A phase controller for controlling the phase of a light signal in a surface waveguide and a method for its fabrication are disclosed. The phase controller controls the phase of the light signal by inducing stress in the waveguide structure, thereby controlling the refractive indices of at least some of its constituent layers. The phase controller includes a phase-control element formed on topographic features of the top cladding of the waveguide, where these features (1) provide a shape to the phase-control element that matches the shape of the mode field of the light signal and (2) give rise to stress-concentration points that focus and direct induced stress into specific regions of the waveguide structure, thereby providing highly efficient phase control. As a result, the phase controller can operate at a lower voltage, lower power, and/or over a shorter interaction length than integrated-optic phase controllers of the prior art.

Optical-fiber connector modules are disclosed. In one example, an optical-fiber connector module can include a receptacle disposed in a housing, a cable extending from the housing, and an optical fiber within at least the cable. The receptacle can be configured to accept insertion of a first plug for establishing a first optical connection between the optical-fiber connector module and an optical-fiber stylet of a medical device. The cable can include a second plug for establishing a second optical connection between the optical-fiber connector module and an optical interrogator. The optical fiber extends from the receptacle through the cable to the second plug. The optical fiber can be configured to convey input optical signals from the optical interrogator to the optical-fiber stylet and reflected optical signals from the optical-fiber stylet to the optical interrogator. Shape-sensing systems including the optical-fiber connector modules and methods of the foregoing are also disclosed.

The optical fiber sensing method of the present invention includes steps of: joining heat shrinkable tubes to two ends of a sensing segment of an optical fiber; coupling a fixing element on the heat shrinkable tube below the sensing segment; detachably connecting at least one floating element to the fixing element; placing the floating element into a fluid; and providing an input signal to the sensing segment and generating an output signal after the input signal is processed by the sensing segment, wherein the tensile force applied to the sensing segment would change with variation of the buoyant force upon the floating element, resulting in change of the output signal. Accordingly, the optical fiber sensing method has numerous advantages, including rapid on-site construction, recyclability of components and changeability of design parameters.

According to an exemplary embodiment of the present disclosure, apparatus and process for providing at least one radiation can be provided. For example, with at least one multi-mode waveguide, it is possible to transmit the radiation(s). In addition, with a shape sensing arrangement, it is possible To dynamically measure a shape of the multi-mode waveguide(s). Further, with a specifically programmed computer arrangement, it is possible to control a light modulator arrangement based on the dynamically-measured shape to cause the radiation(s) transmitted through the multi-mode waveguide(s) to have at least one pattern.

In this light source device, in order to reduce the size thereof and reduce the line width, a first optical fiber 12 is optically coupled to a light source 11. Through the first optical fiber 12, light that has exited from the light source 11 is let into a second optical fiber 14 to be guided thereby. An optical isolator 13 is inserted between the first optical fiber 12 and the second optical fiber 14. An optical fiber that readily generates back-scattering is used for the first optical fiber 12. As light that has back-scattered in the first optical fiber 12 returns to the light source 11, and by constituting a long resonator, the line width of the output light can be reduced.

A measurement system may be enabled to detect properties within an enclosure based on information detected using optical fiber sensors. The measurement system may include an enclosure having at least one wall with an inside surface and an outside surface; at least one silica-based optical fiber comprising at least one functional optical fiber core and at least one cladding layer; at least one optical fiber interrogation member; at least one transducer arranged to output energy; a controller; and a processing element configured to communicate with the optical fiber interrogator and the controller. The silica-based optical fiber is associated with a wall of the enclosure. The controller is configured to control the optical fiber interrogator and the transducer. The processing element is configured to process information from the optical fiber interrogation member.

The invention relates to a seal containing a substrate which can be applied to an object to be sealed, so that said seal is changed when it is removed without authorization, wherein the substrate contains or comprises a polymer and/or a glass and at least one optical waveguide is arranged in the substrate, at least one first Bragg grating being arranged in said optical waveguide, wherein the substrate has a thickness of less than 200 m. The invention further relates to a system having a seal of this kind and having an evaluation device, and also to a sealing method.

A multichannel optical coupler can include an output optical coupler array and a plurality of optical fibers. At least two of the plurality of optical fibers can be connected together at an end opposite the output optical coupler array.

A photonic displacement sensor comprises a photonic fiber including a) a core section having a first band gap aligned along an extended longitudinal axis, and b) a cladding section surrounding the core section having a second band gap. The first band gap is adapted to block a spectral band of radiation centered on a first wavelength that is directed along the longitudinal axis, and the second band gap is adapted to block a spectral band of radiation centered on a second wavelength that is directed transversely to the longitudinal axis, and wherein displacement is detected based on a shift in at least one of the first and second band gap of the photonic fiber, enabling an intensity of radiation to be detected that is in proportion to the displacement in the photonic fiber.

A system includes at least one optical fiber having at least one FBG and a detection system. The optical fiber is configured to be coupled to a structure in at least one location. The location at which the optical fiber is to be coupled to the structure is different from a location at which the FBG is disposed. The detection system includes a light source configured to inject light into the optical fiber, a photodetector configured to detect a shift in a wavelength spectrum of light reflected by the FBG as a result of a time-varying strain induced at the at least one FBG, and a processor configured to detect a shear-horizontal guided stress wave propagating in said structure based on the shift in the wavelength spectrum detected by the photodetector induced by a longitudinal-type guided stress wave that is propagated along the optical fiber.