Armored vehicles, weapon measurement system, and methods for determining barrel elevation of a gun, are provided. In one example, an armored vehicle includes a vehicle body portion and a gun having a barrel extending away from the vehicle body portion at a barrel elevation angle. A weapon measurement system includes a reference light generator arrangement configured to generate a reference light at a single wavelength or within a narrow wavelength band and to diffuse the reference light, thereby defining a distributed reference light. An image sensor arrangement includes an image sensor and a filter. The filter is configured to substantially block light that is at a different wavelength than the distributed reference light while allowing the distributed reference light to pass through to the image sensor for determining the barrel elevation angle.

A method and apparatus for displaying a position of an impact point of a directed-energy weapon which has an effective beam optical system and an imaging optical system. An emission of primary radiation of the directed-energy weapon is triggered as an effective beam, and radiation exiting from an irradiated object is received by the imaging optical system and directed onto a camera of a screen. A beam bundle cross section of an effective beam is covered with a reflective optical auxiliary element, the effective beam or the auxiliary beam is triggered with the beam bundle cross section covered, and primary radiation of the effective beam or of the auxiliary beam which is reflected by the reflective optical auxiliary element is received by the imaging optical system and directed onto a spot of the camera as the impact point.

An imaging instrument for controlling a target designation makes it possible to visualise a target designation spot (SP) within a scene (SC), while using only one image sensor. To do this, a filter is arranged on the image sensor, in a restricted area (ZC) of same. The filter makes it possible to increase a contrast and a signal-to-noise ratio for an image of the target designation spot, when a misalignment (DP) is produced in order to bring the image of the target designation spot into the area of the filter.

This invention discloses a method for correcting the point of aim in riflescopes or other optical weapon sights. The point of aim is corrected by attaching one or more corrector wedge prisms in front of the riflescope. Each wedge prism shifts the point of aim by a predetermined amount such as 5 cm at 100 m or 10 cm at 100 m, etc. A shooter can zero-in his rifle by first firing a set of test shots to determine how far off the bullets hit from the desired point of impact. He then selects one or more wedge prisms supplied with the riflescope and attaches them to the front (objective side) of the riflescope. The wedge prisms shift the riflescope's point of aim and bring it in alignment with the rifle's point of impact.

The invention relates to a sighting device having an optical reversing system and a target mark as well as a ballistics computer for computing data that is relevant in terms of ballistics, the reversing system being adjustable mechanically and the target mark being adjustable electronically and at least one adjusting device being provided for adjusting the reversing system and the target mark.

The invention relates to a sighting device having an optical reversing system and a target mark as well as a ballistics computer for computing data that is relevant in terms of ballistics, the reversing system being adjustable mechanically and the target mark being adjustable electronically and at least one adjusting device being provided for adjusting the reversing system and the target mark.

The invention relates to a method (100) for monitoring the accuracy of the azimuthal orientation of a handheld optoelectronic measuring device to be determined (110) by means of an electronic magnetic compass, including an automatic ascertainment (120) of an estimated accuracy value by the measuring device based on measured data of the magnetic compass, characterized by a safety check (200), within the scope of which a probability that the estimated accuracy value meets a previously determined (140) accuracy criterion is automatically ascertained (220) by the measuring device, and the ascertained probability is provided (230) to a user as a return value. The invention also relates to a handheld optoelectronic measuring device including an electronic magnetic compass for carrying out the method according to the invention.

The invention relates to a method (100) for monitoring the accuracy of the azimuthal orientation of a handheld optoelectronic measuring device to be determined (110) by means of an electronic magnetic compass, including an automatic ascertainment (120) of an estimated accuracy value by the measuring device based on measured data of the magnetic compass, characterized by a safety check (200), within the scope of which a probability that the estimated accuracy value meets a previously determined (140) accuracy criterion is automatically ascertained (220) by the measuring device, and the ascertained probability is provided (230) to a user as a return value. The invention also relates to a handheld optoelectronic measuring device including an electronic magnetic compass for carrying out the method according to the invention.

An area denial system may be operationally placed with communication latency compensation. The area denial system may include a plurality of munitions, one or more sensor devices, and a command and control unit, networked together and having a command and control latency for communication between the command and control unit and the remainder of the area denial system. Latency compensation may include determining a first target position, determining a first predicted position area for the target using the command and control latency and the first target position, receiving an authorization to arm one or more of the munitions, determining a second target position, and determining that the second target position is outside a threshold distance from a first authorized munition of the one or more authorized munitions, and in response, de-authorizing the first authorized munition.

An area denial system may be operationally placed with communication latency compensation. The area denial system may include a plurality of munitions, one or more sensor devices, and a command and control unit, networked together and having a command and control latency for communication between the command and control unit and the remainder of the area denial system. Latency compensation may include determining a first target position, determining a first predicted position area for the target using the command and control latency and the first target position, receiving an authorization to arm one or more of the munitions, determining a second target position, and determining that the second target position is outside a threshold distance from a first authorized munition of the one or more authorized munitions, and in response, de-authorizing the first authorized munition.