EP2229756A1

EP2229756A1 - Method for adjusting data traffic and device for implementing said method

Info

Publication number: EP2229756A1
Application number: EP08872322A
Authority: EP
Inventors: Luc Miotti
Original assignee: Nexter Systems SA
Current assignee: Nexter Systems SA
Priority date: 2007-12-12
Filing date: 2008-12-08
Publication date: 2010-09-22
Also published as: FR2925249B1; FR2925249A1; WO2009101298A1

Abstract

The invention relates to a method for adjusting packet data traffic on a communication network (1), wherein said network includes at least one user Ui and at least one data source Si. The method is characterised in that at least one user Ui transmits to the data source Si at least one spacing information Ei of the data packets, said information being implemented by said data source Si for spacing the transmission of data packets in the information flow Fi thereof. The invention also relates to a data traffic adjustment device for implementing said method.

Description

METHOD FOR CONTROLLING DATA TRAFFIC AND DEVICE IMPLEMENTING SUCH A METHOD

The technical field of the invention is that of methods and devices for regulating packet data traffic on a communication network.

Today it is conventional to transmit data across a network in a digital way and in the form of packets.

A network includes a number of Si data sources and Ui users. The data sources may for example consist of sensors such as video cameras.

Data packets are most often managed in known networks through switches that regulate data traffic. The switches operate according to control methods which make it possible to limit the bottlenecks of the data and which ensure a synchronized distribution of the data to the different users. The conventional methods implement algorithms that are known to those skilled in the art under the Anglo-Saxon names of "token bucket" and "leaky bucket".

The "token bucket" algorithm makes it possible to regulate the average transmission rate of the data while allowing transmission peaks (however less than a limit).

The "leaky bucket" algorithm smooths the peaks of data traffic by regulating switch output traffic. Other algorithms exist combining to some extent the characteristics of these two known algorithms.

However, the known methods have the disadvantage of leading, in the event of a peak of traffic, to a loss of data at certain parts of a network. Moreover, during traffic pitches on certain flows, the corresponding bandwidth is not made available to other flows. These methods finally require the implementation of specific switches in which the processing algorithms are implemented.

Also known from the patent application US2007 / 0140254 a method in which the adaptation of the traffic to the needs of users has been obtained by a regular time spacing of the data packets and by assigning each user dedicated slots.

However, this method requires controlling the instants of data transmission by the different sources. Moreover the bandwidth of each user is limited by the assignment to each of dedicated slots. However, it is possible for one user of the network not to request data while another user wishes on the contrary to obtain a stream with a higher bit rate. In addition, a data source may be a priority because it conveys the most important information at a given moment. It then becomes necessary to privilege it for one or more users. Finally, this method requires for its implementation a specific switch that can handle such a synchronous allocation of slots.

Patent US6175570 discloses a data traffic control method in which the packets are spaced such that the spacing is greater than a "negotiated" value upon connection. However, the spacing is here performed at a network communication node, therefore at a specific switch. The object of the invention is to propose a method making it possible to optimally and dynamically use the characteristics of a standard network.

The method according to the invention thus makes it possible to adapt quickly to a modification of the needs of the different users. The method according to the invention can also be implemented without requiring a specific switch, it can even be implemented within a network without a switch provided that it is provided with a anticollision mechanism, for example of the type known as the Anglo-Saxon: CS / MA (Carrier Sense / Multiple Access).

For this the invention will rely on the one hand on the computing resources of users and on the other hand on the ability of some data sources (including video sources) to regulate their own emissions.

It is indeed possible at most sources (including video sources) to control a spacing of the transmission of data packets.

Indeed, these sources generally include a preprocessor ensuring the formatting of the data and their transmission on a line.

The invention also aims to propose a device for regulating packet data traffic over a communication network, a device implementing such a method.

Thus, the subject of the invention is a method for regulating packet data traffic over a communication network, network comprising at least one user U ₁ and at least one data source S ₁ , characterized in that at least one U ₁ user transmits to the data source S ₁ at least one spacing information E ₁ data packets, information that is implemented by this source S ₁ to space the transmission of data packets from its stream of data. information F ₁ .

