JP6524010B2 - Communication relay system and method - Google Patents

Description

  Embodiments of the present invention relate to a communication relay system and method.

BACKGROUND Conventionally, a distributed antenna system (communication relay system) has been known for enabling mobile communication terminal devices such as mobile phones and smartphones to be used indoors.
In such a distributed antenna system, a plurality of slave units (slaves) are connected to one master station unit (master unit) connected to the radio base station to effectively set the communication area of the radio base station. The expansion covered a wide range of indoor areas such as large commercial facilities and office buildings.

  In addition, in order to improve the data rate of mobile phones, it is possible to improve the data rate using multiple bands, supplement W-CDMA and LTE, and use them simultaneously or use multiple mobile phone systems and multiple bands simultaneously. In addition, multi-banding has been achieved in the distributed antenna system.

WO 2008/129680 pamphlet JP, 2012-217174, A JP, 2008-091984, A

  However, in the above prior art, as the upstream signal (uplink signal), since the output of the low noise amplifier (LNA) prepared for each slave station device is synthesized, in the parent device, The noise corresponding to the number of slave station devices will be synthesized, and there is a possibility that the synthesized noise value (synthesized NF), which is the total noise value (NF) as the whole distributed antenna system, is deteriorated.

  The present invention has been made in view of the above, and improves the combined noise value in the master unit even when a plurality of slave units are connected to one master unit apparatus to construct a distributed antenna system. An object of the present invention is to provide a communication relay system and method capable of establishing a good communication environment.

The communication relay system according to the embodiment is a communication relay system including at least a master station device and a plurality of slave station devices and relaying communication directly or indirectly between a wireless base station and a mobile communication terminal device. .
The detection unit detects, in a transmission system performing transmission from the slave station apparatus to the radio base station, whether or not the signal transmitted in the transmission system includes an uplink signal from the mobile communication terminal apparatus.
The upstream signal blocking control unit, as a result of the detection by the detection unit, includes an upstream signal in a predetermined observation period for one or more transmission systems detected that the upstream signal from the mobile communication terminal device is not included. If not detected, the transition to the blocking state of the upstream signal or the blocking state of the upstream signal is maintained when the detection is continuously performed a predetermined number of times or more.
Furthermore, after the upstream signal blocking control unit receives control to the blocking state, if a blocking release signal is received, whether or not the upstream signal from the mobile communication terminal device is included until the closing control limitation period ends. The blocking release state is maintained regardless of whether or not the transmission system including the upstream signal from the mobile communication terminal shifts to the upstream signal blocking release state or maintains the upstream signal blocking release state for a predetermined period. .

FIG. 1 is a schematic configuration block diagram of a mobile phone communication network according to an embodiment. FIG. 2 is a schematic configuration block diagram of the distributed antenna system of the embodiment. FIG. 3 is a schematic block diagram of a slave station apparatus according to the first embodiment. FIG. 4 is a schematic block diagram of an example of the upstream signal blocking control unit according to the first embodiment. FIG. 5 is an explanatory diagram of an actual reception signal and an upstream signal detection state. FIG. 6 is an operation flowchart of the occlusion control unit according to the first embodiment. FIG. 7 is an operation timing chart of the main part of the first embodiment. FIG. 8 is a schematic block diagram of a slave station apparatus according to the second embodiment. FIG. 9 is a schematic block diagram of an example of the upstream signal blocking control unit according to the second embodiment. FIG. 10 is an operation flowchart of the blockade control unit of the second embodiment. FIG. 11 is an operation timing chart of the main part of the second embodiment. FIG. 12 is a schematic block diagram of an example of the upstream signal blocking control unit according to the third embodiment. FIG. 13 is an operation timing chart of the main part of the third embodiment. FIG. 14 is a schematic block diagram of a slave station apparatus according to the fourth embodiment. FIG. 15 is a schematic block diagram of an example of the upstream signal blocking control unit according to the fourth embodiment. FIG. 16 is a schematic block diagram of an example of the cooperation control unit. FIG. 17 is a schematic configuration block diagram of a hub station device of the fifth embodiment. FIG. 18 is a schematic block diagram of an example of the addition / blockage control unit. FIG. 19 is a schematic block diagram of a master station apparatus.

Embodiments will now be described in detail with reference to the drawings.
FIG. 1 is a schematic configuration block diagram of a mobile phone communication network according to an embodiment.
The mobile phone communication network NET interconnects with another connecting carrier communication network ENET via a gateway switch (Interconnecting Gateway Switch, not shown), and performs mobile terminal connection control of the mobile phone terminal belonging to the connecting carrier. A plurality of base station controllers BSC connected to the telephone core network CNET and a mobile phone core network CNET for managing and controlling base stations described later, and a plurality of radio base stations BTS connected to each base station controller BSC And a distributed antenna system (communication relay system) 1 wired to the corresponding radio base station BTS by a communication cable LC such as a coaxial cable.
In the present embodiment, it is assumed that the distributed antenna system 1 is disposed in a building BLD which is a kind of so-called dead zone and in the underground mall UG.

FIG. 2 is a schematic configuration block diagram of the distributed antenna system of the embodiment.
The distributed antenna system 1 is connected to the master station apparatus (MU: Master Unit) 2 connected to the radio base station BTS by a communication cable, and to the master station apparatus 2 via the communication cable LC, and other hub station apparatuses Are also wirelessly connected via the antenna 5 to a plurality of hub station devices (HU: Hub Unit) 3 connected via the communication cable LC and the mobile communication terminal device 4 such as a mobile phone or a smartphone. A plurality of slave units (RU: Remote Unit) 6 are provided.
In the above configuration, the slave station device 6 is connected to the hub station device 3 directly or indirectly via another slave station device 6 as shown in FIG.

[1] First Embodiment FIG. 3 is a schematic block diagram of a slave station device according to the first embodiment.
The slave station device 6 includes a transmission path interface unit 121 that performs communication interface operation with the hub station device 3, a demapper unit 122 that extracts and outputs a control signal from a frame signal, a D / A converter 123, and an antenna 5. And an A / D converter 125 for performing analog / digital conversion of a signal received via the antenna interface unit 124. If an upstream signal is detected based on the output signal (uplink signal) of the A / D converter 125, the output signal (uplink signal) of the A / D converter 125 is output to the mapper unit 128 described later, Upstream signal blocking control section (shown as D & S in the figure) that blocks upstream signals when no signal is detected 12 And a mapper unit 128 which multiplexes the output data of the upstream signal blocking control unit 126 into a frame signal and transmits it to the hub station apparatus 3 via the transmission path interface unit 121.

