A vehicle is provided that includes a vehicle body defining a cabin interior and comprising a front row of seats and a rear row of seats, a plurality of seats located within the cabin interior, and a monitoring system for detecting and monitoring a pet or passenger within the cabin interior. The vehicle also includes a movable center console positioned between a pair of the forward row of seats and forward of the rear row of seats and comprising a holder for holding a drink container, and a controller processing signals generated by the monitoring system and determining a location of the detected pet or passenger on the rear row of seats based on the processed signals, the controller further controlling the movable console between a forward first position and a rearward second position closer to the rear row of seats.

A pet ramp is provided having two panels in a collapsible arrangement, with a first panel having legs and a second panel able to be cantilevered from the first panel. The second panel extends beyond the legs and is pivotable to rest on any available surface. A stop is provided between the first and second panels to hold a cantilevered deployed position of the second panel.

A pet ramp is provided having two panels in a collapsible arrangement, with a first panel having legs and a second panel able to be cantilevered from the first panel. The second panel extends beyond the legs and is pivotable to rest on any available surface. A stop is provided between the first and second panels to hold a cantilevered deployed position of the second panel.

The present disclosure discloses an intelligent pet calling device, including a collar detachably connected to the body or head of a pet, and a functional box detachably arranged on the collar; a wireless connection module and a voice device are arranged in the functional box; the functional box also includes a shell assembly, a control board, a battery, a button and a charging interface; the shell assembly is a hollow cavity; the control board, the voice device and the battery are respectively fixedly arranged in the shell assembly; the battery supplies electric energy to the control board and the voice device; the button and the charging interface are respectively arranged on the control box and penetrate through the shell assembly; the functional box also includes a heart rate monitoring device; and the functional box further includes a camera.

An animal tracking system comprising a first LoRa receiver configured as a gateway to receive transmissions on a first set of channels or a second set of channels and forward said transmissions to a first remote server, and a transmitting tag configured to be affixed to an animal. The transmitting tag includes a memory configured to store digital information, a passive RFID receiver configured to detect a close proximity to an RFID transmitter and store detection of the close proximity in comprising in the memory, a processor configured to determine an alarm status according to a frequency of detection of the close proximity, an internal energy source, and a LoRa transmitter configured to transmit signals for a distance greater than 100 meters via energy from the internal energy source.

The present disclosure relates to an agricultural monitoring system and method for monitoring a nutrient flow within an agricultural site. The method comprises the steps of detecting a quantity related to a carried material of a known material type; determining a nutrient content of the captured material based on the detected quantity and based on at least one nutrient content parameter value associated with the carried material; obtaining information related to a source location and a target location for the carried material, and forming information related to the nutrient flow, said information comprising the source location, the target location, information related to the determined nutrient content of the carried material and preferably material type of the carried material.

Methods for enhancing embryonic and post-hatch growth and performance of poultry by administration of a probiotic composition, such as a composition containing a mixture of one or more bacterial cultures, to the surface of the shells of fertilized eggs prior to setting. Optionally, the method further includes administration of the same probiotic composition at the same concentration to chicks hatched from the eggs that had received the topical in ovo administration to the shell. The probiotic composition is administered to the chicks orally, such as in feed.

In predictive natural disaster response, a server determines an affected location predicted to be affected by a natural disaster and determines whether the type of natural disaster requires relocation of an animal population at the affected location. When relocation is required, using machine learning models, the server generates a rehabilitation needs prediction for the relocation, determines an optimal location for the relocation from candidate locations, and generates a relocation plan to relocate the animal population from the affected location to the optimal location. When relocation is not required, using the machine learning models, the server generates a demands prediction for products and services at the affected location, generates a supply prediction for the products and the services at the affect location, and generates a supply plan using the demands and supply predictions.

In predictive natural disaster response, a server determines an affected location predicted to be affected by a natural disaster and determines whether the type of natural disaster requires relocation of an animal population at the affected location. When relocation is required, using machine learning models, the server generates a rehabilitation needs prediction for the relocation, determines an optimal location for the relocation from candidate locations, and generates a relocation plan to relocate the animal population from the affected location to the optimal location. When relocation is not required, using the machine learning models, the server generates a demands prediction for products and services at the affected location, generates a supply prediction for the products and the services at the affect location, and generates a supply plan using the demands and supply predictions.

An animal information management system includes a storage and an information processor. The information processor causes an imaging device to perform tracking imaging of a pig, and accumulates still pictures including the pig in the storage, the still pictures being obtained during the tracking imaging. The information processor brings the imaging device into a zoom-in state having a zooming magnification higher than that during the tracking imaging when a predetermined requirement for the accumulated still pictures is satisfied, obtains the identification information of the pig by causing the imaging device in the zoom-in state to capture an image of the pig, and stores the identification information in the storage, in association with the accumulated still pictures.