KR101403911B1 - A dynamic bandwidth allocation device for a passive optical network system and the method implemented - Google Patents

Abstract

The present invention relates to an apparatus and method for allocating dynamic bandwidths used in a passive optical network system, which allocates a total transmission byte sequentially to each transmission container in a passive optical network system in each dispatch cycle, A bandwidth allocation strategy unit for reading a transmission container bandwidth allocation list in each dispatch cycle, allocating a total transmission byte to each timing frame within a dispatch cycle, and finally generating a bandwidth allocation map; Unit.

Passive optical network system, dynamic bandwidth allocation device, dispatch cycle, transmission container, transmission container bandwidth allocation list, bandwidth allocation subunit, bandwidth allocation map, bandwidth distribution strategy control subunit.

Description

TECHNICAL FIELD [0001] The present invention relates to a dynamic bandwidth allocating apparatus and a dynamic bandwidth allocating apparatus for use in a passive optical network system,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication field, and more particularly, to a dynamic bandwidth allocation (DBA, dynamic bandwidth allocation) scheme for realizing a passive optical network system (XPON) such as a gigabit passive optical network bandwidth assignment device and an implementation method thereof.

GPON technology is a new broadband passive optical network technology that supports gigabit rates. GPON is a point-to-multipoint structure in physical topology, but is logically a point-to-point structure. The downlink data transmission is a broadcasting format in which all optical network terminals (ONTs) can receive all downlink data frames from a physical PON port. Conversely, each ONT can transmit uplink data only within an uplink granting time slot allocated by an optical line terminal (OLT) with time division multiplex access (TDMA).

In the GPON, the authorization object of bandwidth allocation is a "transport container" (T-CONT, transmission containers). One ONT may include a plurality of T-CONTs. There are five types of T-CONT: T-CONT1, T-CONT2, T-CONT3, T-CONT4 and T-CONT5. Among them, T-CONT type 1 does not need to participate in dynamic bandwidth allocation with a fixed bandwidth type, and all other types of T-CONT can acquire bandwidth through dynamic bandwidth allocation. In OLT, the functional unit that allocates the upstream bandwidth to each T-CONT is called dynamic bandwidth allocation (DBA). The DBA of the GPON includes two types of status reporting DBA (SR-DBA) and non-status reporting DBA (NSR-DBA). Because the SR-DBA can more accurately respond to the bandwidth demand situation of T-CONT, the utilization rate of bandwidth is high. When using the SR-DBA, bandwidth allocation (T-CONT) reported by the T-CONT should be considered when allocating the upstream bandwidth to the T-CONT, as well as the service level agreement (SLA) , service level agreement) parameters should also be considered. The contents of these parameters differ depending on the type of T-CONT.

As one of the core technologies of GPON, realization of DBA should be carefully planned in consideration of various factors. In general, bandwidth allocation has a demand for throughput, time delay, jitter and fairness. There is a need for algorithm execution efficiency and resource share for algorithms. In addition, the DBA is a very active part of the GPON system. It affects the quality of service (QoS) and should be controlled normally. Currently, there are relatively few studies on GPON DBA, and most of them focus on research on algorithms. There are very few research reports on DBA realization design. In an earlier report, a DBA design approach was presented in "Efficient medium arbitration of FSAN-compliant GPONs" (published by H. C. Leliguo, Int.J.Commum.Syst 2006; 19: 603-617). One of the salient features of the scheme is that it realizes the assignment of the location and length of the time slots in the bandwidth allocation and bandwidth allocation map (BWMap) with one algorithm. In this case, there is a problem that the possibility of expansion is low due to strong coupling between the two. Therefore, it is necessary to study a new DBA realization method.

(Problem to be solved)

In order to solve the above problems, it is an object of the present invention to provide a dynamic bandwidth allocation apparatus and an implementation method thereof used in a passive optical network system.

