CN111464890A - Dynamic bandwidth allocation method for network slice and O L T - Google Patents

Abstract

A dynamic bandwidth allocation method of network slices and O L T relate to a DBA method of a PON system, and include the steps of setting service quality grades of all network slices a1., establishing a corresponding relation with T-CONT, configuring the residual bandwidth scheduling type of the T-CONT to BE none, NA or BE, a2, allocating the bandwidth of the current DBA period to the network slices according to the bandwidth requirement collected in the last DBA period of each T-CONT, enabling the bandwidth allocated by each T-CONT not to BE larger than the sum of the fixed bandwidth and the guaranteed bandwidth, a3., if a PON port has unallocated bandwidth, sequentially meeting the bandwidth requirement of the T-CONT with the residual bandwidth scheduling type of the NA according to the service quality grades, a4., if the PON port still has unallocated bandwidth, sequentially meeting the bandwidth requirement of the T-CONT with the residual bandwidth scheduling type of the BE according to the service quality grades.

Description

Dynamic bandwidth allocation method for network slice and O L T

Technical Field

The invention relates to a Dynamic Bandwidth Allocation (DBA) method of a Passive Optical Network (PON) system, in particular to a Dynamic Bandwidth Allocation method of a Network slice and O L T.

Background

The PON access Network adopts passive Optical fiber transmission, can simultaneously carry various services such as data, voice, video and the like, and mainly comprises an Optical line terminal (Optical L incoming terminal, O L T), an Optical Network Unit (ONU) and an Optical Distribution Network (ODN).

An operator can access a plurality of ONUs through an ODN under one PON port, and the ONUs share a PON link of O L T, in an uplink direction, a Time-division multiplexing (TDM) mode is generally adopted to realize that the ONUs share an uplink, O L T uses a Dynamic Bandwidth Allocation (DBA) function to allocate a Time slot to each ONU, and the ONUs can only send data in a given Time slot to avoid uplink collision, various services in the PON network are carried by using a geoport, and the granularity of uplink bandwidth scheduling is a scheduling Container (T-CONT).

The method includes the steps that a network slicing function of a PON system can be introduced, the reusability of the basic network infrastructure can be improved, a plurality of operators can share one network, and the network construction cost can be greatly reduced, so that the reusability of O L T equipment can be further improved, physical O L T is divided into a plurality of logic slices, Service forwarding and configuration management among the slices are independent, an application scene that a plurality of tenants (virtual operators) share O L T equipment is realized, in the application, slicing Service level agreements (Service L even policy) facing different tenants exist, S L A) are different, if slices serving high-value government users generally need larger bandwidth and lower time delay, and when a family user slice serving common values needs lower Service priority, the network provider also needs to share a plurality of network slices according to the quality of the same ODN when providing the network slices for each tenant, and the PON can share a plurality of network slices.

The specific implementation is that a Dynamic Bandwidth Allocation (DBA) algorithm of O L T is to schedule and allocate bandwidth for all T-CONT in the whole PON port, so that only indiscriminate mixed scheduling can be performed among all slices, bandwidth required by preferential scheduling for high-value slice users cannot be scheduled, and delay optimization cannot be performed for high-value slice users.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a dynamic bandwidth allocation method of network slices and O L T, which are used for providing differentiated quality assurance services for different network slice users.

In order to achieve the above object, in one aspect, a method for dynamically allocating bandwidth of a network slice is adopted, which includes the steps of:

a1. setting the service quality grade of each network slice, and establishing a corresponding relation between a scheduling container T-CONT and the network slices; configuring the residual bandwidth scheduling type of the T-CONT as no residual bandwidth none, no guaranteed bandwidth NA or best effort bandwidth BE;

a2. according to the bandwidth demand collected in the last dynamic bandwidth allocation DBA period of each T-CONT, the bandwidth of the current DBA period is allocated to the network slice, and the bandwidth allocated to each T-CONT is not more than the sum of the fixed bandwidth and the guaranteed bandwidth of the T-CONT;

a3. if the PON port of the passive optical network has unallocated bandwidth, sequentially meeting the bandwidth requirement of the T-CONT with the residual bandwidth scheduling type of NA according to the service quality grade of each network slice;

a4. and if the PON port still has unallocated bandwidth, sequentially meeting the bandwidth requirement of the T-CONT with the residual bandwidth scheduling type BE according to the service quality grade of each network slice.

