An electro-optical device includes a mirror being positioned above a surface of a substrate and modulating light, a torsion hinge being positioned between the mirror and the substrate, and supporting the mirror via a mirror support post such that the mirror is pivotable about an axis, and address electrodes being positioned between the mirror and the substrate, and supplying electrostatic forces between the address electrodes and the mirror. Each of the address electrodes includes a first address electrode that is positioned on a side of the axis in plan view, and a second address electrode that is positioned on the opposite side of the axis with respect to the first address electrode in plan view. The first address electrode and the second address electrode are driven independently of each other.

Systems and methods are provided for selectively incoupling light having different wavelengths into one of a plurality of waveguides. The systems and methods provided for selectively incoupling light having different wavelengths into one of a plurality of waveguides comprise a switching device comprising switchable reflective elements that can be configured to redirect incoming light towards an incoupling element associated with one of a plurality of waveguides.

A method in an optical Wavelength Selective Switch, WSS, for multidirectional switching of optical signals. The optical WSS comprises a reflective element, a first tributary port and a second tributary port. The optical WSS switches (304) an optical signal between the first tributary port and the second tributary port with the reflective element.

The present invention makes it possible to inhibit decrease in optical performance due to a foreign object, while securing a space necessary for wire bonding. A cover (3) is configured such that a distance (z2) between an optical device (1) and a sub-cover member (32) becomes greater than a distance (z1) between the optical device (1) and a cover glass (31).

A MEMS optical switch and a switching node are disclosed. The MEMS optical switch includes N.sub.1 input ports, N.sub.1 input MEMS mirrors, M.sub.1 output ports, and M.sub.1 output MEMS mirrors, where a first input port is configured to transmit a first optical signal to a first input MEMS mirror. The first input MEMS mirror is configured to reflect the first optical signal to a first destination output MEMS mirror, where along a straight line in which a first deflection axis is located, the first input MEMS mirror is located on an edge of the N.sub.1 input MEMS mirrors, and when reflecting the received first optical signal to a first output MEMS mirror and a second output MEMS mirror, the first input MEMS mirror deflects towards an opposite direction relative to a second deflection axis.

A 3D-MEMS optical switch is disclosed. In an embodiment, the 3D-MEMS optical switch includes a collimator array, a PD array, a wedge prism, a light-splitting triangular prism, a micro-electro-mechanical system MEMS micro-mirror, and a core optical switch controller that is connected to the PD array and the MEMS micro-mirror. In the present invention, the PD array is integrated into a core optical switch, which simplifies an architecture of the optical switch and reduces a volume of the optical switch; the wedge prism and the light-splitting triangular prism are used to perform light splitting, and some optical signals are transmitted to the PD array to detect optical power, so that the core optical switch controller adjusts the MEMS micro-mirror according to the optical power, which is detected by the PD array, of the optical signal, making an insertion loss of the 3D-MEMS optical switch meet a preset attenuation range.

A two-dimensional (2D) optical fiber array component takes the form of a (relatively inexpensive) fiber guide block that is mated with a precision output element. The guide block and output element are both formed to include a 2D array of through-holes that exhibit a predetermined pitch. The holes formed in the guide block are relatively larger than those in precision output element. A loading tool is used to hold a 1×N array of fibers in a fixed position that exhibits the desired pitch. The loaded tool (holding the pre-aligned 1×N array of fibers) is then inserted through the aligned combination of the guide block and output element, and the fiber array is bonded to the guide block. The tool is then removed, re-loaded, and the process continued until all of the 1×N fiber arrays are in place. By virtue of using a precision tool to load the fibers, the guide block does not have to be formed to exhibit precise through-hole dimensions, allowing for a relatively inexpensive guide block to be used.

A multicast optical switch based on free-space transmission comprises a 1×M input collimator array, a light splitting device, an optical distance compensation device, a spot transformation device, a 1×N output collimator array and a reflector array which are arranged in sequence. The 1×N output collimator array corresponds to reflector array. The light splitting device is provided with a light splitting surface and a reflection surface, and by means of light splitting surface and reflection surface, light splitting and beam splitting of n times are carried out on input signals of 1×M input collimator array, and then N beams of sub-signal light are generated. The optical distance compensation device compensates optical distance differences among M×N sub-signal light beams produced by light splitting device. The M×N sub-signal light beams are focused to be 1×N light spots through light spot conversion device, and then 1×N light spots are reflected to reflector array.

An optical device includes: wavelength selection elements; an optical switch that switches a propagation path of input light that is from an input port such that the input light propagates to one designated wavelength selection element among the wavelength selection elements; and a separation element disposed in the propagation path of the input light between the input port and the wavelength selection elements and that separates the input light into wavelength components.

Data center interconnections, which encompass WSCs as well as traditional data centers, have become both a bottleneck and a cost/power issue for cloud computing providers, cloud service providers and the users of the cloud generally. Fiber optic technologies already play critical roles in data center operations and will increasingly in the future. The goal is to move data as fast as possible with the lowest latency with the lowest cost and the smallest space consumption on the server blade and throughout the network. Accordingly, it would be beneficial for new fiber optic interconnection architectures to address the traditional hierarchal time-division multiplexed (TDM) routing and interconnection and provide reduced latency, increased flexibility, lower cost, lower power consumption, and provide interconnections exploiting scalable optical modular optically switched interconnection network as well as temporospatial switching fabrics allowing switching speeds below the slowest switching element within the switching fabric.