FR2898231A1 - MECHANISM FOR MULTILAYER REGULATION OF THE FLOW OF A TCP DATA STREAM IN A HIGH DUTY ETHERNET FULL DUPLEX NETWORK - Google Patents

Abstract

The invention relates to a mechanism for regulating the data transmission rate in a terminal connected to a communication network, implementing a first regulation of the data rate at the transport layer of the terminal as a function of a state of data. overall congestion of the communication network; and a second data rate regulation at the data link layer of the terminal according to a congestion state of said data link layer. Said method comprises at least one step of determining at least one parameter representative of a congestion state of the data link layer of the terminal, said first regulation of the data rate at said transport layer taking into account said representative parameter of a congestion state of the data link layer.

Description

The field of the invention is that of communication networks in mode

  packets. It is recalled that a communication network is a heterogeneous structure both in terms of the media used to carry the data (copper pairs, optical fibers, radiofrequencies), the level of available bandwidth, data throughput or even protocols implemented. The heterogeneity of communication networks has the effect of generating congestions on the network. When the network is congested, it means that several frames of data are colliding, resulting in the loss of the information they carry. In packet mode networks, congestions occur when a path carrying packets is composed of segments with different rates. Congestion is an annoying phenomenon because it forces re-transmission of the lost data and significantly slows down the time the data is sent to the destination terminal. It is important to limit this phenomenon in order to improve the quality of service of communication networks. In order to overcome this disadvantage, efforts are made to use reliable transport protocols, which are able to detect congestion on the network and adapt their data transmission procedures accordingly, while ensuring the good reception of the data by the destination terminal. Transmission Control Protocol (TCP) is an example of a reliable transmssi protocol. The: schematically shows a connection to two terntinaL <TI and T2 of sta-ts', sart the TCP protocol. In this figure, each terminal is represented with three of its protocol layers: for example, the TOP, for example, the MA layer, the protocols represented, correspond to the protocol layers defined by the Open Systems Interconnection (OSI) model. Intermediate terminals S1 and S2 are also shown. These terminals S 1 and S 2 are scattered over the network and are, for example, Ethernet switches or routers.

  The connection established between the two terminals TI and T2 by means of the TCP protocol is shown schematically in Figure 1 by a double arrow A connecting the transport layer of the two terminals. The TCP conventionally comprises a mechanism for regulating the transmission rate of the data according to a state of global congestion of the network, as well as a mechanism for retransmission of the lost data. The TCP protocol perceives congestion via the loss of a packet. Thus, when the mechanism for regulating the data transmission rate is informed of the occurrence of congestion, the transmission rate of the transmission layer of the transmitting terminal, here the terminal T ,, is reduced in order to avoid the amplification of the phenomenon of congestion but also to avoid the loss of data. Transmission rate control is achieved through a sliding window whose size varies according to the overall congestion state of the network. The transmission window contains the bytes that the transmitting terminal Ti can transmit between two instants tk and tk + 1.

