KR20050118390A - Method for sla-based dynamic bandwidth allocation for ethernet passive optical network - Google Patents

Abstract

An object of the present invention is to provide a dynamic bandwidth allocation (DBA) method for uplink data transmission of an ONU (optical network unit) in an Ethernet passive optical subscriber network (EPON).

According to the present invention, if an uplink desired time length is greater than the maximum available time length, the maximum time length that can be used for uplink transmission to all ONUs at least once and the time already used by ONUs before the specific ONU are surplus. Determining a time; Determining a time available from the surplus time for burst traffic processing of the particular ONU; And finally determining an uplink bandwidth available time using a parameter related to the distribution of the redundant band determined by the SLA and a time available for burst traffic processing of the specific ONU. There is provided a dynamic bandwidth allocation method for uplink data transmission comprising: a.

Description

Method for SLA-based dynamic bandwidth allocation for ethernet passive optical network

The present invention relates to a bandwidth allocation method of a passive optical network (PON), and in particular, uplink data transmission of an ONU (optical network unit) in an Ethernet passive optical network (EPON: Ethernet PON). The present invention relates to a dynamic bandwidth allocation method (DBA).

X-Digital Subscriber Line (xDSL), Hybrid Fiber Coax (HFC), Fiber To The Building (FTTB), Fiber To The Curb (FTTC), and Fiber To (FTTH) Various home structures such as The Home are proposed.

Meanwhile, among these various network structures, the FTTx structure may be classified into an active FTTx and a passive FTTx depending on the presence of outdoor active equipment. Among these, PON is a passive FTTx method, which has a point-to-multipoint topology by passive devices, and a single optical fiber is shared by several ONUs, thereby reducing the cost of installing optical fibers and using outdoor active devices. It is attracting attention as an economical way of implementing an optical subscriber network by reducing operation management and maintenance costs.

The above-described PON connects one optical line termination device (OLT) and a plurality of optical subscriber network devices (ONUs) using a 1: N passive optical distribution network (ODN), thereby providing a tree structure. It is an optical subscriber network structure forming a distributed topology.

1 is a conceptual diagram illustrating a general configuration of an Ethernet passive optical subscriber network.

As shown in FIG. 1, the EPON has a tree structure in which one OLT corresponds to 1: N through a plurality of ONUs and passive elements. In the downlink transmission from the OLT to the ONU, the data transmitted by the OLT is broadcast to all ONUs, and since this method is almost the same as in the existing Ethernet, there is no problem of media sharing due to EPON.

However, in the uplink transmission from the ONU to the OLT, since a plurality of ONUs are connected from the passive element to the OLT through one optical fiber, in order to perform uplink transmission without collision between ONUs, a TDMA MAC (accessing a medium while avoiding duplication in time) A Time Division Multiple Access Medium Access Control protocol is required.

The simplest uplink bandwidth allocation method is to allocate fixed time slots to each ONU to avoid collisions between the ONUs. However, this method has a problem that the ONU without uplink data continues to occupy the band, thereby causing unnecessary band waste.

The present invention has been made to solve the above problems of the prior art, while preventing data collisions between ONUs that may occur when one ONU is shared by TDMA schemes for uplink transmission in an E-PON. The purpose is to provide a method for dynamically uplink bandwidth allocation to each ONU.

According to the present invention for achieving the object as described above, the uplink data of the optical network unit (ONU) of the Ethernet passive optical network (E-PON) including a plurality of optical network units (ONU) In the Dynamic Bandwidth Allocation (DBA) method for transmission, when a bandwidth allocation request message including uplink bandwidth use time length information (REQi) is received from a specific ONU, the bandwidth allocation request message is received by a service level agreement (SLA). A first step of comparing the guaranteed maximum available time length (MAX_GRANTi); As a result of the comparison in the first step, if the desired uplink bandwidth use time length is greater than the maximum available time length, the maximum length of time (MAX_CYCLE_TIME) that can be uplinked at least once to all ONUs and the ONU before the specific ONU A second step of determining surplus time REMNANT_TIME using the time they have already used; A third step of determining an available time (ADD_TIME) for processing burst traffic of the specific ONU from the surplus time calculated in the second step; And finally using the uplink band by using a parameter (WFi) related to the allocation of the surplus band determined by the SLA and the available time (ADD_TIME) for processing burst traffic of a specific ONU determined in the third step. A fourth step of determining a possible time; There is provided a dynamic bandwidth allocation method for uplink data transmission comprising: a.

In the following, with reference to the accompanying drawings, a preferred embodiment according to the present invention will be described in detail.

