WO2020128246A1

WO2020128246A1 - Method for determining a data transmission path, and corresponding device

Info

Publication number: WO2020128246A1
Application number: PCT/FR2019/053040
Authority: WO
Inventors: Joël PENHOAT; Alassane SAMBA; William DIEGO MAZA; Jean-Marc Kelif
Original assignee: Orange
Priority date: 2018-12-18
Filing date: 2019-12-12
Publication date: 2020-06-25
Also published as: FR3090262B1; FR3090262A1

Abstract

The invention concerns a method for determining a path from a plurality of paths available for a data transmission between a terminal (90) and an entity of a service provider (94), the paths of the plurality being distinguished from each other by their radio access technology, the determination method being implemented by the terminal and comprising, for each of the paths, the following steps: - A step (100) of estimating a first quality level criterion (C1) for each of the paths, depending on at least one predefined parameter necessary for the service; - A step (110) of estimating a second energy consumption criterion (C2) for each of the paths, depending on the type of radio access technology; - A step (120) of selecting the path (1) for the data transmission, depending on a combination of the estimated quality levels and the estimated energy consumptions.

Description

Title: Method for determining a data transmission path, and corresponding device.

1. Field of the invention

The field of the invention is that of energy saving, in particular in the field of data transmission over a network comprising at least one segment of transmission by radio waves.

The present invention finds particular applications in the field of telecommunications.

2. Prior art

Nowadays, data transmission, in particular by radio waves is omnipresent, whether for the exchange of information around the world, or for the daily use of terminals such as mobile phones, tablets, or computers.

Such communication devices exchange quasi-continuously, in a conventional manner, data with a service provider, such as an internet access provider, via different types of interface (Wifi, 3G, 4G , ...).

Due in particular to the proliferation in recent years of communications between terminals and access providers as well as the increase in the size of data sent and communication rates, the problem of terminal energy consumption has been put in light. The terminals having a portable battery having a limited dimension, which is therefore discharged relatively quickly, other axes have been developed to respond to this problem of energy consumption.

Thus, a solution is known which consists of a method for selecting a radio network based on the time required to transfer between the network to which the terminal is connected and the target network to which the terminal could connect. This method removes from the list of potential networks the networks with a long transfer time, because it is all the more energy-consuming the longer the transfer time. However, such a method does not address the energy footprint of a service according to the level of quality of service required for its end-to-end transmission.

Another known method consists in putting the most energy-consuming radio interfaces to sleep so as to completely reduce the energy consumption of a terminal.

However, such a method also does not address the energy footprint of a service based on the level of service quality required for its end-to-end transmission.

Yet another known method is to measure the energy consumed by the applications of a smartphone. This method is only applicable on the terminal side and not on the operator side since the latter has no information on the energy consumption measurements made by the terminal.

However, and as with the other methods, such a method also does not address the energy footprint of a service according to the level of quality of service required for its end-to-end transmission.

One of the aims of the invention is to remedy these drawbacks of the state of the art.

3. Statement of the invention

The invention improves the situation using a method for determining a path among a plurality of paths available for data transmission between a terminal and an entity of a service provider, the paths of the plurality being distinguished from each other by their radio access technology, the determination method being implemented by the terminal and comprising, for each of the paths, the following steps:

A step of estimating a first quality level criterion of each of the paths, as a function of at least one predefined parameter necessary for the service;

A step of estimating a second energy consumption criterion for each of the paths, depending on the type of radio access technology; A step of selecting the path for the transmission of data, according to a combination of the estimated quality levels and the estimated energy consumption.

Thus, the invention proposes a new and inventive approach making it possible to identify a data transmission path between a first device and a second device which, for a given service, will make it possible to consume less energy, or even the minimum of energy. .

The path determined by the determination method according to the invention makes it possible to determine the path which consumes the least possible energy, as a function of a level of quality necessary for a service requested by a user.

According to a particular aspect of at least one embodiment of the invention, the step of estimating the first quality level criterion for each of said paths depends on a previous estimate, and in that the step of estimate of the second energy consumption criterion of each of said paths depends on a previous estimate.

As a result, this allows precise estimates to be made since they take into account previous estimates for each of these two criteria. These previous estimates can for example be based on a supervised learning model, improved as it is used over time, and to which the proposed method can contribute.

