WO2006018404A1 - Method for controlling data traffic in packet-oriented communication networks - Google Patents

Abstract

The aim of the invention is to control data traffic (DP, DP<sub

Description

description

Method for controlling data traffic in packet-transmission-based communication networks

The invention relates to a method for controlling the data traffic in packet-transmission-based communication networks according to the preamble of patent claim 1.

In connection with the control of data traffic in packet-based communication networks, such as e.g. (i) local area networks according to the standardization family IEEE 802 - the so-called Local Area Networks (LANs), as there are in particular the Ethernet-based local networks according to IEEE 802.3 (...), the Wireless Local Area Networks

(WLANs) according to IEEE 802.11 (...) and derivatives of both Virtual Local Area Networks (VLANs) exploiting LAN switching, (ii) larger area networks, e.g. Wide Area Networks (WANs) and Metropolitan Area Networks (MANs) or

(iii) the global open network consisting of several subnetworks is constantly endeavoring to equip the network with a certain "Quality of Service (QoS)".

"Quality of Service" is generally understood to mean the quality features which a service provider can make available to his service user. With respect to the ISO / OSI communication system of a network, the term "quality of service" indicates the power provided by the communication system for a particular service. Attributes of the "quality of service" are performance with the parameters 'throughput and delay', power fluctuations with the parameters 'jitter, error rates and guarantees', reliability with the parameters 'completeness, uniqueness and order preservation' and security with the parameters 'Confidentiality, Integrity, Authenticity, Commitment and Availability'. In the "Quality of Service", a distinction is made between different types of data (eg "real-time voice", video, Internet, "file transfer", etc.). These are divided into different categories and transmitted according to their importance with different priority over the network medium. This ensures that important data, eg with high demands on delay and jitter, are not blocked or slowed down by unimportant data ,

For the implementation of the "Quality of Service", corresponding data fields are generally provided in the data header (header) of an Internet protocol data unit, an Ethernet protocol data unit or a VLAN protocol data unit. However, these special data fields are in one

Home network rarely supported today. For example, in known computer networks, e.g. a central QoS server is necessary, which, however, should not be present in a home network as soon as possible. As a result, in particular in home networks, a "quality of service" can not be realized.

The problem underlying the invention is to control the data traffic in packet-transmission-based communication networks in such a way that a data type which is in accordance with the quality of service of a communication network over other data types is based on a network-specific QoS mechanism preferably treated, that is, prioritized, will be identified safely and as a result the data with the assigned priority can be transmitted.

This object is achieved on the basis of the method defined in the preamble of claim 1 ge by the features indicated in the characterizing part of claim 1 ge. The idea underlying the invention is that data packets of different types of data for the transmission according to the priority given in the "Quality of Service" have or possess a marking which makes the division of the data packets into categories possible.

This tag preferably consists of a source or destination IP address and / or a source or destination port number. On the basis of these "filter criteria" a network can be configured and a "Quality of Service", especially in one

Home network can be realized without a central QoS server is necessary and without operating systems, Daten¬ sources and data sinks themselves (for example, PC applications or streaming set-top boxes) must support the "Quality of Service". The categorization of the packets may e.g. from the respective network driver at the link layer level (MAC layer).

This results in the advantage that now also in communication systems of networks in which the "quality of service" at the application, transport and network layer level (eg network layer and / or application layer) is not supported the "Quality of Service" can be realized if the layer layer (in particular the MAC layer) of the network has the option of prioritizing

Provides packets (e.g., IEEE 802.11 (e) WLAN networks or appropriately modified Ethernet switches).

If, for example, in a home network in accordance with the IEEE 802.11 (e) standard, "video sharing" is also to be transmitted over the network, and both transmissions work according to the "best effort" guarantee stage without "quality of service", it may happen that the Video transmission is disturbed by "file transfers". With the proposed measures it is now possible, based on the knowledge of the data paths (video runs from IP address IP _x with port number P _x to IP address IPy and port number P _y ) the data path IP _X / P _X <-> IP prioritize _y / P _y for video. Now, make sure that the Video data are primarily transported relative to the other data.

Additional advantageous developments of the invention are specified in the following description of an embodiment of the invention and in the dependent claims.

The embodiment of the invention will be explained with reference to FIGS. 1 a to 1 c, 2, 3, 4 a and 4 b, 5 a to 5 c and 6 a to 6 d.

FIG. 1a a communication network in which the transmission of data packets of different types of data between network nodes is controlled in the sense of a QoS mechanism for prioritizing the data transmission;

FIGURE 1b is a communication network table corresponding to the communication network in FIGURE 1a;

FIG. 1c shows a priority assignment table for the communication network shown in FIG. 1a,

FIG. 2 shows the sequence of a prioritized data transmission between two network nodes in the communication network according to FIG.