  However, if data has been lost, it is re-issued by the data retransmission mechanism. Similarly, in order to regulate the transmission rate of data on the network, locally, the various terminals T ;, T2, SI, and S2 disseminated on the network and requested to route the data use protocols of: equation of the flow rate of the data link. This region, a of the output rate, is a local control pu; Intervene between two terminals consenu f on the network such as terminals Ti and S1. This regimen is exemplified by the fact that it is negated in FIG. 1 by a double bit rate is defined by the Institute of Electrical and Electronics Engineers (IEEE). Under this name, the IEEE defines in the MAC layer a flow control between two terminals connected to each end of the same full-duplex Ethernet link. A full-duplex Ethernet link is a two-way, simultaneous link using the Ethernet channel management protocol to transmit data between two machines. Thus, when the buffer memory of a first terminal, here the terminal S1 for example, fills beyond a threshold called threshold XOFF, it transmits an XOFF frame. This frame stops the transmission of the terminal vis-à-vis, here, the terminal Ti. The number of bytes contained in the buffer memory of the terminal S1 then decreases, until reaching a threshold called threshold XON from which the terminal S1 transmits an XON frame to the terminal Tl which reactivates its transmission. Although the use of the TCP protocol makes it possible to avoid the loss of data and limits the amplification of congestion phenomena occurring on the network, a connection between two terminals as described in FIG. 1 does not offer a bit rate. emission satisfactory with regard to the volumes of data exchanged and the demand for bandwidth always greater. In order to adapt to the increasing demand for bandwidth, Ethernet networks are commonly deployed by telecom operators due to the maturity and cost of the technology, with proposed speeds ranging from 10 MI: Vs to 1 Giga bits / s. Figure 2 schematically shows a connection made between two remote TIs and T2s having a version of the prereq: eo! E TCP nriodflee and adapted to Etherr networks. In this modified version of the TCP protocol, presented in this issue: Case for the tail-to-bottom, back press-ie congestion versus / network grid of Mr. Herbert and P. Vice net, the data of the transmitter is the transmission of data, and the regulation of the transmission rate is the only mechanism for regulating the data transmission rate proposed in this embodiment. control mechanism of the data link layer represented by a double arrow C in FIG. 2. The regulation of the data transmission rate is then a local regulation and no longer a global one. Although this realization improves the transmission rate of data on the network compared to the embodiment of Figure 1, it only works for full-duplex Ethernet networks end-to-end. Thus, when the data travels over a network exhibiting bandwidth variations related to the media used or to the different protocols used, this technique is not suitable. It also assumes that each segment of the path carrying the data flow activates the local flow control. The solution proposed in the context of the invention does not have these disadvantages of the prior art. Indeed, it relies on a method for regulating the data transmission rate in a terminal connected to a communication network, implementing a first regulation of the data rate at the transport layer of the terminal as a function of a overall congestion state of the communication network; and a second data rate regulation at the data link layer of the terminal according to a congestion state of said data link layer. According to the invention, this method comprises at least one step of at least one step representative of a terminal state of the data link layer of the terminal, first layer Lac; the flow rate at the level of said transpor layer. This parameter is representative of a congestion state of the layer 1 of the loopback sound, ie the interconnection between the data link layers and the transport of this terminal. This solution has never been considered in the prior art. Indeed, in the prior art, the data rate is managed protocol layer protocol layer without worrying about the congestion state of the lower layers. The person skilled in the art has in fact always considered that this would have made the dialogues between the different protocol layers very complex and would have, in fact, slowed the transmission of data on the network. In addition, this layer-by-layer approach is recommended in the standards. Going against these prejudices of a person skilled in the art, the inventors of the present application have, on the contrary, found that the interaction between the data link and transport layers offers a better responsiveness and a better adaptability to the nature from the network located downstream of the transmission terminal, to the mechanism for regulating the transmission of data. More precisely, an objective of the invention is to improve the data transmission rate of a terminal implementing: a first regulation of the data rate at its transport layer, as a function of a state of congestion global network, a second regulation of the data transmission rate at the data link layer, according to a state of congestion the latter, and whatever the type of network to which it is connected. In a particular example of an application, the purpose of this is to propose an in ternal technique that allows this to be done in a TCP-based way. noc_P to an uplex Ethernet network performing uni-level flow control at the MAC level. It applies in particular, but sively, in the case where such a TCP connection transits via an id-duplex network, ,, a to t, the pers able pers. According to a feature of the invention, the first regulation is based on a variation the size of a data transmission window, according to two distinct growth phases comprising a first phase during which the size of the data transmission window increases according to a first law of exponential variation, and a second phase during which the size of the data transmission window increases according to a law of linear variation. When said parameter satisfies at least one non-congestion criterion, the solution of the invention introduces a third growth phase of the size of said window during which the size of said window increases according to a second law of exponential coefficient variation. growth greater than the growth coefficient of the first phase. By introducing this new phase of rapid growth in the size of the transmission window when the congestion state of the data link layer allows it, the transmission rate of the terminal is improved and the resource utilization is optimized. According to another characteristic of the invention, the value of the growth coefficient of the law of variation of the third phase is a function of a state of global congestion of the network. This makes it possible to adapt the growth of the size of the data transmission window to the congestion state of the network. Thus, resources are used optimally. According to another characteristic of the invention, the parameter representing a congestion state of the data link layer corresponds to the maximum quantity of bytes that the data link layer DedL ns, e; hang an inter. are of determined time. When the data transmission is less than said parameter, the size of the data transmission window follows the second law of exponential variation of the third growth phase. By making the variations of the size of the window depend on transmission of data of the congestion state of the data link layer, it is possible to optimize the resources of the transmission terminal. Indeed, when the global congestion state of the network is such that the regulation at the level of the transport layer allows an increase in the size of the data transmission window, the latter is weighted according to the state of the transmission. congestion of the data link layer. Only data that can be handled by the data link layer are emitted by the transport layer. Thus, it avoids clogging the buffers of the transmission terminal.