Preferably, in the step a1, a DBA scheduling parameter vector is configured for the T-CONT, where the DBA scheduling parameter vector includes a fixed bandwidth, a guaranteed bandwidth, a maximum bandwidth, and a remaining bandwidth scheduling type;

each network slice is identified by an index, the DBA scheduling parameter vector further comprises a parameter which represents the index of the network slice to which the T-CONT belongs, and each T-CONT uniquely belongs to one network slice.

Preferably, for each T-CONT belonging to one slice, the sum of the fixed bandwidth configuration and the guaranteed bandwidth configuration is not more than the maximum bandwidth configuration; and the sum of the fixed bandwidth configuration and the guaranteed bandwidth configuration of all the T-CONT is not more than the total bandwidth of the PON port.

Preferably, the step a2 includes reading the bandwidth requirements of all T-CONT ports under the corresponding PON port collected by the optical line terminal O L T in the last DBA cycle:

if the bandwidth requirement is less than the sum of the fixed bandwidth and the guaranteed bandwidth, the bandwidth allocated to the T-CONT is the bandwidth required by the T-CONT; otherwise, the bandwidth allocated to the T-CONT is equal to the sum of the fixed bandwidth and the guaranteed bandwidth of the T-CONT.

Preferably, the service quality level of the network slice is represented by a priority and a weight, and the higher the priority is, the higher the service quality level of the corresponding network slice is; the higher the weight of the network slice with the same priority, the higher the service quality level.

Preferably, the unallocated bandwidth in step a3 is an unallocated guaranteed bandwidth allocable to the PON port, and is the sum of the bandwidths allocated by all the T-CONT according to step a2 subtracted from the total bandwidth of the PON port;

processing each network slice according to the priority from high to low, sequentially meeting the requirement of T-CONT with the residual bandwidth scheduling type of NA in each network slice, and updating the residual value of the bandwidth which can be distributed by the PON port and is not guaranteed;

and allocating the network slices with the same priority according to the weight proportion without ensuring the bandwidth.

Preferably, for each network slice indexed by i, all remaining bandwidth scheduling types x in the network slice_ABT-CON of NAT^jBandwidth R allocated in period t^j(t) is:

where j is the index of T-CONT, j ∈ { I^j＝i}，I^jThe index of the network slice to which the T-CONT belongs takes values of 1-N,

to be configured for T-CONT^jThe maximum bandwidth of the first channel and the second channel,

to be configured for T-CONT^jThe fixed bandwidth of the network,

for each T-CONT in the period T^jThe bandwidth requirement of (d);

if T-CONT^jThe bandwidth can be satisfied, then

Continuing to process the next T-CONT in the network slice, wherein

Allocating an unqualified bandwidth for the network slice i;

otherwise, stopping updating the bandwidth of the T-CONT in the network slice and continuing to process the next network slice until all network slices are processed or the residual bandwidth S which is not guaranteed and is totally available at the PON port_NA(t) total depletion;

the above-mentioned

And configuring the bandwidth for guaranteeing.

Preferably, the unallocated bandwidth in step a4 is the best effort bandwidth allocable by the PON port, and is the sum of the bandwidths allocated by all T-CONT according to step a2 and step a3 and subtracted from the total bandwidth of the PON port;

processing each network slice according to the priority from high to low, sequentially meeting the requirement of T-CONT with BE type of residual bandwidth scheduling in each network slice, and updating the best effort bandwidth residual value allocable by a PON port;

and allocating best-effort bandwidth according to the proportion of the weight for the network slices with the same priority.

Preferably, for each network slice indexed by i, all remaining bandwidth scheduling types χ within the network slice_ABBE's T-CONT^jBandwidth R of^j(t) is:

where j is the index of T-CONT, j ∈ { I^jI is the index of the network slice to which the T-CONT belongs, and takes values from 1 to N,

to be configured for T-CONT^jThe maximum bandwidth of the first channel and the second channel,

to be configured for T-CONT^jThe fixed bandwidth of the network,

for each T-CONT in the period T^jThe bandwidth requirement of (d);

if T-CONT^jThe bandwidth can be satisfied, then

And continuing to process the next T-CONT within the network slice, wherein,

the best effort bandwidth which can be allocated is left for the network slice i;

otherwise, the network is stoppedUpdating the bandwidth of the T-CONT in the network slice and continuously processing the next network slice until all the network slices are processed or the residual best-effort bandwidth S which is totally available at the PON port_BE(t) total depletion;

the above-mentioned

And configuring the bandwidth for guaranteeing.

