A metalized textile containing a textile, a first metalized layer at least partially covering a first side of the textile, and a second metalized layer at least partially covering the first metalized layer. The first metalized layer contains a metal and the second metalized layer contains a plurality of metallic particles, binder, and a pigment. The present invention is primarily directed towards metalized textiles for use in multispectral camouflage products.

The present invention relates to camouflage pattern printed fabrics and coatings for objects such as clothing, surfaces, buildings, ground vehicles, aircraft and watercraft and superstructures, wherein the patterns are created to mimic a view from underwater towards the surface so that the camouflage pattern matches what an aquatic animal would see from underwater.

Subwavelength conducting particles can be arranged on conducting surfaces to provide arbitrary thermal emissivity spectra. For example, a thermal emissivity spectrum can be tailored to suppress a thermal signature of an object without sacrificing radiative cooling efficiency.

Subwavelength conducting particles can be arranged on conducting surfaces to provide arbitrary thermal emissivity spectra. For example, a thermal emissivity spectrum can be tailored to suppress a thermal signature of an object without sacrificing radiative cooling efficiency.

An apparatus includes at least one transmitter configured to transmit wireless signals that create different localized heating in different portions of a scene. The different localized heating in the different portions of the scene is based on different moisture or liquid content within objects in the scene. The apparatus also includes at least one controller configured to control the at least one transmitter in order to control the different localized heating in the different portions of the scene and to create a desired thermal radiation pattern in the scene. The desired thermal radiation pattern in the scene may include a camouflage pattern that increases clutter in an infrared image, at least one temporary infrared marker, or at least one false shape in an infrared image. The desired thermal radiation pattern could reduce a contrast between a cold infrared background in the scene and one or more targets in the scene.

An apparatus includes at least one transmitter configured to transmit wireless signals that create different localized heating in different portions of a scene. The different localized heating in the different portions of the scene is based on different moisture or liquid content within objects in the scene. The apparatus also includes at least one controller configured to control the at least one transmitter in order to control the different localized heating in the different portions of the scene and to create a desired thermal radiation pattern in the scene. The desired thermal radiation pattern in the scene may include a camouflage pattern that increases clutter in an infrared image, at least one temporary infrared marker, or at least one false shape in an infrared image. The desired thermal radiation pattern could reduce a contrast between a cold infrared background in the scene and one or more targets in the scene.

Rather than trying to call a gobbler and waiting for the gobbler to approach, the hunter instead attempts to seek a gobbler while holding a decoy. As the hunter comes within sight of the gobbler, he can slowly move (e.g., tilt and/or rotate) the decoy so that its fan moves in a manner that mimics movement of a real turkey. It has been found that the gobbler will often fixate on the decoy failing to notice the hunter even when he is not well camouflaged. In fact, the gobbler will often approach the decoy in an aggressive manner making it much less wary than in a typical hunt where a hunter is attempting to make calls that imitate a hen. When the hunter feels that the gobbler is fixated on the decoy, he can couple the decoy to his weapon thereby freeing both of his hands for operating his weapon.

Rather than trying to call a gobbler and waiting for the gobbler to approach, the hunter instead attempts to seek a gobbler while holding a decoy. As the hunter comes within sight of the gobbler, he can slowly move (e.g., tilt and/or rotate) the decoy so that its fan moves in a manner that mimics movement of a real turkey. It has been found that the gobbler will often fixate on the decoy failing to notice the hunter even when he is not well camouflaged. In fact, the gobbler will often approach the decoy in an aggressive manner making it much less wary than in a typical hunt where a hunter is attempting to make calls that imitate a hen. When the hunter feels that the gobbler is fixated on the decoy, he can couple the decoy to his weapon thereby freeing both of his hands for operating his weapon.

Methods and systems fort operating one or more light sources to project adversarial patterns generated to disorient a machine learning based detection system, comprising generating one or more adversarial patterns configured to disorient the machine learning based detection system and operating one or more light sources configured to project one or more of the adversarial pattern(s) in association with the targeted object in order to disorient the machine learning based detection system.