JP2007281549A - Management device, management method, and local area network - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To use each communication system effectively in the entire local area network, where a plurality of communication systems are available. <P>SOLUTION: A management device 5 manages a plurality of terminal devices in the local area network, where a plurality of kinds of communication systems are available. The management device 5 comprises: a storage 56 for deciding priority in utilization for using the plurality of kinds of communication systems in the entire local network system for an available communication system, among a telephone line communication modulation/demodulation section 5T corresponding to each of the plurality of kinds of communication systems, a coaxial line communication modulation/demodulation section 5C, a power line communication modulation/demodulation section 5P, a radio LAN communication modulation/demodulation section 5R, and each terminal device; a priority decision section 53; and a control unit 52 and a router 51 for selecting the communication system among respective terminal devices according to utilization priority. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an apparatus and method for managing a plurality of terminal devices in a local area network, and a local area network by a management device and terminal devices.

  With the spread of FTTH (Fiber To The Home) and the rise of digital home appliances, information processing equipment such as personal computers and digital home appliances are placed in the same local area network at home, and each device is used in a coordinated manner. It has become possible to share Internet connections by installing gateways. On the other hand, there are, for example, a coaxial line communication system, a telephone line communication system, a wireless LAN communication system, a power line communication system, etc. as a communication system in a home network, and a gateway or terminal device is generally equipped with a plurality of communication means. It is becoming.

For example, Patent Document 1 discloses an appropriate communication method that can communicate with each other between two personal computers provided with communication means of a plurality of communication methods, and that can communicate with each other and, if necessary, consider the communication speed. A method of selecting by a communication switching utility installed in a personal computer is disclosed.
Patent Document 2 discloses a communication system that can use a plurality of transmission paths for data transmission between devices. In this communication system, when the data transmission amount per unit time reaches the reference amount, data can be transmitted using a plurality of transmission paths.

JP 2003-8861 A (FIGS. 1-4) JP 2004-64568 A (pages 4 to 6)

However, for example, when the one with the fastest communication speed is selected from a plurality of communication systems, only a specific communication system is used. As a result, only the transmission path of the communication system is crowded, and the transmission paths of other communication systems are vacant. May occur.
In view of the conventional problems as described above, an object of the present invention is to effectively utilize each communication method in the entire local area network in which a plurality of communication methods can be used.

The present invention is a management device that manages a plurality of terminal devices in a local area network that have a plurality of types of communication methods that can be used, each of which corresponds to the plurality of types of communication methods, Communication means that can be used between the terminal device and the priority order determining means for determining the use priority order to utilize the plurality of types of communication systems in the entire local area network, and according to the use priority order. And a control means for selecting the communication method.
In the management apparatus configured as described above, a plurality of communication methods in the network are effectively used and traffic is distributed.

In the above management device, if there is a communication method that can be used only with one terminal device, this should be the first communication method with the highest priority for use with the one terminal device. Can do.
In this case, a communication method that can be used exclusively can be effectively used without being idle.

In the management apparatus, it is preferable that the control means switches the communication method according to the usage priority order based on the accumulation of data in the transmission buffer.
In this case, since it is possible to switch to the communication method according to the usage priority order in response to the transmission path capacity and traffic volume that vary greatly in time, there is a large fluctuation in the transmission path capacity and traffic volume. Also, good transmission quality can be maintained.

In the management apparatus, the control unit may determine whether or not the data to be transmitted can be retransmitted, and may switch the communication method only for retransmittable data.
In this case, it is possible to suppress the occurrence of errors during data transmission for data that cannot be retransmitted, and to maintain good transmission quality.

In addition, the management device includes means for measuring the delay or error rate in the communication means of each communication method, a communication method having a smaller delay or error rate than other communication methods, for transmission of data that cannot be retransmitted, It may be used preferentially.
In this case, good transmission quality can be maintained by transmitting data that cannot be retransmitted by a communication method with a low error rate and delay.

In addition, the management apparatus may include a unit that reduces a delay or an error rate in a communication unit of a communication method used for transmission of data that cannot be retransmitted.
In this case, a communication method (transmission path) with a low error rate and delay can be ensured.

