A sensor assembly for horse monitoring is disclosed. The sensor assembly comprises a sensor housing. The sensor housing comprises a plurality of surfaces including a first surface, a second surface, a third surface, and a fourth surface, and one or more protrusions including a first primary protrusion extending from a surface of the plurality of surfaces. The sensor assembly comprises a first optical sensor positioned at a first window of the first surface and configured to be positioned below an ear of a horse. The sensor assembly comprises an attachment element comprising a sensor opening configured for alignment with the first window. The attachment element comprises one or more openings including a first primary opening configured to receive the first primary protrusion. The attachment element is configured to removably attach the sensor assembly to a horse head equipment.

An apparatus for improving stability of a recreational animal may comprise a stability enhancement component. The stability enhancement component may comprise a top component, a bottom component, and four side components and may be rectangularly shaped. The stability enhancement component may comprise a diffuse surface that is configured to absorb the pressure the recreational animal exerts and spread the exerted pressure firmly throughout the rest of the stability enhancement component. The stability enhancement component may further comprise a direct surface that is configured to exert pressure in a direction opposite of a direction in which pressure is exerted by the recreational animal.

Automated systems and methods are presented for determining the physiological response of human or suitable animal subjects to physical exertion. The methods and systems can include monitoring sensors that capture the motion of the subject along with corresponding physiological data, and can track such motion for the duration of a period of physical exertion. The system is able to acquire an initial stream of physiological data from the subject during a range of physical exertion activities that are representative of the events intended to be monitored with the proposed method and system, enabling a corresponding dynamic physiological response model to be created. The motion tracking system and physiological response model can then be used to predict the physiological response to physical exertion events under a prescribed framework, including applications during real-time event monitoring.

The current disclosure is directed to a mobile environment for the transportation of hamsters, other small rodents, or small animals kept as pets. This mobile environment allows the user to easily carry the pet hamster on the go. This mobile environment is based on the idea of stacking multiple areas for the hamster to interact. The bottom portion serves as the hideout for the hamster, providing shade, a place to tunnel into bedding, and a place to have food that is easily accessible. Above the “hide-away” portion is the exercise wheel. This wheel sits horizontally and spins freely, providing an easily accessible form of exercise for the hamster. Lastly, the funneling form on the top of the mobile environment provides a means to attach a water bottle for hydration on the go.

The current disclosure is directed to a carrier for an exercise ball for rodents and other small animals that are kept as pets. This plastic carrier allows the carrying and setting up of stationary, 360 degree, or omnidirectional spin of the exercise ball within a compact ring form factor. The carrier is intended for recreational use in the home, in backyards, or in pet friendly parks.

Suspension assembly (100) for exercising and training animals, and especially canines using a suspended tug toy (200). Assembly (100) comprises an upper member (110) and a plurality of legs (120, 130, 140, 150) extending therefrom. Each of the plurality of legs is collapsible. Assembly (100) comprises one or more guide (160) for an associated tether line (300) for suspending tug toy (200). Guide (160) is connected relative to upper member (110) and defines an aperture (162) for receiving tether line (300). When assembly (100) is installed on a surface (400), legs (120, 130, 140, 150) engage with the surface via an associated pivotable foot (122, 132, 142, 152) and elevate upper member (110) and guide (160) from surface (400). Guides (170) for tether line (300) are connected relative to leg (120) and define an aperture (172) for receiving tether line (300).

Implementations described and claimed herein provide systems, apparatuses, and methods for exercising and entertaining a pet. In one implementation, a pet exercise and entertainment device includes a launch funnel for launching projectiles for a pet to retrieve. The launch funnel has a feeder and a chute. The feeder is configured to receive a projectile and transport the projectile to an intake end of the chute. A sensor is configured to sense the projectile in the intake end of the chute and to command one or more motors to power up in response to sensing the projectile. An actuator is configured to release the projectile from the intake end of the chute into the launch end of the chute after a pre-determined time has elapsed. One or more wheels, rotated by the one or more motors, are configured to launch the projectile from the launch end of the chute.

A treadmill may include two separate left and right belts rotating around two sets of rollers, four legs having an adjustable height via air suspension to customize an inclination of the treadmill, a thermoelectric assembly, a fragrance assembly having a rotating fragrance cartridge to emit various smells toward a user of the treadmill, a display on which exercise programs are played, and an attachment module having a dispensing tray on which treats are dispensed. A handle of the treadmill may have a sensor to sense a height and front-rear position, and a belt divider provided between the left and right belts may have position or proximity sensors to sense a left-right position. An inclination of the treadmill may be automatically adjusted according to positions detected by the sensors, and the fragrance assembly, attachment module, and inclination may be automatically operated in accordance with an exercise program played on the display.

A small animal habitat and a method for coupling an exercise wheel assembly to a small animal habitat. The small animal habitat includes a primary habitat portion, the primary habitat portion having a bottom portion, a central portion, and a top portion. The small animal habitat also includes an external hide structure coupled to the top portion of the primary habitat portion. An exercise wheel assembly is also provided, wherein the exercise wheel assembly is coupled to, and suspended from, the external hide structure. Additionally, a portion of the exercise wheel extends outside of the external hide structure.

A device is provided for studying the ability of at least one mouse to find its bearings in a maze, the device including a plurality of houses distributed around a central agora and in which at least one stimulator allows the at least one mouse to carry out certain activities and/or satisfy certain primary needs. Each house further includes at least one sensor for measuring the activity of the mouse in the house, and more particularly its use of the at least one stimulator. Finally, a sensor makes it possible to detect and measure the movements of each mouse in the device. Quantitative parameters originating from these measurements thus make it possible to highlight the quality of the geographical memory of the at least one mouse.