(Solution to Problem)

According to one aspect of the present invention, there is provided a dynamic bandwidth allocation apparatus for use in a passive optical network system, the apparatus comprising: means for sequentially allocating a total number of transmission bytes to each transmission container in a passive optical network system in each dispatching period; A bandwidth allocation sub-unit for storing a transmission container bandwidth allocation list allocated and generated, a transmission bandwidth allocating sub-unit for allocating a total transmission byte number to each timing frame within the dispatch cycle after reading the transmission container bandwidth allocation list within each dispatch cycle, A dynamic bandwidth allocation apparatus comprising a bandwidth distribution strategy control sub-unit for generating a map.

In the dynamic bandwidth allocation apparatus described above, the bandwidth allocation subunit and the bandwidth distribution strategy control subunit perform different algorithms independently of each other.

In the dynamic bandwidth allocation apparatus, the bandwidth allocation sub-unit performs a bandwidth allocation algorithm to calculate the total number of transmission bytes based on the upstream bandwidth request information and the transport container service level protocol information set by the user.

In the dynamic bandwidth allocation apparatus, the bandwidth distribution strategy control subunit allocates the total number of transmission bytes to each timing frame by applying a bandwidth distribution strategy provided by the network manager under consideration of overhead allocation, Obtain the time slot position and length of the frame.

In the above-mentioned dynamic bandwidth allocation device, the upstream bandwidth request information transmitted from each transport container in the preceding cycle and received by the optical line terminating device is examined, and idle A bandwidth billing and statistics inquiring sub-unit for checking the statistics of the number of bytes, performing processing on the result of the examination, and storing the data through an interface provided by a data maintenance sub-unit, Provide an interface to the bandwidth billing and statistical exploration subunit so as to preserve uplink bandwidth billing information, provide an interface to the bandwidth allocation subunit so as to preserve the transport container bandwidth allocation list, Bandwidth distribution strategies A data maintenance sub-unit for providing an interface to the sub-unit, and a timing service sub-unit for providing a timing service to each sub-unit in the dynamic bandwidth allocation apparatus.

The dynamic bandwidth allocation apparatus comprising: an interface installation sub-unit for providing a user with an interface for installing a dynamic bandwidth allocation-related parameter, a transport container service level protocol parameter and a bandwidth distribution strategy; And an overhead processing sub-unit for calculating an uplink overhead to be transmitted by each frame in the same period.

In the dynamic bandwidth allocation apparatus, the passive optical network system is a gigabit passive optical network system.

According to another aspect of the present invention, there is provided a method for allocating dynamic bandwidth in a passive optical network system, the method comprising the steps of: allocating a bandwidth allocation subunit, a bandwidth distribution strategy control subunit, an interface installation subunit, an overhead processing subunit, A method for realizing a dynamic bandwidth allocation apparatus comprising a statistical exploration subunit, a data maintenance subunit, and a timing service subunit, the timing service subunit providing a timing interruption to form a cycle, The sub-unit is transmitted from each of the transmission containers in the previous cycle in each dispatch cycle, examines the upstream bandwidth request information received by the optical line interrupting device, and compares statistics of the number of non-idle bytes actually transmitted by each of the transmission containers in the previous cycle And after processing the result of the investigation, The bandwidth allocation subunit sequentially allocates the total number of transmission bytes to each of the transmission containers in the passive optical network system within each dispatch cycle, The bandwidth distribution strategy control subunit reads the transport container bandwidth allocation list in each dispatch cycle and then allocates the total number of transmission bytes to each timing frame in the dispatch cycle to finally allocate the bandwidth The dynamic bandwidth allocation unit notifies the bottom layer MAC hardware that the bandwidth allocation map has already been updated within each dispatch period and the MAC hardware transmits a bandwidth allocation map to each optical network And a step of transmitting to the work station.

In the above-mentioned realization method, the bandwidth allocation subunit and the bandwidth distribution strategy control subunit perform different algorithms independently of each other.

