DE112016003940T5 - Communication control device, communication control method and program - Google Patents

Abstract

[Problem] Ensure reliability in a preferred mode and reduce the consumption of communication resources depending on the status of the communication.
[Solution] This communication control apparatus is provided with: a control unit that controls communication with communication devices connected via wireless communication paths; and a detection unit that acquires information related to communication with one or more of the communication devices, the control unit based on the number of communication devices to which a transmission request for a response for confirming a delivery of data with respect to the communication devices is to be sent determined on the information collected in relation to the communication.

Description

Technical area

The present disclosure relates to a communication control device, a communication control method, and a program.

State of the art

Wireless local area networks (LANs) represented by Institute of Electrical and Electronics Engineers (IEEE) 802.11 have become widespread in recent years, and wireless communication devices compatible with wireless LANs are increasing accordingly. In addition, as an example of techniques relating to communication between such wireless communication devices, a technique known as multicast in which the same data is simultaneously transmitted to a plurality of wireless communication devices is also considered.

Further, in the IEEE 802.11 series of standards, the technology for a case where a wireless communication device serving as a transmission source transmits data in communication between wireless communication devices is developed for checking whether the transmitted data is transmitted to a wireless communication device serving as a wireless communication device Transmission target serves, were delivered. The use of such a technology by the wireless communication device serving as the transmission source makes it possible to transmit the data in an example to the wireless communication device serving as a transmission destination for which the delivery of data could not be confirmed, thereby providing a Deterioration of communication quality is prevented. In one example, Patent Literature 1 discloses an example of a technique that allows a wireless communication device serving as the data transmission source to check whether data has been supplied to a wireless communication device serving as the transmission destination.

References list

patent literature

Patent Literature 1: JP 2014-053832A

Disclosure of the invention

Technical problem

In this regard, in transmitting data to a plurality of wireless communication devices, such as multicast, a case of checking a delivery of the data to a wireless communication device serving as the transmission destination is considered. In this case, the reliability of communication tends to be improved as the number of wireless communication terminals that check the delivery of data increases.

Meanwhile, in a case of checking the delivery of data to a plurality of wireless communication devices, a plurality of communication tasks take place simultaneously to check the delivery, which consumes communication resources. Accordingly, when the number of wireless communication terminals that check the supply of data increases, the communication between the wireless communication devices under a load caused by the delivery check may suffer depending on the communication status between the wireless communication devices, resulting in some cases Deterioration of communication quality leads.

In view of this, the present disclosure provides a communication control apparatus, a communication control method, and a program capable of improving the reliability and reducing the consumption of communication resources in a more preferred mode depending on the communication status.

the solution of the problem

According to the present disclosure, there is provided a communication control device including: a control unit configured to control communication with a communication device connected via a wireless communication path; and a detection unit configured to acquire information regarding the communication with one or more of the communication devices. The control unit determines a number of the communication devices to which a transmission request for a Response for confirming a delivery of data is transmitted to the communication device based on the acquired information regarding the communication.

In addition, according to the present disclosure, there is provided a communication control device including: a detection unit configured to have a communication device connected via a wireless communication path as a transmission destination of a transmission request for a response for confirming a delivery of data based on detected Information regarding a communication is determined to detect the transmission request transmitted from the communication device; and a control unit configured to control the response corresponding to a receiving situation of the data to the detected transmission request to be transmitted to the communication apparatus.

In addition, according to the present disclosure, there is provided a communication control method to be executed by a processor and including: controlling communication with a communication device connected via a wireless communication path; Acquiring information regarding the communication with one or more of the communication devices; and determining a number of the communication devices to which a transmission request for a response for confirming a delivery of data is transmitted to the communication device based on the acquired information regarding the communication.

In addition, according to the present disclosure, there is provided a communication control method including: detecting the transmission request transmitted from the communication device if a communication device connected via a wireless communication path as a transmission destination of a transmission request for a response for confirming a delivery of data determined based on detected information regarding a communication; and controlling, by a processor, the response corresponding to a reception situation of the data to the detected transmission request to be transmitted to the communication apparatus.

In addition, according to the present disclosure, a program is provided that causes a computer to perform: controlling communication with a communication device connected via a wireless communication path; Acquiring information regarding the communication with one or more of the communication devices; and determining a number of the communication devices to which a transmission request for a response for confirming a delivery of data is transmitted to the communication device based on the acquired information regarding the communication.

Advantageous Effects of the Invention

According to the present disclosure, as described above, a communication control apparatus, a communication control method, and a program capable of improving the reliability and reducing the consumption of communication resources in a more preferred mode depending on the communication status are provided.

It is noted that the effects described above are not necessarily limiting. With or instead of the above effects, any of the effects described in this specification or other effects that can be obtained from this description can be achieved.

list of figures

• [ 1 ] 1 FIG. 10 is a diagram illustrating a communication system including a communication control device and a communication device according to an embodiment of the present disclosure.
• [ 2 ] 2 Fig. 15 is a diagram illustrated to describe an example of a processing procedure in a case where a master node multicasts data to a plurality of slave devices and checks a delivery of the data.
• [ 3 ] 3 Fig. 10 is a graph illustrating an example of a relationship between the number of slave devices serving as a BAR destination and a packet loss rate.
• [ 4 ] 4 FIG. 10 is a block diagram illustrating a schematic functional configuration of a communication device according to a first embodiment of the present disclosure. FIG.
• [ 5 ] 5 Fig. 10 is a diagram illustrating an example of the structure of a DL frame used to transmit a BAR by setting a plurality of slave devices as destinations.
• [ 6 ] 6 FIG. 15 is a diagram illustrating for describing an example of a processing sequence of the communication system according to the present embodiment. FIG.
• [ 7 ] 7 FIG. 15 is a diagram illustrating for describing an example of a processing sequence of the communication system according to the present embodiment. FIG.
• [ 8th ] 8th FIG. 10 is a flowchart illustrating an example of steps in the operation procedure of a communication device that operates as a master node in the communication system according to the present disclosure.
• [ 9 ] 9 FIG. 10 is a flowchart illustrating an example of steps in the operation procedure of a communication device that operates as a slave device in the communication system according to the present embodiment.
• [ 10 ] 10 FIG. 10 is a flowchart illustrating an example of steps in the operation procedure of a communication device that operates as a master node in the communication system according to a modification of the present embodiment.
• [ 11 ] 11 FIG. 10 is a flowchart illustrating an example of steps in the operation procedure of a communication device that operates as a slave device in the communication system according to the present embodiment.
• [ 12 ] 12 FIG. 15 is a diagram illustrating for describing an example of a processing sequence of the communication system according to a second embodiment of the present disclosure. FIG.
• [ 13 ] 13 FIG. 10 is a diagram illustrating for describing an example of a processing sequence of a communication system according to a third embodiment of the present disclosure. FIG.
• [ 14 ] 14 FIG. 15 is a diagram illustrating for describing an example of a processing sequence of a communication system according to a fourth embodiment of the present disclosure. FIG.
• [ 15 ] 15 FIG. 10 is a flowchart illustrating an example of a series of processing procedures of a communication device 10 that is a master node in a communication system according to a fifth embodiment of the present disclosure.
• [ 16 ] 16 FIG. 10 is a flowchart illustrating an example of a series of processing procedures of a communication device that is a master node in the communication system according to the present embodiment.
• [ 17 ] 17 FIG. 10 is a block diagram illustrating an exemplary schematic configuration of a smartphone. FIG.
• [ 18 ] 18 FIG. 10 is a block diagram illustrating an exemplary schematic configuration of an automobile navigation device. FIG.
• [ 19 ] 19 FIG. 10 is a block diagram illustrating an example schematic configuration of a wireless access point. FIG.

Embodiment (s) of the invention

Hereinafter, a preferred embodiment (s) of the present disclosure will be described in detail with reference to the attached drawings. In this specification and the appended drawings, structural elements having substantially the same function and structure are denoted by the same reference numerals, and repetitive explanation of these structural elements will be omitted.

1. 1. Übersicht über das Kommunikationssystem gemäß einer Ausführungsform der vorliegenden Offenbarung
2. 2. Überlegungen hinsichtlich einer Lieferungsüberprüfung bei Multicast
3. 3. Erste Ausführungsform: Beispiel für das Suchen nach der Anzahl an BAR-Zielen basierend auf Addition
   • 3-1. Konfiguration der Vorrichtung
   • 3-2. Verarbeitung der Vorrichtung
   • 3-3. Modifikation
   • 3-4. Kurzdarstellung
4. 4. Zweite Ausführungsform: Beispiel für das Suchen nach der Anzahl an BAR-Zielen basierend auf Subtraktion
5. 5. Dritte Ausführungsform: Beispiel für eine anwendbare Suche nach der Anzahl an BAR-Zielen zur Änderung der Kommunikationsumgebung
6. 6. Vierte Ausführungsform: Beispiel für das Suchen nach der Anzahl an BAR-Zielen zur weiteren Verbesserung der Kommunikationsqualität
7. 7. Fünfte Ausführungsform: Beispiel für die Möglichkeit, die Anzahl an BAR-Zielen zu aktualisieren
8. 8. Anwendungsbeispiele
   • 8-1. Erstes Anwendungsbeispiel
   • 8-2. Zweites Anwendungsbeispiel
   • 8-3. Drittes Anwendungsbeispiel
9. 9. Fazit

In addition, the description will be given in the following order.

1. 1. Overview of the communication system according to an embodiment of the present disclosure
2. 2. Considerations regarding a multicast delivery check
3. 3. First Embodiment: Example of searching for the number of BAR targets based on addition
   • 3-1. Configuration of the device
   • 3-2. Processing of the device
   • 3-3. modification
   • 3-4. Summary
4. Second Embodiment: Example of Searching the Number of BAR Targets Based on Subtraction
5. 5. Third Embodiment Example of an applicable search for the number of BAR destinations for changing the communication environment
6. 6. Fourth Embodiment: Example of searching for the number of BAR destinations to further improve the communication quality
7. 7. Fifth Embodiment: Example of the ability to update the number of BAR targets
8. 8. Application examples
   • 8-1. First application example
   • 8-2. Second example of use
   • 8-3. Third application example
9. 9. Conclusion

<Overview of the communication system according to an embodiment of the present disclosure>

An overview of a communication control device and a communication device according to an embodiment of the present disclosure will now be described with reference to FIG 1 described. 1 FIG. 10 is a diagram illustrating a communication system including the communication control device and the communication device according to an embodiment of the present disclosure. FIG. In addition, the communication control device and the communication device are also referred to collectively as the communication device.

The communication system includes a plurality of communication devices 10 , The communication device 10 has a wireless communication function and communicates using multiplexing. In addition, the communication device works 10 as a so-called access point (hereinafter referred to as "AP" (access point)) or operates as a terminal (hereinafter referred to as "STA" (station)). A communication device that operates as an AP is also referred to as a master node, and a communication device that operates as a terminal is hereinafter also referred to as a slave device. For this reason, a point-to-point communication can be achieved by using multiplexes between the master node and the slave devices in the communication system. In addition, communication from the master node to the slave device is also referred to as downlink (DL) communication, and communication from the slave device to the master node is referred to as uplink (UL) communication ,

In one example, the communication system includes a plurality of communication devices 10 # 0 through 10 # N, as in FIG 1 is illustrated. The communication device 10 # 0 serving as a master node and the communication devices 10 # 1 to 10 # N serving as slave devices are connected to each other by wireless communication and transmit and receive frames directly to and from each other.

Further, the communication device 10 # 0, which is the master node, is capable of simultaneously supplying the same data to the plurality of slave devices (eg, the communication devices 10 # 1 to 10 # N) based on the technique, the multicast is called to transfer.

Further, the communication device 10 # 0 which is the master node and the communication devices 10 # 1 to 10 # N which are the slave devices are all the IEEE 802.11 compliant communication devices, and in one example, the master Node, which is the transmission source, is able to check the delivery of the transmitted data to the slave device. Specifically, the master node checks whether Ack or Block Ack (BA) indicating a delivery confirmation has been retransmitted by the slave device that is the data transfer destination to verify that the data is correctly sent to the slave device the data transmission destination is delivered. The use of such a mechanism allows the master node to prevent deterioration in communication quality (ie, improve communication reliability) by, in one example, resubmitting the intended data to the slave device for which the delivery of at least some of the data could not be confirmed.

The overview of the communication control device and the communication device according to an embodiment of the present disclosure is described above with reference to FIG 1 described.

<Considerations regarding delivery check in multicast>

An example of a process related to a check of the delivery of data in the case (ie, in the case of multicast) in which the communication device 10 # 0 which is the master node, the same data to the plurality Slave devices (e.g., the communication devices 10 # 1 to 10 # N) will now be described. Then, problems of the communication system according to the present embodiment will be described.

An example is 2 a diagram that is illustrated to describe an example of the processing procedure in the case where the master node multicasts data to the multiple slave devices and checks the delivery of the data. In addition, the horizontal axis represents in 2 a time. In addition, in the following description, data subjected to multicasting will sometimes be referred to as "multicast data".

In a specific example, after transmission of the multicast data, the communication device 10 # 0, which is the master node, transmits an acknowledgment request (hereinafter referred to as "BAR" (Block Ack Request)) to the slave device (eg, at least one any of the communication devices 10 # 1 to 10 #). Then, the communication device 10 # 0 receives an acknowledgment (hereinafter referred to as "BA" (Block Ack)) from the slave device serving as a destination to which the acknowledgment request has been transmitted, thus confirming that the multicast data to the slave Device were delivered. Additionally, in the description of the present disclosure, the BAR may be a block-ack request based on the IEEE 802.11 standard, or may be another frame used to report a confirmation request. Additionally, in the description of the present disclosure, the BA may be a "Block Ack" or "Ack" based on the IEEE 802.11 standard or may be another frame used to report an acknowledgment.

Illustrated by an example 2 an example of the operation in the case where the communication device 10 # 0, which is the master node, multicasts data to the communication devices 10 # 1 to 10 # 4, which are the slave devices, and checks the delivery of the data ,

At the in 2 first, the communication device 10 # 0 transmits the multicast data to the communication devices 10 # 1 to 10 # 4, and then transmits the BAR to the communication devices 10 # 2 to 10 # 4. In addition, in this event, it is assumed that the communication device 10 # 2 successfully receives the multicast data and the communication device 10 # 4 fails to receive at least some of the multicast data.

