The stackable trellis support system of the present invention comprises base and main trellis assemblies having wire mesh over the horizontal wire mesh frame assembly. The base trellis assembly allows additional sections to be added to the system, utilizing four main post apparatuses for connecting each trellis assembly. Any number of main trellis assemblies may be connected using the main post apparatus to form the stackable trellis support system. The base trellis assembly can be anchored in soil/ground using anchored rebar stakes to which the base post apparatus slides over and attaches, using locking bolts, allowing the height of base trellis assembly to be adjustable along the vertical axis of said rebar stakes, and perpendicular to soil/ground. The trellis side wire panels can be hung from said wire mesh frame assembly to provide vertical support.

The stackable trellis support system of the present invention comprises base and main trellis assemblies having wire mesh over the horizontal wire mesh frame assembly. The base trellis assembly allows additional sections to be added to the system, utilizing four main post apparatuses for connecting each trellis assembly. Any number of main trellis assemblies may be connected using the main post apparatus to form the stackable trellis support system. The base trellis assembly can be anchored in soil/ground using anchored rebar stakes to which the base post apparatus slides over and attaches, using locking bolts, allowing the height of base trellis assembly to be adjustable along the vertical axis of said rebar stakes, and perpendicular to soil/ground. The trellis side wire panels can be hung from said wire mesh frame assembly to provide vertical support.

Disclosed are methods of improving germination rates of plants/crops, as well as preventing or arresting water evaporation loss from targeted soil areas, which allows for improved water usage efficiency by crops, plants, grasses, vegetation, etc.

This invention relates to methods and materials for providing a benefit to a plant by associating the plant with a complex endophyte comprising a host fungus further comprising a component bacterium, including benefits to a plant derived from a seed or other plant element treated with a complex endophyte. For example, this invention provides purified complex endophytes, purified complex endophyte components such as bacteria or fungi, synthetic combinations comprising said complex endophytes and/or components, and methods of making and using the same.

Use of a device D in agricultural applications, forestry or home and garden applications, wherein said device D is used for dispensing in the air, as a vapor, an active ingredient that is liquid at ambient temperature, wherein device D contains: —an aeration system that contains a pipe (2, 4, 510) opening into the open air and is configured to allow an airflow to pass through the pipe; —at least one distributor member (8, 208) that is in fluid connection with a storage container and is intended to be supplied with a liquid active ingredient from said storage container, said distributor member containing a porous body (8, 208) that contains micro-channels forming an outlet arranged in said pipe in order to constitute an evaporation zone for the active ingredient therein, wherein the pores present in said porous body are at least a part of the micro-pipes of the distributor member; —a heating member (11, 211, 132) arranged on or in the distributor member so as to control a flow of the active ingredient through the distributor member.

An amino acid fertilizer composition manufactured from livestock farming by-product using acid, alkali and protease treatment. More specifically, the amino acid fertilizer composition may be manufactured by: 1) separating and producing a crude collagen peptide from livestock farming by-product, such as, bovine skin, pig skin or bovine bone using acid and alkali treatment, 2) hydrolyzing the obtained crude collagen peptide using collagen specific protease produced from Bacillus sp. variant Iren-101, and 3) obtaining an amino acid level fertilizer composition.

An amino acid fertilizer composition manufactured from livestock farming by-product using acid, alkali and protease treatment. More specifically, the amino acid fertilizer composition may be manufactured by: 1) separating and producing a crude collagen peptide from livestock farming by-product, such as, bovine skin, pig skin or bovine bone using acid and alkali treatment, 2) hydrolyzing the obtained crude collagen peptide using collagen specific protease produced from Bacillus sp. variant Iren-101, and 3) obtaining an amino acid level fertilizer composition.

Methods for predicting a yield of fruit growing in an agricultural plot are provided. At a first time, a first plurality of images of a canopy of the agricultural plot is obtained from an aerial view of the canopy of the agricultural plot. From the first plurality of images, a first number of detectable fruit is estimated. At a second time, a second plurality of images of the canopy of the agricultural plot is obtained from the aerial view of the canopy of the agricultural plot. From the second plurality of images, a second number of detectable fruit is estimated. Using at least the first number of detectable fruit and the second number of detectable fruit and agricultural plot information, predict the yield of fruit from the agricultural plot.

A computer system obtains, using a camera, a first plurality of images of a canopy an agricultural plot. For each respective fruit of a plurality of fruit growing in the agricultural plot, the computer system identifies a first respective image in the first plurality of images that comprises the respective fruit. The first respective image has a corresponding first camera location. The computer system also identifies a second respective image in the first plurality of images that comprises the respective fruit. The second respective image has a corresponding second camera location. The computer system uses at least i) the first and second respective images and ii) a distance between the first and second camera locations to determine a corresponding size of the respective fruit.

A computer system obtains, using a camera, a first plurality of images of a canopy an agricultural plot. For each respective fruit of a plurality of fruit growing in the agricultural plot, the computer system identifies a first respective image in the first plurality of images that comprises the respective fruit. The first respective image has a corresponding first camera location. The computer system also identifies a second respective image in the first plurality of images that comprises the respective fruit. The second respective image has a corresponding second camera location. The computer system uses at least i) the first and second respective images and ii) a distance between the first and second camera locations to determine a corresponding size of the respective fruit.