JP2016019033A - Relay device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a relay device that is capable of communication in accordance with time division duplex using one amplifier and is inexpensive and compact.SOLUTION: A relay device includes: first and second input/output terminals into which first and second link signals are input respectively; an amplifier; an input terminal and an output terminal of the amplifier; a switch circuit provided between the first and second input/output terminals; a detection circuit for figuring out which terminal the link signal is input, the first input/output terminal or second input/output terminal; and a switching control circuit for performing switching control of the switch circuit. If the detection circuit detects the first (second) link signal, the switching control circuit performs switching control to configure a first (second) transmission path so that the first (second) link signal is supplied to the input terminal of the amplifier, and the first (second) link signal amplified by the amplifier is output from the second (first) input/output terminal.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a relay device used for wireless communication or wired communication.

  The relay device is a device that amplifies and shapes a signal by radio waves or light and relays it. For example, when performing wireless communication, a relay device is generally provided between a base station and a terminal. The relay device is provided, for example, on a radio tower or a rooftop of a building, and has a function of expanding a communicable range between the base station and the terminal. Further, the relay device has an amplifier, for example, amplifies a signal received from the base station side, and transmits the amplified signal to the terminal.

  In Patent Document 1, input light from the first and second optical amplifiers, the first and second optical input / output ports, and the first optical input / output port is supplied to the input of the first optical amplifier. First light distribution means for supplying output light of the second optical amplifier to the first optical input / output port, and input light from the second optical input / output port to the input of the second optical amplifier. A bidirectional optical amplifying device having a second optical distribution means for supplying output light of the first optical amplifier to a second optical input / output port is disclosed.

Japanese Patent Laid-Open No. 2001-148665

  The relay device can be configured to perform bidirectional signal transmission (duplex), for example, as described in Patent Document 1. In such an apparatus capable of duplexing, two amplifiers corresponding to the transmission direction are provided. In the duplex operation, a transmission path passing through one of these two amplifiers is selected according to the transmission direction, and a signal is transmitted through the selected transmission path.

  On the other hand, there is a time division duplex (TDD) system as a communication system. The TDD method is a method of transmitting and receiving signals while dividing a signal (information) on a time axis and switching a signal transmission direction at high speed. For this reason, when TDD relaying is performed in a relay device that supports duplexing, a downlink amplifier and an uplink amplifier are provided, and duplexing is performed while switching the downlink signal and uplink signal by time division. .

  In general, it is desirable that electronic components are inexpensive and compact.

  The present invention has been made in view of the above points, and an object thereof is to provide an inexpensive and compact relay device.

  The relay device according to the present invention includes first and second input / output terminals to which first and second link signals are input, an amplifier, an input terminal and an output terminal of the amplifier, and first and second input terminals. A switching circuit provided between the output terminal, a detection circuit that detects whether a link signal is input to any of the first and second input / output terminals, and a switching control circuit that performs switching control of the switching circuit When the first link signal is detected by the detection circuit, the switching control circuit supplies the first link signal to the input terminal of the amplifier, and the first link signal amplified by the amplifier The first transmission path is configured to be output from the second input / output terminal, and when the second link signal is detected by the detection circuit, the second link signal is supplied to the input terminal of the amplifier, and the amplifier Amplified by The second link signal is characterized by forming the switching control which constitutes the second transmission path so as to be outputted from the first output terminal.

(A) And (b) is a figure which shows the structure of the relay apparatus which concerns on Example 1, (c) is the relationship between the switching signal in the relay apparatus which concerns on Example 1, the connection state of a switch circuit, and a transmission direction. FIG. (A) And (b) is a figure which shows the transmission path | route of the signal at the time of operation | movement of the relay apparatus based on Example 1. FIG. It is a figure which shows the structure of the relay apparatus which concerns on the modification 1 of Example 1. FIG. (A) And (b) is a figure which shows the structure of the relay apparatus which concerns on the modifications 2 and 3 of Example 1, respectively.

