JP2007104039A - Communication apparatus, control server, and communication system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a communication apparatus capable of improving communication efficiency without any useless transmission line communication evaluation. <P>SOLUTION: The communication apparatus comprises: a transmission result storage section 10 at which transmission parameters are registered; a frame configuration section 1 that refers to inherent information 12 containing the inherent ID (Identification) of its own device, and that of the communication device installed near via a transmission line 15, and transmits information for inquiring the transmission parameters with its own device to the nearby communication device; and an instruction reception section 14 that registers the transmission parameters transmitted according to inquiry information from its own device at the transmission result storage section 10, and retrieves the transmission result storage section 10 according to an inquiry to its own device for returning corresponding transmission parameters to the communication device of an inquiry source. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a communication device that shares optimal transmission parameters among communication devices that perform data transmission by, for example, power line communication, a management server that manages and manages transmission parameters of the communication devices, and a communication system including these. is there.

  As a conventional communication apparatus using power line communication, for example, there is a power line communication apparatus disclosed in Patent Document 1. This communication device has a transmission result storage means for storing and storing transmission results for each transmission partner at the time of data transmission, and performs calculation using evaluation points corresponding to the stored past transmission results. The quality of the data transmission path is evaluated based on the result. In addition, efficient data transfer is realized by obtaining an average score from a plurality of past transmission results, calculating an evaluation score by weighting with an elapsed time, and setting transmission parameters based on these scores.

  In this way, by evaluating the quality of the data transmission path according to the past transmission results, for example, the periodicity of the communication environment to be used such that the noise generation situation at the same time on different days is the same, although it changes with time. In a kind of steady state in which various changes are repeated, noise countermeasures can be effectively taken.

JP 2000-147331 A

  In conventional communication devices, if there is a situation in which sudden noise occurs or a situation in which noise occurs randomly, unnecessary transmission results cannot be set due to the effects of noise. Remembered. For this reason, useless transmission path communication evaluation will be performed by the amount corresponding to the transmission result.

  Further, even when data communication is performed with a communication device located in the vicinity of the noise source, an unnecessary transmission result in which an optimum transmission parameter cannot be set due to the influence of noise is stored in the transmission result storage unit. Therefore, by referring to such unnecessary past transmission results, there is a possibility that erroneous transmission parameters that do not apply to the actual communication situation are set. In this case, when viewed from the whole communication system, a data error occurs due to data transmission with an inappropriate transmission parameter, and data retransmission or the like is performed on the data error, thereby degrading transmission efficiency.

  Furthermore, when past unnecessary transmission results are stored in the transmission result storage means, transmission of transmission data is evaluated including the above-mentioned unnecessary transmission results until optimum transmission parameters are determined when data is transmitted. For this reason, it is necessary to repeat the evaluation based on the past transmission results before reaching the optimum transmission parameter, which takes unnecessary effort.

  In addition, conventionally, information such as optimal transmission parameters acquired through such efforts is not shared with other communication devices, so that communication devices located in the vicinity also take similar efforts. Transmission parameters must be determined. In such a case, even if the number of communication devices is small, or even if the number of communication devices is large, they are equally distributed and loosely coupled, so that there is little problem in communication efficiency. However, the communication efficiency deteriorates as the number of communication devices is large and a plurality of communication devices are tightly coupled in some places.

  The present invention has been made in order to solve the above-described problems, and grasps other communication devices arranged in the vicinity of the own device based on unique identification information capable of uniquely specifying each communication device, and the communication device. By sharing the optimal transmission parameters determined by the transmission path communication evaluation among the communication apparatuses, the communication parameters that can improve the communication efficiency without performing unnecessary transmission path communication evaluation, the transmission parameters of a plurality of communication apparatuses It is an object of the present invention to obtain a management server that performs overall management, and a communication system including these.

  A communication apparatus according to the present invention relates to a parameter storage unit in which a transmission parameter that defines data transmission conditions is registered, and a communication apparatus installed in the vicinity of the own apparatus via a transmission path, with respect to communication with the own apparatus. A parameter request unit that inquires about the presence or absence of transmission parameters and a transmission parameter that is transmitted in response to an inquiry from the own device are registered in the parameter storage unit, and the parameter storage unit is searched in response to an inquiry to the own device. And a parameter sharing processing unit that returns a transmission parameter to the inquiring communication device.

  According to the present invention, since transmission parameters are inquired between the own device and a communication device in the vicinity thereof and the transmission parameters are shared with each other in response to the inquiry, useless transmission path communication evaluation can be omitted. There is an effect that the efficiency can be improved.

Embodiment 1 FIG.
FIG. 1 is a block diagram showing a configuration of a communication apparatus according to Embodiment 1 of the present invention, and shows an example in which the present invention is applied to a power line communication apparatus. In the figure, a frame configuration unit (parameter request unit) 1 configures an information frame including input transmission data based on transmission parameters. The transmission parameter is a parameter that defines data transmission conditions between communication devices. For example, the length of information frames, the maximum number of continuous information frames that can be transmitted continuously without waiting for a response from the receiving side. And so on. Further, the transmission parameter is optimized based on the quality of the transmission path 15 between the communication devices.

  The error detection code adding unit 2 calculates an error detection code for each information frame configured by the frame configuration unit 1, and configures an information frame in which the error detection code is incorporated into the information frame. The modulation unit 3 modulates the information frame to which the error detection code adding unit 2 has added the error detection code, and outputs the modulated signal to the power line coupling unit 4. In addition, the modulation unit 3 outputs a timing signal to the no-response determination unit 5 when the modulation of one information frame is completed.

  The power line coupling unit 4 is connected to a transmission line 15 made of a power line, and superimposes the modulation signal modulated by the modulation unit 3 on the transmission line 15. In addition, the power line coupling unit 4 extracts the modulation signal superimposed on the transmission path 15 and outputs it to the demodulation unit 6. Based on the output of the demodulated signal from the demodulating unit 6, the no-response determining unit 5 determines whether or not there is a response frame from the receiving side with respect to the transmission of the information frame for a certain time from the input timing signal of the modulating unit 3. judge.

  The demodulation unit 6 demodulates the modulation signal input from the power line coupling unit 4 and reproduces a response frame from the reception side. The error detector 7 receives the information frame demodulated by the demodulator 6 and detects an error in the data of the information frame. If the error detection unit 7 does not detect an error in the data included in the information frame, the reception content analysis unit 8 analyzes the content of the information frame and receives data indicating the analysis result from the transmission result storage unit 10 and the instruction reception. To the unit 14.

  For example, as in Patent Document 1, the transmission control unit 9 continuously transmits information at a time based on the quality of the transmission line 15 from the transmission line state determination unit 11 without waiting for an information frame length or a response from the reception side. A transmission parameter indicating the maximum number of continuous information frames that can be determined is determined and output to the frame configuration unit 1. For example, if the quality of the transmission line 15 is good, it can be transmitted without any trouble even if the length of the information frame to be transmitted at a time is increased. If the quality of the transmission line 15 is deteriorated, it is transmitted at a time. Corresponding to possible communication failures by shortening the length of the information frame.

  Further, for example, as in Patent Document 1, an error in data is detected by the error detection unit 7, no response is determined by the no response determination unit 5, and a negative response of the response frame is extracted by the received content analysis unit 8. Then, the transmission control unit 9 outputs data for resending the transmission data to the frame configuration unit 1. In response to this, the frame configuration unit 1 configures an information frame including transmission data that has already been transmitted at least once based on the transmission parameter from the transmission control unit 9, and outputs this information frame to the modulation unit 3. And resend.

  In particular, in the transmission control unit 9 of the present invention, when transmitting data to another communication device, as described later, the optimum transmission parameter transmitted from a nearby communication device in response to an inquiry and the patent document as described above. 1, the transmission parameter determined based on the quality of the transmission line 15 from the transmission line state determination unit 11 is selected and set in the frame configuration unit 1.