Since the amount of traffic that ONUs wants to send varies over time and is bursty, it is essential to dynamically allocate an uplink accordingly to prevent unnecessary waste of the uplink and to reduce transmission delay time.

Accordingly, the present invention provides a method for dynamically allocating uplink bandwidth, thereby maximizing utilization of uplink TDMA, minimizing delay time of uplink traffic, and ensuring fairness between ONUs. In addition, TDM-dedicated line-class fixed bandwidth services, guaranteed bandwidth services capable of providing quality of service (QoS), and uplink dynamic bandwidth to effectively provide non-guaranteed extended bandwidth services for bursty Best Effort services Provide an allocation method.

The core of the present invention is to vary the size of the uptime slot allocated to each ONU according to the data transmission amount, more specifically, by setting GUARANTEED_TIME and EXTENDED_TIME within MAX_CYCLE_TIME, guaranteed services such as dedicated line-class TDM service and video The GUARANTEED_TIME is used, and the other best effort traffic is implemented using a GUARANTEED_TIME and EXTENDED_TIME to implement a DBA that performs burst burst traffic efficiently.

In addition, the present invention uses VARIABLE_CYCLE_TIME without using FIXED_CYCLE_TIME, and according to the time allocated to each ONU, CYCLE_TIME is variable within a range not exceeding MAX_CYCLE_TIME, so that the delay of uplink transmission is smaller than that of FIXED_CYCLE_TIME.

In addition, in FIXED_CYCLE_TIME, the delay between REQ and GRANT is inevitably occurred in DBA implementation by calculating a surplus band and sending a GRANT after receiving REQ from all ONUs to investigate a band not used by other ONUs. do. However, according to the present invention, even if receiving only the REQ of the ONU without such a process, it is possible to calculate the band left without using other ONUs and send the GRANT.

For convenience of explanation, it is assumed that the distance between the OLT and several ONUs is the same. In addition, terms used herein are defined as follows.

REQi: Uptime transmission request time requested by ONUi to OLT

GRANTi: OLT allows uplink transmission time for ONUi, and tells ONUi the start time of transmission and the length of time available. Meanwhile, the exchange of REQi and GRANTi uses the Multi Point Control Protocol (MPCP) defined in IEEE 802.3ah, and each ONU transmits REQi up once by round robin for one CYCLE_TIME. Receive GRANTi The transmission of REQi is accomplished by transmitting MPCP Ethernet frames at the end of uplink data transmission, and the transmission of GRANTi is achieved by sending MPCP Ethernet frames at the end of downlink data transmission.

MAX_GRANTi: This is a fixed time allocated to ONUi for one cycle regardless of REQi. It is determined by the initial Service Level Agreement (SLA).

* MAX_CYCLE_TIME: This is the maximum time period that all ONU can transmit upward at least once, to provide the service that needs minimum delay time guarantee such as voice, video or leased line. Typically, when POTS service is provided, the delay condition is satisfied by setting MAX_CYCLE_TIME within 2 msec.

REMNANT_TIME: MAX_CYCLE_TIME-Total usage time of previous N-1 ONUs = MAX_CYCLE_TIME-Sum {j = i- (N-1) to i-1} (GRANTj). Here, i- (N-1) is shorthand for i- (N-1) mod N. After that, unless otherwise stated, it is assumed that mod N operation is used due to repeated cycles.

* GUARANTEED_TIME: Sum of all MAX_GRANTi. When FIG. 4 is described, it will be described in detail.

EXTENDED_TIME: MAX_CYCLE_TIME-GUARANTEED_TIME. When explaining FIG. 4, it demonstrates in detail.

* ADD_TIME: It means additional time to ONUi besides MAX_GRANTi.

* WFi: Weighted Fairness usage coefficient of ADD_TIME, which is a range between 0 and 1.

FIG. 2 is a flowchart illustrating a dynamic bandwidth allocation method according to an embodiment of the present invention, FIG. 3 is a flowchart illustrating a transformation calculation for FIG. 2, FIG. 4 is a conceptual diagram illustrating GUARANTEED_CYCLE_TIME and EXTENDED_CYCLE_TIME, and FIG. 5 is pre. FIG. 6 is an exemplary diagram illustrating a REMNANT_TIME calculation method according to a CYCLE_TIME condition, and FIG. 6 is an exemplary diagram illustrating a ADD_TIME calculation method according to a post CLCLE_TIME condition.

First, in step S201, for uplink transmission, the ONUi requests the OLT to allow uplink transmission through REQi. At this time, REQi includes data transmission time required according to the ONUi buffer state.