  For example, in duplex communication by time division such as the TDD method, bidirectional signal transmission is not performed simultaneously. That is, when two amplifiers are provided, the two amplifiers are not used simultaneously. In addition, the amplifier is expensive and large in size compared to other parts.

  The inventors of the present invention perform bidirectional communication as in the TDD system, for example. However, when bidirectional communication is not performed at the same time, one amplifier may be shared for bidirectional transmission. Focused on being possible. In addition, the component parts of the device were examined in accordance with this, and attention was paid to reducing the component cost, and to reducing the size of the device and thus the casing (case) surrounding the device.

  Examples of the present invention will be described in detail below.

  FIG. 1A is a diagram illustrating a configuration of the relay device 10 according to the first embodiment. The relay device 10 includes first and second input / output terminals T1 and T2 to which a link signal is input. When the first link signal S1 is input to the first input / output terminal T1, the relay device 10 amplifies the first link signal S1 and outputs it from the second input / output terminal T2. In addition, when the second link signal S2 is input to the second input / output terminal T2, the relay device 10 amplifies the second link signal S2 and outputs the amplified signal from the first input / output terminal T1. In the present embodiment, the first link signal S1 and the second link signal S2 are signals by a time division duplex method.

  In the present embodiment, a case where the relay apparatus 10 relays a radio signal between the base station BS and the terminal apparatus TD will be described. Specifically, the first input / output terminal T1 is connected to the first antenna A1. The second input / output terminal T2 is connected to the second antenna A2. The terminal device TD is a mobile terminal such as a radio, a mobile phone, a smartphone, or a tablet, for example.

  The first link signal S1 received by the first antenna A1 is amplified by the amplifier of the relay device 10 and transmitted from the second antenna A2. The second link signal S2 received by the second antenna A2 is amplified by the amplifier of the relay device 10 and transmitted from the first antenna A1. That is, the first link signal S1 is a downlink signal from the base station BS to the terminal device TD, and the second link signal S2 is an uplink signal from the terminal device TD to the base station BS. The relay device 10 is used for a communication method using time division duplex.

  In the present embodiment, the operation of the relay device 10 when the radio signal (first link signal S1) from the base station BS is relayed to the terminal device TD is referred to as downlink, and the first link signal at the time of downlink The transmission path of S1 is referred to as a downlink path (first transmission path) P1. Further, the operation of the relay apparatus 10 when the radio signal (second link signal S2) from the terminal apparatus TD is relayed to the base station BS is referred to as uplink, and the transmission path of the second link signal S2 at the uplink time. Is referred to as an uplink path (second transmission path) P2. Note that the second transmission path P2 is a transmission path in the opposite direction to the first transmission path P1.

  FIG. 1B is a block diagram illustrating a detailed structure of the relay device 10. The relay device 10 has an amplifier circuit 11 including an amplifier AP. The amplifier circuit 11 includes an amplifier AP, a switch circuit SWC provided between the input terminal and the output terminal of the amplifier AP, and the first and second input / output terminals T1 and T2. The switch circuit SWC includes a first switch circuit 11A connected between the output terminal of the amplifier AP and the first input / output terminal T1, and a first switch circuit connected between the input terminal of the amplifier AP and the second input / output terminal T2. 2 switch circuit 11B.

  The first switch circuit 11A is connected between the SPDT (single pole double throw) switch (first SPDT switch) SW1 connected to the output terminal of the amplifier AP, and between the SPDT switch SW1 and the first input / output terminal T1. SPDT switch (second SPDT switch) SW2. The second switch circuit 11B includes an SPDT switch (third SPDT switch) SW3 connected to the input terminal of the amplifier AP, and an SPDT switch (fourth switch) connected between the SPDT switch SW3 and the second input / output terminal T2. SPDT switch) SW4. The SPDT switch SW1 is connected to the SPDT switch SW4, and the SPDT switch SW2 is connected to the SPDT switch SW3. Each of the SPDT switches SW1 to SW4 is composed of a semiconductor element using, for example, a diode or a transistor.