  According to a characteristic of the invention, a parameter representative of an available bandwidth on said network is also evaluated, corresponding to a maximum quantity of bytes that can carry a channel between said terminal and a receiving terminal of said data. This parameter constitutes a threshold conditioning a passage of the size of the transmission window of said first growth phase, when the size is less than said threshold at said second growth phase, when said size is greater than said threshold. The transmission rate of the data takes into account the state of the data link layer thus allowing a better use of the resources.

  This makes it possible to have a high data transmission rate even when the data link layer is congested. According to one characteristic of the invention, the parameter representative of a congestion state of the data link layer and / or the -ei-esentative parameter of the bandwidth available on the network are determined recurrently. This makes it possible to adapt the transport layer to the possibilities of the data link layer dynamically. In this way, the data always feels dry and allows you to take a closer look at the onge terminal. This improves process responsiveness and better resource utilization. According to a characteristic of the invention, the time separating two consecutive determinations of the parameter representative of a congestion state of the data link layer and / or the parameter representative of the available bandwidth on the network is a function of said global congestion state. communication network. The determination of these parameters is conditioned by the receipt of a triplet {XOFF, XON, XOFF} for the parameter representative of a congestion state of the data link layer and the reception of an acknowledgment by the transport layer of the terminal transmitter for parameter representative of the bandwidth available on the network. According to a characteristic of the invention, it is required that the parameter representative of a congestion state of the data link layer is less than or equal to the parameter representative of the bandwidth available on the network. This makes it possible to offer interoperability between several existing transport protocols and the invention. Thus, the deployment of the invention in a network is facilitated.

  According to another characteristic of the invention, said transmitting terminal is a TCP server, said first regulation is a TCP flow control between said server and a TCP client, and said second regulation is a SC2.3x tcree flow control. performed at the level of the MAC layer of the server, between said server c! er. or an intermediate device Ju network ce.0 - (ie v., serv ..) ur Ethernet Full Duplex. The invention also relates to a data transmission terminal which is connected to a communication terminal, and second means for regulating the data rate at the data link layer of said data terminal. transmission according to a congestion state of said data link layer. This terminal further comprises means for determining a parameter representative of a congestion state of said data link layer, said first regulation means taking into account said parameter representative of a congestion state of the link layer of data. The invention further relates to a computer program comprising program code instructions for executing the steps of the method as previously described when said program is executed by a processor. The invention finally relates to a communication system between a server terminal and a client terminal through a communication network, said system also comprising at least one intermediate device located between said client and server terminals, said server terminal comprising first means regulating the data rate at the transport layer of said server terminal, as a function of a global congestion state of the communication network between said server terminal and said client terminal, and second means of regulating the data flow at the level of the data link layer of said server terminal as a function of a congestion state of the data link layer between the server terminal and said intermediate equipment. In such a system, said server terminal comprises means for detecting a parameter representing a state of congestion of a data layer layer: said parameter representative of a congestion state of the data link layer is taken into account. by the yens of reg-mine! Other features and advantages will become apparent from the reading of preferred embodiments described with reference to the drawings in which: - Figure 1 schematically shows a connection between two remote terminals realized by means of the TCP protocol according to a first prior art; FIG. 2 diagrammatically shows a connection between two remote terminals made by means of a modified version of the TCP protocol according to a second prior art; FIG. 3 schematically represents a connection between two remote terminals made by means of FIG. a modified version of the TCP protocol according to the invention; FIG. 4 schematically represents the operating principle of the data transmission rate regulation mechanism at the level of the data link layer according to the invention; FIG. 5 is a diagram representing the three phases of variation of the size of a window of data mission according to the invention - FIG. 6 represents the algorithm for determining the law of variation of the size of a transmission window as a function of the parameter representative of a congestion state of the data link layer As well as the parameter representative of the available bandwidth, FIG. 7 schematically represents the main steps performed by a computer program comprising code instructions for the execution of the method according to the invention. reuse, e connection made -ru two tel-nt had /. Remote .1, T2 by means of a reliable transport protocol. In the exemplary embodiment describes this protocol This transport is the TCP protocol. I, ret, de,. The TI terminal is a data terminal, and the terminal T2 is a data receiver terminal. This communication network may be a wired support network, or a radio frequency network Each T1, T2 terminal is represented with three of its protocol layers defined according to the OSI model The layers represented are the protocol transport, TCP, network, and IP layers In this figure, intermediate terminals S1 and S2 and their MAC protocol layer are also represented, such terminals being, for example, Ethernet switches, routers or any other network equipment located on the path between the terminals. T1 and T2 In this embodiment, the TCP protocol comprises a mechanism for regulating the transmission rate as a function of a state of overall network congestion as well as a mechanism for retransmission of the lost data as previously described in relation to FIG. 1 of the prior art. This is represented in FIG. 3 by double the arrow A 'connecting the TCP layers of the two terminals. Similarly, the data transmission rate at the MAC protocol layer is regulated by means of appropriate control protocols (see FIG. 1). This regulation is shown diagrammatically in FIG. 3 by the double arrows B connecting the MAC layers of two successive terminals, such as TI and Si. In the exemplary embodiment described, the regulation protocol is the 802.3x protocol. Indeed, in the example, the transmission rate of the layer i, iAC between the transmitting terminal TI and the first intermediate terminal SI on the network is regulated by means of a protocol of: uiec - the data transmission rate of the MAC layer which is the 802.3x protocol. This should be unused between the other terminals, Si, S2, etc. On FIG. 3, it can also be seen that the MAC and TCP protocol layers of the transmitting terminal T1 exchange information between themselves. This exchange of information is materialized by a double arrow D in FIG. 3. The exchange of information between the TCP and MAC protocol layers of the transmitting terminal T1 consists of the transmission of data relating to a state of congestion of the MAC layer to the TCP layer. This data is then used by the mechanism for regulating the data transmission rate as a function of a global congestion state of the TCP protocol network.