According to another aspect of at least one embodiment, the step of estimating the first criterion comprises a step of estimating the quality level of each of the paths on a first segment between said terminal and an access point, said step of estimating the second criterion includes a step of estimating said energy consumption of each of the paths on said first segment, and said step of selecting the path for data transmission, as a function of a combination of the quality levels estimated and estimated energy consumption, includes a step of selecting the path on said first segment.

According to yet another aspect of at least one embodiment of the invention, said step of estimating the first criterion comprises a step of estimating the level of quality of each of the paths on a second segment between said access point and a collection equipment, said step of estimating the second criterion comprises a step of estimating said energy consumption of each of the paths on said second segment, and said step of selecting the path for the transmission of data, as a function of a combination of the estimated quality levels and the estimated energy consumption, comprises a step of selecting the path on said second segment.

According to a characteristic of at least one embodiment of the invention, said type of radio access technology belongs to the group comprising:

- Wireless ;

- Edge;

- 2G;

- 3G;

4G, and

- 5G.

According to a variant of at least one embodiment of the invention, said step of estimating the first criterion comprises a step of estimating the quality level of each of the paths on a third segment between said collection equipment and a core network, said step of estimating the second criterion comprises a step of estimating said energy consumption of each of the paths on said third segment, and said step of selecting the path for data transmission, as a function of a combination of estimated quality levels and estimated energy consumption, includes a step of selecting the path on said third segment.

According to another characteristic of at least one embodiment of the invention, said step of estimating the first criterion comprises a step of estimating the quality level of each of the paths on a fourth segment between said core network and said entity of said service provider, said step of estimating the second criterion comprises a step of estimating said energy consumption of each of the paths on said fourth segment, and said step of selecting the path for the transmission of data, as a function of a combination of the estimated quality levels and the estimated energy consumption, comprises a step of selecting the path on said fourth segment.

In this case, only one data transmission path may be available on the third and / or fourth segment.

According to one aspect of at least one embodiment of the invention, the at least one predefined parameter belongs to the group comprising:

bandwidth ;

the flow ;

latency;

- jitter;

the packet loss rate.

According to another aspect of at least one embodiment of the invention, said service belongs to the group comprising:

voice call;

the audio call;

video streaming;

web browsing;

downloading files;

sending a message.

The invention also relates to a computer program product comprising program code instructions for executing the steps of the method for determining a path among a plurality of paths available for data transmission between a terminal and a data entity. a service provider (94) according to any of the above embodiments.

The invention further relates to a non-transient recording medium readable by a computer on which a program comprising instructions for the implementation of a method according to any one of the abovementioned embodiments is recorded.

The invention finally relates to a device configured for the implementation of the method for determining a path among a plurality of paths available for data transmission between a terminal and an entity of a service provider, the device comprising:

- a receiver of a request for determining a path;

- a memory memorizing at least one predefined parameter necessary for the service;

- a processing unit configured for:

estimating a first quality level criterion of each of the paths, as a function of said at least one predefined parameter necessary for the service;

estimate a second energy consumption criterion for each path, depending on the type of radio access technology;

select a path for data transmission, based on a combination of the estimated quality levels and the estimated energy consumption.

4. List of figures

Other characteristics and advantages of the invention will appear more clearly on reading the following description of a particular embodiment, given by way of simple illustrative and nonlimiting example, and of the appended drawings, among which:

[Fig 1] is a diagram showing a determination method according to a first embodiment of the invention;

[Fig 2] is a diagram showing a communication network provided with a plurality of paths, in which a method according to the first embodiment of the invention is applicable;

[Fig 3] is a diagram presenting the supervised learning sub-method according to an embodiment of the invention, and

[Fig 4] illustrates a device configured to implement the method of determining a path according to a particular embodiment of the invention.

5. Description of an embodiment A first embodiment of the invention is illustrated below, treated as a simple illustrative example, and not limiting, with the support of FIGS. 1 to 3.

The invention proposes to provide a method P making it possible to identify a data transmission path between a first device and a second device which, for a given service, will make it possible to consume less energy, or even the minimum of energy.

This service can, depending on the wishes of a user, be a voice call, video streaming, internet browsing, file downloading, ...