FIG. 3 shows the autoconfiguration of the communication network according to FIG. 1a with respect to the priority allocation table;

FIG. 4a shows a communication network in which the transmission of video data packets between network nodes is controlled by the Media ™ player by Microsoft,

FIG. 4b shows a priority allocation table for a network node of the communication network illustrated in FIG. 4a, FIG. 5a shows a communication network in which the transmission of video data packets between two network nodes forming a "client-server" architecture is prioritized,

FIG. 5b shows a priority assignment table for the network node designed as a "client" of the communication network shown in FIG. 5a, FIG.

FIG. 5c shows a priority allocation table for the network node of the communication network illustrated in FIG. 5a as a "server";

FIG. 6 a shows a communication network modified in FIG. 5 a in which the transmission of video data packets between two network nodes forming a "client-server architecture" takes place via an intermediate node designed as an "access point" and is controlled in a prioritized manner;

FIG. 6b shows a priority assignment table for the as

"Client" trained network node of the communication network shown in FIGURE 6a,

FIG. 6c shows a priority allocation table for the intermediate node formed as "access point" of the communication network illustrated in FIG. 6a, FIG.

FIG. 6d shows a priority assignment table for the network node formed as "server" of the communication network illustrated in FIG. 6a.

FIG. 1a shows a preferably called "Local Area Network (LAN)" with wireless communication according to the 802.11 technology (IEEE 802.11 standard) or with wireline communication according to what is referred to as "ETHERNET"

802.3 technology (IEEE 802.3 standard) trained, based on the TCP / IP protocol (Stw.: Internet), a ring topology having communication network KNW, in which the Transmission of data packets DP _A , DP _B , DP _C , DP _D unterschiedli¬ cher data type between preferably designed as a personal computer network nodes PCl, PC2, PC3 in terms of a QoS mechanism for prioritizing the data transmission is controlled. According to the above-mentioned type of communication network KNW ["Wireless Local Area Network (WLAN)" or "ETHERNET"], a network connection PCl, PC2, PC3 that forms the communication network KNW entwe¬ preferably a first connection Vl designed for wireless communication for wireless communication or a second connection V2, preferably designed as a line connection, for wired communication.

So that the data packet DP _A , DP _B , DP _C , DP _D sent by a first network node PC 1, PC 2, PC 3 can also be delivered and received by a second network node PC 2 / PC 3, PC 1 / PC 3, PC 1 / PC 2, the individual network nodes PCl, PC2, PC3 of the communication network KNW on a single personal computer in the communication network KNW uniquely identifying delivery address, because of in the

Communication network KNW TCP / IP protocol used an Internet Protocol (IP) address IP _A , IP _B , IP _C is. Thus, a first personal computer PC1 designed as a network node has a first IP address IP _A , and a second personal computer PC2 designed as a network node has a second one

IP address IP _B and formed as a network node ter third personal computer PC3 a third IP address IP _C.

In the example shown in FIGURE Ia communication network KNW V2 via the connecting Vl from the first personal computer PCl to the third personal computer PC3, both in the downward direction ABWR as well as in the upward direction AUWR a first data packet DP _A to from the first personal computer PCl the second personal computer PC2 again in both the DOWN direction ABWR and in the upward direction AUWR a second data packet DP _B and from the second personal computer PC2 to the third personal computer PC3 again both in the downward direction ABWR and in the upward direction AUWR transmit a third data packet DP _C and a fourth data packet DP _D. The four data packets DP _A , DP _B , DP _C , DP _D , which are formed as protocol data units and handled independently of one another between network nodes PC1, PC2, PC3, form the data traffic of the communication network KNW and usually have three data fields , a data packet header DPVS, a packet packet trailer DPNS and a packet data payload DPNL. While in the payload data field DPNL only user data of the data packet is transmitted, control information is contained in the header data field DPVS and in the trailer data field DPNS. Alternatively, however, said control information may also be included in the payload data field DPNL.

In particular in the header data field DPVS of the data packet DP _A , DP _B , DP _C , DP _D , the IP address IP _A , IP _{B /} are part of the control information for unambiguously identifying the network node PC1, PC2, PC3 contained in the communication network KNW. IP _C and as an addition to the IP address indicating the activation of an application in the network node PCl, PC2, PC3 of the communication network KNW port number P _A , P _{B /} P _C ~ a first port number P _A , a second port number P _B and a third port number P _c - included.

In the present embodiment, the IP address IP _A , IP _{B /} IP _C and the port number P _A , P _B , P c are preferably included in the header data field DPVS. However, it is equally possible for the information mentioned to be contained in the trailer data field DPNS instead of in the header data field DPVS or to be contained in both the header data field DPVS and in the trailer data field DPNS.