In the above-described realization method, the bandwidth distribution strategy control subunit allocates the total number of transmission bytes to each timing frame by applying the bandwidth distribution strategy implemented by the network manager under the circumstances in which the overhead allocation is considered.

In the above-mentioned realization method, the method further includes installing service level protocol parameters of each transport container, a parameter of the dynamic bandwidth allocation device itself, and a bandwidth distribution strategy through installation of an interface.

In the above-mentioned realization method, the passive optical network system is a gigabit passive optical network system.

Therefore, the method and apparatus according to the present invention can enhance the active and expandability of DBA function installation among XPON, for example, GPON. Other features and advantages of the invention will be set forth in detail in the description which follows, and in part will become apparent from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention may be realized and attained by the structure particularly pointed out in the written description and claims hereof and in the drawings.

(effect)

According to the method and apparatus of the present invention, since the bandwidth allocation portion and the bandwidth distribution control portion within the dispatch period can be separated, it is possible to independently adjust the bandwidth allocation algorithm and the bandwidth distribution strategy algorithm and provide an interface for installing DBA-related parameters. This method is simple to realize and can be realized not only by hardware but also by software. By adopting the DBA realization method, it is possible to improve the active and expandability of XPON, for example, DBA function installation in GPON.

The drawings described herein are for the purpose of understanding the present invention only and should not be construed as limiting the scope of the present invention.

1 is a GPON topology diagram according to an embodiment of the present invention,

FIG. 2 is a structural guide view of a DBA functional unit according to an embodiment of the present invention,

1 is a workflow diagram of a DBA apparatus according to an embodiment of the present invention.

(Detailed Description for Implementation of the Invention)

Specific embodiments of the present invention will be described with reference to the following drawings.

SUMMARY OF THE INVENTION The present invention provides a method of realizing a DBA function of a GPON that solves the disadvantages of non-existing and low scalability existing in the current technology.

A method of realizing the DBA function of the GPON according to the present invention is as follows:

The DBA functional unit includes a bandwidth allocation subunit, a bandwidth distribution strategy control subunit, an interface installation subunit, an overhead processing subunit, a DBRu and a statistics inquiry subunit, and a data maintenance maintenance sub-unit and a timing service sub-unit.

In the second step, the DBA device operates periodically. When the timing provided by the timing service subunit is interrupted, the DBRu and the statistical probing sub-unit firstly transmit the upward DBRu information received from the OLT to all the T-CONTs in the preceding cycle, And then stores the data through the access interface provided by the data maintenance sub-unit, thereby allowing the bandwidth allocation sub-unit to use the data. In addition, the statistics of the number of non-idle bytes actually transmitted by each T-CONT are examined in the previous cycle, the data is processed and stored through the access interface provided by the data maintenance sub-unit, and the bandwidth allocation sub- .

In the third step, the DBA bandwidth allocation subunit performs a bandwidth allocation algorithm. CONT allocates the total number of transmission bytes to each T-CONT in the dispatch cycle based on the DBRu information and the T-CONT SLA information set by the user, and transmits the generated T-CONT bandwidth allocation list to the data maintenance sub-unit Through the interface.

In a fourth step, the bandwidth allocation scheme control sub-unit follows and reads the bandwidth allocation list generated by the bandwidth allocation sub-unit through the access interface provided by the data maintenance sub-unit. Then, on the basis of overhead allocation, And allocates the total transmission bytes of each T-CONT to each 125us frame in the dispatch cycle to finally generate a BWMap.

In step 5, the DBA device notifies the lower layer MAC hardware that the BWMap has already been updated, and the MAC transmits the BWMap to the ONT through the downstream frame.

The sixth step, and the third step to the sixth step are duplicated.

Step 7, the network administrator can install the SLA of each T-CONT and the DBA device's own parameters and bandwidth distribution strategy through the layout interface.

Among them, the first step further includes the following steps.

1, the bandwidth allocation sub-unit performs a bandwidth allocation algorithm to allocate the total number of bytes that can be transmitted in one dispatch cycle to each T-CONT.