  This data is in the form of a parameter representative of a state of congestion of the MAC layer S '. The calculation phases leading to the determination of the parameter representing a congestion state of the MAC layer S 'are described in the particular example where the transmitting terminal T1 is connected to an intermediate terminal S1 by means of an Ethernet link Full -Duplex allowing the use of the 802.3x protocol. These different calculation phases correspond to the execution of the step E1 as represented in FIG. 7. The parameter S 'corresponds to the maximum quantity of bytes N that the MAC layer of the transmitting terminal T1 can transmit during a time interval. At. In order to determine the parameter S ', the protocol 802.3x which makes it possible to regulate the data transmission rate at the local level is implemented as follows: at a time t1 the MAC layer of the transmitting terminal T1 receives a information from the intermediate terminal S1, which is directly consecutive on the network, asking him to stop the sending of data. This iformation is in the form of a XOFF frame conforming to the 802.3x protocol. At an estant t2 the layer h.1, AG of the terminus it emits T receives an info:) venai mir S; The same information is in the form of an XON frame. The time interval At corresponds to the time elapsed between times t1 and t2. During this time interval At, buffer memories of the MAC layer of the transmitting terminal TI accumulate at most M bytes of data. The quantity N corresponds to the number of bytes of data transmitted on the network by the intermediate terminal SI during the time interval At, namely: RxAt (EQ1), where R is the flow rate of the network located downstream of the intermediate terminal SI, that is to say the network that connects the terminals S1 and S2 in FIG. 3. At a time t3, the MAC layer of the transmitting terminal TI receives information from the intermediate terminal S1 requesting it to stop the sending data. This information is in the form of an XOFF frame.

