A cam assembly for an archery bow is provided. The cam assembly includes a cam body and an anchoring lug. The cam body defines a pivot axis and a groove circumferentially routed at least partially around the pivot axis. The anchoring lug is coupled with the cam body and includes a force sensor. The anchoring lug is offset from the pivot axis and is configured to facilitate attachment of a bow cord thereto. The force sensor is configured to facilitate detection of a tension on the bow cord as a function of a force imparted to the force sensor from the bow cord. An archery bow is also provided.

Archery bow overdraw or under draw sensing system is comprised of four main parts: (1) a force sensing resistor (FSR) on the bow limb near a cam between the draw stop on the cam and the bow limb where the draw stop rests on the bow limb at full draw or on the grip; (2) at least one LED light mounted on or adjacent to the bow sight; (3) a controller for reading the force of the draw stop on the force sensing resister (FSR) and controlling the on/off function of the LED; and (4); and a power source for the system.

A method for monitoring operation of an archery bow includes attaching an apparatus to a bow cord. The apparatus includes a processor, a monitoring device electrically coupled with the processor, a wireless communication module electrically coupled with the processor, and a power supply electrically coupled with each of the processor and the wireless communication module. The method further includes detecting, by the monitoring device, a tension of the bow cord. The method also includes generating, by the processor and based upon the detected tension of the bow cord, data concerning tension of the bow cord. The method further includes wirelessly transmitting, by the wireless communication module, the data to a remote computing device. The method also includes receiving, by the remote computing device, the data. The method also includes presenting, by the remote computing device and based upon the data, information to a user reflecting the detected tension.

An interactive device for improving accuracy in archery and similar endeavors is provided. In some embodiments, a deformable device is provided that is operable to communicate with an archery bow and receive force during use of the bow. The deformable device is operable to deflect in a manner that produces an audible and tactile signal to a user. The signal may correspond to an appropriate amount of string tension or draw, for example.

An arrow rest assembly and method are described herein. The arrow rest assembly, in an embodiment, includes a bow engagement portion configured to be mounted to an archery bow and an accessory support coupled to the bow engagement portion. The accessory support is configured to support an arrow rest accessory that has an arrow holder. The assembly includes an adjuster support, a driver engaged with the adjuster support, and a biaser coupled to the driver. The biaser is configured to generate a biasing force acting on the driver.

A cam assembly for an archery bow is provided. The cam assembly includes a cam body and an anchoring lug. The cam body defines a pivot axis and a groove circumferentially routed at least partially around the pivot axis. The anchoring lug is coupled with the cam body and includes a force sensor. The anchoring lug is offset from the pivot axis and is configured to facilitate attachment of a bow cord thereto. The force sensor is configured to facilitate detection of a tension on the bow cord as a function of a force imparted to the force sensor from the bow cord. An archery bow is also provided.

An interactive device for improving accuracy in archery and similar endeavors is provided. In some embodiments, a deformable device is provided that is operable to communicate with an archery bow and receive force during use of the bow. The deformable device is operable to deflect in a manner that produces an audible and tactile signal to a user. The signal may correspond to an appropriate amount of string tension or draw, for example.

A method for diagnosing an abnormality of an archery bow is provided. The method includes detecting, by one or more controllers, an operating condition of the archery bow from at least one onboard monitoring device of the archery bow, and comparing, by the one or more controllers, the operating condition to a threshold operating condition. The method further includes identifying, by the one or more controllers, an abnormal condition based on the comparing of the operating condition to the threshold operating condition, and presenting, by the one or more controllers, the abnormal condition to a user. A non-transitory computer readable medium for performing the method is also provided.

An interactive device for improving accuracy in archery and similar endeavors is provided. In some embodiments, a deformable device is provided that is operable to communicate with an archery bow and receive force during use of the bow. The deformable device is operable to deflect in a manner that produces an audible and tactile signal to a user. The signal may correspond to an appropriate amount of string tension or draw, for example.

An arrow rest assembly and method are described herein. The arrow rest assembly, in an embodiment, includes a bow engagement portion configured to be mounted to an archery bow and an accessory support coupled to the bow engagement portion. The accessory support is configured to support an arrow rest accessory that has an arrow holder. The assembly includes an adjuster support, a driver engaged with the adjuster support, and a biaser coupled to the driver. The biaser is configured to generate a biasing force acting on the driver.