In this case, the communication device 10 # 2 notifies the communication device 10 # 0 of the delivery of the multicast data by retransmitting the BA as a response to the BAR from the communication device 10 # 0. This allows the communication device 10 # 0 to confirm that the multicast data has been correctly delivered to the communication device 10 # 2. On the other hand, the communication device 10 # 4 does not receive the multicast data correctly. Accordingly, the communication device 10 # 4 does not return the BA as a response to the BAR from the communication device 10 # 0 or returns the BA indicating failure of reception of at least some of the multicast data. This enables the communication device 10 # 0 to recognize that the communication device 10 # 4 failed in receiving at least some of the multicast data.

Next, the communication device 10 recognizes # 0 at the in 2 illustrated example that the communication device 10 # 4 failed to receive at least some of the multicast data, and thus the communication device 10 # 0 retransmits the multicast data to the communication devices 10 # 1 to 10 # 4. Such operation enables the reliability of communication associated with the transmission of the multicast data at the time of the ingress 2 illustrated example, to improve (ie to improve the communication quality). In addition, in this event, the series of processing associated with a transmission of the BAR, a response of the BA to the BAR, and retransmission of the multicast data will cause an overhead in transmitting the multicast data.

As in 2 For example, in the case where the master node multicasts data to the multiple slave devices simultaneously and checks the delivery of the data, multiple communication tasks take place to verify the delivery. Accordingly, the overhead described above tends to increase as the number of slave devices for which the master node verifies the delivery of multicast data increases. In particular, in a communication environment, in the transmission and reception of data between a plurality of communication devices 10 The overhead that occurs to improve reliability is consumed as in 2 illustrates communication resources, which consequently also causes a deterioration of the communication quality. In addition, in a situation of checking the supply of data to a slave device, particularly one whose data receiving situation among the slave devices to which the multicast data is to be transmitted is unfavorable, the number of times of retransmission of the data increases. which in some cases causes deterioration of communication characteristics of the entire system. In addition, if the latency necessary for traffic handled by the system is set to be short, a situation may be considered where the desired latency is exceeded as the number of times of delivery check or retransmission increases.

An example of the relationship between the number of slave devices serving as the destination of the confirmation request (BAR) of data (hereinafter also referred to as "the number of BAR destinations") and the system properties will now be described with reference to FIG 3 described.

An example is 3 4 is a graph illustrating an example of the relationship between the number of slave devices serving as BAR targets and a packet loss rate indicating characteristics of the entire system. In 3 For example, the horizontal axis represents the number of slave devices serving as the BAR targets, and the vertical axis represents the packet loss rate indicating characteristics of the entire system. As in 3 For example, in the area where the number of BAR destinations is relatively small (for example, an area where the number of BAR destinations is n ₁ or less), the communication reliability improves when the number of BAR Goals increases. Accordingly, the packet loss rate of the entire system decreases and the communication quality tends to improve. On the other hand, if the number of BAR targets exceeds a certain value (eg, if the number of BAR targets exceeds n ₁ ), it is found that the overall system packet loss rate increases as the number of BAR targets increases, and the quality of communication tends to worsen. This is due to an increase in communication tasks for confirmation or an increase in the number of times of retransmission of data, resulting in the communication in the entire system suffering from a burden.

In other words, as in 3 illustrates that in a situation where the master node multicasts data to multiple slave devices and verifies the delivery of the data, the number of BAR destinations is set to a more appropriate value. This should make it possible to reduce the consumption of communication resources while increasing the reliability and thus improving the communication quality of the entire system.

Meanwhile, setting the number of BAR destinations that can improve the communication quality of the entire system is not limited to a fixed value, but may vary in one example depending on the communication status. In a specific example, in a situation where the usage rate of communication resources is for transferring data between the communication devices 10 is high (ie, a busy situation), the communication quality of the entire system is improved in the situation with a lower number of BAR targets as compared to a situation in which the usage rate of communication resources is low (ie, an unoccupied situation).

In view of the above, the present disclosure provides a mechanism that is capable of improving reliability and reducing the consumption of communication resources in a more preferred mode by increasing the number of slave devices that are to be BAR targets ( that is, the number of BAR destinations), depending on the communication status. The communication device 10 according to one embodiment of the present disclosure will now be described in detail.

<First Embodiment: Example of Searching for the Number of BAR Targets Based on Addition>

A communication device 10 According to a first embodiment of the present disclosure will now be described. In addition, the communication device 10 according to the present embodiment, in some cases hereinafter referred to as a "communication device 10-1", wherein by distinguishing it from a communication device 10 will be described according to another embodiment.

<Configuration of the device>

First, an example of a configuration of the communication device will be described 10 1 according to the first embodiment of the present disclosure with reference to FIG 4 described. 4 FIG. 12 is a block diagram illustrating a schematic functional configuration of the communication device. FIG 10 1 according to the first embodiment of the present disclosure.

As in 4 1, the communication device 10-1 includes a data processing unit 11, a communication unit 12 and a control unit 18 , First, basic functions of the communication apparatus 10-1 will be described.

((Basic functions))

The data processing unit 11 performs processing for transmitting and receiving data. Specifically, the data processing unit 11 generates a frame based on data from the upper communication layer and provides the generated frame for a signal processing unit 14 , which will be described later, ready. For example, the data processing unit 11 generates a frame (or packets) from the data and performs processing such as adding a header or an error detection code to the generated frame. In addition, the data processing unit 11 extracts data from a received frame and provides the extracted data for the upper communication layer. For example, the data processing unit 11 acquires data by it performs header analysis, code error detection and correction, resorting processing, and the like on the received frame.

As in 5 1, the communication device 12 includes a modulation and demodulation unit 13 , a signal processing unit 14, a channel estimation unit 15 , a wireless interface unit 16 and an amplification unit 17 , In addition, although not illustrated, the communication device 10 -1 is provided with a power supply such as a fixed power source or a battery.

The modulation-and-demodulation unit 13 performs modulation processing or the like on the frame. Specifically, the modulation-and-demodulation unit generates 13 a character stream by performing coding, interleaving and modulation on the frame provided by the data processing unit 11 in accordance with the coding and modulation schemes provided by the control unit 18 be determined. Then put the modulation-and-demodulation unit 13 the generated character stream for the signal processing unit 14 ready. It also detects the modulation and demodulation unit 13 a character stream generated by spatially processing from the signal processing unit 14 is obtained, demodulates and decodes the character stream to obtain a frame, and sets the detected frame for the data processing unit 11 or the control unit 18 ready.

Furthermore, the signal processing unit leads 14 processing related to space division multiplex communication. Specifically, the signal processing unit performs 14 a signal processing associated with a spatial division on the symbol stream produced by the modulation-and-demodulation unit 13 is generated and provides each character stream obtained by the processing for the respective wireless interface units 16 ready. In addition, the signal processing unit performs 14 Spatial processing, for example, character stream division processing or the like, on the character stream associated with a signal from the wireless interface units 16 is obtained, and provides the character stream obtained by the processing to the modulation-and-demodulation unit 13.

The channel estimation unit 15 estimates a channel gain. Specifically, the channel estimation unit calculates 15 complex channel gain information from a preamble portion or a training reference signal portion of a signal associated with the character stream obtained from the wireless interface unit 16. In addition, the calculated complex channel gain information for the signal processing unit 14 through the control unit 18 and used for demodulation processing, space division processing or the like.

The wireless interface unit 16 generates a signal to be transmitted and received via an antenna. Specifically, the wireless interface unit transforms 16 the signal associated with the symbol stream received by the signal processing unit 14 is converted to an analog signal and performs filtering and frequency up-conversion on it. Then put the wireless interface unit 16 the signal obtained for the amplification unit 17 ready. In addition, the wireless interface unit performs 16 processing reverse to the case of signal transmission, for example, frequency down conversion, digital signal conversion or the like, to the signal transmitted from the amplifying unit 17 is obtained, and provides a signal obtained by the processing for the channel estimation unit 15 and the signal processing unit 14 ready. In addition, it is not necessary to have multiple wireless interface units 16 take.

The reinforcement unit 17 amplifies the signal. Specially reinforces the amplification unit 17 the analog signal provided by the wireless interface unit 16 is at a predetermined power level and causes a signal obtained by the gain to be transmitted via an antenna. In addition, the amplification unit amplifies 17 a signal related to a radio wave received via an antenna is at a predetermined power level and provides a signal obtained by the amplification to the wireless interface unit 16 ready. For example, the amplification unit 17 a power amplifier module or the like. In addition, the wireless interface unit 16 with a function for amplifying radio waves for transmission and / or a function for amplifying radio waves for receiving the amplification unit 17 be equipped.

Further, the modulation and demodulation unit 13 , the signal processing unit 14 , the channel estimation unit 15 , the wireless interface unit 16 and the amplification unit 17 hereinafter also referred to collectively as "communication unit 12".

The control unit 18 controls the overall operation of the communication device 10 -1. Specifically, the control unit performs 18 a processing, such as a transfer of information between respective functions, setting of communication parameters, transmission power control and scheduling of frames (or packets) in the data processing unit 11.

((Function in case of operating as master node))

Next, functions in a case where the communication device 10 -1 as the master node works, described in detail.

(Multicast function)

The control unit 18 controls the operation of the data processing unit 11 and the communication unit 12 so that the same data to be transmitted is transmitted to the plurality of slave devices specified as destinations.

In a specific example, the control unit groups 18 multiple slave devices specified as destinations by multicast addresses (eg, a multicast IP address) and outputs the address to the data processing unit 11. The data processing unit 11 appends control information (eg, multicast MAC addresses) corresponding to the address (eg, a multicast IP address) received from the control unit 18 is output to the header of the frame generated from the data to be transmitted. Then the control unit causes 18 that the communication unit 12 transmits the frame with the information attached thereto to the slave device. Such control allows the slave device side to check whether the frame is a frame transmitted to the slave device concerned by referring to the control information attached to the header of the received frame.

The multicast operation described above is just one example and so long the communication device 10 -1 # 0, which is the master node, the same data to the multiple communication devices 10 which are the slave devices can transmit (ie multicasting), the method is not limited to the example described above.

Furthermore, the control unit 18 if the control unit 18 recognizes that at least some of the data has not been correctly supplied to at least some of the slave devices among the plurality of slave devices to which the data is being copied using the "data delivery checking function" described later; the data processing unit 11 and the communication unit 12 so control that the data is retransmitted. In this case, the control unit 18 in one example, controlling to re-write the data to the multiple slave devices to which the data has been multiplexed.

(Function of checking the data delivery)

The control unit 18 checks the delivery of data to the slave device to which the data is being transferred. Specifically, the control unit 18 causes the data processing unit 11 to generate a DL frame including a BAR (eg, a BAR frame) for requesting transmission of confirmation of the data, and causes the communication unit 12 transmits the DL frame to the slave device.

In addition, the control unit 18 if the control unit 18 Multicast data to multiple slave devices, designate at least some of the multiple slave devices as BAR targets. Specifically, the control unit determines 18 a slave device to be a BAR target, within the range of the number of BAR targets previously determined by a "BAR target number determining function" described later, among the plurality of slave devices to which the data is to be copied. Then the control unit 18 the operation of the data processing unit 11 and the communication unit 12 so that the BAR is transmitted to each of the slave devices that have been designated as destinations (ie, so that the BAR is transmitted to each slave device as a destination).

Furthermore, the control unit 18 the operation of the data processing unit 11 and the communication unit 12 so that the BAR is transmitted to each of the multiple slave devices as destinations. In this case, in one example, the data processing unit 11 generates a DL frame so that the BAR is transmitted to each of the plurality of slave devices. An example is 5 12 is a diagram illustrating an example of the structure of the DL frame used to transmit the BAR to each of the plurality of slave devices as destinations.

The in 5 Illustrated DL frames include, for example, "frame control,""duration / ID,""RA,""TA,""BARcontrol," and "BAR information." In addition, "BAR information" is provided as many times as the number of slave devices serving as targets. The "frame control" includes information regarding the frame. In addition, "duration / ID" includes information regarding the length of the frame. In addition, "RA" includes an address indicating that it is a frame addressed to multiple slave devices. In addition, "TA" includes an address of the transmission source (eg, the master node). In addition, the "BAR control" includes Information regarding the following "BAR Information". In addition, the "BAR information" includes information used to identify a slave device and which traffic is used for the BAR. Specifically, the "BAR information" includes "AID" and "TID value". The "AID" includes information used to identify each slave device. The "TID value" includes information used to identify the traffic. In addition, the "BAR information" may include several "AIDs" and "TID values".

Next, the control unit checks 18 the delivery of data to the slave device based on a BA transmitted from the slave device as a response to the BAR. Specifically, when a UL frame including the BA (eg, a BA frame) is received, the data processing unit 11 acquires information indicating a transmission source of the UL frame and the BA, and outputs the acquired information indicating a transmission source and specify the BA to the control unit 18 out. The control unit 18 checks whether the data is correctly delivered to the slave device serving as the transmission source of the BA, depending on the content of the detected BA. In addition, the control unit 18 if the UL frame including the BA is not transmitted within a predetermined period in response to the BAR from the slave device that has transmitted the DL frame including the BAR, recognize that transmission of at least some of the data the slave device failed. In addition, in the following description, a DL frame (eg, a BAR frame) including a BAR is sometimes simply referred to as BAR, and a UL frame (eg, a BA frame) including a BA is sometimes referred to simply as BA designates.

Further, the BA transmitted from each slave device can be multiplexed. In addition, in one example, the multiplexing described herein may be space division multiplexing, frequency division multiplexing, time division multiplexing and Orthogonal Frequency Division Multiple Access (OFDMA). In addition, the control unit 18 if the BA is multiplexed, notify the slave device side of control information necessary to perform the multiplexing. In this case, the control unit 18 in an example, controlling to notify the slave device of the control information by including the control information in the BAR. In addition, the control unit 18 in another example, controlling to associate the frame including the control information with the BAR. In addition, the control unit 18 in yet another example, to control that the slave device is notified of the control information using another frame that precedes or follows the BAR.

(Function of Collecting Communication Property Information)

The master node is to determine the number of BAR destinations based on the measurement result of the communication properties on the slave device side, and requests that the slave device measures the communication characteristics and notifies the measurement result. Then, the master node receives notification of the measurement result of the communication characteristics from the slave device as a response to the request. In addition, in the following description, this requirement is also called "communication property information request". In addition, the information including the measurement result of the communication characteristics notified from the slave device side is also called "communication property information".

