number of branching directions of an incident beam is large and increasing the coupling efficiency even when the rotation accuracy of a rotary motor is not increased too high and coping with high-speed switching of the optical path is provided. In a beam branching device, a rotation shaft of a rotary motor is rotated to rotate a rotating member together with a plurality of reflection mirrors so that an incident beam is reflected from a reflection mirror surface portion of any one of the plurality of reflection mirrors and the incident beam is branched to a plurality of directions to switch an optical path of a reflection beam. A central axis of the rotating member is at a skewed position in relation to a central line of the incident beam, and the plurality of reflection mirrors are arranged at a position on the rotating member to face both sides in an axial direction of the rotating member with a position closest to the incident beam interposed therebetween.

A beam branching device capable of suppressing an increase in the cost and the like even when the number of branching directions of an incident beam is large and increasing the coupling efficiency even when the rotation accuracy of a rotary motor is not increased too high and coping with high-speed switching of the optical path is provided. In a beam branching device, a rotation shaft of a rotary motor is rotated to rotate a rotating member together with a plurality of reflection mirrors so that an incident beam is reflected from a reflection mirror surface portion of any one of the plurality of reflection mirrors and the incident beam is branched to a plurality of directions to switch an optical path of a reflection beam. A central axis of the rotating member is at a skewed position in relation to a central line of the incident beam, and the plurality of reflection mirrors are arranged at a position on the rotating member to face both sides in an axial direction of the rotating member with a position closest to the incident beam interposed therebetween.

A LCOS routing device, comprising: an optical input and plurality of optical outputs; a spatial light modulator (SLM) between said input and output, for displaying a kinoform; a data processor, configured to provide kinoform data for displaying said kinoform on said SLM. Said data processor inputs routing and calculates said kinoform data. Said data processor calculates kinoform data by: determining an initial phase pattern for said kinoform; calculating a replay field of said phase pattern; modifying an amplitude component of said replay field, retaining a phase component of said replay field to provide an updated replay field; performing a space-frequency transform on said updated replay field to determine an updated phase pattern for said kinoform; and repeating said calculating and updating of said replay field and said performing of said space-frequency transform until said kinoform for display is determined; and outputting said kinoform data for display on said LCOS SLM.