In a produce management system (1), a production-base-side apparatus (10) outputs management data generated or input in a process of breeding produce at a production base. A management-base-side apparatus (70) stores or outputs at least one of the management data, a piece of relevant information generated as a result of processing or inspection of the management data, and a piece of certification information generated in response to obtainment of the management data, when the management-base-side apparatus obtains the management data.

In a produce management system (1), a production-base-side apparatus (10) outputs management data generated or input in a process of breeding produce at a production base. A management-base-side apparatus (70) stores or outputs at least one of the management data, a piece of relevant information generated as a result of processing or inspection of the management data, and a piece of certification information generated in response to obtainment of the management data, when the management-base-side apparatus obtains the management data.

An electro-mechanical device cuts plant stems at a desired angle after a stem is inserted into a stem shaft and a sensor triggers activation of a blade along a blade path at a desired angle. A portable device powered by batteries can be used with plantings where they are growing or a powered device can be used for line production or high volume work.

An electro-mechanical device cuts plant stems at a desired angle after a stem is inserted into a stem shaft and a sensor triggers activation of a blade along a blade path at a desired angle. A portable device powered by batteries can be used with plantings where they are growing or a powered device can be used for line production or high volume work.

Exemplary sap flow sensors are provided. A sap flow sensor includes a substrate having a main body and at least two arms spaced apart from one another. The at least two arms extend from the main body. The sap flow sensor further includes a sap flow gauge that is disposed on the substrate. The sap flow gauge is configured to monitor a flow rate of sap through a stem of a plant. The sap flow gauge includes a heating element coupled to an arm of the at least two arms. The sap flow gauge further includes a first temperature sensor and a second temperature sensor disposed on opposite sides of the heating element. The first temperature sensor and the second temperature sensor each coupled to a neighboring arm of the at least two arms.

The present invention provides a system, method and apparatus for irrigation control and data management. According to a preferred embodiment, an irrigation control system may include a data collection module which receives and stores system data generated by sensors and supporting systems including irrigation, drive, weather, sensor and electrical systems of a mechanized irrigation system. According to preferred embodiments, the system preferably also includes a system control module which transmits system control instructions to system components. Additionally, the present invention also includes a display module which provides a display of graphical user interfaces embedded with system data and selectable control instructions.

Crops for human and animal consumption of many types are well known by their respective growers. Years of experience in the field provide the grower knowledge about a range of conditions that lead to the full spectrum of crop yields and crop quality, and each grower creates a store of knowledge which they can combine with the available measures of those conditions. This disclosure provides a method for indicating the onset of water stress in one or more plants located in a soil the roots of which are within the measurement zone of a soil moisture sensor located in the soil, by determining from representative data of the daily soil water usage and the evapotranspiration value in the region of the crop each day for a predetermined number of 24 hour periods consecutively prior to a stress determination day d by calculating the line of best fit for the daily crop water usage and recorded ETo for the predetermined number of consecutive 24 hour periods. Calculating the difference of each daily crop water usage from the line of best fit. Determining the statistical standard deviation of the differences of each daily crop water usage value from the line of best fit. Determine a predicted crop water usage for day d using the ETo for day d and the line-of-best fit. Determining whether the difference between the daily crop water usage for day d and the predicted crop water usage for day d, and if the difference is equal to or more than the value V, where the value V is an amount of deviation from the mean where V in an example is the standard deviation. Indicating that a period of water stress of the one or more plants has been entered as of day d to thereby control elements of a crop management arrangement to irrigate or not to irrigate automatically with no human intervention.

Methods and systems for generating agronomic indices and executing one or more actions in response to said agronomic indices at an agriculture site, the method comprising: receiving a set of samples associated with the agriculture site; generating a sample dataset upon processing the set of samples with a set of sample processing operations; generating a set of microbiome-associated features upon performing a set of transformation operations upon the sample dataset, wherein the set of microbiome-associated features comprises a first subset of taxonomic annotations, a second subset of functional annotations and a third subset of ecological indices; generating values of a set of agronomic indices based upon the set of microbiome-associated features; and executing an action for producing a desired outcome at the agriculture site, based upon the set of agronomic indices.

The invention provides novel systems and methods for drying and storing pollen. The invention further provides novel methods for delivering pollen to a recipient plant. The systems provided herein include a chamber configured to permit a drying gas to contact pollen, a source for the drying gas, and an instrument configured to measure the humidity of the drying gas or a sensor configured to measure the moisture content of the pollen. The methods provided herein include methods of drying pollen to a desired moisture content, methods of storing dried pollen, and methods of applying the dried or stored pollen to at least a recipient plant, thereby pollinating the recipient plant with the dried or stored pollen from the donor plant.

The invention provides novel systems and methods for drying and storing pollen. The invention further provides novel methods for delivering pollen to a recipient plant. The systems provided herein include a chamber configured to permit a drying gas to contact pollen, a source for the drying gas, and an instrument configured to measure the humidity of the drying gas or a sensor configured to measure the moisture content of the pollen. The methods provided herein include methods of drying pollen to a desired moisture content, methods of storing dried pollen, and methods of applying the dried or stored pollen to at least a recipient plant, thereby pollinating the recipient plant with the dried or stored pollen from the donor plant.