Embodiments of a controlled odor emission system and device include an odor presentation port tube and an odor tray securely retained against a platform, a valve housing securable to the platform adjacent the tray, a valve secured within the valve housing and an actuator for moving the valve. By controlling movement of the valve, precise amounts of an odor can be dispensed under programmatic control for training animals. Further, a system incorporating a central control unit and a reward dispenser in communication with an odor emission device to facilitate animal training.

A cat teaser includes a base, pogo pins of a power supply, a main body shell, a fixed frame, a main control circuit board, a main body motor, a laser emitting module, an auxiliary motor that swings up and down, and a conductive disc. The pogo pins of the power supply are in contact with the conductive disc. The conductive disc supplies power to the main control circuit board. The main control circuit board controls the main body motor, the laser emitting module and the auxiliary motor that swings up and down.

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 system for training animals includes a hand-held device and a remote device, where the remote device applies a stimulus when a user presses a button or trigger on the hand-held device. The amount of pressure applied is measured by a pressure sensitive transducer and transformed into proportional transducer signals. These transducer signals are transmitted to the remote device, which then applies a stimulus to an animal being trained. The amplitude of the applied stimulus corresponds to the amplitude of the transducer signals; a trainer can thus precisely control the intensity of the stimulus by applying and relieving pressure on the button. The type of stimulus applied is controlled based on the position of a rotary switch on the hand-held device. Sensor data generated by specialized sensors in the remote device may be transmitted to the hand-held device to provide the user with sensory feedback.

A system for training animals includes a hand-held device and a remote device, where the remote device applies a stimulus when a user presses a button or trigger on the hand-held device. The amount of pressure applied is measured by a pressure sensitive transducer and transformed into proportional transducer signals. These transducer signals are transmitted to the remote device, which then applies a stimulus to an animal being trained. The amplitude of the applied stimulus corresponds to the amplitude of the transducer signals; a trainer can thus precisely control the intensity of the stimulus by applying and relieving pressure on the button. The type of stimulus applied is controlled based on the position of a rotary switch on the hand-held device. Sensor data generated by specialized sensors in the remote device may be transmitted to the hand-held device to provide the user with sensory feedback.

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 system comprising a first transmitter for transmitting a first signal at a first frequency and a second transmitter for transmitting a second signal at a second frequency. The system includes a collar unit comprising a filter for receiving a combined signal, wherein the combined signal comprises the first signal and the second signal, wherein the filter includes a first antenna for detecting the first signal and a second antenna for detecting the second signal. The collar unit includes at least one signal analysis component configured to analyze the first signal and the second signal. The collar unit is configured to instruct a stimulus delivery unit to deliver a stimulus to the animal when the first signal voltage falls below a first value and the second signal voltage exceeds a second value.

One variation of a method for autonomously training an animal includes: loading an autonomous training protocol for the animal onto a training apparatus configured to dispense units of a primary reinforcer responsive to behaviors performed by the animal; during an autonomous training session for the animal, accessing a video feed of a working field near the training apparatus, detecting the animal in the video feed, and executing the first autonomous training protocol; calculating a training score for the autonomous training session based on behaviors performed by the animal during the autonomous training session; selecting a manual training protocol, from a set of manual training protocols, based on the training score; generating a prompt to execute the first manual training protocol with the animal during a first manual training session; and transmitting the prompt to a user associated with the animal.

One variation of a method for autonomously training an animal includes: loading an autonomous training protocol for the animal onto a training apparatus configured to dispense units of a primary reinforcer responsive to behaviors performed by the animal; during an autonomous training session for the animal, accessing a video feed of a working field near the training apparatus, detecting the animal in the video feed, and executing the first autonomous training protocol; calculating a training score for the autonomous training session based on behaviors performed by the animal during the autonomous training session; selecting a manual training protocol, from a set of manual training protocols, based on the training score; generating a prompt to execute the first manual training protocol with the animal during a first manual training session; and transmitting the prompt to a user associated with the animal.

A wearable animal training apparatus may include a casing having an inner wall, and an outer wall. The apparatus may include a flexible first wire disposed against a proximal surface between the inner wall and the outer wall of the casing, and a flexible second wire disposed against a distal surface between the inner wall and the outer wall of the casing. The apparatus may also include a power source having a positive terminal and a negative terminal, and an electric motor. The first wire may be connected to the positive terminal of the power source, and the second wire may be connected to the negative terminal of the power source.