Advantageously, when the network comprises at least two data sources, the user will control the spacing of the packets of the data sources S ₁ only if the values of the periods P ₁ separating the bursts R ₁ from each data stream F ₁ are all greater than the sum of the different transmission times T ₁ needed to transmit the information of a burst Ri (P ₁ > Σ T ₁ ).

There is actually according to the invention a command of all active sources of the network. However, this command can only be performed if the smallest value of the periods of the different flows is greater than the sum of the average durations of the different bursts. The invention proposes to consider, at a given moment, a stream only for each source. In the case where in practice a source could generate several streams in parallel, such a source would be equivalent to several different sources. The treatment of the data packet spacing problem is then identical to that of the packet spacing for several different sources.

For each value of period Pi, therefore, we shall consider only the one separating the bursts Ri from a given stream Fi (or more simply the interval of time separating two successive bursts of the same stream, which actually corresponds to the examples which will be described later).

Each burst is therefore considered identical at the level of a given stream. If over time the bursts of this stream have a period that changes, the proposed calculation algorithms will check if there is still a possibility to discard the source packets.

Moreover, if a stream with different characteristics appears temporally at a given source, this new stream will not be superimposed on the previous stream, but it will appear temporally after a previously processed stream and each user will detect any changes in the Pi periods of this new stream. flux. Overall it is therefore for a source If always the same flow Fi but the numerical values of Pi and Ti may be different over time and space commands will be driven accordingly.

It goes without saying that the knowledge of the parameters Ti, Ri, Si at a given instant is ensured by a learning period of the first user U1.

Beyond this learning period, information Ti, Ri, Si that are measured at each moment will also be known to other users of the network because exchanged between them and will be acquired automatically by a new user who will connect.

According to a first embodiment, the user calculates the spacing Ei for a data source Si by the formula E ₁ = P ₁ ZN ₁ , where P ₁ is the period of time of the packet bursts Ri of the information flow Fi, or if not an optimal enhancement of this value and N ₁ is the number of packets burst Ri of the flux F ₁ . According to a second embodiment, the user calculates the spacing E ₁ for a data source S ₁ by the formula E ₁ = sum (Ti, ... T ₁ , ... T _n ) / N ₁ , expression wherein T ₁ is the minimum transmission time necessary to transmit all the information of a burst Ri of the information flow F ₁ and N ₁ is the number of packets cutting the flow F ₁ .

According to a variant of the invention, when the network comprises at least two users Ui, the method is characterized in that, before transmitting them to the sources, each user communicates in advance to the other users his calculated values Ei and in that the Values retained by all users are common values determined by a selection criterion.

When no priority is requested by a user, the common values retained by all the users U ₁ for the E ₁ may be the upper bounds of each E ₁ .

Conversely, when a user requests a priority for a source S ₁ , the common values retained by all U ₁ users may incorporate the lower of the different E ₁ for the priority source considered.

The invention also relates to a device for regulating packet data traffic on a communication network, network comprising at least one user U ₁ and at least one data source S ₁ , this device is characterized in that each user U ₁ is provided with means for calculating and exchanging data enabling it to determine an optimum spacing information E ₁ between the data packets of a source S ₁ and also enabling it to transmit this spacing information E ₁ at the source S ₁ considered, the latter using this information E ₁ to effectively space the transmission of data packets from its information flow F ₁ . According to one embodiment, the means for calculating and exchanging data of each user will be able to exchange with each other via the network to determine, from a common choice criterion, values of common spacing information Ei.

The invention will be better understood on reading the following description of particular embodiments, a description given with reference to the accompanying drawings and in which: FIG. 1 shows a communication network implementing a traffic control device data according to a first embodiment of the invention,

FIG. 2 a communication network implementing a device for regulating data traffic according to a second embodiment of the invention,

FIGS. 3a and 3b show examples of data streams according to the prior art,

FIG. 4 shows an example of flow regulation according to a first embodiment of the invention; FIG. 5 shows an example of flow regulation according to a second embodiment of the invention;

FIG. 6 shows another example of flow regulation according to this second embodiment of the invention.