The management apparatus may select another communication method when data is retransmitted due to an error in data transmitted by one communication method.
In this case, occurrence of an error again can be suppressed. As a result, only one retransmission is required, delay is reduced, and good transmission quality can be maintained. Further, it is possible to reduce retransmission data and reduce the overall traffic.

On the other hand, the present invention is a management method for managing a plurality of terminal devices in a local area network having a plurality of types of available communication methods by a management device. The use priority order is determined so as to utilize the plurality of types of communication methods in the entire local area network, and the communication method used with each terminal device is selected according to the use priority order.
In the management method as described above, a plurality of communication methods in the network are effectively used, and traffic is distributed.

In addition, the local area network of the present invention includes a plurality of terminal devices that can use a plurality of types of communication methods as a whole, and manages the plurality of terminal devices to form a local area network and between each terminal device. And a management device that determines the priority of use in order to utilize the plurality of types of communication methods throughout the plurality of terminal devices, and selects a communication method according to the priority.
In the local area network configured as described above, a plurality of communication methods in the network are effectively used and traffic is distributed.

  According to the management apparatus / management method / local area network of the present invention, a plurality of communication methods in the network are effectively used and traffic is distributed. Thereby, the communication speed as the whole network improves.

  FIG. 1 is a diagram showing a configuration of a local area network including a management apparatus according to the first embodiment of the present invention. This local area network is, for example, installed in a home. In the figure, a management apparatus (for example, gateway) 5 is connected to a plurality (four units) of terminal devices 1 to 4 via transmission paths using a plurality of communication methods. Here, coaxial line communication, telephone line communication (DSL), and power line communication can be used as a communication method using a wired transmission path, and wireless wireless LAN communication can be used. In FIG. 1, the number of terminal devices is four, but any number of terminal devices can be connected within the range of the number connectable to the management apparatus 1.

  FIG. 2 is a block circuit diagram showing the internal configuration of the management apparatus 5. In the figure, the management device 5 includes a router (or switch) 51 and a control unit 52 as control means, a priority order determination unit 53 and storage unit 56 as priority order determination means, a telephone line communication modem 5T as communication means, A coaxial line communication modulation / demodulation unit 5C, a power line communication modulation / demodulation unit 5P, a wireless LAN communication modulation / demodulation unit 5R, and an antenna 57 are connected as shown in the figure. Each modulation / demodulation unit 5T, 5C, 5P, 5R includes a transmission buffer 501, a loopback unit 502, a modulation / demodulation processing unit 503, and an error rate measurement unit 504, which are connected as shown in the figure.

  The control unit 52 instructs the router 51 on the communication method to be used. Each of the communication modulation / demodulation units 5T, 5C, 5P, and 5R transmits the data temporarily stored in the transmission buffer 501 to the terminal devices 1 to 4 by the modulation / demodulation processing unit 503, and the data transmitted from the terminal devices 1 to 4. Receive. In addition, the transmission buffer 501 provides the control unit 52 with information on the degree of accumulation of the transmission buffer at the current time. On the other hand, the error rate measurement unit 504 measures the error rate in the modulation / demodulation processing unit 503. The loopback unit 502 detects a delay in the modulation / demodulation processing unit 503.

  The memory | storage part 56 has memorize | stored the communication system which can be utilized between each terminal devices 1-4, ie, the content of Table 1 mentioned later. Based on the output of the storage unit 56, the priority order determination unit 53 determines the priority order of the communication method, and gives priority order information to the control unit 52.

  FIG. 3 is an internal block diagram of the terminal devices 1 to 4. The terminal device 1 is configured by connecting a telephone line communication modulation / demodulation unit 1T, a power line communication modulation / demodulation unit 1P, and a switch 1S as illustrated. The terminal device 2 is configured by connecting a coaxial line communication modulation / demodulation unit 2C, a power line communication modulation / demodulation unit 2P, and a switch 2S as illustrated. The terminal device 3 is configured by connecting a wireless LAN communication modulation / demodulation unit 3R, a power line communication modulation / demodulation unit 3P, and a switch 3S as illustrated. An antenna 31 is connected to the wireless LAN communication modulation / demodulation unit 3R. The terminal device 4 is configured by connecting a telephone line communication modem 4T and a switch 4S as illustrated.