Preferably, O L T converts the bandwidth allocated by each T-CONT in the T-th period into bandwidth allocation parameters, including the number AB of upstream bytes allocated in each frame and the service interval SI of the T-CONT, generates a bandwidth bitmap BWmap and sends the bandwidth bitmap BWmap to the ONU;

the higher the priority of the network slice is, the lower the value of SI is, and the value of SI is a multiple of 125 us; and AB^j＝R^j(t)*SI^jWhere j is the number of T-CONT, R^j(T) is the bandwidth allocated for the T-CONT in the T-th period.

In another aspect, an O L T applicable to the above method for dynamic bandwidth allocation of network slices is provided, including:

the configuration module is used for setting the service quality grade of each network slice and establishing the corresponding relation between the scheduling container T-CONT and the network slices; configuring the residual bandwidth scheduling type of the T-CONT as no residual bandwidth none, no guaranteed bandwidth NA or best effort bandwidth BE;

the first bandwidth allocation module is used for allocating the bandwidth requirement collected in the DBA period according to the last dynamic bandwidth of each T-CONT, allocating the bandwidth of the current DBA period to the network slice, and enabling the bandwidth allocated by each T-CONT to be not more than the sum of the fixed bandwidth and the guaranteed bandwidth of the T-CONT;

the second bandwidth allocation module is used for sequentially meeting the bandwidth requirement of the T-CONT with the residual bandwidth scheduling type of NA according to the service quality grade of each network slice when the PON port has unallocated bandwidth after the first bandwidth allocation module is allocated;

and the third bandwidth allocation module is used for sequentially meeting the bandwidth requirement of the T-CONT with the residual bandwidth scheduling type being BE according to the service quality grade of each network slice when the PON port has unallocated bandwidth after the second bandwidth allocation module is allocated.

The technical scheme has the following beneficial effects: assigning T-CONT to the network slices by setting service quality grades of different network slices, and preferentially ensuring the T-CONT in the high-priority slices to obtain residual bandwidth scheduling when calculating the residual bandwidth; the bandwidth is distributed in proportion by weight in the same priority, operators can provide differentiated quality guarantee services for different network slice users while fully sharing access network infrastructure by utilizing network slices, and particularly high-value network slice users can provide high-quality guarantee services.

Furthermore, according to the priority of the network slice, the bandwidth service interval in the DBA period is adjusted, and the forwarding time delay of the service in the high-priority slice is reduced.

Drawings

FIG. 1 is a flow chart of a method for dynamic bandwidth allocation of network slices according to an embodiment of the present invention;

fig. 2 is a schematic view of a multi-tenant application scenario based on a PON system network slice according to an embodiment of the present invention;

fig. 3 is a flowchart of a dynamic bandwidth allocation method for network slices according to another embodiment of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples.

As shown in fig. 1, an embodiment of a method for dynamic bandwidth allocation of a network slice is provided, which includes the steps of:

a1. and setting the service quality grade of each network slice, and establishing the corresponding relation between the T-CONT and the network slices.

Preferably, the service quality levels of the network slices are represented by priorities and weights, for example, the priorities include 8 levels of 0 to 7; in this embodiment, the greater the sequence number of the priority, the higher the service quality level of the corresponding network slice; in other embodiments, the smaller the sequence number of the priority, the higher the quality of service level of the corresponding network slice. The higher the weight of the network slice with the same priority, the higher the service quality level.

The method comprises the steps of configuring a DBA scheduling parameter vector of the T-CONT, wherein the DBA scheduling parameter vector comprises a fixed bandwidth, a guaranteed bandwidth, a maximum bandwidth and a residual bandwidth scheduling type, the residual bandwidth scheduling type comprises a non-allocated residual bandwidth none, a non-allocated non-guaranteed bandwidth NA (non-allocated), and a best-effort bandwidth BE (best-effort), the residual bandwidth scheduling type is one of { none, NA and BE }.

a2. And according to the bandwidth demand collected in the last DBA period of each T-CONT, allocating the bandwidth of the current DBA period to the network slice, and enabling the bandwidth allocated to each T-CONT not to be larger than the sum of the fixed bandwidth and the guaranteed bandwidth of the T-CONT. In addition, if the period is the first DBA period, the service bandwidth is not distributed to the network slice, and only the bandwidth request of the ONU is acquired.