  The transmission result storage unit (parameter storage unit) 10 is a calculation result indicating whether or not there is an error in the data frame in the information frame from the error detection unit 7, and the information frame for a certain period or a certain number of transmissions from the received content analysis unit 8. Data indicating the contents and data indicating no response from the no response determination unit 5 are stored as a transmission result.

  The transmission result storage unit 10 of the present invention also registers the optimum transmission parameters transmitted from nearby communication devices in response to an inquiry as will be described later. The transmission path state determination unit 11 determines the quality of the transmission path 15 as a data transmission path by using a past transmission result stored in the transmission result storage unit 10 by, for example, the same method as in Patent Document 1.

  The unique information 12 is identification information for uniquely identifying the own device, and identification for uniquely identifying another communication device according to the present invention installed in the vicinity of the own device via the transmission path 15. For example, a unique ID for each communication device is conceivable. The unique ID may be a MAC address for each communication device or a non-overlapping numerical value separately defined for each communication device.

  The unique ID may be set as electronic information that is read and processed by an arithmetic processing unit of a computer that embodies each communication device. In this case, for example, a unique ID setting program is executed by an arithmetic processing unit of a computer that embodies the communication apparatus to receive the unique ID setting, and the unique ID input to the computer is set accordingly. Furthermore, hardware such as a DIP switch may be used, and each switch may be set in association with its own device and a nearby communication device.

  FIG. 2 is a diagram schematically illustrating an example of unique information according to the first embodiment. In the illustrated example, “9” is set as the unique ID in the unique information 12a of the own device, and “1”, “2”, and the unique IDs in the unique information 12b, 12c, and 12d of the communication devices installed in the vicinity. “3” is set. In other words, the communication devices having the unique IDs in the unique information 12a to 12d are arranged in the vicinity where the communication environment (such as the occurrence of noise) on the transmission path 15 will be substantially the same.

  The information transfer unit 13 searches the unique information 12 to determine whether there is a nearby communication device, and when there is a nearby communication device, reads the unique ID from the unique information 12 and outputs it to the frame configuration unit 1 To do. In the frame configuration unit 1, an information frame of inquiry information including the unique ID of the destination communication device acquired from the information transfer unit 13 is configured and transmitted to the communication device via the modulation unit 3.

  In response to an inquiry about a transmission parameter from another communication device, the instruction receiving unit (parameter sharing processing unit) 14 determines whether or not the transmission result storage unit 10 has a transmission parameter communicated with the communication device in the past. Search for. If there is a transmission parameter corresponding to the inquiry, the instruction receiving unit 14 calls the transmission parameter from the transmission result storage unit 10 and returns it to the inquiry source communication device.

Next, the operation will be described.
The present invention is characterized by a process for setting an optimum transmission parameter obtained by inquiring another communication apparatus for data transmission. This process will be mainly described.
In the conventional communication device disclosed in Patent Document 1, the transmission result is accumulated in the transmission result storage unit 10 for each transmission process, and the transmission line state determination unit 11 determines the quality of the transmission line using this accumulated information. . Based on the transmission parameters determined by the transmission control unit 9 based on the determination result, the frame configuration unit 1 configures an information frame, and the transmission path is transmitted via the error detection code addition unit 2, the modulation unit 3, and the power line coupling unit 4. Was sent out. On the other hand, in the first embodiment, it is possible to refer to the optimum transmission parameters acquired from other communication devices arranged in the vicinity as described later.

  FIG. 3 is a flowchart showing a flow of transmission parameter inquiry processing of the communication apparatus according to the first embodiment. First, when the transmission data specifying the transmission destination communication device is input, the frame configuration unit 1 performs normal transmission processing (for example, past transmission shown in Patent Document 1 in accordance with the bit value set in the header portion). (Transmission with transmission parameters determined according to the result)) or a process for inquiring a neighboring communication device for an optimal transmission parameter is selected. For example, a bit value corresponding to each of the above-described processes is set in predetermined bits in the header portion of the transmission data, and the frame configuration unit 1 selects the process by referring to the bit value when the transmission data is input.

  Here, when a process for inquiring a nearby communication device for an optimal transmission parameter for transmission data is designated, the frame configuration unit 1 notifies the information transfer unit 13 to that effect. Thereby, the information transfer unit 13 refers to the specific information 12 (specific information 12b, 12c, 12d,...) And checks whether another communication device is in the vicinity (step ST1). At this time, if there is no communication device in the vicinity from the unique information 12, the information transfer unit 13 notifies the transmission control unit 9 accordingly.

  As a result, the process proceeds to step ST6, where the transmission control unit 9 instructs the transmission path state determination unit 11 to store the transmission result stored in the transmission result storage unit 10 by the same method as in Patent Document 1, for example. Is used to determine the quality of the transmission line 15. Based on the quality of the transmission path 15, the transmission control unit 9 determines a transmission parameter and sets it in the frame configuration unit 1. The frame configuration unit 1 configures an information frame including transmission data according to the set transmission parameter, and is superimposed on the transmission line 15 through the processes of the error detection code adding unit 2, the modulation unit 3, and the power line coupling unit 4. And transmit (step ST5).

  On the other hand, when there is a nearby communication device in step ST1, the information transfer unit 13 sends an instruction to the frame configuration unit 1 to confirm whether there is a transmission parameter that has been communicated to the communication device in the past. The frame construction unit 1 composes an information frame based on transmission parameter inquiry information including the unique ID of the inquired communication device, and passes through the processes of the error detection code addition unit 2, the modulation unit 3 and the power line coupling unit 4. It is superimposed on the transmission line 15 and transmitted (step ST2).

As described above, in the frame configuration unit 1, the transmission parameters determined by the conventional method disclosed in, for example, Patent Document 1 are processed by the same processing as normal data transmission without performing special processing when the present invention is applied. Thus, it is possible to realize data transmission in which any one of the optimum transmission parameters acquired from a nearby communication device in response to the above inquiry is set.
In addition, since the specific information 12 shown in FIG. 2 does not set the position information of the communication device, the inquiry is made by broadcast transmission, for example. In this case, the communication device that has received the inquiry information determines whether it is an inquiry to the own device, for example, based on whether or not the received information analysis unit 8 includes the unique ID of the own device in the inquiry information.

  When the inquiry device receives the inquiry information of the transmission parameter via the transmission line 15, the inquiry information is analyzed through the processes of the power line coupling unit 4, the demodulation unit 6, and the error detection unit 7. Input to section 8. If no data error is detected by the error detection unit 7, the reception content analysis unit 8 analyzes the content of the information frame and outputs data indicating the analysis result to the transmission result storage unit 10 and the instruction reception unit 14.

  When the reception content analysis unit 8 analyzes that the inquiry is transmission parameter inquiry information, the instruction reception unit 14 searches the transmission result storage unit 10 based on the unique ID of the inquiry source communication device included therein, It is investigated whether there is an optimum transmission parameter when communicating with the communication device in the past.

  Here, if the optimal transmission parameter at the time of communication in the past has been registered, the instruction receiving unit 14 reads the parameter value from the transmission result storage unit 10 and performs transmission control via the transmission path state determination unit 11. To the unit 9. If there is no communication in the past and there is no optimal transmission parameter, the instruction receiving unit 14 notifies the transmission control unit 9 to that effect.

  Thereby, if there is an optimum transmission parameter value, the transmission control unit 9 outputs this transmission parameter value to the frame configuration unit 1, and if there is no optimum transmission parameter value, response information that informs that fact. Output to the frame configuration unit 1. In the same manner as described above, the frame construction unit 1 constructs an information frame with response information including an optimal transmission parameter value or response information indicating that there has been no communication in the past and there is no optimal parameter value. The information is transmitted to the inquiring communication device by being superimposed on the transmission path 15 through the processing of the adding unit 2, the modulating unit 3, and the power line coupling unit 4. Note that the response information including the optimum transmission parameter value may be information in which a bit value indicating a response to an inquiry is set in a predetermined bit of the header portion of the data.