  FIG. 4 is a block circuit diagram showing the internal configuration of the telephone line communication modem 1T as a representative. In the figure, a telephone line communication modulation / demodulation unit 1T is configured by connecting a modulation / demodulation processing unit 101, an error rate measurement unit 102, a transmission buffer 103, and a loopback response unit 104 as illustrated. The other communication modulation / demodulation units 1P, 2C, 2P, 3R, 3P, and 4T have the same configuration.

  Each of the communication modulation / demodulation units 1T, 1C, 1P, and 1R transmits the data temporarily stored in the transmission buffer 103 to the management device 5 by the modulation / demodulation processing unit 101 and receives the data transmitted from the management device 5. Further, the error rate measuring unit 102 measures the error rate in the modulation / demodulation processing unit 101. Further, the loopback response unit 104 has a function of responding to information sent from the loopback unit 502 of the management device 5.

  In FIG. 2, the router 51 of the management device 5 is connected to the outside (such as a line termination device). On the other hand, in FIG. 3, each switch 1S, 2S, 3S, 4S of the terminal devices 1 to 4 is connected to a personal computer or a digital home appliance. In this way, a local area network in the house including the management device 5 and the terminal devices 1 to 4 is configured.

  In the local area network as described above, communication methods (transmission paths) that can be used between the management device 5 and the terminal devices 1 to 4 are as shown in Table 1 below.

  As can be seen from Table 1, only the terminal device 2 can use the coaxial line, and only the terminal device 3 can use the wireless LAN. Therefore, for the terminal device 2, the coaxial line is given priority 1 and the power line is given priority 2. For the terminal device 3, the wireless LAN is given priority 1 and the power line is given priority 2. As a result, the coaxial line that is a communication method that can be used only by the terminal device 2 and the wireless LAN that is a communication method that can be used only by the terminal device 3 can be used effectively. That is, a communication method that can be exclusively used can be effectively used without being idle.

  On the other hand, since the terminal device 4 is only a telephone line, this is given priority 1 (no priority 2). For the terminal device 1, for example, the higher communication speed is given priority, the telephone line is given priority 1, and the power line is given priority 2. Such a determination is automatically made in the priority order determination unit 53. In this way, the following priority table 2 is obtained. However, the method of determining the priority order is not limited to this, and in short, the use priority order may be determined in order to utilize a plurality of types of communication methods in the entire local area network. Here, “utilization” refers to effective use, for example, avoid creating idle communication methods as much as possible, or distributing selected communication methods to reduce bias (particularly priority order 1). To avoid concentrating the position).

The priority information shown in Table 2 is given to the control unit 52 from the priority determination unit 53 (FIG. 2). Moreover, based on this priority information, the control part 52 selects the communication system between the terminal devices 1-4. That is, a telephone line, a coaxial line, a wireless LAN, and a telephone line are selected as communication methods for the terminal devices 1, 2, 3, and 4, respectively. At the same time, the control unit 52 also gives priority information to the terminal devices 1 to 4 via the communication modulation / demodulation unit of the selected communication method. Based on this, the terminal devices 1 to 4 select the transmission modem for transmission according to the priority order.
As described above, a plurality of communication methods in the network are effectively used, and traffic is appropriately distributed. As a result, the communication speed of the entire network is improved.

  Next, switching of communication methods according to priority will be described with reference to the flowchart of FIG. The process of this flowchart is performed by the control unit 52 and the router 51. In the figure, first, in step S1, it is determined whether or not the transmission buffer capacity for the priority 1 transmission path is 80% or more. Here, if it is less than 80%, the determination in step S1 is repeated, but if it is 80% or more, switching to the transmission path of priority 2 is performed in step S2. This switching is also notified to the corresponding terminal device (1/2/3/4), and the communication modulation / demodulation unit is switched by the switch (1S / 2S / 3S / 4S) (the same applies hereinafter).

  Subsequently, in step S3, it is determined whether or not the transmission buffer capacity for the priority 1 transmission path has dropped to 70% or less. Here, when it is 70% or less, switching to the transmission path of priority 1 is performed in step S4, and the process returns to step S1. On the other hand, if it exceeds 70%, it is determined in step S5 whether or not the transmission buffer capacity for the priority 2 transmission path is 80% or more. Here, if it is less than 80%, the process returns to the determination in step S3. If it is 80% or more, switching to the transmission path of priority 3 is performed in step S6.