The first round of bandwidth calculation is that if the bandwidth requirement of the T-CONT is smaller than the sum of the fixed bandwidth and the guaranteed bandwidth of the T-CONT, the bandwidth allocated to the T-CONT is the bandwidth required by the T-CONT, otherwise, the bandwidth allocated to the T-CONT is equal to the sum of the fixed bandwidth and the guaranteed bandwidth of the T-CONT.

a3. And if the PON port of the passive optical network has unallocated bandwidth, sequentially meeting the bandwidth requirement of the T-CONT with the residual bandwidth scheduling type of NA according to the service quality grade of each network slice.

Specifically, after the first round of bandwidth calculation is completed, the unallocated guaranteed bandwidth of the PON port is calculated, which is equal to the sum of the total bandwidth of the PON port minus the bandwidth allocated by the T-CONT first round of bandwidth calculation. And if the allocable bandwidth of the PON port is larger than 0, performing bandwidth calculation in a second round.

An embodiment of a second wheel bandwidth calculation method is provided, comprising: and processing each slice according to the sequence of the priority of the network slices from top to bottom, using the unallocated guaranteed bandwidth allocable by the PON port to satisfy all the T-CONT with the residual bandwidth scheduling type of NA in the slice, and updating the unallocated guaranteed bandwidth residual value of the PON port. The meaning of "satisfying" above is: the bandwidth value allocated to the T-CONT reaches the bandwidth requirement of the T-CONT, or reaches the maximum bandwidth limit of the T-CONT. And processing the network slices with low priority only after the T-CONT in the network slices with high priority are all satisfied. For the network slices with the same priority, the allocable non-guaranteed bandwidth is allocated according to the proportion of the weight. And if the allocable bandwidth of the PON port is exhausted, the bandwidth calculation of the second round is finished.

a4. And if the PON port still has unallocated bandwidth, sequentially meeting the bandwidth requirement of the T-CONT with the residual bandwidth scheduling type BE according to the service quality grade of each network slice.

Specifically, after the second round of bandwidth calculation is completed, the best effort bandwidth allocable for the PON port is calculated, which is equal to the sum of the total bandwidth of the PON port minus the bandwidths allocated in the first two rounds of T-CONT. And if the best-effort bandwidth allocable by the PON port is larger than 0, performing a third round of bandwidth calculation.

An embodiment of a third round bandwidth calculation method is provided, comprising: and processing each slice according to the sequence of the priority of the network slices from top to bottom, sequentially satisfying the T-CONT with the residual bandwidth scheduling type BE in each network slice by using the best-effort bandwidth allocable by the PON port, and simultaneously updating the best-effort bandwidth residual value allocable by the PON port. The meaning of "satisfy" in this example is: the bandwidth value allocated to the T-CONT reaches the bandwidth requirement of the T-CONT, or reaches the maximum bandwidth limit of the T-CONT. And processing the network slices with low priority only after the T-CONT in the network slices with high priority are all satisfied. For network slices with the same priority, the best-effort bandwidth which can be allocated is allocated according to the proportion of the weight. If the best effort bandwidth allocable by the PON port is exhausted, the third round of bandwidth calculation is finished.

After the step a4, the O L T calculates the number of upstream bytes (AB) and Service Intervals (SI) allocated to each T-CONT in each frame of the DBA scheduling period according to the priority of the network slice, the bandwidth allocated to each T-CONT, and the length of the DBA scheduling period, generates BWMap (bandwidth map) and sends the BWMap to the ONU, where the BWMap is a bandwidth bitmap issued by the O L T in the GPON standard and used for indicating the upstream data sending time and length of the ONU, the value of the SI is a multiple of 125us, and for a network slice, the higher the priority is, the smaller the value of the SI is, so as to reduce the forwarding delay of the network slice service, and the lower the priority of the network slice is, the value of the SI may be relatively larger, so as to not preferentially guarantee the delay of the network slice service.