  During a time interval At 'corresponding to the time that has elapsed between times t2 and t3, the MAC layer of the transmitting terminal TI transmits at most M' bytes of data to the intermediate terminal Si. quantity of bytes N is such that N = (PxR) xAt EQ2), where P is the rate of the Ethernet link Full-Duplex connecting the transmitter terminal TI to the intermediate terminal Si. It is deduced from the equations EQ1 and EQ2 that: N = ( P) / ((I / At ') + (If At) (EQ3) If At> At', then N (PxAt ') 12. If At At, then N> (PxAt) / 2. parameter S 'at time t3 is then S t3) = (Px min ((t2- t1), (t3- t2))) 12 (EQ4) the last equation aractenst ques avanteg {Dn ins de n ce; This equates to the size of the tasks, and it makes it possible to obtain a value of the parameter S 'which is smaller than the number of bytes of data N. Therefore, it minimizes the data losses. Equation EQ4 means that the parameter S 'is a function of the time intervals At and At'. The value of the parameter S 'is updated after each reception by the MAC layer of the sending terminal TI of a sequence of frames {XOFF, XON, XOFF}, this sequence of frames corresponds to the implementation of the 802.3x protocol between the terminal transmitter Ti and the intermediate terminal S1.

  FIG. 4 represents a buffer memory M of the data link layer of the intermediate terminal SI involved in the implementation of the local regulation mechanism of the data transmission rate in accordance with the 802.3x protocol. The buffer memory M represented has a low level filling threshold L and a high level filling threshold H. Thus, when the transmitting terminal TI transmits data to the intermediate terminal SI, the buffer of the intermediate terminal accumulates the data up to the number of bytes corresponding to the accumulated data volume reaches the high level threshold H. When this event occurs, the MAC layer of the intermediate terminal S1 sends an XOFF frame to the MAC layer of the transmitting terminal TI . On receipt of this XOFF frame, the MAC layer of the transmitting terminal stops sending data to the intermediate terminal Si. Similarly, when the number of bytes corresponding to the volume of the accumulated data reaches the low level threshold L, the layer MAC of the intermediate terminal em & c a XON frame with tooth inaton of the MAC layer of the transmitter terminal T. Upon receipt of this tram the MAC core TI dec. ssion of dor, tint. read This update of the parameter S 'is a recurring phenomenon which is a function of a state of global congestion of the network. Thus, each time a sequence of frames {XOFF, XON, XOFF} is received by the MAC layer of the transmitting terminal TI, the parameter S 'is updated.

  In order to avoid the occurrence of a mechanism called "starvation of the buffer memory", the parameter S 'is initialized at infinity when the connection between the transmitting terminal and the receiving terminal is opened and the parameter is positioned. S 'to infinity if it is zero in the equation (EQ4). Once the parameter representative of a congestion state of the MAC layer S 'determined, it is transmitted to the transport layer of the transmitting terminal in order to be used by the control mechanism of the data transmission rate according to a global congestion state of the transport protocol network. This corresponds to the step E2 of FIG. 7. The regulation of the transmission rate of the data by the TCP protocol is carried out by means of a sliding transmission window whose size F, expressed in bytes, varies as a function of a state of global congestion of the network. A data transmission window is defined by its size F in bytes but also by its sequence number. FIG. 5 shows the variations of the size F of the data transmission window as a function of the number of acknowledgment messages received by the TCP protocol. Indeed, in order to ensure that data transmitted by the transmitting terminal TI to the receiving terminal T2 have been received by it, the receiving terminal T2 transmits to the transmitting terminal TI a wipe of at t, ttemenl. no acknowledgment message is received by 1-a transmitter and TCP understands that the data has been lost. The TCP protocol then re-transmits the lost data. debt figure F d. data window follows three p of cruises iist ux first phases of growth (pl and (pH of the size of the window F data emission are exponential growth phases, the third phase of growth (pub as for it, is a phase of linear growth The existence of these different growth phases of the size F of the data transmission window makes it possible to adapt the transmission rate of data of the transport layer to a state of global congestion of the network. thus allowing a better use of the resources of the TI transmitter terminal, as well as a better routing of the data on the network Thus, at the creation of the connection between the transmitting terminal TI and the receiving terminal T2, the size F of the transmission window data is in the first phase of growth (pl) During this growth phase, the size of the data transmission window increases according to a law of variation exponen growth coefficient a. The growth coefficient a varies in a range [amin, amax]. For each new window a is multiplied by 2. When data is lost, i.e. when no acknowledgment from the receiver terminal T2 is received by the TCP layer, the growth coefficient a is divided 2. In a particular embodiment, amin is 4 and arna is 32. The transition between the first growth phase (pi and the second growth phase (fold occurs when the size F of the emission window of The first threshold corresponds to the parameter representative of a congestion state of the MAC layer S. When the threshold S 'is exceeded, the size F of the data transmission window increases according to the law. The second law of variation is a law exponent of a coeffciency of -corcance equal to 2. In order to be able to distinguish this second phase of exponential growth from the first phase. rite always be strict ur to 2.