  The common terminal (common terminal) c of the SPDT switch SW1 is connected to the output terminal of the amplifier AP. The first selection terminal a of the SPDT switch SW1 is connected to the first selection terminal a of the SPDT switch SW2. The second selection terminal b of the SPDT switch SW1 is connected to the second selection terminal b of the SPDT switch SW4. The common terminal c of the SPDT switch SW2 is connected to the first input / output terminal T1. The second selection terminal b of the SPDT switch SW2 is connected to the second selection terminal b of the SPDT switch SW3.

  The common terminal c of the SPDT switch SW3 is connected to the input terminal of the amplifier AP. The first selection terminal a of the SPDT switch SW3 is connected to the first selection terminal a of the SPDT switch SW4. The common terminal c of the SPDT switch SW4 is connected to the second input / output terminal T2.

  The relay device 10 includes a detection circuit 12 that detects which of the first and second input / output terminals T1 and T2 the link signal is input to. When the detection circuit 12 detects the first link signal (downlink signal) S1, the relay device 10 relays the first link signal S1 through the first transmission path P1. When the detection circuit 12 detects the second link signal (uplink signal) S2, the relay device 10 relays the second link signal S2 through the second transmission path P2.

  The relay device 10 includes a switching control circuit 13 that performs switching control of the switch circuit SWC based on the detection result of the detection circuit 12. The switching control circuit 13 generates a switching signal SS for switching between the first transmission path P1 and the second transmission path P2, and supplies the switching signal SS to the first and second switch circuits 11A and 11B.

  When the detection circuit 12 detects the first link signal S1, the switching control circuit 13 supplies the first link signal S1 to the input terminal of the amplifier AP, and the first link signal S1B amplified by the amplifier AP. Switching control for configuring the first transmission path (downlink path) P1 is performed so that (see FIG. 2A) is output from the second input / output terminal T2. Further, when the detection circuit 12 detects the second link signal S2, the switching control circuit 13 is supplied with the second link signal S2 to the input terminal of the amplifier AP, and is amplified by the amplifier AP. Switching control for configuring the second transmission path (uplink path) P2 is performed so that the signal S2B (see FIG. 2B) is output from the first input / output terminal T1.

  More specifically, when the first link signal S1 is detected by the detection circuit 12, the switching control circuit 13 receives the first link signal S1 from the first input / output terminal T1 as the first switch circuit 11A. To the amplifier AP via the second switch circuit 11B, and the first link signal S1B amplified by the amplifier AP is transmitted from the first switch circuit 11A to the second switch circuit 11B to be transmitted to the second input circuit. The first and second switch circuits 11A and 11B are switched so as to be output from the output terminal T2.

  Further, when the detection circuit 12 detects the second link signal S2, the switching control circuit 13 receives the second link signal S2 from the second input / output terminal T2 from the second switch circuit 11B to the amplifier AP. The first and second switch circuits 11A and 11B are supplied so that the second link signal S2B amplified by the amplifier AP is transmitted to the first switch circuit 11A and output from the first input / output terminal T1. Is switched.

  The detection circuit 12 includes a directional coupler (hereinafter simply referred to as a coupler) 12A connected between the second input / output terminal T2 and the second switch circuit 11B, and a signal from the coupling port c of the coupler 12A. And a high frequency detector (hereinafter simply referred to as a detector) 12B. In the detection circuit 12, the detector 12B detects the input of the link signal by detecting the carrier signal (unmodulated wave) of the link signal (second link signal S2 in this embodiment).

  The directional coupler 12A is composed of, for example, a three-port directional coupler. The coupler 12A can be formed by a metal wiring pattern on a substrate such as a microstrip line. The coupler 12A can also be configured by an element using a ceramic material. The detector 12B is composed of a semiconductor element using, for example, a diode or a resistor.

  The input port i of the coupler 12A is connected to the second input / output terminal T2, and the output port o is connected to the second switch circuit 11B (common terminal c of the SPDT switch SW4 in this embodiment). The coupling port c of the coupler 12A is connected to the detector 12B. When the second link signal S2 is input to the second input / output terminal T2, the second link signal S2 is supplied from the coupling port c to the detector 12B. The detector 12B generates a DC voltage corresponding to the level of the link signal from the coupler 12A.

