KR0175759B1 - Signal delay device using coaxial cable - Google Patents

Abstract

The present invention relates to an apparatus for checking the operation of a propagated proximity fuse, and more particularly, to a high frequency signal delay apparatus for use in simulating a distance detection function of a proximity fuse target.

The present invention is connected between the high frequency signal input through the input antenna and the circulator and receiving cable having a predetermined length; A circulator for transmitting a signal through the receiving cable toward the high frequency signal switch, and a signal input through the high frequency signal switch to the transmitting cable; A control unit for controlling a high frequency signal applied through the circulator to be connected to a desired delay cable among a plurality of delay cables; A plurality of delay cables each having a separate length connected as the contacts of the high frequency signal switch are connected; A second circulator connected to a rear end of the delay cable and transmitting a signal propagated through the cable to an amplifier, and transmitting a signal from a second delay cable back to the delay cable; An amplifier for compensating for insertion loss and the like; In addition, the present invention provides a high frequency signal delay apparatus comprising a second delay cable having a predetermined length.

Description

Signal delay device using coaxial cable

The present invention relates to an apparatus for checking the operation of a propagated proximity fuse, and more particularly, to a high frequency signal delay apparatus for use in simulating a distance detection function of a proximity fuse target.

A fuse is a device that causes the initial process of the explosive chain to ignite and explode the explosives of the explosive device.

If the fuse is classified according to its function or function, it can be classified into an impact fuse, a time fuse, a peripheral fuse, a proximity fuse, and a command fuse.

Proximity fuses are equipped with electronic devices having the functions of transmitting and receiving in their fuses, and receiving signals reflected from the target by radio waves transmitted from the targets through the receiving device of the fuse, and detonating them at the optimum approach distance. A fuse with the ability to work. In this case, the proximity fuse uses the operation principle of transmission and reception, that is, continuous wave Doppler effect, frequency modulation, pulse radar and pulse Doppler effect.

The signal processor determines the frequency of the IF signal through the bandpass filter and calculates the distance of the target using the determined frequency. Continue this process and output the detonation signal when the target reaches the adjusted distance to the fuse.

To do this, it is necessary to measure the distance between the proximity fuse and the target. In practice, it is not easy to measure the operation with a distance of several tens of meters.

The present invention is to solve the above problems, and has a transmission function and a reception function for detecting the proximity of the target, the proximity fuse for detecting the distance to the target by receiving a signal reflected by the transmitted signal is the target It is an object of the present invention to provide a signal delay device for an inspection apparatus that has a predetermined signal delay for checking a target detection function of a target and changes its delay distance to simulate a necessary distance.

1 is a block diagram of a signal delay device constructed in accordance with the present invention.

2 is a detailed configuration diagram of a control unit according to the present invention.

3 is a block diagram showing the configuration of a second delay circuit as an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

100: receiving antenna 150: receiving cable

200: circulator 300: control unit

310: high frequency signal switch (coaxial relay) 320a, 320b, 320c: delay cable

330: control signal generator 510: second circulator

520: amplifier 530: second delay cable

In order to achieve the above object, the present invention has a proximity function having a transmission function and a reception function for detecting proximity of a target, and receiving a signal reflected by the target signal to detect a distance to the target. An apparatus for checking a target detection function of a device, comprising: a receiving cable connected between a high frequency signal input through an input antenna and a circulator and having a predetermined length; A circulator for transmitting a signal through the receiving cable toward the high frequency signal switch, and a signal input through the high frequency signal switch to the transmitting cable; A control unit for controlling a high frequency signal applied through the circulator to be connected to a desired delay cable among a plurality of delay cables; A plurality of delay cables each having a separate length connected as the contacts of the high frequency signal switch are connected; A second circulator connected to a rear end of the delay cable and transmitting a signal propagated through the cable to an amplifier, and transmitting a signal from a second delay cable back to the delay cable; An amplifier for compensating for insertion loss and the like; In addition, the present invention provides a high frequency signal delay apparatus comprising a second delay cable having a predetermined length.

EXAMPLE

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a signal delay apparatus using a coaxial cable constructed in accordance with the present invention.