  Subsequently, in step S7, it is determined whether or not the transmission buffer capacity for the priority 1 transmission path has dropped to 70% or less. Here, when it is 70% or less, switching to the transmission path of priority 1 is performed in step S8, and the process returns to step S1. On the other hand, if it exceeds 70%, it is determined in step S9 whether or not the transmission buffer capacity for the priority 2 transmission path has dropped to 70% or less. Here, if it exceeds 70%, the process returns to the determination in step S7, but if it is 70% or less, switching to the transmission path of the priority order 2 is performed in step S10, and the process returns to the determination in step S3.

  By the above processing, switching to the communication method (transmission path) according to the usage priority order is performed in accordance with the transmission path capacity and traffic volume that vary greatly with time. Therefore, it is possible to effectively use a plurality of communication systems (transmission paths) and maintain good transmission quality even if there are large fluctuations in the transmission path capacity and traffic volume.

  Next, switching of communication methods considering data that cannot be retransmitted will be described with reference to the flowcharts of FIGS. 6, 7, and 8 represent one flowchart as a whole, and symbols a to f surrounded by circles in the drawings are connected to each other. Examples of data that cannot be retransmitted include VoIP (Voice over IP) and video data. Such data cannot be retransmitted if an error occurs by switching the transmission path during communication. Therefore, it is preferable to avoid transmission path switching during communication as much as possible.

  Whether the data cannot be retransmitted can be identified by the port number, for example, when a unique layer 4 port number is assigned to each application. Further, it can be distinguished by VoIP and header information (preamble etc.) specific to video data. Further, it can be distinguished by whether or not a UDP (User Datagram Protocol) header is attached. In addition, when the ToS (Type of Service) or VLAN of the IP frame is used for these data, it can be distinguished by the CoS (Class of Services) value of the VLAN tag.

  6 is performed by the control unit 52 and the router 51. In the figure, first, in step S11, a determination is made as to whether or not the transmission buffer capacity for the priority 1 transmission path is 60% or more. Here, if it is less than 60%, the determination in step S11 is repeated, but if it is 60% or more, only the retransmittable frame is switched to the transmission path of priority 2 in step S12. This switching is also notified to the corresponding terminal device 1 and the like, and the communication modem is switched by the switch 1S and the like (the same applies hereinafter).

  Subsequently, in step S13, it is determined whether or not the transmission buffer capacity for the priority 1 transmission path has dropped to 50% or less. Here, if it is 50% or less, a process of switching the retransmittable frame to the transmission path of priority 1 is performed in step S14, and then a process of returning to step S11 is performed. On the other hand, if it exceeds 50%, it is further determined in step S15 whether or not the transmission buffer capacity for the transmission path of priority 1 is 90% or more. Here, if it is 90% or more, in step S16, a process of switching the non-retransmittable frame to the transmission path of priority 2 is performed. If it is less than 90%, the process of returning to step S13 is performed.

  Subsequently, in step S17 (FIG. 7), it is determined whether or not the transmission buffer capacity for the priority 1 transmission path is 50% or less. Here, if it is 50% or less, in step S18, a process of switching all frames to the transmission path of priority 1 is performed, and then a process of returning to step S11 is performed. If it exceeds 50%, it is determined in step S19 whether or not the transmission buffer capacity for the priority 2 transmission path is 60% or more. Here, if it is less than 60%, the process of returning to step S17 is performed, but if it is 60% or more, the retransmittable frame is switched to the transmission path of priority 3 in step S20.

  Subsequently, in step S21, it is determined whether or not the transmission buffer capacity for the priority 1 transmission path has been reduced to 50% or less. Here, when it is 50% or less, a process of switching all frames to the transmission path of priority 1 is performed in step S22, and then a process of returning to step S11 is performed. On the other hand, if it exceeds 50%, it is further determined in step S23 (FIG. 8) whether or not the transmission buffer capacity for the priority 2 transmission path is 50% or less.