  The switching control circuit 13 includes a voltage conversion circuit (hereinafter simply referred to as a conversion circuit) 13A that converts the DC voltage generated by the detector 12B into a switching signal SS, and a switching signal output that outputs the switching signal SS to the amplifier circuit 11. A circuit (hereinafter simply referred to as an output circuit) 13B. The conversion circuit 13A is connected to the output circuit 13B, and the output circuit 13B is connected to control terminals (not shown) of the SPDT switches SW1 to SW4 in the first and second switch circuits 11A and 11B of the amplifier circuit 11. . The conversion circuit 13A converts the DC voltage generated by the detector 12B into a switching signal SS that matches the logic level necessary for switching the terminals of the SPDT switches SW1 to SW4.

  FIG. 1C is a diagram illustrating the relationship between the logic level of the switching signal SS input from the switching control circuit 13 to the amplifier circuit 11 and the connection state of the SPDT switches SW1 to SW4. For ease of understanding, the signal transmission direction is also shown. The switching signal SS has two types of logic levels, a high level (H) and a low level (L). At the time of downlink, that is, when the first link signal S1 is input from the first input / output terminal T1 (first antenna A1), the first and second switch circuits 11A and 11B have L level. A switching signal SS is input. Similarly, at the time of uplink, that is, when the second link signal S2 is input from the second input / output terminal T2 (second antenna A2), the switching signal SS at the H level is the first signal of the amplifier circuit 11. And the second switch circuits 11A and 11B.

  At the time of downlink, the common terminal c is connected to the second selection terminal b in each of the SPDT switches SW1 to SW4. That is, the circuit between the terminals a and c is in an open (off) state, and the terminal between the terminals bc is in a closed (on) state. Thereby, the first transmission path P1 is configured. On the other hand, at the time of downlink, in each of the SPDT switches SW1 to SW4, the common terminal c is connected to the first selection terminal a. That is, the terminal a-c is closed (on), and the terminal b-c is open (off). Thereby, the second transmission path P2 is configured. FIG. 1B shows the connection state of the switches at the time of uplink.

  FIG. 2A is a diagram schematically illustrating the first transmission path P1 of the first link signal S1 in the relay apparatus 10 at the time of downlink. Note that FIG. 2A and FIG. 2B described later are similar to FIG. 1B, but some lines and characters are omitted for clarity. In FIG. 2A, the first transmission path P1 is indicated by a solid arrow, and the switching signal SS (L level) is indicated by a broken arrow.

  The first link signal S1 transmitted from the base station BS is received by the first antenna A1 and input to the device 10 from the first input / output terminal T1. At this time, since no signal is input to the second input / output terminal T2, no signal is input to the input port i of the coupler 12A. Therefore, no signal is input to the detector 12B, and the switching signal SS becomes L level. Thereby, the L-level switching signal SS is supplied from the output circuit 13B to the control terminals of the SPDT switches SW1 to SW4. Accordingly, in each of the SPDT switches SW1 to SW4, the terminal b-c is turned on (conductive state), and the first transmission path P1 is configured.

  The first link signal S1 is propagated from the first input / output terminal T1 through the SPDT switch SW2 and the SPDT switch SW3 in this order, and is input to the amplifier AP and amplified, and the first link signal (amplified signal) S1B is amplified. It becomes. The amplified signal S1B is propagated through the SPDT switch SW1 and the SPDT switch SW4 in this order, and is supplied to the output port o of the coupler 12A. The amplified signal S1B input to the output port o of the coupler 12A is supplied from the input port i to the second input / output terminal T2, and is output from the second input / output terminal T2. The output amplified signal S1B is transmitted from the second antenna A2 and received by the terminal device TD.

  FIG. 2B is a diagram schematically illustrating the second transmission path P2 of the second link signal S2 in the relay apparatus 10 at the time of uplink. In FIG. 2B, the second transmission path P2 is indicated by a solid arrow, and the switching signal SS (H level) is indicated by a broken arrow.