  When the inquiry source communication apparatus receives the response information via the transmission path 15 (step ST3), the response information is received via the processes of the power line coupling unit 4, the demodulation unit 6 and the error detection unit 7. Input to the analysis unit 8. The reception content analysis unit 8 analyzes the content of the information frame if no error is detected by the error detection unit 7. For example, based on the bit information added to the header part of the received data as described above, it is determined whether or not it is a response to the inquiry.

  In step ST4, if the response information is information on the optimum transmission parameter sent from the inquired communication device, the transmission parameter value is sent from the received content analysis unit 8 to the instruction receiving unit 14. Thereby, the instruction receiving unit 14 registers the transmission parameter value in the transmission result storage unit 10. If the response information indicates that there is no optimal parameter value, the received content analysis unit 8 notifies the transmission control unit 9 to that effect. In the transmission control unit 9, if there is an optimum transmission parameter value sent from the inquiry destination communication device registered in the transmission result storage unit 10, this is set in the frame configuration unit 1, and is sent from the inquiry destination communication device. If there is no transmission parameter of step ST1, the process returns to the process from step ST1, and it is checked again whether another communication apparatus is in the vicinity, and the processes after step ST2 are repeated.

  When the optimum transmission parameter sent from the inquiry communication device is set by the transmission control unit 9, the frame configuration unit 1 configures an information frame including transmission data to the communication device based on the transmission parameter. Then, after passing through the processes of the error detection code adding unit 2, the modulation unit 3 and the power line coupling unit 4, it is superimposed on the transmission line 15 and transmitted (step ST5).

  As described above, according to the first embodiment, the transmission result storage unit 10 in which the transmission parameters defining the data transmission conditions are registered, the unique ID of the own device, and the unique ID of the communication device installed in the vicinity. Frame configuration unit 1 that transmits information for inquiring about the presence or absence of a transmission parameter between itself and a nearby communication device with reference to unique information 12 including Since the transmitted transmission parameter is registered in the transmission result storage unit 10, the instruction reception unit 14 searches the transmission result storage unit 10 in response to an inquiry from another communication device and returns a corresponding transmission parameter. Sharing transmission parameters with nearby communication devices by inquiring about the existence of transmission parameters with the local device to nearby communication devices It can be. Thereby, useless transmission line communication evaluation can be omitted, and communication efficiency can be improved.

Embodiment 2. FIG.
The second embodiment is provided with a server that manages and manages transmission parameters of a plurality of communication devices existing on a transmission path.

  FIG. 4 is a block diagram showing a configuration of a communication system according to Embodiment 2 of the present invention, and shows an example in which the present invention is applied to a power line communication device, as in FIG. In the figure, a server (management server) 16 centrally manages transmission parameters of a plurality of communication devices existing on the transmission path 15. Further, the unique information 12 is identification information for uniquely identifying the own device, and identification information for uniquely identifying another communication device installed in the vicinity of the own device via the transmission path 15. In addition, position information for specifying at which position on the transmission line 15 the communication device is arranged is described.

  FIG. 5 is a diagram schematically illustrating an example of unique information according to the second embodiment. In the illustrated example, in the unique information 12, the unique ID “9” is set as the unique information 12a of the own apparatus, and “A-9” is set as the position information 12a-1 for specifying the position of the own apparatus. In the second embodiment, the position information of the unique information 12 is used when information such as transmission parameters is transferred to the server 16.

  In the communication device disclosed in Patent Document 1, the configuration corresponding to the transmission path state determination unit 11 determines the quality of the transmission path based on the past transmission result, and corresponds to the transmission control unit 9 according to the result. The data communication is performed by setting an appropriate transmission parameter to a configuration corresponding to the frame configuration unit 1.

  On the other hand, in the second embodiment, the information transfer unit 13 transmits the transmission parameters set as described above and the unique ID in the unique information 12 of the own device and the communication device in the vicinity thereof to the server 16. . Then, when transmitting data to another communication device, the information transfer unit 13 sends an instruction to the frame configuration unit 1 to confirm whether or not there is an optimal transmission parameter in the server 16. In the frame configuration unit 1, for example, a unique ID of the own device and a unique ID of the destination communication device are set in transmission data in which a bit value indicating whether there is an optimum transmission parameter is set in a predetermined bit of the header portion. Is generated and transmitted to the server 16.

  Note that each time data is transmitted to another communication device, the server 16 does not check whether or not there is an optimal transmission parameter. For example, a timer is provided in the communication device, and a predetermined period after the previous transmission is performed. If it has not elapsed (the time width that can be assumed that there will be no change in the communication status), the transmission path state determination unit 11 transmits based on the transmission result stored in the transmission result storage unit 10 of its own device. The parameter may be determined.

  The instruction receiving unit (parameter sharing processing unit) 14 registers the transmission parameter information transmitted from the server 16 in response to the inquiry in the transmission result storage unit 10. For example, when the reception content analysis unit 8 analyzes that the reception data is transmission data from the server 16, the instruction reception unit 14 uses the optimum communication device used for data transfer by another communication device in the area to which the device itself belongs. It is determined that the transmission parameter value is the content, and is registered as data related to the corresponding communication device in the transmission result storage unit 10. Thereby, the transmission path state determination unit 11 can select and refer to the optimal transmission parameter value received from the server 16 from the transmission result storage unit 10 when determining the quality of the transmission path 15.

  An evaluation point indicating the priority of parameter selection by the transmission path state determination unit 11 is provided, and when the instruction receiving unit 14 registers the value of the received transmission parameter in the transmission result storage unit 10, the evaluation point is weighted. May be registered. In addition, when the transmission path state determination unit 11 selects the transmission parameter registered in the transmission result storage unit 10, the transmission parameter from the server 16 may always be selected with priority.

  Further, for example, when a communication device is provided with a timer and a predetermined reference period (a time width in which it is assumed that there is no change in the communication status) has elapsed since the transmission parameter was received from the server 16, the transmission of the device itself Based on the transmission result of the result storage unit 10, the transmission path state determination unit 11 may determine the transmission parameter. The server 16 centrally manages transmission parameters of a plurality of communication devices existing on the transmission path 15, and may be embodied by a computer prepared separately from the communication device. You may comprise as.

  FIG. 6 is a block diagram illustrating a configuration example of a server of the communication system according to the second embodiment, and illustrates a configuration provided separately from the communication device. In the figure, a server (management server) 16A is configured to process transmission parameters, a storage device that stores position information data (position management storage unit) 17 and parameter data (parameter management storage unit) 18, and parameter reception. Unit 19, parameter determination unit 20, parameter transmission unit 21, and communication processing unit 21 a for communicating with a communication device on the transmission path 15. For the sake of simplicity, the location information data 17 and the parameter data 18 including the storage device that stores the location information data 17 and the parameter data 18 are simply referred to as the location information data 17 and the parameter data 18.

  The position information data 17 stores a unique ID for each communication device and its position information in association with each other. The parameter data 18 describes each piece of information constituting transmission parameters used for communication between communication devices. The parameter receiving unit 19 receives a request from the communication device via the transmission path 15. Here, the request from the communication device includes a registration request for registering the position information data 17 and the parameter data 18 in the storage unit of the server 16 and an optimum transmission set between the communication devices that are about to start communication. There are two types of transmission parameter requests for querying parameters.

  The parameter receiving unit 19 directly performs processing for registering the data transmitted from the communication device as the position information data 17 and the parameter data 18. On the other hand, in response to an optimal transmission parameter transmission request (transmission parameter inquiry), the parameter determination unit 20 performs a determination process on whether or not the position information data 17 and the parameter data 18 are optimal, and extracts transmission parameters.

  The information on the optimal transmission parameter extracted by the parameter determination unit 20 is returned as transmission data to the frame configuration unit 1 of the inquiry source communication device via the parameter transmission unit 21 and the communication processing unit 21a. As described above, data exchange between the communication device and the server 16A provided separately from the communication device is performed via the communication processing unit 21a having the same communication function as that of the communication device. The parameter transmitting unit 21 sets a bit value indicating that it is a response to the inquiry in a predetermined bit of the header portion of the transmission data including the optimal transmission parameter. When the frame construction unit 1 of the inquiry source communication device inputs the transmission data, the frame configuration unit 1 refers to a predetermined bit of the header portion, and if the bit value indicates that it is a response to the inquiry, the transmission parameter in the transmission data is set. Take it out and set it to self.

  FIG. 7 is a diagram illustrating a configuration example of a communication device according to the second embodiment, and illustrates a configuration in which a server is provided as one function of the own device. In FIG. 7, the components given the same reference numerals as those in FIG. 6 are the same or corresponding components. In the server (management processing unit) 16B provided as one function of the own device, the communication processing unit 21a for communicating with other communication devices is omitted. If the received content analysis unit 8 determines that the request is for the server 16B as an analysis result of the information content received via the transmission path 15, the received content analysis unit 8 outputs the received information to the server 16B.

  In the server 16B, the parameter receiving unit 19 receives a data registration request for the position information data 17 and the parameter data 18, and an optimal transmission parameter transmission request is output from the parameter receiving unit 19 to the parameter determining unit 20. As a result, as in the case of the server 16A described above, the parameter receiving unit 19 performs data registration processing for the position information data 17 and the parameter data 18 for each request, and the parameter determining unit 20 provides information on the optimum transmission parameter. The extraction process is performed.

  In this way, the server 20B holds the position information and the transmission parameters as the position information data 17 and the parameter data 18 for each communication device on the transmission path 15. The position information data 17 and the parameter data 18 are held in conjunction with the unique ID of the communication device. Further, information regarding the optimum transmission parameter extracted by the parameter determination unit 20 is returned to the requesting communication apparatus by the parameter transmission unit 21.

Here, the position information data 17 and parameter data 18 managed by the servers 16A and 16B described above will be described.
FIG. 8 is a diagram illustrating an example of position information data according to the second embodiment. In the illustrated example, as the unique ID 22 of the communication device, the unique ID 22-1 having the ID number “1”, the unique ID 22-2 having the ID number “2”, the unique ID 22-3 having the ID number “3”,. Is registered, and as the position information 23 of each communication device corresponding to these unique IDs, the position information 23-1 with the area code number "A-1" and the position information with the area code number "A-2" 23-2, position information 23-3,... With an area code number “B-1” is registered.

  The unique ID 22 of the communication device may be information that can uniquely identify the communication device. If the communication system of the present invention is applied to a LAN (Local Area Network), for example, a computer that embodies the communication device. It may be something like an IP address or MAC address assigned to. Moreover, the serial number attached | subjected for every computer may be sufficient. In the illustrated example, a serial number is simply used (ID number = “1” to “3”) for ease of explanation.

  The position information 23 is information indicating a place where the communication device is installed on the transmission path 15. The position information 23 has, for example, a GPS (Global Positioning System) function in each communication device (for example, as a function of the parameter receiving unit 19), and the position information obtained by the GPS is used as position information on the transmission line 15. You may convert and use.

  In addition, a numerical value that can uniquely determine the position on the transmission path 15 may be set in advance. For example, the numerical value is set with a DIP switch of a computer that embodies the communication device, the numerical value is set in advance as a variable of a program to be executed by the communication device, or the aforementioned IP address or MAC address is embedded. A unique ID 22 such as

  In addition, the communication device having the ID number from what number to the unique ID 22 is arranged in the vicinity, and the unique ID 22 is set in the server 16 by setting information that it belongs to a certain area at the time of installation. Just give the corresponding location information. Further, the server 16 is provided with a function such as DHCP (Dynamic Host Configuration Protocol) used in the network, and when connecting a new communication device, the server 16 can be notified to identify itself. For example, the communication device can automatically determine which area the device belongs to by setting an IP address or the like from the server 16.

  In the example of FIG. 8, the position information 23 is represented by a combination of area codes A, B, C, D... And a serial number. That is, “A-1” means a communication device with a unique ID “1” belonging to area A, “A-2” means a communication device with a unique ID “2” belonging to area A, and “B” “−1” means a communication device having a unique ID “1” belonging to area B.

Subsequently, the parameter data 18 will be described.
The parameter data 18 is data in which transmission parameters are set in association with the unique ID for each communication device. The transmission parameter is determined by the transmission control unit 9 according to the quality determined by the transmission path state determination unit 11 from the evaluation points assigned to the past transmission results, as proposed in Patent Document 1. It is information that defines the communication conditions. Further, as described in Reference Document 1, the transmission parameter may include information such as season, date, time, statistical information, and data rate information.
Reference 1: JP-T-2004-501535

  FIG. 9 is a diagram illustrating an example of parameter data according to the second embodiment. As shown in the figure, the parameter data 18 is information in which the unique IDs of communication apparatuses other than the communication apparatus and their transmission parameters are collected for each unique ID of the communication apparatus. In this way, the server 16 manages the transmission parameters of the communication devices existing on the transmission path 15 in an integrated manner.

  For example, with respect to the parameter data 18A of the communication device with the communication device ID “1”, “2”, “3”, “4”,... Are communicated as the unique ID (communication device ID) 24a of the destination communication device. Are set to the device IDs 24a-1, 24a-2, 24a-3,..., And the transmission parameters 25a- are set as the transmission parameters 25a corresponding to the communication device IDs 24a-1, 24a-2, 24a-3,. 1, 25a-2, 25a-3,... Are associated and registered. Similarly, for the parameter data 18B of the communication device with the communication device ID “2”, the unique ID (communication device ID) 24b of the destination communication device is “1”, “3”, “4”,. Communication device IDs 24b-1, 24b-2, 24b-3,... Are associated with transmission parameters 25b-1, 25b-2, 25b-3,. Registered.

  In the illustrated example, the transmission parameters 25a and 25b are represented as 5-bit digital information. For example, one bit is assigned to one frequency band for the transmission parameters 25a and 25b, and whether or not to use the frequency band is determined by referring to the value of the corresponding bit.

  FIG. 10 is a diagram illustrating a relationship between a communication device, a server, and an area to which these belong in the communication system according to the second embodiment. In the illustrated example, the communication devices 27 and 28 arranged adjacent to each other on the transmission path 15 are classified as communication devices in the area A, the communication devices 29 and 30 are classified as communication devices in the area B, and the communication devices 31, 32 is classified as an area C communication device, and communication devices 33 and 34 are classified as an area D communication device.

  The transmission parameters of the communication devices 27 to 34 are managed in an integrated manner by the server α in the form shown in FIG. In FIG. 10, a set of communication device areas in which transmission parameters are collectively managed by the server α is defined as one management area 26. FIG. 10 shows an example in which the server α is provided separately from the communication device, but the server α may be incorporated as one of the functions of the communication device, and each communication device may include a part of the server α. The functions of the server α may be realized by distributing each communication device.

Next, the operation will be described.
(1) Operation at System Startup (Initialization Process) FIG. 11 is a flowchart showing the operation at the system startup of the server according to the second embodiment. First, when the system is activated, the server 16 executes an initialization process (step ST1a). As one of the initialization processes, for example, the parameter receiving unit 19 of the server 16 checks whether or not the location information and transmission parameters of the communication device are preset in the server 16 (step ST2a).

  If these initial values are set, the parameter receiving unit 19 registers these values as initial values of the position information data 17 and the parameter data 18 (step ST3a). On the other hand, if the initial value is not set, the process at the time of starting the system is terminated. The above-described series of processing is performed when it is known from the time of system design which communication device is connected to which position on the transmission path 15.

  FIG. 12 is a flowchart showing the operation of the communication apparatus according to the second embodiment when the system is activated. First, when the system is activated, the communication device executes an initialization process (step ST1b). As one of the initialization processes, or when the server 16 first requests data transmission after the initialization process, the communication apparatus registers the unique information 12 of the own apparatus in the server 16 (step ST2b). .

