The present invention is directed to an assembly for use in detecting an analyte in a sample based on thin-film spectral interference. The assembly includes a light source to emit light signals; a light detector to detect light signals; a coupler to optically couple the light source and the light detector to a waveguide tip; a monolithic substrate having a coupling side and a sensing side; and a lens between the waveguide tip and the monolithic substrate. The lens relays optical signals between the waveguide tip and the monolithic substrate.

One or more embodiments relates to a system for simultaneously detecting vibration and the presence of a target gas having a tunable fiber ring laser in electronic and optical communication with a vibration sensor and a gas detection sensor. One or more embodiments relate to a method for simultaneously measuring vibration and detecting the presence of a target gas in an environment having the steps of providing a system for simultaneously measuring vibration and detecting a target gas into an environment; sending an optical signal to a vibration sensor and gas detection sensor; and collecting and analyzing modified signals from the vibration sensor and gas detection sensor.

An integrated device, comprising a substrate having a first surface; and at least one pixel formed on or in the substrate. The at least one pixel comprising a reaction chamber configured to receive a sample, and a sensor configured to detect emission light emitted from the reaction chamber and at least one nanostructure disposed in a plane between a waveguide and the sensor, wherein the optical nanostructure is configured to converge at least a portion of the emission light in a direction substantially perpendicular to the plane. The waveguide is configured to couple excitation light to each pixel.

A sensor device and a method of analyzing a component in a fluid are described. The sensor device comprises a planar substrate defining a substrate plane, an electromagnetic waveguide forming a waveguide resonator and extending in a length direction in a waveguide resonator plane parallel to the substrate plane, wherein the electromagnetic waveguide is supported on the substrate by a support structure, wherein the electromagnetic waveguide has a width in the waveguide resonator plane in a direction perpendicular to the length direction, and a height out of the waveguide plane in a direction perpendicular to the length direction.

A sensing system for monitoring a composition of a downhole fluid in a well, where the sensing system includes: a light source, an optical waveguide, an evanescent field sensing element that is indirect contact with a downhole fluid, and a detector. The light source is operable for emitting a beam and includes a frequency comb generator configured to modify at least a portion of the beam into a sensing comb beam. The evanescent field sensing element provides attenuated internal reflection of the sensing comb beam at the interface between the evanescent field sensing element and the downhole fluid, and the portion of the sensing comb beam interacts with the fluid to form at least a portion of an interacted beam. The detector obtains a spectral distribution of the interacted beam.

A diffractometric sensing device for analyzing molecular interactions is described, the diffractometric sensing device comprising a transparent carrier medium, the carrier medium comprising a grating structure (42.1-42.5) with a plurality of consecutive surfaces or lines and a plurality of binding sites arranged thereon, the binding sites being configured to interact with one or more target molecules, wherein the grating structure is configured to diffract a portion of coherent light propagating in the carrier medium so as to produce a constructive interference signal at a light detector (4.1-4.4), the signal being dependent on molecular interactions at or in the vicinity of the binding sites. The invention offers more sensitivity, faster response, miniaturization, easy manufacturing and more applications compared to current diffractometric sensing devices.

Methods, apparatuses, and systems associated with a sample testing device are provided.

An optical sensing apparatus is provided comprising: an input interface for receiving input light into the optical sensing apparatus; an input waveguide and a reference waveguide, both arranged to receive input light from the input interface; a closed loop resonator, wherein the input waveguide is optically coupled to the closed loop resonator at an input point for introducing input light to the closed loop resonator; a sample region, adjacent the closed loop resonator, for receiving a sample such that evanescent coupling can occur between light in the closed loop resonator and the sample; a drop-port waveguide, optically coupled to the closed loop resonator at a drop point for receiving dropped light from the closed loop resonator; an output waveguide; and an output interface. The reference waveguide and the drop-port waveguide are arranged to direct interfering light through the output waveguide to produce an output signal at the output interface.

The present invention is directed to an assembly for use in detecting an analyte in a sample based on thin-film spectral interference. The assembly includes a light source to emit light signals; a light detector to detect light signals; a coupler to optically couple the light source and the light detector to a waveguide tip; a monolithic substrate having a coupling side and a sensing side; and a lens between the waveguide tip and the monolithic substrate. The lens relays optical signals between the waveguide tip and the monolithic substrate.

A method of analyzing a material (12) comprising at least one analyte, said method comprising a material status analyzing procedure (76), in which a present status of the material is analyzed, wherein based on a result of said material status analyzing procedure (76), at least one of a selection of analyte-characteristic-wavelengths used during an analyte measurement procedure (78), an absolute time or a relative time proportion of use of analyte-characteristic-wavelengths during said analyte measurement procedure (78), an individual excitation radiation intensity, or a relative weight given to the wavelengths in the analysis, a selection of analyte-characteristic-wavelengths to be used simultaneously during said analyte measurement procedure (78), and a selection of one or more main frequencies of the modulation of said excitation radiation (18) intensity to be used during said analyte measurement procedure (78) is determined.