JP2011244077A - Radio communication equipment, radio communication system, and communication control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To eliminate a lack of packet data by overflow in radio communication equipment using a plurality of radio transmission paths and an adaptive modulation system.SOLUTION: Receiving parts 11a and 11b output pieces of reception data for every radio transmission path (Route_A and Route_B), information extraction parts 12a and 12b generate pieces of transmission control information 22a and 22b for specifying transmission rate and a modulation system to each radio transmission path from the pieces of reception data to be output from the receiving parts 11a and 11b. A service quality control part 14 determines the transmission rate, the modulation system, and sorting ratio to each radio transmission path based on the pieces of transmission control information 22a and 22b, and outputs a transmission frame from transmission data 31 to each radio transmission path. Transmission parts 13a and 13b input transmission frames from the service quality control part 14, and output transmission signals according to the transmission rate, and the modulation system set for every transmission path based on the pieces of transmission control information 22a and 22b.

Description

  The present invention relates to a wireless communication apparatus, a wireless communication system, and a communication control method that transmit IP packet data using a plurality of wireless transmission paths and use an adaptive modulation method.

  In a wireless communication apparatus that performs packet transmission, an adaptive modulation method that changes a modulation method in accordance with the state of a wireless transmission path may be employed. The adaptive modulation system is switched to a modulation system with a large number of multi-levels when the wireless transmission path conditions are good, and when the wireless transmission path conditions are poor, the multi-level number of the modulation system is lowered and transmitted. The modulation method is switched to a low-speed modulation method. Thus, in a wireless communication system that employs an adaptive modulation scheme in a wireless communication section, the wireless transmission rate varies depending on the state of the wireless transmission path. In this case, in order to maintain a necessary network environment, it is necessary to perform QoS control on IP packet data to be transmitted in accordance with a change in the wireless transmission speed of the wireless communication section. It is necessary to perform QoS control.

  Note that “QoS (Quality of Service) control” refers to packet scheduling and shaping. In addition, the above “maintain necessary network environment” means that time critical data such as voice and video is delivered to the destination device within a certain time on the IP network. This shows that priority (QoS) control for transferring data in consideration of QoS (Quality of Service) of traffic is applied to each node device.

  There are related base station apparatuses, terminals, and bandwidth control methods (see Patent Document 1). The terminal and the bandwidth control method described in Patent Document 1 are intended to realize bandwidth-guaranteed communication in a communication system using an adaptive modulation scheme. For this reason, in the radio base station, a fixed resource is allocated to the fixed terminal, and a resource amount necessary for using a low-speed modulation scheme is allocated to the mobile terminal. When a higher-speed modulation method than a low-speed modulation method can be used for the connection with the mobile terminal, data is modulated using the high-speed modulation method.

  Further, there is a related transmission side wireless communication apparatus and packet transmission method (see Patent Document 2). The transmission side wireless communication apparatus and the packet transmission method described in Patent Document 2 select a wireless communication channel configuration method according to wireless communication quality when the wireless communication channel is configured using at least one physical channel. The purpose is to do. For this purpose, the wireless communication terminal sets a wireless communication channel with the wireless base station, and the wireless communication terminal selects either the aggregate channel method or the single channel method according to the wireless quality information. .

  There are also related wireless communication terminals, wireless base stations, and packet communication methods (see Patent Document 3). The wireless communication terminal, the wireless base station, and the packet communication method described in Patent Document 3 are intended to adapt a session setting method for setting a plurality of communication sessions on a wireless communication channel to the communication state of the wireless communication terminal. . For this reason, in the first session setting method, the wireless communication terminal and the wireless base station allow all types of packets to be transmitted using one wireless communication channel, and the communication band per wireless communication channel is wide. In the second session setting method, a specific type of packet is transmitted using a dedicated wireless communication channel, even if the communication bandwidth per wireless communication channel is narrow. Suppresses the transmission delay of the type packet.

  There are also related wireless communication systems, scheduling methods, communication devices, and programs (see Patent Document 4). The communication device described in Patent Document 4 is intended to obtain good transmission efficiency in the technique of arranging clustered frequency signals. For this purpose, in a technique for arranging clustered frequency signals, clusters are arranged only in frequency bands that satisfy a predetermined reception quality.

JP 2007-266719 A JP 2009-141522 A JP 2009-159310 A JP 2010-054442 A

  When normal QoS control used for a wired LAN is applied to a wireless communication system that uses a plurality of wireless transmission paths and adopts an adaptive modulation method for the wireless transmission path, the wireless transmission speed of the wireless transmission path is packet data. If it is larger than the transmission speed of the packet data, there is no packet data waiting time. However, when the packet data rate exceeds the wireless transmission rate, a waiting time for flow control occurs, or packet data loss (packet loss) due to overflow occurs.

  Therefore, it has been desired to perform efficient packet transfer by eliminating the waiting time of packet data by performing optimum QoS control (shaping) for a plurality of wireless transmission paths (wireless lines). Note that the prior art described in Patent Document 1 to Patent Document 4 does not attempt to perform QoS control simultaneously on a plurality of wireless lines in accordance with the quality (transmission state) of the plurality of wireless transmission paths. Absent.

  The main object of the present invention is to suppress the transmission rate of packet data without exceeding the total transmission rate (upper limit transmission rate) of a plurality of wireless transmission paths in a wireless communication apparatus using a plurality of wireless transmission paths and an adaptive modulation method. Then, it is providing the radio | wireless communication apparatus, the radio | wireless communications system, and the communication control method which can eliminate the loss of the packet data by generation | occurrence | production of the waiting time for flow control, and overflow.

  The present invention has been made to solve the above-described problems, and the wireless communication apparatus of the present invention can transmit packet data using a plurality of wireless transmission paths and an adaptive modulation scheme with a variable modulation scheme. The transmission status of each wireless transmission path is monitored, an upper limit transmission rate that is an upper limit is set according to the transmission status of each wireless transmission path, and the modulation method and transmission in each wireless transmission path are set according to the upper limit transmission rate. It is characterized in that the rate and the transmission data distribution ratio are changed.

  In the wireless communication apparatus of the present invention, a plurality of wireless transmission paths are monitored, and an upper limit transmission rate that can be transmitted through the plurality of wireless transmission paths is set according to the transmission status of each wireless transmission path. Accordingly, the modulation scheme, transmission rate, and transmission data distribution ratio for each wireless transmission path are changed, so that the information transmission rate does not exceed the upper limit transmission rate, and flow control is performed. Occurrence of waiting time and loss of packet data due to overflow can be eliminated.

