The application is directed to a locking adjustment assembly for an optical aiming device. The locking adjustment assembly is usable across different optical platforms regardless of the focal length of a particular optical platform. The locking adjustment assembly is operationally configured to be reset to a zero position. The locking adjustment assembly may also provide an automatic lock at a zero position.

The invention discloses a selectable offset image wedge assembly and various methods for making and for use with any optical system having a circular lens and an objective, comprising a housing with a rear-facing end that mounts onto the objective and a forward-facing end with a circular wedge lens mounted therein that is coaxially aligned with the circular lens of the optical system, wherein, the wedge is adjustable to any predetermined clocking position after detachment from the optical system, allowing quick and repeated reattachment to the optical system to an approximately exact vertical orientation of a first image produced by the wedge lens and a second image produced by the circular lens of the optical system.

A digital booster for an optical system includes an image acquisition unit. The image acquisition unit is configured to acquire an image frame from a non-magnified optic. The image frame includes an aiming reticle imposed by the non-magnified optic. The digital booster includes a display and a processor. The processor is configured to locate the aiming reticle on the image frame, select a sub-frame of the image frame with an aspect ratio that is centered on the aiming reticle of the image frame, perform image inversion and rescaling of the sub-frame, and transmit the sub-frame to the display.

Aiming systems are provided for use with a particle projection device. Such aiming systems may have a housing mountable to the particle projection device for movement therewith, a window defining a field of view when in a first orientation and a second field of view when in a second orientation. A first reticle image is visible in the window when the housing and particle projection device are at the first orientation with the first reticle image representative of a projection path of the particles in the first field of view. A second reticle image is visible in the window when the housing and particle projection device are at the second orientation with the second reticle image being representative of a projection path of the particles in the second field of view.

Aiming systems are provided for use with a particle projection device. Such aiming systems may have a housing mountable to the particle projection device for movement therewith, a window defining a field of view when in a first orientation and a second field of view when in a second orientation. A first reticle image is visible in the window when the housing and particle projection device are at the first orientation with the first reticle image representative of a projection path of the particles in the first field of view. A second reticle image is visible in the window when the housing and particle projection device are at the second orientation with the second reticle image being representative of a projection path of the particles in the second field of view.

A modular display assembly for riflescopes and related methods are provided. In one example, a modular display assembly includes a housing, a control module, and a reflective element. The control module can be operably coupled to the housing and include a substrate and display. The display can be coupled to the substrate and configured to emit light onto the reflective element. At least a portion of the housing is configured to be removably inserted into the riflescope. The modular display assembly can include a user interface that receives user input. The user input can vary information displayed on the display and reflected from the reflective element. One or more alignment pins can engage the substrate and, when rotated, shift the position of the display relative to the reflective element.

In a visual target acquisition scope system for an adjustable connection is provided between a unity magnification scope producing 1× magnification image viewed by one eye of the user and a photographic lens/viewfinder of a photographic camera viewed by another eye of the user. According to the system, while the user is looking at an object through the unity magnification scope with one eye and looking at the object through the photographic camera lens with the second eye, the target visible with the first eye is also visible with the second eye.

In a visual target acquisition scope system for an adjustable connection is provided between a unity magnification scope producing 1× magnification image viewed by one eye of the user and a photographic lens/viewfinder of a photographic camera viewed by another eye of the user. According to the system, while the user is looking at an object through the unity magnification scope with one eye and looking at the object through the photographic camera lens with the second eye, the target visible with the first eye is also visible with the second eye.

A holographic sporting/combat optic may be mounted to weapon. The holographic sporting/combat optic includes a laser diode, a holographic recording element and one or more optical components arranged in a housing. In response to a light beam incident thereon, the holographic recording element projects a composite, multidimensional reticle image into the optical viewing window. Of note, the holographic recording element has two or more reticle elements recorded thereon which form the composite reticle image. Each of the two or more reticle elements is captured at a different distance from the weapon during different exposures of the holographic recording element.

A holographic sporting/combat optic may be mounted to weapon. The holographic sporting/combat optic includes a laser diode, a holographic recording element and one or more optical components arranged in a housing. In response to a light beam incident thereon, the holographic recording element projects a composite, multidimensional reticle image into the optical viewing window. Of note, the holographic recording element has two or more reticle elements recorded thereon which form the composite reticle image. Each of the two or more reticle elements is captured at a different distance from the weapon during different exposures of the holographic recording element.