KR100686962B1 - Redundancy switch apparatus - Google Patents

Abstract

A redundancy switch apparatus is provided to perform a stable flow of a signal in a system by transmitting a signal of an abnormal amplifier to a normal amplifier. In a redundancy switch apparatus, first and second switches(410,420) switch a signal to two routes. The signal is inputted from first and second input ports. A combiner(460) is connected to one of the two routes of the first and second switches(410,420) respectively. The combiner(460) adjusts power of the two inputted signals to a half of the power and combines the power of the two signals. A third switch(430) switches the signal output from the combiner(460) to the two routes. A forth switch(440) switches the other route of the two routes of the first switch(410) and one route of the third switch(430) to output to the first output port. A fifth switch(450) switches the other route of the two routes of the second switch(420) and the other route of the third switch(430) to output to the second output port.

Description

Redundancy switch apparatus

1 is a structural diagram of a conventional RF system,

2 is a structural diagram for explaining an RF system to which the present invention is applied;

3 is a structural diagram of a first embodiment of a redundancy switch device according to the present invention;

4 is a structural diagram of a second embodiment of a redundancy switch device according to the present invention;

<Description of Symbols for Main Parts of Drawings>

SPDT: 310, 320, 330, 340, 410, 420, 430, 440, 450

360, 370, 380, 390, 470, 480: PAD

350: 3 dB Coupler

460: Combiner

The present invention relates to a redundancy switch device, and more particularly, to a redundancy switch device for use in a radio frequency (hereinafter, simply referred to as 'RF') system.

Generally, in RF systems, an amplifier is used a lot because the power of a signal emitted through an antenna must be very large.

1 is a structural diagram of a conventional RF system.

As shown in the figure, in an RF system requiring four amplifiers 110-113, the switches 130-133 are connected to the amplifiers 110-113, respectively, and the signals input to the amplifiers 110-113. Is amplified and sent to the transceiver (Tx / Rx).

If one amplifier fails (e.g., the 111 amplifier in FIG. 1 fails), the switch 131 is switched to the spare amplifier 120 to allow the system to operate smoothly. do.

However, since the price of the amplifier is very high in the RF system that high power passes, there is a problem that the additional use of the preliminary amplifier 120 inevitably burdens the user. In addition, after the signal input by the amplifier (110 ~ 113, 120) is amplified to a high power, the signal is switched at the rear end, so that a stable mechanical switch must be used for a high output, the cost is inevitable have.

SUMMARY OF THE INVENTION The present invention has been proposed to solve the above problems, and it is an object of the present invention to provide a redundancy switch device for switching and amplifying a path of a working amplifier before amplifying a signal without using a preamplifier. have.

In order to achieve the above object, according to a preferred embodiment of the present invention, the first and second switches for switching the signal input from the first and second input port in two paths; A combiner connected to one of the two paths of the first and second switches to adjust the power of the two input signals to substantially one-half and combine them; A third switch for switching the signal output from the combiner into two paths; A fourth switch for switching the other one of the two paths of the first switch and one path of the third switch to output the first output port; And a fifth switch for switching the other one of the two paths of the second switch and the other path of the third switch to output to the second output port.

Here, the first attenuator for adjusting the loss of the path connected to the first and fourth switch is further included, and the second attenuator for adjusting the loss of the path connected to the second and fifth switch further includes. do.

In this case, when the amplifiers connected to the fourth and fifth switches operate normally, the first path connected to the first and fourth switches and the second path connected to the second and fifth switches, respectively. When the signal is bypassed and any one of the amplifiers connected to the fourth and fifth switches is broken, the signal input to the first input port is the first switch, the combiner, the third switch, And a third path connected to a switch in contact with a faulty amplifier, wherein the signal input to the second input port contacts the second switch, the combiner, the third switch, and a faulty amplifier. It is output through the fourth path connected to the switch.

Further, according to another embodiment of the present invention, the first and second switches for switching the signal input from the first and second input port in two paths; A coupler connected to one of the two paths of the first and second switches to adjust the power of the two input signals to substantially one-half, and couple them; A third switch for switching the other one of the two paths of the first switch and one path output from the coupler to output to the first output port; And a fourth switch for switching the other one of the two paths of the second switch and one path output from the coupler to output the second output port to the second output port.