It is a block diagram which shows the structure of the radio | wireless communication apparatus concerning the 1st Embodiment of this invention. It is a block diagram which shows the structure of the service quality control part of the wireless communication apparatus shown in FIG. 3 is a graph showing an operation of the wireless communication apparatus shown in FIG. It is a block diagram which shows the structure of the radio | wireless communications system concerning the 2nd Embodiment of this invention. It is a figure which shows the format of the frame in the radio | wireless communications system shown in FIG. FIG. 5 is a block diagram illustrating a configuration of a transmission baseband processing unit of a wireless communication device in the wireless communication system illustrated in FIG. 4. It is a block diagram which shows the structure of the reception baseband process part concerning the 3rd Embodiment of this invention.

[Overview]
In a wireless communication system that employs an adaptive modulation method in a wireless communication section, the wireless transmission rate varies depending on the state of the wireless transmission path. The present invention is characterized in that QoS control is performed on IP packet data to be transmitted in accordance with a change in wireless transmission speed in a wireless communication section in order to maintain a necessary network environment. Furthermore, it is characterized in that a plurality of wireless communication sections are simultaneously subjected to QoS control.

  For this reason, in the present invention, optimum QoS control (shaping) is performed for the modulation scheme selected by adaptive modulation. Also, the switching timing of QoS control (shaping) is controlled by comparing the current modulation method and the next modulation method. As a result, the optimal QoS control (shaping) is always performed, thereby eliminating the waiting time of packet data and performing efficient packet transfer.

[First embodiment]
Next, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a block diagram showing a configuration of a communication apparatus according to the first embodiment of the present invention. The communication apparatus shown in FIG. 1 includes a reception unit 11a, a reception unit 11b, an information extraction unit 12a, an information extraction unit 12b, a transmission unit 13a, a transmission unit 13b, and a service quality control unit 14.

The receiving unit 11a receives the input signal 20a and outputs received data 21a. The information extraction unit 12a receives the reception data 21a from the reception unit 11a, extracts the transmission control information 22a from the reception data 21a, and outputs it to the service quality control unit 14. The transmission control information 22a specifies a transmission rate when the transmission unit 13a transmits the transmission signal 30a. The transmission control information 22 may specify a modulation method when the transmission unit 13a performs modulation. Specifically, the transmission control information 22a may specify a modulation target (amplitude, frequency, or phase), a multi-value number that is the number of modulation steps, a modulation rate, and the like.
Even when the transmission control information 22a specifies the modulation method, the transmission unit 13a can determine the transmission rate at which the transmission signal 30a is transmitted based on the transmission control information 22a.

  The transmission unit 13a receives the transmission frame 32a from the service quality control unit 14. The transmission unit 13a outputs the transmission signal 30a at the first transmission rate a set based on the transmission control information 22a input from the information extraction unit 12a. The transmission unit 13a outputs a transmission timing signal 33a indicating the completion timing of transmission of the transmission signal. The first transmission rate a is set for each transmission frame 32a.

Each time the transmission unit 13a outputs the transmission timing signal 33a, the transmission unit 13a changes the first transmission rate a when the next transmission signal 30a is transmitted. Also, the transmission control information 22a during transmission of the transmission signal 30a is not the transmission rate at that time (that is, the first transmission rate a), but the transmission rate at which the next transmission signal 30a is transmitted (hereinafter referred to as “the first transmission rate 30a”). 2) is designated. In other words, the first transmission rate a, that is, the transmission rate of the transmission signal 30a being transmitted is specified by the previous transmission control information 22a. The second transmission rate a, that is, the transmission rate of the transmission signal 30a to be transmitted next is specified by the current transmission control information 22a. The transmission unit 13a outputs transmission rate information 34a indicating the first transmission rate to the service quality control unit 14.
The service quality control unit 14 performs service quality control (QoS control and distribution control). Specifically, the transmission frame 32a and the transmission frame 32b are generated from the transmission data 31 and output based on the set upper limit transmission rate and distribution ratio. The detailed configuration and operation of the service quality control unit 14 will be described later.

  The configuration of the reception unit 11a, the information extraction unit 12a, the transmission unit 13a, and the service quality control unit 14, which are upper-side circuit portions (portions related to the wireless transmission path Route_A), has been described above. The same applies to the portion (portion related to the wireless transmission path Route_B). That is, the configurations of the reception unit 11b, the information extraction unit 12b, the transmission unit 13b, and the service quality control unit 14 are the same as those on the upper side. Regarding the lower circuit portion, in the description of the upper circuit portion (the portion related to Route_A) described above, the subscripts of the symbols of the respective processing units and signals are changed from the code “a” to the code “b”. become. For example, the receiving unit 11a is replaced with the receiving unit 11b, the information extracting unit 12a is replaced with the information extracting unit 12b, and the transmitting unit 13a is replaced with the transmitting unit 13b. The service quality control unit 14 is used in common. Also, the input signal 20a is replaced with the input signal 20b, the reception data 21a is replaced with the reception data 21b, the transmission control information 22a is replaced with the transmission control information 22b, and the transmission frame 32a is replaced with the transmission frame 32b. The same applies to other signal names. For this reason, the overlapping description about the configuration of the circuit portion on the lower side is omitted.

(Description of configuration and operation of service quality control unit 14)
The operation of the service quality control unit 14 will be described in detail with reference to the drawings. FIG. 2 is a block diagram showing a configuration of a service quality control unit in the wireless communication apparatus shown in FIG.
As shown in FIG. 2, the service quality control unit 14 includes a QoS control unit 41 and a distribution control unit 42. The QoS control unit 41 outputs post-QoS control-processed data 43 from the transmission data 31 so as to be equal to or lower than the wireless transmission speed of the wireless transmission path. At this time, the QoS control unit 41 detects that the first transmission rate changes, that is, that the first transmission rate and the second transmission rate are different, and performs the following control on the upper limit transmission rate. I do. Since the total transmission rate of the transmission signal 30a and the transmission signal 30b is specified by the transmission control information 22a and the transmission control information 22b, the QoS control unit 41 observes changes in the transmission control information 22a and the transmission control information 22b. Thus, it is detected that the total transmission rate changes.