  Here, if it is 50% or less, in step S24, a process of switching to a transmission path of priority 2 is performed for the retransmittable frame. If it exceeds 50%, in step S25, it is determined whether or not the transmission buffer capacity for the priority 2 transmission path is 90% or more. Here, if it is less than 90%, the process of returning to step S21 is performed, but if it is 90% or more, in step S26, the non-retransmittable frame is switched to the transmission path of priority 3.

  Subsequently, in step S27, it is determined whether or not the transmission buffer capacity for the priority 1 transmission path has dropped to 50% or less. Here, if it is 50% or less, a process of switching all the frames to the transmission path of the priority order 1 is performed in step S28, and then a process of returning to step S11 is performed. On the other hand, if it exceeds 50%, it is further determined in step S29 whether or not the transmission buffer capacity for the priority 2 transmission path is 50% or less. Here, when it is 50% or less, a process of switching all frames to the transmission path of priority 2 is performed in step S30, and then a process of returning to step S17 is performed. On the other hand, if it exceeds 50%, the process of returning to step S27 is performed.

  As described above, the transmission path is switched as much as possible for retransmittable data. For data that cannot be retransmitted, the transmission path is not switched as much as possible. Thereby, the occurrence of errors during data transmission can be suppressed and good transmission quality can be maintained.

  Next, the management apparatus 5 according to the second embodiment of the present invention will be described. FIG. 9 is a block circuit diagram showing the internal configuration of the management apparatus 5. The difference from FIG. 2 is that a delay comparing unit 54 and an error rate comparing unit 55 are further provided as components of the priority determining unit, and outputs thereof are given to the priority determining unit 53. Further, the error rate measurement unit 504 of each of the communication modulation / demodulation units 5T, 5C, 5P, and 5R measures the error rate in the modulation / demodulation processing unit 503, and provides an error rate information output to the error rate comparison unit 55. Further, the loopback unit 502 of each of the communication modulation / demodulation units 5T, 5C, 5P, and 5R detects a delay in the modulation / demodulation processing unit 503, and provides an output of delay amount information to the delay comparison unit 54. The control unit 52 can control the modulation / demodulation processing units 503 of the communication modulation / demodulation units 5T, 5C, 5P, and 5R.

  The storage unit 56 stores communication methods that can be used between the terminal devices 1 to 4, that is, the contents of Table 1 described above. Based on the outputs of the delay comparison unit 54, the error rate comparison unit 55, and the storage unit 56, the priority order determination unit 53 determines the priority order of the communication method, and gives priority order information to the control unit 52. The control unit 52 instructs the modulation / demodulation processing units 503 of the communication modulation / demodulation units 5T, 5C, 5P, and 5R to change the error rate and delay.

  It is desirable that data that cannot be retransmitted be transmitted with low delay and low error rate. The loopback unit 502 of each of the communication modulation / demodulation units 5T, 5C, 5P, and 5R in the management device 5 periodically transmits loopback information, and delays depending on the response time from the loopback response unit 104 of the terminal devices 1 to 4. Measure. The delay comparison unit 54 compares the delays of the communication modulation / demodulation units 5T, 5C, 5P, and 5R, and gives the comparison result to the priority order determination unit 53. In addition, the error rate measuring unit 504 records the data error rate and obtains the average error rate for the most recent fixed time. The error rate comparison unit 55 compares the average error rates generated in the communication modulation / demodulation units 5T, 5C, 5P, and 5R, and gives the comparison result to the priority determination unit 53.

As a result, if the coaxial line <telephone line <power line <wireless LAN, the coaxial line and the telephone line, which are the upper two of the ones with less delay, are designated as data-dedicated transmission paths that cannot be retransmitted. The In addition, priority is set so that retransmittable data does not use these two transmission paths. The same applies to the error rate.
For example, if the priority of data that cannot be retransmitted is as shown in Table 3, the priority of data that can be retransmitted is as shown in Table 4.

In this way, good transmission quality can be maintained by routing data that is transmitted in real time and cannot be retransmitted to a transmission path with a low error rate and delay.
In Table 4, the telephone line priority is ranked first because the terminal device 4 has no other communication method, and this is an exceptional order setting.

