A system for determining the muzzle velocity of a firearm includes a firearm having a barrel and a gas block. A first sensor is arranged at a gas block and is configured to determine a change in pressure within the gas block. A second sensor is positioned at an end of the barrel of the firearm for detecting a pressure wave produced by a projectile fired by the firearm. A control unit is in communication with the first sensor and the second sensor and is configured to determine a velocity of the projectile based on information received from the first sensor and the second sensor.

Automated systems and methods for collecting environmental data along a ballistic trajectory are disclosed. The systems and methods may comprise automatically estimating the ballistic trajectory of a projectile. The systems and methods may comprise automatically converting the ballistic trajectory into a ballistic flight path comprising a plurality of coordinates. The systems and methods may comprise electronically communicating the ballistic flight path to a guidance system of an Unmanned Aerial Vehicle (UAV). The guidance system may be configured to cause the UAV to navigate along the ballistic flight path. The systems and methods may comprise automatically collecting environmental data along the ballistic flight path.

A system for predicting exterior ballistics has first and second bullet detectors operable to detect the passage of a bullet, the first and second bullet detectors being spaced apart by a selected detector spacing distance, the first and second bullet detector each being connected to a common time signal facility that generates a time signal, the first bullet detector being operable to generate a first time of passage based on the time signal, the second bullet detector being operable to generate a second time of passage based on the time signal, the first bullet detector being operable to measure a first bullet velocity, a controller in communication with the first and second bullet detectors, and the controller operable based on the difference between the first time and the second time, and based on the first bullet velocity to calculate a ballistic characteristic for the bullet.

A method of determining an uncertainty estimate of an estimated velocity of an object includes, determining the uncertainty with respect to a first estimated coefficient and a second estimated coefficient of the velocity profile equation of the object. The first estimated coefficient being assigned to a first spatial dimension of the estimated velocity and the second estimated coefficient being assigned to a second spatial dimension of the estimated velocity. The velocity profile equation represents the estimated velocity in dependence of the first estimated coefficient and the second estimated coefficient. The method also includes determining the uncertainty with respect to an angular velocity of the object, a first coordinate of the object in the second spatial dimension, and a second coordinate of the object in the first spatial dimension.

A system for predicting exterior ballistics has first and second bullet detectors operable to detect the passage of a bullet, the first and second bullet detectors being spaced apart by a selected detector spacing distance, the first and second bullet detector each being connected to a common time signal facility that generates a time signal, the first bullet detector being operable to generate a first time of passage based on the time signal, the second bullet detector being operable to generate a second time of passage based on the time signal, the first bullet detector being operable to measure a first bullet velocity, a controller in communication with the first and second bullet detectors, and the controller operable based on the difference between the first time and the second time, and based on the first bullet velocity to calculate a ballistic characteristic for the bullet.

An apparatus for measuring velocities of projectiles launched from firearms is disclosed. The apparatus includes a stationary clamp arm and a movable clamp arm works in concert with the stationary clamp arm for clamping the apparatus to a firearm. A thumb screw is employed to secure the movable clamp arm and the stationary clamp arm to the firearm. A sensor module, which is integrated to the stationary clamp, includes a first and second sensor coils, a first magnet adjacent to the first sensor coil, and a second magnet adjacent to the second sensor coil.

A system for measuring rigidity characteristics that measures a CT value of a golf club head based on an acceleration occurring in an impactor when the impactor is caused to strike the golf club head. Correlation data is calculated by measuring a representative CT value of the golf club head, which is calculated based on CT values measured multiple times by changing the impact velocity of the impactor, and a test velocity CT value, which is a CT value when the impact velocity is set to a predetermined test velocity, for each of a plurality of the golf club heads of an identical model. A rigidity characteristic value measuring device measures the test velocity CT value for another golf club head of the model. A computer estimates the representative CT value of the other golf club head based on the test velocity CT value and the correlation data.

The present disclosure relates to a system for detecting characteristics of a moving element. The system may include a tubular housing having a tubular first portion having a first end and a second end, with the first end forming an input port and the second end forming an output port. A source of wireless electromagnetic energy projects a wireless electromagnetic energy signal, travelling in a first direction, into the input port and through an interior area defined by the tubular first portion. A signal processing subsystem detects at least one characteristic of the signal after the signal is reflected back to the first end after having interacted with the element as the element moves past the output port of the housing.

A method of determining an uncertainty estimate of an estimated velocity of an object includes, determining the uncertainty with respect to a first estimated coefficient and a second estimated coefficient of the velocity profile equation of the object. The first estimated coefficient being assigned to a first spatial dimension of the estimated velocity and the second estimated coefficient being assigned to a second spatial dimension of the estimated velocity. The velocity profile equation represents the estimated velocity in dependence of the first estimated coefficient and the second estimated coefficient. The method also includes determining the uncertainty with respect to an angular velocity of the object, a first coordinate of the object in the second spatial dimension, and a second coordinate of the object in the first spatial dimension.

A compound bow includes a riser, an upper limb, and a lower limb, the upper limb and lower limbs coupled to the riser. The compound bow may include a draw sensor. The compound bow includes a performance module coupled to the riser, the performance module operatively coupled to the draw sensor. A compound bow may include an arrow chronometer assembly. A method may include determining draw weight or length based on measurements of the draw sensor. A method may include determining arrow speed based on measurements of the arrow chronometer assembly.