JP6498846B2 - Wireless communication apparatus and wireless communication system - Google Patents

Description

  The present invention relates to a radio communication apparatus and a radio communication system, and for example, relates to an OFDMA radio communication apparatus and a radio communication system.

  In a radio system of OFDMA (Orthogonal Frequency Division Multiplex), there is a 1: N connection communication control technology in which a plurality of terminal stations (MS) are connected to a base station (BS) (for example, Patent Document 1). reference).

  FIG. 5 shows a radio reception block diagram of a general radio communication apparatus 110 (base station side) of the OFDMA system. FIG. 6 shows a general frame configuration diagram of the OFDMA system. The wireless communication device 110 includes an antenna 115, an RF unit 120, and a baseband unit 130. The RF unit 120 includes an LPF 121 (low pass filter), an ATT / AMP 122, and a BPF 123 (band pass filter). The baseband unit 130 includes an ADC 132, a received power calculation unit 136, and an AGC gain calculation unit 135.

  The AGC gain calculation unit 135 calculates an AGC gain value from the received power in the data burst region of the frame and transmits the AGC gain value to the ATT / AMP 122 of the RF unit 120. The ATT / AMP 122 controls the reception gain based on the AGC gain value.

  In the 1: N connection state, a plurality of Data Bursts are allocated in the frame as shown in FIG. The distance between the base station and each terminal station varies, and a difference occurs in the received power from the terminal station for the base station, so that the reception AGC of the base station cannot be appropriately controlled. For this reason, generally, at the time of 1: N connection, the reception AGC gain value of the base station (BS) is fixed, and the terminal station performs transmission power control.

JP 2008-177969 A

By the way, if the reception AGC gain value is a fixed value, there is a problem that the area where the base station can perform wireless communication is narrowed. Such an example is shown below.
(1) Reception AGC full gain fixed The terminal station connected at the cell edge (near the boundary of the communication cell) at the time of 1: 1 connection is connectable and does not change as a long-distance connectable area. However, the transmission wave from the terminal station directly below the base station becomes over-input and connection is impossible. That is, the short-distance connectable area is narrowed. Even if the terminal station performs transmission power control, the gain width of the reception AGC is generally larger than the transmission power control gain width, so that the connectable area at a short distance is narrowed when the reception AGC gain is fixed.
(2) Fixed other than the received AGC full gain When the received AGC gain value is fixed to a terminal station other than the cell edge, the connection of the terminal station that can be connected at the cell edge during 1: 1 connection becomes impossible.

  The present invention has been made in view of such a situation, and an object thereof is to solve the above problems.

