WO2015123881A1

WO2015123881A1 - Node, resource multiplexing method and system

Info

Publication number: WO2015123881A1
Application number: PCT/CN2014/072448
Authority: WO
Inventors: 董晨; 姜彤
Original assignee: 华为技术有限公司
Priority date: 2014-02-24
Filing date: 2014-02-24
Publication date: 2015-08-27
Also published as: CN105308873A; CN105308873B

Abstract

The present invention relates to the technical field of networks. Provided in an embodiment of the present invention are a node, resource multiplexing method and system, the method comprising: a first central control node of a first coexisting network sets a detection time domain within the eligible time domain, and notifies first common nodes requiring multiplexing in the first coexisting network to successively send ISP signals of a first coexisting system in the detection time domain, such that a specified node in a second coexisting system detects in the detecting time domain whether the ISP signals are received; and then according to the summary of detection results, determining whether the first common nodes can multiplex resources in the second coexisting system. In the present invention, the first common nodes requiring resource multiplexing successively send ISP signals in the detection time domain, and the specified node in the second coexisting system detects whether the ISP signals are received, thus determining whether the first common nodes can multiplex resources in the second coexisting system, so that a network in a coexisting system can multiplex resources in other coexisting systems.

Description

Node, resource multiplexing method and system

The present invention relates to the field of network technologies, and in particular, to a node, resource multiplexing method and system. Background technique

Power line communication (PLC, Power Line Communications) refers to a communication method that uses power lines as a medium for communication transmission. The power line is a shared medium resource. When multiple networks using different PLC standards appear on the power line, how can they effectively coexist and share resources because networks cannot communicate with different PLC standards? Therefore, avoiding mutual interference is a major problem faced by PLC technology.

The G.9972 standard is to implement multiple network systems using different PLC standards (including: access system in IEEE 1901, Fast Fourier Transformation Orthogonal Frequency Division Multiplexing (FFT OFDM)). The coexistence between indoor systems, wavelet-based Orthogonal Frequency Division Multiplexing (Walllet OFDM, Wavelet Orthogonal Frequency Division Multiplexing) indoor systems, and G.hn systems) defines an ISP dedicated to coexistence (Internet- System protocol, inter-system protocol), and allocates an ISP window for each coexistence system in the time domain. Each ISP window contains two ISP time domains, and all nodes in each coexistence system coexist at the same time. The ISP signal is sent in the ISP window in the system. Each coexistence system can monitor the situation of ISP signals sent in the ISP window of other coexisting systems, so as to know the types of networks (ie, network states) that currently exist on the power line using different PLC standards, and then according to the G.9972 standard for each type. The resource allocation scheme defined by the network state takes up power line resources and realizes resource sharing.

In the process of implementing the present invention, the inventors have found that the prior art has at least the following problems: In the case where the traffic of some networks increases or periodic interference or noise occurs on the power line, the G.9972 standard is a coexistence network. The allocated resources may not meet the transmission needs of the network. At this time, these networks require additional resources, but the G.9972 standard can no longer allocate additional resources for these networks. Summary of the invention

In order to solve the problem in the prior art that the G.9972 standard cannot allocate additional resources to the network, a first tens of thousands of multiplexed systems, providing a first-level coherent system and a second coexistence system, the first coexistence system including at least one including a first central control node and a first coexistence network of at least one first common node, the second coexistence system comprising at least one second coexistence network including a second central control node and at least one second common node,

For any first coexistence network that needs to multiplex resources, the first central control node of the first coexistence network sets n detection time domains in the eligible time domain, and controls to the second center of the second coexistence network. The node sends a detection request message, where the detection request message includes the location information of the n detection time domains and the type information of the first coexistence system, and sends n resources to the first coexistence network. The first common node sends an indication message, where the indication message carries location information of a detection time domain uniquely corresponding to the first common node;

The first common node receives the indication message, and sends an inter-system protocol ISP signal corresponding to the first coexistence system in a detection time domain corresponding to the first common node;

The second central control node receives the detection request message, and sends a detection event request message to each designated node of the second coexistence network, where the detection event request message is used to indicate that the designated node is in the n detections Detecting, by the time domain, whether the ISP signal of the first coexistence system is received, the designated node being the second common node and/or the any one of the second coexistence networks having a transmission requirement within a specific time period a second central control node, wherein the specific time period is a period of time determined by the second central control node;

The specified nodes of the second coexistence network detect whether the ISP signal of the first coexistence system is received in the n detection time domains, and send the detection result of each detection time domain to the second through the detection result report message. a second central control node of the coexistence network;

The second central control node of the second coexistence network aggregates the detection result report messages sent by the designated nodes of the second coexistence network, and obtains a summary result of each detection time domain, and the result is obtained in the first coexistence network. The first central control node sends a summary notification message carrying the summary result;

The first central control node of the first coexistence network determines, according to the summary result in the summary notification message sent by the second central control node, that the ISP signal is sent in each detection time domain in the first coexistence network. Whether the first normal node has the right to reuse the resources of the second coexistence system.

In a first possible implementation manner of the first aspect, the second central control of the second coexistence network Get Liu Gu's test of the Japanese domain '/[ Result, 3⁄4栝:

For each detection time domain, when the detection result of the at least one designated node of the second coexistence network is that the ISP signal of the first coexistence system is detected on the detection time domain, the second central control node Determining that the summary result is that the second coexistence network detects the first coexistence system on the detection time domain; when the detection results of each designated node of the second coexistence network are not in the detection If the ISP signal of the first coexistence system is detected on the domain, the second central control node determines that the summary result is that the second coexistence network does not detect the first coexistence system in the detection time domain. .

With reference to the first aspect or the first possible implementation manner of the first aspect, in a second possible implementation manner, the first central control node of the first coexistence network is configured according to the second central control node Determining a notification message, determining that the first coexistence network sends the detection time in each detection time domain

Whether the first common node of the ISP signal has the right to multiplex the resources of the second coexistence system, including: when there is a second coexistence network in the second coexistence system, for each detection time domain, when The summary result of the second central control node is that the second coexistence network detects the first coexistence system on the detection time domain, and the first central control node determines to send the ISP in the detection time domain The first common node of the signal does not have the right to multiplex the resources of the second coexistence system; when the summary result of the second central control node is that the second coexistence network does not detect the detected time domain Determining the first coexistence system, the first central control node determining that the first common node that sends the ISP signal in the detection time domain has the right to reuse resources of the second coexistence system;

When there are two or more second coexistence networks in the second coexistence system, for each detection time domain, a summary result of the second central control node of at least one second coexistence network in the second coexistence system Detecting the first coexistence system on the detection time domain for the second coexistence network, the first central control node determining that the first common node that sends the ISP signal in the detection time domain does not have And multiplexing the resources of the second coexistence system; the summary result of the second central control node of each second coexistence network in the second coexistence system is the second coexistence network on the detection time domain The first coexistence system is not detected, and the first central control node determines that the first common node that transmits the ISP signal in the detection time domain has the right to multiplex resources of the second coexistence system.

With reference to the first aspect, the first possible implementation manner of the first aspect, or the second possible implementation manner of the first aspect, in a third possible implementation manner, the qualified time domain is in compliance with the first The second judgment of the ^κ仟^κ , is the extended ISP window of the first header system, or the default ISP window of the first coexistence system and the default time of the first coexistence system Domain resource

The first determining condition is: the first coexistence system determines a coexistence state of a coexistence system on a power line according to an ITU-T G.9972 ISP window mechanism, and determines the coexistence state according to the ITU-T G.9972 standard. Time domain resources allocated to the first coexistence system;

The second determining condition is: the first coexistence system determines a coexistence state of a coexistence system on a power line according to a topology discovery protocol in the IEEE 1905.1 standard, and determines the allocation in the coexistence state according to the ITU-T G.9972 standard. Giving time domain resources of the first coexistence system;

The default time domain resource of the first coexistence system refers to that the first coexistence system determines the coexistence state on the power line, and determines that the first coexistence is allocated in the coexistence state according to the ITU-T G.9972 standard. Time domain resources of the system;

The extended ISP window of the first coexistence system refers to a time domain having a predetermined duration from the ISP window of the first coexistence system, and the predetermined duration is a duration of the n detection time domains.

In combination with the first aspect, the first possible implementation of the first aspect, the second possible implementation of the first aspect, or the third possible implementation of the first aspect, in a fourth possible implementation All first coexistence networks in the first coexistence system follow the same PLC standard, and all second coexistence networks in the second coexistence system follow the same PLC standard, the first coexistence system and the The second coexistence system follows different PLC standards.

Combining the first aspect, the first possible implementation of the first aspect, the second possible implementation of the first aspect, the third possible implementation of the first aspect, or the fourth possible aspect of the first aspect In a fifth possible implementation manner, the first central control node and the second central control node are both devices based on the IEEE 1905.1 standard, and the detection request message and the summary notification are sent. Messages are encapsulated into IEEE 1905.1 abstraction layer control messages.

In a second aspect, a first central control node is provided, where the first central control node is the first central control node in a first coexistence network including a first central control node and at least one first common node. The first coexistence network is a coexistence network in the first coexistence system, and the first central control node includes:

a setting module, configured to set n detection time domains in a qualified time domain;

a first sending module, configured to send, to the first coexistence network, the n first resources that need to be multiplexed resources Detecting the date or position of the 1¥ en, the ISP signal of the first head-storage system sent by the detection of the Japanese domain in the first 逋吏 ;

The first sending module is further configured to send a detection request message to the second central control node of the second coexistence network in the second coexistence system, where the detection request message includes the location information and the location of the n detection time domains. The type information of the first coexistence system, so that the second central control node sends a detection event request message to each designated node of the second coexistence network, where the detection event request message is used to indicate that the designated node is in the Detecting whether the ISP signal of the first coexistence system is received by the detection time domain, and detecting, by the each designated node, whether the ISP signal is received in the n detection time domains, and passing the detection result through the detection result The report message is sent to the second central control node; and the second central control node summarizes the detection result report message sent by each specified node, and obtains a summary result of each detection time domain, to the first The central control node sends a summary notification message carrying the summary result, where the designated node is the second coexistence network Any one of which the transmission requirement a second ordinary node of said second period of time determined by the central control node and / or the second central control node, said specific time period by a particular time period;

a determining module, configured to receive the summary notification message sent by the second central control node, and determine, according to the summary result in the summary notification message, that the ISP signal is sent in each detection time domain in the first coexistence network Whether a normal node has the right to reuse resources of the second coexistence system.

In a first possible implementation manner of the second aspect, when the second coexistence network exists in the second coexistence system, the determining module includes:

a first determining unit, configured, for each detection time domain, when a summary result of the second central control node is that the second coexistence network detects the first coexistence system on the detection time domain, Determining that the first normal node that sends the ISP signal in the detection time domain does not have the right to reuse resources of the second coexistence system;

a second determining unit, configured, for each detection time domain, when the summary result of the second central control node is that the second coexistence network does not detect the first coexistence system on the detection time domain, Determining, by the first common node that sends the ISP signal in the detection time domain, a right to reuse resources of the second coexistence system;

When there are two or more second coexistence networks in the second coexistence system, the determining module includes: The second co-existing point of the second head of the m-network is [> the result is that the first coexistence system is detected on the detection time domain of the second head memory, and the detection time domain is determined. The first normal node that sends the ISP signal does not have the right to reuse resources of the second coexistence system;

a fourth determining unit, configured to: for each detection time domain, a summary result of the second central control node of each second coexistence network in the second coexistence system is the second coexistence network in the detection time domain If the first coexistence system is not detected, determining that the first common node that sends the ISP signal in the detection time domain has the right to multiplex resources of the second coexistence system.

With reference to the second aspect, or the first possible implementation manner of the second aspect, in a second possible implementation manner, the qualified time domain is the first coexistence system when the first determining condition is met Default time domain resource;

The qualified time domain is an extension of the first coexistence system when the second judgment condition is met

An ISP window, or an extended ISP window of the first coexistence system and a default time domain resource of the first coexistence system;

With reference to the second aspect, the first possible implementation manner of the second aspect, or the second possible implementation manner of the second aspect, in a third possible implementation manner, all the first ones in the first coexistence system The coexistence network all follow the same PLC standard, all of the second coexistence networks in the second coexistence system follow the same PLC standard, and the first coexistence system and the second coexistence system follow different PLC standards.

Combining the second aspect, the first possible implementation manner of the second aspect, and the second The first nailing point and the second hearting point are both devices based on the IEEE 1905.1 standard, and the detected request message and the summary notification message are both encapsulated into IEEE. 1905.1 Abstract layer control message.

In a third aspect, a first common node is provided, where the first common node is the first common node in a first coexistence network including a first central control node and at least one first common node, The first coexistence network is a coexistence network in the first coexistence system, and the first common node includes:

a first receiving module, configured to receive an indication message sent by the first central control node of the first coexistence network, where the indication message carries location information of a detection time domain uniquely corresponding to the first common node, where The detection time domain is one of the n detection time domains set by the first central control node of the first coexistence network in the eligible time domain, where n is the first resource in the first coexistence network that needs to be reused The number of ordinary nodes;

And a second sending module, configured to send an ISP signal of the first coexistence system in the detecting time domain. In a first possible implementation manner of the third aspect, the qualified time domain is a default time domain resource of the first coexistence system when the first determining condition is met;

The qualified time domain is an extended ISP window of the first coexistence system, or an extended ISP window of the first coexistence system and a default time domain of the first coexistence system when the second judgment condition is met Resource

In a fourth aspect, a second central control node is provided, where the second central control node is included A heart control point, the second head of the storage network is a head of the second head system T, the second central control node includes:

a second receiving module, configured to receive a detection request message sent by the first central control node of the first coexistence network in the first coexistence system, where the detection request message includes location information of the n detection time domains and the first coexistence Type information of the system;

a third sending module, configured to send, to each designated node of the second coexistence network, a detection event request message, where the designated node is any one of the second coexistence network having a transmission requirement in a specific time period a second common node and/or the second central control node, wherein the specific time period is a period determined by the second central control node, and the detection event request message is used to indicate that the designated node is in the n Detecting whether the ISP signal of the first coexistence system is received, so that the respective designated nodes detect whether the second central control node of the first coexistence system is received in the n detection time domains;

a summary module, configured to summarize the detection result report message sent by each specified node, and obtain a summary result of each detection time domain;

The third sending module is further configured to send, to the first central control node in the first coexistence network, a summary notification message carrying the summary result, so that the first central control node is configured according to the summary notification message. The result of the aggregation determines whether the first common node that sends the ISP signal in the respective detection time domains in the first coexistence network has the right to multiplex resources of the second coexistence system.

In a first possible implementation manner of the fourth aspect, the summary module includes: a fifth determining unit, configured, for each detection time domain, a detection result of at least one specified node of the second coexistence network When the ISP signal of the first coexistence system is detected on the detection time domain, determining that the summary result is that the second coexistence network detects the first coexistence system on the detection time domain;

a sixth determining unit, configured, for each detection time domain, when the detection result of each designated node of the second coexistence network is that the ISP signal of the first coexistence system is not detected on the detection time domain And determining, according to the summary result, that the second coexistence network does not detect the first coexistence system on the detection time domain.

In combination with the fourth aspect or the first possible implementation of the fourth aspect, in the second possible The second coexistence of T is the second PLC, and the first coexistence system and the second coexistence system follow different PLC standards.

With reference to the fourth aspect, the first possible implementation manner of the fourth aspect, or the second possible implementation manner of the fourth aspect, in a third possible implementation manner, the first central control node and the first The two central control nodes are all devices based on the 1905.1 standard, and the detection request message and the summary notification message are encapsulated into 1905.1 abstraction layer control messages.

In a fifth aspect, a second common node is provided, where the second common node is the second common node in a second coexistence network including a second central control node and at least one second common node, The second coexistence network is a coexistence network in the second coexistence system, and the second common node includes:

a third receiving module, configured to receive a detection event request message sent by the second central control node of the second coexistence network, where the detection event request message is used to indicate that the designated node detects whether to receive the first coexistence in the n detection time domains. The ISP signal of the system, the designated node is the second common node and/or the second central control node having any transmission requirement in a certain time period of the second coexistence network, the specific time period a period of time determined by the second central control node;

a detecting module, configured to detect, in the n detecting time domains, whether the ISP signal is received, or a fourth sending module, configured to send, by using the detection result report message, the detection result of each detection time domain detected by the detecting module Giving the second central control node of the second coexistence network, so that the second central control node aggregates the detection result report messages sent by the designated nodes of the second coexistence network, and obtains the summary result of each detection time domain. And sending, to the first central control node of the first coexistence network, a summary notification message carrying the summary result, so that the first central control node determines the first according to the summary result in the summary notification message. Whether the first common node that transmits the ISP signal in each detection time domain in a coexistence network has the right to multiplex resources of the second coexistence system.

In a first possible implementation manner of the fifth aspect, the detecting module is further configured to: detect, for each detection time domain, whether an ISP signal of the first coexistence system is received in the detection time domain.

With reference to the fifth aspect, or the first possible implementation manner of the fifth aspect, in a second possible implementation manner, all the first coexistence networks in the first coexistence system comply with the same PLC standard, where All second coexistence networks in the second coexistence system follow the same PLC standard, the first In conjunction with the fifth possible embodiment of the fifth or third, or the second possible embodiment of: the fifth possible embodiment, in a third possible implementation, the first central control The node and the second central control node are both 1905.1-based devices, and the summary notification message is encapsulated into a 1905.1 abstraction layer control message.

According to a sixth aspect, a first central control node is provided, where the first central control node is the first central control node in a first coexistence network including a first central control node and at least one first common node. The first coexistence network is a coexistence network in the first coexistence system, and the first central control node includes:

a processor, configured to set n detection time domains in an eligible time domain;

a transmitter, configured to send an indication message to the n first common nodes that need to multiplex resources in the first coexistence network, where the indication message carries a detection time domain uniquely corresponding to the first common node Position information, so that the first common node sends the ISP signal of the first coexistence system in the detection time domain;

The transmitter is further configured to send a detection request message to the second central control node of the second coexistence network in the second coexistence system, where the detection request message includes the n detection time domain detection request messages, and the detecting And requesting the message and the type information of the first coexistence system, so that the second central control node sends a detection event request message to each designated node of the second coexistence network, where the detection event request message is used to indicate the designation The node detects whether to receive the ISP signal of the first coexistence system in the n detection time domains, and detects, by the each designated node, whether the ISP signal is received in the n detection time domains, and the detection result is And sending, by the second central control node, the detection result report message sent by each specified node, and obtaining a summary result of each detection time domain, The first central control node sends a summary notification message carrying the summary result, where the designated node is The second common node and/or the second central control node having a transmission requirement in any one of the second coexistence networks, wherein the specific time period is determined by the second central control node For a while;

a receiver, configured to receive the summary notification message sent by the second central control node, where the processor is further configured to determine, according to the summary result in the summary notification message, each detection time in the first coexistence network Whether the first common node that sends the ISP signal in the domain has the right to multiplex the resources of the second coexistence system.

In a first possible implementation of the sixth aspect, In the mother detection, when the first coexistence system is detected on the detection time domain of the second τ cardiac pinch point, the result is determined at the time of the detection. Domain sending

The first normal node of the ISP signal does not have the right to reuse the resources of the second coexistence system;

The processor is further configured to: when there is a second coexistence network in the second coexistence system, for each detection time domain, when the summary result of the second central control node is the second coexistence network When the first coexistence system is not detected in the detection time domain, determining that the first common node that sends the ISP signal in the detection time domain has the right to reuse resources of the second coexistence system;

The processor is further configured to: when there are two or more second coexistence networks in the second coexistence system, for each detection time domain, when at least one second coexistence network of the second coexistence system The result of the aggregation of the second central control node is that the second coexistence network detects the first coexistence system on the detection time domain, and determines that the first common node that sends the ISP signal in the detection time domain does not Having the right to reuse resources of the second coexistence system;

The processor is further configured to: when there are two or more second coexistence networks in the second coexistence system, for each detection time domain, when each of the second coexistence networks in the second coexistence system The summary result of the two central control nodes is that the second coexistence network does not detect the first coexistence system in the detection time domain, and then determines the first common node that sends the ISP signal in the detection time domain. Having the right to reuse resources of the second coexistence system.