Subsequently, in step S203, the OLT determines whether the REQi of the ONUi matches the SLA. At this time, the determination of conformance is made by comparing the values of REQi and MAX_GRANTi.

As a result of the determination in step S203, if REQi satisfies SLA and is smaller than MAX_GRANTi, in step S205, the OLT allocates GRANT (GRANTi = REQi) for the time requested by the ONUi, and then proceeds to step S213.

On the other hand, as a result of the determination in step S203, if REQi is equal to or larger than MAX_GRANTi, even if only ON_i is allowed up to MAX_GRANTi, it does not violate SLA. However, if there is a surplus band remaining by other ONUs, the surplus band may be additionally allocated to the best effort. That is, if REQi is greater than MAX_GRANTi, it is determined through the surplus time REMNANT_TIME whether additional band allocation is possible, which is implemented in detail through the following process. Meanwhile, as shown in FIG. 5, REMNANT_TIME is a time obtained by subtracting the total GRANT time used by N-1 ONUs prior to ONUi from MAX_CYCLE_TIME, and represents a maximum time that ONUi can use within a range not exceeding MAX_CYCLE_TIME.

Therefore, in step S207, REMNANT_TIME of ONUi is calculated as shown in [Equation 1] below.

REMNANT_TIME = MAX_CYCLE_TIME-Sum {j = i-(N-1) to i-1} (GRANTj)

Where N is the total number of ONUs, i is an integer greater than or equal to 1 and less than or equal to N, and i- (N-1) is short for i- (N-1) mod N for convenience.

Meanwhile, in order to ease the implementation and reduce the time delay between REQ and GRANT, REMNANT_TIME can be calculated using the previously calculated REMNANT_TIME without having to calculate a new one every time, and this is shown in step S311 of FIG. 3. According to [Equation 2].

REMNANT_TIME = REMNANT_TIME-GRANTi + GRANTi + 1

Where GRANTi + 1 represents the GRANT value of ONUi + 1 in the previous cycle.

Subsequently, in step S209, from the REMNANT_TIME and EXTENDED_TIME, ONUi actually calculates ADD_TIME that can be used in addition to MAX_GRANTi.

On the other hand, as shown in Figure 5, the total time that the ONUi can be used must be less than REMNANT_TIME. Also, as shown in FIG. 6, it should be smaller than MAX_GRANTi + EXTENDED_TIME. Because if ONUi exceeds this value, the worst case CYCLE_TIME from ONUi to ONU _{i + N-1} will be reduced when all N-1 ONUs after ONUi use their MAX_GRANTi time. This is because MAX_CYCLE_TIME is exceeded. Therefore, ADD_TIME can be calculated as shown in Equation 3 below.

ADD_TIME = MIN (REMNANT_TIME-MAX_GRANTi, EXTENDED_TIME)

EXTENDED_TIME = MAX_CYCLE_TIME-Sum {i = 1 to N} (MAX_GRANTi)

Next, in step S211, GRANTi is calculated. WFi, on the other hand, is a SLA parameter for the distribution of the redundant band and has a value between 0 and 1. If WFi is 0, ADD_TIME cannot be used at all. If 1, ONUi uses GREEDY freely of all the surplus bands at that moment. Properly setting WFi can provide fair distribution of burst traffic. For example, setting WFi = 1 / N means that all ONUs are divided equally in the excess band. In addition, setting WFi = 0.3 means that ONUi can be used up to 30% of the surplus band. WFi is determined by SLA. Accordingly, GRANTi allocated to ONUi is determined as shown in Equation 4 below.

GRANTi = MAX_GRANTi + WFi * ADD_TIME

On the other hand, when WFi is less than 1 and ADD_TIME is not used by ONUi, CYCLE_TIME up to ONUi is reduced by (REMNANT_TIME-GRANTi). Accordingly, CYCLE_TIME is smaller than MAX_CYCLE_TIME, resulting in reduced delay time.

Then, in step S213, 1 is added to i to proceed to the next ONU, and then the process returns to the step S201.

On the other hand, using a fixed cycle time as in the prior art does not reduce the cycle time even when there is less uplink data to be transmitted, while using a variable cycle time as in the present invention results in reducing the cycle time when the amount of upstream data is small The transmission delay can be reduced.

In addition, it is possible to provide a TDM service with a dedicated circuit concept that always assigns GRANTi to MIN_GRANTi or higher to set the minimum value of the uptime time slot of the ONU to guarantee a certain speed or more. At this time, the MIN_GRANTi time is a time that is not allocated to another ONU even if ONUi is not used. Therefore, it is a time fixed exclusively for ONUi. This result means that the present invention provides a fixed bandwidth.

In addition, QoS transfer is possible by allowing GRANTi to be available at any time within the MAX_GRANTi range for one cycle time. At this time, the time until MAX_GRANTi corresponds to the same service as the fixed bandwidth providing effect in that it can be used any time when ONUi requests. However, if the time zone is not used by the ONUi, the result of the fact that other ONUs can be used means that it provides guaranteed bandwidth.

In addition, the present invention has introduced EXTENDED_TIME and REMNANT_TIME to enable the use of surplus time that previous ONUs did not use within one cycle time. In particular, in the calculation of REMNANT_TIME, the start and end of one cycle time is not fixed, and the cycle time up to ONUi (pre CYCLE_TIME) and cycle time from ONUi (post CYCLE_TIME) on the basis of ONUi at each moment are MAX_CYCLE_TIME. By using the condition that it should not exceed, ONUi calculates additional ADD_TIME that can be used to send instantaneous traffic during this time, thus providing the non-guaranteed extended bandwidth.

On the other hand, using the present invention shows an example of bandwidth setting according to the SLA contract as follows.

The uplink bandwidth is set for each ONU, and the downlink bandwidth is set by the inherent characteristics of the Ethernet and thus has no relation to the contents of the present invention.

(1) Example 1

* Fixed Bandwidth: 4 Mbps (E1 Dedicated Line + BcN Video Phone)

* Guaranteed Bandwidth: 12 Mbps (Dual Video Service for DTV + High Speed Internet)

* Non-guaranteed extended bandwidth: 400 Mbps (Efficient acceptance of burst traffic such as P2P, FTP, etc. of users who operate private servers)

* MAX_CYCLE_TIME = 2 msec

* Total number of ONUs = 32

* GUARD_TIME = 1 usec

* MIN_GRANTi = 2 msec * 4 Mbps / 1 Gbps = 8 usec to provide fixed bandwidth

* MAX_GRANTi = 2 msec * 12 Mbps / 1 Gbps = 24 usec to provide guaranteed bandwidth

* GUARANTEED_TIME = 32 * (1 + 8 + 24) = 1056 usec

* EXTENDED_TIME = 2000-1056 = 944 usec

* Maximum surplus bandwidth = 944/2000 * 1 Gbps = 472 Mbps

Therefore, setting WFi = 0.85 allows for 400 Mbps of unguaranteed extended bandwidth.

(2) Example 2

* Fixed Bandwidth: 4 Mbps (E1 Dedicated Line + BcN Video Phone)

* Guaranteed Bandwidth: 20 Mbps (Two-way Video Service for DTV + High Speed Internet)

* Non-guaranteed extended bandwidth: 100 Mbps (Efficient acceptance of burst traffic such as P2P, FTP, etc. of users who operate private servers)

* MAX_CYCLE_TIME = 2 msec

* Total number of ONUs = 32

* GUARD_TIME = 1 usec

* MIN_GRANTi = 2 msec * 4 Mbps / 1 Gbps = 8 usec to provide fixed bandwidth

* MAX_GRANTi = 2 msec * 20 Mbps / 1 Gbps = 40 usec for guaranteed bandwidth

* GUARANTEED_TIME = 32 * (1 + 8 + 40) = 1568 usec

* EXTENDED_TIME = 2000-1568 = 432 usec

* Maximum surplus bandwidth = 432/2000 * 1 Gbps = 216 Mbps

Thus, setting WFi = 0.47 allows for 100 Mbps of unguaranteed extended bandwidth.

On the other hand, due to the time of the turn on / off of the laser diode, MPCP messages, etc. during the transmission between the ONU, there is a constant GUARD_TIME between the transmission between the ONU, there is a total of N GUARD_TIME during one CYCLE_TIME. Accordingly, the utilization of the uplink transmission band is calculated as (CYCLE_TIME-n * GUARD_TIME) / CYCLE_TIME.

Therefore, if CYCLE_TIME is reduced, transmission delay is reduced, but utilization is inferior. This phenomenon is a problem when the number of ONU is large. For example, if MAX_CYCLE_TIME is 2 msec, GUARD_TIME is 1 usec, and 32 ONUs, EXTENDED_TIME is not set, MAX_GRANT = 2000/32 usec-1 usec = 61.5 usec. If one of the 32 ONUs is idle with no data to be sent at a given time, the maximum efficiency a single ONU can achieve is 61.5 / (61.5 + 32 * 1) = 0.66, which is about 660 Mbps. If GUARD_TIME is increased for physical implementation reasons, the efficiency is further reduced. This low efficiency is because the ratio occupied by GUARD_TIME becomes relatively large when CYCLE_TIME decreases.

