There is proposed a system for managing fire of snipers, including a central station (CS) and a plurality of N individual kits (IK), each operated by one sniper. Preferably, the IK includes: --a rifle, --an optical sight (OS) mounted on the rifle with a mechanism for correction of the OS, --equipmen
There is proposed a system for managing fire of snipers, including a central station (CS) and a plurality of N individual kits (IK), each operated by one sniper. Preferably, the IK includes: --a rifle, --an optical sight (OS) mounted on the rifle with a mechanism for correction of the OS, --equipment including devices activating the rifle's firing pin; --a laser target designator having an axis coinciding with the OS axis, satellite navigation receiver (SNR), video-camera, symbol generator, adding device summarizing output signals, readiness sensor installed on the rifle's trigger, command decoder; zoom-lens actuator; electronic switches controlling the zoom-lens actuator, laser rangefinder; commutator receiving output signals from the laser rangefinder and SNR, and radio-modem module (IK-RM) provided with a two-way communication with the CS furnished with certain devices specified therein. The system enhances the synchronousness and target hit accuracy, and is capable of counteraction to acoustic counter-sniper systems.
대표청구항▼
1. A system for managing fire of a plurality of sniper rifles adapted to be operated by users, said system comprising: a central station (CS) including means for verbal radio-communication with said users, said CS operatively producing CS output signals; and a plurality of N individual kits (IK), wh
1. A system for managing fire of a plurality of sniper rifles adapted to be operated by users, said system comprising: a central station (CS) including means for verbal radio-communication with said users, said CS operatively producing CS output signals; and a plurality of N individual kits (IK), wherein N is a positive integer number, each said IK comprises: a sniper rifle having a rifle firing-trigger mechanism including a firing pin;an optical sight (OS) mounted on said rifle, and having an axis of said OS, the OS includes a mechanism for input of corrections into said OS;a power supply source (PSS) operatively producing a feed voltage;equipment mounted on said rifle, including: a means for activating said firing pin (FPA);a laser target designator (LTD) having an axis coinciding with the axis of said OS, said LTD has a casing mechanically coupled with said mechanism for input of corrections into the OS, said LTD is capable to be corrected by said mechanism for input of corrections into the OS;a receiver module of satellite navigation (SNR) operatively producing SNR output signals;a video-camera (VC) operatively producing VC output signals;a digital symbol generator (DS) operatively producing DS output signals;an electronic video-mixer receiving and mixing said VC and DS output signals;a sniper readiness sensor installed on said trigger, said sniper readiness sensor is connected to and capable of activating said digital symbol generator;a video signal compression device (VCS) receiving output signals from said video mixer and operatively producing VCS output signals;a command decoder (DC1) operatively producing DC1 output signals;a zoom-lens actuator;a first electronic switch (ES1) receiving said DC1 output signals and controlling said zoom-lens actuator by applying an inverse voltage, being inverse to said feed voltage, to the zoom-lens actuator;a second electronic switch (ES2) receiving said DC1 output signals and controlling said FPA;a laser rangefinder (LR) operatively producing LR output signals;an electronic DPDT switch (COMM) switching said LR output signals and said SNR output signals, thereby operatively producing COMM output signals; andan IK radio-modem module (IK-RM) receiving said VCS output signals, said COMM output signals, and said CS output signals; said IK-RM transmits said CS output signals to said DC1 operatively decoding said CS output signals; said IK-RM transmits said VCS output signals and said COMM output signals to said CS. 2. The system according to claim 1, wherein said CS further comprising: a first switch (S1);a second switch (S2);a third switch (S3);a guided rectangular waveform voltage pulse generator (SPG) controlled by said S1, S2, and S3; said SPG operatively produces SPG output signals;at least one central station radio-modem (CS-RM) for communication with said IK-RM of each said IK; said CS-RM operatively produces CS-RM output signals;a guided matrix switch (GMC) receiving said SPG output signals and communicates said SPG output signals in any combination to the CS-RM; said at least one CS-RM is connected with said GMC;a weather station module (WS) capable of registering a temperature, pressure, humidity, and wind intensity and direction; said WS operatively produces WS output signals;a satellite navigation receiver module (SNR) operatively producing SNR output signals;N devices (VSDC) for decompression of digital video-signals; said VSDC receives said CS-RM output signals and decompresses thereof; said VSDC operatively produces VSDC output signals;a video-multiplexor receiving said VSDC output signals; said video-multiplexor operatively produces video-multiplexor output signals;a first video-monitor (VM1) receiving said video-multiplexor output signals for visual display of said VC output signals;a video-recorder receiving said video-multiplexor output signals;a guided electronic rotary switch (GSC1) receiving said CS-RM output signals, and operatively produces GSC1 output signals;a ballistic calculator module (BC) receiving said WS output signals, said SNR output signals, and said GSC1 output signals, controlling said GSC1, and operatively produces BC output signals; anda second video-monitor (VM2) receiving said BC output signals for visual display thereof. 3. The system according to claim 1 further comprising a mobile relay station capable of broadband digital communication. 