Depending on the service requested by the user, the needs will not be the same, for example in terms of bandwidth or latency, which will influence the determination of the transmission path.

This data transmission path is to be determined from among a plurality of paths available for data transmission between a terminal 90 and an entity of a service provider 94.

The data transmission paths can in particular be distinguished from each other, as illustrated in FIG. 2, by their radio access technology.

Depending on the embodiments, the radio access technology can belong to the group comprising:

- Wireless ;

- Edge;

- 2G;

- 3G;

4G, and

- 5G.

Therefore, the data transmission paths can be composed of several path segments, using Wifi waves, or radio waves of other types.

The method P of determining a path among a plurality of paths available for data transmission between the terminal 90 and the entity of a provider of a service 94, is implemented by the terminal and comprises, for each of the paths, the following steps:

A step 100 of estimating a first criterion C1 of the quality level of each of the paths, as a function of at least one predefined parameter necessary for the service;

A step 110 for estimating a second criterion C2 of an energy consumption of each of the paths, as a function of the type of radio access technology;

A step 120 of selecting path 1 for data transmission, as a function of a combination of the quality levels and the estimated energy consumption.

By quality level is meant the performance level of each of the paths of the plurality of paths to be estimated. In other words, the first criterion C1 of estimated quality level corresponds to the level of end-to-end quality of service achievable on the determined path.

This level of quality notably refers to at least one predefined parameter necessary for the service.

As described above, this service can, for example, according to the wishes of a user, be an audio call, a voice call, video streaming, internet browsing, file downloads.

Thus, for each service, one or more predefined parameters can be prioritized so that the user has the best possible service.

According to the embodiments, and the service, the predefined parameter belongs to the group comprising:

bandwidth ;

the flow ;

latency;

- jitter;

the packet loss rate. For example, video streaming is a service that will require more bandwidth than a voice call. In contrast, a voice call is a service requiring less bandwidth but low latency and a low rate of packet loss.

As regards the step of estimating the second criterion C2 of energy consumption of each of the paths, it depends on the type of radio access technology. For example, 3G technology consumes less energy than 4G technology but more than Wifi technology.

Step 120 of selecting path 1 for data transmission, as a function of a combination of the estimated quality levels and the estimated energy consumption, consists in selecting the path for data transmission which presents the best possible compromise between a first estimated criterion C1, which is necessary for a user for a given service, and a second estimated criterion C2 which makes it possible to select a path consuming the least possible energy.

More particularly, this step 120 of selecting the path comprises, in this embodiment, a sub-step of identifying the paths among the plurality of paths on which the quality level is greater than or equal to a given threshold.

In this embodiment, the path selection step 120 further comprises a sub-step for classifying, among the paths identified as having a level of quality greater than or equal to a given threshold, paths consuming the least energy .

Thus, the path determined by the determination method, in this embodiment, determines the path which consumes the least energy possible, as a function of a level of quality necessary for a service requested by a user.

In this embodiment, and as illustrated in FIG. 2, the data transmission path, to be determined from among a plurality of paths available for data transmission between a terminal 90 and an entity of a service provider 94, is segmented . In other words, the data transmission path can comprise a plurality of segments, or portions of path, linked together, for example by network equipment.

In the illustrated embodiment, in particular in FIG. 2, the data transmission path 1 has 4 segments.

The first segment SI is bounded by the terminal 90 and an access point 91. The second segment S2 is bounded by the access point 91 and a collection equipment 92. As for the third segment S3, it is bounded by the collection equipment 92 and a core network 93. Finally, the fourth segment S4 is bounded by the core network 93 and the service provider 94.

Thus, in this embodiment, the method of determining a path will carry out a determination “step by step”, that is to say segment by segment, and not from end-to-end in one time.

Such an approach makes it possible to optimize the level of quality and energy consumption over the entire path by determining, step by step, the best possible path for data transmission.

Thus, in the determination method according to the embodiment presented in FIG. 1:

the step 100 for estimating the first criterion C1 comprises a step 101 for estimating the quality level of each of the paths on the first segment SI between the terminal 90 and the access point 91, the step 110 for estimating of the second criterion C2 comprises a step 111 of estimating the energy consumption of each of the paths on the first segment SI,

and the step 120 for selecting path 1 for the transmission of data, as a function of a combination of the estimated quality levels and the estimated energy consumption, comprises a step 121 for selecting the path on the first segment SI.