2, the bandwidth distribution maneuvering control sub-unit allocates time slot positions and lengths within each 125 us frame in each dispatch cycle of each T-CONT by applying a bandwidth allocation strategy.

3, The interface installation sub-unit provides the interface to install DBA-related parameters, T-CONT SLA parameters and bandwidth distribution strategies to the user.

4, the overhead processing sub-unit computes the total available bandwidth in one dispatch period and the uplink overhead that each frame should transmit within the same period.

5, the DBRu and the inquiry subunit examine and compile statistics of occupancy status and actual uplink transmission of their ranks reported by each T-CONT.

6, the data maintenance sub-unit maintains a list of data required by the other sub-units and provides an access interface.

7, Timing service sub-unit provides the timing synchronization service required for other sub-units.

The basic idea of the present invention will be described in detail below with reference to Figs. 1 is a GPON network topology diagram associated with the method of the present invention.

A plurality of ONTs may be connected to an OLT PON port through a spectroscope as shown in FIG. The downlink data transmission format from the OLT to the ONT is a time division multiple access and physical layer broadcast format, that is, each downlink frame is transmitted to the PON port of all the ONTs. The uplink data transmission format from the ONT to the OLT is a TDMA format. Each ONT includes a plurality of T-CONTs, and the allocation of the upstream bandwidth is realized through the DBA functional unit of the OLT, and the T-CONT is performed with authorization.

2 is a structural diagram of the DBA apparatus 200 according to the method of the present invention. 2, the DAB device 200 includes a bandwidth allocation subunit 202, a bandwidth distribution strategy control subunit 204, an interface installation subunit 206, an overhead processing subunit 208, A data maintenance subunit 212, and a timing service subunit 214. The data service subunit 212 is a data service subunit.

The functions of each sub-unit are as follows.

(1) The bandwidth allocation sub-unit 202 allocates the total number of bytes (number?) That can be transmitted to each T-CONT in one dispatch cycle. The parameters input thereby include the total available bandwidth, the SLA, DBRu information, type of each T-CONT, statistical information of the previous period, and bandwidth allocation granularity. The output is the total number of bytes that each T-CONT has obtained in this dispatch cycle and the list item is the total number of bytes that the T-CONT can transmit in this period. In this embodiment, the bandwidth allocation algorithm used by the bandwidth allocation subunit 202 can be provided as an independent dynamic link library without being related to the realization of the first DAB device 200. [

(2) The bandwidth distribution strategy control subunit 204 allocates the total number of transmittable bytes of the T-CONT generated by the bandwidth allocation subunit to each frame in the dispatch cycle according to a specified distribution strategy, and the overhead processing subunit 208 ) Together with the window distribution situation found by the ONT, constitutes a BWMap conforming to the ITU-T G.984.3 standard, and notifies the OLT MAC 216 to transmit a new BWMap to each ONT in a downlink frame . The bandwidth distribution strategy mentioned here is actually a Qos realization trick that a network administrator can install. For example, when employing the "throughput first" distribution strategy, the transmission time slot of a T-CONT belonging to one ONT should be arranged in one place to reduce the overhead as much as possible. In addition, there are strategies such as "time delay priority" or "jitter priority". This sub-unit is the best part of the entire DAB device 200 and its strategy algorithm can also be provided as a dynamic link library to facilitate updating and maintenance.

(3) The interface installation sub-unit 206 provides an interface for installing a DBA and a T-CONT SLA to a user who is a network administrator.

A. T-CONT SLA: Fixed Bandwidth, Assured Bandwidth, Non-Assured Bandwidth, Best Effort Bandwidth, Maximum Burst Packet Size and Weight (weight) etc .;

B. DBA device parameters: dispatch frequency, bandwidth allocation granularity, frequency of processes discovered by the ONT, maximum bandwidth available;

C. Bandwidth distribution strategy.

(4) The overhead processing sub-unit 208 processes the uplink overhead transmission request provided by the GPON OLT state machine. Based on this, computes the total available uplink bandwidth in the dispatch cycle and sends the result to the bandwidth allocation sub-unit 202. In addition, an overhead transmission request is provided to the bandwidth distribution strategy control subunit 204 to provide overhead transmission time slots at the BWMap.