  When it is detected that the second transmission rate a and the second transmission rate b are smaller than the first transmission rate a and the first transmission rate b, the QoS control unit 41 sets the upper limit transmission rate to the second transmission rate a The transmission rate is changed to the total transmission rate of the transmission rate a and the second transmission rate b. In other words, when the QoS control unit 41 detects that the total transmission rate of the transmission signal 30a and the transmission signal 30b is reduced, the QoS control unit 41 changes the upper limit transmission rate to the transmission rate after the reduction. Before the transmission rate of the transmission signal 30a (or transmission signal 30b) is reduced by the control, the transmission rate of the transmission frame 32a (or transmission frame 32b) is reduced, and a transmission waiting time by flow control or a frame due to overflow・ Can prevent loss.

  Also, when it is detected that the second transmission rate a and the second transmission rate b are larger than the transmission rate a and the first transmission rate b, the QoS control unit 41 transmits the transmission unit 13a (or the transmission unit). 13b), the upper limit transmission rate is changed to the next transmission rate at the timing when the transmission rate of the transmission signal 30a (or transmission signal 30b) is changed. In other words, when the QoS control unit 41 detects that the transmission rate of the transmission signal 30a (or transmission signal 30b) increases, the QoS control unit 41 waits for the output of the transmission timing signal 33a (or transmission timing signal 33b), Change the transmission rate to the increased transmission rate. By the above control, after the transmission rate of the transmission signal 30a (or transmission signal 30b) is increased, the transmission rate of the post-QoS control data 43 is increased to increase the transfer efficiency.

  The distribution control unit 42 distributes and outputs from the post-QoS control data 43 to the transmission frame 32a and the transmission frame 32b so that the transmission rate necessary for transmission is in accordance with the distribution ratio. At this time, the distribution control unit 42 changes the first transmission rate a and the first transmission rate b, that is, the first transmission rate a (or the first transmission rate b) and the second transmission. It detects that the rate a (or the second transmission rate b) is different. The distribution control unit 42 changes the upper limit transmission rate to the next transmission rate at the timing when the transmission rate of the transmission signal 30a (or transmission signal 30b) is changed in the transmission unit 13a (or transmission unit 13b). In other words, when the QoS control unit 41 detects an increase in the transmission rate of the transmission signal 30a (or transmission signal 30b), it waits for the output of the transmission timing signal 33a (or transmission timing signal 33b) and transmits The frame 32a and the transmission frame 32b are output according to the distribution ratio. At this time, the distribution ratio follows the ratio of the transmission rate of the first transmission rate a and the first transmission rate b.

By the above control, the transmission rate ratio between the transmission signal 30a and the transmission signal 30b and the transmission rate ratio between the transmission frame 32a and the transmission frame 32b are combined to prevent the occurrence of frame loss due to transmission waiting time or overflow due to flow control. Or increase the transfer efficiency.
Note that the first transmission rate a (or the first transmission rate b) is equal to the second transmission rate a (or the second transmission rate b), that is, the transmission rates of the transmission signals 30a and 30b are changed. If not, the upper limit transmission rate and distribution ratio are not changed.

  Thus, by controlling by the service quality control unit 14, the transmission rate (information transmission rate) of each of the transmission frame 32a and the transmission frame 32b is always determined by the transmission unit 13a and the transmission unit 13b. And the transmission rate applicable when transmitting the transmission signal 30b, that is, the bandwidth or less.

  Next, a specific operation example in the wireless communication apparatus of the present embodiment will be described with reference to the graph of FIG. FIG. 3 is a graph showing an operation example of the wireless communication apparatus according to the first embodiment of the present invention, where the vertical axis represents a transmission rate and the horizontal axis represents time. For each line in the graph, a solid line A indicates a bandwidth, and a broken line B indicates an upper limit transmission rate for performing QoS control. In the lower part of the graph, the first transmission rate a (current modulation scheme), which is the transmission rate applied to the transmission signal 30a currently being transmitted to the radio transmission path (Route_A), and the next transmission signal 30a are shown. The transition of the 2nd transmission rate a (next modulation system) which is a transmission rate applied is shown. Also, the first transmission rate b (current modulation scheme) that is the transmission rate applied to the transmission signal 30b currently being transmitted to the wireless transmission path (Route_B), and the transmission rate applied to the next transmission signal 30b. A transition of a certain second transmission rate b (next modulation method) is shown. Furthermore, a distribution ratio is shown. The transmission rate can be set to any of the three types R3, R2, and R1, and is assumed to increase in this order.

  At time t1, the service quality control unit 14 detects that the transmission rate of the wireless transmission path Route_A changes from R3 to R2 based on the transmission control information 22a. In this case, it means that the total transmission rate is lowered. However, the transmission rate indicated by the transmission control information 22a is a transmission rate applied to the next transmission signal 30a, and the transmission rate actually changes after the transmission of the currently transmitted transmission signal 30a is completed. is there.

  At this time, the service quality control unit 14 immediately switches the upper limit transmission rate to the total transmission rate of the second transmission rate a and the second transmission rate b. That is, the upper limit transmission rate is lowered before the timing (time t2) when the transmission rate applied to the transmission signal 30a is lowered. At this time, the distribution ratio is switched at the timing (time t2) when the first transmission rate a is changed.

  The same applies to time t3. That is, the service quality control unit 14 detects that the second transmission rate a simultaneously decreases from R2 to R1 and the second transmission rate b from R3 to R2 at time t3, and the upper limit transmission rate at time t3. Is switched to the total transmission rate of the second transmission rate a and the second transmission rate b.

  The same applies to time t4. That is, the service quality control unit 14 switches to the distribution ratio at the timing (time t4) when the first transmission rate a and the first transmission rate b are changed.

  At time t7, the service quality control unit 14 detects that the second transmission rate b is higher than the first transmission rate b. At this time, at the timing (time t8) when the first transmission rate b is changed, the upper limit transmission rate is switched to the total transmission rate of the second transmission rate a and the second transmission rate b and the distribution ratio.

  The same applies to time t9. That is, it is detected that the second transmission rate a and the second transmission rate b increase at the same time as the first transmission rate a and the first transmission rate b at time t9, and the upper limit transmission rate at time t10, And switch the distribution ratio.

  At time t11, the service quality control unit 14 simultaneously detects that the second transmission rate a is higher than the first transmission rate a and the second transmission rate b is lower than the first transmission rate b. . At this time, since the total transmission rate of the second transmission rate a and the second transmission rate b does not change, the service quality control unit 14 switches only the distribution ratio at time t12.

