KR101996610B1 - Potable electronic intelligence eqipment - Google Patents

Abstract

Provided are a portable electronic information apparatus and an operating method thereof. The portable electronic information apparatus comprises: an antenna unit which is portable and receives a signal from the outside; a signal processing unit which is portable and converts and processes the signal received through the antenna unit; and a coupling unit which couples the antenna unit with the signal processing unit. The antenna unit and the signal processing unit are coupled to or separated from each other by the coupling unit.

Description

[0001] Potable electronic intelligence eqipment [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for electronic support of an electronic warfare, and more particularly to an electronic intelligence apparatus for radar signal detection.

In today's battlefield environment, the number and types of radars used in various platforms are increasing and used in combination, so that the importance of electronic warfare equipment that receives, analyzes and identifies such signals is increasing day by day. However, it is difficult to mount the equipment that can completely analyze the characteristic parameters of the radar on all platforms because it may be limited by the cost and space. Therefore, (electronic warfare support) analysis.

In general, electronic warfare equipment collects electromagnetic waves radiated by a radar to detect the position of the radar, and if necessary, interferes with the operation of the radar by using an electromagnetic wave. Such electronic warfare apparatus receives the pulse signal information of the radar signal, the signal strength, the pulse intensity, the arrival time, etc., extracts the pulse train, analyzes the frequency of the pulse train, and derives the threat information to identify the radar platform And generates a radar signal corresponding thereto to paralyze or disable the function of the red radar. Such electronic warfare equipment consists largely of Electronic Support (ES) equipment that searches for radio waves and Electronic Attack (EA) equipment that interferes with radar detection.

Electronic warfare receivers belong to electronic support equipment, but depending on their mission, it is a receiver of various electronic warfare equipment such as radar warning receiver, self-protection jammer and electronic intelligence (ELINT) Collect, analyze and identify signals.

Meanwhile, ELINT equipment for collecting radar electromagnetic signals has been constructed in the form of a ground fixing facility for carrying out mission only in a specific area or a form for mounting in air vehicles, vehicles, ships and the like. Thus, conventional ELINT equipment is manufactured to such a large scale and weight that it is impossible for human beings to operate. In addition, conventional ELINT devices have limitations in terms of securing reception sensitivity for acquiring weak radar signals. That is, as the distance from the antenna, which is the input terminal of the system, to the RF processing unit for receiving and processing the signal is increased, the loss of the signal occurs, thereby deteriorating the receiving sensitivity performance of the system.

Korea Patent No. 10-0971773

The present invention provides an electronic information device which can be portable and which is small and lightweight so as not to be restricted by the operating environment.

The present invention provides a portable electronic information device capable of remarkably reducing a distance between an antenna and an RF processing unit to prevent loss of electromagnetic wave signal intensity.

According to an aspect of the present invention, there is provided an antenna unit that is portable and receives signals from outside; A signal processing unit which is portable and converts signals received through the antenna unit; And a coupling unit coupling the antenna unit and the signal processing unit, wherein the antenna unit and the signal processing unit are combined or separated by the coupling unit.

The antenna unit includes a plurality of antennas for receiving signals of different frequency bands and a switch provided between the plurality of antennas and the signal processing unit for selectively transmitting a signal according to a frequency band to the signal processing unit.

The signal processing unit includes an RF input / output selector connected to the switch and receiving an RF signal received from the antenna unit, an RF receiver for receiving an RF signal from the RF input / output selector and converting the RF signal into an IF signal, A digital receiver for receiving an RF signal and converting the RF signal into a digital signal, and a memory for storing at least one of the RF signal, the IF signal, and the digital signal.

The coupling portion includes a plurality of fixing portions fixed to one side surface of the antenna portion and one side surface of the signal processing portion and having a predetermined space inwardly and an engagement pin inserted in an inner space of the plurality of fixing portions.

And a cable port provided on one side of the antenna unit and the signal processing unit, respectively, and a cable is coupled to the cable port to electrically connect the antenna unit and the signal processing unit.

And a control unit provided between the antenna unit and the signal processing unit.

The control unit is connected to the signal processing unit and receives data from the signal processing unit.

The control unit includes a notebook computer, a tablet PC, and a smart phone.

