A work management system includes an estimation unit that estimates a performed work amount based on a position of a portion of a work object to which a fluid is estimated to be blown while the work is performed. In addition, the work management system includes a first correction unit that compares a target passing position through which a fluid blowing device passes while the work is performed with a position of the fluid blowing device to determine whether the fluid blowing device has passed through the target passing position while the work is performed, and executes a first correction process of reducing the work amount estimated by the estimation unit when it is determined that the fluid blowing device has not passed through the target passing position.

A work management system includes an estimation unit that estimates a performed work amount based on a position of a portion of a work object to which a fluid is estimated to be blown while the work is performed. In addition, the work management system includes a first correction unit that compares a target passing position through which a fluid blowing device passes while the work is performed with a position of the fluid blowing device to determine whether the fluid blowing device has passed through the target passing position while the work is performed, and executes a first correction process of reducing the work amount estimated by the estimation unit when it is determined that the fluid blowing device has not passed through the target passing position.

In an embodiment, agricultural intelligence computer system stores a digital model of nutrient content in soil which includes a plurality of values and expressions that define transformations of or relationships between the values and produce estimates of nutrient content values in soil. The agricultural intelligence computer receives nutrient content measurement values for a particular field at a particular time. The agricultural intelligence computer system uses the digital model of nutrient content to compute a nutrient content value for the particular field at the particular time. The agricultural intelligence computer system identifies a modeling uncertainty corresponding to the computed nutrient content value and a measurement uncertainty corresponding to the received measurement values. Based on the identified uncertainties, the modeled nutrient content value, and the received measurement values, the agricultural intelligence computer system computes an assimilated nutrient content value.

A system and computer-implemented method for assessing an amount of ash includes an agricultural implement and an ash assessment system. The implement includes a crop processing portion configured to move a cut organic material in a field. The ash assessment system includes an ash sensor configured to determine a measured ash contamination value, a GNSS receiver configured to determine a geolocation, and a processor programmed to perform an ash assessment process. The process includes receiving the measured ash contamination value from the ash sensor and receiving the geolocation data from the GNSS receiver. The geolocation data corresponds to a geolocation of the measured ash contamination value. The process also includes correlating the measured ash contamination value and the geolocation data to one another and storing the measured ash contamination value and the geolocation data in a memory device that is coupled in communication with said processor.

A system and computer-implemented method for assessing an amount of ash includes an agricultural implement and an ash assessment system. The implement includes a crop processing portion configured to move a cut organic material in a field. The ash assessment system includes an ash sensor configured to determine a measured ash contamination value, a GNSS receiver configured to determine a geolocation, and a processor programmed to perform an ash assessment process. The process includes receiving the measured ash contamination value from the ash sensor and receiving the geolocation data from the GNSS receiver. The geolocation data corresponds to a geolocation of the measured ash contamination value. The process also includes correlating the measured ash contamination value and the geolocation data to one another and storing the measured ash contamination value and the geolocation data in a memory device that is coupled in communication with said processor.

Disclosed herein is an apparatus for facilitating managing cultivation of crops based on monitoring the crops. Further, the apparatus comprises an apparatus body, cameras, light sensors, a processing unit, and a communication interface. Further, the cameras generate a measurement of a crop and a field portion. Further, the light sensors generate an environment measurement of an environment of the apparatus. Further, the processing unit analyzes the environment measurement, determines a factor affecting the measurement, and generates a calibrating factor for the cameras. Further, the calibrating factor facilitates compensating the affecting of the factor in the measurement. Further, the cameras calibrate a camera parameter of the cameras based on the calibrating factor to generate the measurement. Further, the processing unit analyzes the measurement and generates a status of the crop. Further, the communication interface transmits the status to a device.

Disclosed herein is an apparatus for facilitating managing cultivation of crops based on monitoring the crops. Further, the apparatus comprises an apparatus body, cameras, light sensors, a processing unit, and a communication interface. Further, the cameras generate a measurement of a crop and a field portion. Further, the light sensors generate an environment measurement of an environment of the apparatus. Further, the processing unit analyzes the environment measurement, determines a factor affecting the measurement, and generates a calibrating factor for the cameras. Further, the calibrating factor facilitates compensating the affecting of the factor in the measurement. Further, the cameras calibrate a camera parameter of the cameras based on the calibrating factor to generate the measurement. Further, the processing unit analyzes the measurement and generates a status of the crop. Further, the communication interface transmits the status to a device.

An agricultural trench depth sensing system having a trench implement adapted to be disposed in a soil trench opened in a soil surface. In one embodiment an ultrasonic sensor detects a distance to an upper surface of said trench implement or a target disposed thereon. In another embodiment, said trench implement includes one or more fingers which rotate with respect to said trench implement to detect the soil surface relative to said trench implement. In another embodiment, said trench implement includes side sensors for detecting the sidewall of the soil trench.

An agricultural trench depth sensing system having a trench implement adapted to be disposed in a soil trench opened in a soil surface. In one embodiment an ultrasonic sensor detects a distance to an upper surface of said trench implement or a target disposed thereon. In another embodiment, said trench implement includes one or more fingers which rotate with respect to said trench implement to detect the soil surface relative to said trench implement. In another embodiment, said trench implement includes side sensors for detecting the sidewall of the soil trench.

A structure and method for three-dimensional restoration of slope soil in an abandoned ion-absorbed rare earth mining area, belonging to the field of ecological restoration technologies. The structure for three-dimensional restoration of slope soil in an abandoned ion-absorbed rare earth mining area provided by the present invention includes an ecological water-harvesting pond, ecological intercepting ditches, an improved soil layer laid on the surface of a to-be-restored slope region and a soil restoration ecological network disposed on the improved soil layer. The improved soil layer, the ecological water-harvesting pond and the ecological intercepting ditches are each provided with a combined plant synusia system. The restoration structure provided by the present invention can effectively improve an extremely degraded ecological environment of the abandoned ion-absorbed rare earth mining area caused by tailings waste land and restore the degraded or polluted mining area soil and environment caused by mine destruction during rare earth mining.