Here, the first attenuator for adjusting the loss of the path connected to the first and third switch is further included, and the second attenuator for adjusting the loss of the path connected to the second and fourth switch is further included. And a third attenuator for adjusting the loss of the path connected to the coupler and the third switch, and further comprising a fourth attenuator for adjusting the loss of the path connected to the coupler and the fourth switch.

In this case, when the amplifiers connected to the third and fourth switches operate normally, the first path connected to the first and third switches and the second path connected to the second and fourth switches, respectively. When a signal is bypassed and any one of the amplifiers connected to the third and fourth switches has a fault, the signal input to the first input port may cause the first switch, the coupler, and the amplifier not to fail. The signal is output through the third path connected to the switch in contact with the switch, and the signal input to the second input port is output through the fourth path connected to the switch in contact with the second switch, the coupler, and the amplifier which has not failed. .

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same components have the same number as much as possible even if displayed on different drawings. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a structural diagram illustrating an RF system to which the present invention is applied.

As shown in the figure, the redundancy switch apparatuses (RSAs) 210 and 211 of the present invention are arranged in front of the amplifiers 110 to 113 for amplifying a signal. If one of the amplifiers fails, it is responsible for switching the signal to the other amplifier.

For convenience of description, a case in which four amplifiers are described as an example in the system to which the present invention is applied is not limited thereto.

In the RF system to which the present invention is applied, it can be seen that the spare amplifier 120 does not need to be used when compared with FIG. 1.

3 is a structural diagram of a first embodiment of a redundancy switch device according to the present invention.

As shown in the figure, the redundancy switch device of the present invention, the first to fourth switch unit (single-pole double-throw (hereinafter referred to simply as 'SPDT') 310 ~ 340, 3dB coupler (coupler) 350, first to fourth attenuators (commonly referred to as 'PAD', hereinafter referred to as 'PAD') (360 to 390), and the J3 and J4 ports connected to an amplifier. Port.

In general, SPDT refers to a device in which one common terminal may be connected to one of two other contacts, and the first and second SPDTs 310 and 320 respectively receive one signal input from the J1 port and the J2 port. It is responsible for selecting one of two paths. In addition, the third and fourth SPDTs 330 and 340 are responsible for selecting one of two input paths and outputting them to the J3 port and the J4 port, respectively.

The 3dB coupler 350 is responsible for adjusting the power of the input signal by 1/2 to combine them. The first to fourth PADs 360 to 390 are in charge of adjusting a loss of each path.

Referring to the operation of the redundancy switch device of the present invention in detail as follows. For convenience of explanation, the redundancy switch device of reference numeral 210 of FIG. 2 will be described. The J3 and J4 ports, which are output ports of the redundancy switch device 210, are arranged to be connected to two amplifiers 110 and 111, respectively.

When the amplifiers 110 and 111 of FIG. 2 operate normally, signals input to the J1 port are bypassed to the paths of the first SPDT 310, the first PAD 360, and the third SPDT 330. The signal input to the J2 port is bypassed to the paths of the second SPDT 320, the second PAD 370, and the fourth SPDT 340. This will be the same as the signal flow in the conventional system of FIG.

If the amplifier 110 fails, the first SPDT 310 switches the switch so that the signal is connected to the 3dB coupler 350, and the second SPDT 320 also switches the switch to signal the signal. 3dB coupler 350 to be connected. The 3dB coupler 350 combines the power of each signal by 1/2, and transfers the combined signal to the fourth PAD 390. Thereafter, the signal passing through the fourth PAD 390 passes through the fourth SPDT 340 and is output only to the J4 port. At this time, an external controller (not shown) controls the third SPDT 330 so that the third switch 330 is shorted. As a result, the signal passing through the 3dB coupler 350 is directed only to the fourth SPDT 340.

The two different signals input to the J1 and J2 ports are reduced in half and input to the amplifier of reference numeral 111. The amplifier 111 amplifies the input signal and delivers the signal to the transmitting and receiving terminal.

4 is a structural diagram of a second embodiment of a redundancy switch device according to the present invention.

As shown in the figure, the redundancy switch device of the present invention includes a first to fifth SPDT (410 ~ 450), a coupler 460, the first and second PAD (470, 480).

