An apparatus for detecting a plant health status is described. The apparatus includes a light source positioned relative to the plant and a detector positioned relative to the plant. The light source is configured to emit a white light or an ultraviolet light. The ultraviolet (UV) light corresponds to UV-A and has a wavelength in the range of 340 nanometers (run) to 400 nm. The detector is configured to receive evaluation light. The evaluation light is related to the emitted light and corresponds to a health status of the plant.

An information processing apparatus, an information processing method, a non-transitory computer-readable medium, an a storage device for quantitatively analyzing and storing a relationship between an environment of a measurement target and a response of the measurement target with respect to the environment. The information processing apparatus includes a storage circuitry and an operation circuitry configured to acquire a first physical value by analyzing captured image information, the first physical value being indicative of an environment of a measurement target associated with a first pixel of the plurality of pixels, acquire a second physical value by analyzing the captured image information, the second physical value being indicative of a response of the measurement target with respect to the environment, and control the storage circuitry to store the first physical value and the second physical value in correlation with each other.

The present technology relates to an imaging apparatus, an imaging method, and a program that perform appropriate exposure control, to thereby enable a desired object to be appropriately imaged.

The present technology includes: an imaging unit including a plurality of pixels having different spectral characteristics; and an exposure control unit setting information associated with exposure control on the plurality of pixels depending on specification information for specifying a kind of a measurement target. Alternatively, the present technology includes: an imaging unit including a plurality of pixels having different spectral characteristics; and an exposure control unit setting information associated with exposure control on the plurality of pixels on the basis of a predicted output value of each of the plurality of pixels based on a spectral characteristic related to a measurement target. The present technology is applicable to an imaging apparatus which senses vegetation, for example.

The present invention relates to an improved technology for a device that identifies and diagnoses an environmental stress state of plants. A control circuit 20b controls a measurement light source 12 such that a second measurement light ML2 has higher power than a first measurement light ML1 and the first measurement light ML1 and the second measurement light ML2 become opposite-phase rectangular waves, and further controls the measurement light source 12 such that the first measurement light ML1 and the second measurement light ML2 are output in synchronization to form the first measurement light ML1 and the second measurement light ML2 into a quasi-single composite rectangular wave measurement light ML3 of 5 kHz to 30 kHz. A transmitted light detector 18 detects the composite rectangular wave measurement light ML3 transmitted through a plant sample S as a composite rectangular wave transmitted light TL. An analysis circuit 20a calculates a light absorption difference by utilizing the composite rectangular wave transmitted light TL, and calculates Y(ND) which is an oxidized state of P700 as a ROS marker utilizing the light absorption difference, and diagnoses an environmental stress state of plants by utilizing the ROS marker.

A solution for illuminating plants is provided. An illustrative system can include: a set of visible light sources configured to emit visible radiation directed at the plant; a set of ultraviolet radiation sources configured to emit ultraviolet radiation directed at the plant; and a set of sensors, wherein at least one sensor is configured to detect a fluorescence emitted from the plant due to the ultraviolet radiation and a fluorescence emitted from the plant due to the visible radiation.

The present inventors have recognized that various diseases in plants, such as Phytophthora infestans (late blight) and Alternaria solani (early blight), and/or various stages of such diseases in plants, can be reliably detected by applying measurements from electromagnetic reflections detected from a plant in a model to produce an output indicating a probability of the disease and/or stage. In one aspect, coefficients can be applied to each measurement at each wavelength to emphasize identification of a given disease or stage. In another aspect, an imager can capture images comprising spectral pixels in which each pixel comprises measurements from the electromagnetic reflections for application in a model to identify a given disease or stage.

A side illuminated multi point multi parameter optical fiber sensor that requires no sensitive coating is provided. This sensor comprises an optical fiber having at least one removed cladding section as the sensitive region, at least one probing light source that side illuminates the fiber, a power supply, a detector, a signal processor and a display. The sensitive optical fiber is optically affected by the presence of a measurand medium that can fluoresce, phosphoresce, absorb and/or scatter the probing light. This probing light is guided by the fiber core towards a detector which measures the light intensity and this light intensity is correlated with a measurand.

A side illuminated multi point multi parameter optical fiber sensor that requires no sensitive coating is provided. This sensor comprises an optical fiber having at least one removed cladding section as the sensitive region, at least one probing light source that side illuminates the fiber, a power supply, a detector, a signal processor and a display. The sensitive optical fiber is optically affected by the presence of a measurand medium that can fluoresce, phosphoresce, absorb and/or scatter the probing light. This probing light is guided by the fiber core towards a detector which measures the light intensity and this light intensity is correlated with a measurand.

The invention relates to a device for automatic species analysis and to a method for carrying out the same. In particular, the invention relates to a device for automatic species analysis within a large biological group and to a method for automatically carrying out such analyses. A device according to the invention for automatic species analysis within a large biological group comprises a first beam path (10), directed from a first laser radiation source (12) to a sample region (40), the fluorescence radiation emitted by a sample (42) within the sample region (40) as a result of excitation by the first laser radiation source (12) being collected and fed to a first spectrometer (14) for spectral evaluation; a second beam path (20), directed from a second laser radiation source (22) to the sample region (40), the fluorescence radiation emitted by the sample (42) within the sample region (40) as a result of excitation by the second laser radiation source (22) being collected and fed to a second spectrometer (24) for spectral evaluation; and a camera (30), which is designed to capture a photograph of the sample (42) within the sample region (40); the device also comprising a means for automatic species analysis (50), which is designed to carry out an automatic species analysis from the sample-related results of the spectroscopic evaluation of the first spectrometer (14) and of the second spectrometer (24) and the photograph of the camera (30) by means of a multi-step threshold value comparison for certain determination parameters stored in an associated database. A method according to the invention serves to carry out an automatic species analysis by means of a device according to the invention.

An apparatus for remote detection of plant growth dynamics is described. The apparatus includes an excitation LED (light emitting diode) module, a detection module and a controller module coupled to the excitation LED module and the detection module. The excitation LED module includes at least one LED. Each LED is configured to emit an excitation light in response to an excitation control signal. The excitation light has an emitted light spectrum.

The detection module includes a photodetector configured to detect an initial chlorophyll a fluorescence (ChlF) light and an excited ChlF light from a plant species. The photodetector is further configured to convert the detected initial ChlF light into an initial detection electrical signal and the detected excited ChlF light into an excited detection electrical signal, The excited ChlF light is emitted from the plant species in response to receiving the excitation light.

The controller module is configured to provide the excitation control signal to the excitation module, to capture the initial and excited detection electrical signals from the detection module and to determine chlorophyll fluorescence data based, at least in part, on the initial and excited detection electrical signals. The excitation LED module and the detection module are configured to be positioned remotely from the plant species. The chlorophyll fluorescence data represents a growth characteristic of the plant species.