Examples of communication characteristics (ie, communication property information) to be measured on the slave device side include the number of received packets, the number of received packets without retransmission, the packet loss rate, the throughput, the signal-to-noise ratio, and the like , The master node collects at least one of these information from each target slave device.

In addition, the master node may set all slave devices capable of communication as targets for collecting communication property information. In addition, in another example, the master node may limit the slave device, which is a destination for collecting the communication property information, from all the slave devices capable of communication based on a predetermined condition. In a specific example, the master node may set the slave device that has not transmitted the BA among the slave devices to which the BAR has been transmitted as a target for collecting the communication feature information. In addition, in another example, the master node may set the slave device that transmitted the BA among the slave devices to which the BAR has been transmitted as a target for collecting the communication characteristic information. It is obvious that the example described above is only an example and is not necessarily limited to the example described above.

Here, the operation of the master node is described in more detail. The control unit 18 instructs the data processing unit 11 to generate a frame including the communication property information request (hereinafter also referred to as "request frame"). In addition, the communication property information request may include, for example, information regarding the content to be measured on the slave device side (in other words, the type of information-to-be-detected information to be acquired).

Furthermore, the control unit 18 transmit the request frame to multiple slave devices in a multiplexed or multicast mode, or can transmit it to each slave device individually. In addition, the control unit includes 18 if the request frame is transmitted to a plurality of slave devices, resource allocation information used to multiplex the frame (eg, frequency division multiplexing, spatial multiplexing, OFDM, etc.) when the slave device side retransmits the communication feature information in the request frame. In addition, examples of the resource allocation information may include information such as time, center frequency, frequency width, coding matrix index, transmission power, and the like.

Then the control unit controls 18 the operation of the communication unit 12 so that the request frame generated by the data processing unit 11 is transmitted to the target slave device (eg, a slave device subjected to a multicast).

When the frame including the communication property information transmitted in response to the communication property information request from each slave device is received, the control unit detects 18 Further, a result from the data processing unit 11 obtained by extracting the communication property information from the frame. Such control allows the control unit 18 collect the communication property information from each slave device.

In addition, in the above, the example is described in which the slave device side notifies the communication property information as a response to the communication property information request from the master node. However, as long as the master node can collect the communication property information from the slave device, it is not necessarily limited to the embodiment. In a specific example, the master node may instruct the slave device to periodically notify the communication property information. More specifically, in one example, the master node may include information indicating a notification period of the communication property information in the request frame, thereby notifying the slave device of the notification period. In this case, the slave device side may notify the master node of the communication property information at fixed intervals based on the information included in the request frame indicating the notification period.

Further, the master node may cause only the slave device that satisfies a specific condition to notify the communication property information. In a more specific example, the master node may instruct each slave device to communicate the communication feature information only if the measurement result of the communication characteristics exceeds a predetermined threshold. More specifically, in one example, the master node may receive information indicating a condition (eg, a threshold of the communication characteristics) in the case of notifying the communication property information in the request frame, thereby notifying the slave device of the condition. In this case, if the measurement result of the communication characteristics satisfies the condition included in the request frame, the slave device side may notify the master node of the measurement result of the communication characteristics as the communication feature information.

(Function of determining the number of BAR targets)

The control unit 18 determines the number of BAR targets depending on system properties. In a specific example, the control unit estimates 18 System properties (eg, a packet loss rate) based on the communication property information collected by each slave device based on the above-described "communication characteristic information collecting function" and determines whether the estimation result satisfies a predetermined condition (e.g. the system requirement is met).

If the master node determines that the system property estimation result does not satisfy the condition, the master node updates the number of BAR targets. In addition, the details of the processing that with the Updating the number of BAR destinations is associated later, together with the description of the processing of the communication device 10 -1 described. If the number of BAR destinations is updated, the master node retrieves the communication property information from each slave device based on the "communication characteristic information collecting function" and estimates system properties based on the collected communication property information. Then, the master node again determines whether the estimation result satisfies the predetermined condition.

In this way, the master node keeps updating the number of BAR targets and the processing associated with the above determination of the system property estimation result, depending on the updated number of BAR targets, between each different transmission timings of the data Slave devices off. If the master node determines that the system property estimation result meets the predetermined condition, then the master node then determines the number of BAR targets set at that time as the number of BAR targets that will be used, if any Data are then transmitted to the slave device (eg, multicast).

In addition, the relationship between the system characteristics and the setting of the more preferable number of BAR targets depending on the system characteristics can be checked in one example by previous tests and the like, and information based on the check result can be stored in advance in an area provided by the control unit 18 is readable. In addition, in one example, the relationship between the packet loss rate as system characteristics and the number of BAR destinations as in the above description is explained with reference to FIG 3 ,

((Function in case of operating as a slave device))

Next, functions in a case where the communication device 10 -1 operates as the slave device, described in detail.

(Function of notification of delivery of data)

The control unit 18 controls the processing of notification of the master node via a BA corresponding to a receiving situation of data corresponding to the BAR as a response to the BAR transmitted from the master node. Specifically, the control unit checks 18 when the BAR transmitted from the master node is received, whether the reception of the data corresponding to the BAR (ie, data received before the BAR) succeeds. Then the control unit controls 18 the operation of the data processing unit 11 and the communication unit 12 such that the BA corresponding to the receiving situation of the data is transmitted in response to the BAR to the master node which is the transmission source of the BAR.

The data processing unit 11 generates a BA based on an instruction from the control unit 18 and gives the generated BA to the communication unit 12 out.

The communication unit 12 transmits the BA output from the data processing unit 11 to the master node.

In addition, as described above, the BA can be transmitted in a multiplexed format. In this case, the control unit 18 the operation of the data processing unit 11 and the communication unit 12 so that the BA is multiplexed and then transmitted based on the control information used for multiplexing and communicated by the master node.

(Function of Communicating Communication Property Information)

The slave device according to the present embodiment measures a target communication property based on the communication property information request transmitted from the master node, and notifies the master node of the measurement result as the communication property information.

Specifically, the control unit detects 18 When the request frame including the communication property information request transmitted from the master node is received, a result obtained by extracting the communication property information request from the request frame from the data processing unit 11. The control unit 18 measures information indicating the communication characteristics (ie, information to be measured) instructed by the acquired communication property information request.

The control unit 18 outputs the measurement result of the communication characteristics to the data processing unit 11, and causes the data processing unit 11 to generate a frame including the measurement result of the communication characteristics. The frame can be at a Example information used for identifying the communication characteristics to be measured, information associated with the measurement result of the communication characteristics, and the like. Then the control unit controls 18 the operation of the communication unit 12 so that the frame including the measurement result of the communication characteristics generated by the data processing unit 11 is transmitted to the master node. In addition, the control unit 18 at this event, the operation of the communication unit 12 so that the frame including the measurement result of the communication characteristics is transmitted to the master node based on the resource allocation information included in the communication property information request.

The example of the configuration of the communication device 10 1 according to the first embodiment of the present disclosure is described with reference to FIG 4 and 5 described.

<Processing of the device>

Next, referring to 6 to 9 the processing of the communication system and the communication device 10 -1 according to the present embodiment, particularly by focusing on the operation in a case where a master node multicasts data to a plurality of slave devices and checks the delivery of the data.

(Processing sequence of the communication system)

First, an example of the processing sequence of the communication system will be described with reference to FIG 6 and 7 described according to the present embodiment. 6 and 7 Each is a diagram that is illustrated for describing an example of the processing sequence of the communication system according to the present embodiment.

First on 6 Referenced. 6 is an example of a processing sequence focused on updating the number of BAR targets. As in 6 For example, in the communication system according to the present embodiment, the communication device 10-1 # 0, which is the master node (AP), first sets and maintains an initial value (e.g., 1) for the number of BAR destinations Processing associated with transmission of multicast data; and processing associated with verifying delivery of the data (ie, transmission of a BAR and receipt of a BA). In addition, the master node executes the processing associated with the transmission of multicast data and the processing associated with verifying the delivery of the data at least one or more times based on the setting of the number of BAR destinations.

Then, the master node updates the number of BAR targets by adding a predetermined number to the currently set number of BAR targets (eg, increasing the number of BAR targets). In one example, the master node updates at the in 6 For example, if the current fixed number of BAR targets is k, the number of BAR targets is illustrated by adding 1 to the number of BAR targets k (ie, after updating, the number of BAR targets becomes k + 1). Then, the master node performs the processing associated with the transmission of multicast data and the processing associated with verifying the delivery of the data (ie, transmitting the BAR and receiving the BA) based at least once or more on the updated number of BAR goals. In this way, the master node maximizes the number of BAR targets to the number n of all slave devices connected to the master node.

In addition, when updating the number of BAR destinations, a method of setting the slave device is not particularly limited as long as a slave device serving as the BAR destination can be set within the range of the updated number of BAR destinations , In a specific example, if the master node updates the number of BAR destinations, the master node may forward a slave device serving as a new BAR destination to the slave device as the BAR destination is set to update. In addition, in another example, the master node may preferentially set the slave device set as the BAR destination before updating the number of BAR destinations as the BAR destination after updating the number of BAR destinations. It is obvious that the example described above is only an example and is not necessarily limited to the example described above.

In this way, the master node changes (updates) the number of BAR destinations by adding the number of BAR destinations between a first transmission timing at which data is transmitted to the slave device and a second transmission timing after the first transmission timing (FIG. ie between different transmission timings). In other words, the master node updates the number of BAR destinations between processing that involves checking the delivery of the data to each of different data at different Occasions are transmitted to the slave devices.

Further, in the series of sequences associated with the in 6 For example, updating the number of BAR targets associated (eg, the sequence during updating the number of BAR targets from 1 to n), the communication properties for the entire system (ie, system properties). An example is 7 12 is a diagram illustrating an example of a method in which the master node estimates system characteristics in the communication system according to the present embodiment. Moreover, in 7 the processing indicated as "BAR-BA Frame Exchange Sequence", in one example, a process of verifying delivery of the data after the master node has relocated data to each slave device, that is, a series of sequences in which a BAR is transmitted from the master node to the slave device and a BA is transmitted from the slave device to the master node in response to the BAR.

For a specific example, as in 7 1, the master node performs the processing associated with estimating system properties at least one or more times each of the "BAR-BA frame exchange sequences" in which different numbers are designated as the number of BAR destinations. In an example, in the 7 Example of the master node illustrates the processing associated with estimating system properties for both the case where the number of BAR targets is "x" and the case where the number of BAR targets is " y "is off.

More specifically, the master node transmits the communication property information request to the target slave device and thus requests that the slave device measures the communication characteristics and notifies the measurement result in response to the request, then receives the communication property information including the measurement result of the communication characteristics from the slave -Contraption. Then, the master node estimates the communication characteristics (i.e., the system characteristics) of the entire system based on the measurement result of the communication characteristics of the slave device detected by each slave device.

In other words, the master node updates the number of BAR destinations between each different transmission timings of the data to the slave device and estimates the system properties for each number of BAR destinations. Next, the master node determines whether the estimated system properties meet a predetermined condition (that is, whether the system requirement is met). In this manner, the master node repeatedly executes the processing series associated with updating the number of BAR targets, estimating the system properties for each number of BAR targets, determining on the system property estimation result (hereinafter also referred to as " Processing series associated with finding the number of BAR targets "), thereby searching for the number of BAR targets whose system properties meet the predetermined condition.

More specifically, if the master node determines that the system property estimation result satisfies the predetermined condition, the master node may terminate the processing series associated with the search for the number of BAR targets. In this case, in one example, the number of BAR destinations set when the determination is made can be used as the number of BAR destinations in the processing associated with checking the delivery of data, which subsequently is to execute.

Further, if the processing series associated with the search for the number of BAR targets is executed until the number of BAR targets becomes maximum (e.g., until the number of BAR targets becomes n), For example, suppose that any estimation result of the system properties for any number of BAR targets does not satisfy the predetermined condition. In this case, the master node may set the number of BAR targets having the most satisfactory system properties as the number of BAR targets in the processing associated with verifying the delivery of data to be subsequently executed.

Further, during the search for the number of BAR targets, it is assumed that the master node detects when the system properties corresponding to the updated number of BAR targets are worse than the system properties equal to the number of BAR targets before Refresh. In this case, the master node may stop the processing series associated with the search for the number of BAR targets, and may set the number of BAR targets set prior to updating as the number of BAR targets in specify the processing associated with verifying the delivery of data to be subsequently executed.

An example of the processing sequence of the communication system according to the present embodiment is described above with reference to FIG 6 and 7 described. The search for The number of BAR destinations based on the processing sequence as described above enables the master node according to the present embodiment to improve the reliability in a more preferable mode and to reduce consumption of communication resources depending on the state of communication with each slave station. Device reduced.

(Process of the master node)

Next, an example of a process in the case where the communication device 10 -1 as the master node works, with reference to 8th described. 8th Fig. 10 is a flowchart illustrating an example of steps in the operation procedure of the communication device 10 1, which operates as the master node in the communication system according to the present embodiment.

(Step S101)

First, the master node sets an initial value for the number of BAR targets.

(Steps S103 and S105)

Next, the master node transitions to the processing associated with the transmission of multicast data. Specifically, the maser note waits for an instruction associated with the transmission of multicast data as long as there is no multicast data to be transmitted (NO in S103). If multicast data to be transmitted is present (YES in S103), the master node then transmits the multicast data to a plurality of slave devices to which the multicast data is transmitted.

(Steps S107 and S109)

After transmitting the multicast data to the multiple slave devices, the master node verifies the delivery of the data. Specifically, the control unit determines 18 a slave device (ie, a BAR destination) to which the delivery of the data is to be checked, within the predetermined range of the number of BAR destinations from the multiple slave devices to which the data is being multiplexed, and controls the Operation of the data processing unit 11 and the communication unit 12 so that the BAR is transmitted to the slave device (S107). Then, the control unit 18 checks the supply of the data to the slave device based on the reception result of the BA transmitted from the slave device as a response to the BAR (S109).

(Step S111)

The master node performs the processing related to the transmission of the BAR (S107) described above and the processing related to the verification of the delivery of the data to the slave device, based on the Receive result of the BA transmitted from the slave device as a response to the BAR (S109) for all target destinations (NO in S111).

(Step S113)

Next, the master node determines the subsequent processing depending on whether the system properties are to be checked. If the system properties are not checked (NO in S113), the master node waits for an instruction associated with the transmission of the subsequent multicast data (S103).