  The second link signal S2 transmitted from the terminal device TD is received by the second antenna A2 and input to the device 10 from the second input / output terminal T2. The second link signal S2 is input to the coupler 12A and output as a high frequency signal from the coupling port c of the coupler 12A. The detector 12B detects the carrier signal of the high-frequency signal, generates a DC voltage, and outputs it to the conversion circuit 13A. The conversion circuit 13A generates an H level switching signal SS. The generated switching signal SS is supplied from the output circuit 13B to the control terminals of the SPDT switches SW1 to SW4. As a result, the terminals bc are turned on in each of the SPDT switches SW1 to SW4, and the second transmission path P2 is configured.

  Note that the second link signal S2 input to the coupler 12A is output to the coupling port c and also output from the output port o to the amplifier circuit 11. At this time, a part of the first carrier signal (unmodulated wave) of the second link signal S2 is amplified before the SPDT switches SW1 to SW4 are switched for the second transmission path P2. Is input. Therefore, a part of the second link signal S2 is input to the output terminal side of the amplifier AP, and a part of the second link signal S2 is lost.

  However, the actual data can be transmitted as complete data if the preamble signal transmitted after the carrier signal and the subsequent modulation signal are not lost. Therefore, it is necessary to design the detection circuit 12, the switching control circuit 13, and the amplifier circuit 11 so that the transmission path of the amplifier circuit 11 is switched at least before the transmission of the carrier signal is completed and the preamble signal is input.

  Next, the second link signal S2 output from the output port o of the coupler 12A is propagated through the SPDT switch SW4 and the SPDT switch SW3 in this order and input to the amplifier AP, and is amplified. (Amplified signal) S2B. The amplified signal S2B is propagated through the SPDT switch SW1 and the SPDT switch SW2 in this order, and is output from the first input / output terminal T1. The output amplified signal S2B is transmitted from the first antenna A1 and received by the base station BS.

  Note that the transmission end timing of the second link signal S2 in the uplink can be detected by appropriately setting the threshold value of the detector 12B at the falling edge of the second link signal S2. . That is, detecting the end of the uplink or switching from the uplink to the downlink by setting the detector 12B and the conversion circuit 13A so that the switching signal SS becomes L level when the signal level becomes a certain value or less. Can do.

  Note that the amplification factor G of the signals S1B and S2B amplified by the relay device 10 is that the amplification factor of the amplifier AP is GA, the insertion loss in each of the SPDT switches SW1 to SW4 is LS, and the insertion loss in the coupler 12A is LC. Then, G = GA− (4 × LS + LC).

  In the present embodiment, one amplifier AP is used as a shared (common) amplifier in the uplink and downlink. Further, a downlink transmission path P1 and an uplink transmission path P2 passing through the shared amplifier AP are configured, and the switching control circuit 13 switches the transmission paths P1 and P2. Therefore, it is possible to minimize the number of amplifiers which are relatively expensive and complicated and have a large size. In addition, the first and second switch circuits 11A and 11B, the detection circuit 12, and the switching control circuit 13, which are other components, can be configured using inexpensive semiconductor elements, and are inexpensive and compact as a whole. 10

  Note that, in consideration of relay quality such as amplification quality, an expensive and high-performance amplifier is often used for a wireless repeater (wireless repeater) that performs duplexing of high-frequency signals. When the relay device 10 according to the present embodiment is used as a wireless repeater, the cost and device size can be greatly reduced.

  In the present embodiment, the case where the first and second switch circuits 11A and 11B are configured by SPDT switches SW1 to SW4 has been described. However, the configuration of the first and second switch circuits 11A and 11B is as follows. It is not limited to this. For example, the first and second switch circuits 11A and 11B can be configured using a DPDT (double pole double throw) switch or the like.