FIG. 1 shows a communication network 1 here comprising three users Ui, U ₂ and U ₃ and three data sources Si, S ₂ and S ₃ .

The Ui users are for example three operators of an armored vehicle (such as the vehicle commander, the firing operator and the pilot). Si sources are video sources, such as visible or infrared digital cameras arranged at different locations of the vehicle.

The users Ui and the sources S ₁ are connected to a packet switch 2 of a conventional type. Such a switch makes it possible to regulate the data flows between the sources Si and the users Ui- It is provided with conventional means (memories and algorithms) making it possible to store the received packets and to deliver them to the users according to the requests. According to a characteristic of the invention, each user Ui is provided with means for calculating and exchanging data Mi, constituted for example by a microcomputer, a computer or a processor card. These means enable it to perform in real time a number of evaluation calculations of the information flows of the network and they allow it to transmit to each of the sources If an optimum and desired spacing information Ei between the different packets of data emitted by the source Si.

Current video sources (especially those meeting the standard known to the skilled person under the name "GigEVision" (digital cameras Gigabit Ethernet)) have a pre-processor card (not shown) to adapt the signal of output (and in particular its rate) to a particular means of exploitation.

This pre-processor can therefore receive appropriate programming to change the spacing Ei data packets it provides. According to the invention this programming is transmitted directly by one of the calculation means Mi of a user Ui and according to certain selection criteria.

It should be noted that the invention is not restricted to an implementation of video sources. Si sources may also be audio sources (radiocommunication stations) or data sources (computers, sensors). The Man of

The business will adapt the invention by providing, where appropriate, the sources considered electronic processing means for regulating the flow of outgoing data and in particular the spacing between the data packets they provide.

These electronic processing means are well known to those skilled in the art and it is therefore not necessary to describe them in more detail. It can be seen that the invention relies on regulating the data flows not on the characteristics of a specific switch alone but on computing resources. distributed in particular between the users U ₁ and the data sources S ₁ .

More precisely, this spacing of the data packets will make it possible to control the order of the data packets arriving at the switch and in particular will allow the interchange of packets from the different sources, which will make it possible to reduce the latency for receiving the data of certain data packets. sources S ₁ .

By way of example, FIG. 3a shows on an axis of times 4 an unregulated data flow F ₁ . This stream comprises a succession of bursts R ₁ , and each burst can be cut into a number N ₁ of packets N _1I , N ₁₂ , ... N ₁₅ .

Here each burst R ₁ was cut into five packets. The set of data of a burst R ₁ is transmitted over a duration T ₁ . The same source S ₁ will provide another burst R ₁ of data at the end of a period P ₁ .

For video data the burst R ₁ corresponds substantially to the time required to transmit the data of an image. The duration T ₁ is of the order of 5 to 20 milliseconds. The period P ₁ between two bursts R ₁ corresponds to the refresh time of the image. This period P ₁ is of the order of 5 to 50 milliseconds. The number N ₁ of packets is generally between 50 and 500.

FIG. 3b shows two flows Fi and F ₂ as they are emitted unregulated, as well as a first burst (unregulated)

R _NR of the flow F _R resulting at the level of the reception by the users after passage of the streams through the switch 2. There have been included flows whose slot widths and the total gust duration Ti and T ₂ are different. The periods Pi and P ₂ are also represented differently.

It can be seen that the bursts of the fluxes intercalate according to the arrival times of the different packets at the switch. The latency of a packet of a burst of a given stream at the level of a user (that is to say the time interval separating its emission by the source and its reception by the user) is then very variable. . By way of example, FIG. 3b shows the maximum L _iM latency of the third packet of the stream F _{1 as} well as the latency IJ2M maximum for the fifth packet of the F ₂ stream. However, depending on the arrival times of each packet at the switch, the latency can be equal to the maximum value of the duration Ti and T ₂ , ie the total duration of a burst of the two flows.

When traffic peaks with an increase in the number of video sources, the latency can therefore grow strongly, thus penalizing users.