  The transition between the second growth phase (pH and the third growth phase) rises when the size F of the data transmission window reaches a second threshold.This second threshold corresponds to the parameter representative of the bandwidth available on the second phase of growth. the network S.

  When the threshold S is exceeded, the size F of the data transmission window increases according to the law of variation of the third phase (pm of growth) This law of variation is a linear law The calculation of the parameter S is a function of the bandwidth available on a channel of the network, a channel being a path between the transmitting terminal TI and the receiving terminal T2, the parameter S representing the maximum number of bytes that a channel can carry at the instant t. S parameter corresponds to step E3 of Figure 7. When the parameter representative of the available bandwidth on the network S is too large compared to the volume of data in bytes that can transmit the channel, a large part thereof If the parameter S is too small compared to the bandwidth of the channel, the second phase of growth (pH of the size F of the data transmission window starts too early. TI puts, then, a long period of time before filling the available bandwidth.

  This duration is even greater than the round-trip delay RTT between the transmitting terminal TI and the receiving terminal T2 is large. The parameter S is given by the equation EQ6: EQ6). In this equation, D (t) cones.Dond to the kitch of the curve and 'corresponds to the key a, er-return connectedior Te the transmitter terminal TI and the receiver T2 receiver at time t. moment tn. split _ emiss donation is equal to n.

  At a time tm, the sequence number of the same data transmission window is equal to m. At time tm, the rate of the connection between the transmitting terminal TI and the receiving terminal T2 is equal to: D (tm) = (mnn) / (tm ùtn) (EQ8). At each RTT, a value of the parameter S (t) is obtained according to equation (EQ9): S (tm) = D (tm) x rite (tm) (EQ9) In equation EQ9, if one chooses a minimum value of RTT, data loss will be minimized. The equation EQ9 is then written: S (tm) = D (tm) x rttmin (tm) (EQ10) The value of S (t) is updated every pxRTT, p being an even number chosen in the interval [ Praia, Pmax]. In a particular embodiment, purine is 1 and Pmax is 8.

  The parameter is then S (t, p) = 1 / px (Ep D (tp) * rttrnin (tp)} (EQ11) The choice of p is a function of a global congestion state of the network: if data is lost, the value of p is immediately multiplied by 2. When all the acknowledgments corresponding to the data sent in the same transmission window are received, the value of p is divided by 2. This makes it possible to maintain the reactivity of the mechanism. The parameter S is a recurrent phenomenon which is a function of a state of global congestion of the network, the processes of the parameters S 'and S being asynchronous and independent of one another. field fire parameter -nonse to the MAC e transport layer This parameter may be unchanged from the receipt of the previous acknowledgment In order to maintain interoperability between earlier versions of the transport protocols used in some terminals and the invention , the parameter S '(t) must be less than or equal to the parameter S (t). This relation must be verified whatever the moment t. Thus, upon receipt of each new acknowledgment, the parameter S 'is compared with the parameter S. This corresponds to the step E4 of FIG. 7. If the parameter S' is greater than the parameter S then, the parameter S is replaced. by the parameter S according to the following equation: S '(t) = min (S' (t), S (t)). When parameter S 'is equal to parameter S, the second growth phase (pH is suppressed, which means that there are no congestion on the network.

  FIG. 6 represents the algorithm for determining the growth phase followed by the size F of a data transmission window. The execution of this algorithm corresponds to step E5 of FIG. 7. During a step E1, an acknowledgment is received by the transmitting terminal T1 from the receiving terminal T2.

  During a step E2, the size F of the transmission window tk_1 is compared with the parameter S '. If the size F of the transmission window is smaller than the parameter S ', the step E20 is executed. The size F of the transmission window tk is equal to F (t) + (a + 1). This corresponds to the pre-growth phase (pl.sub.i: ifthe F of the emission window e.sub.e) Srameter S ', step E3 is executed. We then compare the ', a Titi F of the fan. If the size F of the task window t, .1 is smaller than the parameter S, a 0 is executed. Therefore, the window of em is equal to FC corresponding to two Issanc-If the size F of the transmission window is greater than the parameter S, step E31 is executed. The size F of the transmission window tk is worth then F tk_I) + I / F (tk_I). This corresponds to the third growth phase (pH ,.