  In the present embodiment, the case where the detection circuit 12 includes the directional coupler 12A and the high frequency detector 12B has been described. However, the configuration of the detection circuit 12 is not limited to this. For example, a receiver capable of detecting the direction of the signal can be used as the detection circuit 12. Although the case where the switching signal SS is output from the switching signal output circuit 13B has been described, the switching signal SS may be directly supplied from the conversion circuit 13A to the first and second switch circuits 11A and 11B. That is, the output circuit 13B can be omitted.

  In this embodiment, the case where the detection circuit 12 (the coupler 12A) is provided between the second input / output terminal T2 and the amplifier circuit 11 has been described. However, the detection circuit 12 includes the first input / output terminal T1. And may be provided between the amplifier circuits 11. Moreover, you may provide in both.

  In the present embodiment, the case where one relay device 10 is provided between the base station BS and the terminal device TD has been described. However, a plurality of relay devices 10 may be provided according to the relay distance or the like.

  FIG. 3 is a diagram illustrating a configuration of the relay device 10A according to the first modification of the first embodiment. The relay device 10A has a configuration for detecting the signal transmission direction without using the directional coupler 12A. Specifically, the relay device 10A includes a detector 12C that is connected to the second input / output terminal T2 and distinguishes and detects inputs of the first and second link signals S1 and S2. For example, the detector 12C includes a receiver that can identify the direction of the signal.

  Similarly to the detection circuit 12, the detector 12C detects which of the first input / output terminal T1 and the second input / output terminal T2 the link signal is input to. The detector 12C detects that the first link signal S1 is input to the first input / output terminal T1 and that the second link signal S2 is input to the second input / output terminal T2. The detector 12C has a function of supplying a switching signal SS for switching the first and second transmission paths P1 and P2 to the first and second switch circuits 11A and 11B of the amplifier circuit 11.

  This modification corresponds to a case where the detection circuit 12 and the switching control circuit 13 in the relay device 10 according to the first embodiment are configured by the detector 12C. As in this modification, it is possible to detect a signal and switch the transmission path without using the directional coupler 12A. The detector 12C may be connected to the first input / output terminal T1 instead of the second input / output terminal T2, or may be connected to both of them.

  FIG. 4A is a diagram illustrating a configuration of the relay device 10B according to the second modification of the first embodiment. The relay device 10B has the same configuration as that of the relay device 10 except that the second input / output terminal T2 and the terminal device TD are connected by wire. In this modification, the terminal device TD is, for example, a transmission / reception radio. The relay device 10B has a first input / output terminal T1 connected to the radio station WS via the first antenna A1. That is, in this modification, the first link signal S1 input to the first input / output terminal T1 is a wireless signal, and the second link signal S2 input to the second input / output terminal T2 is wired. Signal.

  This modification is a configuration example in the case where, for example, the relay apparatus 10 according to the first embodiment is used as a booster provided at the front end of the transceiver. That is, the relay device 10B is used as a radio signal amplifying device at the time of transmission / reception when information such as voice is transmitted / received between the radio station WS and the terminal device TD.

  FIG. 4B is a diagram illustrating a configuration of a relay device 10C according to the third modification of the first embodiment. The relay device 10C has the same configuration as the relay device 10 except that each of the first and second input / output terminals T1 and T2 is connected to the provider PV and the terminal device TD by wire. Yes. In this modification, the terminal device TD is an information device such as a television or a personal computer. That is, in this modification, each of the first and second link signals S1 and S2 input to the first and second input / output terminals T1 and T2 is a wired signal.

  This modified example is a configuration example in the case where the relay device 10 of the first embodiment is used as a line booster of a cable television, for example. That is, the relay device 10C is used as a device that amplifies data when transmitting and receiving video and data between the provider PV and the terminal device TD.

  As shown in FIGS. 4A and 4B, the relay device 10 (relay devices 10A, 10B, and 10C) is a case where bidirectional information is transmitted and received, and both are simultaneously transmitted due to the transmission method and nature. If there is no transmission / reception in the direction, it can be used for various purposes. That is, the relay device 10 (relay devices 10A, 10B, and 10C) can be used when the first link signal S1 and the second link signal S2 are either wireless signals or wired signals.

