KR100618093B1 - Switch matrix isolation deterioration prevention structure for wireless translator of TDD system - Google Patents

Abstract

The present invention provides a switch matrix for a TDD type wireless repeater for switching a downlink signal transmitted from a base station and an uplink signal transmitted from a mobile station, the sum of the lengths of the first and third semiconductor cables; The difference in length with respect to the sum of the lengths of the second and fourth seminar cables is 1/2 wavelength, and the sum of the lengths of the first and fourth seminar cables and the second semi It is characterized in that the length difference with respect to the sum of the lengths of the ridge cable and the third semi-rigid cable is 1/2 wavelength.

Therefore, the lengths of the two feedback paths differ by one-half wavelength, and the phase difference of the signals fed back to the two paths becomes 180 ° to cancel each other, resulting from the synthesis of the signals fed back to the two paths. The degradation of the degree of separation can be prevented.

Therefore, it is a very useful invention such that the convenience in use is improved and the merchandise is more improved.

Repeater, Teddy, Separate, Semiridge Cable, Switch, Amplifier

Description

Switch matrix isolation deterioration prevention structure for wireless translator of TDD system}             

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram of a matrix switch for a TDD type wireless repeater according to the present invention.

Figure 2 is a block diagram of a matrix switch for a wireless TD type of the general TV.

Explanation of symbols on the main parts of the drawings

A: first connection point B: second connection point

C: third connection point D: fourth connection point

200: first switch 201: first semi-conductor cable

202: second switch 203: amplifier

204: third switch 205: three second semi-conductor cable

206: fourth switch 207: third semi-conductor cable

208: fourth semi-conductor cable

The present invention relates to a structure for preventing deterioration of switch matrix separation for a TDD type wireless repeater. More specifically, the length of two feedback paths due to an uplink signal and a downlink signal differs by 1/2 wavelength. The phase difference of the signals fed back through the two paths is offset by 180 °, thereby preventing deterioration of the separation caused by the synthesis of the signals fed back through the two paths.

In general, the TDD (Time Division Duplex) type portable Internet wireless repeater which divides the inside of one frame for transmission and reception for two-way communication at one frequency does not reach the signal of the base station well. Improves call quality in shadowed areas.

That is, the signal output from the base station is installed in a weak place, amplifies the weak signal and outputs it to the mobile station, thereby serving to provide a better mobile communication service.

FIG. 2 is a configuration diagram of a matrix switch for a conventional TDD radio station. The downlink from the base station to the mobile station includes a first connection point A to which a signal output from the base station is connected, and the first connection point A. FIG. The signal received by the first switch 100 to select one of the uplink output signal and the downlink input, and the first semi-srithing cable 101 for transmitting the downlink signal selected by the first switch 100 And a second switch 102 for connecting the downlink signal passing through the first semi-conductor cable 101 and a second connection point B for connecting the downlink signal passing through the second switch 102. An amplifier 103 for amplifying the signal passing through the second connection point B, a third connection point C for connecting the signal amplified by the amplifier 103, and the third connection point C. A third switch 104 for selecting whether to send a signal connected to the downlink or the uplink And a second switch cable 105 for transmitting the signal selected by the third switch 104 to the downlink, and a fourth switch for selecting the uplink signal and the signal passing through the second storage cable 105. And a fourth connection point D.

The uplink from the mobile station to the base station includes a fourth access point D to which a signal output from the mobile station is connected, and a signal received at the fourth access point D includes one of an uplink output signal and a downlink input. The fourth switch 106 to select the third, the third semi-segment cable 107 for transmitting the downlink signal selected by the fourth switch 106, and the uplink passed through the third semi-sage cable 107 And a second connection point B for connecting a signal, and a second connection point B for connecting an uplink signal passing through the second switch 102, and a signal passing through the second connection point B Selecting whether to send the amplifier 103 to be amplified, the third connection point (C) to which the signal amplified by the amplifier 103 is connected, and the signal connected to the third connection point (C) in a downlink or uplink A third switch 104 and a fourth signal for transmitting a signal selected by the third switch 104 to the uplink Consists of a pre-support cable 108 and the first switch 100 and the first connection point (A) to said fourth semi ridge cable (108) select a signal and a downlink signal through the.

Looking at the downlink operation of the matrix switch for a conventional TDD wireless instrument configured as described above, the downlink signal transmitted from the base station is transmitted to the first switch 100 after being connected to the first access point (A), The downlink input signal selected by the first switch 100 is transmitted to the second switch 102 through the first cable 100, and the signal selected by the second switch 102 is the second connection point. It is connected to the external amplifier 103 via (B).

