The disclosure describes systems, methods, and apparatuses for monitoring fluorescent peaks using a fluorometer, where the fluorometer comprises an instrument assembly, a circuit assembly, a casing, and a window set into the casing, wherein at least a portion of the instrument assembly is submerged within a liquid and above an analyte workspace; a buoy assembly; one or more emission sources electrically coupled to the circuit assembly, the emission sources configured to emit light in one or more frequencies or wavelength bands; a prism arranged in contact with the window, the prism configured to direct emissions from the emission sources towards the analyte workspace, the prism including at least one angled surface; at least one photosensor positioned above the window and configured to detect fluorescence emissions of analytes in the analyte workspace; and a filter array positioned between the window and the photosensor.

The invention concerns a method for measuring the concentration of a substance or mixture of substances and/or determining the level in a fluid with intrinsic fluorescence, preferably fuel systems. The invention also refers to the optical device suitable for implementing the method, which comprises a unit which generates light for excitation of the sample; a unit of detection of the signal emitted by the sample and a unit of signal processing. The device and method by which it is implemented also allow the determination of the spatial distribution of the substance or mixture of liquid substances and/or the fluid level in a container. One of the main applications is the measurement of the concentration of oxygen in the fuel tank of aircrafts, based on the measurement of the intrinsic fluorescence of the fuel.

An autonomous biobuoy system and methods for detecting characteristics of a marine environment, the system involving: a light source comprising a blue light emitting diode; a detector assembly for detecting the at least one characteristic of the marine environment, the detector assembly having a single photodiode configured to detect stimulated bioluminescence and transmissivity in response to the light source, the detector assembly configured to generate at least one detector assembly output signal responsive to at least one detected characteristic; and a transmitter coupled with the detector assembly for transmitting the at least one detector assembly output signal.

An electronic device is for monitoring the visible spectrum of a specified sample with agile monitoring techniques. The device may seek to decouple the sensor from static measurements and allow for dynamic measurements in systems where the response is not wide sense stationary, allowing the end user to aggregate multiple data points or moments in summarizing the health of a larger system. In aquacultures, the device may be capable of functioning as a floating buoy where a chemical sensor with a color response can note readings at multiple points within a stream or water body.

A system for in-situ measurement of an apparent spectrum of a water body includes a floating device, and an optical sensing and conduction device, an electronic measurement device, a control circuit, and a power supply device which are loaded on the floating device. The floating device includes a floating body ring and an optical probe mounting frame on the floating body ring in a direction perpendicular to a ring surface. The optical probe mounting frame includes a vertical mounting assembly and a horizontal connecting assembly. The horizontal connecting assembly is provided radially along the ring shape of the floating body ring. One end of the horizontal connecting assembly is connected to the vertical mounting assembly and the other end thereof is connected to the floating body ring.

The invention concerns a method for measuring the concentration of a substance or mixture of substances and/or determining the level in a fluid with intrinsic fluorescence, preferably fuel systems. The invention also refers to the optical device suitable for implementing the method, which comprises a unit which generates light for excitation of the sample; a unit of detection of the signal emitted by the sample and a unit of signal processing.

The device and method by which it is implemented also allow the determination of the spatial distribution of the substance or mixture of liquid substances and/or the fluid level in a container. One of the main applications is the measurement of the concentration of oxygen in the fuel tank of aircrafts, based on the measurement of the intrinsic fluorescence of the fuel.

The system enables remote inspection of an object, such as an underwater steel pile, using a plurality of video cameras. The cameras are positioned on a frame along a plane substantially perpendicular to the axis of the object and spaced apart so as to enable inspection of the circumference of the object. Moving the frame along the surface of the object enables a video of the entire surface area of the object to be made. A plurality of wheels are mounted to the frame to provide rolling contact with the surface of the object and to cause the cameras to remain a fixed distance from the surface of the object. A plurality of springs are mounted between the frame and the wheels to further ensure smooth movement of the frame. A plurality of lights mounted to the frame illuminate the surface of the object during the inspection process.

The present invention relates to a system for in-situ measurement of an apparent spectrum of a water body. The system comprises a floating device, and an optical sensing and conduction device, an electronic measurement device, a control circuit and a power supply device which are loaded on the floating device. The floating device comprises a floating body ring and an optical probe mounting frame which is provided on the floating body ring in a direction perpendicular to a ring surface. The optical probe mounting frame comprises a vertical mounting assembly and a horizontal connecting assembly. The horizontal connecting assembly is provided radially along the ring shape of the floating body ring, one end of the horizontal connecting assembly being connected to the vertical mounting assembly, and the other end thereof being connected to the floating body ring, such that the vertical mounting assembly is overhung outside the ring surface of the floating body ring, and meanwhile a vertical projection of the vertical mounting assembly is located in the center of the ring surface. A ratio of an inner diameter to an outer diameter of the floating body ring is 0.80 to 0.85. The floating body ring is provided with a water-tight cavity which provides flotage for the whole floating device and used for loading a necessary electronic device and a necessary power supply assembly. An optical probe is vertically mounted on the optical probe mounting frame. The device for in-situ observation of the apparent spectrum of the water body disclosed by the present invention may be used for directly measuring a water-leaving radiance L.sub.w of the water body, and can furthest reduce the method defects, personal errors and device errors. The precision of a remote sensing reflectivity R.sub.rs finally observed of the water body is improved remarkably, and the operations are simple.

A high-resolution in situ sensing system and method for providing continuous measurements of at least one dissolved analyte including a sample processing cell having at least a first conduit defining a first passage with at least one selectively-permeable wall capable of passing a portion of the sample liquid into a processing, fluid. The at least one selectively-permeable wall substantially resists flow of another portion of the sample liquid therethrough. Processing fluid is directed through the first conduit while moving the sample liquid and the reagent fluid relative to each other in one of a stationary, concurrent or a countercurrent flow relationship to achieve either partial or full equilibration between the sample liquid and processing fluid to generate at least partially equilibrated reagent fluid and a processed sample in a substantially continuous manner.

A system for monitoring at least one parameter of a fluid contained in a container includes a measuring device based on near-infrared spectroscopy designed to be submerged in the cited fluid to be monitored and to take measurements of the fluid. The measuring device includes a measuring area. The monitoring system includes a flotation system joined to the measuring device. The flotation system is arranged, during the use of the monitoring system, floating on the fluid to be monitored such that the measuring area of the measuring device is submerged in the fluid at a constant depth with respect to the level of fluid in the container, such that all the measurements taken by the measuring device are taken at the same depth with respect to the level of the fluid.