Thus, in the transmitted in the downward direction ABWR from the first personal computer PCl with the IP address IP _A to the third personal computer PC3 with the IP address IP _C first data packet DP _A in the header data field DPVS as a destination IP address Z-IP the third IP address IP _C and in addition to activating the application on the personal computer PCl, PC3 as the destination port number Z port, the second port number P _B , while in the upstream in the uplink AUWR transmitted first data packet DP _A in the header data field DPVS the first IP address IP _A as the destination IP Address Z-IP and, in addition to activating the application on the personal computer PC1, PC3, the port number P _{B is} contained as the source port number Q port. By the destination port number Z-port and the source port number Q-port, the start or end point of the logical protocol connection between the first personal computer PCl implementing the TCP / IP protocol and the third personal computer PC3 is identified ,

In the second data packet DP _B transmitted in the downward direction ABWR from the first personal computer PC1 with the IP address IP _A to the second personal computer PC2 with the IP address IP _B , the second IP address IP is in the header data field DPVS _B as the destination IP address Z-IP and in addition to activating the application on the personal computer PCl, PC2 include the third port number P _c as the destination port number Z-port, while in the uplink AUWR über¬ second data packet DP _B in the header data field DPVS the first IP address IP _A as the destination IP address Z-IP and zu¬ additionally to activate the application on the personal computer PCl, PC2 the third port number P _{c are included} as the source port number Q port. By the destination port number Z-port and the source port number Q-port is again the beginning or end point of the logical protocol connection zwi¬ tween the TCP / IP protocol implementing the first personal computer PCl and the second personal computer PC2 identified.

In the third data packet DP _C transmitted in the downlink direction ABWR from the third personal computer PC3 having the IP address IP _C to the second personal computer PC2 having the IP address IP _B , the second IP address IP is in the header data field DPVS _B as the destination IP address Z-IP and, in addition to activating the application on the personal computer PC2, PC3, the second port number P _B as the destination port number Z-port while in the uplink AUWR transmitted third data packet DP _C in the header data field DPVS the third IP address IP _C as the destination IP address Z-IP and in addition to the activation of the application on the personal computer PC2, PC3 the second port number P _{B is included} as the source port number Q port. By the destination port number Z-port and the source port number Q-port is again the beginning or end point of the logical protocol connection zwi¬ tween the TCP / IP protocol implementing second personal computer PC2 and the third personal computer PC3 identifi¬ ed.

In the fourth data packet DP _D transmitted in the downlink direction ABWR from the third personal computer PC3 with the IP address IP _C to the second personal computer PC2 with the IP address IP _B , the second IP address IP is in the header data field DPVS _B as the destination IP address Z-IP and in addition to activating the application on the personal computer PC2, PC3 include the first port number P _A as the destination port number Z-port, while in the uplink AUWR transmit fourth data packet DP _D in the header data field DPVS the third IP address IP _C as the destination IP address Z-IP and in addition to activating the application on the personal computer PC2, PC3, the first port number P _A as the Source port number Q port are included. By the destination port number Z-port and the source port number Q-port is again the beginning or end point of the logical protocol connection zwi¬ tween the TCP / IP protocol implementing second personal computer PC2 and the third personal computer PC3 identified.

FIGURE Ib shows a communication network table KNWT corresponding to the communication network KNW in FIGURE 1a. In this communication network table KNWT, it is first indicated to what kind of data DA the four data packets DP _A , DP _B , DP _C , DP _D to be transmitted in the communications network KNW belong in each case. After that, the first data packet DP _A and the third data packet DP _C belong to a first one Data type "video", the second data packet DP _B to a second data type "language" and the fourth data packet DP _D to a third data type "file transfer".

In addition, it is indicated which of a category KG and which of the port numbers P _A , P _B used in the communication network KNW of FIG. 1 a as the destination port number Z port and the source port number Q port, Pc is associated with the aforementioned data types DA. According to this, the first data type "video" is the category "2" and the port number is P _B , the second data type "language" is the category "3" and the port number P _c and the third data type "file transfer" are the category "1" and the port number P _A assigned.

FIG. 1c shows a priority allocation table PZT 'for the communication network KNW shown in FIG. In this priority assignment table PZT 'is for each Netz¬ work node PCl, PC2, PC3 another, designated as a sub-table priority assignment table PZT included whose destination IP address Z-IP, source port number Q-port and destination Port number Z port, category KG and transmission priority ÜP subdivided table values, taking into account in the communication network KNW in the FIGURE Ia between the network nodes PCl, PC2, PC3 data packets to be transmitted DP _A , DP _B , DP _C , DP _D and the Communication network table KNWT in FIGURE Ib, assuming that the largest value of the category KG (eg category value "3") is assigned a highest priority value of the transmission priority ÜP (eg transmission priority value "1") and vice versa, as well as due to The fact that provided default values of the destination IP address Z-IP and the source port number / destination port number Q port, Z port respectively the smallest category value (eg Katego¬ ri e value "1") with the lowest transmission priority (eg transmission priority value "3"), as shown.

The network node-specific priority assignment table PZT contains for the respective network node PC1, PC2, PC3 Control information, based on which the network node PCl, PC2, PC3, the division of the data packets DP _A , DP _B , DP _C , DP _D in the categories KG makes each with different Übertragungs¬ priority ÜP and thus the communication network KNW in terms of a "Quality of Service "is configured. In this case, the respective data packet DP _A , DP _B , DP _C , DP _D assigned a label that allows the respective network node PCl, PC2, PC3, the data packet to be transmitted DP _A , DP _B , DP _C , DP _D with a for to give priority to the quality of service. For the communication scenario described with reference to FIGS. 1 a, 1 b and 1 c, the marking or control information consists of the source port number Q port and / or the destination port number Z port.

In this way, the data traffic in packet-transmission-based communication networks, such as the communication network KNW in FIG. 1 a, can be controlled such that a data type which, according to the "Quality of Service" of the communication network KNW, can be compared to other types of data the base of a network-specific QoS mechanism is preferably treated, ie prioritized, is to be, is securely identified and, as a result, data packets belonging to the respective data type can be transmitted with the assigned priority.

FIG. 2 shows the sequence of a prioritized data transmission between two network nodes, a first network node PC1, PC2, PC3 and a second network node PC2 / PC3, PC1 / PC3, PC1 / PC2, of the communication network KNW shown in FIG the connection Vl, V2 are interconnected. The first network node PC1, PC2, PC3 and the second network node PC2 / PC3, PC1 / PC3, PC1 / PC2, which are each again preferably designed as personal computers, each have a user interface BSS, a central control unit ZSTE with "QoS" , a transceiver SEM and a memory SP with the priority assignment table PZT. The named components of the respective network node form a common functional unit for the data transmission sequence described below and are in this regard, although not shown in FIGURE 2, connected together accordingly.

The sequence of data transmission begins with the fact that the user of the first network node PC1, PC2, PC3 creates a data packet DP _{x of} any data type and this data packet DP _{x is} transmitted from the user interface BSS to the central control unit ZSTE. In the central control unit ZSTE the data packet DP _{x is} the source IP address Q-IP, the destination IP address Z-IP, the source port number Q-port and / or the destination port number Z- Port assigned. After that, the central control unit ZSTE accesses the memory SP and reads from the priority assignment table PZT stored therein with respect to the source IP address Q-IP, the destination IP address Z-IP, the source Port number Q port and / or the destination port number Z port one to the source IP address Q IP, destination IP address Z IP, source port number Q port and / or target port number Z port corresponding category value '"of the category KG and transmission priority throw'Z" of the transmission priority ÜP. Based on the read

Values is then sent the data packet DP _x with the transmission gungsrioritäf'Z "ÜP via the transceiver SEM of the first network node PCl, PC2, PC3 to the transceiver of the zwei¬ th network node PC2 / PC3, PC1 / PC3, PC1 / PC2.

In the second network node PC2 / PC3, PC1 / PC3, PC1 / PC2, the transmitted data packet DP _{x is transferred} from the transceiver SEM via the central control unit ZSTE to the user interface BSS. As an optional measure, the user of the second network node PC2 / PC3, PC1 / PC3,

PC1 / PC2 confirm the received data packet DP _x or the second network node PC2 / PC3, PC1 / PC3, PC1 / PC2 automatically confirm the reception. In both cases, an acknowledgment information BSI is generated and transmitted from the user interface BSS to the central control unit ZSTE. In the central control unit ZSTE the confirmation information BSI is the source IP address Q-IP, the destination IP address Z-IP, the source port number Q-port and / or the destination port Assigned number Z-port. After that, the central control unit ZSTE accesses the memory SP and reads from the priority assignment table PZT stored therein with reference to the source IP address Q-IP, the destination IP address Z-IP, the source port number Q-port and / or the destination port number Z-port to the source IP address Q-IP, destination IP address Z-IP, source port number Q-port and / or destination port Number Z-port corresponding category value '"of the category KG and - transfer priority throw'Z" of the transmission priority ÜP. On the basis of the read-out values, the confirmation information BSI with the transmission priority "ÜP is then sent via the transceiver SEM of the second network node PC2 / PC3, PC1 / PC3, PC1 / PC2 to the transceiver of the first network node PC1, PC2, PC3 The first network node PC1, PC2, PC3 transmits the transmitted acknowledgment information BSI from the transceiver SEM via the central control unit ZSTE to the user interface BSS.

FIG. 3 shows the sequence of an autoconfiguration of the communication network KNW according to FIG. 1 a with regard to the priority allocation table PZT. The communication network KNW again has the three network nodes PC1, PC2, PC3, preferably designed as personal computers, which are interconnected via the connection V1, V2 in the manner shown. The mentioned network nodes PC1, PC2, PC3 each have a user interface BSS, a central control unit ZSTE with "QoS", a transceiver SEM and a memory SP with the priority allocation table PZT. The said components of the respective network node form a common functional unit for the autoconfiguration process described below and are accordingly connected, although not shown in FIG. 3, correspondingly to one another. Of the user interfaces BSS of the network nodes PC1, PC2, PC3, only the user interface BSS of the network node PC1 is shown in FIG. 3, while the representation of the other user interfaces BSS is lacking due to lack of space and space Meaning has been omitted in connection with the autoconfiguration process.

The sequence of the autoconfiguration begins with the operator of the communication network KNW and / or the user of the network node PC1 making changes to the priority assignment table PZT stored in the memory SP. By "changing" the priority allocation table PZT, besides the modification of an already existing priority allocation table PZT, its initial creation is to be understood as well. This in turn means that the operator / user of the communication network KNW or of the network node PC1, PC2, PC3 generates the priority allocation table PZT. Alternatively, however, it is also possible for the priority allocation table PZT to be generated by the manufacturer of the network node PC1, PC2, PC3.

The changed priority assignment table PZT is then transmitted from the user interface BSS to the central control unit ZSTE. The central control unit ZSTE transfers the priority allocation table PZT to the memory SP, where it is then stored. Subsequently, the central control unit ZSTE accesses the memory SP, reads out the changed priority assignment table PZT and transmits the changed priority assignment table PZT by incorporating it in a broadcast message via the transceiver SEM to the other transceivers of the other network nodes PC2, PC3 of the communication network KNW. Of the other network nodes PC2, PC3 of the communication network KNW, the changed priority assignment table PZT received by the network node PC1 is forwarded to the respective central control unit ZSTE and incorporated by it into the optionally present priority assignment table PZT or for the creation taken into account its own priority assignment table PZT and then ab¬ in both cases in the respective memory SP. FIG. 4a shows, starting from the communication network KNW shown in FIG. 1a and described in this respect, with the network nodes PC1, PC2, PC3, which are preferably again configured as personal computers, as in the communication network KNW, the transmission of video data packets DP _V over the connections Vl, V2 between the personal computers PCl, PC2, PC3 with the respectively reassigned IP addresses

TM

IP _A , IP _{B /} IP _{C is} controlled prioritized via a media player from Microsoft with the assigned port number "1755", because it can not be determined, although it would be desirable, between which two personal computers belonging to the communication network KNW Personal Computer PCl, PC2, PC3 the transmission of the video data packets DP _V statt¬ find.

From the first personal computer PC1 to the second personal computer PC2 and to the third personal computer PC3 and from the second personal computer PC2 to the third personal computer PC3 in both the downlink ABWR and the uplink AUWR, the video data packet is transmitted through the links V1, V2 Transmit DP _V. The video data packets DP _V transmitted as a whole form the data traffic of the communication network KNW and in each case again have the three data fields, the data packet header DPVS, the data packet trailer DPNS and the data packet payload DPNL. While in the payload data field DPNL only payload data of the video data packet is transmitted, control information is contained in the header data field DPVS and in the trailer data field DPNS. Alternatively, the said control information can also be included again in the payload data field DPNL.

In particular in the header data field DPVS of the video data packet DPv, the component that contains the

TM Activation of the media player from Microsoft in the network node

PCl, PC2, PC3 of the communication network KNW indicating port number "1755". In the present embodiment, the port number "1755" is included in the header data field DPVS. However, it is equally possible that said information is either contained in the trailer data field DPNS instead of in the header data field DPVS or is contained in both the header data field DPVS and the trailer data field DPNS.

For the scenario shown in FIG. 4a, in the video data packet DP _V transmitted in the downward direction ABWR between the personal computers PC1, PC2, PC3, the value "0" in the header data field DPVS is the target IP address Z-IP and Source IP address Q-IP and in addition to the activation of the

TM

Media player from Microsoft on the personal computer PCl, PC2, PC3 include the port number "1755" as the destination port number Z port, while in the uplink AUWR between the personal computers PCl, PC2, PC3 transmitted video data packet DP _V in the header data field DPVS again the value "0" as the destination IP address Z-IP and source IP address Q-IP and in addition to the activation of the media player of

TM

Microsoft on the personal computer PCl, PC2, PC3 the port

Number "1755" as the source port number Q-Port are included. By the destination port number Z-port and the source port number Q-port is again the beginning or end of the logical protocol connection between the TCP / IP protocol implementing personal computers PCl, PC2, PC3 identified.

FIG. 4b shows a priority allocation table PZT which is valid or authoritative for all network nodes PC1, PC2, PC3 of the communication network KNW shown in FIG. 4a, de sources for source IP address Q-IP, destination IP address Z-IP, source Port number Q port, destination port number Z port, category KG and transmission priority U P are subdivided below the video data packets to be transmitted in the communication network KNW in FIG. 4 A between the network nodes PC 1, PC 2, PC 3 DP _V , the category value "2" for the category KG and that according to the table in the FIGURE Ic corresponding transmission priority value "2" the transmission priority ÜP as shown result.

The network-node-specific priority assignment table PZT contains for the respective network node PCl, PC2, PC3 control information, on the basis of the network node PCl, PC2, PC3 the division of the video data packets DP _V in the Kate¬ gory KG ty with corresponding thereto Übertragungspriori¬ ÜP makes and thus the Communication network KNW is configured in terms of a "Quality of Service". In this case, the video data packet DP _{V is} assigned a mark which enables the respective network node PC1, PC2, PC3 to transmit the video data packet DP _V to be transmitted with a priority corresponding to the "Quality of Service". The marking or control information exists for the communication scenario described with reference to FIGS. 4a and 4b from the source port number Q-port and / or the destination port number Z-port with the port number "1755". ,

In this way, the data traffic in packet-transmission-based communication networks, such as the communication network KNW in FIGURE 4a, can be controlled so that the video TM data transmission via the media player from Microsoft, according to the "Quality of Service" of the communication network KNW compared to other types of data on the basis of a network-specific QoS mechanism preferably treated, that is, prioritized, should be, is securely identified and as a result video data packets can be transmitted with the assigned priority.

FIG. 5 a shows, starting from the communication network KNW shown in FIG. 1 a and with the network nodes PC 1, PC 2, PC 3 again preferably configured as personal computers, as in the communication network KNW, the transmission of video data packets DP ' _V via the Connections V1, V2 between the "client-server architecture" forming personal computers PCl, PC2 with the respectively reassigned IP addresses IP _A , IP _B priori- is controlled, wherein the first personal computer PCl acts as a "client" and the second personal computer PC2 is the "server". The personal computer PC1 is to receive the video data by means of file transfer and requests the video data via the port number "139" at the second personal computer PC2.

Via the links V1, V2, from the first personal computer PC1 to the second personal computer PC2, both in the downlink ABWR and in the uplink AUWR, the

Video data packet DP ' _V transferred. The video data packet DP'v transmitted thereby forms the data traffic of the communication network KNW and again has the three data fields, the data packet header DPVS, the data packet trailer DPNS and the data packet payload DPNL. While in the payload data field

DPNL are transmitted exclusively payload data of the video data packet, control information is contained in the header data field DPVS and in the Nachspanndatenfeld DPNS. Alter¬ natively, however, the said control information can also be included again in the payload data field DPNL.

In particular, in the header data field DPVS of Videodatenpa¬ Ketes DP'v are contained as part of the control information to uniquely identify the kit in the Kommunikationsnetzwer- KNW network node PCl, PC2 the IP address of IP _A, IP _B, and as an additive to the IP address which the Activation of the file transfer in the network node PCl, PC2 of the kommunika¬ tion network KNW-containing port number "139" included.

In the present embodiment, the IP address IP _A , IP _B and the port number "139" are preferably contained in the Vor¬ spandatenfeld DPVS. However, it is equally possible for the information mentioned to be contained in the trailer data field DPNS instead of in the bias voltage data field DPVS or to be contained in the bias data field DPVS as well as in the trailer data field DPNS. For the scenario illustrated in FIG. 5a, in the video data packet DP ' _V transmitted in the downward direction ABWR between the personal computers PC1, PC2 in the header data field DPVS, the second IP address IP _B is the destination IP address Z-IP and in addition to the activation of the file transfer on the personal computer PCl, PC2 include the port number "139" as the destination port number Z port, while in the upward direction AUWR between the personal computers PCl, PC2 transmitted video data packet DP ' _V in the header data field DPVS the first IP address IP _A as the destination IP address Z-IP and in addition to activating the file transfer on the personal computer PCl, PC2 the port number "139" as the Source port number Q port are included. By the destination port number Z-port and the source port number Q-port is in each case again the beginning or end point of the logical Protokollver¬ connection between the TCP / IP protocol implementing Perso¬ nal computers PCl, PC2 identified.

FIGURES 5b and 5c respectively show a network node PC1 (first personal computer) configured as a "client" with respect to FIG. 5b, or FIG. 5b for the network node PC2 (second personal computer) configured as a "server" of FIG. 5a represented valid Kommunikationsnetz network KNW valid or authoritative priority assignment table PZT, their respective source IP address Q-IP, destination IP address Z-IP, source port number Q-port, destination port number Z. -Port, category KG and transmission priority ÜP subdivided table values, taking into account in the communication network KNW in the FIGURE 5a between the network node PCl, PC2 to be transmitted video data packets DP'v, the category value "2" for the category KG and the according to Table in the FIGURE Ic corresponding transmission transfer priority value "2" of the transmission priority ÜP as shown result.

The network node-specific priority assignment tables PZT contain control information for the respective network node PC1, PC2, on the basis of which the network node PC1, PC2 the division of the video data packets DP ' _V in the category KG vor¬ takes vor¬ with the corresponding transmission priority ÜP and thus the communication network KNW is configured in the sense of a "Quality of Service". In this case, the video data packet DP 'is _V assigned a label which allows the jewei¬ intelligent network node PCl, PC2, the transmitted video data packet DP' to transmit _V with an appropriate for the "Quality of Service" priority. The marking or control information for the communication scenario described with reference to FIGS. 5a, 5b and 5c consists of the destination port number Z-port with the port number "139" and the destination IP address Z-IP with the second IP Address IP _B for the first personal computer PCl or from the source port number Q-port with the port number "139" and the destination IP address Z-IP with the first IP address IP _A for the second personal computer PC2.

In this way, the data traffic in packet-transmission-based communication networks, such as the communication network KNW in FIGURE 5a, can be controlled such that the video data file transfer, which is in accordance with the "quality of service" of the communication network KNW, compared to others Data types are preferably treated on the basis of a network-specific QoS mechanism, that is to say they should be prioritized, that they should be securely identified and, as a result, video data packets with the assigned priority can be transmitted.

FIG. 6a shows, starting from the communication network KNW shown in FIG. 5a and described in this respect, a modified communication network KNW 'with the network nodes PC1, PC2, PC3, which are preferably again designed as personal computers, and an intermediate node embodied as an "access point" AP and, as in this modified communication network KNW ', the transmission of video data packets DP " _V via the connections _V 1, _V 2 between the personal computers PC 1, PC 2 again forming the" client-server architecture "with the respectively assigned IP addresses IP _A , IP _B with intermediate node AP interposed therebetween. is controlled, wherein the first personal computer PCl acts as a "client" and the second personal computer PC2 is the "server". The personal computer PC1 is to receive the video data by means of file transfer via the intermediate node AP and requests via the intermediate node AP the video data via the port number "139" at the second personal computer PC2.

Via the connections V 1, V 2, both the first personal computer PC 1 to the intermediate node AP and from the intermediate node AP to the second personal computer PC 2 in downward direction ABWR and from the second personal computer PC 2 to the intermediate node AP and "transfer _V. the case total transferred genes video data packets DP" from the intermediate node AP to the first personal computer PCl upward AUWR the video data packet DP _V is the traffic of there are suitable munikationsnetzwerkes KNW 'and each again the three data fields on the Data packet header DPVS, the data packet trailer DPNS and the data packet payload DPNL. While in the payload data field DPNL only payload data of the video data packet are again transmitted, control information is again contained in the bias voltage field DPVS and in the trailer voltage field DPNS. Alternatively, however, the mentioned control information can also be contained again in the payload data field DPNL.

In particular in the header data field DPVS of the video data packet DP " _V , the IP address IP _A , IP _B and, as a supplement to the IP address, are part of the control information for uniquely identifying the network node PC1, PC2 contained in the communication network KNW the activation of the file transfer in the network node PCl, PC2 of the communication network KNW-containing port number "139" included.

In the present exemplary embodiment, the IP address IP _{A /} IP _B and the port number "139" are preferably contained in the bias data field DPVS. However, it is equally possible for the information mentioned to be contained in the trailer data field DPNS instead of in the bias voltage field DPVS are included in both the header data field DPVS and the trailer DPNS.

For the scenario illustrated in FIG. 6a, the video data packet DP " _V " transmitted in the downlink direction ABWR between the first personal computer PC1 and the intermediate node AP in the header data field DPVS is the second IP address IP _B as the destination IP Address Z-IP and in addition to activating the file transfer on the personal computer PC1, PC2, the port number "139" as the destination port number Z-port and between the intermediate node AP and the second staff Computer PC2 transmitted video data packet DP " _V in the Vorspanndaten¬ field DPVS the second IP address IP _B as the destination IP address Z-IP, the first IP address IP _A as the source IP address Q-IP and in addition to activate the file transfer on the

Personal Computer PCl, PC2 include the port number "139" as the destination port number Z-port, while in the uplink in the direction AUWR between the second personal computer PCl and the intermediate node AP transmitted video data DP " _V in the Header data field DPVS the first IP address IP _A as the

Destination IP address Z-IP and, in addition to activating the file transfer on the personal computer PC1, PC2, the port number "139" as the source port number Q-port and between the intermediate node AP and the first personal computer PCl transmitted video data packet DP " _V in the header data field DPVS the first IP address IP _A as the destination IP address Z-IP, the second IP address IPB _A as the source IP address Q-IP and zu¬ In addition to the activation of the file transfer on the personal computer PC1, PC2, the port number "139" is contained as the source port number Q-Port.

Port and the source port number Q-port is again the beginning or end point of the logical protocol connection zwi¬ tween the TCP / IP protocol implementing personal computers PCl, PC2 identified.

FIGURES 6b, 6c and 6d respectively show a network node PC1 (first personal computer) designed as a "client" with respect to FIG. 6b, or with reference to FIG. 6c for FIG the configured as "server" network node PC2 (second personal computer) or with respect to the FIGURE 6d for the configured as an "access point" intermediate node AP of the communication network KNW shown in FIG 6a valid or authoritative priority allocation table PZT, their jewei¬ time after source IP address Q-IP, destination IP address Z-IP, source port number Q-port, destination port number Z-port, category KG and transmission priority UP subdivided table values taking into account in the communication network KNW in the FIGURE 6a between the network node PCl and the intermediate node AP and between the intermediate node AP and the network node PC2 to be transmitted video data packets DP " _V , the category value" 2 "for the category KG and according to the table in the figure Ic corresponding thereto - transfer priority value "2" of the transmission priority ÜP as shown.

The network node-specific priority assignment tables PZT contain control information for the respective network node PC1, PC2 and the intermediate node AP, on the basis of which the network node PC1, PC2 and the intermediate node AP carry out the division of the video data packets DP " _V into the category KG with the transmission priority ÜP corresponding thereto The communication network KNW is configured in the sense of a "quality of service." In this case, the video data packet DP " _{V is} assigned a marking which enables the respective network node PC1, PC2 and the intermediate node AP to receive the video data packet DP to be transmitted " _V with a priority corresponding to the" Quality of Service. "The marking or control information for the communication scenario described with reference to FIGURES 6a, 6b, 6c and 6d consists of the destination port number Z port with the port Number "139" and the destination IP address Z-IP with the second IP address IP _B for the first personal computer PCl or from the source port number Q port with the port number

"139" and the destination IP address Z-IP with the first IP address IP _A for the second personal computer PC2 or from the destination port number Z port with the port number "139", the source -Port- Number Q-Port with the port number "139", the destination IP address Z-IP with the IP address IP _B , IP _A and the source IP address Q-IP with the IP address IP _A , IP _B for the intermediate node AP.

In this way, the data traffic in packet-transmission-based communication networks, such as the communication network KNW in FIG. 6a, can be controlled so that the video data file transfer, which is in accordance with the "quality of service" of the communication network KNW, compared to others Data types on the basis of a network-specific QoS mechanism be¬ preferred treated, that is, prioritized, should be, safe - is identified and as a result, video data packets can be transmitted with the assigned priority.

Claims

Claims / Patent Claims

1. A method for controlling data traffic in paketübertra- supply based communication networks, in which a) data packets (DP, DP _A, DP _B, DP _C, DP _D, DP _V, DP _'V, DP _"V. DP _x) each formed as a protocol data unit and independently of each other are to be transmitted from a first network node (PCl, PC2, PC3) to a second network node (PC2 / PC3, PC1 / PC3, PC1 / PC2), each in a data packet header (DPVS) and / or a data package trailer

(DPNS) a source address (Q-IP) and a destination address (Z-IP) and / or a source port number (Q-port) and a destination port number (Z-port) is assigned, b) data types (DA), to which belonging to transmitting data packets (DP, DP _a, DP _B, DP _C, DP _D, DP _V, DP _'V, DP _"V. DP _X), according to a QoS mechanism to prioritize data transmission in the communication network (KNW, KNW) are divided into categories (KG) with respectively different transmission priorities (ÜP), characterized in that the data packet (DP, DP _A , DP _B , DP _C , DP _D , DP _V , DP ' _V , DP " _V DP _x ) of the transmission priority category (ÜP, KG) on the basis of the source address (Q-IP), the destination address (Z-IP), the source port number (Q-port) and / or the destination port number (Z-port) assigned becomes.

2. The method according to claim 1, characterized in that for the network node (PCl, PC2, PC3) on the basis of the source address (Q-IP), the destination address (Z-IP), the source port number (Q-port) and / or the destination port number (Z-port) generates a priority assignment table (PZT) and stored in the network node (PCl, PC2, PC3).

3. The method according to claim 2, characterized in that the priority allocation table (PZT) by the operator / user of the communication network (KNW, KNW ') is generated.

4. The method according to claim 2, characterized in that the priority assignment table (PZT) is generated by the manufacturer of the network node (PC1, PC2, PC3).

5. The method of claim 2, 3 or 4, characterized marked, that the generated priority allocation table (PZT) within the communication network (KNW, KNW) to all network nodes (PCl, PC2, PC3) is automatically distributed.

6. The method according to any one of claims 1 to 5, characterized ge indicates that a local area network with wireless communication according to the 802.11 technology, in particular for the home area, as the communication network (KNW, KNW ') is used.

7. The method according to any one of claims 1 to 5, characterized ge indicates that a local area network with wired communication in accordance with the designated as "ETHERNET" 802.3 technology, in particular for the home, as the communication network (KNW, KNW ') is used.