FIG. 4 is a schematic block diagram of an example of the upstream signal blocking control unit according to the first embodiment.
The upstream signal blocking control unit 126 is roughly classified into an AND circuit 152, a switch unit 153, a delay unit (denoted as DELAY in the drawing) 154, a distributing unit (denoted as DIV in the drawing) 155, and an upstream signal. A detection unit (denoted as DET in the drawing) 156 and an occlusion control unit (denoted as CONT in the drawing) 157 are provided.

In the above configuration, the output signal of the A / D converter 125 is input to the distribution unit 155, and the distribution unit 155 distributes and outputs the signal to the delay unit 154 and the upstream signal detection unit 156.
As a result, the upstream signal detection unit 156 detects whether the output signal of the A / D converter 125 includes an upstream signal from the mobile communication terminal device 4, and sends the upstream signal detection result signal SD to the blockage control unit 157. Output.

Then, the blockade control unit 157 outputs the control signal SC to control the switch unit 153 based on the upstream signal detection result signal SD output from the upstream signal detection unit 156, and detects that the upstream signal is included. In the case of the result, the switch unit 153 is set to the “1” side.
As a result, the AND circuit 152 outputs the output signal of the delay unit 154, that is, the output signal of the A / D converter 125 including the upstream signal to the mapper unit 128 as it is.

  At this time, the delay amount of the delay unit 154 is the time required for the upstream signal detection unit 156 to detect an upstream signal and the closing control unit 157 to switch the switch unit 153, and thus the upstream signal is detected. In addition, the AND circuit 152 can surely output the output signal of the A / D converter 125 including the upstream signal to the mapper unit 128.

  On the other hand, the blockage control unit 157 controls the switch unit 153 based on the upstream signal detection result signal SD output from the upstream signal detection unit 156, and in the case of a detection result indicating that the upstream signal is not included, The unit 153 is set to the “0” side. The AND circuit 152 effectively prohibits transmission of the output signal of the delay unit 154, that is, the output signal of the A / D converter 125 which does not include the upstream signal, and blocks the upstream signal.

  In the above configuration, the upstream signal detection unit 156 may detect a signal based on a predetermined threshold value for the power value obtained by squaring detection of the upstream signal, or based on the result of performing the filtering process and the like. The detection of the signal may be performed, and any method may be applied as long as it is an effective means for detecting the upstream signal.

FIG. 5 is an explanatory diagram of an actual reception signal and an upstream signal detection state.
By the way, in the case of the OFDMA signal as in the uplink signal of LTE, the peak to signal power ratio (PAPR) is large, if not the same as that of the OFDM signal, and so the waveform is similar to noise. For this reason, when the signal-to-noise power ratio is small, as shown in FIG. 5, regardless of the presence or absence of the upstream signal transmitted by the mobile communication terminal device 4, the signal received by the slave station device 6 is simply portable communication. It can not be determined whether or not an uplink signal is included using a threshold based on the signal power of the uplink signal transmitted by the terminal device 4.

That is, when it is determined whether the output signal of A / D converter 125 includes an upstream signal using a threshold based on the signal power of the upstream signal transmitted by mobile communication terminal device 4 simply, the upstream signal is included. However, it may be determined that upstream signals are not included. In such a state, the switch unit 153 may be accidentally turned to the “0” side, and the upstream signal may be blocked and the communication of the user of the mobile communication terminal device 4 may be disconnected.
If the threshold is lowered to prevent disconnection of the user's communication of the mobile communication terminal 4 by blocking the upstream signal, it is determined that the upstream signal is included even if the upstream signal is not included this time Therefore, the effect of noise suppression may be diminished.

  Therefore, in the distributed antenna system 1 of the first embodiment, in order to suppress the situation in which the user's communication is disconnected as much as possible, in order to execute blocking of the upstream signal in the block control unit 157, a certain observation period Control is performed so that blocking of the upstream signal is performed when it is determined that the upstream signal is not included for a predetermined number of times (a prescribed number of times m described later) within this period. .

  On the other hand, when it is determined that the upstream signal is included from the upstream signal detection unit 156 during the blocking operation, control is performed to immediately release the blocking in order to secure the user's communication.

Next, the operation of the first embodiment will be described.
FIG. 6 is an operation flowchart of the occlusion control unit according to the first embodiment.
FIG. 7 is an operation timing chart of the main part of the first embodiment.
First, in the initial state, the blocking control unit 157 cancels blocking of the upstream signal by the control signal SC, and the upstream signal transmitted by the mobile communication terminal device 4 is transmitted via the hub station device 3 and the master station device 2 to the wireless base station In order to be transmitted to the BTS, the switch unit 153 is set to the “1” side, and the count value n of the control counter for counting the number of times the detection result of the upstream signal does not include the upstream signal is initialized ( Step S11). For example, let n = 1.

Next, the blockade control unit 157 starts observation (step S12, timing indicated by the upward arrow in FIG. 7B), and the sampling timing of the upstream signal detection result signal SD (indicated as upstream signal sample timing in the drawing) It is determined whether there is any (step S13).
In the determination of step S13, when it is not the upstream signal sample timing (step S13; No), a standby state is established.

  On the other hand, in the determination of step S13, if it is the upstream signal sample timing, specifically, if it is the timing shown by the upward arrow in FIG. 7 (d) (step S13; Yes) It is determined whether the output signal of the A / D converter 125 includes (is present) an upstream signal from the mobile communication terminal 4 based on the upstream signal detection result signal SD (step S14).

  In this case, the upstream signal detection unit 156 periodically performs an upstream signal detection operation, and when the output signal of the A / D converter 125 includes the upstream signal from the mobile communication terminal device 4, the upstream signal is detected. The detection result signal SD is set to a state with a signal (“H” level in the case of the example of FIG. 7). In addition, when the upstream signal from the mobile communication terminal 4 is not included in the output signal of the A / D converter 125, the upstream signal detection unit 156 does not have the upstream signal detection result signal SD in a state of no signal (FIG. In the case of the example, it is "L" level).