(Step S115)

On the other hand, if the system properties are checked (YES in S113), the master node performs the processing associated with the detection of the system properties. Specifically, the master node requests that the target slave device performs measurement of the communication characteristics and notification of the measurement result by transmitting the communication property information request to the target slave device, and in response collects the communication property information from the slave device. Then, the master node estimates the system properties (e.g., packet loss rate) based on the communication property information collected by each slave device.

(Step S117)

Next, the master node determines whether the estimation result of the system properties satisfies a predetermined condition (that is, whether the system requirement is met).

(Step S119)

If the master node determines that the system performance estimation result does not satisfy the condition (NO in S117), the master node updates the number of BAR targets (S119) and waits for an instruction that associates with the transmission of the subsequent multicast data is (S103). In addition, in this case, the master node retrieves the communication property information from each slave device after executing the processing associated with each of the slave devices Transmission of multicast data (S105) associated with transmission of a BAR (S107) and reception of a BA (S109), and estimates the system characteristics based on the collected communication characteristic information (S115), then determines again whether the estimation result satisfies a predetermined condition ( S117).

(Step S121)

If the master node determines that the system property estimation result satisfies the predetermined condition (YES in S117), then the master node sets the number of BAR destinations set in the event as the number of BAR destinations in in the case where the data is subsequently transmitted to the slave device (eg multicast).

An example of a process in the case where the communication device 10 -1 as the master node is working, with reference to above 8th described.

(Process of the slave device)

Next, an example of a process in a case where the communication device 10 -1 operates as a slave device, with reference to 9 described. 9 Fig. 10 is a flowchart illustrating an example of steps in the operation procedure of the communication device 10 1, which operates as the slave device in the communication system according to the present embodiment.

(Step S151)

The multicast data is transmitted from the master node to the slave device designated as a target of the multicast. In this case, the target slave device first executes the processing related to the reception of the multicast data until the reception is completed (NO in S151).

(Step S155)

Subsequently, the multicast data is transmitted and then the BAR is transmitted from the master node to the slave device designated as the BAR destination among the slave devices set as targets of the multicast. If the slave device receives the BAR (YES in S153), the slave device transmits the BA corresponding to the reception situation of the multicast data as a response to the BAR to the master node which is the BAR transmission source. Such a mechanism allows the master node, based on the BA transmitted by the slave device, to recognize whether the multicast data has been correctly delivered to the slave device.

(Step S153)

In addition, it is obvious that the BAR is not transmitted from the master node to the slave device, which is not a BAR destination, and the slave device does not receive the BAR (NO in S153). Accordingly, in this case, of course, the slave device does not perform the processing associated with the transmission of the BA (S155).

(Steps S157 and S159)

Next, the slave device, which is a target from which the communication property information is collected, is instructed to measure the communication characteristics and to communicate the measurement result from the master node based on the communication property information request. If the slave device receives the communication property information request from the master node (YES in S157), the slave device measures the communication characteristics indicated in the communication property information request, and notifies the master node of the measurement result as the communication property information (S159). In addition, the communication property information request is not transmitted from the master node to the slave device that is not a target from which the communication property information is collected, and the slave device does not receive the communication property information request (NO in S157). Accordingly, it is obvious in this case that the slave device does not perform the processing associated with the measurement of the communication characteristics and the communication of the measurement result (S159).

An example of the process in the case where the communication device 10 -1 as the slave device operates above with reference to FIG 9 described.

<Modification>

Next, a communication system and a communication device 10 -1 according to a modification of the present embodiment. In the communication system according to the above-described embodiment, the communication device collects 10 -1 # 0, which is the master node, estimates the communication attribute information of multiple target slave devices and estimates the System properties (eg packet loss rate) based on the collected communication property information then determines the number of BAR targets based on the system feature estimation result. Meanwhile, in the communication system according to the modification of the present embodiment, the system characteristics based on the information indicating the reception situation of the data to be confirmed (eg, the multicast data) included in the BA are read by the slave device as one Response to the BAR is estimated instead of the communication property information.

More specifically, the BA to be transmitted to the master node as a response to the BAR from the slave device side includes a bitmap based on the sequence number of the data to be confirmed (e.g., multicast data), which is contained in the BAR indicates whether the data has been received correctly. In the communication system according to the modification of the present embodiment, the master node recognizes the reception characteristics of the slave device serving as the transmission source of the BA based on the bit map included in the BA, and estimates the characteristics of the entire system (ie, system properties) based on a result obtained by detecting the reception characteristics for each slave device.

Accordingly, the description will be described by focusing on the processing involved in estimating the system characteristics of the communication device 10 -1 according to the modification of the present embodiment, in particular different from the communication device 10 according to the embodiment described above. In addition, a detailed description will be made of substantially the same parts as those of the communication device 10 -1 omitted according to the embodiment described above.

(Process of the master node)

First, an example of a process in the case where the communication device 10 -1 as the master node in the communication system according to the modification of the present embodiment, with reference to FIG 10 described. 10 Fig. 10 is a flowchart showing an example of a series of processing procedures of the communication device 10 1, which operates as the master node in the communication system according to the modification of the present embodiment.

(Steps S201 to S211)

In 10 For example, the processing shown as steps S201 to S211 is substantially the same as in FIG 8th processing shown as steps S101 to S111. In other words, the master node sets the initial value of the number of BAR destinations (S201) and executes the processing associated with the transmission of the multicast data (S203 and S205), then performs the processing involved in the checking delivery of the multicast data for all target destinations (ie, slave devices) from (S207 to S211).

(Step S215)

When the processing associated with checking the delivery of the multicast data is performed for all the target slave devices (YES in S211), the master node recognizes the receiving characteristics of the slave devices based on the bit map that is in includes the BA received from each target slave device. Then, the master node estimates the system properties based on the reception characteristics detected for each slave device.

(Steps S217 to S221)

In addition, the subsequent processing shown as steps S217 to S221 is substantially the same as that in steps S117 to S121 in FIG 8th shown processing. In other words, if the master node determines that the estimation result of the system properties does not satisfy the condition (NO in S217), the master node updates the number of BAR destinations (S219), performs the processing involved in the transmission the subsequent multicast data is associated (S203 and S205), and performs the processing associated with checking the delivery of the multicast data is performed (S207 to S211), then again estimates the system properties (S215). If the master node determines that the system performance estimation result satisfies the predetermined condition (YES in S217), then the master node sets the number of BAR destinations set in this event as the number of BAR destinations in FIG in the case of subsequently transferring the data (eg, multicast data) to the slave device.

For example, the process is in the case where the communication device 10 -1 operates as the master node in the communication system according to the modification of the present embodiment, with reference to FIG 10 described.

(Process of the slave device)

Next is an example of a process when the communication device 10 -1 as the slave device in the communication system according to the modification of the present embodiment, with reference to FIG 11 described. 11 Fig. 10 is a flowchart showing an example of a series of processing procedures of the communication device 10 1, which operates as the slave device in the communication system according to the present embodiment.

Moreover, in 11 the processing shown as steps S251 to S255 is substantially the same as in FIG 9 processing shown as steps S151 to S155. In other words, if the slave device is set to multicast, the slave device performs the processing associated with the reception of the multicast data transmitted from the master node (S251). Next, if the slave device is designated as the BAR destination, the slave device performs the processing associated with checking the delivery of the multicast data, that is, performs the processing associated with the receipt of the BAR , which is transmitted from the master node, and the processing associated with the transmission of the BA as a response to the BAR (S253 and S255).

For example, the process is in the case where the communication device 10 -1 operates as the slave device in the communication system according to the modification of the present embodiment, with reference to FIG 11 described.

As described above, in the communication system according to the modification of the present embodiment, as compared with the communication system according to the embodiment described above, it is possible to omit the communication sequence associated with the transmission and reception of the communication property information request and the communication property information as a response to the request is. Accordingly, the communication system according to the modification enables the system characteristics in an environment in which a difference in communication characteristics between a plurality of slave devices to be controlled by the master node (eg, between a plurality of slave devices included in a cell) , is small, or in an environment where it is easy to predict communication characteristics (eg, an environment in which even slave devices are controlled in the design stage of the system) to estimate more efficiently.

<Summary>

As described above, in the communication system according to the present embodiment, the master node updates the number of BAR destinations by adding between respectively different transmission timings of the data to the slave devices, estimates the system properties for each number of BAR destinations, and determines whether the Estimation result meets a predetermined condition. The master node searches for the number of BAR targets whose system properties meet the predetermined condition by repeatedly executing the processing series associated with updating the number of BAR targets, estimating the system properties for each number of BAR targets, and the Determining on the estimation result of the system properties is associated, as described above. Such a configuration enables the communication system according to the present embodiment to improve the reliability in a more preferable mode and reduce the consumption of communication resources depending on the state of communication between the master node and each slave device.

In particular, in circumstances where the overhead influence is greater, such as if multiple slave devices are present in the cell or if there is another cell around the cell controlled by the master node, and a fault is severely affected system properties tend to be more satisfactory when the number of BAR targets is smaller. Accordingly, according to the embodiment of the present embodiment, it is possible for the master node to efficiently search for the more appropriate number of BAR destinations in an environment in which the overhead influence is larger. In addition, it is possible for the master node to further improve the accuracy associated with the system measurement estimation by performing control in such a manner as to increase the number of slave devices from which communication characteristic information is collected becomes.

<Second Embodiment: Example of Searching for the Number of BAR Targets Based on Subtraction>

Next will be a communication device 10 According to a second embodiment of the present disclosure. In addition, in the following description, the communication device 10 according to the present Embodiment in some cases hereinafter referred to as a "communication device 10-2", wherein it by special distinguishing from a communication device 10 will be described according to another embodiment.

The communication device 10 -2 according to the present embodiment is of the communication device 10 -1 according to the first embodiment described above with respect to the processing procedure associated with the search for the number of BAR targets. Specially updated the communication device 10 -2 according to the present embodiment, the number of BAR targets by subtracting a predetermined number from the currently set number of BAR targets (e.g., reducing the number of BAR targets) between respectively different transmission timings of data for the slave devices , Accordingly, the description will be described by focusing on the processing procedure involved in searching for the number of BAR destinations of the feature of the communication device 10 -2 according to the present embodiment, which is different from the communication device 10 -1 according to the first embodiment described above. In addition, a detailed description will be made of substantially the same parts as those of the communication device 10 -1 omitted according to the first embodiment described above.

An example is 12 FIG. 10 is a diagram for describing an example of a processing sequence of the communication system according to the present embodiment, and is an example of a processing sequence focused on updating the number of BAR destinations.

As in 12 illustrates, sets a communication device 10 -2 # 0, which is the master node (AP), in the communication system according to the present embodiment, first an initial value for the number of BAR destinations (e.g., the number n of slave devices connected to the master Nodes) and performs processing associated with transmission of multicast data and processing associated with verifying a delivery of data (ie, transmission of a BAR and receipt of a BA). In addition, the master node executes the processing associated with the transmission of multicast data and the processing associated with verifying the delivery of the data at least one or more times based on the setting of the number of BAR destinations.

Next, the master node updates the number of BAR targets by subtracting a predetermined number from the currently set number of BAR targets (eg, decreasing the number of BAR targets). In one example, the master node updates at the in 12 For example, the number of BAR targets when the number of BAR targets currently set is k is subtracted by 1 from the number k of BAR targets (ie, after updating, the number of BAR targets becomes k-1). Then, the master node performs the processing associated with the transmission of the multicast data and the processing associated with verifying the delivery of the data (ie, the transmission of the BAR and the reception of the BA) based at least once or more on the updated number of BAR goals. In this way, the master node minimizes the number of BAR targets to 1.

Further, the master node estimates the system properties for each number of BAR targets in the series of sequences associated with updating the number of BAR targets, which is similar to the first embodiment. Specifically, the master node may transmit a communication property information request to the target slave device and may collect communication property information including a measurement result of communication characteristics from the slave device as a response to the communication property information as described above with reference to FIG 7 to 9 is described. In this case, the master node may estimate the system characteristics (eg, packet loss rate) based on the measurement result of the communication characteristics in the slave device detected by each slave device. In addition, the master node in another example, as described above with reference to 10 and 11 to recognize the reception characteristics of the slave device serving as the transmission source of the BA based on the bitmap included in the BA transmitted from the slave device side in response to the BAR. In this case, the master node may estimate the system properties based on the recognition result of the reception characteristics for each slave device.

In this way, the master node updates the number of BAR destinations between different transmission timings of the data to the slave devices and estimates the system properties for each number of BAR destinations. Next, the master node determines whether the estimated system properties meet a predetermined condition (ie, whether the system requirement is met). In this way, the master node searches for the number of BAR targets whose System properties satisfy the predetermined condition by repeatedly executing the processing series associated with updating the number of BAR targets, estimating the system properties for each number of BAR targets, and determining the system property estimation result (ie, the processing series associated with finding the number of BAR goals).

In addition, the contents of the processing series associated with the search for the number of BAR destinations by the master node according to the present embodiment are substantially the same as those in the case of the first embodiment described above. In other words, if the master node determines that the system property estimation result satisfies the predetermined condition, the master node may terminate the processing series associated with the search for the number of BAR targets. In this case, in one example, the number of BAR destinations set when the determination is made can be used as the number of BAR destinations in the processing associated with checking the delivery of data, which subsequently is to execute. In addition, if the estimation result of the system characteristics does not satisfy the predetermined condition until the number of BAR targets becomes minimum (for example, until it becomes 1), the master node may count the number of BAR targets having the most satisfactory system characteristics as the number at BAR targets in the processing associated with verifying the delivery of data to be subsequently executed. In addition, if it is detected during the search for the number of BAR targets that the system properties have deteriorated due to the updating of the number of BAR targets, the master node may stop the processing series associated with the search for the number of BARs Targets is associated. In this case, in one example, the number of BAR destinations set prior to updating may be used as the number of BAR destinations in the processing associated with verifying the delivery of data to be subsequently executed.

In addition, when updating the number of BAR destinations, a method of setting the slave device is not particularly limited if a slave device to be the BAR destination is set within the range of the number of BAR destinations after updating , In a specific example, if the master node updates the number of BAR targets, the master node may reduce the number of BAR targets by removing any of the slave devices designated as the BAR target before updating reduce the BAR target. In addition, in another example, the master node may reduce the number of BAR targets by preferentially removing a slave device with more satisfactory communication characteristics from the BAR target depending on the communication characteristics of each slave device. Such control makes it easier to estimate the communication characteristics of the entire system (i.e., system characteristics) from the communication characteristics of some of the slave devices.

