Show metadata Hide metadata

(19)

(11)

2 791 568

(13)

(51)

IPC

G01S17/02(2006-01-01)

(21) (22)

Application

2022117222, 2022-06-24

(24)

Start date

2022-06-24

(22)

Actual filing date

2022-06-24

(45)

Published

2023-03-10

(72)

Inventor

Kuleshov Pavel EvgenevichPopelo Vladimir Dmitrievich

(73)

Holder

Federalnoe Gosudarstvennoe Kazennoe Voennoe Obrazovatelnoe Uchrezhdenie Vysshego Obrazovaniya Uchebno-Nauchnyj Tsentr Voenno-Vozdushnykh Sil Akademiya Imeni Professora N.E. Zhukovskogo I Yu.A. Gagarina" Voronezh) Ministerstva Oborony Rossijskoj Federatsii

METHOD FOR SIMULATION OF SPATIAL SEQUENCE OF REFLECTING SURFACES OF OPTO-ELECTRONIC EQUIPMENT Russian patent published in 2023 - IPC G01S17/02

Abstract RU 2791568 C1

FIELD: optoelectronic technology, optoelectronic countermeasure systems.

SUBSTANCE: a method for simulating a spatial sequence of reflective surfaces of an optical-electronic equipment (OEE) is as follows. A false optical target (FOT) is installed in the OEE search sector. N optical corner reflectors (OCR) of tetrahedral type are included in the FOR with right angles at the top. The height of the n-th OCR is greater than the height of the n + 1-th OCR by a length that provides a delay of laser location radiation (LLR), similar to the delay of the LLR between the n-th and n+1-th reflective surfaces of the simulated OEE, where , and the reflecting surfaces of the n-th and n+1-th OCR have the values of the generalized reflection coefficients equal to the values of the reflection coefficients of the corresponding n-th and n+1-th reflective surfaces of the simulated OEE. N OCRs are installed so that they have a common line of spatial bisectors of the trihedral angles of their vertices, a common input plane and parallel identical edges. LLR is reflected by each FOT OCR and the spatial sequence of reflective surfaces of the OEE is imitated.

EFFECT: an increase in the efficiency of the FOT.

1 cl, 2 dwg

Similar patents RU2791568C1

Title	Year	Author	Number
METHOD FOR IMITATING REFLECTION SURFACES OF OPTOELECTRONIC DEVICE	2023	Kuleshov Pavel Evgenevich Popelo Vladimir Dmitrievich	RU2813678C1
METHOD OF SIMULATION OF AN OPTOELECTRONIC DEVICE	2022	Kuleshov Pavel Evgenevich Popelo Vladimir Dmitrievich	RU2796811C1
METHOD FOR IMAGING AN OPTOELECTRONIC DEVICE	2018	Koziratskij Yurij Leontevich Glushkov Aleksandr Nikolaevich Kuleshov Pavel Evgenevich Alabovskij Andrej Vladimirovich Lobov Vladimir Anatolevich Chernyshov Pavel Valerevich Nagalin Danil Aleksandrovich Mamadzhanyan Ervand Aleksandrovich	RU2712940C1
METHOD FOR INTERFERENCE PROTECTION OF OPTOELECTRONIC TOOLS FROM POWERFUL LASER COMPLEXES	2021	Kuleshov Pavel Evgenevich Koziratskij Yurij Leontevich	RU2777049C1
FALSE OPTICAL TARGET GENERATING METHOD	2018	Koziratskij Yurij Leontevich Glushkov Aleksandr Nikolaevich Kuleshov Pavel Evgenevich Drobyshevskij Nikolaj Vasilevich Prokhorov Dmitrij Vladimirovich	RU2698466C1
METHOD FOR PROTECTING OPTOELECTRONIC APPARATUS FROM A POWERFUL LASER COMPLEX	2021	Kuleshov Pavel Evgenevich Popelo Vladimir Dmitrievich Ilinov Evgenij Vladimirovich Linnik Egor Alekseevich	RU2772245C1
METHOD FOR FORMING A COMBINED DECOY OPTICAL TARGET	2020	Kuleshov Pavel Evgenevich Popelo Vladimir Dmitrievich Alabovskij Andrej Vladimirovich Pavlova Tatyana Nikolaevna	RU2759170C1
METHOD FOR PROTECTING OPTO-ELECTRONIC FACILITIES FROM LASER EXPOSURE COMPLEXES USING FALSE OPTICAL TARGETS	2022	Kuleshov Pavel Evgenevich Popelo Vladimir Dmitrievich Kuleshova Inessa Valerievna	RU2784482C1
METHOD OF IDENTIFYING LOCATION OPTICAL SIGNALS	2017	Glushkov Aleksandr Nikolaevich Kuleshov Pavel Evgenevich Drobyshevskij Nikolaj Vasilevich	RU2698514C2
METHOD OF DETERMINING SPATIAL ORIENTATION OF OBJECT USING OPTOELECTRONIC SYSTEM AND CORNER REFLECTOR	2014	Matveev Mikhail Nikolaevich	RU2556282C1

RU 2 791 568 C1

Authors

Kuleshov Pavel Evgenevich

Popelo Vladimir Dmitrievich

Dates

2023-03-10—Published

2022-06-24—Filed