On the other hand, if the method proposed in the present invention is used, MAX_GRANT is set to 40 usec for each ONU, EXTENDED_TIME = 2000-40 * 32 -1 * 32 = 688 usec, and WFi = 1 The upward utilization is (40 + 688) / (728 + 32 * 1) = 0.957, which is close to 950 Mbps. Therefore, it is possible to maximize the upward utilization through the efficient distribution of the non-bandwidth that is not used compared to the prior art.

Although the technical spirit of the present invention has been described above with reference to the accompanying drawings, it is intended to exemplarily describe the best embodiment of the present invention, but not to limit the present invention. In addition, it is obvious that any person skilled in the art may make various modifications and imitations without departing from the scope of the technical idea of the present invention.

As described above, according to the present invention, by utilizing variable cycle time, extension time and surplus time, it is possible to minimize uplink transmission delay, provide not only fixed bandwidth but also guaranteed bandwidth, and non-guaranteed extension for efficient reception of burst traffic. The bandwidth service can be provided at the same time.

1 is a conceptual diagram showing a general configuration of an Ethernet passive optical subscriber network,

2 is a flowchart illustrating a dynamic bandwidth allocation method according to an embodiment of the present invention;

3 is a flowchart showing a deformation calculation for FIG. 2;

4 is a conceptual diagram illustrating GUARANTEED_CYCLE_TIME and EXTENDED_CYCLE_TIME,

5 is an exemplary diagram illustrating a REMNANT_TIME calculation method based on a pre CYCLE_TIME condition.

6 is an exemplary diagram illustrating a method of calculating ADD_TIME based on a post CYCLE_TIME condition.

Claims (6)

Dynamic Bandwidth Allocation (DBA) method for uplink data transmission of an Optical Network Unit (ONU) of an Ethernet Passive Optical Network (E-PON) including a plurality of optical network units (ONUs) To A first step of, when receiving a band allocation request message including uplink bandwidth use time length information (REQi) from a specific ONU, comparing it with a maximum usable time length (MAX_GRANTi) guaranteed by a service level agreement (SLA); As a result of the comparison in the first step, if the desired uplink bandwidth use time length is greater than the maximum available time length, the maximum length of time (MAX_CYCLE_TIME) that can be uplinked at least once to all ONUs and the ONU before the specific ONU A second step of determining surplus time REMNANT_TIME using the time they have already used; A third step of determining an available time (ADD_TIME) for processing burst traffic of the specific ONU from the surplus time calculated in the second step; And The uplink can be finally used by using a parameter (WFi) related to the allocation of the excess band determined by the SLA and the available time (ADD_TIME) for processing burst traffic of a specific ONU determined in the third step. A fourth step of determining time; Dynamic bandwidth allocation method for uplink data transmission comprising a. The method of claim 1, A fifth step of allocating an uplink bandwidth available time as requested by the specific ONU when the uplink bandwidth desired time length is less than a maximum available time length as a result of the comparison in the first step; Dynamic bandwidth allocation method for uplink data transmission, characterized in that it further comprises. The method of claim 1, The surplus time REMNANT_TIME is determined by Equation 1 below. [Equation 1] REMNANT_TIME = MAX_CYCLE_TIME-Sum {j = i-(N-1) to i-1} (GRANTj) Where N is the total number of ONUs, i is an integer greater than or equal to 1 and less than or equal to N, and i- (N-1) is short for i- (N-1) mod N for convenience. The method of claim 1, The surplus time REMNANT_TIME is determined by Equation 2 below. [Equation 2] REMNANT_TIME = REMNANT_TIME-GRANTi + GRANTi + 1 Where GRANTi + 1 represents the GRANT value of ONUi + 1 in the previous cycle The method of claim 1, In the third step, the available time (ADD_TIME) for processing the burst traffic (Burst Traffic) of the particular ONU is determined by the following equation [3] Dynamic bandwidth allocation method for uplink data transmission. [Equation 3] ADD_TIME = MIN (REMNANT_TIME-MAX_GRANTi, EXTENDED_TIME) EXTENDED_TIME = MAX_CYCLE_TIME-Sum {i = 1 to N} (MAX_GRANTi) The method of claim 1, In the fourth step, the dynamic bandwidth allocation method for uplink data transmission, characterized in that the final uplink available time is determined by the following equation (4). [Equation 4] GRANTi = MAX_GRANTi + WFi * ADD_TIME