The present invention is a wireless communication system in which one base station and a plurality of terminal stations can be connected 1: N (N is a natural number of 2 or more) by the OFDMA method, and the wireless communication apparatus of the base station includes the terminal A control unit that allocates a frame to each station and sets a gain value of a reception AGC when receiving a signal from the terminal station in units of frames; and the control unit is provided in an Initial Ranging area.
If the received AGC is awaited at full gain, the received power from the connected terminal station
Nevertheless, the reception AGC is performed for the initial ranging code from the unconnected terminal station.
It is characterized by that .
The present invention is a wireless communication system in which one base station and a plurality of terminal stations can be connected 1: N (N is a natural number of 2 or more) by the OFDMA method, and the wireless communication apparatus of the base station includes the terminal A control unit that assigns a frame to each station and sets a gain value of a reception AGC when receiving a signal from the terminal station in units of frames; and the control unit is connected to the base station
The terminal station does not perform data communication and does not perform data communication to the terminal station that does not perform data communication.
If no credit band is allocated, the Periodic / BR Ranging area is
The received AGC for the Periodic Ranging Code in the frame uniquely assigned to
Do.
The present invention is a wireless communication system in which one base station and a plurality of terminal stations can be connected 1: N (N is a natural number of 2 or more) by the OFDMA method, and the wireless communication apparatus of the base station includes the terminal A control unit that assigns a frame to each station and sets a gain value of a reception AGC when receiving a signal from the terminal station in units of frames, and the control unit has a plurality of terminals for the base station.
The reception AGC for each of the connected terminal stations in a state in which the terminal station is connected
When the maximum width of the gain value is smaller than the transmission power control dynamic range of the terminal station
The maximum value among the terminal stations connected to the gain value of the reception AGC is
Set as a fixed value in the frame, and the reception A that should be set in each terminal station
The difference between the gain value of GC and the fixed value is reflected in the transmission power control value of the terminal station .
Further, the control unit may perform control such that the timing of a frame allocated to the connected terminal station is defined in burst data and transmitted.
The present invention is a wireless communication apparatus that can connect 1: N (N is a natural number of 2 or more) as a base station with a plurality of terminal stations using the OFDMA method, and assigns a frame to each terminal station. A control unit that sets a gain value of a reception AGC when receiving a signal of each frame, and the control unit sets the reception AGC to a full gain in an Initial Ranging region.
Standby, regardless of the received power from the connected terminal station, from the unconnected terminal station
Receive AGC is performed for the Initial Ranging Code .
The present invention is a wireless communication apparatus that can connect 1: N (N is a natural number of 2 or more) as a base station with a plurality of terminal stations using the OFDMA method, and assigns a frame to each terminal station. A control unit configured to set a gain value of a reception AGC when receiving a signal of each frame , and the control unit is connected to the base station and the terminal station does not perform data communication.
If the terminal station that is not performing data communication is not allocated a bandwidth for data communication,
For the Periodic / BR Ranging area, the frame uniquely assigned to the terminal station is used.
The reception AGC is performed for the Periodic Ranging Code .
The present invention is a wireless communication apparatus that can connect 1: N (N is a natural number of 2 or more) as a base station with a plurality of terminal stations using the OFDMA method, and assigns a frame to each terminal station. A control unit for setting a gain value of a reception AGC when receiving a signal of each frame, and the control unit is connected in a state where a plurality of terminal stations are connected to the base station.
The maximum width of the gain value of the received AGC for each of the terminal stations is the terminal
If it is smaller than the transmission power control dynamic range of the station, the gain value of the reception AGC is set to
The maximum value among the connected terminal stations is set as a fixed value in all frames,
The difference between the gain value and the fixed value of the reception AGC that should be set in each of the terminal stations
Is reflected in the transmission power control value of the terminal station .

  According to the present invention, in OFDMA wireless communication, it is possible to suppress a reduction in communication area at the time of 1: N connection.

1 is a block diagram of an OFDMA wireless communication system according to an embodiment. It is the figure which showed the example to which the terminal station is allocated for every flame | frame based on Embodiment. It is the figure which showed the example which the 1st terminal station is allocated with respect to the data burst area | region of all the frames based on embodiment. It is the figure which showed the example of control of AGC gain and transmission power gain based on embodiment. It is a radio | wireless reception block diagram of the general radio | wireless communication apparatus of the OFDMA system based on background art. It is a general frame configuration diagram of the OFDMA system according to the background art.

  Next, modes for carrying out the present invention (hereinafter, simply referred to as “embodiments”) will be specifically described with reference to the drawings.

  FIG. 1 is a block diagram of an OFDMA wireless communication system 1 according to the present embodiment, focusing on the receiving unit block of the wireless communication device 10. 2 and 3 are diagrams illustrating an example of a frame configuration by the wireless communication system 1. FIG. In particular, FIG. 2 shows an example in which a terminal station 90 is assigned for each frame. In FIG. 3, the first terminal station 91 is assigned to the first frame FL1, the second terminal station 92 is assigned to the second frame FL2, and the third terminal station 93 is assigned to the third frame FL3. FIG. 3 shows an example in which the first terminal station 91 is assigned to the data burst area of all frames.

  As shown in FIG. 1, the wireless communication system 1 includes a wireless communication device 10 that is a base station and a plurality of terminal stations, and performs 1: N connection. Here, as a specific example of 1: N connection, a description will be given by taking an example of 1: 3 connection of three terminal stations 90 (first terminal station 91, second terminal station 92, and third terminal station 93).

  In general, in OFDMA communication, as described above, in the case of a plurality of connections (1: N connection), a data burst region of one frame is divided and assigned to each terminal station. On the other hand, in this embodiment, a technique for allocating the terminal station 90 is introduced for each frame, that is, in a time division manner. The wireless communication device 10 notifies the terminal station 90 of the frame number assigned to each terminal station 90, more specifically, the timing of periodic ranging described later, using the DL burst region.

  First, basic allocation processing will be described with reference to FIGS. 2 and 3. The frame includes a DL subframe transmitted from the wireless communication apparatus 10 toward the terminal station 90 and a UL subframe received from the terminal station 90 by the wireless communication apparatus 10.

  Ranging for synchronizing signal output and signal timing is performed between the radio communication apparatus 10 serving as a base station apparatus and the terminal station 90 using UL subframes. At the beginning of the UL subframe, an initial ranging area is provided. This initial ranging signal is performed when the mobile terminal enters the network. Next, a periodic ranging area periodically performed by the terminal station 90 in a connected state, and a bandwidth request ranging area (BR Ranging) area for requesting a bandwidth are provided, followed by a UL data burst. An area is provided.

  On the other hand, in the DL subframe transmitted from the radio communication apparatus 10, a symbol pattern called “Preamble” is assigned to the first symbol. When the terminal station 90 is initially synchronized with the radio communication device 10, the terminal station 90 scans the frequency, and after the terminal station 90 performs a search for the surrounding base station, that is, the radio communication device 10, the preamble signal at the head of this DL subframe is transmitted. Acquisition and establishment of downlink synchronization with the wireless communication apparatus 10 are performed. By using this preamble signal, signal quality such as received signal strength can be measured.

  Next to the preamble signal, frame control header information (FCH) is transmitted. The frame control header information (FCH) includes the allocation status (modulation method, burst length, etc.) of data bursts transmitted after the frame control header.

  Next to the frame control header information (FCH), mapping information (MAP) is transmitted. The mapping information includes information commonly broadcast to all areas covered by the base station device, such as base station information periodically transmitted from the radio communication device 10 serving as the base station device. The terminal station 90 determines whether or not access to the network is possible by acquiring the broadcast information. DL burst data is transmitted following the mapping information.

  A specific configuration of the wireless communication device 10 will be described with reference to FIG. The wireless communication device 10 includes an antenna 15, an RF unit 20, and a baseband unit 30.

  The RF unit 20 includes a BPF 23, an ATT / AMP 22, and an LPF 21 from the antenna 15 side. A signal (DL subframe) received by the antenna 15 is output to the baseband unit 30 via the BPF 23, the ATT / AMP 22, and the LPF 21. On the other hand, the signal (UL subframe) generated by the baseband unit 30 is transmitted from the antenna 15 via the LPF 21, the ATT / AMP 22, and the BPF 23. Here, the reception function will be mainly described.

  The ATT / AMP 22 acquires an AGC gain value from the control unit 31 described later, and controls the reception gain for each frame based on the value. As a result, an area similar to that at the time of 1: 1 connection can be secured for each terminal station 90.

  The baseband unit 30 includes a control unit 31, an ADC 32, a SW 33, a received power calculation unit 34, an AGC gain value storage memory 50, and an AGC gain value storage memory 50.

  The control unit 31 performs overall control of each component, and also performs an SW33 selection operation, an AGC gain value instruction to the ATT / AMP 22, and an AGC gain value storage instruction to the AGC gain value storage memory 50.

  The ADC 32 converts the analog signal output from the RF unit 20 into a digital signal, and outputs the digital signal to the received power calculation unit 34 via the SW 33.

  The received power calculation unit 34 includes an initial ranging symbol unit 36, a periodic / BR ranging symbol unit 37, and a data burst unit 38.

  The Initial Ranging Symbol unit 36 refers to the initial ranging area of the DL subframe and performs the above-described initial ranging. The Periodic / BR Ranging Symbol unit 37 similarly performs the above-described periodic initial ranging and bandwidth request ranging. The Data Burst unit 38 refers to the data burst area of the DL subframe and identifies the received power.

  The AGC gain calculation unit 35 determines an AGC gain value used for reception gain control in the ATT / AMP 22 for each frame, and notifies the control unit 31 of the AGC gain value.

The AGC gain value storage memory 50 includes a first terminal station area 51, a second terminal station area 52,
The third terminal station area 53, the fourth terminal station area 54,... Are acquired from the control unit 31 and stored in the AGC gain value corresponding to the terminal station 90 to be connected. For example, the AGC gain value used for reception of the first terminal station 91 is stored in the first terminal station area 51. The second terminal station area 52 stores an AGC gain value used for reception by the second terminal station 92. Further, when a connection with a fourth terminal station (not shown) is newly established, an AGC gain value used for reception of the fourth terminal station is stored.

Next, a connection sequence between the wireless communication device 10 and the terminal station 90 will be described.
(Step 1A) The first terminal station 90 (for example, the first terminal station 91) is connected by performing AGC based on the received power in the Data Burst section as in the case of 1: 1 connection. The AGC gain value is stored in the AGC gain value storage memory 50 (first terminal station area 51).
(Step 2A) Wait for reception AGC in the initial ranging area with full gain for the terminal station 90 connected to the second and subsequent units.
(Step 3A) The newly entering terminal station 90 (for example, the second terminal station 92) continuously transmits the initial ranging code. The radio communication apparatus 10 serving as a base station controls the AGC gain value to an appropriate value, and uses this value as the AGC gain value of the terminal station 90 connected to the second unit as the AGC gain value storage memory 50 (second terminal station). Storage area 52).
(Step 4A) The control unit 31 feeds back the AGC gain value calculated in step 3 to the ATT / AMP 22 of the RF unit 20 in the periodic ranging region and data burst region of the second frame FL2. Thereafter, the AGC gain is calculated from the received power in the UL data burst 2 region of the second frame FL2.
(Step 5A) For connection with the third and subsequent terminal stations 90, the same processing as in Step 3 and Step 4 is performed.

  Next, the case where the first to third terminal stations 91 to 93 establish connection with the wireless communication apparatus 10 with reference to FIG. 3 but only the first terminal station 91 performs data communication will be described. As shown in the figure, when the second terminal station 92 and the third terminal station 93 are not performing data communication, all frames are assigned to the first terminal station 91.

  A sequence in which the second terminal station 92 and the third terminal station 93 resume data communication from this state will be described. Here, even if all the data bursts are assigned to the first terminal station 91, the connected second terminal station 92 and third terminal station 93 are in the periodic / band request ranging area of the frame number assigned to them. A periodic ranging code is transmitted at. The wireless communication device 10 controls the AGC gains for the second terminal station 92 and the third terminal station 93 to appropriate values from these periodic ranging codes.

(Step 1B) The second terminal station 92 and the third terminal station 93 transmit a band request ranging code (BR Ranging Code) in the periodic / band request ranging area in the frame number assigned to the own station. Make a request. Since the AGC value is controlled to an appropriate value by the periodic ranging code, the wireless communication device 10 as the base station can receive the band request ranging code without any problem.
(Step 2B) The radio communication apparatus 10 allocates the data burst area of the second frame FL2 to the second terminal station 92 and the data burst area of the third frame FL3 to the third terminal station 93.
(Step 3B) The radio communication apparatus 10 feeds back the AGC gain value calculated from the periodic / band request ranging area of the second frame FL2 to the ATT / AMP 22 in the data burst area of the second frame FL2. Thereafter, reception control for the second terminal station 92 is performed using the AGC gain value calculated from the data burst area.
(Step 4B) The radio communication apparatus 10 feeds back the AGC gain value calculated from the periodic / band request ranging area of the third frame FL3 to the ATT / AMP 22 in the data burst area of the third frame FL3. Thereafter, reception control for the third terminal station 93 is performed using the AGC gain value calculated from the data burst area.

  The AGC gain is not limited to the operation that is feedback-controlled by the automatic control as described above (referred to as “normal operation” for convenience), but the operation that is fixed to the base station reception AGC under a certain condition (for convenience) (Referred to as “AGC fixed operation”). Specifically, the control unit 31 of the wireless communication device 10 determines from the reception AGC gain for each terminal station 90 that the communication quality is maintained by the base station reception AGC fixing and the terminal station power control, that is, each When the maximum width of the received AGC gain value for the terminal station 90 is smaller than the transmission power control dynamic range, the received AGC gain value is fixed to the maximum value among the received AGC gain values of the plurality of connected terminal stations 90, and the difference is set to another terminal. By performing transmission power control at the station 90, switching is made to intra-frame multiple burst allocation. This makes it possible to allocate bandwidth efficiently.

  FIG. 4 shows a control example of such AGC gain and transmission power gain. In this example, the AGC gain for the first terminal station 91 is 20 dB, the AGC gain for the second terminal station 92 is −5 dB, and the AGC gain for the third terminal station 93 is −10 dB on the receiving side during normal operation. The difference between the maximum and minimum is 30 dB. On the transmission side, all transmission power gains for the first terminal station 91 to the third terminal station 93 are 0 dB.

  Here, when the dynamic range of the ATT / AMP 22 is 30 dB or more, as shown in the figure, as the AGC fixed operation, all the AGC gains for the first terminal station 91 to the third terminal station 93 are fixed to a maximum value of 20 dB. The transmission power gain is set to a value reflecting the difference in the base station reception AGC gain value during normal operation. Specifically, the transmission power gain for the first terminal station 91 is set to 0 dB, the transmission power gain for the second terminal station 92 is set to −25 dB, and the transmission power gain for the third terminal station 93 is set to −30 dB. Note that when the AGC fixed operation becomes difficult due to the movement of the terminal station 90 or the change in the reception environment, the control unit 31 returns to the normal operation. By using such an operation method, both power saving and ensuring communication quality can be achieved.

  As another operation method, if the AGC gain values of the plurality of terminal stations 90 are close, the same frame is allocated to the terminal station 90 having the close AGC gain value and the same AGC gain value is used. May be. For example, a situation is assumed in which the AGC gain for the first terminal station 91 is 10 dB, the AGC gain for the second terminal station 92 is 9 dB, and the AGC gain for the third terminal station 93 is −15 dB. At this time, the AGC gains of the first terminal station 91 and the second terminal station 92 are close to each other. Therefore, when the control unit 31 determines that the bandwidth requirements of the first terminal station 91 and the second terminal station 92 are relatively small and the two bandwidths are combined, the same AGC gain value is obtained. Then, using the larger value of 10 dB, the data burst area is divided into two areas of the first terminal station 91 and the second terminal station 92 as shown in FIG. For the third terminal station 93, since the AGC gain value is different from the others, one frame is allocated. By performing such operations, the bandwidth can be effectively utilized.

  As described above, according to the present embodiment, an equivalent communication area can be established regardless of 1: 1 connection or 1: N connection in OFDMA communication. Further, by appropriately changing the operation method as described above, it is possible to realize power saving and effective use of bandwidth.

  The present invention has been described based on the embodiments. This embodiment is an exemplification, and it will be understood by those skilled in the art that various modifications can be made to combinations of these components, and such modifications are also within the scope of the present invention.

DESCRIPTION OF SYMBOLS 1 Wireless communication system 10 Wireless communication apparatus 15 Antenna 20 RF part 21 LPF
22 ATT / AMP
23 BPF
30 Baseband unit 31 Control unit 32 ADC
33 SW
34 Received power calculation unit 35 AGC gain calculation unit 36 Initial Ranging Symbol unit 37 Periodic / BR Ranging Symbol unit 38 Data Burst unit 50 AGC gain value storage memory 51 First terminal station area 52 Second terminal station area 53 Third terminal Station area 54 Fourth terminal station area

Claims (7)

One base station and a plurality of terminal stations 1: N (N is a natural number of 2 or more) by OFDMA
A connectable wireless communication system,
The radio communication device of the base station includes a control unit that assigns a frame to each terminal station and sets a gain value of a reception AGC when receiving a signal from the terminal station in units of frames .
The control unit waits for the received AGC at full gain in the Initial Ranging area.
Regardless of the received power from the connected terminal station, Initia from the unconnected terminal station
l A radio communication system, wherein the reception AGC is performed on a Ranging Code . One base station and a plurality of terminal stations 1: N (N is a natural number of 2 or more) by OFDMA
A connectable wireless communication system,
The radio communication device of the base station includes a control unit that assigns a frame to each terminal station and sets a gain value of a reception AGC when receiving a signal from the terminal station in units of frames.
The control unit is configured such that the terminal station connected to the base station does not perform data communication and transmits data.
If no bandwidth for data communication is allocated to the terminal station that is not communicating, Period
For the ic / BR Ranging area, the frame uniquely assigned to the terminal station
Iodic Ranging radio communications system that and performing the reception AGC to Code. One base station and a plurality of terminal stations 1: N (N is a natural number of 2 or more) by OFDMA
A connectable wireless communication system,
The radio communication device of the base station includes a control unit that assigns a frame to each terminal station and sets a gain value of a reception AGC when receiving a signal from the terminal station in units of frames.
The control unit is connected to a plurality of terminal stations connected to the base station.
The maximum width of the gain value of the reception AGC for each terminal station is determined by the transmission of the terminal station.
If the received power control dynamic range is smaller, connect the gain value of the received AGC.
Is set as a fixed value in all the frames,
The difference between the gain value and the fixed value of the reception AGC that should be set in the terminal station
, Radio communications system, characterized in that to reflect the transmission power control value of the mobile station. 2. The radio communication system according to claim 1, wherein the control unit controls the frame timing allocated to the connected terminal station to be defined and transmitted in burst data. As a base station, a wireless communication apparatus that can be connected to a plurality of terminal stations by an OFDMA method in a 1: N (N is a natural number of 2 or more),
A receiving AG for assigning a frame to each terminal station and receiving a signal from the terminal station
A control unit for setting the gain value of C in units of frames ;
The control unit waits for the received AGC at full gain in the Initial Ranging area.
Regardless of the received power from the connected terminal station, Initia from the unconnected terminal station
the wireless communication apparatus you and performs reception AGC to l Ranging Code. As a base station, a wireless communication apparatus that can be connected to a plurality of terminal stations by an OFDMA method in a 1: N (N is a natural number of 2 or more),
A receiving AG for assigning a frame to each terminal station and receiving a signal from the terminal station
A control unit for setting the gain value of C in units of frames ;
The control unit is configured such that the terminal station connected to the base station does not perform data communication and transmits data.
If no bandwidth for data communication is allocated to the terminal station that is not communicating, Period
For the ic / BR Ranging area, the frame uniquely assigned to the terminal station
the wireless communication apparatus you and performs the reception AGC to iodic Ranging Code. As a base station, a wireless communication apparatus that can be connected to a plurality of terminal stations by an OFDMA method in a 1: N (N is a natural number of 2 or more),
A receiving AG for assigning a frame to each terminal station and receiving a signal from the terminal station
A control unit for setting the gain value of C in units of frames ;
The control unit is connected to a plurality of terminal stations connected to the base station.
The maximum width of the gain value of the reception AGC for each terminal station is determined by the transmission of the terminal station.
If the received power control dynamic range is smaller, connect the gain value of the received AGC.
Set the maximum value among the terminal stations that are fixed as a fixed value in all frames.
The difference between the gain value and the fixed value of the reception AGC that should be set in the terminal station
A wireless communication apparatus, which is reflected in a transmission power control value of a terminal station .

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