  In the determination of step S14, when it is determined that the output signal of the A / D converter 125 does not include the upstream signal from the portable communication terminal 4 based on the upstream signal detection result signal SD from the upstream signal detection unit 156 (Step S14; No), the blockade control unit 157 adds 1 to the count value n of the counter (step S15), and it is determined whether the value of the count value n of the counter after addition exceeds the specified number of times m. It discriminates (step S16).

  Here, the prescribed number of times m corresponds to the observation period in which occlusion of the upstream signal is actually performed in the occlusion control unit 157 as described above, and a predetermined number of times (= prescribed number of times m) within this observation period. As described above, when it is determined that the upstream signal is not included, the blocking of the upstream signal is set to be performed. The observation period and the determination of the specified number m may be determined by observing an actual signal or may be determined probabilistically.

  If it is determined in step S16 that the value of the count value n of the counter after addition does not exceed the prescribed number of times m (step S16; No), the process proceeds to step S13 again and is similar to that described above. Do the processing. Therefore, blocking of the upstream signal will not be performed at this stage.

  On the other hand, if it is determined in step S16 that the count value n of the counter after addition exceeds the prescribed number of times m (step S16; Yes), the blockage control unit 157 controls the blockade of the upstream signal by the control signal SC. So that the switch unit 153 is on the “0” side so that the output signal of the A / D converter 125 is not transmitted to the wireless base station BTS via the hub station apparatus 3 and the master station apparatus 2, the detection result of the upstream signal is The count value n of the control counter for counting the number of times the up signal is not included is reinitialized (step S17).

  Further, in the determination in step S14, it was determined that the output signal of the A / D converter 125 includes the upstream signal from the mobile communication terminal 4 based on the upstream signal detection result signal SD from the upstream signal detection unit 156 In the case (step S14; Yes), the blocking control unit 157 cancels blocking of the upstream signal by the control signal SC, and the upstream signal transmitted by the mobile communication terminal device 4 is transmitted via the hub station device 3 and the master station device 2. So that the switch unit 153 is on the "1" side, and the count value n of the control counter is used to count the number of times that the detection result of the upstream signal does not include the upstream signal. It initializes (step S18).

As described above, according to the first embodiment, even in a signal with a high PAPR such as an LTE signal, missed detection of upstream signal detection can be reduced to prevent occurrence of a false blockage, so user communication can be performed. The noise addition to the radio base station BTS can be prevented without interference.
In the above description, the observation period is performed by counting, but instead, it may be performed by time.

[2] Second Embodiment Next, a second embodiment will be described.
The second embodiment differs from the first embodiment in that, in order to perform blocking control on the upstream signal without inhibiting the communication of the user of the mobile communication terminal device 4, the radio communication signal of the TDD scheme is used for the observation period. The start timing is determined based on transmission / reception switching timing in the TDD system.

In this case, as the transmission / reception switching timing, it is possible to set the symbol start time of the wireless frame or the time that is an integral multiple of the symbol period from the symbol start time.
In addition, it is possible to set the slot start time of the radio frame or a time that is an integral multiple of the slot period from the slot start time.

The details will be described below.
In the TDD LTE signal, the timing of the upstream signal and the timing of the downstream signal are clearly distinguished.
Specifically, in slave station apparatus 6, antenna interface section 124 switches the signal transmission direction at the time of signal transmission and at the time of signal reception at timing based on the switching control signal of the downlink signal and the uplink signal. .

Therefore, in the second embodiment, the start timing of the observation period is determined based on the switching control signal of the downlink signal and the uplink signal.
Normally, in the mobile communication terminal apparatus 4, user data is scheduled for each subframe of a radio frame. Also, control signals are also transmitted in units of subframes, one slot, and one symbol. Therefore, by determining the start timing based on the TDD transmission timing, the blocking control of the upstream signal can be performed without blocking the data signal and the control signal from the portable terminal of the user.

FIG. 8 is a schematic block diagram of a slave station apparatus according to the second embodiment.
8 differs from the first embodiment of FIG. 3 in that the TDD transmission / reception switch timing signal SSW output from the demapper unit 122 is subjected to TDD transmission / reception switch control unit (denoted as CONT1 in the drawing) 127 and each upstream signal blocking control. The point being input to the unit 126 and the point that the TDD transmission / reception switching control unit 127 performs switching control by outputting the switching control signal SSW1 of the downlink signal and the uplink signal to the antenna interface unit 124.

FIG. 9 is a schematic block diagram of an example of the upstream signal blocking control unit according to the second embodiment.
The upstream signal blocking control unit 126 is roughly classified into an AND circuit 152, a switch unit 153, a delay unit 154, a distributing unit 155, an upstream signal detecting unit 156, a blocking control unit 157A, and a timing generating unit (see FIG. And T-GEN) 158).

In the above configuration, the output signal of the A / D converter 125 is input to the distribution unit 155, and the distribution unit 155 distributes and outputs the signal to the delay unit 154 and the upstream signal detection unit 156.
As a result, the upstream signal detection unit 156 detects whether the output signal of the A / D converter 125 includes an upstream signal from the mobile communication terminal device 4 and sends the upstream signal detection result signal SD to the blockage control unit 157A. Output.

Further, the TDD transmission / reception switch timing signal SSW is input to the timing generation unit 158.
As a result, the timing generation unit 158 generates an observation start timing signal ST corresponding to the start timing of the observation period based on the TDD transmission / reception switch timing signal SSW, and outputs the observation start timing signal ST to the occlusion control unit 157A.

  Thereby, the blockade control unit 157A notified of the start timing of the observation period by the observation start timing signal ST outputs the control signal SC based on the upstream signal detection result signal SD output from the upstream signal detection unit 156 to switch The control of the unit 153 is performed, and in the case of the detection result that the upstream signal is included, the switch unit 153 is set to the “1” side.

As a result, the AND circuit 152 outputs the output signal of the delay unit 154, that is, the output signal of the A / D converter 125 including the upstream signal to the mapper unit 128 as it is.
At this time, the delay amount of the delay unit 154 is the time required for the upstream signal detection unit 156 to detect an upstream signal and the blocking control unit 157A to switch the switch unit 153, and thus the upstream signal is detected. In addition, the AND circuit 152 can surely output the output signal of the A / D converter 125 including the upstream signal to the mapper unit 128.