As illustrated in FIG. 3, the first and second SPDTs 410 and 420 are responsible for selecting one signal input from the J1 port and the J2 V port as a desired path among two paths, respectively. The fifth SPDT 450 is responsible for selecting one signal input from the combiner 460 as a desired one among two paths, and the third and fourth SPDTs 430 and 440 are one of two input paths. It is responsible for outputting to J3 port and J4 port by selecting.

The first and second PADs 470 and 480 are responsible for controlling the loss of each path.

The combiner 460 is responsible for adjusting the power of the input signal by 1/2 to combine them.

The operation of FIG. 4 is also the same as described with reference to FIG. 3.

If there is no failure of the amplifier, the signal input to the J1 and J2 ports is bypassed, but if the reference 111 amplifier of FIG. 2 with the J4 port as input fails, the two signals input to the J1 and J2 ports are The power may be input to the combiner 460 to adjust the power to 1/2, and then may be combined and output to the amplifier 110 through the fifth SPDT 450 and the third SPDT 430.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes can be made in the art without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

The present invention as described above has the effect of avoiding the use of a spare amplifier by switching to the path of a normally operating amplifier in the event of a failure of the amplifier, thereby reducing the additional cost.

In addition, the present invention has the effect of contributing to the stable signal flow in the system by transmitting the signal of the amplifier having a failure at the front end of the amplifier to a normally operating amplifier.

Claims (12)

First and second switches for switching signals input from the first and second input ports into two paths; A combiner connected to one of the two paths of the first and second switches to adjust the power of the two input signals to substantially one-half and combine them; A third switch for switching the signal output from the combiner into two paths; A fourth switch for switching the other one of the two paths of the first switch and one path of the third switch to output the first output port; And And a fifth switch for switching the other one of the two paths of the second switch and the other path of the third switch to output to the second output port. The redundancy switch device of claim 1, further comprising a first attenuator for adjusting a loss of a path connected to the first and fourth switches. The redundancy switch device of claim 1, further comprising a second attenuator for adjusting a loss of a path connected to the second and fifth switches. According to any one of claims 1 to 3, When the amplifier connected to the fourth and fifth switches, respectively, the normal operation of the first path connected to the first and fourth switches, and the first Redundancy switch device that the signal is bypassed to the second path connected to the second and fifth switches. The signal input to the first input port according to any one of claims 1 to 3, wherein when any one of the amplifiers connected to the fourth and fifth switches is faulty, the signal input to the first input port is applied to the first switch, A third path connected to the coupler, the third switch, and a switch in contact with an unsuccessful amplifier, and a signal input to the second input port is the second switch, the combiner, the third switch; And a redundancy switch device output through a fourth path connected to a switch in contact with an amplifier that has not failed. First and second switches for switching signals input from the first and second input ports into two paths; A coupler connected to one of the two paths of the first and second switches to adjust the power of the two input signals to substantially one-half, and couple them; A third switch for switching the other one of the two paths of the first switch and one path output from the coupler to output to the first output port; And And a fourth switch for switching the other one of the two paths of the second switch and one path output from the coupler and outputting the second path to the second output port. 7. The redundancy switch device of claim 6, further comprising a first attenuator for adjusting the loss of paths connected to the first and third switches. 7. The redundancy switch device of claim 6, further comprising a second attenuator for adjusting the loss of paths connected to the second and fourth switches. 7. The redundancy switch device of claim 6, further comprising a third attenuator for adjusting the loss of the path to the coupler and the third switch. 7. The redundancy switch device of claim 6, further comprising a fourth attenuator for adjusting the loss of the path to the coupler and the fourth switch. 11. The method of any one of claims 6 to 10, wherein the first path connected to the first and third switches when the amplifier connected to the third and fourth switches operates normally. Redundancy switch device that the signal is bypassed in the second path connected to the second and fourth switches. The switch according to any one of claims 6 to 10, wherein when any one of the amplifiers connected to the third and fourth switches has a fault, the switch connected to the failed amplifier is short-circuited and the first input. The signal input to the port is output through a third path connected to the first switch, the coupler and a switch in contact with a faulty amplifier, the signal input to the second input port is the second switch, the coupler And a redundancy switch device output through a fourth path connected to a switch in contact with an amplifier that has not failed.

Images