  For example, the information transfer unit 13 of the communication device reads out the unique information 12 of the own device and outputs it to the frame configuration unit 1. The frame configuration unit 1 incorporates the unique information 12 of its own device input from the information transfer unit 13 into the information frame, and the information frame is processed by the error detection code addition unit 2, the modulation unit 3, and the power line coupling unit 4 respectively. To the server 16 via. When receiving the unique information 12 from the communication device, the parameter receiving unit 19 of the server 16 extracts the unique ID 12a and the position information 12a-1 of the communication device included in the unique information 12 as shown in FIG. Register as data 17.

  When the server 16 is a server 16B configured as one function of the communication device, data from another communication device to the server 16B is processed by the power line coupling unit 4, the demodulation unit 6, the error detection unit 7, and the like. When the server 16 is a server 16A provided separately from the communication device, data for the server 16A is received by the communication processing unit 21a of the server 16A.

  Further, information for determining whether or not the address is addressed to the server 16 or what kind of contents may be added to a predetermined bit of the header portion of the transmission data. For example, if “0” is set in the first bit of the header portion, normal communication processing is performed. If “1”, the initial registration request for the position information data 17 and parameter data 18 to the server 16 is set. Inquires about the optimum transmission parameter. If “3”, it is a transmission parameter registration request. As a result, on the side receiving the data, the processing corresponding to each request can be easily distinguished and executed by the value of the first bit of the header portion.

(2) Operation at Data Transmission Between Communication Devices FIG. 13 is a flowchart showing an optimal transmission parameter acquisition process of the communication device according to the second embodiment. First, when communicating with another communication device, the communication device receives a communication request from the communication device that is the communication request source (step ST1c). After the transmission of this request, the communication request source communication apparatus (transmission source communication apparatus) checks whether or not it has a transmission parameter with the transmission partner (transmission destination communication apparatus) (step ST2c). For example, it is optimal for a part of the configuration of transmission data to the transmission partner (predetermined bits of the head part (header part) of the transmission data) as data stored in the transmission result storage unit 10 with the destination communication device Information for confirming whether or not the transmission parameter value is present may be added.

  In addition, a user who manages the communication device of the transmission source uses a not-shown input unit to communicate with the communication device of the transmission destination in the transmission result storage unit 10 with respect to the communication device (for example, the transmission control unit 9). If there is an instruction to confirm whether or not the transmission parameter is satisfied, or if a plurality of calling functions are prepared and transmitted using one of the functions, the above confirmation processing is performed and the other function is used. In such a case, a process such as not performing the confirmation process may be defined. In addition, for each communication device, which option is selected in the process of step ST2c may be fixedly set in advance.

  For example, a part of the configuration of the transmission data to the transmission partner (the first bit of the header portion, etc.) has an optimal transmission parameter value with the destination communication device as the storage data of the transmission result storage unit 10 A case will be described in which information for confirming whether or not is set. In this case, the frame configuration unit 1 of the transmission source communication apparatus inputs the transmission data, and if there is an instruction for the confirmation processing in a part of the configuration of the data, notifies the transmission control unit 9 to that effect. . The transmission control unit 9 instructs the transmission path state determination unit 11 to use the unique ID of the destination communication device, and whether there is an optimal transmission parameter value for this communication device in the transmission result storage unit 10. Search for no. At this time, if there is a transmission parameter, the transmission path state determination unit 11 reads the transmission parameter from the transmission result storage unit 10 and outputs the transmission parameter to the transmission control unit 9.

  The transmission control unit 9 checks whether or not the optimum transmission parameter searched by the transmission path state determination unit 11 is used without being updated (step ST3c). For example, a schedule is set in the transmission control unit 9 so that a predetermined transmission parameter is always used only during a certain time of day. In this case, the transmission control unit 9 confirms the time when the transmission parameter is input from the transmission path state determination unit 11, and outputs the transmission parameter to the frame configuration unit 1 in that time zone. The frame construction unit 1 composes an information frame including transmission data based on the transmission parameter, and passes through each process by the error detection code addition unit 2, the modulation unit 3 and the power line coupling unit 4 to the communication device at the communication destination. Send. On the other hand, if it is not the predetermined time zone, the process proceeds to step ST4c.

  If there is no transmission parameter in step ST2c, or if it is determined in step ST3c that the transmission parameter is updated, the transmission control unit 9 inquires of the server 16 about the transmission parameter (step ST4c). For example, the transmission control unit 9 controls the information transfer unit 13 to give the unique ID of the own device and the unique ID of the destination communication device in the unique information 12 to the frame configuration unit 1. The frame configuration unit 1 creates transmission parameter inquiry information as an information frame including the unique ID of the own device and the unique ID of the destination communication device, and is generated by the error detection code adding unit 2, the modulation unit 3, and the power line coupling unit 4. It transmits to the server 16 via each process.

  When the parameter receiving unit 19 of the server 16 refers to a predetermined bit in the header portion of the received data and recognizes the transmission parameter inquiry information from the communication device based on the bit value, the parameter receiving unit 19 sends the inquiry information to the parameter determination unit 20. Output. The parameter determination unit 20 searches the parameter data 18 using the unique ID of the communication device in the inquiry information as will be described later, and determines whether or not the optimum transmission parameter corresponding to the inquiry is registered (step). ST5c). At this time, if the optimum transmission parameter is not registered, the parameter determination unit 20 transmits to the frame configuration unit 1 of the inquiry source communication device as transmission data indicating that there is no transmission parameter corresponding to the inquiry by the parameter transmission unit 21. Send back.

  The frame configuration unit 1 of the inquiry source communication device refers to a predetermined bit in the header portion of the transmission data from the server 16, and notifies the fact that the optimum transmission parameter is not registered from the bit value set in the predetermined bit. It recognizes that the content is present, and notifies the transmission control unit 9 to that effect.

  Thereby, the transmission control unit 9 instructs the transmission line state determination unit 11 to determine the quality of the transmission line 15 as a data transmission line using the transmission result of the transmission result storage unit 10 (step ST6c). In this transmission line communication evaluation, as in Patent Document 1, for example, whether there is an error in the data included in the response frame, the content of the response frame for a certain period or a certain number of times, and no response in the transmission result storage unit 10. The quality of the transmission line 15 is determined using the data shown.

  Thereafter, the transmission control unit 9 determines a transmission parameter based on the quality of the transmission line 15 determined by the transmission line state determination unit 11, and sets the determined transmission parameter in the frame configuration unit 1. The frame configuration unit 1 configures an information frame including the input transmission data based on the transmission parameters from the transmission control unit 9, and performs each process by the error detection code addition unit 2, the modulation unit 3, and the power line coupling unit 4. To the destination communication device. (Step ST7c).

  On the other hand, in step ST5c, when the inquired optimal transmission parameter is registered, the parameter determination unit 20 returns the transmission parameter to the frame configuration unit 1 of the inquiry source communication device by the parameter transmission unit 21. The frame configuration unit 1 of the communication apparatus refers to a predetermined bit in the header portion of the transmission data from the server 16 and recognizes that the transmission parameter from the server 16 is based on the bit value set therein. Thereby, the frame configuration unit 1 configures an information frame including the input transmission data based on the transmission parameter from the server 16, and each process by the error detection code addition unit 2, the modulation unit 3, and the power line coupling unit 4. To the destination communication device (step ST7c).

  As described above, when the data transmission between the communication devices is completed, the information transfer unit 13 determines whether or not the transmission contents between the transmission result storage unit 10 and the transmission device of the transmission destination have been changed. Is determined (step ST8c). When there is a change, the information transfer unit 13 outputs the current transmission parameter value, the unique ID of the own device, and the unique ID of the transmission destination communication device to the frame configuration unit 1.

