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.

The embodiments disclose a stress and strain gauge including at least one stress and strain sensor module configured to sense stresses and strains being applied by an animal biting a rope extending from a protective hand guard, a stress and strain gauge indicator coupled to the at least one stress and strain sensor configured for measuring the sensed stresses and strains as strain levels, a processor coupled to the stress and strain gauge indicator configured to dynamically analyze and compare the strain levels to predetermined threshold strain level measurements to determine a current animal play level that varies incrementally, and an alert module wirelessly coupled to the processor configured to notify a user of the protective hand guard in real-time of the current incremental animal play level.

A stand-alone chamber or multi-chamber inhalation system has at least two alternative vaporized test liquid supply systems for passive or self-administered delivery of vaporized test fluid and air to one or more test chambers, which can be passive or restraint chambers, based on operator selection of delivery on and off times in a passive mode or actuation of an actuator in the chamber by a test animal in a self-administered mode. In one case, a multiple inhalation chamber system has two or more separate test fluid delivery systems and provides options for selective passive uniform drug delivery to multiple chambers or selective delivery of two or more different drugs to different groups of chambers from different delivery systems so that two different drugs or different concentrations of delivered drugs can be tested simultaneously.

Embodiments of the present disclosure can provide an automated mass rearing system for insect larvae. The automated mass rearing system can facilitate hatching, feeding, monitoring the growth and emergence of insect larvae and pupae. In some embodiments, the automated mass rearing system can include a production unit, a transportation unit, a storage unit, a dispensing unit, and a monitoring unit. In some embodiments, this automated mass rearing system can facilitate mass mosquito growth from egg hatching all the way through to full adults or certain stages in between such as the larvae rearing process (i.e., from larvae to pupae) with little or no human intervention. By automating the rearing and transportation of insect eggs, larvae, and pupae, deaths or developmental issues can be minimized. Various techniques and apparatuses are used in this automation that causes minimal disturbance to the insects during development, and thereby maximizing survival rate and fitness of the insects.

A method for monitoring an animal with an autonomous monitoring device in close proximity to the animal, the monitoring device having a first sensor and a second sensor of higher electric power consumption. The method includes measuring a first parameter with the first sensor, the second sensor being deactivated. An estimated status of the animal is determined based on the first parameter. If the estimated status corresponds to a particular status, the second sensor is activated and measures a second parameter which is used to determine a specified estimated status of the animal.

Embodiments of the present disclosure provide systems, apparatuses and methods for synchronous communication and control of LED lights and sensors in an LED light array containing two or more LED lights. Through the use of a master clock within a gateway and/or a master controller that is in communication with LED lights in an array that is in a facility, such as in a greenhouse, hot house, poultry egg production facility, a hospital, dairy production or other lighting facilities, the gateway and/or master controller is capable of synchronizing the emission of light or photons from an LED light array by generating a master signal that contains commands and time from a master clock within the signal that is transmitted to each of the LED lights within an array.

A system for the remote care of an item of vegetation used as a potential source of food for an animal, to include at least one of a proximity tag, RFID tag, transponder device, a predetermined machine-readable pattern, and geo-location device associated with the item of vegetation, and an aerial drone. The aerial drone includes a microprocessor, a sensor coupled to the microprocessor and configured to detect the at least one of the proximity tag, RFID tag, transponder device, predetermined machine-readable pattern, and the geo-location device, and a carrier configured to carry a substance comprising at least one of a solid, gas, and liquid. The aerial drone is configured to act in response to instructions issued by the microprocessor.

A method, system and computer programs for traceability of living specimens are provided. The method comprises executing a first process that performs video tracking of a plurality of living specimens and that determines tracking features thereof; determining a trajectory vector that includes a trajectory followed by each detected living specimen; executing a second process at a certain period of time that determines secondary features of one or more living specimens; matching tracking features of the trajectory vector with the secondary features, providing reference point of hyperfeatures; determining secondary features of the living specimens for other periods of time, providing other reference points of hyperfeatures; identifying when two reference points are contained within a same digital identifier, and as a result providing a potential trajectory segment; comparing physical characteristics of said potential trajectory segment and establish that the potential trajectory segment is valid/invalid depending if said comparison is inside/outside a given range.

An abnormality detecting system includes a first identification unit configured to identify a state of an animal that is a monitoring target in each time range, based on time-series data from a motion sensor placed on a predetermined portion of the animal that is a monitoring target; a first calculation unit configured to calculate a transition probability from the state at a predetermined timing of each time range identified by the first identification unit to a next state; and a determining unit configured to determine that an abnormality of the animal that is a monitoring target is detected when a score calculated based on the transition probability to the next state satisfies a predetermined condition.

A generating device of simulating a particulate environment for an experimental animal includes an experimental chamber. An ultrasonic atomization device is installed at the bottom adjacent to the center of the experimental chamber. The upper side of the ultrasonic atomization device is connected to a guide device for guiding particles. The guide device includes an air seal cover, and a micro fan is installed inside the air seal cover to drive the movement of particles generated in the ultrasonic atomization device. Air guide pipes are fixedly connected to a side wall of the air seal cover. The generating device has good sealing performance, and can generate a variety of particle simulation environments to accurately and effectively simulate the biological effect of particles in the animal body. The generating device can improve the particle simulation environment, reduce the deviation of experimental data, and ensure the accuracy of the overall experimental data.