With reference to the sixth aspect, or the first possible implementation manner of the sixth aspect, in the second possible implementation manner, the qualified time domain is the first coexistence system when the first judgment condition is met Default time domain resource;

The default time domain resource of the first coexistence system refers to the first coexistence system determining the power line E^i or poor source of a sputum;

With reference to the sixth aspect, the first possible implementation manner of the sixth aspect, or the second possible implementation manner of the sixth aspect, in a third possible implementation manner, all the first ones in the first coexistence system The coexistence network all follow the same PLC standard, all of the second coexistence networks in the second coexistence system follow the same PLC standard, and the first coexistence system and the second coexistence system follow different PLC standards.

With reference to the sixth aspect, the first possible implementation manner of the sixth aspect, the second possible implementation manner of the sixth aspect, or the third possible implementation manner of the sixth aspect, in a fourth possible implementation manner The first central control node and the second central control node are both devices based on the IEEE 1905.1 standard, and the detected request message and the summary notification message are both encapsulated into an IEEE 1905.1 abstraction layer control message.

According to a seventh aspect, a first common node is provided, where the first common node is the first common node in a first coexistence network including a first central control node and at least one first common node, The first coexistence network is a coexistence network in the first coexistence system, and the first common node includes:

a receiver, configured to receive an indication message sent by the first central control node of the first coexistence network, where the indication message carries location information of a detection time domain uniquely corresponding to the first common node, where the detection time is The domain is one of the n detection time domains set by the first central control node of the first coexistence network in the eligible time domain, where n is the first common resource in the first coexistence network that needs to reuse resources. The number of nodes;

And a transmitter, configured to send an ISP signal of the first coexistence system in the detection time domain.

In a first possible implementation manner of the seventh aspect, the qualified time domain is a default time domain resource of the first coexistence system when the first determining condition is met;

The first determining condition is: the first coexistence system determines a coexistence state of a coexistence system on a power line according to an ITU-T G.9972 ISP window mechanism, and determines the according to the ITU-T G.9972 standard. The second judgment is: The first memory system is based on IEEE 1905.1. The discovery protocol determines the coexistence state of the coexistence system on the power line, and determines the location according to the ITU-T G.9972 standard. a time domain resource allocated to the first coexistence system in a coexistence state;

According to an eighth aspect, a second central control node is provided, where the second central control node is the second central control node in a second coexistence network including a second central control node and at least one second common node. The second coexistence network is a coexistence network in the second coexistence system, and the second central control node includes:

a receiver, configured to receive a detection request message sent by a first central control node of the first coexistence network in the first coexistence system, where the detection request message includes location information of n detection time domains and the first coexistence system Type information

a transmitter, configured to send a detection event request message to each designated node of the second coexistence network, where the designated node is the second common one of the second coexistence network having a transmission requirement in a specific time period a node and/or the second central control node, the specific time period is a period of time determined by the second central control node, and the detection event request message is used to indicate that the designated node is in the n detections Detecting whether the ISP signal of the first coexistence system is received by the time domain, so that the respective designated nodes detect whether the ISP signal control node of the first coexistence system is received in the n detection time domains; ° ' ' , "

a processor, configured to summarize the detection result report message sent by each specified node, to obtain a summary result of each detection time domain;

The transmitter is further configured to send, to the first central control node in the first coexistence network, a summary notification message carrying the summary result, so that the first central control node is configured according to the summary notification message. And a result of the aggregation, determining whether the first common node that sends the ISP signal in the respective detection time domains in the first coexistence network has the right to multiplex resources of the second coexistence system.

In a first possible implementation manner of the eighth aspect, the processor is further used for each check i or the 1SP 1 on the first sputum of the sneak peek of the sneak peek of the sneak peek of the first sneak peek system;

The processor is further configured to: for each detection time domain, when the detection result of each designated node of the second coexistence network is that the ISP signal of the first coexistence system is not detected on the detection time domain And determining, according to the summary result, that the second coexistence network does not detect the first coexistence system on the detection time domain.

With reference to the eighth aspect, or the first possible implementation manner of the eighth aspect, in a second possible implementation manner, all the first coexistence networks in the first coexistence system comply with the same PLC standard, where All of the second coexistence networks in the two coexistence systems follow the same PLC standard, and the first coexistence system and the second coexistence system follow different PLC standards.

With reference to the eighth aspect, the first possible implementation manner of the eighth aspect, or the second possible implementation manner of the eighth aspect, in a third possible implementation manner, the first central control node and the first The two central control nodes are all devices based on the 1905.1 standard, and the detection request message and the summary notification message are encapsulated into 1905.1 abstraction layer control messages.

A ninth aspect, a second common node is provided, where the second common node is the second common node in a second coexistence network including a second central control node and at least one second common node, The second coexistence network is a coexistence network in the second coexistence system, and the second common node includes:

a receiver, configured to receive a detection event request message sent by a second central control node of the second coexistence network, where the detection event request message is used to indicate that the designated node detects whether to receive the first coexistence in n detection time domains The ISP signal of the system, the designated node is the second common node and/or the second central control node having any transmission requirement in a certain time period of the second coexistence network, the specific time period a period of time determined by the second central control node;

a processor, configured to detect, in the n detection time domains, whether the ISP signal is received, and a sending unit, configured to send, by using the detection result report message, the detection result of each detection time domain detected by the detection module to the a second central control node of the second coexistence network, so that the second central control node aggregates the detection result report messages sent by the designated nodes of the second coexistence network, and obtains a summary result of each detection time domain, and Sending, to the first central control node of the first coexistence network, a summary notification message carrying the summary result, so that the first central control node determines the first coexistence according to the summary result in the summary notification message Within the network Unlimited.

In a first possible implementation manner of the ninth aspect, the processor is further configured to:

For each detection time domain, detecting whether the first coexistence system is received in the detection time domain

ISP signal.

With reference to the ninth aspect, or the first possible implementation manner of the ninth aspect, in a second possible implementation manner, all the first coexistence networks in the first coexistence system follow the same PLC standard, where All of the second coexistence networks in the two coexistence systems follow the same PLC standard, and the first coexistence system and the second coexistence system follow different PLC standards.

With reference to the ninth aspect, the first possible implementation manner of the ninth aspect, or the second possible implementation manner of the ninth aspect, in a third possible implementation manner, the first central control node and the first The two central control nodes are all devices based on the 1905.1 standard, and the summary notification message is encapsulated into a 1905.1 abstraction layer control message.

According to a tenth aspect, a resource multiplexing method is provided, where the first coexistence network is applied to the first central control node that includes a first coexistence network of a first central control node and at least one first common node. As a coexistence network in the first coexistence system, the method includes:

Setting n detection time domains in the eligible time domain;

Sending an indication message to the n first common nodes that need to multiplex resources in the first coexistence network, where the indication message carries location information of a detection time domain uniquely corresponding to the first common node, so as to Transmitting, by the first common node, the ISP signal of the first coexistence system in the detection time domain; and sending a detection request message to the second central control node of the second coexistence network in the second coexistence system, where the detection request message includes The n detecting time domain location information and the first coexistence system type information, so that the second central control node sends a detection event request message to each designated node of the second coexistence network, the detection event And the request message is used to indicate, by the specified node, whether to receive the ISP signal of the first coexistence system in the n detection time domains, and whether the each designated node detects whether the An ISP signal, the detection result is sent to the second central control node by using a detection result report message; and the second central control node sinks And sending the detection result report message sent by each of the designated nodes to obtain a summary result of each detection time domain, and sending, to the first central control node, a summary notification message carrying the summary result, where the designated node is Said second common node and/or said second central control node having any transmission requirement in a certain time period in said second coexistence network, said specific time period being said second Receiving the fascinating '/H forgetting to send the sentiment of the second centric pinch point, determining, according to the summary result in the ‘H forget message, determining that the first coexistence network is sent in each detection time domain Whether the first common node of the ISP signal has the right to multiplex resources of the second coexistence system.

In a first possible implementation manner of the tenth aspect, when there is a second coexistence network in the second coexistence system, the determining, according to the summary result in the summary notification message, determining that the first coexistence network is intrinsic Whether the first common node that sends the ISP signal in each detection time domain has the right to reuse the resources of the second coexistence system includes:

For each detection time domain, when the summary result of the second central control node is that the second coexistence network detects the first coexistence system on the detection time domain, determining to send in the detection time domain The first common node of the ISP signal does not have the right to multiplex resources of the second coexistence system; when the summary result of the second central control node is that the second coexistence network is not in the detection time domain Detecting the first coexistence system, determining that the first common node that sends the ISP signal in the detection time domain has the right to reuse resources of the second coexistence system;

When there are two or more second coexistence networks in the second coexistence system, determining, according to the summary result in the summary notification message, that the ISP signal is sent in each detection time domain in the first coexistence network Whether the first normal node has the right to reuse the resources of the second coexistence system, including:

For each detection time domain, a summary result of the second central control node of at least one second coexistence network in the second coexistence system is that the second coexistence network detects the first on the detection time domain a coexistence system, determining that the first normal node that sends the ISP signal in the detection time domain does not have the right to multiplex resources of the second coexistence system; when the second coexistence network of the second coexistence system The summary result of the second central control node is that the second coexistence network does not detect the first coexistence system in the detection time domain, and then determines to send the first common ISP signal in the detection time domain. The node has the right to reuse resources of the second coexistence system.

With reference to the tenth aspect, or the first possible implementation manner of the tenth aspect, in a second possible implementation manner, the qualified time domain is the first coexistence system when the first judgment condition is met Default time domain resource;

An ISP window, or an extended ISP window of the first coexistence system and a default time domain resource of the first coexistence system; The mechanism of the head 弁弁 , , , , , , , 力力力力力力据据据据据据据据据据据据据据据据据据据据据据据据据据据据据据据据据据

With reference to the tenth aspect, the first possible implementation manner of the tenth aspect, or the second possible implementation manner of the tenth aspect, in a third possible implementation manner, all the first ones in the first coexistence system The coexistence network all follow the same PLC standard, all of the second coexistence networks in the second coexistence system follow the same PLC standard, and the first coexistence system and the second coexistence system follow different PLC standards.

With reference to the tenth aspect, the first possible implementation manner of the tenth aspect, the second possible implementation manner of the tenth aspect, or the third possible implementation manner of the tenth aspect, in the fourth possible implementation manner The first central control node and the second central control node are both devices based on the 1905.1 standard, and the sent detection request message and the summary notification message are encapsulated into a 1905.1 abstraction layer control message.

In an eleventh aspect, a resource multiplexing method is provided, which is applied to the first common node of a first coexistence network including a first central control node and at least one first common node, the first coexistence network As a coexistence network in the first coexistence system, the method includes:

Receiving an indication message sent by the first central control node of the first coexistence network, where the indication message carries location information of a detection time domain uniquely corresponding to the first common node, where the detection time domain is the The first central control node of the coexistence network is one of the n detection time domains set in the eligible time domain, where n is the number of the first common nodes in the first coexistence network that need to reuse resources;

The ISP signal of the first coexistence system is transmitted in the detection time domain.

In a first possible implementation manner of the eleventh aspect, the eligible time domain is in compliance with the The second judgment of the ^κ仟^κ , is the extended ISP window of the first header system, or the default ISP window of the first coexistence system and the default time of the first coexistence system Domain resource

According to a twelfth aspect, a resource multiplexing method is provided, which is applied to the second central control node that includes a second coexistence network of a second central control node and at least one second common node, where the second coexistence The network is a coexistence network in the second coexistence system, and the method includes:

Receiving a detection request message sent by the first central control node of the first coexistence network in the first coexistence system, where the detection request message includes location information of the n detection time domains and type information of the first coexistence system;

Sending a detection event request message to each designated second common node of the second coexistence network, where the designated node is the second common node of any one of the second coexistence networks having a transmission requirement in a specific time period And/or the second central control node, the specific time period is a period of time that can be multiplexed by the first coexistence network determined by the second central control node, and the detection event request message is used for Instructing the designated node to detect whether to receive an ISP signal of the first coexistence system in the n detection time domains, so that the each designated node detects whether the first coexistence system is received in the n detection time domains The ISP signal, and reporting the detection result of each detection time domain to the second central control node through the detection result;

And summarizing the detection result report messages sent by the specified nodes, and obtaining summary results of the respective detection time domains; '/匚逋知消恩, so that the first T-heart pinch point is determined according to the result of the obscurity, knowing the total result of the consumer T, determining to send the ISP signal in each of the detection time domains Whether the first normal node has the right to reuse the resources of the second coexistence system.

In a first possible implementation manner of the twelfth aspect, the summarizing the detection result reported by each specified node to obtain a summary result of each detection time domain, including:

For each detection time domain, when the detection result of the at least one designated node of the second coexistence network is that the ISP signal of the first coexistence system is detected on the detection time domain, determining the summary result is The second coexistence network detects the first coexistence system on the detection time domain; when the detection results of the designated nodes of the second coexistence network are none detected on the detection time domain The ISP signal of the coexisting system determines that the summary result is that the second coexistence network does not detect the first coexistence system in the detection time domain.

With reference to the twelfth aspect, or the first possible implementation manner of the twelfth aspect, in the second possible implementation, all the first coexistence networks in the first coexistence system follow the same PLC standard, All of the second coexistence networks in the second coexistence system follow the same PLC standard, and the first coexistence system and the second coexistence system follow different PLC standards.

With reference to the twelfth aspect, the first possible implementation manner of the twelfth aspect, or the second possible implementation manner of the twelfth aspect, in a third possible implementation manner, the first central control node and The second central control node is a device based on the 1905.1 standard, and the detection request message and the summary notification message are encapsulated into a 1905.1 abstraction layer control message.

According to a thirteenth aspect, a resource multiplexing method is provided, where the second coexistence network is applied to the second common node that includes a second coexistence network of a second central control node and at least one second common node. As a coexistence network in the second coexistence system, the method includes:

Receiving a detection event request message sent by the second central control node of the second coexistence network, where the detection event request message is used to indicate that the designated node detects whether to receive the ISP signal of the first coexistence system in the n detection time domains, The designated node is the second common node and/or the second central control node having any one of the second coexistence networks having a transmission requirement in a specific time period, where the specific time period is a period of time determined by the second central control node;

Detecting whether the ISP signal is received in the n detection time domains;

And sending, by the detection result report message, the detection result of each detection time domain to the second central control node, so that the second central control node summarizes the respective fingers of the second coexistence network The first τ heart-kneading point of the first 弁m network sends a message of [forgetting the result] [forgot the result], so that the first central control node is in the summary notification message As a result of the aggregation, determining whether the first common node that sends the ISP signal in each detection time domain in the first coexistence network has the right to reuse resources of the second coexistence system.

In a first possible implementation manner of the thirteenth aspect, the detecting, in the n detecting time domains, whether the ISP signal is received, includes:

ISP signal.

With reference to the thirteenth aspect or the first possible implementation manner of the thirteenth aspect, in a second possible implementation manner, all the first coexistence networks in the first coexistence system follow the same PLC standard, All of the second coexistence networks in the second coexistence system follow the same PLC standard, and the first coexistence system and the second coexistence system follow different PLC standards.

With reference to the thirteenth aspect, the first possible implementation manner of the thirteenth aspect, or the second possible implementation manner of the thirteenth aspect, in a third possible implementation manner, the first central control node and The second central control node is a device based on the 1905.1 standard, and the summary notification message is encapsulated into a 1905.1 abstraction layer control message.

The beneficial effects of the technical solutions provided by the embodiments of the present invention are:

Setting, by the first central control node of the first coexistence network in the first coexistence system, n detection time domains on the eligible time domain, and notifying the n first common nodes that need to be multiplexed in the first coexistence network Transmitting the ISP signal of the first coexistence system in the n detection time domains, so that the designated node of each second coexistence network in the second coexistence system detects whether the ISP signal is received in the _n detection time domains, and the first central control node further Determining, according to the summary of the obtained detection results, whether the first common node has the right to reuse the resources of the second coexistence system; solving the problem that the G.9972 standard cannot allocate additional resources to the network in the prior art; if the first coexistence The ISP signal sent by the first common node in the network is not received by the second coexistence system, that is, the first common node transmits data and does not affect the second coexistence system, and the first common node can reuse the second coexistence system. Resources, when it is ensured that nodes located in a coexistence network in a coexistence system require additional resources, they can be reused without being affected by them. He coexists the resources of the system and improves the efficiency of resource utilization. DRAWINGS ^Introduction to mn early introduction, it is obvious that the attached ι3⁄4 instrument is a few embodiments of the invention, for those skilled in the art, without creative efforts Other drawings may also be obtained from these drawings.

1A is a schematic diagram of an ISP window allocated by the G.9972 standard for four coexistence systems in the prior art; FIG. 1B is a schematic diagram of the G.9972 standard time domain division in the prior art;

2 is a schematic diagram of a resource multiplexing system provided in an embodiment of the present invention;

3 is a schematic structural diagram of a first central control node provided in an embodiment of the present invention; FIG. 4 is a schematic structural diagram of a first central control node provided in another embodiment of the present invention; FIG. 5 is still another embodiment of the present invention; FIG. 6 is a schematic structural diagram of a first central control node provided in still another embodiment of the present invention; FIG. 7 is a structure of a first common node provided in an embodiment of the present invention; Schematic diagram

8 is a schematic structural diagram of a first common node provided in another embodiment of the present invention; FIG. 9 is a schematic structural diagram of a second central control node provided in an embodiment of the present invention; FIG. 10 is another embodiment of the present invention. FIG. 11 is a schematic structural diagram of a second central control node provided in still another embodiment of the present invention; FIG. 12 is a second central control node provided in still another embodiment of the present invention; FIG. 13 is a schematic structural diagram of a second common node provided in an embodiment of the present invention; FIG. 14 is a schematic structural diagram of a second common node provided in another embodiment of the present invention; FIG. 15 is still another embodiment of the present invention. FIG. 16 is a schematic structural diagram of a second common node provided in another embodiment of the present invention; FIG. 17 is a flowchart of a method for resource multiplexing provided in an embodiment of the present invention; Figure 18 is a flowchart of a method for resource multiplexing provided in another embodiment of the present invention; Figure 19 is another embodiment of the present invention FIG. 20 is a flowchart of a method for resource multiplexing provided in another embodiment of the present invention; FIG. 21A is a resource multiplexing method provided in still another embodiment of the present invention; FIG. 21B is a schematic diagram of a first eligible time domain provided in some embodiments of the present invention; FIG. 21C is a schematic diagram of a second qualified time domain provided in some embodiments of the present invention; 21D is a schematic diagram of a third eligible time domain provided in some embodiments of the present invention; FIG. 21E is a schematic diagram of a topology when two systems are provided in an embodiment of the present invention. For the invented jujube, the winter and the advantages and advantages of the slip, the next 3⁄4 will be attached! The embodiment of the invention is further described in detail.

In order to facilitate the understanding of the technical solution in the present invention, the following is a description of the basic concepts involved in the technical solution of the present invention:

Existing PLC technical standards may include: HomePlug 1.0, HomePlug AV, HomePlug AV2, HomePlug Green PHY and other standards developed by the HomePlug Alliance, G.hn, G.hnem, etc., defined by ITU-T , IEEE 1901, IEEE 1901.2, IEEE 1905.1 and other standards developed by IEEE, as well as PRIME standard and G3-PLC standard. The IEEE 1901 standard includes both the Access network part for smart grid applications and the In-Home network part for indoor broadband applications, while the In-Home part further includes Fu-based Part of the Transforming OFDM (FFT OFDM) and the part based on Wavelet OFDM (Wavelet OFDM).

The IEEE 1905.1 standard is a home networking standard that combines both wired and wireless technologies. IEEE 1905.1 defines a unified abstraction layer for different home networking technologies, and specifies some abstraction layer control messages, abstraction layer control messages. It can be transmitted between any device in the entire hybrid network, and any IEEE 1905.1 device can receive and recognize the abstraction layer control message.

The ITU-T G.9972 standard (also known as the G.cx standard) addresses the coexistence of four different PLC technologies: the Access part of IEEE 1901, the In-Home part based on FFT OFDM, and the Wavelet OFDM based In-Home section, G.hn.

The coexistence scheme of the G.9972 standard is as follows: Schematic diagram of the ISP window, where ACC represents the ISP window assigned to the 1901 access system, IHC1 after the interval represents the ISP window assigned to the 1901 FFT OFDM indoor system, and the IHC2 representative is assigned to 1901. The ISP window of the Wavelet OFDM indoor system, IH-G represents the ISP window assigned to the G.hn system, and the time interval between two adjacent ISP windows is ^T ISP.