As for the first segment SI, in the method according to the embodiment illustrated in FIG. 1: the step 100 for estimating the first criterion C1 comprises a step 102 for estimating the quality level of each of the paths on the second segment S2 between the access point 91 and the collection equipment 92,

the step 110 for estimating the second criterion C2 comprises a step 112 for estimating the energy consumption of each of the paths on the second segment S2,

and the step 120 of selecting path 1 for the transmission of data, as a function of a combination of the estimated quality levels and the estimated energy consumption, comprises a step 122 of selecting the path on the second segment S2.

It should be noted that, on the first segment SI, the estimation of the quality of service depends on the elements having an effect on the capacities and the performance of the terminal according to the interface.

Similarly, on the second segment S2, the estimation of the quality of service depends on the elements having an effect on the capacities and the performance of the access network according to the interface.

In this embodiment, only one data transmission path is available on the third S3 and fourth S4 segments.

In summary, in the embodiment illustrated in FIG. 1, the method comprises the following steps:

step 100 of estimating the first criterion C1 which includes step 101 of estimating the quality level of each of the paths on the first segment SI between the terminal 90 and the access point 91 then step 102 d estimation of the quality level of each of the paths on the second segment S2 between the access point 91 and the collection equipment 92,

step 110 for estimating the second criterion C2 which includes step 111 for estimating the energy consumption of each of the paths on the first segment SI then step 112 for estimating the energy consumption of each path on the second segment S2,

and the step 120 of selecting path 1 for the transmission of data, as a function of a combination of the estimated quality levels and the estimated energy consumption, which comprises the step 121 of selecting the path on the first segment SI then l step 122 of path selection on the second segment S2.

These two selected segments are added to the third S3 and fourth S4 segments (for which only one transmission path is available) to form the data transmission path.

However, one could provide embodiments in which, on the third segment S3, several paths are available.

In this case, and for the third segment S3:

the step 100 for estimating the first criterion C1 comprises a step for estimating the quality level of each of the paths on the third segment S3 between the collection equipment 92 and the core of the network 93,

the step 110 for estimating the second criterion C2 comprises a step for estimating the energy consumption of each of the paths on the third segment S3,

and the step 120 of selecting path 1 for the transmission of data, as a function of a combination of the estimated quality levels and the estimated energy consumption, comprises a step of selecting the path on the third segment 3.

Furthermore, one could also provide embodiments in which, on the fourth segment S4, several paths are available.

In this case, and for the fourth segment S4:

the step 100 for estimating the first criterion C1 comprises a step for estimating the quality level of each of the paths on the fourth segment S4 between the core of the network 93 and the service provider 94,

the step 110 for estimating the second criterion C2 comprises a step for estimating the energy consumption of each of the paths on the fourth segment S4,

and the step 120 of selecting path 1 for the transmission of data, as a function of a combination of the estimated quality levels and the estimated energy consumption, comprises a step of selecting the path on the fourth segment S4.

It should be noted that for the estimation step of the first criterion C1, the quality level being the overall performance level of each of the paths of the plurality of paths to be estimated, step 100 will be influenced only by step 101 for estimating the quality level of each of the paths on the first segment S1 and by step 102 for estimating the quality level of each of the paths on the second segment S2.

It should also be noted that the first criterion C1 will be invariable on the third segment S3 and the fourth segment S4.

In the embodiment where only one data transmission path is available on the third segment S3 and the fourth segment S4, the end-to-end quality level will be equal to the minimum between the quality level on the first segment SI depending on the type of radio access technology, and the quality level on the second segment S2 according to the type of radio access technology.

In this case, by noting RAT the radio access technology, the quality level on a given path, denoted Q (RAT), is defined as follows:

Q (RAT) = / ((S1 (), S2 ()), (S3, S4))

In this case the function f ((x, y), (z, t)) determines the minimum between the level of quality on the first segment SI according to the type of radio access technology, and the level of quality on the second segment S2 depending on the type of radio access technology.

