A detection module of an autonomous detection system for in situ monitoring floating polymer particles and phytoplankton in sea water. The detection module is combined with a floating body, and a communication module with an antenna, and is configured for detecting polymer particles and phytoplankton such as algae. The detection module comprises: a detection area for a water sample, notably a salty water flow with polymer particles and/or phytoplankton; ultraviolet light emitting means configured for emitting ultraviolet light in the detection area, light sensing means configured for sensing light from the detection area in order to detect polymer particles and/or phytoplankton such as cyanobacteria; an energy generating module configured for powering said detection module. The UV emitting means comprise a low power consumption UV LED. A detection process, and a use of an UV light source for removing a biolayer in the detection area.

A portable device operable to identify photosynthetic activity and contents of compounds in a plant part. The portable device includes a light source including light-emitting diodes operable to irradiate the plant part with light. The portable device further includes a control module operable to have the light-emitting diodes emit the light as pulse signals. Additionally, the portable device includes a focus-adjustable lens and a filter optically coupled to the light source, where the adjustable lens and the filter are co-operable to consolidate light reflected from the plant part which may be irradiated by light from the light-emitting diodes. Furthermore, the portable device includes a detector optically positioned to receive from the focus-adjustable lens and the filter the light reflected from the plant part, where the light reflected from the plant part corresponds to the photosynthetic activity and contents of compounds in the plant part.

The present invention discloses a method for evaluating vitality of a plant including (a) a step of measuring a delayed luminescence of a leaf of each plant of a group of plants subject to evaluation to obtain data of delayed luminescence amount, and (b) a step of processing data of a plurality of delayed luminescence amounts thus obtained to evaluate a plant exhibiting a delayed luminescence amount not less than a preset upper limit threshold as an individual of poor growth or evaluate a plant exhibiting a delayed luminescence amount not more than a preset lower limit threshold as an individual of good growth, and a measurement system and an evaluation system used for the method.

A Tilted Filter Imaging Spectrometer (TFIS) is designed to be a very small optical spectrometer having very high sensitivity and spectral resolution. These properties suggest the use of the device as a Fraunhofer Line discriminator (FLD) to detect objects that fluoresce in sunlight. According to at least one embodiment of the present invention, the tilted filter imaging spectrometer incorporates at least one dielectric filter, at least one imaging lens structure; and an imaging detector operatively positioned at a focal length of the imaging lens structure, wherein the dielectric filter is operatively positioned at an angle relative to an optical axis of the imaging lens structure. In at least a second embodiment, the tilted filter imaging spectrometer further incorporates at least one Fabry-Perot Etalon, wherein the Fabry Perot Etalon and the dielectric filter are operatively positioned at angles relative to an optical axis of the imaging lens structure.

There is provided a system for measuring chlorophyll fluorescence. The system comprises at least one light source configured to emit substantially collimated or convergently focused light so as to irradiate an area with light; an actuator configured to controllably direct the light from the light source so as to enable the light source to irradiate a plurality of different areas with light; and an optical sensor configured to detect chlorophyll fluorescence from each area irradiated with light.

A system and method for the detection of bacteria on a sample, utilizes spectroscopic analysis of the sample and the fluorescent properties of bacteria or other substance(s) or matter associated with the bacteria to identify the presence of bacteria on the sample. A detector analyses light emitted from the sample in response to illumination. The detector 5 is arranged to analyze the emission spectra across two wavebands, a first waveband containing the wavelengths associated with the fluorescent properties of the bacterial species or other substance or matter to be detected, and a second waveband excluding these wavelengths but also having an overlapping region with the first waveband.

A phase synchronizing pulse amplitude modulation fluorometer having an excitation light source capable of emitting a pulse of light that will induce fluorescence in an external object. A photo detector for detecting the pulse and a circuit to synchronize a pulse of light from the excitation light source with a pulse of light from an external light source.

The present invention relates to a method for determining a fungal infection of a plantThe method comprises: emitting excitation radiation by one or more radiation sources to the plant, said radiation comprising first excitation wavelengths being within the absorption band of a compound whose content in the plant is affected by a fungal infection, in particular a phenolic compound, and second excitation wavelengths being outside the absorption band of said compound, thereby inducing chlorophyll fluorescence; detecting chlorophyll fluorescence radiation from the plant; and obtaining a value being indicative for the fungal infection of the plant, said value is dependent from the detected chlorophyll fluorescence radiation induced by excitation radiation of the first excitation wavelengths and the detected chlorophyll fluorescence radiation induced by excitation radiation of the second excitation wavelengths. Moreover, the present invention relates to a detection device, in particular a mobile detection device, for carrying out this method.

An intelligent light adjusting system and method thereof in a crop growth process are provided. The intelligent light adjusting system includes a parameter measurement device, a parameter processing device, a light source control device and a light source assembly. The parameter measurement device is for measuring a specified parameter in the crop growth process. The parameter processing device is for acquiring a light source parameter of the light source control device, based on the specified parameter. The light source control device is for controlling lighting of the light source assembly, based on the light source parameter.

A phase synchronizing pulse amplitude modulation fluorometer having an excitation light source capable of emitting a pulse of light that will induce fluorescence in an external object. A photo detector for detecting the pulse and a circuit to synchronize a pulse of light from the excitation light source with a pulse of light from an external light source.