Claims (12)

  A method for regulating the data transmission rate in a terminal connected to a communication network, implementing a first regulation of the data rate at the transport layer of the terminal as a function of a global congestion state of the terminal. communication network; and a second data rate regulation at the data link layer of the terminal according to a congestion state of said data link layer; characterized in that the method comprises at least one step of determining at least one parameter representative of a congestion state of the data link layer of the terminal, and in that said first regulation of the data rate at said transport layer takes into account said parameter representative of a congestion state of the data link layer.   The method for regulating the data transmission rate according to claim 1, wherein the first regulation is based on a variation of the size of a data transmission window, according to two distinct growth phases comprising a first phase at during which the size of the data transmission window increases according to a first law of exponential variation, and a second phase during which the size of the data transmission window increases according to a law of linear variation, characterized in what is introduced, when e_, a-ameter satisfies at least c i.ére I non-congestie -i e-o ssance not sli ee fane e cous céqeele enêde is second oi of vary + ien exponential growth coeecient higher than the race coe of the first ha:   3. Method of regulating the data transmission rate according to claim 2, characterized in that the value of the growth coefficient of the variation law of the third phase is a function of a global congestion state of the network.   4. Method of regulating the data transmission rate according to one of claims 2 to 3 characterized in that the parameter representative of a congestion state of the data link layer corresponds to the maximum amount of bytes that the data link layer can transmit for a given time interval and in that when the size of the data transmission window is smaller than said parameter, the size of the data transmission window follows the second law of exponential variation of the third phase of growth.   5. Method for regulating the data transmission rate according to any one of claims 1 to 4, characterized in that a parameter representative of an available bandwidth on said network is also evaluated, corresponding to a maximum quantity of data. bytes that can carry a channel between said terminal and a receiver of said data, and in that this parameter constitutes a threshold conditioning a passage of the size of the transmission window of said first growth phase, when the size is smaller than said threshold at said second growth phase, when said size is greater than said threshold.   6. A method of regulating the data transmission rate according to one of the preceding claims, characterized in that the parameter representative of a state of stion of the data link layer and or the parameter represents bandwidth available on the network déie `born in a way -éddr-ente,   7. Regeneration of the data transmission rate lo, i the Tracté éue sedaral 1a 'erée létE ns aramÉ i {r of the aieliaison data and / or the representative parameter of the bandwidth available on the network is function of said global congestion state of the communication network.   8. Method for regulating the data transmission rate according to any one of the preceding claims, characterized in that it imposes that the parameter representative of a congestion state of the data link layer is less than or equal to the parameter representative of the bandwidth available on the network.   9. Control method according to any one of claims 1 to 8, characterized in that said terminal is a TCP server, in that said first regulation is a TCP flow control between said server and a TCP client, and in that in that said second regulation is a type 802.3x flow control performed at the MAC layer of said server, between said server and said client or an intermediate equipment of said network connected to said server by a Full Duplex Ethernet link.   A data transmission terminal connected to a communication network, comprising first means for regulating the data rate at the transport layer of said transmission terminal according to a global state of congestion of the communication network, second means for regulating the data rate at the data link layer of said transmission terminal according to a state of congestion of said data link layer, characterized in that it further comprises means determining a parameter representative of a congestion state of the data layer Layer, and in that: esdIls n, e, -s means of egulation L; I have the account of said tentative parameter of a data link state.   A computer program comprising program code instructions for performing the steps of the method according to one of claims 1 to 8 when said program is executed by a processor.   12. A communication system between a server terminal and a client terminal through a communication network, said system also comprising at least one intermediate device located between said client and server terminals, said server terminal comprising first flow control means data at the transport layer of said server terminal, as a function of a global congestion state of the communication network between said server terminal and said client terminal, and second means for regulating the data rate at the link layer of data of said server terminal according to a congestion state of the data link layer between the server terminal and said intermediate equipment characterized in that said server terminal comprises means for determining a parameter representative of a congestion state of said data link layer, and in that said parameter represents A congestion state of the data link layer is taken into account by the first control means of said server terminal.