After the signal amplified by the amplifier 103 is connected through the third connection point (C), it is transmitted to the third switch 104, the downlink signal selected by the third switch 104 is a second semi- Passed through the ridge cable 105 to the fourth switch 106, the signal selected by the fourth switch 106 is sent to the mobile station through the fourth connection point (D).

In operation of the uplink, the uplink signal transmitted from the mobile station is transmitted to the fourth switch 106 after being connected to the fourth access point D, and the uplink input signal selected by the fourth switch 106. Is transmitted to the second switch 102 through the third cable 107, the signal selected by the second switch 102 is connected to the external amplifier 103 through the second connection point (B). .

After the signal amplified by the amplifier 103 is connected through the third connection point C, the signal is transmitted to the third switch 104, and the uplink signal selected by the third switch 104 is the fourth semi-conductor. Passed through the ridge cable 108 to the first switch 100, the signal selected by the first switch 100 is transmitted to the base station through the first connection point (A).

However, the above-described general Tidi-based wireless switch for matrix switch has a problem that the isolation is deteriorated by about 3dB by synthesizing a signal fed back through two paths.

Accordingly, an object of the present invention is to solve the conventional problems as described above, so that the length of the two feedback paths differ by 1/2 wavelength, so that the phase difference of the signal fed back to the two paths is 180 °. By canceling each other so that the deterioration of the separation due to the synthesis of the signal fed back to the two paths to provide a deterioration prevention structure of the switch matrix separation for the TDD-type wireless repeater.

Another object of the present invention is to provide a structure for preventing the deterioration of the switch matrix separation for the TDD type wireless repeater to improve the convenience of use and to improve the marketability.

In accordance with an aspect of the present invention, there is provided a structure for preventing deterioration of a switch matrix separation for a TDD type wireless repeater, including: a first access point for transmitting a downlink signal output from a base station and transmitting an uplink signal to the base station; An amplifier for amplifying the downlink signal and the uplink signal, a second connection point for transmitting the downlink signal and an uplink signal to the amplifier, and receiving the downlink signal and the uplink signal output from the amplifier A third access point, a fourth access point for transmitting an uplink signal output from the mobile station and transmitting a downlink signal to the mobile station, a downlink signal connected to the first access point, and transmitted through the first semi-conductor cable; A first switch for selecting any one of uplink signals transmitted from the fourth medium cable, and the second connection point A second switch configured to select one of a downlink signal transmitted from the first cable and an uplink signal transmitted from the third cable, and connected to the third connection point; A third switch for selecting any one of a downlink signal transmitted through a two-semester cable and an uplink signal transmitted through the fourth-stage cable, and connected to the fourth connection point and transmitted from the second-stage cable In the fourth switch for selecting any one of the downlink signal and the uplink signal transmitted to the third cable, the sum of the length of the first cable and the third cable, the third cable, The length difference of the sum of the lengths of the semi-rigid cable and the fourth semi-conductor cable is 1/2 wavelength, and the first and fourth semi-conductor cables And the total length of the second semi-ridge cables and the length of the sum of the length of the cable car is a third semi-ridge as such that the half-wave, characterized.

Accordingly, by canceling the signals fed back through the two paths with each other, it is possible to prevent deterioration in the degree of separation due to the synthesis of the signals fed back through the two paths.

In addition, the ease of use is improved, and the merchandise is more improved.

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 matrix switch for a Teddy-type wireless repeater according to the present invention, based on FIG. 1 attached to an example of the deterioration prevention structure of the switch matrix for a Teddy-type wireless repeater according to the present invention It is as follows.

Looking at the downlink from the base station to the mobile station, the first access point (A) to which the signal output from the base station is connected, and the signal received at the first access point (A) is one of the uplink output signal and the downlink input Downlink signal passing through the first switch 200 to be selected, the first semi-conductor cable 201 transmitting the downlink signal selected by the first switch 200, and the first semi-conductor cable 201 The second switch 202 for connecting the second switch and the second connection point (B) for connecting the downlink signal passing through the second switch 202, the signal passing through the second connection point (B) is amplified And a third connection point (C) to which the signal amplified by the amplifier 203 is connected, and a third connection point (C) for selecting whether to send a signal connected to the third connection point (C) in a downlink or an uplink. Three switches 204 and the signal selected by the third switch 204 is sent downlink 180 degrees A second semi-ridge consists of a cable 205 and the fourth switch 206 and the fourth connection point (D) for selecting a signal and an uplink signal passes through the second semi-ridge cable (205) to change the.