The features of the communication device 10 -2 according to the present embodiment are described above with reference to FIG 12 and with particular reference to the processing procedure associated with finding the number of BAR targets. As described above, in the communication system according to the present embodiment, the master node updates the number of BAR destinations by subtracting between different transmission timings of the data to the slave device, estimates the system characteristics for each number of BAR destinations, and determines whether the estimation result satisfies the predetermined condition. The master node searches for the number of BAR targets whose system properties meet the predetermined condition by repeatedly executing the processing series associated with updating the number of BAR targets, estimating the system properties for each number of BAR targets, and the Determining on the estimation result of the system properties is associated. Such a configuration enables the communication system according to the present embodiment to improve reliability in a more preferable mode and reduce consumption of communication resources depending on the state of communication between the master node and each slave device.

In particular, under circumstances where the overhead influence is smaller, such as if the number of slave devices in the cell is small, or if there is no other cell around the cell controlled by the master node, then the system characteristics are tend to be more satisfactory if the number of BAR goals is greater. Accordingly, according to the embodiment of the present embodiment, it is possible for the master node to efficiently search for the more appropriate number of BAR destinations in an environment where the overhead influence is smaller.

<Third Embodiment: Example of an applicable search for the number of BAR destinations for changing the communication environment>

Next will be a communication device 10 according to a third embodiment of the present disclosure. moreover In the following description, the communication device 10 according to the present embodiment, may be referred to as a "communication device 10-3" if it is provided by the communication device 10 According to another embodiment is particularly distinguished.

The communication device 10 -3 according to the present embodiment is of the communication device 10 according to the other embodiment, as described above, with respect to the processing procedure associated with the search for the number of BAR targets. In one example, the communication device searches 10 according to the first embodiment and the second embodiment described above, regularly by the number of BAR destinations in a predetermined direction (eg, addition direction or subtraction direction) by determining the number that is determined each time the number is updated at BAR targets to which or from the currently set number of BAR targets is added or subtracted. Meanwhile, the communication device is 10 -3 according to the present embodiment of the communication device 10 of the other embodiment described above, the search for the number of BAR destinations is performed irregularly, for example, random selection of the number of BAR destinations to be subsequently set, from the numbers not previously selected, or like. Accordingly, the description will be made of the features of the communication device 10 -3 according to the present embodiment by focusing on the processing procedure associated with the search for the number of BAR destinations other than the communication device 10 according to the other embodiment described above. In addition, a detailed description of the parts that are substantially the same as those of the communication device 10 according to the other embodiment described above are omitted.

An example is 13 FIG. 10 is a diagram for describing an example of a processing sequence of the communication system according to the present embodiment, and is an example of a processing sequence focused on updating the number of BAR destinations.

As in 13 illustrates, sets a communication device 10 -3 # 0, which is the master node (AP), in the communication system according to the present embodiment, first the number which is randomly selected within the range where the number of connected slave devices is between 1 and n, as the initial one Value for the number of BAR goals. Then, the master node executes the processing associated with the transmission of the multicast data and the processing associated with checking the delivery of the data (ie, transmission of a BAR and reception of a BA). In addition, the master node executes the processing associated with the transmission of multicast data and the processing associated with verifying the delivery of the data at least one or more times based on the setting of the number of BAR destinations.

Next, the master node updates the number of BAR targets by specifying the number that is randomly selected among the numbers of targets from 1 to n within the range other than the number selected as the number of BAR targets, as the new number of BAR goals. In one example, the master node sets the in 13 For example, the number r3 randomly selected from the range of the numbers of the destinations from 1 to n is shown as the initial value for the number of BAR destinations. Next, the master node sets the number r3 randomly selected within the range other than the number r3 selected among the numbers of targets from 1 to n as the new number of BAR targets in updating the number BAR goals fixed. Then, the master node performs the processing associated with the transmission of multicast data and the processing associated with verifying the delivery of the data (ie, a transmission of a BAR and a reception of a BA) based at least once or more on setting the number of BAR goals.

Further, the master node estimates system properties for each number of BAR targets in the series of sequences associated with updating the number of BAR targets, which is similar to each of the embodiments described above. Specifically, the master node as described above with reference to 7 to 9 is described, transmits the communication property information request to the target slave apparatus, and can collect the communication property information including the measurement result of the communication characteristics in response to the communication property information request. In this case, the master node may estimate the system characteristics (eg, packet loss rate) based on the measurement result of the communication characteristics of the slave device detected by each slave device. In addition, in another example, the master node may recognize the receiving characteristics of the slave device serving as the transmission source of the BA based on the bitmap included in the BA that is received from the slave device side as one Answer to the BAR is transferred as above with reference to 10 and 11 is described. In this case, the master node may estimate the system characteristics based on the recognition result of the reception characteristics of each slave device.

In this way, the master node updates the number of BAR destinations between different transmission timings of the data to the slave devices and estimates the system properties for each number of BAR destinations. Next, the master node determines whether the estimated system properties meet a predetermined condition (that is, whether the system requirement is met). In this way, the master node searches for the number of BAR targets whose system properties meet the predetermined condition by repeatedly executing the processing series associated with updating the number of BAR targets, estimating the system properties for each number of BAR targets. Targeting and determining on the estimation result of the system properties (ie, the processing series associated with searching for the number of BAR targets).

In addition, if the master node according to the present embodiment determines that the estimation result of the system properties satisfies the predetermined condition, the master node may terminate the processing series associated with the search for the number of BAR destinations. In this case, in one example, the number of BAR destinations set when the determination is made can be used as the number of BAR destinations in the processing associated with checking the delivery of data, which subsequently is to execute. In addition, if the estimation result of the system properties does not satisfy the predetermined condition for all patterns (ie, 1 to n) from the result of the search for the number of BAR targets, the master node may determine the number of BAR targets having the most satisfactory system characteristics as the number of BAR targets in the processing associated with verifying a delivery of data to be subsequently executed.

Further, in another example, the master node may apply a predetermined search algorithm to search for the number of BAR targets. In one example, the master node may search for the number of BAR targets for a binary search type.

More specifically, the master node estimates the system properties for the case where the number of BAR targets is the minimum (ie 1) and the case where the number is the maximum (ie the number of connected slave devices, n). is. In addition, the method of estimating the system properties is similar to that of the example described above. Next, the master node sets a median (ie, n / 2) of the number of BAR targets (ie, 1 and n) determined by the system property estimate as the new number of BAR targets and estimates the system properties for the number of BAR goals. Then, the master node determines whether the system properties estimated for the newly set number of BAR targets meet a predetermined condition. Next, the master node sets the numbers for which the system property estimation has not yet been performed (ie, n / 4 and 3n / 4), which are medians of the numbers of BAR targets that have been selected (ie, 1, n / 2 and n), determines the number of BAR targets and estimates the system properties for the number of BAR targets. Then, the master node determines whether the system properties estimated for the newly set number of BAR targets meet the predetermined condition. In addition, in a manner similar to the subsequent procedure, the master node sets the median of the numbers of BAR targets determined by estimating the system properties as the new number of BAR targets and estimates the system properties for the number of BAR targets , then determines whether the estimation result of the system properties satisfies the predetermined condition.

In this way, the master node repeatedly executes the processing series associated with updating the number of BAR targets, estimating system properties for each number of BAR targets, and determining the system property estimation result. Then, the master node may end the search for the number of BAR targets at the time when the system properties estimated for each number of BAR targets meet the predetermined condition (e.g., system requirement). In addition, if the system property estimation result does not satisfy the predetermined condition for all patterns (ie, from 1 to n) of the result of the search for the number of BAR targets, the master node may determine the number of BAR targets having the most satisfactory system characteristics as the number of BAR targets in the processing associated with verifying a delivery of data to be subsequently executed.

In addition, the above-described method of searching for the number of BAR targets is only an example and is not necessarily limited to the example described above. In a specific example, the master node may search for the number of BAR targets based on an algorithm other than a binary search.

The features of the communication device 10 -3 according to the present embodiment are described above with reference to FIG 13 and with particular reference to the processing procedure associated with finding the number of BAR targets. As described above, in the communication system according to the present invention, the search direction for the number of BAR destinations to be subsequently set when the master node updates the number of BAR destinations between respectively different transmission timings of data to the slave devices Embodiment given the irregularity. Then, the master node estimates the system properties for each number of BAR targets and determines whether the estimation result satisfies the predetermined condition. The master node searches for the number of BAR targets whose system properties meet the predetermined condition by repeatedly executing the processing series associated with updating the number of BAR targets, estimating the system properties for each number of BAR targets, and the Determining on the estimation result of the system properties is associated. Such a configuration enables the communication system according to the present embodiment to efficiently respond to the more appropriate number of BAR destinations in an environment where the replacement frequency of slave devices in a cell is high, or in an environment where circumstances are severe can be changed (in other words, if it is difficult to predict the environment) searches. In other words, according to the present embodiment, it is possible for the master node to search for the number of BAR destinations more appropriate for a change of the communication environment even in a situation where the communication environment changes significantly.

<Fourth Embodiment: Example of Searching Number of BAR Targets to Further Improve the Communication Quality>

Next will be a communication device 10 According to a fourth embodiment of the present disclosure. In addition, in the following description, the communication device 10 according to the present embodiment, may be referred to as a "communication device 10-4" if it is provided by the communication device 10 According to another embodiment is particularly distinguished.

The communication device 10 -4 according to the present embodiment is of the communication device 10 according to the other embodiment described above with respect to the processing procedure associated with the search for the number of BAR targets. Specifically, the communication device 10 according to the present embodiment therein of the communication device 10 According to each of the above-described embodiments, differently, the number of BAR destinations to be subsequently set is determined depending on a change of system properties in updating the number of BAR destinations (in other words, the search direction for the number of BARs Destinations determined). Accordingly, the description will be made of the features of the communication device 10 -4 according to the present embodiment by focusing on the processing procedure associated with the search for the number of BAR targets. In addition, a detailed description of the parts that are substantially the same as those of the communication device 10 according to the other embodiments described above are omitted.

An example is 14 FIG. 10 is a diagram for describing an example of a processing sequence of the communication system according to the present embodiment, and is an example of a processing sequence focused on updating the number of BAR destinations.

As in 14 illustrates, sets a communication device 10 -4 # 0, which is the master node (AP), in the communication system according to the present embodiment, first the number which is randomly selected within the range where the number of connected slave devices is between 1 and n, as the initial one Value for the number of BAR goals. Then, the master node executes the processing associated with the transmission of multicast data and the processing associated with checking a delivery of the data (ie, transmission of a BAR and reception of a BA). In addition, the master node executes the processing associated with the transmission of multicast data and the processing associated with verifying the delivery of the data at least one or more times based on the setting of the number of BAR destinations.

Next, the master node adds a predetermined number (e.g., 1) to the currently set number of BAR targets, and, as the number of BAR targets is changed again, the master node subtracts a predetermined number from the number t to BAR goals. To better understand the description, the description here is given on the assumption that the number of BAR targets after addition is t + 1 and that the number of BAR targets after subtraction is t-1. Then, the master node estimates the system properties for each of the number of BAR targets after Addition, t + 1, and the number of BAR targets after subtraction, t-1. The method of estimating system properties is similar to that of any of the embodiments described above.

Then, the master node determines the direction in which the system properties between the number t + 1 at BAR destinations after the addition and the number t-1 at BAR destinations after the subtraction are improved, as the search direction for the number BAR targets. More specifically, if the master node detects that a higher improvement in system properties for the number t + 1 at BAR targets is achieved after addition, the master node determines the direction in which the number t of BAR targets increases ( that is, the direction of addition) as the search direction for the number of BAR targets. In addition, if the master node detects that a greater improvement in system characteristics for the number t-1 at BAR targets is achieved after subtraction, the master node determines the direction in which the number t of BAR targets decreases ( ie the subtraction direction) as the search direction for the number of BAR targets.

In this way, the master node updates the number of BAR targets based on the search direction for the particular number of BAR targets between different transmission timings of the data to the slave devices and estimates the system properties for each number of BAR targets. Next, the master node determines whether the estimated system properties meet the predetermined condition (that is, whether the system requirement is met). In this way, the master node searches for the number of BAR targets whose system properties meet the predetermined condition by repeatedly executing the processing series associated with updating the number of BAR targets, estimating the system properties for each of the numbers of BARs Goals and determining is associated with the system property estimation result (ie, the processing series associated with searching for the number of BAR targets).

In addition, if the master node according to the present embodiment determines that the estimation result of the system properties satisfies the predetermined condition, the master node may terminate the processing series associated with the search for the number of BAR destinations. In this case, in one example, the number of BAR destinations set when the determination is made can be used as the number of BAR destinations in the processing associated with checking the delivery of data, which subsequently is to execute. In addition, if the estimation result of the system properties does not satisfy the predetermined condition for all patterns (ie, 1 to n) from the result of the search for the number of BAR targets, the master node may determine the number of BAR targets having the most satisfactory system characteristics as the number of BAR targets in the processing associated with verifying a delivery of data to be subsequently executed. In addition, in another example, it may be assumed that the system properties in both cases of both the number t + 1 at BAR targets after the addition and the number t-1 at BAR targets after the subtraction with respect to the currently fixed ones Decrease number t of BAR goals. In such a case, before a predetermined number is added or subtracted, the master node may set the number t of BAR destinations as the number of BAR destinations in the processing associated with verifying the delivery of data then execute.

In addition, in the example described above, the master node first adds a predetermined number to the currently set number t of BAR targets, and then subtracts a predetermined number, but is not necessarily limited to the above-described operation. In one example, it is obvious that the master node may first subtract a predetermined number from the currently fixed number t of BAR targets and then add a predetermined number to it.

Further, in the example described above, the master node estimates the system properties for both the number t + 1 of BAR targets after addition and the number t-1 of BAR targets after subtraction for the currently fixed number t of BARs. Aim and determines the search direction for the number of BAR goals based on the estimate result. However, it is not necessarily limited to the above-described operation. In a specific example, the master node may estimate the system properties only for either the number t + 1 at BAR destinations after addition or the number t-1 at BAR destinations after the subtraction and may change the search direction for the number of BARs. Determine goals based on the estimation result. More specifically, if the system characteristics of the number t + 1 at BAR targets after addition with respect to the currently fixed number t of BAR targets are improved, the master node may consider the increasing direction as the search direction for the number of BAR targets establish. In addition, if the system characteristics of the number t + 1 at BAR targets after the addition with respect to the currently fixed number t of BAR targets are deteriorated, the master node may consider the decreasing direction as the search direction for the number of BAR targets determine.