Next, the operation of the second embodiment will be described.
The master station device 2 detects the power of the TDD signal to extract transmission / reception switching timing, and distributes the same to the slave station device 6 via the hub station device 3.
As a result, the demapper unit 122 of the slave station device 6 transmits the generated TDD transmission / reception switching timing signal SSW to the TDD transmission / reception switching control unit 127 and the upstream signal blocking control unit 126.

  As a result, based on the TDD transmission / reception switching timing signal SSW, the TDD transmission / reception switching control unit 127 outputs the switching control signal SSW1 for the downlink signal and the uplink signal to the antenna interface unit 124 to perform switching control.

  In parallel with this, the timing generation unit 158 of the upstream signal blocking control unit 126 generates an observation start timing signal ST corresponding to the start timing of the observation period based on the TDD transmission / reception switching timing signal SSW, and sends the blocking control unit 157A Output.

Next, the operation of the second embodiment will be described.
FIG. 10 is an operation flowchart of the blockade control unit of the second embodiment.
FIG. 11 is an operation timing chart of the main part of the second embodiment.
First, in the initial state, the blocking control unit 157A cancels blocking of the upstream signal by the control signal SC, and the upstream signal transmitted by the mobile communication terminal device 4 is transmitted via the hub station device 3 and the master station device 2 to the wireless base station In order to be transmitted to the BTS, the switch unit 153 is set to the “1” side, and the count value n of the control counter for counting the number of times the detection result of the upstream signal does not include the upstream signal is initialized ( Step S21). For example, let n = 1.

Next, the occlusion control unit 157A determines whether or not the observation period has started based on the observation start timing signal ST (step S22).
If it is determined in step S22 that the start of the observation period is not started based on the observation start timing signal ST (step S22; No), the occlusion control unit 157A is in a standby state.

If it is determined in step S22 that the start of the observation period is started based on the observation start timing signal ST (step S22; Yes), the blockade control unit 157A starts observation, and samples the upstream signal detection result signal SD. It is determined whether it is the timing, that is, the upstream signal sample timing (step S23).
In the determination of step S23, when it is not the upstream signal sampling timing (step S23; No), the blockage control unit 157A is in the standby state.

  On the other hand, in the determination of step S23, if it is the upstream signal sampling timing, specifically, if it is the timing shown by the upward arrow in FIG. 11 (e) (step S23; Yes), the upstream signal detection unit 156 It is determined whether the output signal of the A / D converter 125 includes (is present) an upstream signal from the mobile communication terminal 4 based on the upstream signal detection result signal SD from (step S24).

  In this case, the upstream signal detection unit 156 periodically performs an upstream signal detection operation, and when the output signal of the A / D converter 125 includes the upstream signal from the mobile communication terminal device 4, the upstream signal is detected. The detection result signal SD is set to a state with a signal (in the case of the example of FIG. 11D, “H” level). In addition, when the upstream signal from the mobile communication terminal 4 is not included in the output signal of the A / D converter 125, the upstream signal detection unit 156 does not include the upstream signal detection result signal SD (FIG. In the case of the example of d), it is "L" level).

  In the determination of step S24, when it is determined that the output signal of the A / D converter 125 does not include the upstream signal from the mobile communication terminal 4 based on the upstream signal detection result signal SD from the upstream signal detection unit 156 (Step S24; No), the blockade control unit 157A adds 1 to the count value n of the counter (step S25), and whether the value of the count value n of the counter after addition exceeds the specified number of times m It discriminates (step S26).

  If it is determined in step S26 that the number of detections of no upstream signal, which is the value of the count value n of the counter after addition, does not exceed the specified number m (step S26; No), the process proceeds to step S23 again. And perform the same processing as described above. Therefore, blocking of the upstream signal will not be performed at this stage.

  On the other hand, in the determination of step S26, when the value of the count value n of the counter after addition exceeds the specified number of times m (step S26; Yes), the blockage control unit 157 controls the blockade of the upstream signal by the control signal SC. So that the switch unit 153 is on the “0” side so that the output signal of the A / D converter 125 is not transmitted to the wireless base station BTS via the hub station apparatus 3 and the master station apparatus 2, the detection result of the upstream signal is The count value n of the control counter for counting the number of times the up signal is not included is reinitialized (step S27).

  Further, in the determination of step S24, it is determined that the output signal of the A / D converter 125 includes the upstream signal from the mobile communication terminal 4 based on the upstream signal detection result signal SD from the upstream signal detection unit 156 In the case (step S24; Yes), the blocking control unit 157A cancels blocking of the upstream signal by the control signal SC, and the upstream signal transmitted by the mobile communication terminal device 4 is transmitted via the hub station device 3 and the master station device 2. So that the switch unit 153 is on the "1" side, and the count value n of the control counter is used to count the number of times that the detection result of the upstream signal does not include the upstream signal. It initializes (step S28).

  As described above, according to the second embodiment, in addition to the effects of the first embodiment, by setting the start position of the beginning (symbol) of the wireless frame as the observation start timing, the beginning of the wireless frame ( Blocking control of signals can be performed from the symbol), and blocking control can be performed while reducing the influence on communication from the mobile communication terminal device 4.

  In addition, since the allocation period of communication time to the user is scheduled in units of one subframe, portable communication can be performed by performing signal blocking control from the start timing of the slot, which is a basic unit of one subframe. The block control can be performed while reducing the influence on the communication from the terminal device 4.

[3] Third Embodiment Next, a third embodiment will be described.
Conventionally, if the user's mobile communication terminal device 4 starts connection, it is general that the connection is maintained for a certain period of time.
Therefore, when it is determined that the upstream signal is included, it is considered effective to set a guard time so that blocking of the upstream signal is not performed for a certain period.

  For example, the guard time may be set to one second, one minute, ten minutes, etc., but a symbol unit constituting a radio frame or an integral multiple thereof, a slot time, and a period integral multiple thereof By setting the guard time, it is possible to minimize the loss of the radio frame.

  Also, by performing the observation start timing and the blockage control independently, flexible blockage control can be performed by setting the guard time independently without increasing the observation period that affects the delay.

Therefore, the third embodiment realizes these.
The third embodiment will be described in detail below.

FIG. 12 is a schematic block diagram of an example of the upstream signal blocking control unit according to the third embodiment.
The third embodiment of FIG. 12 differs from the second embodiment of FIG. 9 in that the start timing of the observation period and the occlusion control restriction period are set, and in the occlusion control restriction period, control of the occlusion direction from the occlusion control unit Is received only once, and after that, when the control for releasing the blockade is received, the point is fixed only to the blockade release until the blockade control limitation period ends.

  The upstream signal blocking control unit 126 of the third embodiment differs from the upstream signal blocking control unit 126 of the second embodiment in that the start timing of the observation period and the blocking control limitation period are generated instead of the timing generation unit 158. When control of the closing direction is received from the timing generation unit 158A and the closing control unit 157 only once, and then a closing release signal is received, the control to the switch 153 is closed until the closing control restriction period ends. And a gate timing unit 159 fixed to release.

Next, the operation of the third embodiment will be described.
The timing generation unit 158A generates the observation start timing signal ST and the occlusion control restriction period signal SL.

  Then, the timing generation unit 158A outputs the occlusion control restriction period signal SL to the gate timing unit (GA-T) 159.

As a result, the gate timing unit 159 receives control of the occlusion direction from the occlusion control unit 157 only once within the occlusion control limitation period corresponding to the occlusion control limitation period signal SL.
After that, when receiving the closing release signal, the gate timing unit 159 fixes the control of the switch unit 153 to the closing release until the closing control limitation period ends.

The details will be described below.
FIG. 13 is an operation timing chart of the main part of the third embodiment.
First, the blocking control unit 157 receives the upstream signal detection result signal SD from the upstream signal detection unit 156, and starts observation of the upstream signal at a timing based on the observation timing signal ST generated by the timing generation unit 158A.

  In parallel with this, the timing generation unit 158A outputs the closure control restriction period signal SL to the gate timing unit 159.

  Thus, the gate timing unit 159 receives the occlusion control limitation period signal SL generated by the timing generation unit 158A, and the occlusion control signal SC input from the occlusion control unit 157 is closed on the start of the occlusion control limitation period. (When the block control signal SC output from the block control unit 157 corresponds to the block state at time t0 and the block control signal SC remains as it is), the switch section 153 is switched by the block control signal SC1. Leave it on the 0 ′ ′ side, and continue occlusion control without performing occlusion release.

  Further, as shown at time t2, when the blockage is released once by the blockage control signal SC, for example, as shown at time t3, the blockage control signal SC which is the output of the blockage control unit 157 corresponds to the blockage state Even if it does, in the blockade control limit period (blockage control limit period signal SL = “limit”), the blockade release is continued.

  In addition, for example, as shown at time t4, the next block control is performed once when the block control signal SC from the block control unit 157 is controlled to the block release side at the start of the block control limitation period. Only accept.

  As described above, according to the third embodiment, by performing control to provide the blockade control limitation period, unnecessary interruption of communication due to erroneous blockage can be prevented, and noise addition to the radio base station BST can be prevented. Can be prevented.

  Further, since the observation period and the guard time can be set independently, the guard time can be set without affecting the transmission delay of the system due to the observation period.

  Although the above description has been made based on the TDD scheme, even in the case of a distributed antenna system of the FDD scheme, the configuration is partially changed, and the start timing and the block control limitation period are set independently. It is applicable to

[4] Fourth Embodiment Next, a fourth embodiment will be described.
The fourth embodiment shows an application example of performing communication by Multiple-Input and Multiple-Output (MIMO) as an example of different communication functions.

  In the case of MIMO, the transmission path interface unit with the radio base station BTS is provided for each antenna port. For example, in the case of 2 × 2 MIMO, there are two antenna ports, and in the case of 4 × 4 MIMO, there are four antenna ports, but multiple antenna ports need to perform the same operation as one set.

  For example, in the case where two antenna ports (hereinafter referred to as antenna port AT1 and antenna port AT2 for identification) are mounted on the same slave station apparatus 6, transmission of uplink signals from one antenna port AT1 is prohibited. Then, it is necessary to avoid control to allow transmission of the uplink signal of the other antenna port AT2.

  Therefore, in the fourth embodiment, a case will be described in which signals of the antenna port AT1 and the antenna port AT2 are handled for each slave station device 6 and 2 × 2 MIMO signals are handled for each slave station device 6.

In the distributed antenna system, it is effective to perform blockage control in coordination with different types of signals.
For example, when antenna port AT1 and antenna port AT2 of 2 × 2 MIMO are mounted in the same slave station device 6, control is performed such that uplink signal of antenna port 1 is stopped and uplink signal of antenna port 2 is transmitted. Should be avoided.
In addition, it is necessary to simultaneously perform the same control on signals to be subjected to carrier aggregation.

  In addition, since LTE signals and W-CDMA signals, and multi-terminals that can use a wireless LAN are generally used at present, it is only necessary to be able to connect using any method, so in the state where uplink signals of LTE signals are blocked, In a state in which blocking of W-CDMA signal and uplink signal of wireless LAN is canceled and blocking of uplink signal of LTE signal is canceled, control of blocking W-CDMA signal and uplink signal of wireless LAN obstructs user's communication. It is an effective way to increase throughput without

FIG. 14 is a schematic block diagram of a slave station apparatus according to the fourth embodiment.
The fourth embodiment of FIG. 14 is different from the second embodiment of FIG. 8 in that a coordination control unit (denoted as ASSOCI in the drawing) 129 is newly provided, and the uplink signal blocking control unit 126 performs coordination control. The cooperative control is performed under the control of the unit 129, and the cooperative control unit 129 can receive the configuration information SI of the distributed antenna system 1 from the master station apparatus 2 via the demapper unit 122.

FIG. 15 is a schematic block diagram of an example of the upstream signal blocking control unit according to the fourth embodiment.
The upstream signal blocking control unit 126 of FIG. 15 differs from the upstream signal blocking control unit 126 of FIG. 12 in that the blocking control signal SC1 output from the gate timing unit 159 is transmitted to the coordination control unit 129, and from the coordination control unit 129 Is received, and the switch unit 153 is controlled.

FIG. 16 is a schematic block diagram of an example of the cooperation control unit.
The cooperation control unit 129 can be roughly divided into a matrix switch control unit (denoted as M-CONT in the figure) 160, matrix switch units (denoted as M-SW in the figure) 161A and 161B, and an AND circuit block part (denoted as M-SW). In the figure, it is provided with AND and 162, a NOT circuit block portion (not and shown in the figure) 163, and a through portion (denoted as THRU in the figure) 164.

Here, the operation of the coordination control unit 129 will be described.
The matrix switch control unit 160 of the coordination control unit 129 receives the configuration information SI of the distributed antenna system 1 received from the master station device 2 via the hub station device 3. Then, based on the received configuration information SI, the upstream signal blocking control unit 126 corresponding to each of different communication functions such as MIMO, carrier aggregation, W-CDMA signal, LTE signal, wireless LAN signal, etc. is extracted, and each correspondence relationship Understand (attach). The matrix switch units 161A and 161B are connected to the OR block unit 162 for the blockage control signal SC1 from the upstream signal blockage control unit 126, which should simultaneously perform blockage control, based on the grasped correspondence relationship (connection relationship). Then, in the OR block unit 162, logical sum (OR) of the occlusion control signal SC1 output from the upstream signal occlusion control unit 126 for each combination (for example, combination set of MIMO signals, frequency set for performing carrier aggregation) for simultaneously performing occlusion control. To obtain a new occlusion control signal, which is output to the corresponding upstream signal occlusion control unit 126 as a coordination control signal SH.

  In addition, with regard to the block control signal SC1 from the upstream signal block control unit 126 which needs to be exclusively controlled, the block control signal SC1 from the upstream signal block control unit 126 on the side that becomes the main control is the matrix switch unit 161A. , 161 B are connected to both the NOT block portion 163 and the through portion 164.

  As a result, the through section 164 controls the switch section 153 of the upstream signal blocking control section 126 on the side of the main control as it is through the matrix switch sections 161A and 161B.

  On the other hand, the NOT block unit 163 inverts the input occlusion control signal SC1, and cooperates with the upstream signal occlusion control unit 126 on the slave side of the control to cooperate with the inverse occlusion control signal / SC1 which is the inverted occlusion control signal SC1. It is output as a control signal SH.

  As a result, the block control signal SC1 from the upstream signal block control unit 126 on the slave side of control is terminated at the matrix switch unit 161A and is not connected to any of the OR block unit 162, the NOT block unit 163 and the through unit 164. .

  Then, for example, two uplink signal blocking control units 126 serving as a pair corresponding to 2 × 2 MIMO are uplink signals only when both of the uplink signal blocking control units 126 of uplink signals from the corresponding antenna 5 control in the blocking direction. The blockade is performed, and even if one of the upstream signal blockade control units 126 controls blockage release and the other uplink signal blockade control unit 126 controls blockage, both blockages are released.

  More specifically, when the upstream signal blocking control unit 126 corresponding to the W-CDMA signal and the LTE signal blocks the LTE upstream signal with the side serving as the main control being the LTE signal, the upstream signal corresponding to the LTE signal is The switch unit 153 of the block control unit 126 is blocked, and the uplink signal block control unit 126 for the W-CDMA signal controls the uplink signal block control unit 126 for the W-CDMA signal regardless of the presence or absence of the uplink signal for the W-CDMA signal. The closing of the switch unit 153 is released.

As described above, according to the fourth embodiment, it is possible to simultaneously perform blocking control on the upstream signals of the MIMO signal and the signal associated with the carrier aggregation.
In addition, when any service is available, such as LTE, W-CDMA, or wireless LAN, exclusive block control may be performed such that only any service that can be serviced is blocked or released. it can.

Therefore, the area can be expanded and the throughput can be improved by reducing the noise addition to the radio base station BTS while maintaining the service operation rate for the user.
Further, when exclusive closing control is performed, the service serving as the main body of control can be changed in units of slave station devices 6.

For this reason, the main service can be determined for each slave station device 6, and the optimum service can be provided for each area.
Although FIG. 14, FIG. 15, and FIG. 16 assume the case of the TDD method, it is also possible to apply the FDD method by providing the observation start timing and the closure control restriction period independently. is there.

[5] Fifth Embodiment In the above embodiments, blocking control of the upstream signal is performed in the slave station device 6, but in the fifth embodiment, blocking control of the upstream signal in the hub station device 3 Is performed for each slave station device 6.

FIG. 17 is a schematic configuration block diagram of a hub station device of the fifth embodiment.
The hub station device 3 can be roughly divided into a transmission path interface unit 111, a mapper unit 112, a demapper unit 113, a distribution unit 114, a transmission path interface unit 115, and an addition / block control unit (shown as ADD & D & S in the figure). Notation) 116, coordination control unit 117, and demapper unit 118.

In the above configuration, the transmission path interface unit 111 performs a communication interface unit operation with the master station device 2.
The mapper unit 112 multiplexes various signals in a frame signal and transmits the multiplexed signal to the master station device 2 via the transmission path interface unit 111.

The demapper unit 113 separates various signals in the frame signal input from the slave station apparatus 6 via the transmission path interface unit 115, and outputs the separated signals to the addition / blocking control unit 116.
The distribution unit 114 copies and distributes the signals from the master station device 2 received via the transmission path interface unit 111 by the number of slave station devices 6.

Transmission path interface unit 115 performs a transmission interface operation with corresponding slave station apparatus 6.
The addition / blocking control unit 116 performs a function for processing one signal format, that is, one antenna of a MIMO signal, W-CDMA signal, LTE signal, and the like by the number of slave stations, and uplink signal blocking control.
The coordination control unit 117 performs coordination control of the plurality of addition / blocking control units 116.
The demapper unit 118 separates various signals input from the master station device 2 via the transmission path interface unit 111 and outputs the separated signals to the addition / blocking control unit 116.

FIG. 18 is a schematic block diagram of an example of the addition / blockage control unit.
The addition / blockage control unit 116 is roughly classified into an addition unit 151, an AND circuit 152, a switch unit 153, a delay unit 154, a distribution unit 155, and an upstream signal detection unit (denoted as DET-m in the figure). And a closing control unit (denoted as CONT-m in the drawing) 157A, a timing generation unit 158A, and a gate timing unit (denoted as GA-T-m in the drawing) 159A.

The basic operation of the addition / blocking control unit 116 in FIG. 18 is the same as that of the upstream signal blocking control unit 126 in FIG. 15, and the number of AND circuits 152, switch units 153, delay units 154, and distribution units 155 The extension signal detection unit 156A, the block control unit 157A, and the gate timing unit 159A are expanded to be able to process as many slave stations as can be connected. And the addition part 151 is provided so that the result of obstruction | occlusion control may be added according to the number of slaves of an upstream signal.
Further, the coordination control unit 117 has the same function as the coordination control unit 129 of FIG.
Processing is expanded by the number of slave stations.

Therefore, the operation of the fifth embodiment is basically the same as that of the fourth embodiment, and the processing is expanded by the number of connectable slave stations.
Here, the addition / blocking control unit 116 is capable of processing one signal format, that is, W-CDMA signals, LTE signals, etc. for one antenna of a MIMO signal for the number of slave stations. Is different from the operation of the upstream signal blocking control unit 126 of the slave station device 6.

According to the fifth embodiment, in addition to the effects of the fourth embodiment, it is not necessary to provide each slave station device 6 with the block control function by concentrating the block control in the hub station device 3, The manufacturing cost of the device 6 can be reduced.
The above description has been made based on the TDD scheme, but the configuration can be partially changed and the start timing and the block control limit period can be set independently, and the same applies to the FDD scheme.

[6] Sixth Embodiment FIG. 19 is a schematic block diagram of a master station apparatus.
The master station device 2 can be roughly divided into an RF signal interface unit (denoted as RF I / F in the drawing) 101, an A / D converter unit (denoted as A / D in the drawing) 102, and a D / A converter Unit (denoted as D / A in the figure) 103, mapper unit 104, demapper unit 105, distribution unit 106, transmission path interface unit 107, monitoring / control unit 108, cooperation control unit 119, addition And an occlusion control unit 120.

  In the above configuration, the RF signal interface unit 101 of the master station device 2 is connected to the radio base station BTS by a radio signal.

The A / D converter unit 102 converts the received wireless signal into a digital signal.
The D / A converter unit 103 converts a digital signal into a wireless signal.
The mapper unit 104 generates a frame for multiplexing and transmitting digital signals.

The demapper unit 105 extracts various signals from the frame received from the hub station device 3 via the transmission path interface unit 107, and outputs the signals to the corresponding addition / blockage control unit 120.
The distributing unit 106 distributes the frame generated by the mapper unit 104 to the corresponding transmission path interface unit 107 in order to distribute the frames to the plurality of hub station apparatuses 3.

The transmission path interface unit 107 transmits the frame generated by the mapper unit 104 to the corresponding hub station device 3.
The monitoring and control unit 108 controls the entire distributed antenna system 1 and monitors and controls an upstream signal.

  The operation of the addition / blocking control unit 120 is the same as that of the adding / blocking control unit 116 in FIG. 17, and is expanded so that processing can be performed by the number of hub station apparatuses 3. Then, an adding unit is provided to add up signals as a result of the block control for the number of hub station apparatuses 3.

  According to the fifth embodiment, in addition to the effects of the fourth embodiment, the upstream signal blocking control can be concentrated on the master station device 2, so that the upstream signal blocking control is performed for each slave station device 6, and It is possible to reduce the manufacturing cost of the slave station device 6 in comparison.

  Further, by performing uplink signal blocking control for each hub station apparatus 3, the number of slave stations at blocking is effectively increased, so that the amount of addition of noise to the base station can be largely reduced at blocking. For example, when there are ten slave stations 6 under the hub station 3, noise of the slave stations 6 can be reduced.

  Also in the fifth embodiment, although based on the TDD method, the configuration can be partially changed, and the start timing and the block control restriction period can be set independently, so that the same application to the FDD method is possible. It is.

[7] Effects of the Embodiment As described above, according to the above embodiments, the number of slave station devices 6 effectively connected to the master station device 2 can be reduced, and combining in the master station device 2 is possible. It can be seen that the NF can be improved.

  Further, the combined NF is improved and improved, so that the communication area of the slave station device 6 can be expanded. As a result, the station design conditions of the slave station 6 change, and the number of slave stations 6 required to configure the distributed antenna system 1 can be reduced, and the installation cost can be reduced.

  In addition, the throughput of the mobile communication terminal apparatus 4 is substantially improved by the improvement of the synthetic NF. Further, as the combined NF is improved, the signal noise ratio (SNR) of the upstream signal is improved, so that the transmission output power of the mobile communication terminal device 4 can be suppressed, and the battery consumption of the mobile communication terminal device 4 can be suppressed. , You can extend the usable time. Furthermore, the battery life can be improved. Furthermore, since the transmission output power of the mobile communication terminal device 4 can be suppressed, mutual interference of uplink signals from the mobile communication terminal device 4 to the slave station device 6 can be suppressed, and good communication can be performed.

According to this embodiment, since the above effects can be achieved, the system cost of the entire distributed antenna system 1 can be reduced.
In particular, in the case of a distributed antenna system 1 compatible with the LTE (Long Term Evolution) communication standard, when there is a mobile communication terminal device 4 having transmission data, many traffic channels are allocated to the mobile communication terminal device 4 to shorten the length. In order to complete the data transmission in time, the number of mobile communication terminal devices 4 actually transmitting the uplink signal and the substantial transmission time are not so large, so the effect of the present embodiment is received more It becomes possible.

[8] Modification of Embodiment In the above description, as the communication relay system (distributed antenna system), the case where the master station device, the hub station device, and the plurality of slave station devices are present has been described. As in the case where a plurality of slave station devices are directly connected, the present invention is similarly applicable to a communication relay system (distributed antenna system) having at least a master station device and a plurality of slave station devices.

In the above description, the case where the transmission path is transmitted as a digital signal has been described, but the same applies to the case where the transmission path is transmitted as an analog signal.
In addition, although the case of detecting the signal of the upstream signal after digitizing the upstream signal has been described, the present invention can be realized similarly by using the result of analog detection.

  For example, in the above description, W-CDMA signal and LTE signal are taken as different types of signals (different communication standards or different communication protocols), but in the present invention, other wireless signals such as WiMAX signal or wireless LAN signal It is applicable also in the case of a communication signal.

  In the above description, although the case where the frequency band (band) used for communication was one was described as an example, recently, the frequency band handled by the distributed antenna system 1 is plural (for example, 800 MHz band and 2.1 GHz band) The frequency band of the uplink signal input to the slave station device 6 is also plural. Therefore, by performing processing similar to the above processing for each frequency band and configuring switch control to be performed independently for each frequency band, independent control for each frequency band becomes possible, and flexible resources can be obtained. Allocation can be done.

