The present invention relates to a potential difference-based diversion electrode arrangement and field intensity compensation method, comprising the following steps: the arrangement positions of paired diversion electrodes are determined according to the difference of potential around a position of field intensity to be compensated and the direction of an electric field line, and the paired diversion electrodes are inserted; and the field intensity enhancement rate of the position of field intensity to be compensated and the compensated field intensity value are calculated according to the difference of potential and arrangement positions of the paired diversion electrodes. In the present invention, the paired diversion electrodes are arranged in the direction of the electric field line by using the spatial difference of potential in the electric field, and the compensation of local field intensity is implemented, thereby beneficial to improving the overall efficiency of electrokinetic remediation for organic contaminated soil, and reducing the spatial difference of remediation efficiency.

A soil resistivity detection system for an agricultural implement includes a row unit having row unit components. The row unit components include a residue management system configured to condition soil at a leading edge of the row unit, an opening system configured to form a furrow in the soil, a closing assembly configured to close the furrow, and a press wheel assembly configured to compact the soil. The soil resistivity detection system also includes a control assembly configured to output an electrical current to a first pair of the row unit components, receive voltages from a second pair of the row unit components, determine a voltage differential based on the voltages, and determine a soil resistivity based on the voltage differential.

Depth of penetration of a soil coulter is obtained using a sensor being mounted on the side of the disk adjacent the edge such that the sensor as the disk rotates is located above the surface of the soil during a first part of its rotation and is located below the surface during a second part of its rotation. This sensor is also used to detect characteristics of material outside the coulter as it rotates and temperature. This data is used in a growth model to generate predicted growth data to allow control of growth remediation materials to the crop.

A soil measurement system is provided, comprising a soil surveying device, a radio receiver, a plurality of subterranean antennas, and a processor. The soil surveying device comprises a wireless radio transmitter configured to emit a wireless signal at a predetermined bandwidth in a predetermined spectrum. The plurality of subterranean antennas are in an array electronically connected to the radio receiver and configured to be mounted in a subterranean environment at different depths in the subterranean environment. Each of the plurality of subterranean antennas is configured to receive the wireless signal at a respective point in time. The processor is configured to determine a relative time of flight of the received wireless signal between the plurality of antennas at the respective point in time, and estimate a soil permittivity based on the determined relative time of flight. The measurement system may be applied to materials other than soil, in some examples.

System for the disinfection of agricultural soil includes an electric energy source, at least one radiofrequency or microwave generator connected to the electric energy source and arranged to convert the electric energy into electromagnetic power and a plow-like electromagnetic applicator connected to the radiofrequency or microwave generator via wave-guiding lines, the plow-like electromagnetic applicator being arranged to be inserted into the soil so as to transmit the electromagnetic power to the soil, thus obtaining a disinfection of the soil.

System for the disinfection of agricultural soil includes an electric energy source, at least one radiofrequency or microwave generator connected to the electric energy source and arranged to convert the electric energy into electromagnetic power and a plow-like electromagnetic applicator connected to the radiofrequency or microwave generator via wave-guiding lines, the plow-like electromagnetic applicator being arranged to be inserted into the soil so as to transmit the electromagnetic power to the soil, thus obtaining a disinfection of the soil.

A harvester monitoring system configured to determine one or more parameters associated with harvested items, the system comprising: a camera module having a field of view and configured to generate image data associated with the harvested items; a mounting bracket configured to secure the camera module to a harvester such that a conveyor of the harvester is within the field of view of the camera module; a location sub-system configured to determine and output location data representative of a geographical location of the harvester monitoring system; and a processing unit configured to receive the image data and the location data, to determine one or more parameters associated with the harvested items, and to record the one or more parameters in association with the location data on a computer readable medium.

Depth of penetration of a soil coulter is detected using a sensor being mounted on the side of the disk adjacent the edge such that the sensor as the disk rotates is located above the surface of the soil during a first part of its rotation and is located below the surface during a second part of its rotation. The sensor issues a signal which changes in response to whether the sensor is above or below the soil surface which is received by a controller which calculates from the signal a first time when the sensor enters below the soil surface and a second time when the sensor departs the soil surface and calculates from the first and second times the depth of penetration of the coulter in the soil. The system can also detect variations in depth indicative of a value of surface roughness.

Seed sensors for determining seed placement in a furrow to then target at least one of fluid and solid application with respect to the seed are described herein. Plant sensors for determining location of plants within a field and then targeting at least one of fluid and solid application with respect to the plant are also described herein.

Seed sensors for determining seed placement in a furrow to then target at least one of fluid and solid application with respect to the seed are described herein. Plant sensors for determining location of plants within a field and then targeting at least one of fluid and solid application with respect to the plant are also described herein.