Regarding the step of estimating the criterion C2, and as for the step of estimating the first criterion C1, it will be invariable on the third segment S3 and on the fourth segment S4. The end-to-end energy consumption will therefore be equal to the energy consumption on the first segment SI according to the type of radio access technology, added to the energy consumption on the second segment S2 according to the type of technology radio access, to which is added an invariable energy consumption on the third and fourth segments.

In this case, by noting RAT the radio access technology, the energy consumption, denoted E (RAT), necessary for the transmission of the end-to-end service, is defined as follows:

E (RAT) = (E1 (RAT) + E2 (RAT)) + (£ 3 + £ 4)

In this case, the energy E (RAT) is equal to the sum of the integral of the powers P (S1) and P (S2) to be supplied respectively on the segment SI and on the segment S2, plus a constant:

E (RAT) = J £ (Sl) dt + J £ (S2) dt + Constant According to an alternative of the invention, and assuming that on the third segment S3 and on the fourth segment S4 several paths are available, the function f ((x, y), (z, t)) determines the minimum between the quality level on the first segment SI, the quality level on the second segment S2, the quality level on the third segment S3, the level of quality in the fourth segment S4.

In this case, and in the hypothesis or on the third segment S3 and the fourth segment S4 several paths are available, the energy E (RAT) is equal to the sum of the integral of the powers P (S1), P ( S2), P (S3), P (S4) to be supplied respectively on the SI segment, on the S2 segment, on the S3 segment, and on the S4 segment:

According to a variant of the embodiment of the determination method illustrated in FIG. 1, the step of estimating the first quality level criterion C1 for the plurality of paths of each of the segments may depend on a previous estimate. Likewise, the step of estimating the second criterion C2 of energy consumption of the plurality of paths of said segments may depend on a previous estimate. In other words the stages of estimation of the first criterion Cl and of the second criterion C2 can be performed with the help of a supervised learning sub-method as shown in FIG. 3.

As illustrated in FIG. 3, the supervised learning sub-method 200 comprises a step 201 for collecting data, a step 202 for analyzing data, and a step 203 for building a model M.

In this embodiment, and during the course of the method P for determining a data transmission path 1, as illustrated in FIG. 2, the estimates of the first criterion C1 and of the second criterion C2 are collected by means of l step 201 of data collection.

This data can for example be stored in a database so as to collect a large amount of data in order to establish an M model which is as precise as possible.

The origin of this data can be diverse and can include equipment and software for management, monitoring and supervision of terminals (90) and access points (91).

Subsequently, the data collected are analyzed during step 202 of data analysis, for example to make them more reliable and to give them a format suitable for subsequent processing.

This data analysis makes it possible to generate a model M, or to update an already existing model so as to refine it, during step 203 of construction of the model M.

The updating can be carried out continuously, each iteration of the determination process giving rise to a collection of data, then an analysis with a view to generating a new model or updating an existing model.

This model M is then used in the method for determining P of a data transmission path 1 during the steps of estimating the first and second criteria. The model M can be in the form of a function which takes as input new data making it possible to estimate the criteria C1 and C2 and returns as output an estimate of said criteria C1 and C2. It should be noted that, according to the embodiments, a first model can be created during a calibration phase, the learning sub-process making it possible to update it in order to make it more precise as and when .

A device 9 configured for implementing the method P, presented above, for determining a path from among a plurality of paths available for data transmission is presented below, using FIG. 4 between terminal 90 and the service provider entity 94.

Such a device notably comprises a receiver COM of a request for determining a path, and a memory MEM memorizing at least one predefined parameter necessary for the service.

The device further comprises a processing unit UT configured to: estimate a first quality level criterion of each of the paths, as a function of said at least one predefined parameter necessary for the service;

The processing unit UT of the device is equipped with a processor PROC and is controlled by the computer program PG also stored in the memory MEM.

This computer program PG includes program code instructions for executing the steps of the method for determining a path among a plurality of paths available for data transmission between the terminal 90 and the entity of a supplier. of a service 94, when the program is executed by the processor PROC.

It should be noted that, in a variant, the memory may also include a computer program which includes program code instructions for the execution of the steps of the supervised learning sub-method as represented in FIG. 3. In in this case, the memory MEM also makes it possible to store the data of the previous estimates for the estimation of the first and second criteria.