According to the method according to the invention a user U ₁ will transmit to each source S ₁ spacing information E ₁ of its packets.

The users U ₁ must first know the average durations T ₁ of each burst R ₁ of a flow F ₁ and the periods P ₁ (time between two bursts R ₁ ). These values can be stored in the calculation means M ₁ of each user U ₁ . If the network is not fixed and can receive other sources S ₁ , it is possible to provide at the time of startup of the network a learning phase during which each user will measure the duration T ₁ and P ₁ from each source S ₁ or will obtain this information from sources and / or other users.

Moreover, each user U _{1 will} make sure that the smallest value of the periods P ₁ separating the bursts R ₁ from a stream F ₁ is greater than the sum of the durations T ₁ (mini P ₁

> Σ T ₁ ). Such an arrangement ensures the possibility in all cases to have all the data of different bursts R ₁ in a single period P ₁ . If this condition is not met, we will not order packet spacing.

According to a first embodiment of the invention, the user U ₁ calculates the spacing E ₁ for a data source S ₁ by the formula E ₁ = P ₁ ZN ₁ , where P ₁ is the burst period R ₁ of the information flow F ₁ and N ₁ is the number of packets cutting each burst R ₁ of the flow F ₁ . If P ₁ can not be calculated exactly, then P ₁ will be chosen arbitrarily as the smallest computable amount (preferably, the increase should not exceed 10%). The values of P ₁ and N ₁ being stored by the sources or by all or part of the users or measured during the learning phase, the calculation of E ₁ is easy.

By way of example, FIG. 4 shows only the first bursts Ri, R ₂ and R ₃ of the streams Fi, F ₂ and F ₃ of signals supplied by three sources Si, S ₂ and S ₃ on a network.

In this example, each burst is divided into packets of the same duration Tp. The stream Fi comprises three packets per burst Ri, the stream F ₂ has four packets per burst R ₂ and the stream F ₃ has five packets. The left part of each line represents the unregulated burst R ₁ and the right part shows the same burst after regulation (packet spacing).

The duration Ti is equal to 3 × T _p (T _p being the duration of a packet). It is considered here that the value T _p is equal to 2T _U , T _u corresponding to the unit of time adopted. The duration Ti is therefore equal to 6T _U , the duration T ₂ to 8T _U and the duration T ₃ to 10T _u .

In this example, the sum Ti + T ₂ + T ₃ is equal to 24T _U. The values of the periods P ₁ of the bursts R ₁ are chosen for this example all equal to 25T _U (thus greater than the sum of T ₁ ).

The spacings E ₁ = P ₁ ZN ₁ are then equal to: Ei = 8T _u ; E ₂ = 6T _U ; E ₃ = 5T _U.

The packets of the bursts R _x , R ₂ and R ₃ are then separated from each other by time intervals which are respectively equal to 6T _U , 4T _U and 1.5 T _u .

FIG. 4 shows in the last line: the unregulated burst R _NR that would be seen by the users (left curve) and the regulated burst R _R (right curve) resulting as a result of the implementation of the invention, burst R _R as seen by the users at the output of the switch 2.

It is found that the fact of discarding the packets of the different bursts made it possible to order the flow of data which led to favor the fluxes F ₂ and F ₃ which are the largest. Indeed, we have E ₂ <Ei and E ₃ <E ₂ .

Moreover, with the regulation method according to the invention, the maximum latency time for a packet of one flow is theoretically equal to the sum of the durations of a packet of each of the other flows.

Thus, the maximum latency L _m of a packet of the stream Fi is equal to the duration of a packet of the stream F ₂ plus the duration of a packet of the stream F ₃ , ie 4T _U for the example of FIG. 4.

Similarly, the packages here having all the same length

(2T _U ), the L ₂ M latency of a packet of the stream F _{2 as} well as the latency L _3M of a packet of the stream F ₃ are both equal to

4T _U. It will be noted that in the particular example of FIG. 4, (right-hand part of the regulated flow figure R _R ) the maximum latency L _3M is effectively equal to 4T _U while the maximum latencies Li _M and L _2M are equal to 2T _U .