G.9972 divides ⁷ ^ (6 AC cycles) into 3 TDMUs, each TDMU is 2 AC cycles, and each TDMU is subdivided into 8 TDMSs, and the time and position between them are due to any coexistence. The system can send the ISP signal in the assigned ISP window, and other coexistence systems can monitor the ISP signal in the ISP window, so it can be determined that the power line is simultaneously stored. Later, the heads of the system or the poor sources (that is, the TDMS 狈疋狈疋狈疋划分划分划分划分 ) ) ) ) ) ) ) ) ) ) ) ) ) ) TD TD TD TD TD TD TD TD TD TD TD TD TD TD TD TD TD TD TD TD TD . Referring to FIG. 2, a schematic diagram of a resource multiplexing system provided in one embodiment of the present invention is shown. The resource multiplexing system may include a first coexistence system A and a second coexistence system B, and the first coexistence system A includes at least one first coexistence network 220 including a first central control node 222 and at least one first common node 224. The second coexistence system B includes a second coexistence network 240 including a second central control node 242 and at least one second common node 244, since one of the first coexistence networks A in the first coexistence system A is multiplexing the second coexistence system B does not affect the other first coexistence network 220 in the first coexistence system A. Therefore, other first coexistence networks are omitted in FIG. 2. For convenience of description, only the first coexistence that needs to be multiplexed is as follows. The network 220 is described as an example.

For any first coexistence network 220 that needs to multiplex resources, the first central control node 222 in the first coexistence network 220 sets n detection time domains in the eligible time domain, and second to the second coexistence system B. The second central control node 242 of the coexistence network 240 sends a detection request message, where the detection request message includes location information of the n detection time domains and type information of the first coexistence network system A, and needs to be restored to the first coexistence network 220. The indication message is sent by the n first common nodes 224 of the resource, and the indication message carries the location information of the detection time domain uniquely corresponding to the first common node 224.

The first common node 224 of the first coexistence network 220 receives the indication message, and sends the inter-system protocol ISP signal corresponding to the first coexistence system A in the detection time domain corresponding to the first common node 224. The second coexistence network 240 The second central control node 242 receives the detection request message, and sends a detection event request message to each designated node of the second coexistence network 240, where the detection event request message is used to indicate that the designated node detects whether to receive the first coexistence system in the n detection time domains. The ISP signal of A, the designated node is a second common node 244 and/or a second central control node 242 having any transmission requirement in a certain time period of the second coexistence network 240, and the specific time period is the second central control node. 242 decided for a while.

If the detection event request message is transmitted between the second central control node 242 and the second normal node 244, the second central control node 242 and the second common node 244 are both located in the same second coexistence network 240. node.

Each designated node of the second coexistence network 240 detects whether the first is received in the n detection time domains. The second T-cylinder of the second ] ] » » » » 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 242 The first central control node 222 in a coexistence network 220 sends a summary notification message carrying the summary result.

The first central control node 222 of the first coexistence network 220 determines, according to the summary result in the summary notification message sent by the second central control node 242, the first common node in the first coexistence network 220 that transmits the ISP signal in each detection time domain. 224 has the right to reuse the resources of the second coexistence system.

In summary, the resource multiplexing system provided in the embodiment of the present invention sets n detection time domains in the eligible time domain by using the first central control node of the first coexistence network in the first coexistence system, and notifies the The n first common nodes that need to be multiplexed in the first coexistence network sequentially transmit the ISP signals of the first coexistence system in the n detection time domains, so that the designated nodes of the second coexistence network in the second coexistence system are at the n detection times If the domain detects whether the ISP signal is received, the first central control node further determines, according to the summary of the obtained detection results, whether the first common node has the right to reuse the resources of the second coexistence system; and solves the problem in the prior art due to G.9972 The standard cannot allocate additional resources to the network; if the ISP signal sent by the first common node in the first coexistence network is not received by the second coexistence system, that is, the transmission of data by the first ordinary node does not affect the second coexistence system. , the first common node can reuse the resources of the second coexistence system, and can be guaranteed to be located in a coexistence system. Nodes in the network when the need for additional resources, you can not reuse the resources of the other coexistent system of its impact, the effect of improving resource utilization. Still referring to Fig. 2, it may also be a schematic diagram of a resource reuse system provided in another embodiment of the present invention. The resource multiplexing system may include a first coexistence system Α and a second coexistence system 包括, the first coexistence system A including at least one first coexistence network 220 including a first central control node 222 and at least one first common node 224. The second coexistence system B includes a second coexistence network 240 including a second central control node 242 and at least one second common node 244, since one of the first coexistence networks A in the first coexistence system A is multiplexing the second coexistence system B does not affect another first coexistence network 220 in the first coexistence system A. Therefore, other first coexistence networks are omitted in FIG. 2. For convenience of description, only the first coexistence that needs to be multiplexed is as follows. The network 220 is described as an example.

For any first coexistence network 220 that needs to reuse resources, the first coexistence network 220 220 A is to re-use the n first destinations 224 of the poor source to send the donation, and the donation carries the location information of the detection time domain uniquely corresponding to the first common node 224.

The value of n mentioned here may be the total number of all nodes in the first coexistence network 220, or the number of partial nodes. Generally, the value of n is the same as the number of first common nodes 224 determined by the first central control node 222 that need to multiplex resources. For example, when the first central control node 222 allocates resources for each common node 224, If it is found that one or a part of the first common node 224 needs to occupy additional resources (such as when the traffic volume is relatively large), and the first central control node can allocate less resources for it, it can be determined that the first common node 224 has a complex The need for additional resources; 4) obviously, the first normal node 224 can send an allocation request message to the first central control node 222 for requesting the first central control node 222 to allocate additional resources to the first normal node 224, corresponding The first central control node 222 determines whether the first normal node 224 needs to multiplex additional resources according to the allocation request message.

The first common node 224 of the first coexistence network 220 receives the indication message, and transmits the inter-system protocol ISP signal corresponding to the first coexistence system A in the detection time domain.

In general, the first central control node 222 can instruct the first common node 224 to send an ISP signal in multiple manners, such as notifying a broadcast or unicast indication message or by transmitting a beacon frame carrying the indication message. There is no limit to this. Moreover, after the first normal node 224 receives the indication message, it can also reply to the first central control node 222 an acknowledgement message indicating that the indication message has been received. Whether the acknowledgment message is sent or not is not limited in this embodiment. It should be noted that the indication message and the confirmation message mentioned herein are generally not the EEE 1905.1 abstraction layer control message, but the control message in the first coexistence network 220.

In a possible implementation manner, for each predetermined first common node 224, the first central control node 222 may respectively send an indication message to the first common node 224, where each indication message carries one and the first The common node 224 uniquely detects the location information of the time domain. In another possible implementation, the first central control node 222 may multicast the indication message to the first common node 224, where the indication message carries n sets of correspondences, and each set of correspondences includes the first common node 224. The identification information and the location information of the detection time domain uniquely corresponding to the first normal node 224.

The first central control node 222 may further send a detection request message to the second central control node 242 of the second coexistence network 240 in the second coexistence system B, where the detection request message includes n detection time domains. The first 弁糸 ⁄ Μ 恩恩恩恩恩恩恩恩恩恩即即即即即即即即即即即即即即即即即即即即即即即即即即即即即即即即即即即即即即Different ISP signals; in addition, the detection request message may also carry the network label of the first coexistence network 220 (ie, to identify which network in the first coexistence system A is the first coexistence network A), n value, and the like.

The second central control node 242 of the second coexistence network 240 receives the detection request message, and sends a detection event request message to each designated second normal node 244 of the second coexistence network 240, and the detection event request message is used to indicate that the designated node is in the n The detection time domain detects whether the ISP signal of the first coexistence system A is received, wherein the designated node is the second common node 244 and/or the second center of any one of the second coexistence networks 240 having a transmission requirement within a specific time period. Control node 242, the particular time period is a period of time determined by second central control node 242.

That is, as long as any of the second common node 244 and the second central control node 242 of the second coexistence network 240 have transmission requirements for a certain period of time, they can all be designated nodes.

In a practical application, when determining the specific time period, the second terminal control node may include the following three situations:

In the first case, when the detection request message sent by the first central control node 222 carries the specified time period (ie, the first central control node 222 requests to arrange the detection time domain within the time period, and detects whether it can be recovered. With the resources of the second coexistence system B, if the second central control node 242 allows the first coexistence network 220 to detect whether the resources of the second coexistence system B can be multiplexed during the specified time period, the second central control node 242 The specified time period is determined to be a specific time period;

In the second case, when the detection request message sent by the first central control node 222 carries the specified time period, if the second central control node 242 does not allow the first coexistence network 220 to detect whether it can be recovered in the specified time period. With the resources of the second coexistence system B, the second central control node 242 can specify another specific time period, and then the second central control node 242 notifies the first central control node 222 of the other particular time period, so that the first center The control node 222 manages the first coexistence network 220 to detect whether the resources of the second coexistence system B can be multiplexed during the other specific time period.

In the third case, the second central control node 242 takes the default resource of the second coexistence network 240 as a particular time period.

If the detection event request message is transmitted between the second central control node 242 and the second normal node 244, the second central control node 242 and the second common node 244 are both located in the same second coexistence network 240. node. After detecting the ice consumption, the first heart-pinch point 222 of the first memory M-220 can be returned with a detection response message, and the detection response message is used to indicate that the second central control node 242 receives the first The detection request message sent by the central control node 222. Obviously, after receiving the detection request message, the second central control node 242 may further determine whether the resources of the second coexistence system B are allowed to be reused by other coexistence systems, if the resources of the second coexistence system allow other coexistence systems to recover. With the resource, the second central control node carries information indicating that the second coexistence network 240 accepts the multiplexing request of the first coexistence network 220 in the detection response message; otherwise, the second central control node is in the detection response message. Information carrying the second coexistence network 240 rejecting the first coexistence network 220 multiplexing request is carried. It should be noted that the detection request message and the detection response message mentioned herein are both IEEE 1905.1 abstract layer control messages, and the detection event request message is the control message in the second coexistence system 240, and in practical applications, the second The central control node 242 may also not respond to the detection response message, which is not limited in this embodiment.

Each designated node of the second coexistence network 240 detects whether the first central control node 242 sent to the second coexistence network 240 is received in the n detection time domains. It should be noted that when the second central control node 242 has a transmission requirement within a certain time period, the second central control node 242 itself becomes the designated node, that is, the second central control node 242 itself needs to be in the detection time domain. The ISP signal of the first coexistence system A is detected, and the detection result is summarized together with the detection results of other specified nodes.

In practical applications, each designated node detects whether the ISP signal of the first coexistence system A can be received in the n detection time domains, and each time the ISP signal of the first coexistence system A is detected, the second coexistence is performed. The second central control node 242 of the network 240 sends a detection result report message, where the detection result report message carries the detection result of detecting the ISP signal of the first coexistence network system A in the corresponding detection time domain; obviously, when the designated node is in a certain The ISP signal of the first coexistence system A is not detected in the detection time domain, and the detection result report message is sent to the second central control node 242 of the second coexistence network 240. The detection result report message carries the corresponding detection time domain. The detection result of the ISP signal of the first coexistence system A is not detected.

The second central control node 242 of the second coexistence network 240 aggregates the detection result report messages sent by the designated nodes of the second coexistence network 240, and obtains the summary result of each detection time domain, and controls the first center in the first coexistence network 220. The node 222 transmits a summary notification message carrying the summary results of the respective detection time domains. The result of the detection of the "suggested" of the deposits of the deposits is very good. The judgment is that the ISP of the first coexistence system A is detected by one or several designated nodes in the detection time domain. The detection result of the signal, and a summary notification message carrying the summary result of each detection time domain is transmitted to the first central control node 222 in the first coexistence network 220.

The first central control node 222 in the first coexistence network 220 determines, according to the summary result in the summary notification message sent by the second central control node 242 of the second coexistence network 240 in the second coexistence system B, that each of the first coexistence network 220 is internal. It is detected whether the first normal node 224 transmitting the ISP signal in the time domain has the right to multiplex the resources of the second coexistence system B.

In a first possible implementation manner based on the embodiment shown in FIG. 2, the second central control node 242 of the second coexistence network 240 aggregates the detection result report messages sent by the designated nodes of the second coexistence network 240, and obtains each The summary result of the detection time domain may include:

For each detection time domain, when the detection result of at least one designated node of the second coexistence network 240 is that the ISP signal of the first coexistence system A is detected in the detection time domain, the second central control node 242 determines that the summary result is The second coexistence network 240 detects the first coexistence system A on the detection time domain; when the detection result of each designated node of the second coexistence network 240 is that the ISP of the first coexistence system A is not detected in the detection time domain When the signal is received, the second central control node 242 determines that the summary result is that the second coexistence network 240 does not detect the first coexistence system A in the detection time domain.

In a second possible implementation based on the embodiment shown in FIG. 2,

The first central control node 222 of the first coexistence network 220 determines, according to the summary result in the summary notification message sent by the second central control node 242, the first common node in the first coexistence network 220 that transmits the ISP signal in each detection time domain. Whether the 224 has the right to reuse the resources of the second coexistence system B may include:

When there is a second coexistence network 240 in the second coexistence system B, for each detection time domain, when the summary result of the second central control node 242 of the second coexistence network 240 is the second coexistence network 240 at the time of detection The first coexistence system A is detected on the domain, and the first central control node 222 determines that the first normal node 224 that transmits the ISP signal in the detection time domain does not have the authority to multiplex the resources of the second coexistence system B; when the second coexistence The result of the aggregation of the second central control node 242 of the network 240 is that the second coexistence network 240 does not detect the first coexistence system A on the detection time domain, and the first central control node 222 determines to transmit the ISP signal in the detection time domain. The first normal node 224 has the right to reuse the resources of the second coexistence system B; n^X, when the second header system B is less than one second header network 240, the second centroid pinch point 242 is summarized as the second coexistence network 240 detects the first coexistence in the detection time domain System Α, the first central control node 222 determines that the first common node 224 transmitting the ISP signal in the detection time domain does not have the right to multiplex the resources of the second coexistence system; when the second coexistence system 各个 each second coexistence The summary result of the second central control node 242 of the network 240 is that the second coexistence network 240 does not detect the first coexistence system 该 in the detection time domain, and the first central control node 222 determines to transmit the ISP signal in the detection time domain. The first normal node 224 has the authority to multiplex the resources of the second coexistence system.

In a third possible implementation based on the embodiment shown in FIG. 2,

The qualified time domain mentioned above is the default time domain resource of the first coexistence system when the first judgment condition is met;

The qualified time domain mentioned above is the extended ISP window of the first coexistence system A or the extended ISP window of the first coexistence system A and the default time domain resource of the first coexistence system A when the second judgment condition is met. ;

The first determining condition is: the first coexistence system A determines the type and number of coexistence systems on the power line according to the ITU-T G.9972 ISP window mechanism, that is, the coexistence state, and determines coexistence according to the ITU-T G.9972 standard. Time domain resources allocated to the first coexistence system A in the state;

The second judgment condition is: the first coexistence system A determines the type and number of coexistence systems on the power line according to the topology discovery protocol in the IEEE 1905.1 standard, that is, the coexistence state, and determines the coexistence state according to the ITU-T G.9972 standard. Time domain resources allocated to the first coexistence system A;

The default time domain resource of the first coexistence system A refers to the time domain resource allocated by the first coexistence system A to the first coexistence system A according to the ITU-T G.9972 standard after determining the coexistence state of the power line A. ;

The extended ISP window of the first coexistence system A refers to a time domain having a predetermined duration from the ISP window of the first coexistence system A, and the predetermined duration is the duration of the n detection time domains.

It should be noted that, since the present embodiment is implemented based on the IEEE 1905.1 standard (that is, both the first central control node 222 and the second central control node 242 can be IEEE 1905.1 devices, that is, these nodes have an IEEE 1905.1 abstraction layer, Each node may send and receive an IEEE 1905.1 abstraction layer control message. Therefore, the detection request message, the detection response message, and the summary notification message sent between the first central control node 222 and the second central control node 242 may generally be IEEE 1905.1 abstraction layer control message, and first central control node 222 and first normal node 224 The detection contending ice, the detection response message, and the detection result message sent by the dimethyl heart kneading point 242 and the second gongming point 244 may be control messages in the second coexistence system B.

It should be further noted that when a first coexistence network 220 in the first coexistence system A searches for a reusable resource does not affect another first coexistence network 220 to search for reusable resources, That is, the process of finding different reusable resources in the first coexistence system A is independent of each other. When a first coexistence network 220 is looking for resources of the second coexistence system B, it is required that all the second coexistence networks 240 in the second coexistence system B determine whether the first coexistence system A is detected, if the second coexistence system B If all the second coexistence networks 240 do not detect the first coexistence system A, it indicates that the first coexistence network 220 in the first coexistence system A can multiplex the resources of the second coexistence system B. It is obvious that the second coexistence system B is a coexistence system selected by the first coexistence network 220 for finding reusable resources. If the first coexistence network 220 also wishes to reuse resources of other coexistence systems, it can also be Other coexisting systems look for reusable resources. For example, the first coexistence network 220 can simultaneously seek reusable resources to all other or selected coexistence systems; for example, it can sequentially seek reusable resources to all other or selected coexistence systems, when seeking a complex When the resources are used to satisfy the use of the first coexistence network 220, the re-use of the reusable resources for the remaining coexistence system is stopped.

In summary, the resource multiplexing system provided in the embodiment of the present invention sets n detection time domains in the qualified time domain by using the first central control node of the first coexistence network in the first coexistence system, and notifies the The n first common nodes in the first coexistence network that need to multiplex resources sequentially send the ISP signals of the first coexistence system in the n detection time domains, so that the designated nodes of the second coexistence network in the second coexistence system are in the n detections. The time domain detects whether the ISP signal is received, and the first central control node further determines, according to the summary of the obtained detection results, whether the first common node has the right to reuse the resources of the second coexistence system; The .9972 standard cannot allocate additional resources to the network; if the ISP signal sent by the first common node in the first coexistence network is not received by the second coexistence system, that is, the transmission of data by the first ordinary node does not affect the second In the coexistence system, the first common node can reuse the resources of the second coexistence system, so as to ensure that the coexistence network is located in a coexistence system. Nodes in the need for additional resources, we can not reuse the resources of the other coexistent system of its impact, the effect of improving resource utilization. Referring to FIG. 3, it shows a schematic structural diagram of a first central control node provided in an embodiment of the present invention. The first central control node is mainly applied to one of the systems shown in FIG. 2. The point can be: a resolution module 302, a first sending module 304, and a footstep module 306. The setting module 302 can be configured to set n detection time domains in the qualified time domain. The first sending module 304 can be configured to send an indication message to the n first common nodes in the first coexistence network that need to multiplex resources. The indication message carries the location information of the detection time domain uniquely corresponding to the first common node, so that the first common node sends the ISP signal of the first coexistence system in the detection time domain; the first sending module 304 can also be used to the second The second central control node of the second coexistence network in the coexistence system sends a detection request message, where the detection request message includes location information of the n detection time domains and type information of the first coexistence system, so that the second central control node Each designated node of the second coexistence network sends a detection event request message, where the detection event request message is used to instruct the designated node to detect whether to receive the ISP signal of the first coexistence system in the n detection time domains, when the n specified detection nodes Whether the ISP signal is received in the domain, and the detection result is sent to the second central control section through the detection result report message. And the second central control node summarizes the detection result report messages sent by the designated nodes, obtains the summary result of each detection time domain, and sends a summary notification message carrying the summary result to the first central control node, and the designated node is the first a second common node and/or a second central control node having a transmission requirement in a specific time period of any one of the two coexistence networks, wherein the specific time period is a period determined by the second central control node;

The determining module 306 is configured to receive, by the second central control node of each second coexistence network in the second coexistence system, a summary notification message, and determine, according to the summary result in the summary notification message, that the ISP is sent in each detection time domain in the first coexistence network. Whether the first normal node of the signal has the right to reuse the resources of the second coexistence system.