  As described above, when the wireless communication device according to the first embodiment of the present invention detects that the transmission rate of the transmission signal to be transmitted next decreases, the wireless communication device immediately decreases the upper limit transmission rate, After the signal transmission is completed, the distribution ratio is switched. When an increase in the transmission rate of the transmission signal to be transmitted next is detected, after the transmission of the transmission signal being transmitted is completed, the upper limit transmission rate is increased and the distribution ratio is switched. Then, a transmission frame is generated so as to be equal to or lower than the upper limit transmission rate. Therefore, the information transmission rate is always equal to or lower than the transmission rate in the transmission unit. Therefore, it is possible to prevent packet loss due to transmission waiting and overflow due to flow control of the transmission frame, and at the same time improve transfer efficiency.

[Second Embodiment]
Next, a second embodiment in which the wireless communication apparatus of the present invention is applied to a specific wireless communication system will be described. FIG. 4 is a block diagram showing a configuration of a wireless communication system according to the second embodiment of the present invention. This wireless communication system is an example of a wireless communication system to which the wireless communication apparatus of the present invention is applied. FIG. 5 shows a frame format in the wireless communication system of the second embodiment. FIG. 6 is a block diagram illustrating a configuration of a transmission baseband processing unit in the wireless communication system according to the second embodiment.

  The radio communication system shown in FIG. 4 includes a pair of radio communication apparatuses 100 and 200 facing each other. The wireless communication apparatus 100 includes a transmission baseband processing unit 101, a modulator 102a, a modulator 102b, an RF (Radio Frequency) unit 103a, an RF unit 103b, a reception modulation method determination unit 105a, a reception modulation method determination unit 105b, and a reception baseband. A processing unit 106, a demodulator 107a, a demodulator 107b, and an antenna unit 108b are provided. The radio communication apparatus 200 includes a transmission baseband processing unit 201, a modulator 202a, a modulator 202b, an RF unit 203a, an RF unit 203b, a reception modulation method determination unit 205a, a reception modulation method determination unit 205b, and a reception baseband processing unit. 206, a demodulator 207a, a demodulator 207b, an antenna unit 208a, and an antenna unit 208b. Since the wireless communication device 100 and the wireless communication device 200 have the same configuration, the configuration of the wireless communication device 100 will be described below.

  The transmission baseband processing unit 101 performs QoS control / distribution control on the input data 109. Specific processing contents of the QoS control / distribution control will be described later. The transmission baseband processing unit 101 selects a modulation scheme based on the modulation scheme control information 112 a input from the reception baseband processing unit 106. The transmission baseband processing unit 101 multiplexes the input data 109, the modulation scheme control information 112a, and the modulation scheme designation information 114a together with various control signals into the transmission radio frame data 110a in the format shown in FIG. Each frame of the transmission radio frame data 110a includes an overhead part and a payload part. Input data 109 is stored in the payload portion. The overhead part stores modulation scheme control information 112a and modulation scheme designation information 114a. The transmission baseband processing unit 101 outputs the transmission radio frame data 110a to the modulator 102a.

  Since the modulator 102a and the modulator 102b have the same configuration, the configuration of the modulator 102a will be described below. The modulator 102a modulates the transmission radio frame data 110a input from the transmission baseband processing unit 101 according to the modulation scheme control information 112a stored in the overhead part of the transmission radio frame data 110a one frame before. The modulator 102a outputs the modulated signal to the RF unit 103a as a transmission IF (Intermediate Frequency) signal 111a.

  Since the RF unit 103a and the RF unit 103b have the same configuration, the configuration of the RF unit 103a will be described below. The RF unit 103a frequency-converts the input transmission IF signal 111a to a specified radio frequency. The RF unit 103a transmits the frequency-converted radio signal to the radio communication device 200 through the antenna unit 108a. Further, the RF unit 103a has a frequency conversion function for the received radio signal. The RF unit 103a receives the radio signal transmitted from the radio communication device 200 through the antenna unit 108a. Then, the RF unit 103a performs frequency conversion on the received radio signal, and outputs it to the demodulator 107a as a reception IF signal 118a. Furthermore, the RF unit 103a outputs the received signal level as reception level information 117a to the reception modulation scheme determination unit 105a.

  Since reception modulation scheme determination section 105a and reception modulation scheme determination section 105b have the same configuration, the configuration of reception modulation scheme determination section 105a will be described below. Reception modulation scheme determination section 105a selects a transmission modulation scheme based on reception level information 117a, and outputs modulation scheme designation information 114a to transmission baseband processing section 101. As described above, modulation scheme designation information 114 a is multiplexed with transmission radio frame data 110 a and transmitted to radio communication apparatus 200. That is, the radio communication device 100 specifies a modulation scheme to be applied by the radio communication device 200 to the radio communication device 200. As described above, in the adaptive modulation method in the wireless communication system of the present embodiment, the reception-side wireless communication device requests the transmission modulation method to be applied to the opposite-station wireless communication device.

  The modulation scheme designation information 114a will be described in further detail. The modulation scheme designation information 114a generated in the radio communication device 100 is transmitted to the radio communication device 200, and is handled as the modulation scheme control information 212a in the radio communication device 200. That is, the modulation scheme designated by the modulation scheme designation information 114a is multiplexed as the modulation scheme control information 212a with the transmission radio frame data 210a and transmitted to the modulator 202a. Then, the modulator 202a performs modulation according to the modulation scheme control information 212a multiplexed on the transmission radio frame data 210a.

Next, regarding a time lag between the time when the modulation scheme control information 212a is extracted from the received radio frame data 219a and the time when the modulation scheme control information 212a actually specifies the modulation scheme in the modulator 202a. explain. The modulation scheme control information 212a is multiplexed with each transmission radio frame data 210a. The modulation scheme control information 212a extracted from the reception radio frame data 219a by the reception baseband processing unit 206 is multiplexed with the transmission radio frame data 210a to be transmitted next.
The modulation scheme control information 212a multiplexed with the transmission radio frame data 210a currently being transmitted is extracted from the reception radio frame data 219a immediately before the reception radio frame data 219a. is there. In this way, the modulation scheme control information 212a has a time lag between the extracted time and the time at which the modulation scheme is actually designated. In the present embodiment, by using this time lag, it is detected before the actual change that the modulation method is changed. And QoS control corresponding to the change of a modulation system is implement | achieved.