  The frame configuration unit 1 configures an information frame in which a bit value indicating an update request is set in a predetermined bit of the header portion of transmission data including the current transmission parameter value and the unique ID of the communication device, and the modulation unit 3 and the power line coupling Through each process of the unit 4, it is transmitted to the server 16 as a transmission parameter update request (step ST9c). When the parameter receiving unit 19 of the server 16 refers to a predetermined bit in the header portion of the received data and recognizes from the bit value that the received data is a transmission parameter update request of the communication apparatus, the parameter receiving unit 19 determines the transmission parameter from the received data. The parameter data 18 is searched using the unique ID of the communication device included in the update request, and the transmission parameter value requested to be updated is updated.

  FIG. 14 is a flowchart showing processing by the server according to the second embodiment for a transmission parameter inquiry. First, the parameter receiving unit 19 of the server 16 is in a state of receiving the inquiry information about the optimum transmission parameter from the communication device while the data transmission process is started between the communication devices (step ST1d). Here, if the content of the received data is transmission parameter inquiry information, the parameter reception unit 19 outputs the inquiry information to the parameter determination unit 20.

  The parameter determination unit 20 searches the location information data 17 using the unique ID of the communication device included in the inquiry information, and confirms whether there is data relating to the communication device existing in the vicinity of the inquiry source communication device. (Step ST2d). For example, in the position information data 17 shown in FIG. 8, if the unique ID of the inquiry source communication device is “1” of the unique ID 22-1, the position information 23-1 is “A-1”. In this case, a communication device in the vicinity of the communication device is specified as a communication device having a unique ID “2” belonging to the same area A.

  Subsequently, the parameter determination unit 20 searches the parameter data 18 using the unique ID of the nearby communication device specified in step ST2d, and confirms whether there is optimal transmission parameter data regarding the destination communication device. (Step ST3d). At this time, if there is transmission parameter data of the destination communication device, the parameter determination unit 20 returns the transmission parameter to the inquiry source communication device (step ST4d).

  For example, in step ST2d, when a communication device having the unique ID “2” belonging to the area A shown in FIG. 8 is specified as a nearby communication device as described above, the unique ID of the destination communication device is “5”. Then, the parameter determination unit 20 sets the 5-bit digital value “11110” of the transmission parameter 25b-3 with the unique ID “5” in the parameter data 18B with the unique ID “2” of the communication apparatus illustrated in FIG. The data is read from the parameter data 18 and transmitted to the inquiry source communication device via the parameter transmission unit 21 and the communication processing unit 21a.

  On the other hand, if there is no data of a nearby communication device in step ST2d, or if there is no transmission parameter data of a destination communication device in step ST3d, the parameter determination unit 20 of the server 16 indicates that there is no optimal transmission parameter. A reply is made to the inquiry source communication device (step ST5d).

  FIG. 15 is a flowchart showing processing performed by the server according to the second embodiment in response to a transmission parameter update request. The transmission parameter information update processing sent from the communication apparatus after transmission processing is completed will be described with reference to FIG. . When the data transmission process between the communication devices is completed, the parameter receiving unit 19 of the server 16 receives an optimal transmission parameter update request from the communication device (step ST1e).

  Here, the parameter receiving unit 19 refers to the value of a predetermined bit in the header portion of the received data, and when the bit value is confirmed to be a transmission parameter update request from the communication device, it is included in the update request information. The parameter data 18 is searched using the unique ID of the communication device, and the transmission parameter requested to be updated is updated (step ST2e).

  In this way, in the exchange of data between the communication device and the server 16 described above, when communicating normally, by communicating with information corresponding to an ID for specifying the processing content at the head of the data, Without any special processing, it is possible to distinguish between an inquiry for an optimal transmission parameter and a request for updating a transmission parameter.

(3) Access operation to server The access from the communication device to the server 16 may be performed by specifying the server 16 for communication or broadcasting to all communication devices on the transmission path 15. Further, communication from the communication device to the server 16 is a normal communication process between the communication devices if the header portion of the transmission data, for example, the first bit is “0” as described above. For this reason, the server 16 ignores this information. Also, for example, if the first bit is “1”, it is initial data registration from the communication device to the server 16, if “2” it is a transmission parameter inquiry from the communication device, and if “3”, it is from the communication device. It can be determined that the request is a transmission parameter registration request and the processing is performed by the server 16.

  As described above, according to the second embodiment, the position information data 17 in which the position information of the communication device on the transmission path is registered, the parameter data 18 in which the transmission parameter for each communication device is registered, and the position information data 17 and the parameter data 18 are referred to, the parameter determination unit 20 for determining whether or not the transmission parameter corresponding to the inquiry is registered in the parameter data 18, and the transmission parameter of the determination result corresponding to the inquiry as the inquiry source Servers 16A and 16B each having a parameter transmission unit 21 for replying, and the frame configuration unit 1 of the communication device inquires the server 16A and 16B about the presence or absence of transmission parameters with the communication device of the communication partner, and indicates Transmission parameters transmitted from the servers 16A and 16B in response to the inquiry by the receiving unit 14 Since communication is controlled based on transmission parameters from the servers 16A and 16B registered in the transmission result storage unit 10 and registered in the transmission result storage unit 10, the communication device communicates with another communication device. By concentrating the optimal transmission parameters on the servers 16A and 16B and sharing the transmission parameters with nearby communication devices, it is possible to improve the communication efficiency as a result without wastefully evaluating the transmission line communication. .

Embodiment 3 FIG.
In the third embodiment, time information is added to parameter data to select a transmission parameter according to a change over time in the communication status between communication devices. The basic configuration of the communication system is the same as that of FIG. 1, FIG. 4 and FIG. 7 shown in the first embodiment, but has time information using the parameter data 18 and the transmission parameters in the server 16 The difference is that time information is used for selection.

  FIG. 16 is a diagram showing an example of parameter data according to the third embodiment of the present invention, and time information is added to the parameter data of FIG. 9 shown in the second embodiment. In the illustrated example, with respect to the parameter data 18A-1 of the communication device with the communication device ID “1”, the unique ID (communication device ID) 24a of the destination communication device is “2”, “3”, “4”, Are set to the communication device IDs 24a-1, 24a-2, 24a-3,..., And the transmission parameters 25a corresponding to the communication device IDs 24a-1, 24a-2, 24a-3,. As transmission parameters 25a-1, 25a-2, 25a-3,... And time data 35a-1, 35a-2, 35a-3,.

  Similarly, with respect to the parameter data 18B-1 of the communication device having the communication device ID “2”, “1”, “3”, “4”,... As the unique ID (communication device ID) 24b of the destination communication device. Are set to the communication device IDs 24b-1, 24b-2, 24b-3,..., And transmission parameters 25b-1, 25b-2, 25b-3,. , Time data 35b-1, 35b-2, 35b-3,... Are associated and registered as time information 35b. In this manner, by adding time information to the parameter data for each unique ID of the communication device, new information can be selected when there are a plurality of nearby communication devices.

Next, parameter selection processing in response to a transmission parameter inquiry will be described.
For example, it is assumed that communication devices having unique IDs “1”, “2”, and “4” are arranged close to each other and belong to the same area. Here, a communication request is transmitted from the communication device with the unique ID “4” to the communication device with the unique ID “3”, but the communication device with the unique ID “3” has the unique ID “4”. Consider the case where the optimum transmission parameters are not used in communication with the other communication device.

  In this case, the optimal transmission parameter between the communication device with the unique ID “3” is transmitted to the server 16 from the communication device with the unique ID “4” in the same manner as the processing described in the second embodiment. Information to be queried is transmitted. The parameter determination unit 20 of the server 16 searches the parameter data 18 using the unique ID of the destination communication device (the communication device whose unique ID is “3”) included in the inquiry information.

  The parameter determination unit 20 uses the unique IDs in the parameter data 18A-1 and 18B-1 for the communication devices with the unique IDs “1” and “2” belonging to the same area as the communication device with the unique ID “4”. If the transmission parameter data of the communication device “3” exists, the transmission parameter is returned to the inquiring communication device. However, in the example of FIG. 16, the transmission parameters 25a-2 and 25b-2 correspond to the transmission parameters 25a-2 and 25b-2 in the parameter data 18A-1 and 18B-1 as the transmission parameters corresponding to the unique ID “3”. "," 10010 "). For this reason, one of the data must be selected.

  In this case, the parameter determination unit 20 according to the third embodiment refers to the time information 35a-2 and 35b-2 and determines the transmission parameter 25a-2 of the parameter data 18A-1 which is newer data closest to the current time. select. Thereafter, the parameter determination unit 20 reads the digital value “11011” of the transmission parameter 25a-2 from the parameter data 18, and transmits the digital value “11011” to the inquiry source communication device by the parameter transmission unit 21 and the communication processing unit 21a.

  As described above, according to the third embodiment, since time information is added to the parameter data 18, when there is a difference in transmission parameters held by nearby communication devices in the same area, which is more appropriate? Can be judged. As a result, it is possible to suppress a case where an incorrect parameter is selected and communication cannot be performed or communication becomes inefficient. Therefore, as a result, it is possible to improve the communication efficiency without repeating the transmission path communication evaluation.

Embodiment 4 FIG.
FIG. 17 is a block diagram showing a configuration of a communication apparatus according to Embodiment 4 of the present invention. In addition to the configuration of FIG. 6 shown in the second embodiment, the server 16C according to the fourth embodiment has a parameter dynamic update unit that dynamically updates the contents of the position information data 17 and parameter data 18 managed by the server 16C. (Dynamic update unit) 36 is provided. In FIG. 17, the same reference numerals as those shown in FIG. 7 denote the same or corresponding components, and a duplicate description thereof will be omitted. Further, FIG. 17 shows an example in which the server 16C is realized as one function of the communication device, but the server 16C may be constructed by a computer provided separately from the communication device as shown in FIG.

Next, the operation will be described.
FIG. 18 is a flowchart showing the operation of the parameter dynamic update unit according to the fourth embodiment, which will be described with reference to this figure.
The parameter dynamic update unit 36 of the server 16C starts update processing of transmission parameter data in the parameter data 18 in accordance with a fixed update period set for itself (step ST1f). In addition to the above, when the parameter dynamic update unit 36 updates any one of the position information data 17 and the parameter data 18 by the parameter receiving unit 19, this is used as a trigger for other data in the parameter data 18. The update process may be started for data.

  First, the parameter dynamic update unit 36 compares transmission parameters of parameter data (for example, parameter data 18A and 18B in FIG. 9) for each communication device ID from the parameter data 18 (step ST2f), and for each communication device ID. It is determined whether there is a similar transmission parameter in the parameter data (step ST3f). Here, when transmission parameters relating to the same destination communication apparatus have similar values to the extent that it can be estimated that they belong to the same value or the same area, they are determined to be similar transmission parameters.

  If there is no similar transmission parameter in step ST2f, the parameter dynamic update unit 36 proceeds to a comparison process for the parameter data of the next unique ID number (step ST5f). If there are similar transmission parameters, the parameter dynamic update unit 36 corrects the position information data 17 regarding these communication devices, assuming that the communication devices of those parameter data are located in the vicinity and belong to the same area ( Step ST4f).

  A specific example will be described. In the location information data 17 shown in FIG. 8, the location information 23-1 with the communication device ID “1” and the location information 23-2 with the communication device ID “2” are divided into different areas. Think. That is, in FIG. 8, the position information 23-1 with the communication device ID “1” and the position information 23-2 with the communication device ID “2” belong to the same area A, but here the communication device ID is “ It is assumed that the position information 23-1 of “1” is registered with a different area code instead of “A-1”.

  As described above, the parameter dynamic update unit 36 transmits the transmission parameters 25a-1 to 25a-3 in the parameter data 18A having the communication device ID “1” from the parameter data 18 and the parameter data having the communication device ID “2”. The transmission parameters 25b-1 to 25b-3 in 18B are read out and the values of the transmission parameters are compared with each other. In FIG. 9, the parameter data 18A and 18B include the transmission parameters having the communication device ID “3”, and the values are also “11011”.

  Therefore, both the communication device with the unique ID “1” and the communication device with the unique ID “2” have both communicated with the communication device with the unique ID “3”, and further the communication with the unique ID “3”. Communication is performed using the same transmission parameters as the device. Accordingly, it is estimated that the communication device with the unique ID “1” and the communication device with the unique ID “2” are similar in quality of the transmission path 15 and belong to the same area.

  Therefore, the parameter dynamic update unit 36 reads the position information 23-1 and 23-2 regarding the communication device with the unique ID “1” and the communication device with the unique ID “2” from the position information data 17, and both are the same. If it is not registered in this area, it is corrected so that it becomes the same area. In the above-described example, the position information 23-1 of the communication device having the unique ID “1” is corrected to the area code “A-1”.

  As described above, the parameter dynamic update unit 36 is different from updating the parameter data 18 in response to the update request from the communication apparatus as in the second embodiment, and the actual communication registered in the server 16 itself. The position information data 17 is dynamically updated using the parameter data 18 based on the transmission result between the apparatuses.

  Thereafter, the parameter dynamic update unit 36 determines whether or not the processing from step ST2f to step ST4f has been executed for the parameter data of all the communication device IDs in the parameter data 18, and there is unprocessed parameter data. For example, the process from step ST2f is repeated until all parameter data are completed (step ST5f).

  As described above, according to the fourth embodiment, the parameter dynamic update unit 36 that dynamically updates the position information data 17 using the parameter data 18 based on the transmission result between the actual communication apparatuses is provided. Therefore, even if the location data of the wrong area division is registered in the parameter data 18 of the server 16, the area division is performed again based on the actually transmitted result. Thereby, it is possible to correctly select transmission parameters by nearby communication devices in data communication between the communication devices.

Embodiment 5. FIG.
FIG. 19 is a block diagram showing a configuration of a communication system according to Embodiment 5 of the present invention, in which a plurality of units composed of a plurality of communication devices and servers as shown in FIG. 10 of Embodiment 2 are assembled. System. The communication system according to the fifth embodiment does not manage all of a plurality of communication devices connected via a transmission line with a single server, but rather a server for a communication device installed in the vicinity via the transmission line 15. The number of areas that can be allowed by one server is defined according to the performance of the system, the frequency of communication between communication devices, and the like, and a plurality of servers are divided into units that cover several areas. This makes it possible to buffer transmission parameter inquiries and update requests that tend to concentrate on the server.

  The illustrated system includes three units 26A, 26B, and 26C in which transmission between communication apparatuses is managed by a server α, a server β, and a server γ. The units 26A, 26B, and 26C are connected to a transmission line 37 serving as a trunk line via transmission lines 15a, 15b, and 15c, respectively. The unit 26A includes communication devices 27a to 34a whose communication conditions are managed by the server α. The communication devices 27a and 28a that are determined as neighboring communication devices having similar communication conditions belong to the area A. The communication devices 29a and 30a belong to area B, the communication devices 31a and 32a belong to area C, and the communication devices 33a and 34a belong to area D.

  Similarly, in the unit 26B, the communication devices 27b to 34b whose communication conditions are managed by the server β and the communication devices 27b and 28b that are determined to be neighboring communication devices having similar communication conditions belong to the area E. The communication devices 29b and 30b belong to the area F, the communication devices 31b and 32b belong to the area G, and the communication devices 33b and 34b belong to the area H. Further, the unit 26C includes communication devices 27c to 34c whose communication conditions are managed by the server γ, and the communication devices 27c and 28c that are determined to be neighboring communication devices having similar communication conditions belong to the area I. The communication devices 29c and 30c belong to area J, the communication devices 31c and 32c belong to area K, and the communication devices 33c and 34c belong to area L.

  Position information data 17 and parameter data 18 of the communication devices 27a to 34a in the areas A to D are registered in the server α belonging to the unit 26A. Similarly, position information data of the communication devices 27b to 34b is registered in the server β. 17 and parameter data 18 are registered, and the position information data 17 and parameter data 18 of the communication devices 27c to 34c are registered in the server γ.

  As a method of dividing the registration of information to each server, for example, when assigning a unique ID number to each communication device, the ID of the server belonging to each higher-order bit or the ID that can uniquely identify the server It may be possible to allocate a part and specify a server to be managed. Note that the information specifying the server may be set by a dip switch of each communication device.

  Further, the flow of processing for acquiring the optimum transmission parameter when communicating from each communication device to another communication device is the same as that of the first embodiment.

  When the fourth embodiment is applied to the fifth embodiment, the parameter dynamic update unit 36 performs the update process only for the communication devices in the area managed by each server α, β, γ. It does not include communication devices managed by other servers.

  As described above, according to the fifth embodiment, a plurality of units including a plurality of communication devices and servers are aggregated, and the communication conditions of the communication devices managed by the plurality of servers are managed, so the number of communication devices increases. However, it is possible to reduce the increase in the communication load on the transmission path when trying to acquire the transmission parameter during communication or due to a request to update the transmission parameter of the server after the communication is completed.

  In the first to fifth embodiments, the case where a power line is used as the transmission line 15 has been described. However, transmission lines using other communication media are used as long as they do not depart from the spirit of the present invention. It may be.

It is a block diagram which shows the structure of the communication apparatus by Embodiment 1 of this invention. 6 is a diagram schematically illustrating an example of unique information according to Embodiment 1. FIG. 6 is a flowchart showing a flow of transmission parameter inquiry processing of the communication apparatus according to the first embodiment. It is a block diagram which shows the structure of the communication system by Embodiment 2 of this invention. It is a figure which shows typically an example of the specific information by Embodiment 2. 6 is a block diagram illustrating a configuration example of a server of a communication system according to Embodiment 2. FIG. 6 is a diagram illustrating a configuration example of a communication device according to Embodiment 2. FIG. It is a figure which shows an example of the positional information data by Embodiment 2. It is a figure which shows an example of the parameter data by Embodiment 2. It is a figure which shows the relationship between the communication apparatus in the communication system by Embodiment 2, a server, and the area to which these belong. 10 is a flowchart showing an operation at the time of system startup of the server according to the second embodiment. 6 is a flowchart illustrating an operation at the time of system startup of the communication device according to the second embodiment. 10 is a flowchart illustrating an optimal transmission parameter acquisition process of the communication device according to the second embodiment. It is a flowchart which shows the process by the server of Embodiment 2 with respect to a transmission parameter inquiry. It is a flowchart which shows the process by the server of Embodiment 2 with respect to a transmission parameter update request. FIG. 10 is a diagram illustrating an example of parameter data according to a third embodiment. It is a block diagram which shows the structure of the communication apparatus by Embodiment 4 of this invention. 14 is a flowchart illustrating an operation of a parameter dynamic update unit according to the fourth embodiment. It is a block diagram which shows the structure of the communication system by Embodiment 5 of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Frame structure part (parameter request | requirement part), 2 Error detection code addition part, 3 Modulation part, 4 Power line coupling | bond part, 5 Non-response determination part, 6 Demodulation part, 7 Error detection part, 8 Received content analysis part, 9 Transmission Control unit, 10 transmission result storage unit (parameter storage unit), 11 transmission path state determination unit, 12 specific information, 13 information transfer unit, 14 instruction reception unit (parameter sharing processing unit), 15 transmission path, 16, 16A, 16B , 16C server (management server, management processing unit), 17 position information data (storage unit for position management), 18 parameter data (storage unit for parameter management), 18A, 18B, 18A-1, 18B-1 parameter data, 19 Parameter receiving unit, 20 parameter determining unit, 21 parameter transmitting unit, 21a communication processing unit, 22 communication device ID, 222-1 to 22-3, 24a-1 to 24a- , 24b-1 to 24b-3 ID number, 23, 23-1 to 23-3 position information, 24a, 24b communication device ID, 25a, 25b, 25a-1 to 25a-3, 25b-1 to 25b-3 transmission Parameter, 26, 26A, 26B, 26C unit, 27-34, 27a-34a, 27b-34b, 27c-34c communication device, 35a time information, 35a-1 to 35a-3, 35b-1 to 35b-3 time data , 36 Parameter dynamic update unit (dynamic update unit).

Claims (11)

In a communication device that communicates based on transmission parameters that define data transmission conditions,
A parameter storage unit in which the transmission parameters are registered;
A parameter requesting unit that inquires about the presence or absence of transmission parameters related to communication with the own device to a communication device installed in the vicinity of the own device;
The transmission parameter transmitted in response to the inquiry from the own device is registered in the parameter storage unit, and the parameter storage unit is searched in response to the inquiry to the own device, and the corresponding transmission parameter is transmitted to the inquiring communication device. A communication apparatus comprising: a parameter sharing processing unit that sends a reply. A location management storage unit in which location information of communication devices on the transmission path is registered, a parameter management storage unit in which transmission parameters for each communication device are registered, the location management storage unit, and the parameter management storage unit. A parameter determination unit that determines whether or not a transmission parameter according to the inquiry is registered in the parameter management storage unit with reference to the content, and parameter transmission that returns a transmission parameter of a determination result corresponding to the inquiry to the inquiry source A management processing unit having a
The parameter request unit inquires of the management processing unit whether or not there is a transmission parameter with a communication device of a communication partner,
The communication apparatus according to claim 1, wherein the parameter sharing processing unit registers the transmission parameter transmitted from the management processing unit in the parameter storage unit in response to the inquiry. Comprising an information transfer unit for transmitting position information and transmission parameters to the management processing unit;
3. The communication apparatus according to claim 2, wherein the management processing unit includes a parameter receiving unit that registers the transmitted location information and transmission parameters in the location management storage unit and the parameter management storage unit. The parameter management storage unit stores the time information when the transmission parameter was used,
4. The communication apparatus according to claim 2, wherein the parameter determination unit selects a transmission parameter corresponding to the inquiry from the parameter management storage unit based on the time information.   5. The communication according to claim 2, further comprising a dynamic update unit that updates contents of the management storage unit based on a relationship of transmission parameter values for each communication device. apparatus. The parameter storage unit registers past transmission results for each communication device of the communication partner,
A transmission path state determination unit that determines transmission path quality using a transmission result registered in the parameter storage unit, and a transmission parameter is determined based on the transmission path quality determined by the transmission path state determination unit The communication apparatus according to claim 1, further comprising a parameter determination unit. In a management server that connects via a transmission path with a communication device that communicates based on transmission parameters that define data transmission conditions, and manages the transmission parameters of the communication device,
A location management storage unit in which location information of communication devices on the transmission path is registered;
A parameter management storage unit in which transmission parameters for each communication device are registered;
A parameter determination unit that determines whether or not a transmission parameter according to an inquiry from the communication device is registered in the parameter management storage unit with reference to the contents of the location management storage unit and the parameter management storage unit When,
A management server comprising: a parameter transmission unit that returns a transmission parameter of a determination result corresponding to an inquiry to a communication device that is an inquiry source.   8. The management server according to claim 7, further comprising a parameter receiving unit that registers position information and transmission parameters transmitted from the communication device in the position management storage unit and the parameter management storage unit. The parameter management storage unit stores the time information when the transmission parameter was used,
9. The management server according to claim 7, wherein the parameter determination unit selects a transmission parameter in response to the inquiry from the parameter management storage unit based on the time information.   10. The management according to claim 7, further comprising a dynamic update unit that updates contents of the management storage unit based on a relationship of transmission parameter values for each communication device. server. An area is defined for the communication apparatus according to claim 1 and the communication apparatus installed in the vicinity via a transmission line, and transmission parameters of the communication apparatus are managed for each area located in the vicinity. A communication system comprising the management server according to any one of 10.

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