In summary, the first central control node provided in the embodiment of the present invention sets n detection time domains on the qualified time domain by using the first central control node of the first coexistence network in the first coexistence system, and notifies The n first common nodes that need to be multiplexed in the first coexistence network sequentially transmit the ISP signals of the first coexistence system in the n detection time domains, so that the designated nodes in the second coexistence network in the second coexistence system are in the n detections. The time domain detects whether the ISP signal is received, and the first central control node further determines, according to the summary of the obtained detection results, whether the first common node has the right to reuse the resources of the second coexistence system; The .9972 standard cannot allocate additional resources to the network; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal, that is, the transmission of data by the first ordinary node does not affect the second In the coexistence system, the first common node can reuse the resources of the second coexistence system, so as to ensure that the coexistence network is located in a coexistence system. The poor source uses a flat effect. Referring to FIG. 4, it shows a schematic structural diagram of a first central control node provided in another embodiment of the present invention. The first central control node is mainly applied to one of the systems shown in FIG. The first central control node 222 of the coexistence network 220 is exemplified. The first central control node may include: a setting module 402, a first sending module 404, and a determining module 406.

The setting module 402 can be configured to set n detection time domains in the qualified time domain; the value of η mentioned herein may be the total number of all nodes in the first coexistence network, or the number of partial nodes. Generally, the value of η is the same as the number of first common nodes that need to be multiplexed resources determined by the first central control node. For example, when the first central control node allocates resources for each common node, one of them is found or The traffic of some common nodes is relatively large, and when the resources allocated by the first central control node are relatively small, it can be determined that these first common nodes have the requirement of multiplexing additional resources; 4艮 obviously, the first common node can And sending, to the first central control node, an allocation request message for requesting the first central control node to allocate an additional resource to the first common node, and correspondingly, the first central control node determines, according to the allocation request message, whether the first common node needs to be restored. Use extra resources.

The first sending module 404 may be configured to send, to the first common node in the first coexistence network, the first normal node that needs to multiplex the resource, and the indication message carries the location information of the detection time domain that is uniquely corresponding to the first common node, so that The first common node sends the ISP signal of the first coexistence system in the detection time domain; the first sending module 404 is further configured to send a detection request message to the second central control node of the second coexistence network in the second coexistence system, the detecting The request message includes location information of the n detection time domains and type information of the first coexistence system, so that the second central control node sends a detection event request message to each designated node of the second coexistence network, and the detection event request message is used for Instructing the designated node to detect whether the ISP signal of the first coexistence system is received in the n detection time domains, and each of the designated nodes detects whether the ISP signal is received in the n detection time domains, and sends the detection result to the first report through the detection result report message. a second central control node; and the second central control node summarizes the respective designations The detection result of the detection result sent by the point is obtained, and the summary result of each detection time domain is obtained, and the summary notification message carrying the summary result is sent to the first central control node, indicating that the designated node is any one of the second coexistence networks within a certain time period. Transmitting a second common node and/or a second central control node of the demand, the specific time period being a period determined by the second central control node;

The type information of the first coexistence system mentioned here means that the first coexistence system is the G.9972 standard. In addition, the detection of 甫冰消恩 can also carry the network of the first head storage network (ie, which network in the first coexistence system is known as the first coexistence network), n value and other information.

The determining module 406 is configured to receive a summary notification message sent by the second central control node of each second coexistence network in the second coexistence system, and determine, according to the summary result in the summary notification message, that the first coexistence network sends the detection time in each detection time domain. Whether the first normal node of the ISP signal has the right to reuse the resources of the second coexistence system.

In a first possible implementation based on the embodiment shown in FIG. 4,

When there is a second coexistence network in the second coexistence system, the determining module 406 may include: a first determining unit 406a and a second determining unit 406b.

The first determining unit 406a may be configured to, for each detection time domain, when the summary result of the second central control node is that the second coexistence network detects the first coexistence system on the detection time domain, determining that the detection time is The first normal node that sends the ISP signal in the domain does not have the right to reuse the resources of the second coexistence system;

The second determining unit 406b may be configured to, for each detection time domain, determine that the detection is performed when the summary result of the second central control node is that the second coexistence network does not detect the first coexistence system on the detection time domain. The first common node that transmits the ISP signal in the time domain has the right to reuse the resources of the second coexistence system;

When there are two or more second coexistence networks in the second coexistence system, the determining module includes: a third determining unit 406c and a fourth determining unit 406d.

The third determining unit 406c may be configured to: for each detection time domain, a summary result of the second central control node of the at least one second coexistence network in the second coexistence system is that the second coexistence network is detected on the detection time domain The first coexistence system determines that the first common node that transmits the ISP signal in the detection time domain does not have the right to reuse the resources of the second coexistence system;

The fourth determining unit 406d may be configured to: for each detection time domain, when the summary result of the second central control node of each second coexistence network in the second coexistence system is that the second coexistence network is not detected on the detection time domain To the first coexistence system, it is determined that the first normal node transmitting the ISP signal in the detection time domain has the right to multiplex the resources of the second coexistence system.

In a second possible implementation based on the embodiment shown in FIG. 4,

The qualified time domain is the default time domain of the first coexistence system when it meets the first judgment condition. Or: T is the default ^ i or poor source of the extended 1SP and the first head of the first head system;

The first determining condition is: the first coexistence system determines the coexistence state of the coexistence system on the power line according to the ITU-T G.9972 ISP window mechanism, and determines the first coexistence state in the coexistence state according to the ITU-T G.9972 standard. Time domain resources of the system;

The second judgment condition is: the first coexistence system determines the coexistence state of the coexistence system on the power line according to the topology discovery protocol in the IEEE 1905.1 standard, and determines the coexistence state to be allocated to the first coexistence system according to the ITU-T G.9972 standard. Time domain resources;

The default time domain resource of the first coexistence system refers to the time domain resource allocated to the first coexistence system in the coexistence state according to the ITU-T G.9972 standard after determining the coexistence state of the power line on the first coexistence system;

The extended ISP window of the first coexistence system refers to a time domain having a predetermined duration from the ISP window of the first coexistence system, and the predetermined duration is the duration of the n detection time domains.

In a third possible implementation based on the embodiment shown in FIG. 4, all first coexistence networks in the first coexistence system follow the same PLC standard, and all second coexistence networks in the second coexistence system follow The same PLC standard, the first coexistence system and the second coexistence system follow different PLC standards.

In a fourth possible implementation manner of the embodiment shown in FIG. 4, the first central control node and the second central control node are both devices based on the IEEE 1905.1 standard, and the sent detection request message and the summary notification message are both It is encapsulated into an IEEE 1905.1 abstraction layer control message.

In summary, the first central control node provided in the embodiment of the present invention sets n detection time domains on the qualified time domain by using the first central control node of the first coexistence network in the first coexistence system, and notifies The n first common nodes that need to be multiplexed in the first coexistence network sequentially transmit the ISP signals of the first coexistence system in the n detection time domains, so that the designated nodes in the second coexistence network in the second coexistence system are in the n detections. The time domain detects whether the ISP signal is received, and the first central control node further determines, according to the summary of the obtained detection results, whether the first common node has the right to reuse the resources of the second coexistence system; The .9972 standard cannot allocate additional resources to the network; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal, that is, the transmission of data by the first ordinary node does not affect the second The coexistence system, the first common node can reuse the resources of the second coexistence system, and achieves a section that can ensure the coexistence network in a coexistence system. When the need for additional resources, you can not reuse resources from other systems to coexist its impact, improve Referring to FIG. 5, it is a schematic structural diagram of a first central control node provided in another embodiment of the present invention. The first central control node is mainly applied to one of the systems shown in FIG. The first central control node 222 of the coexistence network 220 is exemplified. The first central control node can include: a processor 502, a transmitter 504, and a receiver 506.

The processor 502 is configured to set n detection time domains in the qualified time domain;

The sender 504 is configured to send, to the n first common nodes in the first coexistence network, the indication message, where the message carries the location information of the detection time domain uniquely corresponding to the first common node, so that the first The ordinary node sends the ISP signal of the first coexistence system in the detection time domain;

The transmitter 504 is further configured to send a detection request message to the second central control node of the second coexistence network in the second coexistence system, where the detection request message includes location information of the n detection time domains and type information of the first coexistence system. So that the second central control node sends a detection event request message to each designated node of the second coexistence network, and the detection event request message is used to indicate that the designated node detects whether the ISP signal of the first coexistence system is received in the n detection time domains, Each of the designated nodes detects whether the ISP signal is received in the n detection time domains, and sends the detection result to the second central control node through the detection result report message; and the second central control node summarizes the detection result report message sent by each designated node. Obtaining a summary result of each detection time domain, and sending a summary notification message carrying the summary result to the first central control node, where the designated node is a second common node of any of the second coexistence networks having a transmission requirement within a specific time period and/or Or the second central control node, for a specific time period Two central control node determines a period of time;

The receiver 506 is configured to receive a summary notification message sent by the second central control node of each second coexistence network in the second coexistence system;

The processor 502 is further configured to determine, according to the summary result in the summary notification message received by the receiver 506, whether the first common node that sends the ISP signal in each detection time domain in the first coexistence network has a second coexistence system. Permissions for resources.

In summary, the first central control node provided in the embodiment of the present invention sets n detection time domains on the qualified time domain by using the first central control node of the first coexistence network in the first coexistence system, and notifies The n first common nodes that need to be multiplexed in the first coexistence network sequentially transmit the ISP signals of the first coexistence system in the n detection time domains, so that the designated nodes in the second coexistence network in the second coexistence system are in the n detections. Whether the time domain detects whether the ISP signal is received, and the first central control node is further based on Limitation; Solve the current ^ "抆水甲 G.9972 称〗尤为为为为为网络为为为为为 ; ; ; ; ; ; ; ; ; ; ; ; ; ; ; 如果如果如果如果如果如果如果如果如果如果如果如果如果如果如果如果When the system receives, that is, the first common node transmits data and does not affect the second coexistence system, the first common node can reuse the resources of the second coexistence system, and achieves a node that can ensure the coexistence network in a coexistence system. When additional resources are needed, the resources of other coexisting systems that are not affected by them can be reused, and the effect of resource utilization is improved. Referring to FIG. 6, which shows the first embodiment of the present invention. A schematic diagram of a central control node, the first central control node is mainly illustrated by being applied to a first central control node 222 of one of the first coexistence networks 220 of the system shown in Fig. 2. The first central control node The processor 602, the transmitter 604, the receiver 606, and the memory 608, wherein the processor 602 is coupled to the transmitter 604, the receiver 606, and the memory 608, respectively. At least one type of computer software is stored in the memory 608, and the processor 602 can implement corresponding operations according to the computer software stored in the memory 608.

The processor 602 is configured to set n detection time domains in the qualified time domain;

The value of η mentioned here may be the total number of all nodes in the first coexistence network, or the number of partial nodes. Generally, the value of η is the same as the number of first common nodes that need to be multiplexed resources determined by the first central control node. For example, when the first central control node allocates resources for each common node, one of them is found or The traffic of some common nodes is relatively large, and when the resources allocated by the first central control node are relatively small, it can be determined that these first common nodes have the requirement of multiplexing additional resources; 4艮 obviously, the first common node can And sending, to the first central control node, an allocation request message for requesting the first central control node to allocate an additional resource to the first common node, and correspondingly, the first central control node determines, according to the allocation request message, whether the first common node needs to be restored. Use extra resources.

The sending unit 604 is configured to send, to the first common node in the first coexistence network, the indication message, where the message carries the location information of the detection time domain uniquely corresponding to the first common node, so that the first The ordinary node sends the ISP signal of the first coexistence system in the detection time domain;

The transmitter 604 is further configured to send, to the second central control node of the second coexistence network in the second coexistence system, a detection request message, where the detection request message includes the location information of the n detection time domains and the type of the first coexistence system. Information, so that the second central control node sends a detection event request message to each designated node of the second coexistence network, and the detection event request message is used to indicate that the specified node is in the n check The detection in the domain is: receiving the ISP 1 loss, and transmitting the detection result 逋迓 the detection result to the second central control node; and the second central control node summarizes the detection results sent by the designated nodes The report message is obtained, and the summary result of each detection time domain is obtained, and the summary notification message carrying the summary result is sent to the first central control node, and the designated node is the second common one of the second coexistence network having the transmission requirement in the specific time period. a node and/or a second central control node, the specific time period being a period of time determined by the second central control node;

The type of the first coexistence system mentioned here means that the first coexistence system is one of the four coexistence systems in the G.9972 standard, so different types of coexistence systems correspond to different ISP signals; further, the detection request message The network label of the first coexistence network (ie, which network in the first coexistence system is used to identify the first coexistence network), the n value, and the like may also be carried.

The receiver 606 is configured to receive a summary notification message sent by the second central control node of each second coexistence network in the second coexistence system;

The processor 602 is further configured to determine, according to the summary result in the summary notification message received by the receiver 606, whether the first common node that sends the ISP signal in each detection time domain in the first coexistence network has a second coexistence system. Permissions for resources.

In a first possible implementation based on the embodiment shown in FIG. 6,

When there is a second coexistence network in the second coexistence system, the processor 602 may be further configured, for each detection time domain, when the summary result of the second central control node is the second coexistence network in the detection time domain. When the first coexistence system is detected, determining that the first common node that sends the ISP signal in the detection time domain does not have the right to reuse the resources of the second coexistence system;

The processor 602 is further configured to: when, for each detection time domain, when the summary result of the second central control node is that the second coexistence network does not detect the first coexistence system on the detection time domain, determine that the detection time is The first common node that sends the ISP signal in the domain has the right to multiplex the resources of the second coexistence system; when there are two or more second coexistence networks in the second coexistence system, the processor 602 can also be used for each Detecting the time domain, when the summary result of the second central control node of the at least one second coexistence network in the second coexistence system is that the second coexistence network detects the first coexistence system on the detection time domain, determining the detection time domain The first normal node that sends the ISP signal does not have the right to reuse the resources of the second coexistence system;

The processor 602 is further configured to: for each detection time domain, when the summary result of the second central control node of each second coexistence network in the second coexistence system is the second coexistence network on the detection time domain ^ "Reuse the limits of the second source of the poor.

In a second possible implementation based on the embodiment shown in FIG. 6,

The qualified time domain is the default time domain resource of the first coexistence system when the first judgment condition is met;

If the qualified time domain meets the second judgment condition, it is an extended ISP window of the first coexistence system, or an extended ISP window of the first coexistence system and a default time domain resource of the first coexistence system;

In a third possible implementation based on the embodiment shown in FIG. 6, all first coexistence networks in the first coexistence system follow the same PLC standard, and all second coexistence networks in the second coexistence system follow The same PLC standard, the first coexistence system and the second coexistence system follow different PLC standards.

In a fourth possible implementation manner of the embodiment shown in FIG. 6, the first central control node and the second central control node are both devices based on the IEEE 1905.1 standard, and the sent detection request message and the summary notification message are both It is encapsulated into an IEEE 1905.1 abstraction layer control message.

In summary, the first central control node provided in the embodiment of the present invention sets n detection time domains on the qualified time domain by using the first central control node of the first coexistence network in the first coexistence system, and notifies The n first common nodes that need to be multiplexed in the first coexistence network sequentially transmit the ISP signals of the first coexistence system in the n detection time domains, so that the designated nodes in the second coexistence network in the second coexistence system are in the n detections. The time domain detects whether the ISP signal is received, and the first central control node further determines, according to the summary of the obtained detection results, whether the first common node has the resources of multiplexing the second coexistence system. If the first head 弁m τ is the first point of the 逋 1 is is is is is is is is is is is is is is is is is """"""""""" is is is is is is is The first common node can reuse the resources of the second coexistence system, and can ensure that the nodes coexisting in the coexistence system can re-use the resources of other coexistence systems that are not affected by them when additional resources are needed. The effect of resource utilization is shown in Figure 7, which shows a schematic structural diagram of a first common node provided in an embodiment of the present invention. The first common node is mainly applied to the system shown in Figure 2. An example is shown in the first common node 224 of the first coexistence network 220. The first common node may include: a first receiving module 702 and a second sending module 704.

The first receiving module 702 is configured to receive the indication message sent by the first central control node of the first coexistence network, where the indication message carries the location information of the detection time domain uniquely corresponding to the first common node, and the detection time domain is the first coexistence The first central control node of the network is one of the n detection time domains set in the eligible time domain, and η is the number of the first common nodes in the first coexistence network that need to reuse resources; the second sending module 704, It can be used to send the ISP signal of the first coexistence system in the detection time domain. In summary, the first common node provided in the embodiment of the present invention sends the _ISP signal of the first coexistence system in the detection time domain notified by the first central control node in the first coexistence system, so as to be in the second coexistence system. The designated node detects whether the ISP signal is received in the specified n detection time domains, so that the first central control node can determine, according to the summary of the obtained detection results, whether the first common node has the resources of the second coexistence system. Privilege; solves the problem in the prior art that the G.9972 standard cannot allocate additional resources to the network; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal, that is, the first If the transmission data of a common node does not affect the second coexistence system, the first common node can reuse the resources of the second coexistence system, so as to ensure that the nodes coexisting in the coexistence system of the coexistence system need additional resources. Resources of other coexisting systems that are not affected by them can be reused, and the effect of resource utilization is improved. Still referring to FIG. 7, which also shows a schematic structural diagram of a first common node provided in another embodiment, the first common node is mainly applied to one of the first coexistence networks 220 in the system shown in FIG. 2. The first common node 224 is illustrated in the example. The first common node may include: a first receiving module 702 and a second sending module 704. Show the consumption, donate the consumption and bring ^^} ^ a point of detection of a pair of points or the date of 1 恩, detection time domain is the first central control node of the first coexistence network set in the eligible time domain One of the n detection time domains, n is the number of the first common nodes in the first coexistence network that need to multiplex resources; the second sending module 704 can be used to send the ISP of the first coexistence system in the detection time domain. signal. In a possible implementation manner of the embodiment, the qualified time domain is a default time domain resource of the first coexistence system when the first determining condition is met;

The first determining condition is: the first coexistence system determines the coexistence state of the coexistence system on the power line according to the ITU-T G.9972 ISP window mechanism, and determines the first coexistence state to be assigned to the first according to the ITU-T G.9972 standard. Time domain resources of the coexistence system;

In summary, the first common node provided in the embodiment of the present invention sends the _ISP signal of the first coexistence system in the detection time domain notified by the first central control node in the first coexistence system, so as to be in the second coexistence system. The designated node detects whether the ISP signal is received in the specified n detection time domains, so that the first central control node can determine, according to the summary of the obtained detection results, whether the first common node has the resources of the second coexistence system. Privilege; solves the problem in the prior art that the G.9972 standard cannot allocate additional resources to the network; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal, that is, the first If the transmission data of a common node does not affect the second coexistence system, the first common node can reuse the resources of the second coexistence system, so as to ensure that the nodes coexisting in the coexistence system of the coexistence system need additional resources. Resources of other coexisting systems that are not affected by them can be reused, and the effect of resource utilization is improved. The structure indicates that the first point is to be exemplified in the first common node 224 of the first header network 220 for the system shown in FIG. The first common node may include: a receiver 802 and a transmitter 804.

The receiver 802 is configured to receive the indication information that is sent by the first central control node of the first coexistence network and that carries the detection time domain, and the detection time domain is that the first central control node of the first coexistence network is in the time domain that meets the condition. One of the set of n detection time domains;

The transmitter 804 can be configured to send the ISP signal of the first coexistence system in the detection time domain.

In summary, the first common node provided in the embodiment of the present invention sends the _ISP signal of the first coexistence system in the detection time domain notified by the first central control node in the first coexistence system, so as to be in the second coexistence system. The designated node detects whether the ISP signal is received in the specified n detection time domains, so that the first central control node can determine, according to the summary of the obtained detection results, whether the first common node has the resources of the second coexistence system. Privilege; solves the problem in the prior art that the G.9972 standard cannot allocate additional resources to the network; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal, that is, the first If the transmission data of a common node does not affect the second coexistence system, the first common node can reuse the resources of the second coexistence system, so as to ensure that the nodes coexisting in the coexistence system of the coexistence system need additional resources. Resources of other coexisting systems that are not affected by them can be reused, and the effect of resource utilization is improved. Still referring to FIG. 8 , it also shows a schematic structural diagram of a first common node provided in another embodiment of the present invention. The first common node is mainly applied to one of the first coexistences in the system shown in FIG. 2 . An illustration is made in the first normal node 224 of the network 220. The first common node may include: a receiver 802 and a transmitter 804.