The present invention further provides an O L T embodiment, which is applicable to the above dynamic bandwidth allocation method for network slices, in which the O L T embodiment includes a configuration module, a first bandwidth allocation module, a second bandwidth allocation module, and a third bandwidth allocation module.

The configuration module is used for setting the service quality grade of each network slice and establishing the corresponding relation between the scheduling container T-CONT and the network slices; and configuring the residual bandwidth scheduling type of the T-CONT as no residual bandwidth none, no guaranteed bandwidth NA or best effort bandwidth BE.

And the first bandwidth allocation module is used for allocating the bandwidth of the current DBA period to the network slice according to the bandwidth requirement collected by the last dynamic bandwidth allocation DBA period of each T-CONT, and enabling the bandwidth allocated by each T-CONT not to be larger than the sum of the fixed bandwidth and the guaranteed bandwidth of the T-CONT.

And the second bandwidth allocation module is used for sequentially meeting the bandwidth requirement of the T-CONT with the residual bandwidth scheduling type of NA according to the service quality grade of each network slice when the PON port has unallocated bandwidth after the first bandwidth allocation module is allocated.

And the third bandwidth allocation module is used for sequentially meeting the bandwidth requirement of the T-CONT with the residual bandwidth scheduling type being BE according to the service quality grade of each network slice when the PON port has unallocated bandwidth after the second bandwidth allocation module is allocated.

As shown in FIG. 2, an embodiment of a multi-tenant application scenario based on a PON system Network slice is provided, a PON access Network comprises a local O L T device, an ODN and a remote ONU device, and the O L T and the ONU are connected through the ODN₁And VNO₂Sharing O L T PON port and odn in physical access network through PON network slicing technique in this embodiment, virtual operators correspond to network slices one to one, and VNOs₁The network slice is high priority, and the corresponding network slice is high priority; VNO₂Is generic priority, the corresponding network slice is also generic priority, lower than the VNO₁Corresponding network slice priority. VNO₁Using network slice 1 to carry traffic, its subscribers include ONUs₁～ONU_m(ii) a Virtual operator VNO₂Using network slice 2 to carry traffic, its subscribers include ONUs_m+1～ONU_n. Two virtual network operators independently develop service operation, but all users share bandwidth resources of the PON port. In particular, VNO₁Serving high value users and therefore a limited quality of service guarantee can be obtained by the method in the above embodiment.

As shown in fig. 3, another embodiment of a method for dynamic bandwidth allocation for a network slice is provided, comprising the steps of:

s1, defining service quality grade for O L T network slices, indexing the network slices, wherein the range of index i is 1-N, N is the maximum number of network slices supported by a PON system, and defining a vector V for each network sliceⁱAnd is used to indicate the quality of service of the network slice.

Vⁱ＝(Pⁱ,wⁱ)

Wherein, PⁱRepresenting the priority, and the value from low to high is 0-7; w is aⁱRepresenting the weight of the network slice at the same priority.

S2, assigning T-CONT for each service flow and configuring each T-CONT^jDBA scheduling parameter vector D^j：

Wherein j is the index of T-CONT, the value range is 1-TCONT total number,

to be configured to the T-CONT^jA fixed bandwidth of;

to be configured to the T-CONT^jThe guaranteed bandwidth of (2);

to be configured to the T-CONT^jMaximum bandwidth of;

is the T-CONT^jThe value of the residual bandwidth scheduling type is one of { none, NA and BE }; none indicates that the remaining bandwidth is not allocated, NA indicates that the non-guaranteed bandwidth is allocated, and BE indicates that the best-effort bandwidth is allocated; i is^jIs the T-CONT^jAnd the index of the belonged network slice takes a value of 1-N.

For each T-CONT^jThe above parameters need to satisfy the following constraints:

if x_ABWhen being NA, then

If x_ABBE, then

Wherein the content of the first and second substances,

is T-CONT^jThe fixed bandwidth configuration of (a) is,

is T-CONT^jThe configuration of the guaranteed bandwidth of (a),

is T-CONT^jMaximum bandwidth configuration. The meaning of the above constraints is: for each T-CONT attributed to a network slice i^jWhich is

Of all T-CONT

And

the sum should not be greater than the total bandwidth (C) of the PON port.

And S3, periodically executing DBA dynamic bandwidth allocation. A DBA period is typically a multiple of the duration (125us) of a GPON frame. In the present embodiment, the DBA period is 1ms (8 frames).

S4, performing first-wheel bandwidth distribution, and performing each T-CONT in O L T reading period T^jBandwidth requirement of

Get each T-CONT^jAllocated bandwidth of

S5, calculating the distributable non-guaranteed bandwidth S of the PON port in the period t_NA(t)：

And S6, performing second-wheel bandwidth distribution. Priority P of quality of service according to network sliceⁱSequentially processing all network slices from high to low, and allocating the available bandwidth of the PON port to all residual bandwidth scheduling types x_ABNA T-CONT.

In the processing of each priority, firstly, the assignable non-guaranteed bandwidth of each network slice i in the priority is determined

If the network slice i is the only one network slice in the current priority level, then

If there are multiple network slices within the current priority, S is determined according to the weights of the network slices_NA(t) obtaining each network slice

For each network slice i (cycle 1), all remaining bandwidth scheduling types x within that network slice_ABT-CONT of NA^j(j∈{S^jI }) (cycle 2) the bandwidth R allocated during period t^j(t) is:

wherein the content of the first and second substances,

for each T-CONT in the period T^jI.e., the actual load (L oad).

If T-CONT^jThe bandwidth can be satisfied, then slice the remaining non-guaranteed bandwidth of the network i

Subtract the value assigned to T-CONT^jPart (A) to

Is updated to

Wherein the content of the first and second substances,

for assigning T-CONT in step S4^jThen continues processing the next T-CONT within the network slice (continue loop 2); otherwise, the bandwidth of the T-CONT in the network slice is stopped (the loop 2 is skipped), and the next network slice is updated and continuously processed (the loop 1 is continued) until all slices are processed or the residual bandwidth S which is not guaranteed and is totally available in the PON system is processed_NA(t) total depletion.

S7, calculating the best effort bandwidth S which can be distributed by the PON port in the period t_BE(t)：

And S8, carrying out third round of bandwidth allocation. Priority P of quality of service according to network sliceⁱSequentially processing all network slices from high to low, and allocating the best-effort bandwidth allocable by the PON port to all attributes x_ABT-CONT of BE. In the processing of each priority, the best-effort bandwidth allocable for all network slices in the priority is first determined

If network slice i is the only one within the current priority, then

If there are multiple network slices within the current priority, S is determined according to the weights of the network slices_BE(t) obtaining each network slice

For each network slice i (cycle 3), all remaining bandwidth scheduling types x within that network slice_ABBE's T-CONT^j(j∈{I^jI } (cycle 4) bandwidth R allocated during period t^j(t) is:

if T-CONT^jThe bandwidth can be satisfied, then the network slice i is left with the best-effort bandwidth allocable

Subtract the value assigned to T-CONT^jPart (A) to

Is updated to

Wherein

For assigning T-CONT in step S4^jThen continues processing the next T-CONT within the network slice (continue loop 3); otherwise, stopping the bandwidth updating of the T-CONT in the network slice (jumping out of the loop 3), and continuing to process the next network slice (continuing to loop 4) until all the network slices are processed or S_BE(t) total depletion.

Preferably, on the basis of the above steps, the following steps are further provided:

s9, enabling each T-CONT to be connected^jR of (A) to (B)^j(T) converting into bandwidth allocation parameters in the T-th period, including the number of bytes Allocated (AB) in each GPON frame and the T-CONT^jService Interval (SI). Specifically, for each network slice i, T-CONT within each network slice i (cycle 5)^j(cycle 6), T-CONT^jAssociated network slice priority pⁱCalculating T-CONT^jThe number of bytes (AB) allocated in each service interval, according to the T-CONT^jAnd the Service Interval (SI) and AB of the DBA period.

In this embodiment, in a DBA period of 8 frames, the value of SI may be 1 frame to 8 frames (125us to 1ms) according to T-CONT^jAssociated network slice priority pⁱTo be determined. The SI value of the network slice with the highest priority (value of 7) is 125us, the lower the priority, the larger the SI value, and the SI value of the network slice with the lowest priority (value of 0) is 1 ms. The AB value is then calculated according to the following equation:

AB^j＝R^j(t)*SI^j

s10.O L T generates BWMap according to the bandwidth distribution condition in each GPON frame, and sends the BWMap to ONU, S9 and S10 can adjust the bandwidth service interval in the DBA period according to the priority of the network slice, and reduce the forwarding delay of the service in the high-priority slice.