In the uplink from the mobile station to the base station, the fourth access point (D) to which the signal output from the mobile station is connected, and the signal received at the fourth access point (D) are one of the uplink output signal and the downlink input. A fourth switch 206 for selecting a dog, a third semiconductor cable 207 for transmitting a downlink signal selected by the fourth switch 206, and an upward direction through the third semiconductor cable 207 A second switch 202 for connecting a link signal, and a second connection point B for connecting an uplink signal passing through the second switch 202, and a signal passing through the second connection point B. Selects whether the amplifier 203 to be amplified, the third connection point C to which the signal amplified by the amplifier 203 is connected, and the signal connected to the third connection point C are transmitted in downlink or uplink. The third switch 204 and the signal selected by the third switch 204 to the uplink That is the fourth semi-ridge consist of cable 208, a first switch 200 and the first connection point (A) to said fourth semi ridge cable 208 select the signal with the downlink signal passing through.

Looking at the downlink operation of the TMD matrix switch for a wireless main instrument according to the present invention configured as described above, the downlink signal transmitted from the base station is connected to the first access point (A) and then transferred to the first switch 200. The downlink input signal selected by the first switch 200 is transmitted to the second switch 202 through the first semi-stage cable 201, and the signal selected by the second switch 202 is It is connected to the external amplifier 203 through the second connection point (B).

The signal amplified by the amplifier 203 is connected to the third switch 204 after being connected through the third connection point C, and the downlink signal selected by the third switch 204 is a second semi-semi. In the process of passing through the ridge cable 205, the phase of 180 ° is converted and transmitted to the fourth switch 206, and the signal selected by the fourth switch 206 is sent to the mobile station through the fourth connection point D. do.

The uplink signal transmitted from the mobile station is transmitted to the fourth switch 206 after being connected to the fourth access point D, and the uplink input signal selected by the fourth switch 206. Is transmitted to the second switch 202 through the third cable 207, the signal selected by the second switch 202 is connected to the external amplifier 203 through the second connection point (B). .

After the signal amplified by the amplifier 203 is connected through the third connection point C, the signal is transmitted to the third switch 204, and the uplink signal selected by the third switch 204 is the fourth semi-conductor. Passed through the ridge cable 208 to the first switch 200, the signal selected by the second switch 200 is transmitted to the base station through the first connection point (A).

The section from the first connection point (A) to the fourth connection point (D), which is a path of the leakage signal between the switches generated through the process, is a section consisting of the first and third semiconductor cables 201 and 207. And a second segment cable 205 and a fourth segment cable 208. The length difference between the two sections is 1/2 wavelength, so that a phase difference of 108 ° is generated. The feedback signal between the paths is canceled out.

Similarly, the section from the second connection point (B) to the third connection point (C) is composed of a section consisting of the first and fourth storage cable 201 and 208, the second and the second cable (205) The third segment cable 207 is divided into sections, and the length difference between the two sections is 1/2 wavelength, so that a phase difference of 108 ° is generated so that the feedback signal between the two paths is cancelled.

The present invention can be variously modified within the scope without departing from the basic concept according to the needs of those skilled in the art.

As described above, according to the present invention, the lengths of the two feedback paths differ by one-half wavelength, and the phase differences of the signals fed back through the two paths become 180 ° to cancel each other. There is an effect to prevent the deterioration of the separation degree due to the synthesis of the signal fed back to the path.

Therefore, it is a very useful invention such that the convenience in use is improved and the commercial property is improved.

Claims (1)

A first access point A for transmitting a downlink signal output from a base station and transmitting an uplink signal to the base station, an amplifier 103 for amplifying the downlink signal and an uplink signal, and the amplifier 103. A second connection point B for transmitting the downlink signal and an uplink signal, a third connection point C for receiving the downlink signal and an uplink signal output from the amplifier 103, and a mobile station output from the mobile station; A fourth access point (D) for transmitting an uplink signal and transmitting a downlink signal to the mobile station, a downlink signal connected to the first access point (A), and transmitted through the first medium cable (101); A first switch 100 for selecting any one of the uplink signals transmitted from the fourth storage cable 108 and the second connection point B are connected to each other from the first storage cable 101. Downlink signal transmitted and the A second switch 102 for selecting any one of the uplink signals transmitted from the third storage cable 107 and the third connection point C are connected to the second storage cable 105. A third switch 104 for selecting any one of a downlink signal and an uplink signal transmitted through the fourth seminar cable 108, and the second connection point connected to the fourth connection point D In the fourth switch 106 for selecting any one of the downlink signal transmitted from the cable 105 and the uplink signal transmitted to the third medium cable 107, The difference in length with respect to the sum of the lengths of the first and third storage cables 201 and 207 and the lengths of the second and fourth storage cables 205 and 208 is 1 /. In addition to the two wavelengths, the sum of the lengths of the first and fourth storage cables 201 and 208, and the length of the second and third storage cables 205 and 207. Deterioration prevention structure of the switch matrix separation for a TD type wireless repeater, characterized in that the length difference of the sum of the lengths is 1/2 wavelength.

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