A system for identifying ponding water located on a field from image data is described. In an approach, an image of an agricultural field is analyzed using a classifier that has been trained based on the spectral bands of labeled image pixels to identify a probability for each pixel within the image that the pixel corresponds to water. A flow simulation is performed to determine regions of the field that are likely to pool water after rainfall based on precipitation data, elevation data, and soil property data of the field. A graph of vertices representing the pixels and edges representing connections between neighboring pixels is generated. The probability of each pixel within the graph being ponding water is set based on the probability pixel being water, the likelihood that water will pool in the area represented by the pixel, the probability of neighboring pixels being ponding water, and a cropland mask that identifies which pixels correspond to cropland. A class for each pixel is then determined that maximizes the joint probability over the graph.

This invention relates to a system for releasing beneficial mites and the use of such a system. Mite species that can be used beneficially for human purposes may for example be employed in the control of pests, such as in the field of agriculture, including agricultural production systems for plant products, agricultural production systems for animal products, and animal husbandry, or in the field of storage of food products. The system of the invention may fmd use in any of these fields.

This invention relates to a system for releasing beneficial mites and the use of such a system. Mite species that can be used beneficially for human purposes may for example be employed in the control of pests, such as in the field of agriculture, including agricultural production systems for plant products, agricultural production systems for animal products, and animal husbandry, or in the field of storage of food products. The system of the invention may fmd use in any of these fields.

Disclosed are methods of preserving pollen such that the pollen has improved viability as compared to pollen that is left in ambient conditions. A method of the present invention includes separating dead pollen contents from live pollen grains. In some embodiments, pollen grains are stored with a substance that prevents dead pollen contents from interacting with live pollen grains. The substance may be a solid, liquid, gas, or combination thereof. In some embodiments, the substance may at least partially regulate pollen moisture content, such as maintaining pollen moisture content at 15-60%

Disclosed are methods of preserving pollen such that the pollen has improved viability as compared to pollen that is left in ambient conditions. A method of the present invention includes separating dead pollen contents from live pollen grains. In some embodiments, pollen grains are stored with a substance that prevents dead pollen contents from interacting with live pollen grains. The substance may be a solid, liquid, gas, or combination thereof. In some embodiments, the substance may at least partially regulate pollen moisture content, such as maintaining pollen moisture content at 15-60%

A fume decontamination system connected to any combustion system which comprises seven devices interconnected sequentially in the following manner: an extraction device (A) is first connected to the combustion system and then connected by the other end to a guiding device (B) which, in turn, is connected to a cooling device (C). Once cooled, the combustion gases are channeled to a suction device (D) in which the gases are driven under pressure to an induction device (E) which, in turn, concentrates the gases and directs same to the injection plenum (F), the concentrated, cooled gases being distributed at constant volumes to the entire biological plant filtering device (G) and its decontamination procedure, as shown in FIG. 2/13.

A fume decontamination system connected to any combustion system which comprises seven devices interconnected sequentially in the following manner: an extraction device (A) is first connected to the combustion system and then connected by the other end to a guiding device (B) which, in turn, is connected to a cooling device (C). Once cooled, the combustion gases are channeled to a suction device (D) in which the gases are driven under pressure to an induction device (E) which, in turn, concentrates the gases and directs same to the injection plenum (F), the concentrated, cooled gases being distributed at constant volumes to the entire biological plant filtering device (G) and its decontamination procedure, as shown in FIG. 2/13.

A system for plant parameter detection, including: a plant morphology sensor having a first field of view and configured to record a morphology measurement of a plant portion and an ambient environment adjacent the plant, a plant physiology sensor having a second field of view and configured to record a plant physiology parameter measurement of a plant portion and an ambient environment adjacent the plant, wherein the second field of view overlaps with the first field of view; a support statically coupling the plant morphology sensor to the physiology sensor, and a computing system configured to: identify a plant set of pixels within the physiology measurement based on the morphology measurement; determine physiology values for each pixel of the plant set of pixels; and extract a growth parameter based on the physiology values.

Disclosed herein is a soil remediation and soil pore stabilising composition comprising at least one electrolyte and at least one cofactor.

Disclosed herein is a soil remediation and soil pore stabilising composition comprising at least one electrolyte and at least one cofactor.