(5) The DBRu and statistical survey subunit (i.e., the DBRu and statistical survey subunit shown in FIG. 2) 210 are actually divided into the following two parts. One is to check the number of bytes actually transmitted by each T-CONT and calculate the bandwidth usage status. The list item outputs a "T-CONT bandwidth utilization list", which is the bandwidth utilization rate of the T-CONT, It is used to monitor the use situation. The other is to check the DBRu information received from each T-CONT in the previous cycle and output a "T-CONT bandwidth request list". The list item is the number of bytes requested to be transmitted by the T-CONT.

(6) The data maintenance sub-unit 212 provides an access interface to all parameters and data lists that can be installed in the DBA apparatus and performs mutual exclusion protection processing. However, this sub-unit is the final output of the DBA device and the maintenance of the BWMap list used in the OLT MAC hardware 216 is not responsible.

(7) The timing service subunit 214 is generally implemented in hardware and can be simplified, for example, to provide a timing service of 125us, and when the dispatch cycle is interrupted, the DBA begins cycling.

3 is a complete process flow diagram within one cycle of a DBA device according to the method of the present invention, illustrating the method shown in FIG. 3 in combination with the device 200 shown in FIG. 2 below. As shown in FIG. 3, after receiving the interruption provided by the timing service sub-unit, the DBA starts the operation of one cycle.

In step S302, the DBRu and the statistical inspecting subunit 210 examine the statistics of the uplink DBRu request and actual transmission amount of each T-CONT in the previous cycle through the hardware, Quot; use rate list "and" T-CONT bandwidth request list ". The overhead processing sub-unit 208 computes the total available uplink bandwidth in the following period.

In step S304, the bandwidth allocation sub-unit 202 performs a bandwidth allocation algorithm to allocate the total number of bytes that can be transmitted to each T-CONT and generates a "T-CONT bandwidth allocation list ". The bandwidth distribution strategy control subunit 204 then allocates a specific transmission time slot to the overhead that needs to be transmitted within this period first.

In step S306, an actual transmission time slot is allocated to each T-CONT within each 125us frame in the period according to the currently designated distribution strategy, and the hardware is notified that the final BWMap has been configured and updated.

In step S308, the OLT MAC hardware 216 transmits the BWMap to all ONTs through a downlink frame.

In addition, the method further includes installing the service level protocol parameters of each transport container, the dynamic bandwidth allocation device's own parameters and the bandwidth distribution strategy through the installation of the interface.

In addition, the bandwidth allocation subunit 202 and the bandwidth distribution strategy control subunit 204 are independent and perform different algorithms. In addition, the bandwidth distribution scheme control subunit 204 allocates the total number of transmission bytes to each timing frame by applying the bandwidth distribution scheme implemented by the network manager under circumstances in which overhead allocation is considered.

As described above, according to the present invention, the following effects can be realized.

According to the method and apparatus of the present invention, since the bandwidth allocation portion and the bandwidth distribution control portion within the dispatch period can be separated, it is possible to independently adjust the bandwidth allocation algorithm and the bandwidth distribution strategy algorithm, and provide an interface for installing DBA-related parameters do. This method is simple to realize and can be realized not only by hardware but also by software. By adopting the DBA realization method, it is possible to improve the active and expandability of XPON, for example, DBA function installation in GPON.

The foregoing is not intended to limit the present invention to the optimized embodiments of the present invention. Those skilled in the art can make various changes and changes in the present invention. All such equivalents, equivalents, modifications and the like which are within the scope of the present invention are within the scope of the present invention.

