Example systems, devices, and methods related to an automated target system are provided. In this regard, a target pod device, that may be installed in a target base is provided. The target pod device may include a hinge, a target paddle, a rotary actuator, a sensor, and a processor. The target paddle may be operably coupled to the hinge and the rotary actuator may be operably coupled to the target paddle. The rotary actuator may be configured to rotate the target paddle to a deployed position or a retracted position. The sensor may detect that the target paddle has been moved toward the retracted position. The processor may be configured to transmit a signal to the rotary actuator to cause the rotary actuator to rotate the target paddle, and determine whether the target paddle has been moved toward the retracted position by a projectile.

Example systems, devices, and methods related to an automated target system are provided. In this regard, a target pod device, that may be installed in a target base is provided. The target pod device may include a hinge, a target paddle, a rotary actuator, a sensor, and a processor. The target paddle may be operably coupled to the hinge and the rotary actuator may be operably coupled to the target paddle. The rotary actuator may be configured to rotate the target paddle to a deployed position or a retracted position. The sensor may detect that the target paddle has been moved toward the retracted position. The processor may be configured to transmit a signal to the rotary actuator to cause the rotary actuator to rotate the target paddle, and determine whether the target paddle has been moved toward the retracted position by a projectile.

In a target-shooting simulation system, a master control unit issues flight control instructions to a flight-capable drone to cause the drone to fly along a predetermined flight path and receives GPS coordinates transmitted by a control unit of the drone as the drone flies along the predetermined flight path. The master control unit additionally obtains GPS coordinates, orientation and motion information with respect to a replica firearm, detects actuation of a trigger of the replica firearm and, in response to detecting actuation of the trigger, determines, based on the GPS coordinates of the drone and the GPS coordinates, orientation and motion information with respect to the replica firearm, whether a trajectory of a theoretical shot fired by the replica firearm at time of the trigger actuation will intercept the drone as it flies along the predetermined flight path.

A portable dry fire practice shooting system includes a first base supporting a target. A second base is associated with the first base such that the distance between the first base and the second base can be selectively adjusted. The second base includes a portable electronic device retaining mechanism for holding a portable electronic device on the first base so as to align a camera of the portable electronic device with the target. A software application downloaded onto the portable electronic device utilizes the camera of the portable electronic device to detect light spots reflecting from the target.

A radar target simulator for simulating a radar target is disclosed. The radar target simulator comprises a display module and an input module via which a user of the radar target simulator is enabled to define a target to be simulated. The radar target simulator also comprises a processing module that is connected with the display module and the input module in a signal transmitting manner. The display module and the processing module together provide a graphical user interface for the user of the radar target simulator. The graphical user interface provides a two-dimensional representation of an at least two-dimensional space. The processing module receives at least one input signal from the input module based on an input of the user. The input of the user is associated with input coordinates in the two-dimensional representation. The processing module processes the at least one input signal, thereby generating a symbol of the target defined. The display module illustrates the symbol generated in the two-dimensional representation provided by the graphical user interface.

The invention relates to a reflector comprising a reflector cavity (110) having a front opening for receiving EMR into the reflector cavity (110) for subsequent reflection of the EMR by at least one reflector element (120) arranged within the reflector cavity (110), characterized in that the reflector further comprises a front cover (130) that has high EM R transmittance in at least parts of the EM spectrum, the front cover (130) being arranged to cover the front opening of the reflector cavity (110), and that the front cover (130) and front opening form a gastight seal (140) impermeable to gas to prevent transport of material into and out of the reflector cavity (110) through the front opening.

The invention relates to a reflector comprising a reflector cavity (110) having a front opening for receiving EMR into the reflector cavity (110) for subsequent reflection of the EMR by at least one reflector element (120) arranged within the reflector cavity (110), characterized in that the reflector further comprises a front cover (130) that has high EM R transmittance in at least parts of the EM spectrum, the front cover (130) being arranged to cover the front opening of the reflector cavity (110), and that the front cover (130) and front opening form a gastight seal (140) impermeable to gas to prevent transport of material into and out of the reflector cavity (110) through the front opening.

The present invention relates to a method 300 for facilitating simulation of a shot from a weapon, wherein the weapon is equipped with a laser device which works on the time-of-flight principle. The method comprises the step 310 of receiving an emitted coded laser pulse sequence from the weapon by a simulation device. The method further comprises the step 350 of transferring a returned coded pulse sequence which corresponds to the emitted coded laser pulse sequence back to the weapon by the simulation device. The simulation device is a range simulation device. The method further comprises the step of delaying 330 said transferring in relation to said receiving so that said delay is perceived by said weapon as a longer travel time of the emitted coded laser pulse sequence and the returned coded pulse sequence, respectively. The method further relates to a simulation device.

A chaff electronic countermeasure device that includes an antenna element positioned on a substrate and in electrical communication with an integrated circuit. The conductive antenna element includes a conductive composition of a conductive polymer and graphene sheets. The device absorbs from a radar source a first radio frequency having a first amplitude. In response to absorbing the first radio frequency, the device reradiates at least a portion of a second radio frequency having a second amplitude toward the radar source, which results in an increased radar cross section of the device as perceived by the radar source. The second amplitude is higher than the first amplitude. The device is configured to be dispersed from a mobile platform. The device is configured to reradiate at least a second radio frequency toward the radar source, thereby resulting in an increased radar cross section of the device as perceived by the radar source

A chaff electronic countermeasure device that includes an antenna element positioned on a substrate and in electrical communication with an integrated circuit. The conductive antenna element includes a conductive composition of a conductive polymer and graphene sheets. The device absorbs from a radar source a first radio frequency having a first amplitude. In response to absorbing the first radio frequency, the device reradiates at least a portion of a second radio frequency having a second amplitude toward the radar source, which results in an increased radar cross section of the device as perceived by the radar source. The second amplitude is higher than the first amplitude. The device is configured to be dispersed from a mobile platform. The device is configured to reradiate at least a second radio frequency toward the radar source, thereby resulting in an increased radar cross section of the device as perceived by the radar source