  In the present embodiment, in a wireless communication system to which a predetermined adaptive modulation scheme is applied, QoS control is performed in accordance with a designated modulation scheme. However, in this embodiment, the specific control method of the adaptive modulation scheme is not limited. For example, the criterion for requesting the transmission modulation scheme from the transmission side to the transmission side is not limited to the method using the reception level as described above. Alternatively, the adaptive modulation scheme may be a scheme in which the transmission side determines a transmission modulation scheme to be applied by the transmission side according to a predetermined criterion defined on the transmission side.

  Since the demodulator 107a and the demodulator 107b have the same configuration, the configuration of the demodulator 107a will be described below. The demodulator 107a performs demodulation processing on the reception IF signal 118a. Then, the demodulator 107a outputs the reception IF signal 118a subjected to the demodulation processing to the reception baseband processing unit 106a as reception radio frame data 119a.

  The reception baseband processing unit 106 extracts the modulation scheme designation information 214a and the modulation scheme designation information 214b of the wireless communication apparatus 200 from the received reception radio frame data 119a and reception radio frame data 119b, respectively. In the transmission baseband processing unit 201 of the wireless communication apparatus 200, the modulation scheme designation information 214a and the modulation scheme designation information 214b are multiplexed with the reception radio frame data 119a and the reception radio frame data 119b. Then, the reception baseband processing unit 106 generates modulation scheme control information 112 a and modulation scheme control information 112 b to be applied as the wireless communication apparatus 100 and outputs the modulation scheme control information 112 b to the transmission baseband processing unit 101. In addition, the reception baseband processing unit 106 outputs, as output data 120, payload data multiplexed with the reception radio frame data 119a and the reception radio frame data 119b.

  Since the antenna unit 108a and the antenna unit 108b have the same configuration, the configuration of the antenna unit 108a will be described below. As described above, the antenna unit 108a transmits the radio signal from the RF unit 103a to the radio communication device 200, receives the radio signal from the radio communication device 200, and outputs the radio signal to the RF unit 103a.

  FIG. 6 is a diagram illustrating a configuration of the transmission baseband processing unit 101 illustrated in FIG. Hereinafter, the configuration of the transmission baseband processing unit 101 will be described with reference to FIG. The transmission baseband processing unit 101 includes a QoS control circuit 301, a distribution circuit 302, a radio frame multiplexing circuit 303a, a radio frame multiplexing circuit 303b, and a modulation scheme comparison circuit 304.

The transmission baseband processing unit 101 performs QoS control and distribution control. Specifically, based on the set upper limit transmission rate and distribution ratio, a transmission baseband signal (transmission radio frame data) 110a and a transmission baseband signal (transmission radio frame data) 110b are output from the input data 109. To do.
The QoS control circuit 301 generates and outputs post-QoS control-processed data 310 from the input data 109 so as to be equal to or lower than the wireless transmission rate. At this time, the QoS control circuit 301 determines the upper limit transmission rate based on the band limitation control signal 314 input from the modulation scheme comparison circuit 304.
The distribution circuit 302 outputs a transmission A frame 311a and a transmission B frame 311b according to the distribution ratio from the input post-QoS control data 310. At this time, the distribution circuit 302 determines the distribution ratio based on the distribution ratio control signal 315 input from the modulation scheme comparison circuit 304.

  Since the radio frame multiplexing circuit 303a and the radio frame multiplexing circuit 303b have the same configuration, the configuration of the radio frame multiplexing circuit 303a will be described below. The radio frame multiplexing circuit 303a selects a modulation scheme based on the input modulation scheme control information 112a. Then, the radio frame multiplexing circuit 303a converts the input transmission A frame 311a, modulation scheme control information 112a, and modulation scheme designation information 114a together with various control signals into a transmission baseband signal (transmission radio frame) in the format shown in FIG.・ Data) Multiplex to 110a. Each frame of the transmission radio frame data 110a includes an overhead part and a payload part. Input data 109 is stored in the payload portion. The overhead part stores modulation scheme control information 112a and modulation scheme designation information 114a.

  Then, the radio frame multiplexing circuit 303a outputs the transmission radio frame data 110a to the modulator 102a. The radio frame multiplexing circuit 303 a outputs a radio frame reference pulse signal 312 a and modulation scheme information 313 a that is an information signal of the currently selected modulation scheme to the modulation scheme comparison circuit 304. The radio frame reference pulse signal 312a is a signal indicating the timing of the boundary between frames.

  The modulation scheme comparison circuit 304 selects an upper limit transmission rate and a distribution ratio based on the input modulation scheme control information 112a, modulation scheme control information 112b, modulation scheme information 313a, and modulation scheme information 313b. The modulation scheme comparison circuit 304 outputs the selected upper limit transmission rate to the QoS control circuit as a band limitation control signal 314. The modulation method comparison circuit 304 outputs the selected distribution ratio to the distribution circuit 302 as a distribution ratio control signal 315. Each time the radio frame reference pulse signal 312a (or radio frame reference pulse signal 312b) is input, the modulation scheme comparison circuit 304 receives the modulation scheme control information 112a (or modulation scheme control information 112b) and the modulation scheme information 313a ( Alternatively, the magnitudes of the multilevel numbers of the modulation schemes specified by the modulation scheme information 313b) are compared.

  The modulation scheme specified by the modulation scheme information 313a (or modulation scheme information 313b) is the modulation scheme currently applied in the modulator 102a (or modulator 102b) (hereinafter referred to as “current modulation scheme”). It is. The modulation scheme specified by the modulation scheme control information 112a (or the modulation scheme control information 112b) is a modulation scheme (hereinafter referred to as “next period”) applied at the modulator 102a (or modulator 102b) at the time of transmission of the next frame. It is called “modulation method”. The next modulation scheme is a modulation scheme designated by the wireless communication apparatus 200 using the modulation scheme designation information 214a (or modulation scheme designation information 214b).