According to another aspect of the present invention, there is provided a method of operating a portable electronic information apparatus, the method comprising: coupling and connecting a portable antenna unit and a signal processing unit; Connecting a control unit to the signal processing unit; Receiving the external signal from the antenna unit and supplying the external signal to the signal processing unit; Converting the signal supplied from the antenna unit by the signal processing unit; And comparing the signal of the signal processing unit with the signal pattern of the control unit.

And an engaging pin is inserted and coupled to an inner space of a plurality of fixing portions provided on one side of the antenna portion and the signal processing portion.

And a cable is connected to a cable port provided on one side of the antenna unit and the signal processing unit, respectively.

The control unit opens the antenna unit and places it on the signal processing unit, and then connects to the signal processing unit using a cable.

The signal processing unit receives an RF signal from the antenna unit, converts the RF signal into an IF signal, and converts the IF signal into a digital signal.

The signal processing unit stores the RF signal, the IF signal, and the digital signal in a memory unit.

The control unit stores a pattern of the allied radar signal, compares the stored signal pattern with the signal pattern of the signal processing unit, and determines whether the signal received by the antenna unit is the allied radar signal.

An electronic information apparatus according to embodiments of the present invention includes an antenna unit for receiving a signal and a signal processing unit for processing a signal transmitted from the antenna unit and combining and separating the antenna unit and the signal processing unit using a coupling unit . That is, the antenna unit and the signal processing unit, which are separated from each other, can be combined to reduce the size and weight of a single antenna. Therefore, the electronic information apparatus can be operated without being restricted by the operating environment. Also, since the antenna part and the signal processing part are defective, the distance between the antenna part and the signal processing part can be drastically reduced, and loss of the electromagnetic wave signal strength can be prevented.

1 is an exploded perspective view of a portable electronic information device according to an embodiment of the present invention;
2 is an assembled perspective view of a portable electronic information device according to an embodiment of the present invention;
3 is a rear schematic view of a portable electronic information device according to an embodiment of the present invention.
4 is an assembled perspective view of a portable electronic information device according to another embodiment of the present invention;
5 is an exploded perspective view of an antenna unit of a portable electronic information apparatus according to an embodiment of the present invention;
6 is a block diagram of a signal processing unit of a portable electronic information apparatus according to an embodiment of the present invention;
7 is a block diagram of a portable electronic information device according to an embodiment of the present invention.
8 is a flowchart of a method of operating a portable electronic information apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the invention is not limited to the disclosed embodiments, but is capable of other various forms of implementation, and that these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know completely.

FIG. 1 is an exploded perspective view of a portable electronic information apparatus according to an embodiment of the present invention, FIG. 2 is an assembled perspective view, and FIG. 3 is a rear schematic view. Here, FIG. 2A is a perspective view of the electronic information apparatus in an open state after coupling, and FIG. 2B is a perspective view of the electronic information apparatus in a closed state after coupling. 4 is an assembled perspective view of a portable electronic information apparatus according to another embodiment of the present invention, after being coupled.

1 to 4, a portable electronic information apparatus according to an exemplary embodiment of the present invention includes an antenna unit 1000 for receiving signals, a signal processing unit 2000 for processing signals received from the antenna unit 1000, And a coupling unit 3000 coupling the antenna unit 1000 and the signal processing unit 2000. Here, the antenna unit 1000 and the signal processing unit 2000 can be separated and combined. That is, the antenna unit 1000 and the signal processing unit 2000 can be coupled to and separated from each other using the coupling unit 3000.

The antenna unit 1000 and the signal processing unit 2000 may have the same shape. That is, it has a hexagonal shape having a first length in one direction (lateral direction), a second length in another direction (longitudinal direction) orthogonal to one direction, and a predetermined height in a vertical direction . At this time, the first length in the transverse direction may be longer than the second length in the longitudinal direction, and the first and second lengths may be larger than the height. In addition, the antenna unit 1000 and the signal processing unit 2000 may have the same size. That is, the antenna unit 1000 and the signal processing unit 2000 may have the same first and second lengths and heights. However, the antenna unit 1000 and the signal processing unit 2000 may have different sizes. For example, the antenna unit 1000 may be larger or smaller than the signal processing unit 2000, and the antenna unit 1000 and the signal processing unit 2000 may be the same in width and height but different in height.

