Abstract: An optical switch network, for connecting P switch input waveguides to Q switch output waveguides. The switch input waveguides enter a branching subnetwork consisting of a plurality of branching cascades. In each branching cascade, an array of 1×2 splitters connects the input waveguides of the cascade to the output waveguides of the cascade, and the output waveguides of the cascade cross within the cascade so that output waveguides that connect to the same switch input waveguide emerge from the cascade P output waveguides apart. The output waveguides of the branching subnetwork connect directly to 2×1 combiners of a combining subnetwork that connects the output waveguides of the branching subnetwork to the Q switch output waveguides. The network architecture is reversible, by exchanging the roles of the input and output waveguides and the roles of the splitters and the combiners.

Abstract: An optical switch array in which a plurality of input waveguides is coupled to a plurality of output waveguides. All but one of the output waveguides is coupled to each of the input waveguides by a switching element such as a 1×2 switch. A combining mechanism couples all the input waveguides to each of the output waveguides. In one preferred embodiment, one of the input waveguides continues directly into the output waveguide that is not coupled to input waveguides by switching elements, and each combining mechanism includes, for each of the other input waveguides, a coupling element such as a y-junction combiner. The switching elements are connected to the corresponding combining mechanisms by intermediate waveguides. Intermediate waveguides intersect input waveguides as required to allow the array to be fabricated as a planar integrated device.