The QoS control based on the total transmission rate of the current modulation scheme and the total transmission rate of the next modulation scheme will be described separately below.
(1) When the total transmission rate of the current modulation scheme> the total transmission rate of the next modulation scheme In this case, it means that the information transmission rate in the wireless section is reduced from the time of transmission of the next frame. Therefore, it is necessary to immediately limit the bandwidth by QoS control. Therefore, the modulation scheme comparison circuit 304 outputs a band limitation control signal 314, and changes the band limitation value used for QoS control in the QoS control circuit 301 from a value corresponding to the current modulation scheme to a value corresponding to the next modulation scheme. . At the same time, the modulation system comparison circuit 304 outputs a distribution ratio control signal 315, and changes the distribution ratio in the distribution circuit 302 from a value corresponding to the current modulation system to a value corresponding to the next modulation system.

  The change of the band limit value used for QoS control is a feature of this embodiment. The purpose will be described in detail below. When the multi-level number B of the next modulation system is smaller than the multi-level number A of the current modulation system, the band of the radio section decreases in the next frame. Therefore, at the latest, when the bandwidth of the radio section decreases, it is necessary to complete the limitation of the bandwidth necessary for information transmission.

  At this time, it is conceivable to change the QoS control band limit value for the QoS control circuit 301 simultaneously with the input of the next radio frame reference pulse signal 312a or the radio frame reference pulse signal 312b. That is, the bandwidth limit value for QoS control is not changed before the modulation scheme is changed, but is changed at the same time as the modulation scheme is changed. In this case, the bandwidth of the wireless section is smaller than the data capacity in the transmission buffer during the QoS control process. In other words, as a result of performing band limitation in accordance with the change of the modulation method, data stored in the transmission buffer corresponding to the band before the change is transmitted at a low transmission speed because the wireless transmission capacity is reduced. become. Accordingly, a transmission waiting time is generated for a low-priority packet, so that the data transfer efficiency is reduced, and a packet loss may occur because the highest-priority packet is not transmitted within a desired time.

  As described above, if the bandwidth limit value used for bandwidth limitation is changed simultaneously with the change of the modulation method, problems such as occurrence of waiting time and packet loss may occur. Therefore, in the present embodiment, when the band of the radio section is reduced as the modulation scheme is changed, the band limit value used for band limitation is changed before the modulation scheme is changed.

(2) When the total transmission rate of the current modulation scheme = the total transmission rate of the next modulation scheme In this case, it means that the band of the radio section does not change. Therefore, communication can be continued with the current band. When bandwidth limitation is performed by QoS control, communication may be continued as it is at the current bandwidth. Therefore, the modulation scheme comparison circuit 304 does not perform any particular control. However, when there is a change in the modulation scheme that does not change the total transmission rate, the modulation scheme comparison circuit 304 controls the distribution ratio when the next radio frame reference pulse signal 312a or the radio frame reference pulse signal 312b is input. The signal 315 is output, and the distribution ratio in the distribution circuit 302 is changed from a value corresponding to the current modulation method to a value corresponding to the next modulation method.

(3) When the total transmission rate of the current modulation scheme <the total transmission rate of the next modulation scheme In this case, it means that the bandwidth of the radio section increases. In this case, it is desirable to change the band limit value according to the next modulation method as soon as possible after the band of the radio section increases. Therefore, the modulation scheme comparison circuit 304 outputs a band limitation control signal 314 when the next radio frame reference pulse signal 312a or radio frame reference pulse signal 312b is input, and the band limitation value of the QoS control circuit 301 is changed to the current modulation. Change the method to a value corresponding to the next modulation method. At the same time, the modulation system comparison circuit 304 outputs a distribution ratio control signal 315 when the next radio frame reference pulse signal 312a or radio frame reference pulse signal 312b is input, and the distribution ratio in the distribution circuit 302 is changed to the current modulation system. The corresponding value is changed to a value corresponding to the next modulation method.

Next, with reference to FIG. 4, the flow of signals until the input data 109 input to the wireless communication apparatus 100 is output as output data 220 from the wireless communication apparatus 200 that is the opposite station will be described.
The input data 109 input to the wireless communication apparatus 100 is distributed in the Route_A and Route_B directions by the transmission baseband processing unit 101 and multiplexed into the payload portion in the format shown in FIG. The multiplexed data is output as transmission radio frame data 110a. The description in the Route_B direction is the same as that in the Route_A direction until it is input to the reception baseband processing unit 206 of the wireless communication apparatus 200, and thus the description thereof is omitted.

  The modulator 102a modulates the transmission radio frame data 110a according to the modulation scheme control information of the overhead part in the transmission radio frame data 110a. The modulated transmission IF signal 111a is frequency-converted by the RF unit 103a and transmitted from the antenna unit 108a to the wireless communication apparatus 200. The transmitted radio signal is received by the antenna unit 208a of the radio communication apparatus 200, and output from the RF unit 203a to the demodulator 207a as a reception IF signal 218a. The demodulator 207a demodulates the received IF signal 218a and outputs it as received radio frame data 219a. The reception baseband processing unit 206 extracts data from the payload portion in the radio frame format of the reception radio frame data 219a and the reception radio frame data 219b, and outputs output data 220.

  Next, transmission radio frame data 210a (modulation method designation information 214a) is transmitted from the transmission baseband processing unit 201 in the wireless communication device 200 to the wireless communication device 100 through the modulator 202a, the RF unit 203a, and the antenna unit 208a. In addition, the data is transmitted to the reception baseband processing unit 106 through the antenna unit 108a, the RF unit 103a, and the demodulator 107a of the wireless communication apparatus 100, and the modulation scheme in the reception baseband processing unit 106 based on this modulation scheme designation information The selection control will be described.

  The RF unit 203a outputs the radio channel quality state received by the antenna unit 208a of the radio communication apparatus 200 to the reception modulation method determination unit 205a as reception level information 217a. The reception modulation method determination unit 205a selects an appropriate modulation method and outputs the modulation method designation information 214a to the transmission baseband processing unit 201. At this time, the appropriate modulation scheme indicates a modulation scheme that provides the maximum transmission capacity while maintaining the quality of the wireless communication section. The transmission baseband processing unit 201 multiplexes the input modulation scheme designation information 214a as determination modulation scheme information (see FIG. 5) into a radio frame, and outputs transmission radio frame data 210a to the modulator 202a. The modulation base designation information 214a, which is multiplexed determination modulation system information, is extracted from the reception radio frame data 119a by the reception baseband processing unit 106 in the radio communication apparatus 100.