The hexahedral antenna unit 1000 and the signal processing unit 2000 having such a rectangular plane can be coupled through at least one region. For example, the antenna unit 1000 and the signal processing unit 2000 may be combined with the coupling unit 3000 on the side having the first length of the antenna unit 1000 and the signal processing unit 2000, respectively. That is, one part of the coupling part 3000 is fixed to the first side of the antenna part 1000, and the other part is fixed to the first side of the signal processing part 2000 to form the antenna part 1000 and the signal processing part 2000, Can be coupled by the coupling portion 3000. The coupling unit 3000 may be provided in the form of a hinge (i.e., hinge) so that the antenna unit 1000 and the signal processing unit 2000 can be opened and closed. For example, as shown in FIG. 1, the coupling portion 3000 includes a plurality of fixing portions 3100 provided in a substantially cylindrical shape having a predetermined space therein, and an engagement pin (not shown) inserted into the fixing portion 3100 3200). At this time, the fixing unit 3100 is fixed to one side of the antenna unit 1000 and the signal processing unit 2000, and a predetermined space can be provided therein. A plurality of fixing portions 3100 may be provided for example. A portion of the first and third fixing portions 3110 and 3130 may extend to be fixed to the antenna portion 1000, A part of the fixing parts 3120 and 3140 may be extended and fixed to the signal processing part 2000. [ That is, a part of each of the first to fourth fixing parts 3110 to 3140 extends in one direction and the other direction opposite thereto, and is fixed to the side of the antenna part 1000 and the signal processing part 2000, 4-shaped fixing pins 3200 can be inserted into the inner space formed by the fixing portions 3110 - 3140. The coupling pin 3200 may include a body inserted into a space inside the fixing portion 3100 and a head provided at a distal end of the body and having a larger diameter than the body and hooked to the outside of the fixing portion 3100. The engagement and disconnection of the engagement pin 3200 can be facilitated by the provision of the head.

The jig 100 and the cable port 200 may be provided on one side of the antenna unit 1000 and the signal processing unit 2000 in which the coupling unit 3000 is provided. The jig 100 may be formed on the side of the antenna unit 1000 on the upper side of the coupling unit 3000 and the cable port 200 may be formed on a side of the antenna unit 1000 on the upper side of the coupling unit 3000, And the signal processing unit 2000 on the lower side of the coupling unit 3000. A cable for the electrical connection of the antenna unit 1000 and the signal processing unit 2000 may be inserted into the cable port 200. The cable port 200 may be a cable, That is, a cable is inserted into the cable port 200, and the antenna unit 1000 and the signal processing unit 2000 are connected to each other, so that a signal received by the antenna unit 1000 can be supplied to the signal processing unit 2000. Also, the power of the signal processing unit 2000 may be supplied to the antenna unit 1000. [

Meanwhile, the antenna unit 1000 and the signal processing unit 2000 may be combined, and a control unit 4000 may be provided between the antenna unit 1000 and the signal processing unit 2000. As shown in FIG. 4, for example, a notebook computer can be used as the control unit 4000. That is, the control unit 4000 may include a notebook computer provided with a keyboard and a main body on one side, a monitor on the other side, and a monitor capable of opening and closing the main body. Of course, the control unit 4000 may include a tablet PC, a smart phone, and the like in addition to a notebook computer. At this time, a seating part may be provided on one surface of the antenna unit 1000 and the signal processing unit 2000 facing each other so that the notebook computer can be seated. That is, the antenna unit 1000 can be opened and closed upward from the signal processing unit 2000, and a seating unit can be provided on one surface of the signal processing unit 2000 facing one surface of the antenna unit 1000. The seating part may be provided in a groove shape so that the main body including the keyboard of the notebook computer can be seated. Accordingly, the antenna unit 1000 is opened to open the signal processing unit 2000, and the main body of the notebook computer can be placed on the seating part on one side of the signal processing unit 2000.

Although not shown, a connection cable for connection with a notebook computer may be provided on the seating portion of the signal processing unit 2000. Accordingly, the signal from the signal processing unit 2000 can be transmitted to the notebook computer. In addition, the signal processor 2000 and the notebook computer are electrically connected to each other so that the signal processor 2000 and the notebook computer can share power. In addition, the antenna unit 1000 and the signal processing unit 2000 may be provided with a handle so that the antenna unit 1000 and the signal processing unit 2000 can be freely operated. At this time, the antenna unit 1000 may be provided with a knob on the upper surface for easy opening and closing, and a handle may be provided on the side opposite to the coupling unit 3000 so that the signal processing unit 2000 can freely operate.

As described above, the electronic information apparatus according to embodiments of the present invention includes an antenna unit 1000 for receiving signals, a signal processing unit 2000 for processing signals transmitted from the antenna unit 1000, an antenna unit 1000, And a coupling unit 3000 that couples the signal processing unit 2000. The control unit 4000 may also include a notebook computer or the like, which is mounted on one side of the signal processing unit 2000 and is connected to the signal processing unit 2000. The electronic information apparatus according to the embodiments of the present invention can be combined and separated from the antenna unit 1000 and the signal processing unit 2000 by using the coupling unit 3000 so that the electronic information apparatus is reduced in size and weight, The frequency can be possible. Therefore, the electronic information apparatus can be operated without being restricted by the operating environment. Also, by combining the antenna unit 1000 and the signal processing unit 2000, the distance between the antenna unit 1000 and the signal processing unit 2000 can be remarkably reduced, thereby preventing the loss of the intensity of the electromagnetic wave signal.

The configuration of the antenna unit 1000 and the signal processing unit 2000 of the portable electronic information apparatus of the present invention will be described in more detail with reference to the drawings.

FIG. 5 is an exploded perspective view of an antenna unit of a portable electronic information apparatus according to an embodiment of the present invention, and FIG. 6 is a schematic view of a signal processing unit. 7 is a block diagram of a portable electronic information apparatus according to an embodiment of the present invention.

5, an antenna unit 1000 of an electronic information apparatus according to an embodiment of the present invention includes a rear cover 1110 and a protective cover 1120, a frame 1200, a cable 1300, a receiving antenna 1400 A switch 1500, a support plate 1600, a radio wave absorber 1700, a radome 1800, a radome fixing plate 1900 and a plurality of gaskets 1910, 1920 and 1930. The antenna unit 1000 may be provided inside a substantially hexahedral housing. The rear cover 1110 and the protection cover 1120 and the frame 1200 may function as a housing and the rear cover 1110 and the protection cover 1120 and the frame 1200 may be provided inside a predetermined housing. .

The rear cover 1110 and the protection cover 1120 may be provided to cover the inside of the antenna unit 1000. A cable 1300, a receiving antenna 1400, a switch 1500 and the like may be provided inside the frame 1200 and a supporting plate 1600, a radio wave absorber 1700, a radome 1800 And a radome fixing plate 1900. The rear surface of the antenna unit 1000 on one side of the frame 1200 is covered by the rear cover 1110 and the upper surface of the antenna unit 1000 on the upper side of the radome 1800 is covered with a protective cover (Not shown). At this time, the rear cover 1110 of the antenna unit 1000 may face the combined signal processing unit 2000. That is, one surface of the antenna unit 1000 and one surface of the signal processing unit 2000 may be coupled face to face. At this time, one surface of the antenna unit 1000 may be the rear cover 1110. The rear cover 1100 and the protection cover 1200 may be formed to have a predetermined thickness along the shape of the antenna unit 1000, and may be provided in a substantially rectangular plate shape, for example. On the other hand, the protective cover 1200 may be detachable. That is, when the signal is collected, the signal can be collected in a state in which the radome 1800 is exposed after removing the protective cover 1200, and the radome 1800 can be collected for protection of the radome 1800, Can be reassembled to cover the cover.

 The frame 1200 forms the outer shape of the antenna unit 1000. Further, the frame 1200 may be provided with a cable 1300, a receiving antenna 1400, a switch 1500 and the like on the inner side. Such a frame 1200 may have a predetermined height and a predetermined width and may be provided in a shape of a substantially rectangular hollow. A rear cover 1100 may be provided on the lower portion of the frame 1200 to contact the edge. At this time, a first gasket 1910 may be provided between the edge of the frame 1200 and the rear cover 1100. Meanwhile, the frame 1200 may be manufactured using an aluminum alloy. Also, although the frame 1200 has been described as a substantially rectangular shape, it may be provided in various shapes depending on the shape of the antenna unit 1000.

The cable 1300 may be provided to connect the internal configuration of the antenna unit 1000. [ That is, the cable 1300 may be provided to connect the receiving antenna 1400 and the switch 1500.

The receiving antenna 1400 receives an external signal and may be provided with at least one. That is, the receiving antenna 1400 may be provided with at least two or more than two to receive signals of different frequency bands, respectively. For example, a first antenna 1410 for receiving a signal in a first frequency band, a second antenna 1420 for receiving a signal in a second frequency band, a third antenna 1420 for receiving a signal in a third frequency band, 1430 < / RTI > Here, the first to third frequency bands have different center frequencies, the first frequency band may be lower than the second frequency band, and the third frequency band may be lower than the second frequency band. In addition, the first to third frequency bands may be implemented in various frequency bands according to the judgment of a person skilled in the art in respective frequency bands which do not overlap with each other or overlap only a certain portion. For example, the first frequency band may be less than 2 GHz, the second frequency band may be more than 2 GHz and less than 18 GHz, and the third frequency band may be more than 18 GHz. Accordingly, the first antenna 1410 receives signals of less than 2 GHz, the second antenna 1420 receives signals of 2 GHz to 18 GHz, and the third antenna 1430 receives signals of 18 GHz or more do. Also, the first to third antennas 1410, 1420 and 1430 may be provided in different sizes. For example, the first antenna 1410 may be larger than the second and third antennas 1420 and 1430, and the second antenna 1420 may be larger than the third antenna 1430. Meanwhile, the first to third antennas 1410, 1420 and 1430 may be provided in a predetermined shape, for example, in a circular shape.

The switch 1500 may be coupled to the receive antenna 1400. Also, the switch 1500 may be connected to the signal processing unit 2000. That is, the switch 1500 may be provided between the reception antenna 1400 and the signal processing unit 2000. The switch 1500 is provided between the first to third antennas 1410, 1420 and 1430 and the signal processing unit 2000 and can selectively connect the reception antenna 1400 and the signal processing unit 2000 according to a frequency band.

The support plate 1600 may be provided to fix the reception antenna 1400, the switch 1500, and the like. In addition, the support plate 1600 can support the radome 1800. That is, the reception antenna 1400, the switch 1500 and the like are fixed to one surface of the support plate 1600, and the radome 1800 can be supported on the other surface of the support plate 160. At this time, at least a part of one surface of the support plate 1600 may be embodied as a printed circuit board. That is, the reception antenna 1400, the switch 1500, and the like are fixed and at least a part of one surface of the support plate 1600 may be implemented as a printed circuit board for electrical connection thereof. Of course, the printed circuit board may not be implemented on at least a part of one side of the support plate 1600, because it may be connected via the cable 1300. [ In addition, the support plate 1600 is provided in the form of a plate having a predetermined thickness, and a predetermined width of the edge of the support plate 1600 can be brought into contact with the edge of the frame 1200. At this time, the support plate 1600 may be fixed to the frame 1200. That is, the edge of the support plate 1600 can be fixed by being in contact with the edge of the frame 1200. In addition, the support plate 1600 may be formed with a predetermined opening, and the reception antenna 1400 may be inserted into the opening. That is, an opening may be formed in the support plate 1600 so that a predetermined height of each of the first to third antennas 1410, 1420, and 1430 can be inserted. At this time, since the first to third antennas 1410, 1420 and 1430 are provided in different sizes, a plurality of openings may also be provided in different sizes.

The electromagnetic wave absorber 1700 may be provided on the other surface of the support plate 1600. The electromagnetic wave absorber 1700 may be provided in the same shape and size as the support plate 1600. That is, the microwave absorber 1700 may have a plurality of openings, and the first to third antennas 1410, 1420 and 1430 may be inserted into the plurality of openings. The radio wave absorber 1700 may be provided to shield electromagnetic waves and remove noise or the like. That is, when an electromagnetic wave of an abnormally high voltage flows into the antenna unit 1000, the receiving antenna 1400 may be damaged. The electromagnetic wave absorber 1700 is provided to shield the electromagnetic wave or the like, thereby preventing damage to the internal components.

The radome 1800 may be provided to protect the antenna unit 1000 from the external environment. That is, the radome 1800 is provided on the support plate 1600 and covers the RF receiving antenna 1400 and the like, thereby protecting the receiving antenna 1400 and the like from the external environment. In addition, a plurality of openings are formed at the edge of the radome 1800, and the fastening member is inserted through the opening, so that the radome 1800 can be fastened and fixed to the frame 1200. Further, a second gasket 1920 is provided between the radome 1800 and the support plate 1600 to prevent infiltration of moisture, oxygen, and the like. On the other hand, the radome 1800 may be formed of a resin such as polycarbonate.

The radome fixing plate 1900 may be provided in a rectangular frame shape with a central portion opened. Here, the length of the radome fixing plate 1900 in one direction and the other direction may be the same as the length of the radome 1800. The radome fixing plate 1900 is formed with a plurality of openings at its edges. The opening of the radome fixing plate 1900 may be provided at the same position and the same size as the opening of the radome 1800. Therefore, the fastening member can be inserted through the opening of the radome fixing plate 1900 and the opening of the radome 1800 and inserted into the frame 1200, so that the radome 1800 and the radome fixing plate 1900 are inserted into the frame 1200, Respectively. The radome fixing plate 1900 can be manufactured using, for example, stainless steel. Meanwhile, a third gasket 1930 may be provided between the radome fixing plate 1900 and the radome 1800.

The gaskets 1910, 1920, and 1930 may be provided to prevent external moisture, oxygen, etc. from penetrating into the antenna unit 1000. That is, if moisture, oxygen, or the like penetrates into the inside of the antenna unit 1000, the RF receiving antenna 1400 may be corroded or the conductive pattern of the RF receiving antenna 1400 may be oxidized so that malfunction or failure of the antenna unit 1000 It can be a cause. These gaskets may be provided along the edges of the contact parts. That is, a first gasket 1910 provided between the rear cover 1110 and the frame 1200 may be provided along the lower edge of the frame 1200, and the second gasket 1910 may be provided between the frame 1200 and the support plate 1600, A gasket 1920 may be provided along the upper edge of the frame 1200 and a third gasket 1930 provided between the support plate 1600 and the radome 1800 may be provided along the edge of the support plate 1600 .

6, a signal processing unit 2000 of a portable electronic information apparatus according to an exemplary embodiment of the present invention includes an RF input / output selection unit 2100, an RF reception unit 2200, a digital reception unit 2300, a memory unit 2400 ), A controller 2500, and a power supply 2600. The signal processing unit 2000 may further include a backplane 2700 through which the components are inserted and electrically connected. In the signal processing unit 2000, the components are provided in a housing having a predetermined space therein. In addition, the component parts may be provided in a substrate shape in which a plurality of modules are mounted on a predetermined printed circuit board, and may be inserted and mounted in the backplane 2700 inside the housing. 6 and 7, the components constituting the signal processing unit 2000 are shown in a simplified form as a block, but they may have a structure in which they are inserted into the slots in the housing in the form of a board. At this time, each of the plurality of component parts may constitute one substrate or may be constituted on at least two one substrate.

The RF input / output selection unit 2100 is provided between the antenna unit 1000 and the RF reception unit 2200. That is, the input terminal of the RF input / output selector 2100 is connected to the antenna unit 1000, and the output terminal of the RF input / output selector 2100 is connected to the input terminal of the RF receiver 2200. The RF input / output selection unit 2100 transmits a signal input from the antenna unit 1000 to the RF reception unit 2200. That is, a plurality of signals are input from the antenna unit 1000. The RF input / output selection unit 2100 selects at least one signal and transmits the signal to the RF receiving unit 2200. [

The RF receiver 2200 receives an RF signal from the RF input / output selector 2100 and downconverts the RF signal to generate an instantaneous frequency (IF) signal. That is, the RF receiving unit 2200 receives signals received from the first to third antennas 1410, 1420, and 1430 of the antenna unit 1000 and outputs a signal corresponding to the selected instantaneous frequency range Into one or more downlink frequency signals. That is, the RF receiving unit 2200 can convert the signals of the first to third frequency bands into first to third IF signals corresponding to the first to third instantaneous frequency ranges, respectively.

The digital receiving unit 2300 receives the IF signal from the RF receiver 2200 and performs analog-digital conversion on the IF signal to generate a digital signal. That is, the RF receiving unit 2200 receives the analog signal and converts it into a digital signal.

The memory unit 2400 stores the digital signal generated by the digital receiving unit 2300. Also, the memory unit 2400 may be connected to the RF input / output selection unit 2100 and the RF reception unit 2200 to receive and store signals from the RF input / output selection unit 2100 and the RF reception unit 2200. That is, the memory unit 2400 may be connected to the digital receiving unit 2300 and selectively connected to the RF input / output selecting unit 2100 and the RF receiving unit 2200. Accordingly, the memory unit 2400 may receive and store the RF signal received from the antenna unit 1000 from the RF input / output selection unit 2100, and may receive and store the IF signal from the RF receiving unit 2200. At this time, the memory unit 2400 may match and store the RF signal, the IF signal, and the digital signal. That is, the memory unit 2400 may match and store an RF signal input from the antenna unit 1000, an IF signal obtained by converting the RF signal, and a digital signal obtained by digitally converting the IF signal. Meanwhile, the memory unit 2400 is connected to the control unit 4000 such as a notebook computer, and provides the stored signals to the notebook computer.

The controller 2500 controls components of the signal processing unit 2000. That is, the controller 2500 controls the RF input / output selection unit 2100, the RF reception unit 2200, the digital reception unit 2300, the memory unit 2400, the power supply unit 2600, and the like. Under the control of the controller 2500, the signal processing unit 2000 is driven to convert the RF signal received from the antenna unit 1000 into an IF signal, and the IF signal is converted into a digital signal and stored.

The power supply unit 2600 supplies power necessary for driving the signal processing unit 2000. The power supply unit 2600 may include a rechargeable battery. In addition, the power supply unit 2600 can generate DC power required for driving each configuration of the signal processing unit 2000 by receiving external AC power. Preferably, the power supply unit 2600 may include a battery that can be charged / discharged by an external power supply and can be directly driven to an external power supply. The power supply unit 2600 may include a DC converter that converts external AC power to a plurality of DC power supplies required for driving the components of the signal processing unit 2000. At this time, the DC power generated by the power supply unit 2600 may be supplied to the antenna unit 1000 and used for driving the antenna unit 1000.

Meanwhile, the signal processing unit 2000 may further include a backplane 2700. Each component of the signal processing unit 2000 can be manufactured in at least one substrate form. That is, the RF input / output selection unit 2100, the RF reception unit 2200, the digital reception unit 2300, the memory unit 2400, and the controller 2500 constituting the signal processing unit 2000 are connected to a predetermined printed circuit board Modules may be respectively mounted and configured in the form of a substrate. In addition, each component of the signal processing unit 2000 configured in the form of a board can be fastened to the backplane 2700. That is, the backplane 2700 may include a plurality of expansion slots for plugging component parts in the form of a board to connect the components of the signal processor 2000, and connectors for connecting various peripheral devices. For example, the RF input / output selector 2100 and the RF receiver 2200 are inserted into one side of the bidirectional backplane 2700, and the digital receiver 2300 ), A memory unit 2400, and a control unit 2500 can be inserted.

7, the controller 4000 includes a notebook computer. The controller 4000 is connected to the signal processor 2000 and receives an IF signal, a digital signal, and the like from the signal processor 2000 to determine the waveform of the signal have. That is, signals of various patterns are stored in the notebook computer, and the patterns of the stored signals are compared with the signal pattern of the signal processing unit 2000 and displayed to the user. Accordingly, the user can determine the received signal and determine the nature of the signal. That is, it is possible to judge whether the radar signal generated from the enemy group or the radar signal generated from the friendly group or the like.

A method of operating the portable electronic information device according to the embodiments of the present invention as described above will be described with reference to FIG.

S100: First, the antenna unit 1000 and the signal processing unit 2000, which are respectively provided in a substantially hexahedron shape, are coupled to each other using the coupling unit 3000. That is, the antenna unit 1000 includes at least one fixing unit 3110 and 3130 provided at one side thereof, and at least one fixing unit 3120 and 3140 provided at one side of the signal processing unit 2000, The antenna unit 1000 and the signal processing unit 2000 are coupled to each other by inserting the antenna 3200. [ A cable is connected to a cable port 200 provided on one side of the antenna unit 1000 and the signal processing unit 2000 to electrically connect the antenna unit 1000 and the signal processing unit 2000. Therefore, the signal received by the antenna unit 1000 can be transmitted to the signal processing unit 2000, and the power generated from the signal processing unit 2000 can be supplied to the antenna unit 1000.

S200: Then, the antenna unit 1000 is lifted by using a handle provided on the front surface of the antenna unit 1000 to expose one surface of the signal processing unit 2000. FIG. A control unit 4000 such as a notebook computer is placed on one surface of the signal processing unit 2000 and the control unit 4000 and the signal processing unit 2000 are electrically connected to each other using a predetermined cable. Therefore, the data of the signal processing unit 2000 can be supplied to the control unit 4000, and the power generated from the signal processing unit 2000 can be supplied to the control unit 4000.

S300: Then, the antenna unit 1000 inputs an external signal. That is, the antenna unit 1000 receives a signal emitted from an external predetermined radar. At this time, a plurality of antennas 1410, 1420, and 4130 having different reception frequency bands are provided in the antenna unit 1000, and a plurality of antennas 1400 receive signals according to a frequency band. The signal received by the antenna 1400 is supplied to the signal processing unit 2000 through the switch 1500.

S400: The signal processing unit 2000 receives a signal from the antenna unit 1000 and converts it into an IF signal and a digital signal. That is, the RF input / output selection unit 2100 receives the RF signal through the switch 1500 of the antenna unit 1000 and supplies the RF signal to the RF receiving unit 2200. The RF receiving unit 2200 converts the RF signal into an IF signal , And the digital receiving unit 2300 receives the IF signal from the RF receiving unit 2200 and converts the IF signal into a digital signal. At this time, the RF receiving unit 2200 downconverts the RF signal into an IF signal, and the digital receiving unit 2300 converts the IF signal to a digital signal. Signals input to and processed in the signal processing unit 2000, that is, an RF signal, an IF signal, and a digital signal are stored in the memory unit 2400. At this time, the memory unit 2400 may store the digital signal, and may store and match the RF signal, the IF signal, and the digital signal.

S500: The control unit 4000 may be connected to the memory unit 2400 to receive data from the memory unit 2400. [ The control unit 4000 can determine an external signal using data stored in the memory unit 2400, for example, a digital signal. That is, the control unit 4000 stores signals of various patterns, compares the signals supplied from the signal processing unit 2000 with stored signals, and displays the signals to the user. Accordingly, the user can determine the received signal and determine the nature of the signal. For example, a pattern of a radar signal of a friend is stored in the controller 4000, and a signal pattern stored in the controller 4000 is compared with a signal pattern from the signal processor 2000 to generate a radar signal generated from the enemy arm It is possible to determine whether the radar signal is a radar signal.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the embodiments are for the purpose of illustration only and are not to be construed as limitations. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention.

1000: antenna unit 2000: signal processing unit
3000: Coupling unit 4000: Control unit

Claims (8)

An electronic information apparatus of electronic warfare apparatus for collecting electromagnetic waves radiated by a radar to search for a position of a radar,
An antenna unit which is portable and receives a signal from the outside;
A signal processing unit which is portable and converts signals received through the antenna unit; And
And a coupling unit coupling the antenna unit and the signal processing unit,
The antenna portion and the signal processing portion are each provided in a hexahedron shape,
Wherein the antenna unit and the signal processing unit are coupled or separated by the coupling unit,
The antenna unit includes:
Frame,
A rear cover and a protection cover provided on one side and the other side of the frame,
A support plate provided between the frame and the rear cover,
At least one antenna fixed to the support plate and provided inside the frame,
A radio wave absorber provided on the support plate,
A radome provided on the radio wave absorber,
A portable electronic information device comprising at least one gasket for preventing penetration of moisture, oxygen from the outside.
The apparatus of claim 1, wherein the antenna unit comprises: a plurality of antennas for receiving signals of different frequency bands;
And a switch provided between the plurality of antennas and the signal processing unit for selectively transmitting a signal according to a frequency band to the signal processing unit.
[2] The apparatus of claim 2, wherein the signal processing unit comprises: an RF input / output selector connected to the switch for inputting an RF signal received from the antenna unit;
An RF receiver for receiving an RF signal from the RF input / output selector and converting the RF signal into an IF signal;
A digital receiver for receiving an RF signal from the RF receiver and converting the RF signal into a digital signal,
And a memory unit for storing at least one of the RF signal, the IF signal, and the digital signal.
The signal processing unit according to claim 3, wherein the coupling unit comprises: a plurality of fixing units fixed to one side of the antenna unit and one side of the signal processing unit,
And an engaging pin inserted into an inner space of the plurality of fixing portions.
The portable electronic information apparatus according to claim 4, further comprising a cable port provided on one side of the antenna unit and the signal processing unit, respectively, and a cable is coupled to the cable port, so that the antenna unit and the signal processing unit are electrically connected.
The portable electronic information apparatus according to any one of claims 1 to 5, further comprising a control section provided between the antenna section and the signal processing section.
The portable electronic information apparatus according to claim 6, wherein the control unit is connected to the signal processing unit and receives data from the signal processing unit.
The portable electronic information apparatus according to claim 7, wherein the control unit includes a notebook computer, a tablet PC, and a smart phone.

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