Claims

1. Method (P) for determining a path among a plurality of paths available for data transmission between a terminal (90) and an entity of a service provider (94), the paths of the plurality being distinguished between them by their radio access technology, the determination method being implemented by the terminal and comprising, for each of the paths, the following steps:

A step (100) of estimating a first criterion (C1) of the quality level of each of the paths, as a function of at least one predefined parameter necessary for the service;

A step (110) of estimating a second criterion (C2) of energy consumption of each of the paths, as a function of the type of radio access technology;

A step (120) of selecting the path (1) for the transmission of data, according to a combination of the estimated quality levels and the estimated energy consumption.

2. Method according to claim 1, characterized in that the step of estimating the first criterion (Cl) of quality level for each of said paths (1) depends on a previous estimate, and in that step d estimate of the second criterion (C2) of energy consumption of each of said paths depends on a previous estimate.

3. Method according to one of claims 1 or 2, characterized in that: said step (100) of estimation of the first criterion (C1) comprises a step (101) of estimation of the quality level of each of the paths on a first segment (SI) between said terminal (90) and an access point (91), said step (110) of estimating the second criterion (C2) comprises a step (111) of estimating said energy consumption of each of the paths on said first segment (SI), and said step (120) of selecting the path (1) for the transmission of data, according to a combination of estimated quality levels and estimated energy consumption, comprises a step (121) of selecting the path on said first segment (SI).

Method according to claim 3, characterized in that: said step (100) of estimating the first criterion (C1) comprises a step (102) of estimating the quality level of each of the paths on a second segment (S2) between said access point (91) and a collection equipment (92), said step (110) of estimating the second criterion (C2) comprises a step (112) of estimating said energy consumption of each of the paths on said second segment (S2), and said step (120) of selecting the path (1) for data transmission, as a function of a combination of the estimated quality levels and the estimated energy consumption, comprises a step (122) of selecting of the path on said second segment (S2).

Method according to one of claims 1 to 4, characterized in that said type of radio access technology belongs to the group comprising:

Wireless ;

Edge;

2G;

3G;

4G;

5G.

Method according to claim 4, characterized in that: said step (100) of estimating the first criterion (C1) comprises a step of estimating the quality level of each of the paths on a third segment (S3) between said equipment for collection (92) and a core network (93), said step (110) of estimating the second criterion (C2) comprises a step of estimating said energy consumption of each of the paths on said third segment (S3), and said step (120) of selecting the path (1) for the transmission of data, according to a combination estimated quality levels and estimated energy consumption, includes a step of selecting the path on said third segment (S3).

7. Method according to claim 6, characterized in that: said step (100) of estimating the first criterion (C1) comprises a step of estimating the quality level of each of the paths on a fourth segment (S4) between said core network (93) and said entity of said service provider (94), said step (110) of estimating the second criterion (C2) comprises a step of estimating said energy consumption of each of the paths on said fourth segment ( S4), and said step (120) of selecting the path (1) for the transmission of data, according to a combination of the estimated quality levels and the estimated energy consumption, comprises a step of selecting the path on said fourth segment (S4).

8. Method according to one of claims 6 or 7, characterized in that a single data transmission path is available on the third (S3) and / or fourth (S4) segments.

9. Method according to one of the preceding claims, characterized in that said at least one predefined parameter belongs to the group comprising: bandwidth;

the flow ;

latency;

jitter;

the packet loss rate.

10. Method according to one of the preceding claims, characterized in that said service belongs to the group comprising:

voice call;

the audio call;

video streaming;

web browsing; downloading files;

sending a message.

11. Computer program product (PG) comprising program code instructions for executing the steps of the method for determining a path among a plurality of paths available for data transmission between a terminal (90) and a entity of a service provider (94) according to any one of claims 1 to 9 when said program is executed on a central processing unit.

12. A non-transient recording medium (MEM) readable by a computer on which is recorded a program comprising instructions for the implementation of a method according to any one of claims 1 to 10.

13. Device (9) configured for the implementation of the method (P) of determining a path among a plurality of paths available for data transmission between a terminal (90) and an entity of a supplier of a service (94) according to one of claims 1 to 10, the device comprising:

a receiver (COM) of a request for determining a path;

a memory (MEM) storing at least one predefined parameter necessary for the service;

a processing unit (UT) configured for: