There is provided an industrial machinery system including an industrial machine, an area information acquiring device that acquires information on an operation area where the industrial machine is to be caused to perform an operation, and a control apparatus that determines whether to perform the operation by the industrial machine in the operation area, wherein the control apparatus includes a storage section that stores information on a registered area, the information being acquired in advance, and a determining section that determines whether to perform the operation by the industrial machine in accordance with whether an area corresponding to the operation area is identifiable from the registered area stored in the storage section.

A system comprising: at least one hardware processor; and a non-transitory computer-readable storage medium having stored thereon program instructions, the program instructions executable by the at least one hardware processor to: receive, as input, spectral image data representing spectral reflectance associated with at least one plant, calculate a first and second chlorophyll fluorescence indices in respective first and second wavelength bands, based, at least in part, on said spectral reflectance, and derive a quantum yield value with respect to said at least one plant, by: (i) dividing said first chlorophyll fluorescence index in a sum of said first and second chlorophyll fluorescence indices, and (ii) multiplying (i) by a vegetation index value associated with said at least one plant.

A spreading support system includes a height difference acquisition unit to acquire a height difference in an agricultural field, a spread amount acquisition unit to acquire a planned spread amount which is an amount of an object to be spread on the agricultural field, a spread amount correction unit to correct, on the basis of the height difference acquired by the height difference acquisition unit, the planned spread amount acquired by the spread amount acquisition unit to obtain a corrected spread amount, and a spread amount output unit to output the corrected spread amount.

A nutrient amount determination device acquires number-of-users information indicating a number of users who use a sports facility within a predetermined period, the sports facility having lawn on which a sport is played. The nutrient amount determination device determines based on the acquired number-of-users information an application amount of at least one nutrient to be applied to the lawn of the sports facility by fertilization within the predetermined period.

A concentrated composition for plant nutrition. The composition includes a polymeric stabilizing agent having a high number of polar hydrophilic groups, such as microfibrillated cellulose (MFC), comprising calcium ions, sulfate ions and salts of other elements for plant nutrition. The concentration of calcium ions and sulfate ions and other essential elements exceeds the concentration corresponding to the normal solubility of calcium sulfate and other insoluble salts in water. The proportion of the polymeric stabilizing agent having a high number of polar hydrophilic groups is within a range of 1% and 99% w/w of the suspension. The availability of the nutrient elements is assured within a pH range of 1 to 13.

Provided are a field display device and the like capable of displaying a plurality of fields to be displayed on a screen reliably and immediately. A field information management device is configured such that: a plurality of fields for cultivating plants can be displayed on a main screen, and a plurality of pieces of character information related to the fields that can be displayed on the main screen can be displayed on a sub-screen simultaneously with the main screen; and shape information of each of the fields that can be displayed on the main screen is displayed on the sub-screen together with the character information related to the corresponding field.

A method for plantation treatment of a plantation field, the method comprising: determining (S10) an application rate decision logic (10) based on offline field data (Doff) relating to expected conditions on the plantation field (300); taking (S20) an image (20) of a plantation of a plantation field (300); recognizing (S30) objects (30) on the taken image (20); determining (S40) an application rate based on the determined application rate decision logic (10) and the recognized objects (30); and determining (S50) a control signal (S) for controlling a treatment arrangement (50) of a treatment device (200) based on the determined application rate.

The present disclosure relates to a method for avoiding high temperature and maintaining yield of rice. The method prevents high temperature and builds a comprehensive disaster prevention and mitigation system by screening high-temperature resistant varieties, sowing at suitable time, cultivating strong seedlings, irrigating, applying silicon fertilizer and adjusting density, and chemically regulating; the method can avoid or attenuate heat injury, and be conducive to maintaining yield in disasters. The present disclosure is appropriate for areas prone to high temperature in China, especially for rice regions in the middle and lower reaches of the Yangtze River and Southwest China, for example, Fuyang, Zhejiang Province, Lujiang, Anhui Province, Jingzhou, Hubei Province, and Luzhou, Sichuan Province.

In an embodiment, an integrated sensor system with modular sensors and wireless connectivity components for monitoring properties of field soil is described. In an embodiment, an integrated sensor system comprises one or more sensors that are configured to determine one or more measures of at least one property of soil. The integrated sensor system also includes one or more processing units that are configured to receive, from the sensors, the measures of at least one property of soil and calculate soil property data based on the measures. The system further includes a transmitter that is configured to receive the soil property data from the processing units, establish a communications connection with at least one computer device, and automatically transmit the soil property data to the at least one computer device via the communications connection. In an embodiment, the communications connection is a wireless connection established between the transmitter and a smart hub or a LoRA-enabled device. In an embodiment, the computer sensors, the processors, and the transmitter are installed inside a portable probe.

Methods and systems for crop management are disclosed. An example method can comprise receiving first information associated with an environmental management zone. The first information can relate to one or more of a land characteristic and a management practice. The first information can comprise a soil type of the environmental management zone. An example method can comprise, receiving historical weather data relating to the environmental management zone. An example method can comprise receiving real-time weather data relating to the environmental management zone. An example method can comprise executing a growth model to predict a nitrogen range for the environmental management zone based on one or more of the first information, the historical weather data, and the real-time weather data. The nitrogen range can comprise probabilities for one or more of a current time period and a future time period in the growing season.