S11, in the period, collecting the bandwidth requirement of each T-CONT in the next period, and turning to S3 to start the DBA process in the next period.

The present invention is not limited to the above-described embodiments, and it will be apparent to those skilled in the art that various modifications and improvements can be made without departing from the principle of the present invention, and such modifications and improvements are also considered to be within the scope of the present invention.

Claims (11)

1. A method for dynamic bandwidth allocation of network slices, comprising the steps of:

a1. setting the service quality grade of each network slice, and establishing a corresponding relation between a scheduling container T-CONT and the network slices; configuring the residual bandwidth scheduling type of the T-CONT as no residual bandwidth none, no guaranteed bandwidth NA or best effort bandwidth BE;

a2. according to the bandwidth demand collected in the last dynamic bandwidth allocation DBA period of each T-CONT, the bandwidth of the current DBA period is allocated to the network slice, and the bandwidth allocated to each T-CONT is not more than the sum of the fixed bandwidth and the guaranteed bandwidth of the T-CONT;

a3. if the PON port of the passive optical network has unallocated bandwidth, sequentially meeting the bandwidth requirement of the T-CONT with the residual bandwidth scheduling type of NA according to the service quality grade of each network slice;

a4. and if the PON port still has unallocated bandwidth, sequentially meeting the bandwidth requirement of the T-CONT with the residual bandwidth scheduling type BE according to the service quality grade of each network slice.

2. The method for dynamic bandwidth allocation of a network slice of claim 1, wherein: in the step a1, configuring a DBA scheduling parameter vector for the T-CONT, where the DBA scheduling parameter vector includes a fixed bandwidth, a guaranteed bandwidth, a maximum bandwidth, and a remaining bandwidth scheduling type;

each network slice is identified by an index, the DBA scheduling parameter vector further comprises a parameter which represents the index of the network slice to which the T-CONT belongs, and each T-CONT uniquely belongs to one network slice.

3. The method for dynamic bandwidth allocation of a network slice of claim 2, wherein: for each T-CONT belonging to one slice, the sum of the fixed bandwidth configuration and the guaranteed bandwidth configuration is not more than the maximum bandwidth configuration; and the sum of the fixed bandwidth configuration and the guaranteed bandwidth configuration of all the T-CONT is not more than the total bandwidth of the PON port.

4. The method for dynamic bandwidth allocation of a network slice according to claim 3, wherein said step a2 comprises:

reading the bandwidth requirements of all T-CONT interfaces under the corresponding PON port collected by optical line terminal O L T in the previous DBA cycle:

if the bandwidth requirement is less than the sum of the fixed bandwidth and the guaranteed bandwidth, the bandwidth allocated to the T-CONT is the bandwidth required by the T-CONT; otherwise, the bandwidth allocated to the T-CONT is equal to the sum of the fixed bandwidth and the guaranteed bandwidth of the T-CONT.

5. The method for dynamic bandwidth allocation of a network slice of claim 1, wherein: the service quality grade of the network slice is represented by priority and weight, and the higher the priority is, the higher the service quality grade of the corresponding network slice is; the higher the weight of the network slice with the same priority, the higher the service quality level.

6. The method of dynamic bandwidth allocation for network slices of claim 5, wherein: the unallocated bandwidth in the step a3 is an unallocated guaranteed bandwidth allocable to the PON port, and is the sum of the bandwidths allocated by all the T-CONT according to the step a2 subtracted from the total bandwidth of the PON port;

processing each network slice according to the priority from high to low, sequentially meeting the requirement of T-CONT with the residual bandwidth scheduling type of NA in each network slice, and updating the residual value of the bandwidth which can be distributed by the PON port and is not guaranteed;

and allocating the network slices with the same priority according to the weight proportion without ensuring the bandwidth.

7. The method of claim 6, wherein for each network slice with index i, all remaining bandwidth scheduling types x in the network slice_ABT-CONT of NA^jBandwidth R allocated in period t^j(t) is:

where j is the index of T-CONT, j ∈ { I^j＝i}，I^jThe index of the network slice to which the T-CONT belongs takes values of 1-N,

to configureFor T-CONT^jThe maximum bandwidth of the first channel and the second channel,

to be configured for T-CONT^jThe fixed bandwidth of the network,

for each T-CONT in the period T^jThe bandwidth requirement of (d);

if T-CONT^jThe bandwidth can be satisfied, then

Continuing to process the next T-CONT in the network slice, wherein

Allocating an unqualified bandwidth for the network slice i;

otherwise, stopping updating the bandwidth of the T-CONT in the network slice and continuing to process the next network slice until all network slices are processed or the residual bandwidth S which is not guaranteed and is totally available at the PON port_NA(t) total depletion;

the above-mentioned

And configuring the bandwidth for guaranteeing.

8. The method of dynamic bandwidth allocation for network slices of claim 5, wherein: the unallocated bandwidth in the step a4 is the best-effort bandwidth allocable by the PON port, and is the sum of the bandwidths allocated by all the T-CONT according to the step a2 and the step a3 and subtracted from the total bandwidth of the PON port;

processing each network slice according to the priority from high to low, sequentially meeting the requirement of T-CONT with BE type of residual bandwidth scheduling in each network slice, and updating the best effort bandwidth residual value allocable by a PON port;

and allocating best-effort bandwidth according to the proportion of the weight for the network slices with the same priority.

9. The method for dynamic bandwidth allocation of a network slice of claim 8, wherein: for each network slice indexed by i, all remaining bandwidth scheduling types x within that network slice_ABBE's T-CONT^jBandwidth R of^j(t) is:

where j is the index of T-CONT, j ∈ { I^jI is the index of the network slice to which the T-CONT belongs, and takes values from 1 to N,

to be configured for T-CONT^jThe maximum bandwidth of the first channel and the second channel,

to be configured for T-CONT^jThe fixed bandwidth of the network,

for each T-CONT in the period T^jThe bandwidth requirement of (d);

if T-CONT^jThe bandwidth can be satisfied, then

And continuing to process the next T-CONT within the network slice, wherein,

the best effort bandwidth which can be allocated is left for the network slice i;

otherwise, stopping the bandwidth updating of the T-CONT in the network slice and continuing to process the next network slice until all network slices are processed or the residual best effort available for the PON port is totally realizedBut is the bandwidth S_BE(t) total depletion;

the above-mentioned

And configuring the bandwidth for guaranteeing.

10. The method for dynamically allocating bandwidth of network slice according to claim 5, wherein O L T converts the bandwidth allocated in T-th period for each T-CONT into bandwidth allocation parameters, including the number of upstream bytes AB allocated in each frame and the service interval SI of the T-CONT, generates a bandwidth bitmap BWmap and sends the bandwidth bitmap BWmap to the ONU;

the higher the priority of the network slice is, the lower the value of SI is, and the value of SI is a multiple of 125 us; and AB^j＝R^j(t)*SI^jWhere j is the number of T-CONT, R^j(T) is the bandwidth allocated for the T-CONT in the T-th period.

11. O L T adapted for use in the method for dynamic bandwidth allocation for network slices according to any of claims 1-10, comprising:

the configuration module is used for setting the service quality grade of each network slice and establishing the corresponding relation between the scheduling container T-CONT and the network slices; configuring the residual bandwidth scheduling type of the T-CONT as no residual bandwidth none, no guaranteed bandwidth NA or best effort bandwidth BE;

the first bandwidth allocation module is used for allocating the bandwidth requirement collected in the DBA period according to the last dynamic bandwidth of each T-CONT, allocating the bandwidth of the current DBA period to the network slice, and enabling the bandwidth allocated by each T-CONT to be not more than the sum of the fixed bandwidth and the guaranteed bandwidth of the T-CONT;

the second bandwidth allocation module is used for sequentially meeting the bandwidth requirement of the T-CONT with the residual bandwidth scheduling type of NA according to the service quality grade of each network slice when the PON port has unallocated bandwidth after the first bandwidth allocation module is allocated;

and the third bandwidth allocation module is used for sequentially meeting the bandwidth requirement of the T-CONT with the residual bandwidth scheduling type being BE according to the service quality grade of each network slice when the PON port has unallocated bandwidth after the second bandwidth allocation module is allocated.

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