  In the above, when the first link signal S1 from the first input / output terminal T1 is detected by the detection circuit 12 in the relay device used for communication by the time division duplex method, the first switch circuit 11A The first link signal S1 is supplied to the amplifier AP via the second switch circuit 11B, and the first link signal S1B amplified by the amplifier AP is transmitted from the first switch circuit 11A to the second switch circuit 11B. When the first transmission path P1 configured to be output from the second input / output terminal T2 and the detection circuit 12 detects the second link signal S2 from the second input / output terminal T2 The second link signal S2 is supplied from the second switch circuit 11B to the amplifier AP, and the second link signal S2B amplified by the amplifier AP is supplied to the first switch. Having a second transmission path P2 which is configured to be outputted from the first output terminal T1 is transmitted to the circuit 11A. Therefore, it is possible to provide a compact relay device that can transmit and receive signals bidirectionally with only a single amplifier AP.

10, 10A, 10B, 10C Relay device 11 Amplifier circuit AP Amplifier SWC Switch circuit 11A First switch circuit 11B Second switch circuit 12 Detection circuit 13 Switching control circuit T1 First input / output terminal T2 Second input / output terminal S1 first link signal S2 second link signal

Claims (9)

First and second input / output terminals to which first and second link signals are respectively input;
An amplifier;
A switch circuit provided between an input terminal and an output terminal of the amplifier and the first and second input / output terminals;
A detection circuit for detecting which of the first and second input / output terminals a link signal is input;
A switching control circuit that performs switching control of the switch circuit,
The switching control circuit includes:
When the first link signal is detected by the detection circuit, the first link signal is supplied to the input terminal of the amplifier, and the first link signal amplified by the amplifier is the second link signal. Configure the first transmission path to be output from the input / output terminal,
When the second link signal is detected by the detection circuit, the second link signal is supplied to the input terminal of the amplifier, and the second link signal amplified by the amplifier is the first link signal. A relay apparatus configured to perform the switching control that configures the second transmission path so as to be output from an input / output terminal. The switch circuit includes a first switch circuit connected between the output terminal and the first input / output terminal of the amplifier, and between the input terminal and the second input / output terminal of the amplifier. A second switch circuit connected to
The switching control circuit includes:
When the first link signal is detected by the detection circuit, the first link signal is supplied from the first switch circuit to the amplifier via the second switch circuit and amplified by the amplifier. Switching the first and second switch circuits so that the first link signal is transmitted from the first switch circuit to the second switch circuit and output from the second input / output terminal;
When the second link signal is detected by the detection circuit, the second link signal is supplied from the second switch circuit to the amplifier, and the second link signal amplified by the amplifier is 2. The relay device according to claim 1, wherein the first and second switch circuits are switched so as to be transmitted to a first switch circuit and output from the first input / output terminal.   The detection circuit includes a directional coupler provided between the second input / output terminal and the second switch circuit, and a detector for detecting a signal from a coupling port of the directional coupler. The relay device according to claim 2, wherein   The relay device according to claim 3, wherein the detection circuit detects the input of the second link signal by detecting the carrier signal of the second link signal by the detector. The first switch circuit includes a first SPDT switch connected to the output terminal of the amplifier, a second SPDT switch connected between the first SPDT switch and the first input / output terminal. Consists of
The second switch circuit includes a third SPDT switch connected to the input terminal of the amplifier, and a fourth SPDT switch connected between the third SPDT switch and the second input / output terminal. Consists of
5. The method according to claim 1, wherein the first SPDT switch is connected to the fourth SPDT, and the second SPDT switch is connected to the third SPDT switch. The relay device described.   The relay apparatus according to claim 1, wherein the switching control circuit generates a switching signal for switching between the first transmission path and the second transmission path.   The relay apparatus according to claim 1, wherein each of the first and second link signals is a radio signal. The first link signal is a downlink signal from a base station to a terminal device,
The relay apparatus according to claim 7, wherein the second link signal is an uplink signal from the terminal apparatus to the base station.   9. The relay apparatus according to claim 1, wherein the first and second link signals are signals based on a time division duplex method.

Images