Without the implementation of the method according to the invention the maximum latencies for a packet of each stream could be equal to:

T ₂ + T ₃ (ie 18 T _u ) for the flux Fi, Ti + T ₃ (ie 16 T _u ) for the flux F ₂ and Ti + T ₂ (ie 14 T _u ) for the flux F ₃ .

In the particular example of FIG. 4 (left-hand part R _NR ), the temporal distribution obtained for the resulting unregulated flow leads to a latency of 14 T _u for each flow.

According to a second embodiment of the invention, the user U ₁ calculates the spacing E ₁ for a data source S ₁ by the formula E ₁ = sum (Ti, ... T ₁ , ... T _n ) ZN ₁ , where T ₁ is the minimum transmission time necessary to transmit all the information of the burst Ri of the information flow F ₁ and N ₁ is the number of packets cutting the burst Ri of the flux F ₁ . Here again each user will ensure that the smallest value of the periods P ₁ separating the bursts R ₁ from a stream F ₁ is greater than the sum of the durations T ₁ (mini P ₁ > Σ

T ₁ ) •

Such an embodiment makes it possible to minimize the latency introduced by the regulation on several streams simultaneously.

FIG. 5 thus shows an example in which the network comprises three data sources Ui, U ₂ and U ₃ providing each an information flow F ₁ , F ₂ or F ₃ . In this example, only the first bursts Ri, R ₂ and R ₃ of the streams Fi, F ₂ and F ₃ are represented. Each burst Ri is divided into packets of the same duration. The burst Ri has four packets, the burst R ₂ has eight packets and the burst R ₃ has twelve.

The duration Ti is equal to 4 x T _p (T _p being the duration of a packet), the duration T ₂ = 8T _P and the duration T ₃ = 12T _P.

The packets here having the same duration T _p will thus have according to the invention the following spacings: E ₁ = T _p x (4 + 8 + 12) / 4 ≈ 6 T _p E ₂ = T _p x (4 + 8 +12) / 8 = 3 T _p E ₃ = T _p x (4 + 8 + 12) / 12 = 2 T _p

On each line is shown the burst Ri considered before and after separation of the different packets (unregulated I regulated).

The bottom curve in FIG. 5 shows on the right the regulated signal R _R received at the level of each user Ui after processing by the switch 2 and on the left the unregulated signal R _NR . The regulated signal comprises a temporal succession of the different packets from the sources Si, S ₂ and S ₃ .

The spacing of the data packets during their transmission by the sources leads to a control of the arrival orders of the packets at the level of the switch 2 without it being necessary to control the arrival times of the packets of a packet. precisely.

As a result, at the level of the regulated signal R _R received maximum latency times which are here: Li _M = 0, L ₂ M = 1 T _p and L _3M = 2 Tp. The packets all having the same length (T _p ), the theoretical maximum latency for a packet of each signal is equal to 2T _P.

Without the implementation of the method according to the invention the maximum latency could be equal to: 8T _p + 12T _p = 20T _p for the packets of the stream Fi, 4T _P + 12T _P = 16T _P for the packets of the stream F ₂ and 4T _P + 8T _P = 12T _P for the packets of the stream F ₃ . It can be seen that, thanks to the invention, the latency times can be controlled and are reasonable.

It is of course possible with the invention to manage data streams for which the durations of each packet are different.

FIG. 6 thus shows an example in which the network comprises three data sources Ui, U ₂ and U ₃ each providing an information flow Fi, F ₂ or F ₃ . Here again only the first bursts R ₁ , R ₂ and R ₃ of the streams Fi, F ₂ and F ₃ are represented in the figure.

If we denote T _u the unit of time adopted, we can consider that the packets of the burst R ₁ have a duration of 4T _U , the packets of the burst R ₂ have a duration of 2T _U and the packets of the burst R ₃ have a duration of 6T _U. The burst R ₁ comprises two packets and has a duration T ₁ = 8T _U. The burst R ₂ comprises eight packets and has a duration T ₂ = 16T _U. The burst R ₃ finally comprises four packets and has a duration T ₃ = 24T _U.