The configuration of the signal delay apparatus using the coaxial cable of the present invention is broadly regarded as a receiving unit 100 including a receiving antenna and a receiving cable, a circulator 200, a control unit and a signal delaying unit 300 including a plurality of delay cables, and It is divided into a transmission unit 400 including a transmission antenna and a transmission cable.

If the propagation speed of the spread air is summarized only result bar that can solve the wave equation for the electric field and magnetic field obtained obtain the year, c = 1 / (√ ( εo × μo)) = 3 × 10 8 [m / s], which is equal to the speed of light.

Where c is the rate of propagation, εo is the permittivity, and μo is the permeability.

The propagation wavelength is shortened according to intrinsic characteristics such as permittivity and permeability of the coaxial cable used in the present invention. For example, polyethylene filled as an insulating material in a coaxial cable, the wavelength of radio waves in this coaxial cable is shortened by about 66-67% compared to the wavelength in air.

Therefore, the above-mentioned length of 3m is the actual ground length, but the electrical length that has the electrical delay effect as this length should be calculated in consideration of the wavelength shortening rate, and the electrical length should be determined through experiments.

The lengths of the coaxial cables described below are all the lengths of the actual cables, and the electrical delay effect should be calculated in consideration of the above-described wavelength reduction ratio.

The high frequency signal input through the input antenna 100 is applied to the circulator 200 of the present invention through a receiving cable 150 having a predetermined length formed of a coaxial cable. At this time, as an embodiment of the receiving cable 150 can be configured using a coaxial cable having a length of 3m.

The circulator 200 transmits the signal input through the reception cable 150 toward the high frequency signal switch 310, and the signal input through the high frequency signal switch 310 is transmitted through the transmission cable 410. It performs a function to be transmitted through the antenna 420.

The control unit 300 is responsible for controlling to be connected to a desired delay cable among a plurality of delay cables 320a, 320b, 320c so as to have a delay value of a desired value for the high frequency signal applied through the circulator 200. do.

The control unit 300 selects a desired delay value from among a plurality of delay values preset by the user and applies the signal to the high frequency signal switch 310, the control signal generator (330) 330 operates according to a control signal from the high frequency signal switch 310 for connecting a desired delay cable among a plurality of delay cables each having a separate delay value, since the contacts of the high frequency signal switch 310 are connected. It is formed to include a plurality of delay cables 320 each having a separate length connected along.

As an example of the configuration of the control signal generator 330, for example, the delay cables 320a, 320b and 320c having lengths of 1m, 2m and 8m, and the circulator 200 to the delay cables 320a, 320b and 320c. Three switches (SW1, SW2, SW3) for connecting the received signal applied through and a coaxial relay (310) connected to one of the switches and magnetized and reacted according to the operation of the switch, and When the coil of the coaxial relay 310 is magnetized, the coil may include contacts C1, C2, and C3 for connecting the signal from the circulator 200 to the respective delay cables.

2 shows an example of a circuit configuration of the control signal generator 230, the coaxial relay 310, and the contacts C1, C2, and C3.

The reception before input to the above-described delay cables 320a, 320b, and 320c is reflected when they reach the end of the cable.

The reflected wave is inputted to the transmission cable 410 through the circulator 210 through the high frequency signal switch 310 after passing through the delay cables 320a, 320b and 320c.

As an example of the transmission cable 410, a cable having a length of 9 m can be formed. The signal passed through the transmission cable 410 is transmitted through the transmission antenna 420 again.

Accordingly, the signal input through the receiving antenna 100 is reflected through the receiving cable 150 through the 1m long delay cable 320a, and then again via the transmitting cable 410 and through the transmitting antenna 420. The total delay length in this case becomes 3m + 1m x 2 + 9m, and has a total delay length of 14m. The length at this time is based on the actual length of the coaxial cable, and the electrical delay length should be calculated experimentally accurately in consideration of the wavelength reduction ratio as described above.

On the other hand, as an embodiment of the present invention, it is also possible to form a second signal delay circuit again at the rear end of the delay cable 320.

3 shows the configuration of such a second delay circuit.

The second delay circuit includes a second circulator 510, an amplifier 520, and a second delay cable 530.

The second circulator 510 is connected to the rear ends of the delay cables 320a, 320b, and 320c to transmit a signal propagated through the cable to the amplifier, and sends the signal from the second delay cable back to the delay cable 320a. It performs the function of transmitting to, 320b, 320c.

The second delay circuit includes an amplifier 520. The amplifier 520 compensates for insertion loss of the connection point between the delay cable and the second delay circuit, insertion loss due to the second circulator 510, and the like. Was added to.

The operation of this circuit is the same as that of the first signal delay circuit described above, and thus its detailed description is omitted. However, assuming that the length of the delay cable of the second signal delay circuit is set to 3m, it can be seen that the signal delay caused by the insertion of the second delay signal circuit is only 3m.

Of course, it is possible to reconfigure the circuit by installing a plurality of cables having different lengths and connecting and disconnecting the delay cables of the second signal delay circuit using coaxial relays. It is obvious.

At this time, the signal input through the receiving antenna 100 is incident through the receiving cable 150 through the delay cable 320c of 3m length, is delayed through the second delay cable 530, and then again the delay cable ( 320c) and the total delay length in the case of being transmitted via the transmission antenna 420 via the transmission cable 410 is 3m + 8m + 3m + 8m + 9m, and has a total delay length of 31m. The length at this time is based on the actual length of the coaxial cable, and the electrical length delayed through the signal delay apparatus should be accurately calculated experimentally in consideration of the wavelength reduction ratio as described above.

According to the configuration and its operation as described above, the signal delay circuit of the present invention eliminates the hassle of actually measuring the distance apart in order to measure the correct operation of the transceiver and the signal processing circuit of the proximity fuse, the electrical The effect of simplifying the measurement is achieved by freely separating the distance required as the signal delay.

While the invention has been shown and described with respect to certain preferred embodiments, it will be appreciated that the invention can be modified and modified in various ways without departing from the spirit or scope of the invention as set forth in the claims below. One of ordinary skill in the art will readily know.

Claims (3)

In the apparatus for checking the target detection function of the proximity fuse having a transmission function and a reception function for detecting the proximity of the target, and receiving a signal reflected by the target to detect the distance to the target. A receiving cable 150 connected between the high frequency signal inputted through the input antenna 100 and the circulator 200 and having a predetermined length; A circulator 200 for transmitting a signal through the receiving cable 150 toward the high frequency signal switch 310, and a signal input through the high frequency signal switch 310 toward the transmitting cable 410; A control unit 300 for controlling the high frequency signal applied through the circulator 200 to be connected to a desired delay cable among a plurality of delay cables 320a, 320b, and 320c; And a plurality of delay cables (320a, 320b, 320c) each having a separate length connected as the contacts of the high frequency signal switch (310) are connected. The control signal generator 330 of claim 1, wherein the controller 300 selects a desired delay value from a plurality of delay values preset by a user and applies the signal to the high frequency signal switch 310. ; And a high frequency signal switch 310 which operates according to a control signal from the control signal generator 330 and connects a desired delay cable among a plurality of delay cables each having a separate delay value. High frequency signal delay device characterized in that. In the apparatus for checking the target detection function of the proximity fuse having a transmission function and a reception function for detecting the proximity of the target, and receiving a signal reflected by the target to detect the distance to the target. A receiving cable 150 connected between the high frequency signal inputted through the input antenna 100 and the circulator 200 and having a predetermined length; A circulator 200 for transmitting a signal through the receiving cable 150 toward the high frequency signal switch 310, and a signal input through the high frequency signal switch 310 toward the transmitting cable 410; A control unit 300 for controlling the high frequency signal applied through the circulator 200 to be connected to a desired delay cable among a plurality of delay cables 320a, 320b, and 320c; A plurality of delay cables 320a, 320b, and 320c each having a separate length connected as the contacts of the high frequency signal switch 310 are connected; It is connected to the rear end of the delay cable (320a, 320b, 320c) and transmits the signal propagated through the cable to the amplifier, and transmits the signal from the second delay cable back to the delay cable (320a, 320b, 320c) A second circulator 510 for; An amplifier 520 for compensating insertion loss or the like; And a second delay cable 530 of a predetermined length.