  The reception baseband processing unit 106 outputs the extracted modulation scheme designation information 214a as modulation scheme control information 112a to the transmission baseband processing unit. The transmission baseband processing unit multiplexes the input modulation scheme control information 112a as adaptive modulation pre-control information (see FIG. 5) into a radio frame, and outputs transmission radio frame data 110a to the modulator 102a. At this time, the transmission baseband processing unit 101 selects the modulation scheme of the adaptive modulation control information multiplexed on the radio frame transmitted immediately before, and outputs the transmission radio frame data 110a. That is, the modulation scheme is always selected according to the adaptive modulation control information one time before. Similarly, the modulator 102a selects a modulation method according to the previous adaptive modulation performance.

  The modulator 102a modulates the input transmission radio frame data 110a using the selected modulation method, and outputs it to the RF unit 103a as a transmission IF signal 111a. The RF unit 103a converts the input transmission IF signal 111a into an RF frequency and irradiates the radio communication apparatus 200 of the opposite station from the antenna unit 108a. The RF signal received by the antenna unit 208a in the wireless communication apparatus 200 is returned to the IF frequency by the RF unit 203a, and is output to the demodulator 207a as a reception IF signal 218a. The demodulator 207a demodulates the reception IF signal 218a and outputs it to the reception baseband processing unit 206 as reception radio frame data 219a.

[Third Embodiment]
Next, a third embodiment improved from the second embodiment will be described. FIG. 7 is a block diagram illustrating a configuration of a reception baseband unit in the wireless communication system according to the third embodiment.
Only differences from the second embodiment will be described below. The distribution circuit 302 (see FIG. 6) in the transmission baseband processing unit 101 outputs the transmission A frame 311a and the transmission B frame 311b according to the distribution ratio from the input post-QoS control data 310. At this time, the distribution circuit 302 gives a sequence number for each IP frame to the input post-QoS control data 310. At this time, the distribution circuit 302 determines the distribution ratio based on the input distribution ratio control signal 315.

The reception baseband processing unit 106 illustrated in FIG. 7 includes a radio frame extraction circuit 401a, a radio frame extraction circuit 401b, and an aggregation control circuit 402.
The reception baseband processing unit 106 performs radio frame extraction and IP frame aggregation control. Specifically, the IP frames are rearranged based on the extracted sequence numbers, and the input received baseband signal (received radio frame data) 119a and the input received baseband signal (received radio frame Data) means that output data 120 is output from 119b.

  Since the radio frame extraction circuit 401a and the radio frame extraction circuit 401b have the same configuration, the configuration of the radio frame extraction circuit 401a will be described below. The radio frame extraction circuit 401a extracts the modulation scheme control information 112a from the input reception radio frame data (reception baseband signal) 119a and outputs it. The radio frame extraction circuit 401 a extracts the sequence number 404 a from the input reception radio frame data 119 a and outputs it to the aggregation control circuit 402. When the radio frame extraction circuit 401 a receives the reception permission signal 405 a from the aggregation control circuit 402, the radio frame extraction circuit 401 a extracts the reception A frame 403 a from the input reception radio frame data 119 a and outputs it to the aggregation control circuit 402.

  The aggregation control circuit 402 compares the input sequence number 404a and the sequence number 404b, and outputs either the reception permission signal 405a or the reception permission signal 405b. The aggregation control circuit 402 outputs the output data 120 from the input reception A frame 403a or reception B frame 403b. By comparing and selecting the sequence numbers, the reception baseband processing unit 106 can output the output data 120 without changing the order of the input data 209 input to the wireless communication apparatus 200 for the IP frame. .

  As described above, when IP frames are not output in the order of input, there is a possibility that a line quality problem may occur for moving image / audio data. Therefore, in the present embodiment, the output is performed from the radio communication apparatus of the opposite station without changing the order of the input IP frames.

  As described above, in the wireless communication apparatus of the present invention, the packet data transmission speed is suppressed to be equal to or lower than the wireless transmission speed, so that variations in packet data delay time due to data processing time such as flow control do not occur. In addition, it is possible to perform band control that effectively uses the wireless transmission speed while immediately responding to changes in the modulation scheme in response to changes in the state of the wireless transmission path. Further, it is possible to efficiently perform bandwidth control using a plurality of wireless communication sections.

  Although the embodiments of the present invention have been described above, the wireless communication apparatus and the wireless communication system of the present invention are not limited to the illustrated examples described above, and various modifications can be made without departing from the scope of the present invention. Of course, can be added.

11a, 11b ... receiving unit, 12a, 12b ... information extracting unit, 13a, 13b ... transmitting unit, 14 ... service quality control unit, 41 ... QoS control unit, 42 ... distribution Control unit, 100 ... wireless communication device, 101 ... transmission baseband processing unit, 102a, 102b ... modulator, 103a, 103b ... RF unit, 105a, 105b ... reception modulation method determination unit 106, reception baseband processing unit, 107a, 107b, demodulator, 108a, 108b, antenna unit, 200, wireless communication device, 201, transmission baseband processing unit, 202a, 202b ... Modulator, 203a, 203b ... RF unit, 205a, 205b ... Reception modulation method determination unit, 206 ... Reception baseband processing unit, 207a, 207b ..Demodulators, 208a, 208b ... antenna unit, 301 ... QoS control circuit, 302 ... sorting circuit, 303a, 303b ... radio frame multiplexing circuit, 304 ... modulation method comparison circuit, 401a , 401b... Radio frame extraction circuit, 402... Aggregation control circuit

Claims (10)

  When packet data is transmitted using a plurality of radio transmission paths and an adaptive modulation scheme with a variable modulation scheme, the transmission status of each radio transmission path is monitored, and an upper limit is set according to the transmission status of each radio transmission path. A radio communication apparatus characterized by setting an upper limit transmission rate, and changing a modulation scheme, a transmission rate, and a transmission data distribution ratio in each of the radio transmission paths according to the upper limit transmission rate. Monitoring the plurality of wireless transmission lines, and when the transmission rate of the plurality of wireless transmission lines decreases as a whole, lower the upper limit transmission rate before changing the current modulation scheme,
2. The wireless communication apparatus according to claim 1, wherein when the transmission rate of the plurality of wireless transmission paths increases as a whole, the upper limit transmission rate is increased at the same time as changing the current modulation scheme. A receiving unit that generates and outputs received data from an input signal input from each wireless transmission path; and
An information extraction unit that inputs reception data output from the reception unit and generates transmission control information that sets a transmission rate and a modulation scheme for each wireless transmission path based on the reception data;
A service that determines the upper limit transmission rate, the transmission rate for each radio transmission path, the modulation method, and the distribution ratio based on the transmission control information, and generates and outputs a transmission frame from the transmission data to each radio transmission path A quality control unit;
A transmission unit that inputs the transmission frame from the service quality control unit, and that outputs a transmission signal according to a transmission rate and a modulation scheme set for each wireless transmission path based on the transmission control information;
With
The transmission unit outputs a current transmission signal at a transmission rate set based on transmission control information input from the information extraction unit, and changes the transmission rate when transmission of the current transmission signal is completed. Operates,
Transmission control information output from the information extraction unit during transmission of the current transmission signal is:
The wireless transmission according to claim 1 or 2, wherein the second transmission rate is a transmission rate at the time of transmitting the next transmission signal, not the first transmission rate that is the current transmission rate. Communication device. The service quality control unit
A QoS control unit for controlling a transmission rate and a modulation method;
A distribution control unit that distributes transmission data to each wireless transmission path;
Consists of
The QoS control unit
Detecting the first transmission rate and the second transmission rate in each wireless transmission path;
When it is detected that the second transmission rate is smaller than the first transmission rate in the wireless transmission path, the next transmission rate is changed by immediately reducing the upper limit transmission rate,
When it is detected that the second transmission rate is higher than the first transmission rate in the wireless transmission path, an upper limit is set at the timing at which the transmission rate of the transmission signal is changed in the transmission unit corresponding to the wireless transmission path. Increase the transmission rate to change to the next transmission rate,
The distribution control unit
The wireless communication apparatus according to claim 3, wherein the distribution ratio is changed at a timing at which a transmission rate is changed in the transmission unit. Based on the input data, modulation method control information for setting the transmission rate and modulation method, and the upper limit transmission rate, the modulation method selection, transmission rate control, and distribution control for each wireless transmission path are performed. A transmission baseband for generating transmission radio frame data in which the input data, the modulation scheme control information, and modulation scheme designation information for designating a modulation scheme for another radio communication apparatus serving as a communication partner are stored; A processing unit;
For each radio transmission path, transmission radio frame data is input from the transmission baseband processing unit, and modulation is performed according to modulation scheme control information stored in the transmission radio frame data, and the modulated signal is also transmitted. A modulator that outputs a transmission IF signal as an intermediate frequency signal;
For each wireless transmission path, the transmission IF signal is input from the modulator, frequency-converted to a predetermined wireless frequency, transmitted to the other wireless communication device as a communication partner, and the other wireless communication device An RF unit that receives a radio signal from the receiver, outputs a signal of a received level of the received radio signal, and a reception IF signal obtained by frequency-converting the radio signal;
Reception modulation scheme determination for receiving a reception level signal from the RF unit for each wireless transmission path, generating the modulation scheme designation information based on the reception level information, and outputting the modulation scheme designation information to the transmission baseband processing unit And
For each wireless transmission path, a demodulator that performs demodulation processing of the received IF signal and outputs received radio frame data that has been demodulated,
Based on the reception radio frame data of each radio transmission path input from the demodulator, the modulation scheme control information is generated and output to the transmission baseband processing unit, and the transmission data is transmitted from the reception radio frame data. Receiving baseband processing unit that extracts and outputs as output data;
The wireless communication apparatus according to claim 1, further comprising: The transmission baseband processing unit
A QoS control circuit that performs QoS control on input data and generates and outputs data after QoS control processing;
A modulation scheme comparison circuit that outputs a band limitation control signal that specifies an upper limit transmission rate of a transmission rate to the QoS control circuit, and that outputs a signal of a distribution ratio for each of the wireless transmission paths;
Data after QoS control processing is input from the QoS control circuit, a distribution ratio signal is input from the modulation method comparison circuit, and a transmission frame for each wireless transmission path is generated from the data after QoS control processing according to the distribution ratio. A distribution circuit;
For each radio transmission path, a radio frame multiplexing circuit that multiplexes the transmission frame output from the distribution circuit, the transmission control information, and the modulation scheme designation information to generate transmission radio frame data;
With
The QoS control circuit generates post-QoS control processing data from input data so that a wireless transmission rate is equal to or lower than the upper limit transmission rate based on the band limitation control signal,
The radio frame multiplexing circuit outputs modulation scheme information, which is an information signal of the currently selected modulation scheme, to the modulation scheme comparison circuit for each radio transmission path,
The modulation scheme comparison circuit selects an upper limit transmission rate and a distribution ratio based on the modulation scheme control information and the modulation scheme information of each wireless transmission path, and uses the selected upper limit transmission rate as a band limitation control signal as the QoS limit control signal. The wireless communication apparatus according to claim 5, wherein the wireless communication apparatus outputs to the control circuit, and outputs the selected distribution ratio to the distribution circuit as a distribution ratio control signal. The reception baseband processing unit
A radio frame extraction circuit that extracts a received frame signal from received radio frame data for each radio transmission line; and
An aggregation control circuit for aggregating received frames output from the radio frame extraction circuit;
With
The radio frame extraction circuit includes:
Generate modulation scheme control information from input received radio frame data and output to the transmission baseband processing unit,
Extracting the sequence number information from the input received radio frame data and outputting it to the aggregation control circuit,
The aggregation control circuit includes:
The radio communication apparatus according to claim 5, wherein output data is generated and output based on the received frame and the sequence number input from the radio frame extraction circuit. Each frame of the transmission radio frame data is composed of an overhead part and a payload part,
Input data is stored in the payload part,
The wireless communication apparatus according to claim 5, wherein the modulation scheme control information and the modulation scheme designation information are stored in the overhead section. A wireless communication system in which wireless communication is performed using the wireless communication device according to any one of claims 5 to 7,
Corresponding to each of the plurality of wireless transmission paths, modulation method selection, transmission rate control, and distribution control are performed,
A radio communication system, wherein a transmission modulation scheme to be applied is designated by the modulation scheme designation information from a reception-side radio communication device to an opposite-station radio communication device.   When packet data is transmitted using a plurality of wireless transmission paths and a predetermined adaptive modulation method, the transmission status of each wireless transmission path is monitored, and an upper limit transmission rate that is an upper limit according to the transmission status of each wireless transmission path And a modulation method, a transmission rate, and a transmission data distribution ratio in each wireless transmission path are changed according to the upper limit transmission rate.

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