By implementing the method according to the invention, the following spacings are calculated:

E ₁ = (2x4T _u + 8x2T _u + 4xβT _u ) / 2 = T _u x (8 + 16 + 24) / 2 = 24 T _u E ₂ = T _u x (8 + 16 + 24) / 8 - 6 T _u E ₃ = T _u x (8 + 16 + 24) / 4 = 12 T _u

Again, there is shown on each line the burst Ri considered before and after spacing of the different packets (unregulated / regulated).

The two lower curves in FIG. 6 show the signal received at the level of each user Ui after processing by the switch 2. The curve R _R shows the signal regulated using the method according to the invention and the curve R _NR the unregulated signal.

This signal comprises a temporal succession of the different packets from sources S ₁ , S ₂ and S ₃ .

The theoretical maximum latency L _iM of a packet of the flux F ₁ is equal to the duration of a packet of the flux F ₂ (2T _U ) plus the duration of a packet of the flux F ₃ (6T _U ). It is therefore equal to 8T _U.

Likewise, the theoretical maximum latency L _2M of a packet of the flux F ₂ is equal to 4T _u + 6T _u = 10T _u (duration of a packet of the flux F ₁ more duration of a packet of the stream F ₃ ) and that of a packet of the stream F ₃ is equal to 4T _U + 2T _U = 6T _U (duration of a packet of the stream F ₁ plus duration of a packet of the stream F ₂ ).

Note that in the particular example of Figure 6, the maximum latency L _3M is effectively equal to 6T _U while latency L _m is zero and latency L _2M is equal to 6T _U.

T ₂ + T ₃ (ie 40 T _u ) for the flux F _x , Ti + T ₃ (ie 32 T _u ) for the flux F ₂ and Ti + T ₂ (ie 24 T _u ) for the flux F ₃ .

Those skilled in the art will consider that it is desirable to choose a sufficient number of packets to facilitate the insertions of the streams and thus reduce the overall latency.

In all the preceding examples, a network comprising at least one user Ui has been considered. It is this user who controls the spacings of the packets sent by the sources.

It is of course possible (and advantageous) to implement the invention within a network comprising several users. Each user can also be a transmitter and constitute itself one of the sources of the network. In this case and in order to avoid conflicts at the different sources, it will be possible to determine at the outset that only one user is authorized to control the spacings E ₁ of the data of the different sources Si.

It may also be possible according to a variant of the invention to provide, prior to the control of the sources Si, a prior exchange between the different users Ui of the values of the spacings Ei calculated by each. Each user

U ₁ is provided with a calculation means M ₁ which is equipped with the same calculation and exchange software at which the method according to the invention is codified. Each user will also ensure that the smallest value of the periods Pi separating the bursts R ₁ from a stream F ₁ is greater than the sum of the durations Ti (mini Pi> Σ T ₁ ). Each user will thus be able to communicate beforehand to the other users his calculated values E ₁ and the algorithm implemented by each will be such that the values retained by all the users at their computing means M ₁ will be common values determined by a user. choice criteria. For example, the choice criterion may be: the maximum value of the various calculated E i, the minimum value or the average value. Once common values are chosen by the users, it does not matter which user U _{1 will} control the sources. Indeed, if a source receives twice the same distance command E ₁ it will not change its operation.

Such an arrangement allows a user U ₁ who has just connected to the network to take into account the knowledge of different data sources that has been acquired by other users. This reduces the learning time that would be necessary for the calculation means of a new user.

It will be possible (by programming at each calculation means M ₁ ) to periodically refresh, by dialogue between the different calculation units M _1, the values E ₁ adopted. This will take into account the arrival of a new source or the abandonment of another source.

The implementation of an appropriate choice criterion also makes it possible to prioritize or not one of the sources of the network.

Thus, if no priority is requested by a user, the common values retained by all users U ₁ for E ₁ may be the upper bounds of each E ₁ . In this case, the overall decrease in latency is preferred.