4. The system according to claim 1, wherein said VC is represented by a thermal imagery camera furnished with a digital output, an auto focus, an auto diaphragm, and a guided zoom-lens. 5. A system for managing fire of a plurality of sniper rifles adapted to be operated by users, said system comprising: a central station (CS) including means for verbal radio-communication with said users;and a plurality of N individual kits (IK) wherein N is a positive integer number, each said IK is operated by one of the users; said CS transmits CS signals; each said IK comprises: a sniper rifle having a rifle firing-trigger mechanism including a firing pin;an optical sight (OS) mounted on said rifle, and having an axis of said OS; said OS includes a mechanism for input of corrections into the OS; said mechanism for input of corrections into the OS includes a first step-type micro-actuator for inputting horizontal corrections into the OS and a second step-type micro-actuator for inputting vertical corrections into the OS;a power supply source (PSS) operatively producing a feed voltage;equipment mounted on said rifle, including: a means for activating said firing pin (FPA);a laser target designator (LTD) having an axis coinciding with the axis of said OS, said LTD has a casing mechanically coupled with said mechanism for input of corrections into the OS, said LTD is capable to be corrected by said mechanism for input of corrections into the OS;a receiver module of satellite navigation (SNR) operatively producing SNR output signals;a video-camera (VC) operatively producing VC output signals;a digital symbol generator (DS) operatively producing DS output signals;an electronic video-mixer receiving and mixing said VC and DS output signals;a sniper readiness sensor installed on said trigger, said sniper readiness sensor is connected to and capable of activating said digital symbol generator;a video signal compression device (VCS) receiving output signals from said video mixer and operatively producing VCS output signals;a first command decoder (DC1) operatively producing DC1 output signals;a zoom-lens actuator;a first electronic switch (ES1) receiving said DC1 output signals and controlling said zoom-lens actuator, by applying an inverse voltage, being inverse to said feed voltage, to the zoom-lens actuator;a second electronic switch (ES2) receiving said DC1 output signals and controlling said FPA;a laser rangefinder (LR) operatively producing LR output signals;an electronic DPDT switch (COMM) switching said LR output signals and said SNR output signals, thereby operatively producing COMM output signals;a second command decoder (DC2) operatively producing DC2 output signals;a third electronic switch (ES3) receiving said DC2 output signals and controlling said first step-type micro-actuator;a fourth electronic switch (ES4) receiving said DC2 output signals and controlling said second step-type micro-actuator; andan IK radio-modem module (IK-RM) receiving said VCS output signals said COMM output signals, and said CS output signals; said IK-RM transmits said CS output signals, to said DC1 and to said DC2 operatively decoding said CS output signals; said IK-RM transmits said VCS output signals and said COMM output signals to said CS. 6. The system according to claim 5, wherein said CS further comprising: a first switch (S1);a second switch (S2);a third switch (S3);a guided rectangular waveform voltage pulse generator (SPG) controlled by said S1, S2, and S3; said SPG operatively produces SPG output signals;at least one central station radio-modems (CS-RM) for communication with said IK-RM of each said IK; said CS-RM operatively produces CS-RM output signals;a guided matrix switch (GMC) receiving said SPG output signals; said at least one CS-RM is connected with said GMC;a weather station module (WS) capable of registering a temperature, pressure, humidity, and wind intensity and direction; said WS operatively produces WS output signals;a satellite navigation receiver module (SNR) operatively producing SNR output signals;N devices (VSDC) for decompression of digital video-signals; said VSDC receives said CS-RM output signals and decompresses thereof; said VSDC operatively produces VSDC output signals;a video-multiplexor receiving said VSDC output signals; said video-multiplexor operatively produces video-multiplexor output signals;a first video-monitor (VM1) receiving said video-multiplexor output signals for visual display of said VC output signals;a video-recorder receiving said video-multiplexor output signals;a first guided electronic rotary switch (GSC1) receiving said CS-RM output signals, and operatively produces GSC1 output signals;a ballistic calculator module (BC) receiving said WS output signals, said SNR output signals, and said GSC1 output signals, and operatively produces BC output signals; anda second guided electronic rotary switch (GSC2) receiving said BC output signals, and controlling said GSC1 and communicating with said at least one CS-RM; anda second video-monitor (VM2) receiving said BC output signals for visual display thereof. 7. The system according to claim 5 further comprising a mobile relay station capable of broadband digital communication. 8. The system according to claim 5, wherein said VC is represented by a thermal imagery camera furnished with a digital output, an auto focus, an auto diaphragm, and a guided zoom-lens.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (8)
White John R. (Oak Ridge TN) Walker Kenneth L. (Clinton TN) Coughlan Joel B. (Oak Ridge TN) Upton R. Glen (Oak Ridge TN) Farnstrom Kenneth A. (Oak Ridge TN) Harvey Howard W. (Oak Ridge TN), All terrain mobile robot.
Engler Richard D. (3001 Hewitt Ave. Silver Spring MD 20906) Hudak David M. (14520 Lock Dr. Centreville VA 22020) McKean Andrew (307 Meadow Hall Dr. Rockville MD 20851), Weapon control and firing system.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.