The receiver 802 is configured to receive the indication information that is sent by the first central control node of the first coexistence network and that carries the detection time domain, and the detection time domain is that the first central control node of the first coexistence network is in the time domain that meets the condition. One of the n detection time domains set;

In a possible implementation manner of the embodiment, the qualified time domain is a default time domain resource of the first coexistence system when the first determining condition is met;

If the qualified time domain meets the second judgment condition, it is an extended ISP window of the first coexistence system, or an extended ISP window of the first coexistence system and a default time domain resource of the first coexistence system; The header of the head-and-storage system on the 3⁄4 force line is opened, and the time domain resources allocated to the first coexistence system are classified according to ITU-T G.9972.

In summary, the first common node provided in the embodiment of the present invention sends the _ISP signal of the first coexistence system in the detection time domain notified by the first central control node in the first coexistence system, so as to be in the second coexistence system. The designated node detects whether the ISP signal is received in the specified n detection time domains, so that the first central control node can determine, according to the summary of the obtained detection results, whether the first common node has the resources of the second coexistence system. Privilege; solves the problem in the prior art that the G.9972 standard cannot allocate additional resources to the network; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal, that is, the first If the transmission data of a common node does not affect the second coexistence system, the first common node can reuse the resources of the second coexistence system, so as to ensure that the nodes coexisting in the coexistence system of the coexistence system need additional resources. Resources of other coexisting systems that are not affected by them can be reused, and the effect of resource utilization is improved. Referring to FIG. 9 , it is a schematic structural diagram of a second central control node provided in an embodiment of the present invention. The second central control node is mainly applied to one of the second coexistence networks of the system shown in FIG. 2 . An example is illustrated in the second central control node 242 of 240. The second central control node may include: a second receiving module 902, a third sending module 904, and a summary module 906.

The second receiving module 902 is configured to receive a detection request message sent by the first central control node of the first coexistence network in the first coexistence system, where the detection request message includes location information of the n detection time domains and the first coexistence system Type information

The third sending module 904 may be configured to send a detection event request message to each designated node of the second coexistence network, where the designated node has a transmission requirement for any one of the second coexistence networks in a specific time period. Ε Ε ⁄ Ί Ί 检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测 η η η η η η η η η η η η η η η η η η η η η η η η η η η η η Receiving the ISP signal of the first coexistence system, and sending the detection result of each detection time domain to the second central control node by using the detection result report message, wherein the ISP signal is the first central control node of the first coexistence network to the first The n first common nodes that need to be multiplexed in the coexistence network send an indication message, and when the indication message carries the location information of the detection time domain uniquely corresponding to the first common node, the first common node sends the first time in the detection time domain. ISP signal of the coexistence system;

The summary module 906 can be used to summarize the detection result report messages sent by the specified nodes, and obtain the summary result of each detection time domain;

The third sending module 904 is further configured to send, to the first central control node in the first coexistence network, a summary notification message carrying the summary result, so that the first central control node determines the first according to the summary result in the summary notification message. Whether the first common node that transmits the ISP signal in each detection time domain in the coexistence network has the right to multiplex the resources of the second coexistence system.

In summary, the second central control node provided in the embodiment of the present invention notifies the n detection areas sent by the first central control node of the first coexistence network in the first coexistence system to the designated node in the second coexistence system, So that the designated node detects whether the ISP signal of the first coexistence system is received in the n detection time domains, so that the first central control node determines whether the first common node has the second shared coexistence system according to the summary of the obtained detection results. Permissions of resources; solved the problems in the prior art

The G.9972 standard cannot allocate additional resources to the network; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal, that is, the transmission of data by the first ordinary node does not affect the first In the second coexistence system, the first common node can reuse the resources of the second coexistence system, and the node that can ensure that the coexistence network in a coexistence system can re-use other resources that are not affected by the coexistence network in a coexistence system. The resources of the coexistence system improve the effect of resource utilization. Referring to FIG. 10, it is a schematic structural diagram of a second central control node provided in another embodiment of the present invention. The second central control node is mainly applied to one of the systems shown in FIG. The second central control node 242 of the coexistence network 240 is exemplified. The second central control node may include a second receiving module 1002, a third transmitting module 1004, and a summary module 1006.

The second receiving module 1002 is configured to receive, by the first central control node of the first coexistence network in the first coexistence system, a detection request message, where the detection request message has n detection time domain location letters. After the purchase of the τ, the second heart-pinch point of the second head-storage network receives the message of the detection of the ice, and may reply a first response message to the first central control node in the first coexistence network, the detection response message And configured to indicate that the second central control node receives the detection request message sent by the first central control node. Obviously, after receiving the detection request message, the second central control node may further determine whether the resources of the second coexistence system are allowed to be multiplexed by other coexistence systems, if the resources of the second coexistence system allow other coexistence systems to reuse resources. And the second central control node carries, in the detection response message, information indicating that the second coexistence network accepts the first coexistence network multiplexing request; otherwise, the second central control node carries the indication in the detection response message. The second coexistence network rejects the information of the first coexistence network multiplexing request. It should be noted that the detection request message and the detection response message mentioned herein are both 1905.1 abstract layer control messages, and the detection request message is a control message in the second coexistence system, and in practical applications, the second center control The node may also not reply to the detection response message, which is not limited in this embodiment.

The third sending module 1004 may be configured to send a detection event request message to each designated node of the second coexistence network, where the designated node is a second common node of any one of the second coexistence networks that has a transmission requirement in a specific time period and/or a second central control node, the specific time period is a period determined by the second central control node, and the detection event request message is used to instruct the designated node to detect whether to receive the ISP signal of the first coexistence system in the n detection time domains, so as to specify each The node detects whether the ISP signal of the first coexistence system is received in the n detection time domain, and sends the detection result of each detection time domain to the second central control node by using the detection result report message, where the ISP signal is the first coexistence network. The first central control node sends an indication message to the n first common nodes that need to be multiplexed in the first coexistence network, where the indication message carries the location information of the detection time domain uniquely corresponding to the first common node, The ISP signal of the first coexistence system sent by the node in detecting the time domain;

The summary module 1006 can be used to summarize the detection result report messages sent by each designated node, and obtain the summary result of each detection time domain;

In an actual application, for each detection time domain, the second central control node determines, according to all the detection result reports sent by the specified nodes of the second coexistence network, whether there is a specified one or several specified in the detection time domain. The node detects the detection result of the signal of the first coexistence system, and sends a summary notification message carrying the summary result of each detection time domain to the first central control node in the first coexistence network.

It is worth noting that when the second central control node has transmission requirements within a certain period of time, then 3 or on the 1SP 1 loss of the tester, the test results are summarized together with the test results with his donation points. The third sending module 1004 is further configured to send, to the first central control node in the first coexistence network, a summary notification message carrying the summary result, so that the first central control node determines the first according to the summary result in the summary notification message. Whether the first common node that transmits the ISP signal in each detection time domain in the coexistence network has the right to multiplex the resources of the second coexistence system.

In a first possible implementation manner of the embodiment shown in FIG. 10, the summary module 1006 may include: a fifth determining unit 1006a and a sixth determining unit 1006b.

The fifth determining unit 1006a may be configured to, for each detection time domain, determine a summary result when the detection result of the at least one designated node of the second coexistence network is that the ISP signal of the first coexistence system is detected on the detection time domain. Detecting a first coexistence system on the detection time domain for the second coexistence network;

The sixth determining unit 1006b may be configured to determine, when the detection result of each designated node of the second coexistence network is that the ISP signal of the first coexistence system is not detected in the detection time domain, for each detection time domain, As a result, the second coexistence network does not detect the first coexistence system in the detection time domain.

In a second possible implementation manner of the embodiment shown in FIG. 10, all the first coexistence networks in the first coexistence system follow the same PLC standard, and all the second coexistence networks in the second coexistence system follow the same The PLC standard, the first coexistence system and the second coexistence system follow different PLC standards.

In a third possible implementation manner of the embodiment shown in FIG. 10, the first central control node and the second central control node are both devices based on the 1905.1 standard, and the detection request message and the summary notification message are encapsulated into a 1905.1 abstraction layer. Control messages.

In summary, the second central control node provided in the embodiment of the present invention notifies the n detection areas sent by the first central control node of the first coexistence network in the first coexistence system to the designation in the second coexistence system. a node, so that the designated node detects whether the ISP signal of the first coexistence system is received in the n detection time domains, so that the first central control node determines whether the first common node has the second multiplexing according to the summary of the obtained detection results. The authority of the resources of the coexistence system; solves the problem that the prior art cannot allocate additional resources to the network due to the G.9972 standard; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal To that, that is, the first ordinary node transmits data does not affect the second coexistence system, the first common node can reuse the resources of the second coexistence system, and the node that can coexist in the coexistence network in a coexistence system is needed. When additional resources are available, resources of other coexisting systems that are not affected by them can be reused, and the effect of resource utilization is improved. Buckwheat sees l3⁄4 11 , which shows a schematic structural diagram of a second centripetal kneading node provided by the invention, which is mainly used in the system shown in FIG. 2 . An example is illustrated in the second central control node 242 of a second coexistence network 240. The second central control node can include: a receiver 1102, a transmitter 1104, and a processor 1106.

The receiver 1102 is configured to receive a detection request message sent by the first central control node of the first coexistence network in the first coexistence system, where the detection request message includes the location information of the n detection time domains and the type information of the first coexistence system. ;

The transmitter 1104 is configured to send a detection event request message to each designated node of the second coexistence network, where the designated node is a second common node and/or a second of any one of the second coexistence networks that has a transmission requirement in a specific time period. a central control node, the specific time period is a period determined by the second central control node, and the detection event request message is used to indicate that the designated node detects whether to receive the ISP signal of the first coexistence system in the n detection time domains, so that each designated node is η detecting time domain detection whether the first transmission is sent to the second central control node, and the ISP signal is that the first central control node of the first coexistence network sends an indication message to the n first common nodes that need to be multiplexed in the first coexistence network. When the indication message carries the location information of the detection time domain that is uniquely corresponding to the first common node, the ISP signal of the first coexistence system sent by the first common node in the detection time domain;

The processor 1106 is configured to summarize the detection result report message sent by each specified node, and obtain a summary result of each detection time domain.

The transmitter 1104 is further configured to send, to the first central control node in the first coexistence network, a summary notification message carrying the summary result, so that the first central control node determines the first coexistence network according to the summary result in the summary notification message. Whether the first common node that internally transmits the ISP signal in each detection time domain has the right to multiplex the resources of the second coexistence system.

In summary, the second central control node provided in the embodiment of the present invention notifies the n detection areas sent by the first central control node of the first coexistence network in the first coexistence system to the designation in the second coexistence system. a node, so that the designated node detects whether the ISP signal of the first coexistence system is received in the n detection time domains, so that the first central control node determines whether the first common node has the second multiplexing according to the summary of the obtained detection results. The authority of the resources of the coexistence system; solves the problem that the prior art cannot allocate additional resources to the network due to the G.9972 standard; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal To, that is, the first ordinary node transmits data It can be used to identify the resources of a coexisting system that is not affected by it. It can improve the resource utilization efficiency. Referring to FIG. 12, it shows a schematic structural diagram of a second central control node provided in another embodiment of the present invention. The second central control node is mainly applied to one of the systems shown in FIG. The second central control node 242 of the coexistence network 240 is exemplified. The second central control node may include: a receiver 1202, a transmitter 1204, a processor 1206, and a memory 1208. The processor 1206 may be coupled to the receiver 1202, the transmitter 1204, and the memory 1208, respectively. The memory 1208 may store at least one type. Computer software, processor 1206 can utilize the computer software stored in memory 1208 to perform related operations.

The receiver 1202 is configured to receive, by the first central control node of the first coexistence network in the first coexistence system, a detection request message, where the detection request message has location information of the n detection time domains and a type of the first coexistence system. Detecting request information;

In a practical application, after receiving the detection request message, the second central control node of the second coexistence network may reply a first response control message to the first central control node in the first coexistence network, where the detection response message is used to indicate The second central control node receives the detection request message sent by the first central control node. Obviously, after receiving the detection request message, the second central control node may further determine whether the resources of the second coexistence system are allowed to be multiplexed by other coexistence systems, if the resources of the second coexistence system allow other coexistence systems to reuse resources. The second central control node detection response message carries information indicating that the second coexistence network accepts the first coexistence network multiplexing request; otherwise, the second central control node carries the indication message in the detection response message. The second coexistence network rejects the information of the first coexistence network multiplexing request. It should be noted that the detection request message and the detection response message mentioned herein are both EEE 1905.1 abstract layer control messages, and the detection request message is a control message in the second coexistence system, and in practical applications, the second central control The node may also not reply to the detection response message, which is not limited in this embodiment.

The transmitter 1204 may be configured to send a detection event request message to each designated node of the second coexistence network, where the designated node is a second common node and/or a second of any one of the second coexistence networks that has a transmission requirement in a specific time period. a central control node, the specific time period is a period determined by the second central control node, and the detection event request message is used to indicate that the designated node detects whether to receive the ISP signal of the first coexistence system in the n detection time domains, so that each designated node is Whether n detection time domain detection receives the first Sending to the second centroid pinch point, the isp 1¥ loss is the first centroid pinch point of the first header m network to send an indication message to the n first common nodes that need to be multiplexed in the first coexistence network, indicating When the message carries the location information of the detection time domain that is uniquely corresponding to the first common node, the ISP signal of the first coexistence system sent by the first common node in the detection time domain;

The processor 1206 can be used to:

Summarizing the detection result report messages sent by each specified node, and obtaining summary results of each detection time domain;

It is worth noting that when the second central control node has a transmission requirement within a certain time period, the second central control node itself becomes the designated node, that is, the second central control node itself needs to detect the first in the detection time domain. Coexist the ISP signal of the system and summarize the test results together with the test results of other specified nodes. The transmitter 1204 is further configured to send, to the first central control node in the first coexistence network, a summary notification message carrying the summary result, so that the first central control node determines the first coexistence network according to the summary result in the summary notification message. Whether the first common node that internally transmits the ISP signal in each detection time domain has the right to multiplex the resources of the second coexistence system.

In a first possible implementation manner based on the embodiment shown in FIG. 12, the processor 1206 may be further configured, for each detection time slot, when the detection result of the at least one designated node of the second coexistence network is When the ISP signal of the first coexistence system is detected in the detection time domain, it is determined that the summary result is that the second coexistence network detects the first coexistence system in the detection time domain;

The processor 1206 may be further configured to: for each detection time slot, when the detection result of each designated node of the second coexistence network is that the ISP signal of the first coexistence system is not detected in the detection time domain, the summary result is determined. The first coexistence system is not detected in the detection time domain for the second coexistence network.

In a second possible implementation manner of the embodiment shown in FIG. 12, all the first coexistence networks in the first coexistence system follow the same PLC standard, and all the second coexistence networks in the second coexistence system follow the same The PLC standard, the first coexistence system and the second coexistence system follow different PLC standards. And the second heart-kneading point is based on the discussion of 1905.1. The detection of 甫冰消恩 and '/[forgetting the message is encapsulated into 1905.1 abstraction layer control message.

In summary, the second central control node provided in the embodiment of the present invention notifies the n detection areas sent by the first central control node of the first coexistence network in the first coexistence system to the designation in the second coexistence system. a node, so that the designated node detects whether the ISP signal of the first coexistence system is received in the n detection time domains, so that the first central control node determines whether the first common node has the second multiplexing according to the summary of the obtained detection results. The authority of the resources of the coexistence system; solves the problem that the prior art cannot allocate additional resources to the network due to the G.9972 standard; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal To that, that is, the first ordinary node transmits data does not affect the second coexistence system, the first common node can reuse the resources of the second coexistence system, and the node that can coexist in the coexistence network in a coexistence system is needed. When additional resources are available, resources of other coexisting systems that are not affected by them can be reused, and resource utilization is improved. Effect. Referring to FIG. 13, which is a schematic structural diagram of a second common node provided in an embodiment of the present invention, the second common node is mainly applied to one of the second coexistence networks 240 in the system shown in FIG. 2. An example of the second normal node 244 is illustrated. The second common node may include: a third receiving module 1302, a detecting module 1304, and a fourth sending module 1306.

The third receiving module 1302 is configured to receive a detection event request message sent by the second central control node of the second coexistence network, where the detection event request message is used to indicate that the designated node detects whether to receive the first coexistence system in the n detection time domains. The ISP signal, the designated node is a second common node and/or a second central control node having any transmission requirement in a certain time period in the second coexistence network, and the specific time period is a segment determined by the second central control node The ISP signal is that the first central control node of the first coexistence network in the first coexistence system sends an indication message to the n first common nodes in the first coexistence network that need to multiplex resources, and the indication message carries one and the first common When the node uniquely detects the location information of the time domain, the first common node sends the ISP signal of the first coexistence system in the detection time domain; the detecting module 1304 can be configured to detect whether the ISP signal is received in the n detection time domains. The fourth sending module 1306 can be configured to pass the detection result of each detection time domain detected by the detecting module through the detection result. Sending a message to the second central control node of the second coexistence network, so that the second central control node aggregates the detection result report messages sent by the designated nodes of the second coexistence network, and obtains the summary result of each detection time domain, and obtains the first result The first central control node of the coexistence network sends and carries 〉Forget the result, 碉疋The first point in the network that detects or sends the ISP 1 loss has the right to reuse the resources of the second coexistence system.

In summary, the second common node provided in the embodiment of the present invention receives the n detection regions sent by the second central control node and the type of the first coexistence system, and detects whether the first detection time domain is received. The ISP signal of the coexisting system further causes the first central control node to determine whether the first common node has the right to reuse the resources of the second coexistence system according to the summary of the obtained detection results; and solve the prior art G.9972 The standard cannot allocate additional resources to the network; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal, that is, the transmission of data by the first ordinary node does not affect the second coexistence system. The first common node can reuse the resources of the second coexistence system, so as to ensure that the nodes coexisting in the coexistence system can reuse other coexistence systems that are not affected by them when additional resources are needed. Resources have improved the effectiveness of resource utilization. Referring to FIG. 14, which is a schematic structural diagram of a second common node provided in another embodiment of the present invention, the second common node is mainly applied to one of the second coexistence networks in the system shown in FIG. 2. An example of this is illustrated in the second normal node 244 of 240. The second common node may include: a third receiving module 1402, a detecting module 1404, and a reporting module 1406.

The third receiving module 1402 is configured to receive a detection event request message sent by the second central control node of the second coexistence network, where the detection event request message is used to indicate that the designated node detects whether to receive the first coexistence system in the n detection time domains. The ISP signal, the designated node is a second common node and/or a second central control node having any transmission requirement in a certain time period in the second coexistence network, and the specific time period is a period determined by the second central control node;

The ISP signal is that the first central control node of the first coexistence network in the first coexistence system sends an indication message to the n first common nodes in the first coexistence network that need to multiplex resources, and the indication message carries a unique correspondence with the first common node. When detecting the location information of the time domain, the first common node transmits the ISP signal of the first coexistence system in the detection time domain.

The detecting module 1404 may be configured to detect whether the ISP signal is received in the n detecting time domains. The reporting module 1406 may be configured to send, by using the detection result reporting message, the detection result of each detection time domain detected by the detecting module 1404 to the first a second central control node of the second coexistence network, so that the second central control node aggregates detection results sent by each designated node of the second coexistence network Point transmission with ^ ^ "Valley detection day domain" [forget results] [forget the knowledge, so that the first central control node of the first header is based on the summary in the received summary notification message As a result, it is determined whether the first normal node transmitting the ISP signal in each detection time domain in the first coexistence network has the right to multiplex the resources of the second coexistence system.

In practical applications, each designated node detects whether the ISP signal of the first coexistence system can be received in the n detection time domains, and each time the ISP signal of the first coexistence system is detected, the second coexistence network is obtained. The second central control node sends a detection result report message, where the detection result report message carries the detection result of detecting the ISP signal of the first coexistence network system in the corresponding detection time domain; obviously, when the designated node is in a certain detection time domain The ISP signal of the first coexistence system is not detected, and the detection result report message may be sent to the second central control node of the second coexistence network, where the report result report message carries the first coexistence system not detected in the corresponding detection time domain. The detection result of the ISP signal.

In a possible implementation manner based on the embodiment shown in FIG. 14, the detecting module 1404 can also be used to:

For each detection time domain, it is detected whether the ISP signal of the first coexistence system is received in the detection time domain. In the two possible implementations based on the embodiment shown in FIG. 14, all the first coexistence networks in the first coexistence system follow the same PLC standard, and all the second coexistence networks in the second coexistence system follow The same PLC standard, the first coexistence system and the second coexistence system follow different PLC standards.

In three possible implementations based on the embodiment shown in Figure 14, the first central control node and the second central control node are both 1905.1-based devices, and the summary notification message is encapsulated into 1905.1 abstraction layer control messages.

In summary, the second common node provided in the embodiment of the present invention receives the n detection regions sent by the second central control node and the type of the first coexistence system, and detects whether the first detection time domain is received. The ISP signal of the coexisting system further causes the first central control node to determine whether the first common node has the right to reuse the resources of the second coexistence system according to the summary of the obtained detection results; and solve the prior art G.9972 The standard cannot allocate additional resources to the network; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal, that is, the transmission of data by the first ordinary node does not affect the second coexistence system. The first common node can reuse the resources of the second coexistence system, so as to ensure that the nodes coexisting in the coexistence system can reuse other coexistence systems that are not affected by them when additional resources are needed. Resources, improved resources Referring to FIG. 15, which is a schematic structural diagram of a second common node provided in another embodiment of the present invention, the second common node is mainly applied to one of the second coexistence networks in the system shown in FIG. 2. An example of this is illustrated in the second normal node 244 of 240. The second general node may include: a receiver 1502, a processor 1504, and a transmitter 1506.

The receiver 1502 is configured to receive a detection event request message sent by the second central control node of the second coexistence network, where the detection event request message is used to indicate that the designated node detects whether to receive the ISP signal of the first coexistence system in the n detection time domains. And the designated node is a second common node and/or a second central control node that has any transmission requirement in a specific time period in the second coexistence network, and the specific time period is a period determined by the second central control node;

The ISP signal is that the first central control node of the first coexistence network in the first coexistence system sends an indication message to the n first common nodes in the first coexistence network that need to multiplex resources, and the indication message carries a unique one with the first common node. Corresponding to detecting the location information of the time domain, the ISP signal of the first coexistence system transmitted by the first common node in the detection time domain.

The processor 1504 is configured to detect whether the ISP signal is received in the n detection time domains. The transmitter 1506 is configured to send the detection result of each detection time domain detected by the detection module to the second coexistence through the detection result report message. The second central control node of the network, so that the second central control node aggregates the detection result report messages sent by the designated nodes of the second coexistence network, obtains the summary result of each detection time domain, and controls to the first center of the first coexistence network The node sends a summary notification message carrying the summary result, so that the first central control node determines, according to the summary result in the summary notification message, whether the first common node that sends the ISP signal in each detection time domain in the first coexistence network has the second multiplexing The permissions of the resources of the coexisting system.

In summary, the second common node provided in the embodiment of the present invention receives the n detection regions sent by the second central control node and the type of the first coexistence system, and detects whether the first detection time domain is received. The ISP signal of the coexisting system further causes the first central control node to determine whether the first common node has the right to reuse the resources of the second coexistence system according to the summary of the obtained detection results; and solve the prior art G.9972 The standard cannot allocate additional resources to the network; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal, that is, the transmission of data by the first ordinary node does not affect the second coexistence system. , the first common node can reuse the resources of the second coexistence system, and the node that can ensure the coexistence network in a coexistence system is needed. Use a flat effect. Referring to FIG. 16, which is a schematic structural diagram of a second common node provided in another embodiment of the present invention, the second common node is mainly applied to one of the second coexistence networks in the system shown in FIG. 2. An example of this is illustrated in the second normal node 244 of 240. The second general node may include: a receiver 1602, a processor 1604, a transmitter 1606, and a memory 1608, wherein the processor 1604 is coupled to the receiver 1602, the transmitter 1606, and the memory 1608, respectively, and the memory 1608 stores at least one computer software. The processor 1604 can perform related operations according to computer software stored in the memory 1608.

The receiver 1602 may be configured to receive a detection event request message sent by the second central control node of the second coexistence network, where the detection event request message is used to indicate that the designated node detects whether to receive the ISP signal of the first coexistence system in the n detection time domains. And the designated node is a second common node and/or a second central control node that has any transmission requirement in a specific time period in the second coexistence network, and the specific time period is a period determined by the second central control node;

The processor 1604 is configured to detect whether the ISP signal is received in the n detection time domains. The transmitter 1606 is configured to send, by using the detection result report message, the detection result of each detection time domain obtained by the processor 1604 to the second a second central control node of the coexistence network, so that the second central control node aggregates the detection result report messages sent by the designated nodes of the second coexistence network, and obtains the summary result of each detection time domain, and the first coexistence network A central control node sends a summary notification message carrying a summary result of each detection time domain, so that the first central control node of the first coexistence network determines, according to the summary result in the received summary notification message, each of the first coexistence network Detecting whether the first common node transmitting the ISP signal in the time domain has the right to multiplex the resources of the second coexistence system.

In practical applications, each designated node detects whether the ISP signal of the first coexistence system can be received in the n detection time domains, and each time the ISP signal of the first coexistence system is detected, the second coexistence network is obtained. The second central control node sends a detection result report message, and the detection result reports the message When the donation point is detected, the domain detection method detects the 1SP 1 loss of the first storage system of the Liu, and may also send a detection result report message to the second central control node of the two-dimensional coexistence network, and the detection result is reported to be carried. There is a detection result of the ISP signal of the first coexistence system not detected in the corresponding detection time domain.

In a possible implementation manner based on the embodiment shown in FIG. 16, the processor 1604 is further configured to:

For each detection time domain, it is detected whether the ISP signal of the first coexistence system is received in the detection time domain. In the two possible implementations based on the embodiment shown in FIG. 16, all the first coexistence networks in the first coexistence system follow the same PLC standard, and all the second coexistence networks in the second coexistence system follow The same PLC standard, the first coexistence system and the second coexistence system follow different PLC standards.

In the three possible implementations based on the embodiment shown in Fig. 16, the first central control node and the second central control node are both 1905.1-based devices, and the summary notification message is encapsulated into a 1905.1 abstraction layer control message.

In summary, the second common node provided in the embodiment of the present invention receives the n detection regions sent by the second central control node and the type of the first coexistence system, and detects whether the first detection time domain is received. The ISP signal of the coexisting system further causes the first central control node to determine whether the first common node has the right to reuse the resources of the second coexistence system according to the summary of the obtained detection results; and solve the prior art G.9972 The standard cannot allocate additional resources to the network; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal, that is, the transmission of data by the first ordinary node does not affect the second coexistence system. The first common node can reuse the resources of the second coexistence system, so as to ensure that the nodes coexisting in the coexistence system can reuse other coexistence systems that are not affected by them when additional resources are needed. Resources have improved the effectiveness of resource utilization. It should be noted that, in the process of implementing the multiplexing resource, the first central control node, the first common node, the second central control node, and the second common node provided by the foregoing embodiments are only exemplified by the division of the foregoing functional modules. In the actual application, the foregoing function allocation may be completed by different functional modules according to requirements, that is, the internal structures of the nodes in the first coexistence network and the second coexistence network are divided into different functional modules to complete the above description. All or part of the function. In addition, the first central control node, the first common node, the second central control node, and the second common provided by the foregoing embodiments The case or the system of buying a case is not a real fan. Referring to FIG. 17, a flowchart of a method for resource multiplexing provided in an embodiment of the present invention is shown. The resource multiplexing method is mainly illustrated in the first central control node 222 of one of the first coexistence networks 220 of the system shown in FIG. The resource multiplexing method may include:

1701, setting n detection time domains in the qualified time domain;

1702. Send an indication message to the n first common nodes that need to multiplex resources in the first coexistence network, where the indication message carries the location information of the detection time domain that is uniquely corresponding to the first common node, so that the first common node is detected. The domain sends the ISP signal of the first coexistence system;

1703. Send a detection request message to the second central control node of the second coexistence network in the second coexistence system, where the detection request message includes location information of the n detection time domains and type information of the first coexistence system, so that the second central control The node sends a detection event request message to each designated node of the second coexistence network, where the detection event request message is used to indicate that the designated node detects whether to receive the ISP signal of the first coexistence system in the n detection time domains, and the n detections are performed by each designated node. Detecting whether the ISP signal is received in the time domain, and transmitting the detection result to the second central control node by using the detection result report message; and the second central control node sums up the detection result report message sent by each designated node, and obtains a summary of each detection time domain. As a result, a summary notification message carrying the summary result is sent to the first central control node;

The designated node mentioned here is a second common node and/or a second central control node having any transmission requirement in a certain time period in the second coexistence network, and the specific time period is a period determined by the second central control node.

1704. Receive a summary notification message sent by the second central control node, and determine, according to the summary result in the summary notification message, whether the first common node that sends the ISP signal in each detection time domain in the first coexistence network has the resource of multiplexing the second coexistence system. permission.

In summary, in the resource multiplexing method provided in the embodiment of the present invention, the first central control node of the first coexistence network in the first coexistence system sets n detection time domains on the eligible time domain, and notifies the The n first common nodes that need to be multiplexed in a coexistence network sequentially send the ISP signals of the first coexistence system in n detection time domains, so that the designated nodes in the second coexistence network in the second coexistence system are in the n detection times. The domain detects whether the ISP signal is received, and further determines, according to the summary of the obtained detection results, whether the first common node has the right to reuse the resources of the second coexistence system; and solves the problem that the G.9972 standard cannot be used as the network in the prior art. The problem of allocating additional resources; if the first coexistence network is the first If the data does not affect the younger brothers, then the younger one can reuse the poor sources of the two brothers, and the nodes that can coexist in a coexistence system need additional resources. When resources of other coexisting systems that are not affected by them can be reused, the effect of resource utilization is improved. Referring to FIG. 18, a flowchart of a method for resource multiplexing provided in another embodiment of the present invention is shown. The resource multiplexing method is mainly illustrated in the first common node 224 of the first coexistence network 220 applied to the system shown in FIG. 2. The resource multiplexing method may include:

1801: Receive an indication message sent by a first central control node of the first coexistence network, where the indication message carries location information of a detection time domain uniquely corresponding to the first common node, where the detection time domain is the The first central control node of the coexistence network is one of the n detection time domains set in the eligible time domain, where n is the number of the first common nodes in the first coexistence network that need to reuse resources;

1802. Send an ISP signal of the first coexistence system in the detection time domain.

In summary, the resource multiplexing method provided in the embodiment of the present invention sends the _ISP signal of the first coexistence system in the detection time domain notified by the first central control node in the first coexistence system, so as to be in the second coexistence system. The designated node detects whether the ISP signal is received in the n detection time domains, so that the first central control node can determine, according to the summary of the obtained detection results, whether the first common node has the right to reuse the resources of the second coexistence system. Solving the problem that the prior art cannot allocate additional resources to the network due to the G.9972 standard; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal, that is, the first If the ordinary node transmits data and does not affect the second coexistence system, the first common node can reuse the resources of the second coexistence system, so that the node that can coexist in the coexistence system can ensure that when the additional resources are needed, Reusing resources of other coexisting systems that are not affected by them improves the efficiency of resource utilization. Referring to FIG. 19, there is shown a flowchart of a method for resource multiplexing provided in still another embodiment of the present invention. The resource multiplexing method is primarily illustrated in the second central control node 242 of one of the second coexistence networks 240 of the system shown in FIG. The resource multiplexing method may include:

1901. Receive a detection request message sent by a first central control node of the first coexistence network in the first coexistence system, where the detection request message includes location information of the n detection time domains and a class of the first coexistence system. 1902. Send a detection contention crying to the valley donor points of the second head network, and the detecting contention request message is used to instruct the designated node to detect whether to receive the ISP signal of the first coexistence system in the n detection time domains. So that each designated node detects whether the ISP point of the first coexistence system is received in the n detection time domains;

The designated node mentioned here is a second common node and/or a second central control node having any transmission requirement in a certain time period in the second coexistence network, and the specific time period is a segment determined by the second central control node. The ISP signal mentioned here is that the first central control node sends an indication message to the n first common nodes in the first coexistence network that need to multiplex resources, and the indication message carries a detection time domain uniquely corresponding to the first common node. The location information is transmitted by the first common node in the detection time domain of the first coexistence system ISP signal.

1903. Summarize the detection result report messages sent by each specified node, and obtain a summary result of each detection time domain;

1904. Send a summary notification message carrying the summary result to the first central control node in the first coexistence network, so that the first central control node determines to send the ISP signal in each detection time domain according to the summary result in the summary result notification message. Whether the first normal node has the right to reuse the resources of the second coexistence system.

In summary, the resource multiplexing method provided in the embodiment of the present invention notifies the n detection areas sent by the first central control node of the first coexistence network in the first coexistence system to the designated node in the second coexistence system. So that the designated node detects whether the ISP signal of the first coexistence system is received in the n detection time domains, so that the first central control node determines whether the first common node has the second coexistence according to the summary of the obtained detection results. The authority of the resources of the system; solved the problem in the prior art

The G.9972 standard cannot allocate additional resources to the network; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal, that is, the transmission of data by the first ordinary node does not affect the first In the second coexistence system, the first common node can reuse the resources of the second coexistence system, and the node that can ensure that the coexistence network in a coexistence system can re-use other resources that are not affected by the coexistence network in a coexistence system. The resources of the coexistence system improve the effect of resource utilization. Referring to FIG. 20, a flowchart of a method for resource multiplexing provided in still another embodiment of the present invention is shown. The resource multiplexing method is mainly applied to one of the second common systems of the system shown in FIG. 2001, receiving a second quasi-centralized point of the second header, and detecting an event request message is used to indicate that the designated node detects whether to receive the first coexistence system in the n detection time domains. ISP signal;

The designated node is a second common node and/or a second central control node having any transmission requirement in a certain period of time in the second coexistence network, and the specific time period is a period of time determined by the second central control node.

The ISP signal is that the first central control node of the first coexistence network in the first coexistence system sends an indication message to the n first common nodes in the first coexistence network that need to multiplex resources, and the indication message carries a unique correspondence with the first common node. The location information of the detection time domain is transmitted by the first common node in the detection time domain of the ISP signal of the first coexistence system.

2002, detecting whether an ISP signal is received in n detection time domains;

In 2003, the detection result of each detection time domain is sent to the second central control node by the detection result report message, so that the second central control node summarizes the detection result report message sent by each designated node of the second coexistence network, and obtains each detection. a summary result of the time domain, and sending a summary notification message carrying the summary result to the first central control node of the first coexistence network, so that the first central control node determines each of the first coexistence network according to the summary result in the summary notification message Detecting whether the first common node transmitting the ISP signal in the time domain has the right to multiplex the resources of the second coexistence system.

The designated node mentioned here is a second common node and/or a second central control node having any transmission requirement in a certain time period in the second coexistence network, and the specific time period is a period determined by the second central control node. .

In summary, the resource multiplexing method provided in the embodiment of the present invention detects whether the n detection areas and the first coexistence system type are sent by the second central control node, and detects whether the first detection time domain is received. The ISP signal of the coexisting system further causes the first central control node to determine whether the first common node has the right to reuse the resources of the second coexistence system according to the summary of the obtained detection results; and solve the prior art G.9972 The standard cannot allocate additional resources to the network; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal, that is, the transmission of data by the first ordinary node does not affect the second coexistence system. The first common node can reuse the resources of the second coexistence system, so as to ensure that the nodes coexisting in the coexistence system can reuse other coexistence systems that are not affected by them when additional resources are needed. Resources have improved the effectiveness of resource utilization. The buckwheat is shown in l3⁄4 21A, and it shows a flow chart of the method of the poor source multiplexing method provided by the jujube invention. The resource multiplexing method is mainly illustrated by being applied to the system shown in FIG. 2. Since one first coexistence network in the first coexistence system does not affect another first coexistence network in the first coexistence system when multiplexing the second coexistence system, for convenience of description, only one of the following needs to be reused. The first coexistence network is taken as an example for illustration. The resource multiplexing method may include:

2101. The first central control node sets n detection time domains in the qualified time domain; the value of n herein may be the total number of all nodes in the first coexistence network, or the number of partial nodes. Generally, the value of n is the same as the number of first common nodes that need to be multiplexed resources determined by the first central control node. For example, when the first central control node allocates resources for each common node, one of them is found or The traffic of some common nodes is relatively large, and when the resources allocated by the first central control node are relatively small, it can be determined that these first common nodes have the requirement of multiplexing additional resources; 4艮 obviously, the first common node can And sending, to the first central control node, an allocation request for requesting the first central control node to allocate an additional resource to the first common node. Correspondingly, the first central control node determines, according to the allocation request message, whether the first common node determines whether the message is sent.

In a possible implementation, the duration of each detection time domain may be the length of an ISP domain in the G.9972 standard.

In practical applications, due to different standards, the eligible time domain can have many different options, which may include:

In the first case, the qualified time domain is the default time domain resource of the first coexistence system A when the first judgment condition is met;

In the second case, the eligible time domain is the extended ISP window of the first coexistence system A when the second judgment condition is met;

In the third case, the qualified time domain is the extended ISP window of the first coexistence system A and the default time domain resource of the first coexistence system A when the second judgment condition is met;

The second judgment condition is: the first coexistence system A determines the type and number of coexistence systems on the power line according to the topology discovery protocol in the IEEE 1905.1 standard, that is, the coexistence state, and determines the coexistence state according to the ITU-T G.9972 standard. Time domain resources allocated to the first coexistence system A; After the header is stored, ITU-T G.9972 states that the header resource is allocated to the first header A.

In the first case above, please refer to FIG. 21B, which shows a schematic diagram of a first eligible time domain provided in some embodiments of the present invention. The first coexistence system is a G.hn system, and the second The EE window set up by the E. TDMS 1, TDMS2 and TDMS7, the TDMS available for the second coexistence system are TDMS3, TDMS4, TDMS5 and TDMS6. At this time, the first central control node in the first coexistence network can set n on TDMS0, TDMS1, TDMS2 and TDMS7. Detect time domain. These n detections i may be either adjacent i or , or may be non-adjacent.

In the second case above,

Referring to FIG. 21C, a schematic diagram of a second eligible time domain provided in some embodiments of the present invention is shown. The first coexistence system is a G.hn system, and the second coexistence system is an EEE 1901 access system. The ISP window set by G.9972 for G.hn system is IH-G, and the ISP window set for EEE 1901 access system is ACC, then the TDMS available for the first coexistence system are TDMS0, TDMS1, TDMS2 and TDMS7, second The TDMS available for the coexistence system are TDMS3, TDMS4, TDMS5, and TDMS6. At this time, the first central control node in the first coexistence network can set n detection time domains on the ISP window IH-G and TDMS0, TDMS1, TDMS2, and TDMS7. . These n detection time domains may be adjacent time domains or non-adjacent time domains.

In the third case above, please refer to FIG. 21D, which shows a schematic diagram of a third eligible time domain provided in some embodiments of the present invention. The first coexistence system is a G.hn system, and the second The EE window set up by the E. TDMS1, TDMS2 and TDMS7, the TDMS available for the second coexistence system are TDMS3, TDMS4, TDMS5 and TDMS6. At this time, the first central control node in the first coexistence network can be in the ISP window IH-G and the ISP window IH-G. N detection time domains are set on the adjacent extended time domain (where the scalable time domain can occupy a part of a TDMS behind the ISP window IH-G, a TDMS or a plurality of TDMSs, etc.). These n detection time domains can usually be adjacent time domains. for:

In the first way, for any coexisting system, the value of n is a fixed value;

In the second way, for a coexisting system, the value of n is a fixed value, and the values of n can be different for different coexisting systems;

In the third way, for any coexisting system, the n value can be dynamically set.

2102, the first central control node sends a detection request message to the second central control node of the second coexistence network, where the detection request message carries the location information of the n detection time domains and the type information of the first coexistence system;

The type information of the first coexistence system mentioned here means that the first coexistence network is one of the four coexistence systems in the G.9972 standard, so different types of coexistence systems correspond to different ISP signals, that is, the ISP signal can be The type of the coexistence system is uniquely identified; in addition, the detection request message may further include information of a network label of the first coexistence network (ie, a coexistence network for uniquely identifying whether the first coexistence network is the first coexistence system), an n value, and the like.

Generally speaking, the first coexistence network selects which one or other coexistence systems to send the detection request message, which usually depends on which other coexistence system resources are to be multiplexed by the first coexistence network, so the first coexistence network can go to any one of the The second coexistence system (non-first coexistence system) looks for reuse resources. For example, the first coexistence network may simultaneously send the detection request message to all other coexistence systems (the second coexistence system is one of the coexistence systems); or may send the detection request message to other coexistence systems in sequence. When the reusable resource of the application satisfies the first coexistence network multiplexing, the search for reusable resources for the remaining other coexistence systems is stopped, and when the reusable resources of the application still cannot satisfy the first coexistence network multiplexing, Then continue to find reusable resources in the next coexistence system.

It should be noted that, (1) if the first coexistence network sets n detection time domains in the time domain starting from the ISP window of the first coexistence network, when the value of n is the first setting described in step 2101. In the mode, since the value of n is a fixed value for all coexisting systems, the second coexistence system can know the value of n, that is, the second coexistence system can know in advance that the ISP window of the first coexistence system starts. The n detection time domains, and therefore the first central node may not carry the n detection time domains when transmitting the detection request message. (2) If the first coexistence network sets n detection time domains in the time domain starting from the ISP window of the first coexistence system, when the value of n is the second setting mode described in step 2101, due to the n value For the first coexistence network, it is a fixed value. Therefore, the first central control node may carry the detection time request message to the second central control node for the first time, and may carry the n detection time domains. Do not carry the n test days or.

2103, the first central control node sends an indication message to the predetermined n first common nodes, where the indication message carries the location information of the detection time domain uniquely corresponding to the first common node;

The indication message is used to indicate that the first common node that receives the indication message sends the ISP signal of the first coexistence system in the detection time domain carried by the indication message.

In a possible implementation, for each predetermined first common node, the first central control node may separately send an indication message to the first common nodes, where each indication message carries one unique with the first common node. The corresponding location information of the detection time domain. In another possible implementation, the first central control node may send an indication message to the first common node, where the indication message carries n groups of correspondences, and each group correspondence includes identifier information of the first common node. And location information of the detection time domain uniquely corresponding to the first common node.

2104. The first common node receives the indication message sent by the first central control node.

Generally, the first central control node may instruct the first common node to send the ISP signal of the first coexistence system in multiple manners, such as notifying a broadcast or unicast indication message or by sending a beacon frame carrying the indication message. This embodiment is not limited thereto. Moreover, after the first normal node receives the indication message, the first central control node may also reply with a confirmation message indicating that the indication message has been received. Whether the acknowledgement message is sent or not is not limited in this embodiment. It should be noted that the indication message and the confirmation message mentioned herein are generally not the abstract layer control message of IEEE 1905.1, but the control message in the first coexistence network.

2105. The second central control node receives the detection request message.

In a practical application, after receiving the detection request message, the second central control node may reply a first response control message to the first central control node in the first coexistence network, where the detection response message is used to indicate that the second central control node receives The detection request message sent by the first central control node is reached. Obviously, after receiving the detection request message, the second central control node may further determine whether the second coexistence system allows resources to be multiplexed by other coexistence systems. If the resources of the second coexistence system allow resources to be multiplexed by other coexistence systems, The second central control node carries information for indicating that the second coexistence system accepts the first coexistence network multiplexing request in the detection response message; otherwise, the second central control node carries the second response node in the detection response message for indicating the second The coexistence network rejects the information of the first coexistence network multiplexing request. It should be noted that the detection request message and the detection response message mentioned herein are both IEEE 1905.1 abstract layer control messages, and in actual applications, the second central control node may not reply. 2106, the first dimethyl heart pinch point sends the detection contends to the valley donation point; the designated node mentioned here is the second common node of any of the second coexistence networks that has transmission demand in a certain time period. And/or a second central control node, the specific time period being a period of time determined by the second central control node.

That is to say, as long as any one of the second common node and the second central control node of the second coexistence network has a transmission requirement within a certain period of time, it can be used as the designated node.

In the first case, when the detection request message sent by the first central control node carries the specified time period (ie, the first central control node requests to arrange the detection time domain within the time period, and detects whether the second time can be reused. The resource of the second coexistence system), if the second central control node allows the first coexistence network to detect whether the resource of the second coexistence system can be multiplexed in the specified time period, the second central control node determines the specified time period as the specific time Paragraph

In the second case, when the detection request message sent by the first central control node carries the specified time period, if the second central control node does not allow the first coexistence network to detect whether the second coexistence network can be multiplexed in the specified time period. The resource of the coexistence system, the second central control node may specify another specific time period, and then the second central control node notifies the first central control node of the other specific time period, so that the first central control node manages the first coexistence network It is detected during the other specific time period whether the resources of the second coexistence system can be multiplexed.

In the third case, the second central control node takes the default resource of the first coexisting network as a specific time period.

For convenience of description, in this embodiment, only the second common node having any transmission requirement in a certain period of time in the second coexistence network is used as the designated node 242.

The detection event request message described herein is used to instruct the designated node to detect whether to receive the ISP signal of the first coexistence system in the above-mentioned n detection time domains.

Generally, after receiving the detection request message sent by the first central control node, the second central control node generates a detection event request message, where the detection event request message usually carries the n detection times carried in the detection request message. The location information of the domain and the type information of the first coexistence system are used to indicate that the designated node detects whether the ISP signal of the first coexistence system is received in the _n detection time domains. The second central control node may separately send a detection event request message to each designated node, or The detection disputes sent to the valley donation points are the same, and the detection event request message is usually the control message in the second coexistence system.

2107. The designated node receives the detection event request message sent by the second central control node. After receiving the detection event request message sent by the second central control node, the designated node usually parses the detection event request message to obtain n detection time domains. The location information and the type information of the first coexistence system are used to detect whether the ISP signal of the first coexistence system can be received in the n detection time domains.

2108, the first common node sends the ISP signal of the first coexistence system in the detection time domain;

After step 2104, the first normal node parses the detection time domain corresponding to the first normal node in the indication message, and sends the ISP signal of the first coexistence system in the detection time domain.

2109. The designated node detects, in the n detection time domains, whether an ISP signal of the first coexistence system is received.

For each detection time domain, each designated node detects whether the ISP signal of the first coexisting system is received in the detection time domain. That is to say, each of the designated nodes obtains n detection results that are uniquely corresponding to the n detection time domains, and for each detection time domain, the corresponding detection result may include: receiving the first coexistence in the detection time domain The ISP signal of the system and the ISP signal of the first coexistence system are not received in the detection time domain.

2110, the specified node sends the detection result of each detection time domain to the second central control node by using the detection result report message;

In practical applications, each designated node detects whether the ISP signal of the first coexistence system can be received in the n detection time domains, and each time the ISP signal of the first coexistence system is detected, the node is controlled to the second center. Sending a detection result report message, where the detection result report message is used to indicate that the detection result of the ISP signal of the first coexistence system is detected in the corresponding monitoring time domain; obviously, when the designated node does not detect the first coexistence in a certain detection time domain The ISP signal of the system may also send a detection result report message to the second central control node, where the detection result report message is used to indicate that the detection result of the ISP signal of the first coexistence system is not detected in the corresponding monitoring time domain.

In a possible implementation manner, after receiving the detection event request message, the designated node may send a detection event response message to the second central control node, where the detection event response message carries the detection result of the designated node, which is obviously The detection event response message may include a detection result of the specified node when detecting a time domain, or may include the specified node at all n detection times. ^ To be added, the detection of disputes and the detection of disputes can usually be the control messages in the second coexistence network, rather than the IEEE 1905.1 abstraction layer control messages.

2111, the second central control node summarizes the detection result report messages sent by the designated nodes, and obtains the summary result of each detection time domain;

It is worth noting that when the second central control node has a transmission requirement within a certain time period, the second central control node itself becomes the designated node, that is, the second central control node itself needs to detect the first in the detection time domain. Coexist the ISP signal of the system and summarize the test results together with the test results of other specified nodes.

In a possible implementation manner, the summary rule of the second central control node may be as follows: For each detection time domain, if the detection result of at least one specified node in the second coexistence network is that the first detection field is detected in the detection time domain The ISP signal of the coexistence system determines that the summary result is that the second coexistence network detects the first coexistence network on the detection time domain;

For each detection time domain, if the detection result of each designated node in the second coexistence network is that the ISP signal of the first coexistence system is not detected in the detection time domain, it is determined that the summary result is that the second coexistence network is detecting The first coexistence network was not detected on the domain.

2112. The second central control node sends, to the first central control node, a summary notification message carrying a summary result of each detection time domain.

The summary notification message is typically an IEEE 1905.1 abstraction layer control message, which may include the type of the second coexistence system (ie, which of the four coexistence systems the second coexistence system is), the network label of the second coexistence network (ie, the second coexistence network is the coexistence network of the second coexistence system), the detection result on each detection time domain, and the like.

2113. The first central control node receives the summary notification message.

In a possible implementation, after receiving the summary notification message sent by the second central control node, the first central control node may also reply a summary confirmation message to the second central control node to indicate that the first central control node has The summary notification message was successfully received.

It should be noted that the summary notification message and the summary confirmation message mentioned here are usually IEEE 1905.1 abstract layer control messages.

2114. The first central control node determines, according to the summary result in the summary notification message sent by the second central control node of each second coexistence network, whether the first common node that sends the ISP signal in each detection time domain in the first coexistence network has a complex Permission to use the resources of the second coexistence system. The rule of a Jinci point is that the county ^ reuses the second source of the poor source of the second source can be as follows: First, for each detection time domain, when the second central control node of the second coexistence network The result of the aggregation is that the second coexistence network detects the first coexistence system on the detection time domain, and determines that the first common node that sends the ISP signal of the first coexistence system in the detection time domain does not have the resource of multiplexing the second coexistence system. permission;

Second, for each detection time domain, when the summary result of the second central control node of the second coexistence network is that the second coexistence network does not detect the first coexistence system in the detection time domain, it is determined to be sent in the detection time domain. The first normal node of the ISP signal has the authority to multiplex the resources of the second coexistence system.

When there is a second coexistence network in the second coexistence system, the rules of the first central control node in determining whether the first normal node has the right to reuse the resources of the second coexistence system may be as follows: First, for each detection Time domain, when the summary result of the second central control node of the at least one second coexistence network in the second coexistence system is that the second coexistence network detects the first coexistence system on the detection time domain, determining to send in the detection time domain The first common node of the ISP signal of the first coexistence system does not have the right to reuse the resources of the second coexistence system;

That is, for each detection time domain, if at least one designated node of any one of the second coexistence networks in the second coexistence system receives the ISP signal of the first coexistence system in the detection time domain, it indicates that the detection is The first normal node that transmits the ISP signal in the time domain does not have the right to reuse the resources of the second coexistence system.

Second, for each detection time domain, when the summary result of the second central control node of each second coexistence network in the second coexistence system is that the second coexistence network does not detect the first coexistence system in the detection time domain, Then, it is determined that the first ordinary node that transmits the ISP signal in the detection time domain has the right to multiplex the resources of the second coexistence system.

That is, for each detection time domain, if all the designated nodes of each second coexistence network in the second coexistence system do not receive the ISP signal of the first coexistence system in the detection time domain, it indicates that The first normal node that detects the time domain transmitting the ISP signal has the right to multiplex the resources of the second coexistence system.

For example, please refer to FIG. 21E, which shows a topological diagram of two systems coexisting in an embodiment of the present invention, which are a HomePlug system and a G.hn system, respectively, in the HomePlug system. Contains nodes A, B, and C. The G.hn system has only one coexistence network. The coexistence network contains nodes 0, E, and F. The line in Figure 21E indicates that the nodes at both ends of the connection are connected to each other. Deficit 3, G.hn 甲的 point D, E ^ F This test does not receive Liu ISP 1 loss, so node A can reuse the time domain assigned to nodes D, E and F in G.hn system For example, node A can be multiplexed into the time domain allocated by node D, that is, node A and node D can simultaneously transmit data in the time domain allocated for node D, and the transmission of each other does not cause interference to the other party. Similarly, Node B can also reuse the time domain assigned to nodes D, E, and F in the Ghn system. Since the node C transmits the ISP signal of the HomePlug system when detecting the time domain, it can be monitored by the node D in the G.hn system, so the node C cannot reuse the resources in the G.hn system. Since the time between two adjacent ISP windows of the same coexistence system is ⁷ Η = ^{4 β 7} ^, that is, 24 AC cycles. If the qualifying time domain is the scalable time domain starting from the ISP window of the first coexistence network, when the topology in the first coexistence network and/or the second coexistence system and the interference noise environment change, Since the reuse resource of the first coexistence network is not applicable to the current environment, the first coexistence network needs to re-find the reuse resource, and the first coexistence system needs to wait for the arrival of the next eligible time domain. , that is, waiting for the arrival of the next scalable time domain starting from the ISP window of the first coexisting network. This waiting time is up to 24 AC cycles. In order to minimize the waiting time for finding the multiplexed resource next time, you can reset the n detection time domain on the default time domain resource allocated to the first coexistence network (that is, one of the above qualified time domains) to start as early as possible. The next time you look for a process of multiplexing resources.

It should be further noted that since this embodiment is implemented based on the IEEE 1905.1 standard (ie, the first central control node and the second central control node are both IEEE 1905.1 devices, that is, these nodes each have an IEEE 1905.1 abstraction layer, each The node can send and receive the IEEE 1905.1 abstract layer control message), so the detection request message, the detection response message, and the summary notification message transmitted between the first central control node and the second central control node in the above may generally be EEE 1905.1. The abstract layer controls the message, and the indication message sent between the first central control node and the first common node is a control message in the first coexistence network, and the detection is sent between the second central control node and the second common node. The resulting reported message is a control message in the second coexistence system.

It should be further noted that a first coexistence network in the first coexistence system does not affect another first coexistence network to seek resource reuse when searching for resource reuse, that is, different coexistence networks in the first coexistence system. The search for resource reuse is independent of each other. For example, the first coexistence system is a G.hn system, and there are two G.hn networks under the G.hn system, namely G.hn network 1 and G.hn network 2, respectively, and whether Ghn network 1 needs to be The network looking for multiplexing resources and when the Ghn network 1 starts to look for multiplexing resources for the network are independently determined by the G.hn network 1, regardless of the decision of the G.hn network 2. n , ^ have to get the second head τ ^ ^ "di two heads m network (can 0 ^ a head 弁 mm multiple coexistence networks) are determined whether the first coexistence system is detected, if the second coexistence If the first coexistence system does not detect the first coexistence system in the system, it indicates that the first coexistence network in the first coexistence system can reuse the resources of the second coexistence system. 艮 Obviously, the second coexistence system is the first The coexistence network selects a coexistence system for multiplexing resources. If the second coexistence network also wants to reuse resources of other coexistence systems, it can also find multiplexing resources to other coexistence systems in the above manner. For example, the second coexistence network can At the same time, multiplex resources are sought from all other or selected coexistence systems; for example, multiplex resources may be sought in turn for all other or selected coexistence systems, and when the multiplexed resources sought are available for use by the second coexistence network, Stop looking for reuse resources for the remaining coexistence system.

It should also be added that, for the same detection time domain, steps 2108 and 2109 are usually performed simultaneously, but there is no strict sequence between steps 2103, 2104 and steps 2102 to 2107.

In summary, in the resource multiplexing method provided in the embodiment of the present invention, the first central control node of the first coexistence network in the first coexistence system sets n detection time domains on the eligible time domain, and notifies the The n first common nodes that need to be multiplexed in the first coexistence network sequentially send the ISP signals of the first coexistence system in the n detection time domains, so that the designated nodes of the second coexistence network in the second coexistence system are in the n detection times. The domain detects whether the ISP signal is received, and the first central control node further determines, according to the summary of the obtained detection results, whether the first common node has the right to reuse the resources of the second coexistence system; The 9972 standard cannot allocate additional resources to the network; if the first common node in the first coexistence network is not received by the second coexistence system after the ISP signal, that is, the transmission of data by the first ordinary node does not affect the second coexistence. The system, the first common node can reuse the resources of the second coexistence system, and the node that can ensure the coexistence network in a coexistence system is To additional resources can not be multiplexed other resources of the impact of the coexistence system, improve the effectiveness of resource utilization. Those of ordinary skill in the art will appreciate that the elements and algorithm steps of the various examples described in connection with the embodiments disclosed herein can be implemented in electronic hardware, or a combination of computer software and electronic hardware. Whether such functions are performed in hardware or software depends on the functionality described for the particular application of the technical solution, but such implementation should not be considered to be beyond the scope of the present invention. The system, the installation, and the early work of the county, can be used to buy the method of the τ, and will not repeat them here.

In the several embodiments provided herein, it should be understood that the disclosed systems, devices, and methods may be implemented in other ways. For example, the device embodiments described above are only schematic. For example, the division of the unit may be only a logical function division. In actual implementation, there may be another division manner, for example, multiple units or components may be combined. Either can be integrated into another system, or some features can be ignored, or not executed. In addition, the mutual coupling or direct coupling or communication connection shown or discussed may be an indirect coupling or communication connection through some interface, device or unit, and may be electrical, mechanical or otherwise.

The units described as separate components may or may not be physically separate, and the components displayed as the units may or may not be physical units, that is, may be located in one place, or may be distributed to multiple network units. Some or all of the units may be selected according to actual needs to achieve the objectives of the solution of the embodiment.

In addition, each functional unit in each embodiment of the present invention may be integrated into one processing unit, or each unit may exist physically separately, or two or more units may be integrated into one unit.

The functions, if implemented in the form of software functional units and sold or used as separate products, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present invention, which is essential or contributes to the prior art, or a part of the technical solution, may be embodied in the form of a software product, which is stored in a storage medium, including The instructions are used to cause a computer device (which may be a personal computer, server, or network device, etc.) to perform all or part of the steps of the methods described in various embodiments of the present invention. The foregoing storage medium includes: a U disk, a mobile hard disk, a read-only memory (ROM), a random access memory (RAM), a magnetic disk, or an optical disk, and the like, which can store program code. .

The above is only the specific embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily think of changes or substitutions within the technical scope of the present invention. It should be covered by the scope of the present invention. Therefore, the scope of the invention should be determined by the scope of the claims.

Claims

A resource multiplexing system, the system comprising a first coexistence system and a second coexistence system, the first coexistence system comprising at least one first coexistence including a first central control node and at least one first common node Network, the second coexistence system includes a second coexistence network including a second central control node and at least one second common node, wherein

The second central control node of the second coexistence network aggregates the detection result report messages sent by the designated nodes of the second coexistence network, and obtains a summary result of each detection time domain, and the result is obtained in the first coexistence network. The first central control node sends a summary notification message carrying the summary result; the first central control node of the first coexistence network determines, according to the summary result in the summary notification message sent by the second central control node Whether the first common node that transmits the ISP signal in each detection time domain in the first coexistence network has the right to multiplex resources of the second coexistence system.

2. The system according to claim 1, wherein the second of the second coexistence network Well, get Liu Gu's test day or '/[Forget the result, 3⁄4栝:

The system according to claim 2, wherein the first central control node of the first coexistence network determines the first coexistence network according to the summary notification message sent by the second central control node. Whether the first common node that sends the ISP signal in the respective detection time domain has the right to reuse the resources of the second coexistence system includes:

When there is a second coexistence network in the second coexistence system, for each detection time domain, when the summary result of the second central control node is that the second coexistence network is detected on the detection time domain In the first coexistence system, the first central control node determines that the first common node that sends the ISP signal in the detection time domain does not have the right to multiplex resources of the second coexistence system; The result of the aggregation of the second central control node is that the second coexistence network does not detect the first coexistence system on the detection time domain, and the first central control node determines to send the The first common node of the ISP signal has the right to reuse the resources of the second coexistence system;

When there are two or more second coexistence networks in the second coexistence system, for each detection time domain, a summary result of the second central control node of at least one second coexistence network in the second coexistence system And detecting, by the second coexistence network, the first coexistence system on the detection time domain, where the first central control node determines that the first common node that sends the _IS p signal in the detection time domain does not Having the authority to multiplex the resources of the second coexistence system; the summary result of the second central control node of each second coexistence network in the second coexistence system is the second coexistence network in the detection time domain The first coexistence system is not detected, and the first central control node determines that the first common node that sends the ISP signal in the detection time domain has the right to multiplex the resources of the second coexistence system.