If, on the other hand, a user U ₁ requests a priority for the data provided by a source S ₁ , the common values retained by all the users U ₁ advantageously incorporate the minor of the different E ₁ for the priority source considered, the other distances E ₁ for non-priority sources are then increased.

Such an arrangement tightens the packets at the preferred source while discarding the packets for other sources. This results in a facility to insert the packets of the preferred source, so a decrease in latency for the latter (at the price nevertheless of an increase in latency for other sources). Thanks to the invention, the switch 2 has a function that is no longer essential. Most of the traffic regulation is ensured by the direct dialogue between the calculation means Mi of the different users and the different sources Si. The switch 2 simply makes it possible to avoid the peaks of flux over periods of the order of a few packets and it ensures the storage of the different packets provided by the sources.

It is possible, as an alternative, to define a network 1 in which there is no longer a switch but only users Ei and sources Si.

Such a network is represented in FIG. 2 in the form of an annular BUS 3 of the Ethernet or quasi-annular BUS type of the CAN type. There is shown in 5 a termination resistor of this CAN BUS. Each user Ui can, using his calculation means Mi, communicate through the BUS with the other users U ₁ and also with the different sources Si. The distances Ei of the packets of each source are defined according to the method described above. and at least one user Ui transmits these spacing commands to the different sources (after exchanging with the other users to determine Ei values common to all).

Claims

A method for regulating packet data traffic on a communication network (1), network comprising at least one user U ₁ and at least one data source S ₁ , characterized in that at least one user U ₁ transmits at the source of data S ₁ at least one spacing information E ₁ data packets, information that is implemented by this source S ₁ to space the transmission of data packets of its information flow F ₁ .

A method for regulating data traffic according to claim 1 when the network (1) comprises at least two data sources, characterized in that the user controls the packet spacing of the data sources S ₁ only if the values of the periods P ₁ between the bursts R ₁ of each stream F ₁ of data are all greater than the sum of the different transmission times T ₁ necessary to transmit the information of a burst Ri (P ₁ > Σ T ₁ ).

A method for regulating data traffic according to claim 2, characterized in that the user calculates the spacing E ₁ for a data source S ₁ by the formula E ₁ = P ₁ ZN ₁ , where P ₁ is the period of time of packet bursts Ri of the information flow Fi, or, failing this, an optimal enhancement of this value and N ₁ is the number of packets cutting a burst Ri of the stream F ₁ .

4. Method of regulating data traffic according to claim 2, characterized in that the user calculates the spacing E ₁ for a data source S ₁ by the formula E ₁ = sum (T ₁ , ... T ₁ , ... T _n ) ZN ₁ , where T ₁ is the minimum transmission time necessary to transmit all the information of a burst Ri of the information flow F ₁ and N ₁ is the number of packets splitting the flow F ₁ .

5. Method of regulating data traffic according to one of claims 1 to 4 when the network comprises at least two users Ui, characterized in that, before transmitting them to the sources, each user communicates in advance to other users its values Ei calculated and in that the values retained by all users are common values determined by a selection criterion.

A method for regulating data traffic according to claim 5, characterized in that, when no priority is requested by a user, the common values retained by all the users U ₁ for the E ₁ are the upper bounds of each E ₁ .

7. A method of regulating data traffic according to one of claims 5 or 6, characterized in that, when a user requests a priority for a source S ₁ , the common values retained by all U ₁ users incorporate the lower of the different E ₁ for the priority source considered.

8. Device for regulating packet data traffic on a communication network (1), network comprising at least one user U ₁ and at least one data source S ₁ , characterized in that each user U ₁ is provided with computing and data exchange means (M ₁ ) enabling it to determine an optimum spacing information E ₁ between the data packets of a source S ₁ and also enabling it to transmit this spacing information E ₁ to the source S ₁ considered, the latter using this information E ₁ to effectively space the transmission of data packets of its information flow F ₁ .

9. Device for regulating data traffic according to claim 8, characterized in that the means (M ₁ ) for calculating and exchanging data of each user (U ₁ ) can exchange with each other via the network (1). for determining, based on a common choice criterion, values of common spacing information E ₁ .