The features of the communication device 10 -4 according to the present embodiment are described above with reference to FIG 14 and with particular reference to the processing procedure associated with finding the number of BAR targets. As described above, in the communication system according to the present embodiment, the master node determines the search direction for the number of BAR destinations to be subsequently set in response to a change in system properties before and after updating when the number of BARs Targets between each different transmission timings of the data is updated to the slave devices. Such control allows the master node to determine whether to increase the number of BAR targets or to decrease the number of BAR targets, depending on a change in system properties corresponding to the number of BAR targets. Then, the master node estimates the system properties for each number of BAR targets and determines whether the estimation result satisfies a predetermined condition. The master node searches for the number of BAR targets whose system properties meet the predetermined condition by repeatedly executing the processing series associated with updating the number of BAR targets, estimating the system properties for each of the numbers of BAR targets, and the determining is associated with the system property estimation result as described above (ie, the processing series associated with searching for the number of BAR targets). Such a configuration enables the communication system according to the present embodiment to efficiently search for the number of BAR destinations, thereby further improving the communication quality even under circumstances where the circumstances can be significantly changed.

<Fifth Embodiment: Example of the Opportunity to Update the Number of BAR Targets>

Next, as a fifth embodiment of the present disclosure, an example of a case where the communication device 10 In one embodiment of the present disclosure, the number of BAR destinations previously set (in other words, an example of the ability to update the number of BAR destinations) is updated in one example based on the processing associated with the destination is associated with the number of BAR destinations described above as the first to fourth embodiments.

An example is 15 a flowchart showing an example of the procedure of a processing series of the communication device 10 which is the master node in the communication system according to the present embodiment, particularly by focusing on the control of the possibility of updating the number of BAR destinations.

Specially updated the communication device 10 which is the master node, if a condition for updating the predefined number of BAR destinations is satisfied (YES in S301), the number of BAR destinations by executing the processing associated with the determination of the number of BAR destinations is in accordance with any of the above-described embodiments (S320).

In a more specific example, if the master node detects a change (in particular a degradation of system properties) of system properties (or if the amount of change exceeds a threshold), the master node may perform the processing associated with updating the number of BARs. Goals is associated. In addition, in another example, if the master node receives an instruction associated with the change in the number of BAR destinations, the master node may receive from an upper layer, such as an application layer (if, for example, a System operator sets the number of BAR destinations to be changed) to perform the processing associated with updating the number of BAR destinations. In addition, in another example, if the master node receives a request to change the number of BAR destinations from a slave device that is to be part of a multicast (for example, the user who is operating a Terminal operates, the terminal to change the number of BAR destinations) performing the processing associated with updating the number of BAR destinations. In addition, in another example, the master node may perform the processing associated with updating the number of BAR destinations at a predetermined time (eg, a pre-scheduled time).

In other words, in one example, if the master node receives the instruction associated with updating the number of BAR destinations, the master node may perform the processing associated with updating the number of BAR destinations , In addition, the master node may perform the processing associated with updating the number of BAR targets at a predetermined timing. In addition, if predetermined processing is performed, the master node may include the processing associated with updating the number of BAR destinations in connection with the execution of the predetermined processing (eg, in conjunction with a predetermined event). To run.

The control as described above enables, if data is subsequently transferred (eg, multicast) to the slave device, the number of BAR destinations in an example is updated depending on the estimation result of the system characteristics at that time ,

In addition, the communication device 10 which is the master node, any of the processing associated with updating the number of BAR destinations (S320), and the processing associated with the determination of the number of BAR destinations identified above as the First to fourth embodiment is described apply. It is obvious that the method is not necessarily limited to the processing associated with the determination of the number of BAR targets described above as the first to fourth embodiments, as long as it is possible to reduce the number of BARs. To determine goals. In a specific example, the master node may observe the usage situation of a channel (in other words, the channel occupation degree) based on a carrier detection or the like, and may determine the number of BAR destinations based on the observation result.

Further, in another example, the master node may determine the number of BAR destinations depending on the communication situation (traffic situation) in the master node itself or in each of the slave devices. In addition, examples of the information indicating the communication situation on the master node side include a packet size of the traffic to be handled, a modulation-and-coding scheme (MCS), an access category (AC), a latency, a Packet loss rate, throughput or the like. In addition, examples of the information indicating the communication situation on the slave device side include the number of received packets of the traffic to be handled, the number of packets received excluding a retransmission, the latency, the packet loss rate, the throughput, the signal Noise Ratio (SINR: Signal-to-Interference Noise Ratio), the received power, the presence or absence of other traffic to be handled, or the like.

Further, in another example, the number of BAR destinations may be determined based on the information indicating the state of the slave device, such as the position, speed, acceleration, power supply state, or the like of each slave device.

Furthermore, the communication device 10 which is the master node, may be configured to be able to selectively change several different processings depending on the situation as the processing associated with the determination of the number of BAR targets. An example is 16 a flowchart showing an example of the procedure of a processing series of the communication device 10 , which is the master node in the communication system according to the present embodiment, and illustrates another mode of processing associated with updating the number of BAR destinations. At the in 16 In the illustrated example, the master node selectively switches the processing associated with the determination of the number of BAR destinations described above as the first to fourth embodiments, depending on the situation.

(Step S321)

Specifically, the master node changes to the in 16 5 illustrate, for example, the processing associated with determining the number of BAR targets, depending on whether it knows the communication environment well in and around its own cell. In addition, in one example, the situation in which the communication environment may be known in and around the own cell may be the case where the number of times of replacements of slave devices belonging to own cell is small, in the case where the number of cells other than the own cell existing in the vicinity is small (ie, if the interference influence between cells is small) or the like.

(Step S322)

In one example, if it is difficult to know the communication environment in and around the master node's own cell (NO in S321), such as in the case of the slave devices belonging to its own cell, the master node of the master node, are often replaced, or if there are many other cells in the environment (ie, if the interference between cells is large), processing capable of responding to changes in the communication environment more appropriately by the number of BARs To seek goals. Examples of the processing associated with the search of the number of BAR destinations include the processing described above as the third embodiment, the processing described as the fourth embodiment, and the like. In addition, depending on the communication quality necessary for communication with the slave device and the type of data to be transmitted to and received from the slave device, the master node may selectively switch between the processing according to third Embodiment and processing according to the fourth embodiment change.

(Step S323)

Further, if the master node knows the communication environment in and around its own cell (YES in S321), the master node selectively changes the processing associated with the determination of the number of BAR targets depending thereon whether the overheade influence is large. In addition, examples of the situation where the overhead influence is large include the case where the number of slave devices in its own cell is large, the traffic load in the own cell is large, the case where the number of others is large Cells existing in the environment are large (ie, the case where the interference influence between cells is large), the case where the traffic load in other cells existing in the environment is large, and the like.

(Step S324)

In one example, if the overhead influence is small (NO in S323), as described above, the system characteristics tend to be more satisfactory if the number of BAR targets is larger. Accordingly, in this case, the master node applies the processing described above as the second embodiment, that is, the processing of updating the number of BAR targets by subtracting and searching for the more appropriate number of BAR destinations (ie, the processing of searching for the number of BAR targets in the subtraction direction) by estimating the system properties for each number of BAR directions.

(Step S325)

Further, if the overhead influence is large (YES in S323) as described above, the system characteristics tend to be more satisfactory if the number of BAR targets is smaller. Accordingly, in this case, the master node applies the processing described above as the first embodiment, that is, the processing of updating the number of BAR destinations by adding and searching for the more appropriate number of BAR destinations (ie, the processing of searching for the number of BAR destinations in the addition direction) by estimating the system properties for each number of BAR directions (S326 and S327). In addition, in this case, the master node can selectively switch the processing associated with the system property estimation depending on whether the characteristics of each slave device are easy to predict. In addition, examples of the situation in which the characteristics of each slave device are easy to predict include a case of operating in an environment in which even the slave device is controlled in the design stage of the system, a case where the positional relationship between the master node and the slave device in the own cell is narrow (in other words, the case where the difference of communication characteristics between plural slave devices is small) and the like.

(Step S326)

Specifically, if it is difficult to predict the characteristics of each slave device (NO in S325), the master node, in one example, applies the processing described as the first embodiment, that is, the processing of collecting the measurement results of the communication characteristics of each Slave device and the estimation of the system properties based on the collected measurement results of the communication properties.

(Step S327)

In another example, if the characteristics of each slave device are easy to predict (YES in S325), the master node further uses, in one example, the processing described as the modification of the first embodiment, that is, processing of estimating the system properties based on the bitmap included in the BA transmitted from the slave device side as a response to the BAR.

An example of the case where the communication device 10 According to an embodiment of the present disclosure, the predetermined number of BAR destinations is updated in one example based on the processing described above as the first to fourth embodiments, which is associated with the determination of the number of BAR destinations (in other words, an example of the ability to update the number of BAR targets) is described above with reference to FIG 15 and 16 described. As described above, the communication device 10 According to the embodiment of the present disclosure, it may be configured to execute the processing associated with updating the number of BAR destinations in response to a predetermined condition. In addition, the communication device 10 be configured to selectively change and execute a plurality of respectively different processing methods depending on the situation as the processing associated with the determination of the number of BAR targets.

<8th Example>

The technology according to the present disclosure can be applied to various products. For example, the communication device 10 operating as a slave device, as mobile terminals, such as smart phones, tablet PCs (personal computers), notebook PCs, portable gaming terminals or digital cameras, as stationary type terminals, such as television receivers, printers, digital scanners or network memories or as vehicle-mounted terminals, such as vehicle navigation devices. In addition, the slave device may be implemented as terminals that perform M2M (machine-to-machine) communication (also referred to as MTC (Machine Type Communication) terminals) such as smart meters, vending machines Remote Monitors or Point of Sale (POS) Terminals. Further, the slave device may represent wireless communication modules mounted in such terminals (eg, integrated circuit modules configured by a die).

On the other hand, for example, the communication device 10 , which operates as a master node, can be realized as a wireless LAN access point (also referred to as a wireless base node) having a router function or having no router function. In addition, the master node can be realized as a mobile wireless LAN router. Further, the master node may also be a wireless communication module (eg, an integrated circuit module with a die) mounted on the device.

[First Application Example]

17 FIG. 10 is a block diagram showing an example of a schematic configuration of a smartphone 900 to which the technology of the present disclosure can be applied. Smartphone 900 includes processor 901, memory 902, memory 903, external connection interface 904, camera 906, sensor 907, microphone 908, input device 909, display 910, speaker 911, wireless communication interface 913, an antenna switch 914, an antenna 915, a bus 917, a battery 918, and an auxiliary controller 919.

The processor 901 may be, for example, a CPU (Central Processing Unit) or a SoC (System on Chip) system, and controls functions of an application layer and other layers of the smartphone 900. The memory 902 includes a RAM (FIG. Random Access Memory) and a ROM (Read Only Memory) and stores programs and data that are executed by the processor 901. The memory 903 may include a storage medium such as a semiconductor memory or a hard disk. The external connection interface 904 is an interface for connecting an externally mounted device such as a memory card or a Universal Serial Bus (USB) device to the smartphone 900.

The camera 906 includes an image sensor such as a CCD (Charge Coupled Device) or a CMOS (Complementary Metal Oxide Semiconductor) to produce recorded images. The sensor 907 may include a sensor array including, for example, a positioning sensor, a gyroscope sensor, a geomagnetic sensor, an acceleration sensor, and the like. The microphone 908 converts a sound input to the smartphone 900 into audio signals. The input device 909 includes, for example, a touch sensor that detects touches on a screen of the display device 910, a key pad, a keyboard, buttons, switches, and the like for receiving manipulations or information input from a user. The display device 910 has a screen such as a Liquid Crystal Display (LCD) or an OLED (Organic Light Emitting Diode) display for displaying output images of the smartphone 900. The speaker 911 converts audio signals output from the smartphone 900 into sound.

The wireless communication interface 913 supports one or more of the IEEE 802.11a, -11b, -11g, -11n, -11ac, and -11ad wireless LAN standards to perform the wireless communication. The wireless communication interface 913 may communicate with another device via a wireless LAN access point in an infrastructure mode. In addition, in a direct communication mode, such as an ad hoc mode or Wi-Fi Direct (registered trademark), the wireless communication interface 913 may communicate directly with another device. It is noted that Wi-Fi Direct is different from the ad hoc mode, and accordingly one of two terminals operates as an access point. However, communication is performed directly between the terminals. The wireless communication interface 913 may typically include a baseband processor, an RF (radio frequency) circuit, a power amplifier, and the like. The wireless communication interface 913 may be a one-chip module having a memory that supports a communication control program stores, a processor that executes the program, and a relevant circuit are integrated. The wireless communication interface 913 may support another type of wireless communication scheme, such as a cellular communication scheme, short range wireless communication scheme, or short range wireless communication scheme, in addition to the wireless LAN scheme. The antenna switch 914 changes a connection destination of the multiple circuit antenna 915 (for example, circuits for different wireless communication schemes) included in the wireless communication interface 913. The antenna 915 has a single or multiple antenna elements (eg, multiple antenna elements constituting a MIMO antenna) and is used by the wireless communication interface 913 to transmit and receive wireless signals.

It is noted that the smartphone 900 may include a plurality of antennas (eg, an antenna for a wireless LAN and an antenna for a short-range wireless communication scheme), without the example of FIG 17 to be limited. In this case, the antenna switch 914 may be omitted from the configuration of the smartphone 900.

Bus 917 connects processor 901, memory 902, memory 903, external connection interface 904, camera 906, sensor 907, microphone 908, input device 909, display 910, speaker 911, wireless communication interface 913 and the auxiliary control 919 with each other. The battery 918 provides electrical power to each of the 17 shown blocks of the smartphone 900 via power supply lines, which are partially indicated by dashed lines in the drawing. For example, the auxiliary controller 919 causes the necessary minimum functions of the smartphone 900 to be executed in a sleep mode.

At the in 17 shown smartphone 900, the data processing unit 11, the communication unit 12 and the control unit 18, with reference to 4 may be mounted in the wireless communication interface 913. Further, at least some of the functions may be mounted on the processor 901 or the auxiliary controller 919. In one example, the controller updates 18 the number of BAR goals between each different data transmission timings and searches for a more appropriate number of BAR destinations based on the system properties estimated for each number of BAR destinations. Then the control unit determines 18 in that the smartphone 900 is to be the BAR destination within the range of the number of BAR destinations determined based on the search result, and transmits the communication unit 12 the BAR only to the smartphone 900. Accordingly, it is possible to reduce the consumption of communication resources while improving the reliability of the communication.

