The present disclosure discloses a smart pet feeder, motor drives the rotating mechanism to rotate, and the rotating mechanism quantitatively pushes the pet food in the support into a sliding chute, and the pet food falls into the food bowl through the sliding chute, which effectively achieves smart quantitative feeding of pets in either an automatic manner or a manual manner.

The invention is a dispensing module for use in delivering measured doses of feed supplement to an animal. It comprises a storage container for holding the supplement and a metering module that is rotatably connected to the storage container for dispensing a measured (pre-determined) dose of the supplement. The dispensing module is adapted to be moved between an open configuration and a closed configuration. In the open configuration, the measured dose of the supplement is able to be dispensed out of the dispensing module. In the closed configuration, the measured dose of the supplement is prevented from being dispensed out of the dispensing module. Compressed air can be used to send the dose to an outlet when the dispensing module is closed.

A monitoring and/or food/water/medicine control system and method of use of the systems provide that (i) an experimenter at the computer desktop sets the schedule for feeding/fasting (food or water or medicine) the animal according to their need, and the animal’s access to food or water or medicine will be set accordingly. This allows animal scientists, experimentalists, and experimenters to fully control animal feeding scenarios; (ii) the experimenter remotely opens and closes the animal’s access to food/water/medicine regardless of the pre-set schedule; (iii) the experimenter checks the animal’s status via real-time monitoring; (iv) an artificial intelligence system identifies and tracks the animal’s location and its activities; and (v) a software module connects the vision unit and feeding mechanism to the experimenter’s desktop to provide full control of both the vision unit and the feeding mechanism, to calculate different parameters of the animal’s activities, and to report the animal’s feeding/fasting history, activity history, and upcoming scheduled feedings.

Certain aspects of the present disclosure provide techniques for detecting an operational state of an autonomous pet interaction device, including: commanding a treat dispenser to dispense a treat from the autonomous pet interaction device; capturing image data using an image sensor of the autonomous pet interaction device; and determining, based on the image data, whether or not the treat was dispensed from the treat dispenser.

A method and system are arranged to perform a feed-related action at a feed table, upon which fodder for feeding of a group of animals is present. The system includes a sensor, configured to measure constituents, physical property or chemical property of the fodder on the feed table at a first point in time; a database, configured to store the measured constituents, physical property or chemical property of the fodder, associated with the first point in time; and a controller, configured to perform the feed-related action, based on the measured constituents, physical property or chemical property of the fodder.

Disclosed is a multifunctional intelligent breeding and rearing system. Functional modules such as a radio-frequency ear tag and identification device, a central controller (1), an isolation and dislodging device (2), a multifunctional feeding trough (3), an automatic feeding device (4), a quantitative water supply device, a feeding trough automatic flushing and a remaining feed detection are utilized to form a basic automatic feeding unit. Through the feeding unit, an identity and eating information of a pig is identified; for a pig that does not eat during a feeding time period, feed and water are injected into a feeding trough simultaneously according to a feed amount and a mixing ratio preset by the system, for precise feeding; a pig that has eaten up is dislodged in real time; and the feeding trough is automatically flushed at an end of feeding. The system realizes automatic and intelligent feeding of a livestock.

One variation of a method for acclimating a dog to autonomous training with a training apparatus, includes: accessing a video feed of a working field; dispensing a first set of treats into the working field at a first frequency and outputting an audible reinforcer at a first volume level; estimating a first acclimation score representative of acclimation to dispensation of the first set of treats; in response to the first acclimation score exceeding a threshold acclimation, dispensing a second set of treats at a second frequency less than the first frequency and outputting the audible reinforcer at a second volume greater than the first volume; estimating a second acclimation score responsive to the second set of treats; in response to the second acclimation score exceeding the threshold acclimation, the second frequency falling below a threshold frequency, and the second volume exceeding a threshold volume, verifying acclimation of the dog.

A feeder including: a) a base portion having a serving area; b) a chamber portion supported by the base portion and configured to retain a granular material within a chamber interior; c) a dispenser configured to segregate a portion of the granular material from the chamber interior and transfer the portion of the granular material from the chamber portion to the serving area, wherein the dispenser includes: i) a rocker body; and ii) one or more fins projecting from the rocker body; and wherein the feeder includes one or more of: i) the fin(s) are flexible; ii) sensing device(s) part of a sensing tower configured to sense the presence, distance, and/or amount of the granular material within the chamber portion; and/or iii) sensing device(s) configured to sense the presence, distance, and/or amount of the granular material within the serving area.

This invention general relates to animal feeders, an animal feeding monitor and a method of training an animal to use a feeder. An animal feeder may have a housing comprising an aperture for a food bowl (8) and having a door for covering the aperture, the feeder comprising a door mechanism to control movement of the door over the aperture, wherein the feeder comprises a sensor to detect when an animal has moved away from the aperture, and the feeder is configured to be operable in a training mode wherein the door mechanism is operable to control the door to cover a portion of the aperture in response to a said detection and to respond to one or more later said detections by controlling the door to cover a portion of the aperture larger than the preceding said portion.

A pet feeding apparatus includes a feed tank, a discharge tank, and an ejection assembly. The feed tank includes an accommodation chamber and a discharge outlet communicating with the accommodation chamber. The discharge tank includes an ejection outlet, an inlet, and an ejection chamber located between the ejection outlet and the inlet. The inlet communicates with the discharge outlet of the feed tank. The ejection assembly includes a rotation blade and a driving member. The rotation blade is received in the ejection chamber, and the rotation blade includes a rotation shaft and a blade extending from the rotation shaft. The driving member is connected to the rotation shaft and is capable of driving the rotation shaft to rotate with respect to the ejection chamber, so that the driving member drives the blade to swing from the inlet toward the ejection outlet.