  Also, among the available frequency bands, when there is no use of the frequency band by the mobile communication terminal device 4 etc., the slave station 6 side or the hub station device 3 side is also turned off in synchronization with the frequency band. By doing this, it is possible to reduce the power consumption of the slave station device 6 or the hub station device 3.

  The master station device, hub station device or slave station device constituting the communication relay system of the present embodiment includes a control device such as a CPU, a storage device such as a ROM (Read Only Memory) and a RAM, an HDD, and a CD drive. It has an external storage device such as a device, a display device such as a display device, and an input device such as a keyboard and a mouse, and has a hardware configuration using a normal computer.

  Programs executed by the master station apparatus, hub station apparatus or slave station apparatus constituting the communication relay system of the present embodiment are files in an installable format or an executable format, and the CD-ROM, flexible disk (FD Computer-readable recording media such as CD-R and DVD (Digital Versatile Disk).

Also, the program executed by the master station apparatus, hub station apparatus or slave station apparatus constituting the communication relay system of the present embodiment is stored on a computer connected to a network such as the Internet and downloaded via the network It may be configured to be provided by Further, the program executed by the communication relay device of the present embodiment may be provided or distributed via a network such as the Internet.
Further, the program of the master station apparatus, hub station apparatus or slave station apparatus constituting the communication relay system of the present embodiment may be provided by being incorporated in a ROM or the like in advance.

  While certain embodiments of the present invention have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, substitutions, and modifications can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and the gist of the invention, and are included in the invention described in the claims and the equivalent scope thereof.

Reference Signs List 1 distributed antenna system 2 master station device 3 hub station device 4 mobile communication terminal device 5 antenna 101 RF signal interface unit 102 A / D converter unit 103 D / A converter unit 104 mapper unit 105 demapper unit 106 distribution unit 107 transmission path interface unit 108 monitoring / control unit 109 addition / block control unit 111 transmission line interface unit 112 mapper section 113 demapper section 115 transmission line interface unit 116 addition / block control unit 121 transmission line interface unit 122 demapper section 123 D / A converter 124 antenna interface unit 125 A / D converter 126 Uplink signal blocking control unit 127 TDD transmission / reception switching control unit 128 Mapper unit BSC Base station control device BTS radio base station CNET mobile phone core network Click ENET other connection business communication network LC communication cable

Claims (13)

A communication relay system comprising at least a master station device and a plurality of slave station devices and relaying communication directly or indirectly between a wireless base station and a mobile communication terminal device,
A detection unit for detecting whether a signal transmitted in the transmission system includes an uplink signal from the mobile communication terminal apparatus in a transmission system performing transmission from the slave station apparatus to the wireless base station;
As a result of the detection by the detection unit, one or more transmission systems detected that the upstream signal from the mobile communication terminal device is not included, a predetermined number of times or more if the upstream signal is not included in a predetermined observation period And an upstream signal blocking control unit for transitioning to a blocking state of the upstream signal or maintaining the blocking state of the upstream signal when detected continuously .
If the upstream signal blocking control unit receives control to the blocking state and then receives a blocking release signal, does the upstream signal blocking control unit include an upstream signal from the mobile communication terminal until the blocking control restriction period ends? The blocking release state is maintained regardless of whether or not the transmission system including the upstream signal from the mobile communication terminal device is transitioned to the upstream signal blocking release state or the upstream signal blocking release state is specified. Maintain for a period,
Communication relay system. The upstream signal blocking control unit transitions to a blocking release state of the upstream signal or maintains the blocking release state of the upstream signal for one or more transmission systems including the upstream signal from the mobile communication terminal device.
The communication relay system according to claim 1. The communication relay system adopts a time division duplex system,
The start timing of the predetermined observation period is determined based on the transmission / reception switching timing.
The communication relay system according to claim 1. The start timing is determined based on the beginning of the radio frame of the upstream signal,
The communication relay system according to claim 3. The start timing is a symbol start time of a radio frame or a time that is an integral multiple of a symbol period from the symbol start time,
The communication relay system according to claim 3. The start timing is a slot start time of a radio frame or a time that is an integral multiple of a slot period from the slot start time,
The communication relay system according to claim 3. The predetermined observation period is a symbol period of a radio frame or a period that is an integral multiple of a symbol period from a symbol start time.
The communication relay system according to claim 1 . Let the predetermined observation period be a slot period of a radio frame or a period that is an integral multiple of the slot period,
The communication relay system according to claim 7. The detection unit and the upstream signal blocking control unit are provided in the master station apparatus, or provided in each of the plurality of slave station apparatuses.
A communication relay system according to any one of claims 1 to 8 . The communication relay system includes a master station device, a hub station device, and a plurality of slave station devices,
The detection unit and the upstream signal blocking control unit are provided in the hub station device.
A communication relay system according to any one of claims 1 to 8 . There are a plurality of transmission systems,
Exclusively blocking the upstream signals in the transmission systems of the plurality of systems based on the detection result of the upstream signals for each of the transmission systems.
The communication relay system according to any one of claims 1 to 10 . There are a plurality of transmission systems,
Blockade of the upstream signals in the plurality of transmission systems in parallel is performed based on the detection result of the upstream signal for each of the transmission systems;
The communication relay system according to any one of claims 1 to 10 . A communication relay system comprising at least a master station device and a plurality of slave station devices and relaying communication directly or indirectly between a wireless base station and a mobile communication terminal device, comprising:
Detecting whether the signal transmitted in the transmission system includes an uplink signal from the mobile communication terminal apparatus in a transmission system performing transmission from the slave station apparatus to the wireless base station;
Continuous before dangerous and out of the result, the portable communication for one or more transmission lines is detected that the information does not include an uplink signal from the terminal device does not include the uplink signal in a predetermined observation period a predetermined number of times or more Transitioning to the upstream signal blocking state or maintaining the upstream signal blocking state, if detected .
The process of maintaining the closed state includes an uplink signal from the mobile communication terminal device until the closing control restriction period ends when a closing release signal is received after receiving control to the closing state. The transmission release state is maintained regardless of whether or not the transmission system including the upstream signal from the mobile communication terminal apparatus is shifted to the upstream signal blocking release state or the upstream signal blocking release state is Maintain for a predetermined period,
Method.

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