It should be noted that the smartphone 900 can function as a wireless access point (software AP) when the processor 901 performs the function of an access point at an application level. In addition, the wireless communication interface 913 may have the function of a wireless access point.

[Second example of use]

18 FIG. 10 is a block diagram showing an example of a schematic configuration of a car navigation device 920 to which the technology of the present disclosure can be applied. The car navigation device 920 includes a processor 921, a memory 922, a Global Positioning System (GPS) module 924, a sensor 925, a data interface 926, a content player 927, a storage medium interface 928, an input device 929, a display device 930, a speaker 931, a wireless communication interface 933, an antenna switch 934, an antenna 935, and a battery 938.

The processor 921 may be, for example, a CPU or SOC that controls navigation function and other functions of the car navigation device 920. The memory 922 includes a RAM and a ROM storing data and programs to be executed by the processor 921.

The GPS module 924 measures a position of the car navigation device 920 (eg, latitude, longitude, and altitude) using GPS signals received from a GPS satellite. The sensor 925 may include a sensor array including, for example, a gyroscope sensor, a geomagnetic sensor, a barometric sensor, and the like. For example, the data interface 926 is connected to an in-vehicle network 941 via a terminal, not illustrated, to detect data generated on the vehicle side, such as vehicle speed data.

The contents player 927 reproduces a content stored in a storage medium (for example, a CD or a DVD) inserted in the storage media interface 928. The input device 929 includes, for example a touch sensor that detects touches on a screen of the display device 930, buttons, switches, and the like for receiving manipulation or information input from a user. The display device 930 has a screen, such as an LCD or OLED display, for displaying images of the navigation function or reproduced content. The speaker 931 outputs sounds of the navigation function or a reproduced content.

The wireless communication interface 933 supports one or more of the IEEE 802.11a, -11b, -11g, -11n, -11ac, and -11ad wireless LAN standards to perform wireless LAN communication. The wireless communication interface 933 may communicate with another device via a wireless LAN access point in the infrastructure mode. In addition, in a direct communication mode, such as an ad hoc mode or Wi-Fi Direct, the wireless communication interface 933 may communicate directly with another device. The wireless communication interface 933 may typically include a baseband processor, an RF circuit, a power amplifier, and the like. The wireless communication interface 933 may be a one-chip module on which a memory storing a communication control program, a processor executing the program, and a relevant circuit are integrated. The wireless communication interface 933 may support another type of wireless communication scheme, such as a short range wireless communication scheme, a short range wireless communication scheme, or the cellular communication scheme, in addition to the wireless LAN scheme. The antenna switch 934 changes a connection destination of the multi-circuit antenna 935 included in the wireless communication interface 933. The antenna 935 has a single or multiple antenna elements and is used by the wireless communication interface 933 to transmit and receive wireless signals.

It is noted that the car navigation device 920 may include a plurality of antennas without reference to the example 18 to be limited. In this case, the antenna switch 934 may be omitted from the configuration of the car navigation device 920.

The battery 938 provides electrical power to each of the 18 shown blocks of the car navigation device 920 via power supply lines, which are partially indicated by dashed lines in the drawing. In addition, the battery 938 accumulates electric power supplied from the vehicle.

At the in 18 The vehicle navigation device 920 shown in FIG. 2 may include the data processing unit 11, the communication unit 12 and the control unit 18 referring to 4 may be mounted in the wireless communication interface 933. Further, at least some of the functions may be mounted on the processor 921. In one example, the controller updates 18 the number of BAR goals between each different data transmission timings and searches for a more appropriate number of BAR destinations based on the system properties estimated for each number of BAR destinations. Then the control unit determines 18 in that the car navigation device 920 is to be the BAR destination within the range of the number of BAR destinations that is determined based on the search result, and transmits the communication unit 12 Accordingly, it is possible to reduce the consumption of communication resources while improving the reliability of the communication.

Further, the wireless communication interface 933 may be used as the communication device 10 which is the master node described above, and can provide a wireless connection to a user's terminal in the vehicle. In this event, the control unit updates 18 in one example, the number of BAR targets between each different data transmission timings and searches for a more appropriate number of BAR targets based on the system properties estimated for each number of BAR targets. Then the control unit determines 18 in that another communication device is to be the BAR destination within the range of the number of BAR destinations determined based on the search result, and transmits the communication unit 12 the BAR only to the other communication device. This makes it possible to reduce the consumption of communication resources while improving the reliability of the communication.

Further, the technology of the present disclosure may be implemented as an in-vehicle system (or vehicle) 940 including one or more blocks of the above-described vehicle navigation device 920, an in-vehicle network 941, and a vehicle-side module 942. The on-vehicle module 942 generates on-vehicle data such as a vehicle speed, the number of engine revolutions or error information, and outputs the generated data to the in-vehicle network 941.

[Third Application Example]

19 FIG. 10 is a block diagram showing an example of a schematic configuration of a wireless access point 950 to which the technology of the present disclosure may be applied. The wireless access point 950 includes a controller 951, a memory 952, an input device 954, a display device 955, a network interface 957, a wireless communication interface 963, an antenna switch 964, and an antenna 965.

The controller 951 may be, for example, a CPU or a digital signal processor (DSP) and performs various functions (e.g., access restriction, routing, encryption, firewall, and log management) of the Internet Protocol (IP) layer and higher layers of the wireless access point 950 to be operated. The memory 952 includes a RAM and a ROM, and stores a program executed by the controller 951 and various types of control data (for example, a terminal list, a routing table, an encryption key, security settings, and a log).

The input device 954 includes, for example, a button or switch and receives manipulation from a user. The display device 955 includes an LED lamp and indicates an operation status of the wireless access point 950.

The network interface 957 is a wired communication interface that connects the wireless access point 950 to a wired communication network 958. The network interface 957 may include multiple connection terminals. The wired communication network 958 may be a LAN such as an Ethernet (Registered Trade Mark) or a Wide Area Network (WAN).

The wireless communication interface 963 supports one or more of the IEEE 802.11a, -11b, -11g, -11n, -11ac, and -11ad wireless LAN standards to support a wireless connection to a nearby terminal as an access point. The wireless communication interface 963 may typically include a baseband processor, an RF circuit, and a power amplifier. The wireless communication interface 963 may be a one-chip module in which a memory for storing a communication control program, a processor executing the program, and relevant circuits are integrated. The antenna switch 964 changes a connection destination of the antenna 965 among a plurality of circuits included in the wireless communication interface 963. The antenna 965 includes one or more antenna elements and is used to transmit and receive a wireless signal through the wireless communication interface 963.

At the in 19 The wireless access point 950 may include the data processing unit 11, the communication unit 12 and the control unit 18, with reference to 5 may be mounted on the wireless communication interface 963. Further, at least some of the functions may be mounted on the controller 951. In one example, the controller updates 18 the number of BAR goals between each different data transmission timings and searches for a more appropriate number of BAR destinations based on the system properties estimated for each number of BAR destinations. Then the control unit determines 18 in that another communication device is to be the BAR destination within the range of the number of BAR destinations determined based on the search result, and transmits the communication unit 12 the BAR only to the other communication device. This makes it possible to reduce the consumption of communication resources while improving the reliability of the communication.

<Conclusion>

As described above, according to the first embodiment of the present disclosure, even in a situation where the communication state between the master node and each slave device changes, it is possible to improve the reliability in a more preferable mode and the consumption of communication resources to reduce. In particular, according to the first embodiment, in circumstances where the overhead influence is greater, such as when multiple slave devices are present in the cell or if another cell is around the cell is around, which is controlled by the master node, and a disturbance amount between them is large, it is possible for the master node to efficiently search for the more appropriate number of BAR targets. In addition, it is possible for the master node to further improve the accuracy associated with the system measurement estimation by controlling the number of slave devices so that the number of slave devices from which the communication feature information is collected , is increased.

Further, according to the second embodiment of the present disclosure, under circumstances where the overhead influence is smaller, such as when the number of slave devices in the cell is small or if there is no cell around the cell, that is through the master Node is controlled, and a disturbance amount between them is large, it is possible for the master node to efficiently search for the more appropriate number of BAR destinations.

Further, according to the third embodiment of the present disclosure, in environments where the circumstances can be greatly changed (in other words, if it is difficult to predict the environment), such as if the replacement frequency of slave devices in the cell is high It is possible for the master node to efficiently search for the more appropriate number of BAR destinations. In other words, according to the third embodiment of the present embodiment, it is possible for the master node to search for the number of BAR destinations that is more appropriate for a change of the communication environments.

Further, according to the fourth embodiment of the present disclosure, it is possible for the master node to determine whether to increase the number of BAR destinations or to increase the number depending on a change in system characteristics corresponding to the number of BAR destinations reduced at BAR goals. Accordingly, it is possible for the master node to efficiently search for the number of BAR destinations for which the communication quality is further improved, even in environments where the circumstances can be greatly changed.

Further, the master node according to the fifth embodiment of the present disclosure may be configured to execute the processing associated with updating the number of BAR destinations in response to a predetermined condition. Such a configuration makes it possible, even in the situation that various circumstances are changed, such as changes in the system, that the master node selectively updates the number of BAR targets depending on the change of the situation. In addition, the master node may be configured to selectively switch and execute a plurality of respectively different processing methods depending on the situation as the processing associated with the determination of the number of BAR targets. Such a configuration allows the master node to search for the more appropriate number of BAR targets based on the more appropriate processing (eg, more efficient processing) in response to a change in the situation.

Although the preferred embodiments of the present disclosure have been described in detail with reference to the accompanying drawings, the technical scope of the present disclosure is not limited to such examples. It will be understood that one of ordinary skill in the art can devise various modifications or that modifications within the scope of the technical idea described in the claims are, of course, understood to be within the technical scope of the present disclosure.

In addition, the effects described in this specification are merely illustrative or exemplary and are not limiting. That is, the technique according to the present disclosure may demonstrate other effects that will become apparent to those skilled in the art from the description of the present specification, along with the above-described effects or effects.

1. (1) Eine Kommunikationssteuervorrichtung, die Folgendes beinhaltet:
   • eine Steuereinheit, die dazu konfiguriert ist, eine Kommunikation mit einer Kommunikationsvorrichtung, die über einen Drahtloskommunikationspfad verbunden ist, zu steuern; und
   • eine Erfassungseinheit, die dazu konfiguriert ist, Informationen hinsichtlich der Kommunikation mit einer oder mehreren der Kommunikationsvorrichtungen zu erfassen,
   • wobei die Steuereinheit eine Anzahl der Kommunikationsvorrichtungen, an die eine Übertragungsanforderung für eine Antwort zum Bestätigen einer Lieferung von Daten an die Kommunikationsvorrichtung übertragen wird, basierend auf den erfassten Informationen hinsichtlich der Kommunikation bestimmt.
2. (2) Die Kommunikationssteuervorrichtung nach (1), wobei die Steuereinheit, falls die Daten dazu gesteuert werden, an mehrere Kommunikationsvorrichtungen übertragen zu werden, die Anzahl der Kommunikationsvorrichtungen, an die die Übertragungsanforderung übertragen wird, basierend auf erfassten Informationen hinsichtlich der Kommunikation mit den mehreren der Kommunikationsvorrichtungen bestimmt.
3. (3) Die Kommunikationssteuervorrichtung nach (1) oder (2), wobei die Steuereinheit die Anzahl an Kommunikationsvorrichtungen, an die die Übertragungsanforderung zwischen mehreren jeweils unterschiedlichen Übertragungstimings der Daten übertragen wird, ändert und die Anzahl der Kommunikationsvorrichtungen, an die die Übertragungsanforderung anschließend übertragen wird, basierend auf erfassten Informationen hinsichtlich der Kommunikation, die jeder der Anzahl an Kommunikationsvorrichtungen entspricht, bestimmt.
4. (4) Die Kommunikationssteuervorrichtung nach (3), wobei die Steuereinheit die Anzahl an Kommunikationsvorrichtungen durch Addieren der Anzahl an Kommunikationsvorrichtungen, an die die Übertragungsanforderung übertragen wird, ändert.
5. (5) Die Kommunikationssteuervorrichtung nach (3), wobei die Steuereinheit die Anzahl an Kommunikationsvorrichtungen durch Subtrahieren der Anzahl an Kommunikationsvorrichtungen, an die die Übertragungsanforderung übertragen wird, ändert.
6. (6) Die Kommunikationssteuervorrichtung nach (3), wobei die Steuereinheit die Anzahl der Kommunikationsvorrichtungen auf eine solche Weise ändert, dass jeweils unterschiedliche Zahlen zwischen den mehreren Übertragungstimings als die Anzahl der Kommunikationsvorrichtungen, an die die Übertragungsanforderung übertragen wird, festgelegt werden.
7. (7) Die Kommunikationssteuervorrichtung nach (6), wobei die Steuereinheit die Anzahl der Kommunikationsvorrichtungen durch zufälliges Festlegen einer Zahl, die nicht zuvor festgelegt ist, als die Anzahl der Kommunikationsvorrichtungen, an die die Übertragungsanforderung übertragen wird, ändert.
8. (8) Die Kommunikationssteuervorrichtung nach (6), wobei die Steuerung die Anzahl der Kommunikationsvorrichtungen durch Suchen nach einer Anzahl der Kommunikationsvorrichtungen, die neu festzulegen sind, basierend auf einer zuvor festgelegten Anzahl der Kommunikationsvorrichtungen, an die die Übertragungsanforderung übertragen wird, ändert.
9. (9) Die Kommunikationssteuervorrichtung nach (3), wobei die Steuereinheit die Anzahl der Kommunikationsvorrichtungen, an die die Übertragungsanfrage anschließend übertragen wird, basierend auf einer Änderung zwischen Informationen hinsichtlich der Kommunikation bestimmt, die vor und nach der Änderung der Anzahl an Kommunikationsvorrichtungen, an die die Übertragungsanforderung übertragen wird, erfasst werden.
10. (10) Die Kommunikationssteuervorrichtung nach (9), wobei die Steuereinheit eine Richtung, in die die Anzahl der Kommunikationsvorrichtungen, an die die Übertragungsanfrage anschließend übertragen wird, geändert wird, basierend auf einer Richtung der Änderung zwischen Informationen hinsichtlich der Kommunikation bestimmt, die vor und nach der Änderung der Anzahl an Kommunikationsvorrichtungen, an die die Übertragungsanforderung übertragen wird, erfasst werden.
11. (11) Die Kommunikationssteuervorrichtung nach einem von (1) bis (10), wobei die Erfassungseinheit die Informationen, hinsichtlich der Kommunikation von der Kommunikationsvorrichtung erfasst.
12. (12) Die Kommunikationssteuervorrichtung nach (11), wobei die Erfassungseinheit Informationen hinsichtlich einer Kommunikationseigenschaft, die durch die Kommunikationsvorrichtung gemessen wird, als die Informationen hinsichtlich der Kommunikation von der Kommunikationsvorrichtung erfasst.
13. (13) Die Kommunikationssteuervorrichtung nach einem von (1) bis (10), wobei die Erfassungseinheit Informationen hinsichtlich der Antwort von der Kommunikationsvorrichtung auf die Übertragungsanforderung, wenn eine Lieferung der Daten zuvor bestätigt wird, als die Informationen hinsichtlich der Kommunikation erfasst.
14. (14) Die Kommunikationssteuervorrichtung nach einem von (1) bis (13), wobei die Steuereinheit, falls eine vorbestimmte Bedingung zum Ändern der Anzahl an Kommunikationsvorrichtungen, an die die Übertragungsanforderung übertragen wird, erfüllt wird, die Anzahl der Kommunikationsvorrichtungen, an die die Übertragungsanfrage anschließend übertragen wird, basierend auf den erfassten Informationen hinsichtlich der Kommunikation bestimmt.
15. (15) Die Kommunikationssteuervorrichtung nach einem von (1) bis (14), wobei die Steuereinheit eine Verarbeitung zum Bestimmen der Anzahl der Kommunikationsvorrichtungen, an die die Übertragungsanforderung übertragen wird, in Abhängigkeit von einer Kommunikationsumgebung mit der Kommunikationsvorrichtung wechselt.
16. (16) Eine Kommunikationssteuervorrichtung, die Folgendes beinhaltet:
    • eine Erfassungseinheit, die dazu konfiguriert ist, falls eine Kommunikationsvorrichtung, die über einen Drahtloskommunikationspfad verbunden ist, als ein Übertragungsziel einer Übertragungsanforderung für eine Antwort zum Bestätigen einer Lieferung von Daten basierend auf erfassten Informationen hinsichtlich einer Kommunikation bestimmt wird, die Übertragungsanforderung, die von der Kommunikationsvorrichtung übertragen wird, zu erfassen; und
    • eine Steuereinheit, die dazu konfiguriert ist, die Antwort, die einer Empfangssituation der Daten entspricht, auf die erfasste Übertragungsanforderung, die an die Kommunikationsvorrichtung zu übertragen ist, zu steuern.
17. (17) Die Kommunikationssteuervorrichtung nach (16), wobei die Steuereinheit eine Steuerung auf eine solche Weise durchführt, dass Informationen hinsichtlich einer Eigenschaft einer Kommunikation mit der Kommunikationsvorrichtung an die Kommunikationsvorrichtung als die Informationen hinsichtlich der Kommunikation basierend auf einer Anforderung von der Kommunikationsvorrichtung übertragen werden.
18. (18) Ein Kommunikationssteuerverfahren, das durch einen Prozessor auszuführen ist, wobei das Verfahren Folgendes beinhaltet:
    • Steuern einer Kommunikation mit einer Kommunikationsvorrichtung, die über einen Drahtloskommunikationspfad verbunden ist;
    • Erfassen von Informationen hinsichtlich der Kommunikation mit einer oder mehreren der Kommunikationsvorrichtungen; und
    • Bestimmen einer Anzahl der Kommunikationsvorrichtungen, an die eine Übertragungsanforderung für eine Antwort zum Bestätigen einer Lieferung von Daten an die Kommunikationsvorrichtung übertragen wird, basierend auf den erfassten Informationen hinsichtlich der Kommunikation.
19. (19) Ein Kommunikationssteuerverfahren, das Folgendes beinhaltet:
    • Erfassen der Übertragungsanforderung, die von der Kommunikationsvorrichtung übertragen wird, falls eine Kommunikationsvorrichtung, die über einen Drahtloskommunikationspfad verbunden ist, als ein Übertragungsziel einer Übertragungsanforderung für eine Antwort zum Bestätigen einer Lieferung von Daten basierend auf erfassten Informationen hinsichtlich einer Kommunikation bestimmt wird; und
    • Steuern der Antwort, die einer Empfangssituation der Daten entspricht, auf die erfasste Übertragungsanforderung, die an die Kommunikationsvorrichtung zu übertragen ist, durch einen Prozessor.
20. (20) Ein Programm, das bewirkt, dass ein Computer Folgendes ausführt:
    • Steuern einer Kommunikation mit einer Kommunikationsvorrichtung, die über einen Drahtloskommunikationspfad verbunden ist;
    • Erfassen von Informationen hinsichtlich der Kommunikation mit einer oder mehreren der Kommunikationsvorrichtungen; und
    • Bestimmen einer Anzahl der Kommunikationsvorrichtungen, an die eine Übertragungsanforderung für eine Antwort zum Bestätigen einer Lieferung von Daten an die Kommunikationsvorrichtung übertragen wird, basierend auf den erfassten Informationen hinsichtlich der Kommunikation.

In addition, the present technology may also be configured as described below.

1. (1) A communication control device including:
   • a control unit configured to control communication with a communication device connected via a wireless communication path; and
   • a detection unit configured to acquire information regarding communication with one or more of the communication devices,
   • wherein the control unit determines a number of the communication devices to which a transmission request for a response for confirming a delivery of data is transmitted to the communication device, based on the detected information regarding the communication.
2. (2) The communication control apparatus according to (1), wherein the control unit, if the data is controlled to be transmitted to a plurality of communication devices, the number of the communication devices to which the transmission request is transmitted based on detected information regarding the communication with the plurality the communication devices determined.
3. (3) The communication control apparatus according to (1) or (2), wherein the control unit changes the number of communication devices to which the transmission request is transmitted between a plurality of respectively different transmission timings of the data and the number of communication devices to which the transmission request is subsequently transmitted , based on recorded Information regarding the communication corresponding to each of the number of communication devices is determined.
4. (4) The communication control apparatus according to (3), wherein the control unit changes the number of communication devices by adding the number of communication devices to which the transmission request is transmitted.
5. (5) The communication control apparatus according to (3), wherein the control unit changes the number of communication devices by subtracting the number of communication devices to which the transmission request is transmitted.
6. (6) The communication control apparatus according to (3), wherein the control unit changes the number of the communication devices in such a manner that respectively different numbers between the plurality of transmission timings are set as the number of communication devices to which the transmission request is transmitted.
7. (7) The communication control apparatus according to (6), wherein the control unit changes the number of the communication devices by randomly setting a number not previously set as the number of communication devices to which the transmission request is transmitted.
8. (8) The communication control apparatus according to (6), wherein the controller changes the number of the communication devices by searching for a number of the communication devices to be redefined based on a predetermined number of the communication devices to which the transmission request is transmitted.
9. (9) The communication control apparatus according to (3), wherein the control unit determines the number of the communication devices to which the transmission request is subsequently transmitted based on a change between information regarding the communication before and after the change of the number of communication devices to which the transfer request is transmitted.
10. (10) The communication control apparatus according to (9), wherein the control unit determines a direction in which the number of the communication devices to which the transmission request is subsequently transmitted is determined based on a direction of change between information regarding the communication before and after changing the number of communication devices to which the transmission request is transmitted.
11. (11) The communication control apparatus according to any one of (1) to ( 10 ), wherein the detection unit detects the information relating to the communication from the communication device.
12. (12) The communication control apparatus according to (11), wherein the detection unit acquires information regarding a communication characteristic measured by the communication device as the information regarding the communication from the communication device.
13. (13) The communication control apparatus according to any one of (1) to ( 10 ), wherein the detection unit acquires information regarding the response from the communication device to the transmission request when a delivery of the data is previously confirmed as the information regarding the communication.
14. (14) The communication control apparatus according to any one of (1) to ( 13 ), wherein, if a predetermined condition for changing the number of communication devices to which the transmission request is transmitted is satisfied, the control unit determines the number of the communication devices to which the transmission request is subsequently transmitted based on the detected information regarding the communication.
15. (15) The communication control apparatus according to any one of (1) to ( 14 ), wherein the control unit switches processing for determining the number of communication devices to which the transmission request is transmitted, in response to a communication environment with the communication device.
16. (16) A communication control device including:
    • a detection unit configured to, if a communication device connected via a wireless communication path, confirm as a transmission destination of a transmission request for a response a delivery of data based on detected information regarding communication is determined to detect the transmission request transmitted from the communication device; and
    • a control unit configured to control the response corresponding to a reception situation of the data to the detected transmission request to be transmitted to the communication apparatus.
17. (17) The communication control apparatus according to ( 16 ), wherein the control unit performs control in such a manner that information regarding a characteristic of communication with the communication device is transmitted to the communication device as the information regarding the communication based on a request from the communication device.
18. (18) A communication control method to be executed by a processor, the method including:
    • Controlling communication with a communication device connected via a wireless communication path;
    • Acquiring information regarding the communication with one or more of the communication devices; and
    • Determining a number of the communication devices to which a transmission request for a response for confirming a delivery of data is transmitted to the communication device based on the acquired information regarding the communication.
19. (19) A communication control procedure that includes:
    • Detecting the transmission request transmitted from the communication device if a communication device connected via a wireless communication path is determined as a transmission destination of a transmission request for a response for confirming a delivery of data based on detected information regarding communication; and
    • Controlling, by a processor, the response corresponding to a reception situation of the data to the detected transmission request to be transmitted to the communication apparatus.
20. (20) A program that causes a computer to do the following:
    • Controlling communication with a communication device connected via a wireless communication path;
    • Acquiring information regarding the communication with one or more of the communication devices; and
    • Determining a number of the communication devices to which a transmission request for a response for confirming a delivery of data is transmitted to the communication device based on the acquired information regarding the communication.

LIST OF REFERENCE NUMBERS

10, 10-1 to 10-5

communication device

12

communication unit

13

Modulation and demodulation unit

14

Signal processing unit

15

Channel estimation unit

16

Wireless interface unit

17

amplification unit

18

control unit

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2014053832 A [0004]

Claims (20)

A communication control device comprising: a control unit configured to control communication with a communication device connected via a wireless communication path; and a detection unit configured to acquire information regarding communication with one or more of the communication devices, wherein the control unit determines a number of the communication devices to which a transmission request for a response for confirming a delivery of data is transmitted to the communication device, based on the detected information regarding the communication. Communication control device after Claim 1 wherein, if the data is controlled to be transmitted to a plurality of communication devices, the control unit determines the number of communication devices to which the transmission request is transmitted based on detected information regarding the communication with the plurality of communication devices. Communication control device after Claim 1 wherein the control unit changes the number of communication devices to which the transmission request is transmitted between a plurality of respectively different transmission timings of the data and the number of communication devices to which the transmission request is subsequently transmitted based on detected information regarding the communication corresponding to each of the numbers corresponds to communication devices determined. Communication control device after Claim 3 wherein the control unit changes the number of the communication devices by adding the number of the communication devices to which the transmission request is transmitted. Communication control device after Claim 3 wherein the control unit changes the number of the communication devices by subtracting the number of the communication devices to which the transmission request is transmitted. Communication control device after Claim 3 wherein the control unit changes the number of the communication devices in such a manner that respectively different numbers between the plurality of transmission timings are set as the number of the communication devices to which the transmission request is transmitted. Communication control device after Claim 6 wherein the control unit changes the number of the communication devices by randomly setting a number not previously set as the number of communication devices to which the transmission request is transmitted. Communication control device after Claim 6 wherein the controller changes the number of the communication devices by searching for a number of the communication devices to be redefined based on a predetermined number of the communication devices to which the transmission request is transmitted. Communication control device after Claim 3 wherein the control unit determines the number of communication devices to which the transmission request is subsequently transmitted based on a change between information regarding the communication detected before and after the change of the number of the communication devices to which the transmission request is transmitted. Communication control device after Claim 9 wherein the control unit determines a direction in which the number of communication devices to which the transmission request is subsequently transmitted is changed based on a direction of change between information regarding communication before and after the change of the number of the communication devices which the transfer request is transmitted. Communication control device after Claim 1 wherein the detection unit detects the information regarding the communication from the communication device. Communication control device after Claim 11 wherein the detection unit acquires information regarding a communication property measured by the communication device as the information regarding the communication from the communication device. Communication control device after Claim 1 wherein the detection unit acquires information regarding the response from the communication device to the transmission request when a delivery of the data is previously confirmed as the information regarding the communication. Communication control device after Claim 1 wherein, if a predetermined condition for changing the number of the communication devices to which the transmission request is transmitted is satisfied, the control unit determines the number of the communication devices to which the transmission request is subsequently transmitted based on the detected information regarding the communication. Communication control device after Claim 1 wherein the control unit switches processing for determining the number of communication devices to which the transmission request is transmitted, in response to a communication environment with the communication device. A communication control device comprising: a detection unit configured to determine, if a communication device connected via a wireless communication path as a transmission destination of a transmission request for a response for confirming a delivery of data based on detected information regarding communication, the transmission request sent from the communication device is transmitted; and a control unit configured to control the response corresponding to a reception situation of the data to the detected transmission request to be transmitted to the communication apparatus. Communication control device after Claim 16 wherein the control unit performs control in such a manner that information regarding a characteristic of communication with the communication device is transmitted to the communication device as the information regarding the communication based on a request from the communication device. A communication control method to be executed by a processor, the method comprising: Controlling communication with a communication device connected via a wireless communication path; Acquiring information regarding the communication with one or more of the communication devices; and Determining a number of the communication devices to which a transmission request for a response for confirming a delivery of data is transmitted to the communication device based on the acquired information regarding the communication. A communication control method comprising: Detecting the transmission request transmitted from the communication device if a communication device connected via a wireless communication path is determined as a transmission destination of a transmission request for a response for confirming a delivery of data based on detected information regarding communication; and Controlling, by a processor, the response corresponding to a reception situation of the data to the detected transmission request to be transmitted to the communication apparatus. Program that causes a computer to do the following: Controlling communication with a communication device connected via a wireless communication path; Acquiring information regarding the communication with one or more of the communication devices; and Determining a number of the communication devices to which a transmission request for a response for confirming a delivery of data is transmitted to the communication device based on the acquired information regarding the communication.

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