RU2001135383A - A method for detecting optical and optoelectronic objects and a device for detecting optical and optoelectronic objects - Google Patents

Claims (3)

1. A method for detecting optical and optoelectronic objects based on sensing a controlled volume of space with pulsed or continuous radiation with a spectral composition corresponding to the working spectrum of the detected means, encoding the probe radiation by amplitude manipulation, receiving the reflected radiation in the same spectrum, converting the reflected signals into visible for the operator’s image of the located volume of space, the selection by the operator of images of signals reflected from optical and ptoelectronic means according to the tiring effect of the flicker frequency corresponding to the frequency of the amplitude manipulation of the probe signal, characterized in that the probe signal reflected from the object is produced from the direction exactly matching the center of the probe probe radiation pattern. 2. A device for detecting optical and optoelectronic devices located in the near field, comprising a television camera with a lens connected to a monitor, a laser or other collimated light source, the input of which is connected to the second output of the television camera through a modulator and frequency divider f _k / n, characterized in that a semitransparent mirror and a radiation absorber are introduced into it, for example, a high-density neutral filter, a television camera and a laser are installed so that their optical axes are directly angle, and at the intersection of the optical axes of the television camera and the laser at an angle of 45 ° to the optical axis of the laser, a translucent mirror is installed, with the reflective coating of the translucent mirror facing the probed volume of space, the energy absorber is parallel to the translucent mirror in the center of the laser optical axis, without overlapping aperture of the lens of a television camera. 3. The device according to claim 2, in which there is no energy absorber, and instead of a translucent mirror, a glass plane parallel plate is installed in the same position, an opaque mirror coating is applied to the center of the end face of the plate facing the probing volume of space, covering the laser radiation aperture.