4. The system of claim 1 wherein: ^ Domain poverty source;

The system according to any one of claims 1 to 4, wherein all of the first coexistence networks in the first coexistence system follow the same PLC standard, and all of the second coexistence systems Both coexistence networks follow the same PLC standard, and the first coexistence system and the second coexistence system follow different PLC standards.

The system according to any one of claims 1 to 4, wherein the first central control node and the second central control node are both devices based on the IEEE 1905.1 standard, and the detection is sent. Both the request message and the summary notification message are encapsulated into an IEEE 1905.1 abstraction layer control message.

A first central control node, wherein the first central control node is the first central control node in a first coexistence network including a first central control node and at least one first common node, A coexistence network is a coexistence network in the first coexistence system, and the first central control node includes:

a setting module, configured to set n detection time domains in the qualified time domain; The Jinci point sends a donation, and the donation shows the location information of the detection time domain with the first point of the first point, so that the first common node is in the detection time domain. Sending an ISP signal of the first coexistence system;

The first sending module is further configured to send a detection request message to the second central control node of the second coexistence network in the second coexistence system, where the detection request message includes the location information and the location of the n detection time domains. The type information of the first coexistence system, so that the second central control node sends a detection event request message to each designated node of the second coexistence network, where the detection event request message is used to indicate that the designated node is in the The n detection time domain detects whether the ISP signal of the first coexistence system is received, and the each designated node detects whether the ISP signal is received in the n detection time domains, and passes the detection result through the detection result. The report message is sent to the second central control node; and the second central control node summarizes the detection result report message sent by each specified node, and obtains a summary result of each detection time domain, to the first The central control node sends a summary notification message carrying the summary result, where the designated node is the second coexistence The network of any one particular time period with a second ordinary node transmission requirements and / or the second central control node, the particular time period by the second central control node determines a period of time;

8. The first central control node according to claim 7, wherein:

When the second coexistence network exists in the second coexistence system, the determining module includes: a first determining unit, configured, for each detection time domain, when the summary result of the second central control node is When the second coexistence network detects the first coexistence system in the detection time domain, determining that the first common node that sends the ISP signal in the detection time domain does not have the second coexistence system Permissions for resources;

When there are two or more second coexistence networks in the second coexistence system, the determining module, Thirdly, in the case of the mother detection, the summary result of the second central control node of the second coexistence network is the second coexistence network in the detection time domain. After detecting the first coexistence system, determining that the first common node that sends the ISP signal in the detection time domain does not have the right to reuse resources of the second coexistence system;

9. The first central control node of claim 7 wherein:

The qualified time domain is a default time domain resource of the first coexistence system when the first judgment condition is met;

The first central control node according to any one of claims 7 to 9, wherein all of the first coexistence networks in the first coexistence system follow the same PLC standard, and the second coexistence system All of the second coexistence networks in the system follow the same PLC standard, the first coexistence system and the The first central control node according to any one of claims 7 to 9, wherein the first central control node and the second central control node are both devices based on the IEEE 1905.1 standard, and are sent. Both the detection request message and the summary notification message are encapsulated into an IEEE 1905.1 abstraction layer control message.

12. A first common node, where the first common node is the first common node in a first coexistence network including a first central control node and at least one first common node, the first coexistence network a first coexistence network in the first coexistence system, the first common node includes: a first receiving module, configured to receive an indication message sent by the first central control node of the first coexistence network, The indication message carries location information of a detection time domain uniquely corresponding to the first common node, where the detection time domain is n detections set by the first central control node of the first coexistence network in a qualified time domain. In the time domain, the n is the number of the first common nodes in the first coexistence network that need to reuse resources;

And a second sending module, configured to send an ISP signal of the first coexistence system in the detecting time domain.

13. The first general node according to claim 12, characterized in that

The eligible time domain is an extended ISP window of the first coexistence system, or an extended ISP window of the first coexistence system and a default time domain of the first coexistence system when the second judgment condition is met. Resource

The default time domain resource of the first coexistence system refers to that the first coexistence system determines that the coexistence state on the power line is allocated to the first in the coexistence state according to the ITU-T G.9972 standard. The first ISP's extended ISP is a time domain that has been donated from the 1SP of the first head system for a predetermined period of time, and the predetermined duration is the n detection time zones. The length of time.

14. A second central control node, the second central control node being the second central control node in a second coexistence network including a second central control node and at least one second common node, The second coexistence network is a coexistence network in the second coexistence system, and the second central control node includes:

a third sending module, configured to send, to each designated node of the second coexistence network, a detection event request message, where the designated node is any one of the second coexistence network having a transmission requirement in a specific time period a second common node and/or the second central control node, the specific time period is a period determined by the second central control node, and the detection event request message is used to indicate that the designated node is in the n Detecting whether the ISP signal of the first coexistence system is received, so that the respective designated nodes detect whether the ISP heart control node of the first coexistence system is received in the n detection time domains;

The second central control node according to claim 14, wherein the summary module comprises:

a fifth determining unit, configured, for each detection time domain, when the detection result of the at least one designated node of the second coexistence network is that the ISP signal of the first coexistence system is detected on the detection time domain, Determining that the summary result is that the second coexistence network detects the first time on the detection time domain Sixth early, in the case of the mother detection, when the detection results of the valley donor nodes of the second head are not detected in the detection time domain, the ISP signal of the first coexistence system is detected. And determining, according to the summary result, that the second coexistence network does not detect the first coexistence system on the detection time domain.

The second central control node according to claim 14 or 15, wherein all the first coexistence networks in the first coexistence system follow the same PLC standard, and all of the second coexistence systems The second coexistence network all follow the same PLC standard, and the first coexistence system and the second coexistence system follow different PLC standards.

The second central control node according to claim 14 or 15, wherein the first central control node and the second central control node are both standards-based devices, and the detection request message and the The summary notification message is encapsulated into a 1905.1 abstraction layer control message.

18. A second common node, the second common node being the second common node in a second coexistence network including a second central control node and at least one second common node, the second coexistence network a second coexistence network in the second coexistence system, the second common node includes: a third receiving module, configured to receive a detection event request message sent by the second central control node of the second coexistence network, The detection event request message is used to indicate that the designated node detects whether to receive the ISP signal of the first coexistence system in the n detection time domains, and the designated node has a transmission requirement for any one of the second coexistence networks in a specific time period. The second common node and/or the second central control node, wherein the specific time period is a period determined by the second central control node;

a detecting module, configured to detect, in the n detecting time domains, whether the ISP signal is received, or a fourth sending module, configured to send, by using the detection result report message, the detection result of each detection time domain detected by the detecting module Giving the second central control node of the second coexistence network, so that the second central control node aggregates the detection result report messages sent by the designated nodes of the second coexistence network, and obtains the summary result of each detection time domain. And sending, to the first central control node of the first coexistence network, a summary notification message carrying the summary result, so that the first central control node determines the first according to the summary result in the summary notification message. Whether a first common node that transmits the ISP signal in each detection time domain in a coexistence network has a resource for multiplexing the second coexistence system The second common node according to claim 18, wherein the detecting module is further configured to:

For each detection time domain, it is detected whether an ISP signal of the first coexistence system is received in the detection time domain.

The second common node according to claim 18 or 19, wherein all the first coexistence networks in the first coexistence system follow the same PLC standard, and all the second coexistence systems Both coexistence networks follow the same PLC standard, and the first coexistence system and the second coexistence system follow different PLC standards.

The second common node according to claim 18 or 19, wherein the first central control node and the second central control node are both devices based on the 1905.1 standard, and the summary notification message is encapsulated. Into the 1905.1 abstraction layer control message.

22, a first central control node, the first central control node is the first central control node in a first coexistence network including a first central control node and at least one first common node, A coexistence network is a coexistence network in the first coexistence system, and the first central control node includes:

The transmitter is further configured to send a detection request message to the second central control node of the second coexistence network in the second coexistence system, where the detection request message includes the n detection time domain detection request messages, and the detecting And requesting the message and the type information of the first coexistence system, so that the second central control node sends a detection event request message to each designated node of the second coexistence network, where the detection event request message is used to indicate the designation The node detects whether to receive the ISP signal of the first coexistence system in the n detection time domains, and detects, by the respective designated nodes, whether to receive in the n detection time domains. Kneading the point; opening the 3⁄4th heart-twisting point' [the reported result of the detection result sent by the fascinating point of the valley, obtaining the summary result of each detection time domain, to the first central control node Sending a summary notification message carrying the summary result, the designated node being the second common node and/or the second center having any transmission requirement in a specific time period in any one of the second coexistence networks a control node, the specific time period being a period of time determined by the second central control node;

23. The first central control node of claim 22, wherein

The processor is further configured to: when there is a second coexistence network in the second coexistence system, for each detection time domain, when the summary result of the second central control node is the second coexistence network When the first coexistence system is detected in the detection time domain, determining that the first common node that sends the ISP signal in the detection time domain does not have the right to reuse resources of the second coexistence system;

The processor is further configured to: when there are two or more second coexistence networks in the second coexistence system, for each detection time domain, when each of the second coexistence networks in the second coexistence system The summary result of the two central control nodes is that the second coexistence network does not detect the first coexistence system in the detection time domain, and then determines the first common node that sends the ISP signal in the detection time domain. Having the right to reuse resources of the second coexistence system. The ^κ仟^κ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _

The first central control node according to any one of claims 22 to 24, wherein all first coexistence networks in the first coexistence system follow the same PLC standard, and the second coexistence system All of the second coexistence networks in the system follow the same PLC standard, and the first coexistence system and the second coexistence system follow different PLC standards.

The first central control node according to any one of claims 22 to 24, wherein the first central control node and the second central control node are both devices based on the IEEE 1905.1 standard, and are sent. Both the detection request message and the summary notification message are encapsulated into an IEEE 1905.1 abstraction layer control message.

27. A first common node, where the first common node is the first common node in a first coexistence network including a first central control node and at least one first common node, the first coexistence network It is a coexistence network in the first coexistence system, and the first common node includes: The value of the detection day or the position of the first day of the first coexistence network is the same as the first central control node of the first coexistence network. One of the n detection time domains set in the time domain, where n is the number of the first common nodes in the first coexistence network that need to reuse resources;

28. The first general node of claim 27, wherein

29. A second central control node, the second central control node being the second central control node in a second coexistence network including a second central control node and at least one second common node, The second coexistence network is a coexistence network in the second coexistence system, and the second central control node includes:

a receiver, configured to receive a detection request message sent by a first central control node of the first coexistence network in the first coexistence system, where the detection request message includes location information of the n detection time domains and the The transmitter sends a detection quiz to the valley donation point of the second header storage network, and the designated node has a transmission requirement for any one of the second coexistence networks in a specific time period. The second common node and/or the second central control node, the specific time period is a period determined by the second central control node, and the detection event request message is used to indicate the designated node Detecting whether to receive the ISP signal of the first coexistence system in the n detection time domains, so that the respective designated nodes detect whether the ISP signal of the first coexistence system is received in the n detection time domains, the node ;

The second central control node according to claim 29, wherein the processor is further configured to: when detecting the time domain, when the detection result of the at least one designated node of the second coexistence network is When the ISP signal of the first coexistence system is detected on the detection time domain, determining that the summary result is that the second coexistence network detects the first coexistence system on the detection time domain;

31. The second central control node according to claim 29 or 30, wherein all of the first coexistence networks in the first coexistence system follow the same PLC standard, and all of the second coexistence systems The second coexistence network all follow the same PLC standard, and the first coexistence system and the second coexistence system follow different PLC standards.

32. The second central control node according to claim 29 or 30, wherein Detecting the ice and the fascination of the 甫 [ [ 逋逋逋 190 190 190 190 190 190 190 190 190 190 190 190 190 190

33. A second common node, where the second common node is the second common node in the second coexistence network including the second central control node and the at least one second common node, the second coexistence network a second coexistence network in the second coexistence system, the second common node includes: a receiver, configured to receive a detection event request message sent by a second central control node of the second coexistence network, The detection event request message is used to indicate that the designated node detects whether to receive the ISP signal of the first coexistence system in the n detection time domains, and the designated node has a transmission requirement for any one of the second coexistence networks in a specific time period. The second common node and/or the second central control node, wherein the specific time period is a period determined by the second central control node;

a processor, configured to detect, in the n detection time domains, whether the ISP signal is received, and a sending unit, configured to send, by using the detection result report message, the detection result of each detection time domain detected by the detection module to the a second central control node of the second coexistence network, so that the second central control node aggregates the detection result report messages sent by the designated nodes of the second coexistence network, and obtains a summary result of each detection time domain, and Sending, to the first central control node of the first coexistence network, a summary notification message carrying the summary result, so that the first central control node determines the first coexistence according to the summary result in the summary notification message Whether the first normal node transmitting the ISP signal in each detection time domain in the network has the right to multiplex the resources of the second coexistence system.

The second common node according to claim 33, wherein the processor is further configured to:

The second common node according to claim 33 or 34, wherein all the first coexistence networks in the first coexistence system follow the same PLC standard, and all the second coexistence systems Both coexistence networks follow the same PLC standard, and the first coexistence system and the second coexistence system follow different PLC standards. Both the heart-kneading point and the second heart-kneading point are based on the 1905.1 statement, and the 'forgetting notification message' is encapsulated into a 1905.1 abstraction layer control message.

37. A resource multiplexing method, applied to the first central control node that includes a first coexistence network of a first central control node and at least one first common node, wherein the first coexistence network As a coexistence network in the first coexistence system, the method includes:

Setting n detection time domains in the eligible time domain;

Sending an indication message to the n first common nodes that need to multiplex resources in the first coexistence network, where the indication message carries location information of a detection time domain uniquely corresponding to the first common node, so as to Transmitting, by the first common node, the ISP signal of the first coexistence system in the detection time domain; and sending a detection request message to the second central control node of the second coexistence network in the second coexistence system, where the detection request message includes The n detecting time domain location information and the first coexistence system type information, so that the second central control node sends a detection event request message to each designated node of the second coexistence network, the detection event And the request message is used to indicate, by the specified node, whether to receive the ISP signal of the first coexistence system in the n detection time domains, and whether the each designated node detects whether the An ISP signal, sending the detection result to the second central control node by using a detection result report message; and by the second center The system node collects the detection result report message sent by each specified node, obtains a summary result of each detection time domain, and sends a summary notification message carrying the summary result to the first central control node, where the specified node The second common node and/or the second central control node having a transmission requirement for any one of the second coexistence networks in a specific time period, wherein the specific time period is controlled by the second central node a period of time determined;

Receiving, by the second central control node, the summary notification message, determining, according to the summary result in the summary notification message, whether the first common node that sends the ISP signal in each detection time domain in the first coexistence network has The authority to multiplex the resources of the second coexistence system.

The method according to claim 37, wherein, when there is a second coexistence network in the second coexistence system, the determining the first coexistence network according to the summary result in the summary notification message Whether the first common node that sends the ISP signal in the respective detection time domain has the right to reuse the resources of the second coexistence system includes: ]» 络所检测检测检测检测或或或或或或或或或检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测检测The authority of the resource of the second coexistence system; when the summary result of the second central control node is that the second coexistence network does not detect the first coexistence system on the detection time domain, determining that the detection is performed The first common node that sends the ISP signal in the domain has the right to multiplex the resources of the second coexistence system;

When there are two or more second coexistence networks in the second coexistence system, determining, according to the summary result in the summary notification message, that the first coexistence network sends the detection time in each detection time domain

Whether the first common node of the ISP signal has the right to multiplex the resources of the second coexistence system, including: for each detection time domain, when the second coexistence network of the second coexistence system controls the second center of the second coexistence network The summary result of the node is that the second coexistence network detects the first coexistence system on the detection time domain, and determines that the first common node that sends the ISP signal in the detection time domain does not have a multiplexing station. The authority of the resources of the second coexistence system; the summary result of the second central control node of each of the second coexistence networks in the second coexistence system is that the second coexistence network is not detected on the detection time domain The first coexistence system determines that the first common node that sends the ISP signal in the detection time domain has the right to reuse resources of the second coexistence system.

39. The method of claim 37, wherein

40. The method according to any one of claims 37 to 39, wherein all first coexistence networks in the first coexistence system follow the same PLC standard, and all of the second coexistence systems Both coexistence networks follow the same PLC standard, and the first coexistence system and the second coexistence system follow different PLC standards.

The method according to any one of claims 37 to 39, wherein the first central control node and the second central control node are both devices based on the 1905.1 standard, and the detection request is sent. The message and the summary notification message are encapsulated into a 1905.1 abstraction layer control message.

42. A resource multiplexing method, applied to the first common node that includes a first coexistence network of a first central control node and at least one first common node, where the first coexistence network is a first coexistence system A coexistence network, wherein the method comprises:

43. The method of claim 42 wherein:

The first determining condition is: the first coexistence system determines a coexistence state of a coexistence system on a power line according to an ITU-T G.9972 ISP window mechanism, and determines the total according to the ITU-T G.9972 standard. The second judgment is: The first memory system is based on IEEE 1905.1, and the discovery protocol determines the coexistence state of the coexistence system on the power line, and determines the location according to the ITU-T G.9972 standard. a time domain resource allocated to the first coexistence system in a coexistence state;

44. A resource multiplexing method, applied to the second central control node that includes a second coexistence network of a second central control node and at least one second common node, where the second coexistence network is a second coexistence A coexistence network in the system, the method comprising:

Sending a detection event request message to each designated node of the second coexistence network, where the designated node is the second common node and/or the location of any one of the second coexistence networks that has a transmission requirement in a specific time period The second central control node, the specific time period is a period determined by the second central control node, and the detection event request message is used to indicate that the designated node detects whether to receive in the n detection time domains. The ISP signal of the first coexistence system, so that the respective designated nodes detect whether the ISP signal of the first coexistence system is received in the n detection time domains, and pass the detection result of each detection time domain through the detection result Reporting the message to the second central control node;

And summarizing the detection result report messages sent by the specified nodes, and obtaining summary results of the respective detection time domains;

Sending, to the first central control node in the first coexistence network, a summary notification message carrying the summary result, so that the first central control node determines, according to the summary result in the summary result notification message, that Whether the first normal node transmitting the ISP signal in each detection time domain has the right to multiplex the resources of the second coexistence system.

45. The method according to claim 44, wherein said summing said each specified section For the parent detection day or when the detection result of the primary donor node of the second head network is that the ISP signal of the first coexistence system is detected on the detection time domain, the summary result is determined. Detecting, by the second coexistence network, the first coexistence system on the detection time domain; when the detection results of each designated node of the second coexistence network are not detected on the detection time domain The ISP signal of the first coexistence system determines that the summary result is that the second coexistence network does not detect the first coexistence system on the detection time domain.

46. The method according to claim 44 or 45, wherein all first coexistence networks in the first coexistence system follow the same PLC standard, and all second coexistence networks in the second coexistence system Both follow the same PLC standard, and the first coexistence system and the second coexistence system follow different PLC standards.

The method according to claim 44 or 45, wherein the first central control node and the second central control node are both devices based on the 1905.1 standard, the detection request message and the summary notification The message is encapsulated into a 1905.1 abstraction layer control message.

48. A resource multiplexing method, applied to the second common node that includes a second coexistence network of a second central control node and at least one second common node, where the second coexistence network is a second coexistence system A coexistence network, wherein the method comprises:

Detecting whether the ISP signal is received in the n detection time domains; and the central control node, so that the second central control node summarizes the detection result report message sent by each designated node of the second coexistence network, and obtains a summary result of each detection time domain, and sending a summary notification message carrying the summary result to the first central control node of the first coexistence network, so that the first central control node is configured according to the summary notification message Summarize the results, determine the number The second limit is the limit of the poor source of the system.

The method according to claim 48, wherein the detecting, in the n detecting time domains, whether the ISP signal is received comprises:

50. The second central control node according to claim 48 or 49, wherein all first coexistence networks in the first coexistence system follow the same PLC standard, and all of the second coexistence systems The second coexistence network all follow the same PLC standard, and the first coexistence system and the second coexistence system follow different PLC standards.

The method according to claim 48 or 49, wherein the first central control node and the second central control node are both devices based on the 1905.1 standard, and the summary notification message is encapsulated into a 1905.1 abstraction. Layer control message.