Abstract: The present invention relates to the design and manufacture of microstructured optical fibres. The invention has particular application in the manufacture of microstructured optical fibres for imaging purposes such as, for example, endoscopy, ear-implants, and chip-to-chip interconnects. A first aspect of the invention provides a method of producing a microstructured optical fibre from a preform, said method including the steps of: creating zones of relatively high refractive index at predetermined locations in said preform, said zones substantially surrounded by material of relatively low refractive index to create an array of light guiding cores, and subsequently drawing said preform to create a length of said microstructured optical fibre.

Abstract: An optical waveguide in the form of an optical fibre (10) having at least one longitudinally extending light guiding core region (11) composed at least in part of a polymeric material, a longitudinally extending core-surrounding region (12) composed of a polymeric material, and a plurality of light confining elements (15), such as, for example, channel-like holes, located within the core surrounding region. The light confining elements extend in the longitudinal direction of the core region and are distributed about the core region, and at least a majority of the light confining elements having a refractive index less than that of the polymeric material from which the core-surrounding region is composed. A preform for use in manufacture of the optical waveguide is also disclosed.

Abstract: This invention provides an optical fibre (1) incorporating a body (2), and an array of longitudinally extending holes or inclusions (3) formed in the body (2), the holes or inclusions (3) having a different refractive index from the surrounding body (2) and being arranged to form a full or partial ring structure (5) extending generally around a longitudinal axis of the fibre, the ring structure (5) being disposed so as to approximate the refractive or reflective transmission characteristics of a multi-layer optical fibre. The fibre (1) may have a solid core or a hollow air core. The invention also provides a method of forming the microstructured optical fibre (1).

Abstract: An optical waveguide in the form of an optical fibre (10) having at least one longitudinally extending light guiding core region (11) composed at least in part of a polymeric material, a longitudinally extending core-surrounding region (12) composed of a polymeric material, and a plurality of light confining elements (15), such as, for example, channel-like holes, located within the core surrounding region. The light confining elements extend in the longitudinal direction of the core region and are distributed about the core region, and at least a majority of the light confining elements having a refractive index less than that of the polymeric material from which the core-surrounding region is composed. A preform for use in manufacture of the optical waveguide is also disclosed.

Abstract: A method of terminating a polymer optical fibre (10) having a longitudinally extending light guiding cor region (11) and longitudinally extending channel-like light confining holes (13). The method comprises restricting a cross-sectional area of the some or all of the holes over a portion of their length adjacent and extending to a terminal end (14) of the optical fibre (10). The cross-sectional area of the holes is restricted, using the inherent properties of the polymeric material, in a manner effectively to increase the cross-sectional area of the light guiding region (11) of the optical fibre (10) adjacent its terminal end (14). Further, a method of splicing two of such polymer optical fibres (10) comprising terminating each of the optical fibres by the above-defined method, aligning them and conjoining their terminal ends (14).

Abstract: An optical fibre (1) having at least one longitudinally extending light guiding core region (11), a longitudinally extending core-surrounding region (12), and a plurality of light confining elements (15, 16, 17, 18), such as, for example, channel-like holes, located within the core-surrounding region (12). The light confining elements (15, 16, 17, 18) extend in the longitudinal direction of the core region and are located geometrically in zones that surround the core region. The aggregate cross-sectional area defined by the light confining elements within the respective zones increases with increasing radial distance of the zones from the core region. A preform for use in manufacture of the optical fibre is also defined.