  Note that, for a transmission path dedicated to non-retransmittable data, the delay of the transmission path can be intentionally reduced or the error rate can be reduced. In order to reduce the delay, there are methods such as directly controlling the modulation / demodulation processing unit 503 from the control unit 52 to make the interleaving shallow, and to increase the baud rate. In order to reduce the error rate, there are methods such as improving the error correction capability in the modulation / demodulation processing unit 503 and decreasing the number of modulation bits (decreasing the communication speed). As a result, it is possible to secure a transmission path with a small error rate and delay.

  Further, as a third embodiment, in the case of data that can be retransmitted, another transmission path may be used for retransmission. If data that can be retransmitted is transmitted and an error occurs when a certain transmission path is used and retransmission becomes necessary, the temporal transmission path conditions change significantly, and the switching of communication methods according to priority has caught up. If not, an error may occur even after retransmission. Therefore, with respect to retransmission data due to error occurrence or the like, if retransmission is performed using another transmission path, the occurrence of another error can be suppressed. As a result, only one retransmission is required, delay is reduced, and good transmission quality can be maintained. Further, it is possible to reduce retransmission data and reduce the overall traffic.

It is a figure which shows the structure of the local area network containing the management apparatus by 1st Embodiment of this invention. It is a block circuit diagram which shows the internal structure of a management apparatus. It is an internal block diagram of a terminal device. It is a block circuit diagram which shows the internal structure of a telephone line communication modem part. It is a flowchart which shows the process of switching a communication system. It is a flowchart (1/3) which shows the switching process of the communication system in consideration of the data which cannot be resent. It is a flowchart (2/3) which shows the switching process of the communication system in consideration of the data which cannot be retransmitted. It is a flowchart (3/3) which shows the switching process of the communication system in consideration of the data which cannot be retransmitted. It is a block circuit diagram which shows the internal structure of the management apparatus by 2nd Embodiment.

Explanation of symbols

1-4 terminal equipment 5 management device 5T telephone line communication modem (communication means)
5C Coaxial line communication modulator / demodulator (communication means)
5P power line communication modem (communication means)
5R wireless LAN communication modem (communication means)
51 router (control means)
52 Control unit (control means)
53 Priority determining unit (priority determining means)
54 Delay comparison unit (priority determination means)
55 Error rate comparison unit (priority determination means)
56 storage unit 501 transmission buffer

Claims (9)

A management device that manages a plurality of terminal devices in a local area network having a plurality of available communication methods,
A communication means corresponding to each of the plurality of types of communication methods;
For communication methods that can be used with each terminal device, priority determining means for determining a priority for using the plurality of types of communication methods in the entire local area network,
And a control unit that selects a communication method with each terminal device in accordance with the priority of use.   The management apparatus according to claim 1, wherein when there is a communication method that can be used only with one terminal device, this is a communication method with the highest priority for use with the one terminal device.   The management device according to claim 1, wherein the control unit switches a communication method according to the use priority order based on a data accumulation state of a transmission buffer.   The management device according to claim 3, wherein the control unit determines whether or not the data to be transmitted can be retransmitted, and switches the communication method only for the retransmittable data.   A means for measuring a delay or error rate in a communication means of each communication method is provided, and a communication method having a smaller delay or error rate than other communication methods is preferentially used for transmission of data that cannot be retransmitted. The management apparatus according to 1.   2. The management apparatus according to claim 1, further comprising means for reducing a delay or an error rate in communication means of a communication method used for transmission of data that cannot be retransmitted.   2. The management apparatus according to claim 1, wherein when data is retransmitted due to an error in data transmitted by one communication method, another communication method is selected. A management method for managing a plurality of terminal devices in a local area network having a plurality of available communication methods by a management device,
For communication methods that can be used with each terminal device, a priority order of use is determined in order to utilize the plurality of types of communication methods throughout the local area network,
A management method comprising: selecting a communication method to be used with each terminal device according to the use priority. Overall, multiple terminal devices that can use multiple types of communication methods,
The plurality of terminal devices are managed, a local area network is configured, and a communication method that can be used with each terminal device is prioritized to use the plurality of types of communication methods across the plurality of terminal devices. A local area network comprising: a management device that determines a ranking and selects a communication method according to the ranking.

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