Claims (10)

1. A dynamic bandwidth allocation apparatus used in a passive optical network system, A bandwidth allocation sub-unit for sequentially allocating a total number of transmission bytes to each transmission container in the passive optical network system and storing a transmission container bandwidth allocation list generated in each dispatch cycle; A bandwidth distribution strategy control sub-unit for reading the transmission container bandwidth allocation list in each dispatch cycle, allocating the total number of transmission bytes to each timing frame in the dispatch cycle, and finally generating a bandwidth allocation map; The upstream bandwidth request information transmitted from each of the transmission containers in the previous cycle and received by the optical line interception device is examined and the statistics of the number of idle bytes actually transmitted by each of the transmission containers in the previous period are examined, A bandwidth sub-unit for storing the bandwidth sub-unit and the bandwidth sub-unit for saving through an interface provided by the data maintenance sub-unit, Providing an interface to the bandwidth billing and statistical exploration subunit so as to preserve the uplink bandwidth billing information and providing an interface to the bandwidth allocation subunit so as to preserve the transmission container bandwidth allocation list, A data maintenance sub-unit for providing an interface to the bandwidth distribution strategy control sub-unit so as to access the allocation list, And a timing service sub-unit for providing a timing service to each sub-unit in the dynamic bandwidth allocation apparatus, Wherein the bandwidth allocation subunit and the bandwidth distribution strategy control subunit are independent from each other, The bandwidth allocation subunit performs a bandwidth allocation algorithm to calculate the total number of transmission bytes based on the upstream bandwidth request information and the transport container service level protocol information set by the user, Wherein the bandwidth distribution scheme control subunit allocates the total number of transmission bytes to each of the timing frames by applying a bandwidth distribution scheme established by a network manager under consideration of overhead allocation, Wherein the dynamic bandwidth allocation apparatus is used in a passive optical network system. The method according to claim 1, An interface installation sub-unit for providing a user with a dynamic bandwidth allocation related parameter, an interface for installing a transmission container service level protocol parameter and a bandwidth distribution scheme, Further comprising an overhead processing sub-unit for calculating the total available bandwidth within one dispatch period and the uplink overhead to be transmitted by each frame in the same period. The dynamic bandwidth allocation apparatus of claim 1 or 2, wherein the passive optical network system is a gigabit passive optical network system. A bandwidth allocation sub-unit, an interface installation sub-unit, an overhead processing sub-unit, a bandwidth billing and statistical inspection sub-unit, and a bandwidth allocation sub-unit, which are used for dynamic bandwidth allocation of a passive optical network system, A method of realizing a dynamic bandwidth allocation apparatus including a maintenance sub-unit and a timing service sub- Said timing service sub-unit providing an interruption of timing to form a period, The bandwidth billing and statistics inquiry sub-unit is transmitted from each transport container within a full cycle within each dispatch cycle and examines the uplink bandwidth billing information received by the optical line interrupting device, and the non-idle The number of bytes is checked, the result of the examination is processed, and the result is stored through the interface provided by the data maintenance subunit, thereby allowing the bandwidth allocation subunit to use the bandwidth allocation subunit. The bandwidth allocation subunit sequentially allocates the total number of transmission bytes to each transport container in the gigabit passive optical network system in each dispatch cycle and stores the generated transport container bandwidth allocation list, Wherein the bandwidth distribution strategy control subunit reads the transport container bandwidth allocation list in each dispatch cycle and then allocates the total number of transmission bytes to each timing frame in the dispatch cycle to finally generate a bandwidth allocation map, The dynamic bandwidth allocation device notifies the lower layer MAC hardware that the bandwidth allocation map has already been updated within each dispatch cycle and the MAC hardware transmits the bandwidth allocation map to each optical network terminal through a downstream frame And realizing the dynamic bandwidth allocation apparatus.  5. The method as claimed in claim 4, wherein the bandwidth allocation subunit and the bandwidth distribution strategy control subunit perform different algorithms independently of each other. The method of claim 4 or 5, wherein the passive optical network system is a gigabit passive optical network system. delete delete delete delete

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