FI121835B - Method and apparatus for indicating differences in data transmission delays - Google Patents

Description

Method and arrangement for detecting differences in data transmission delays

Shared application, which is subtracted from application FI20080066 by division.

FIELD OF THE INVENTION The invention relates to the detection of differences in transmission delays experienced by communication frames. The invention relates to a method and arrangement for detecting differences in transmission delays experienced by received communication frames. The invention also relates to a network element and a computer program.

BACKGROUND OF THE INVENTION In many telecommunication applications, it is advantageous, or even necessary, that the differences in transmission delay between communication frames in a communication flow are within acceptable limits. Said communication frames may be, for example, Internet Protocol (IP) packets, Asynchronous Transfer Mode (ATM) cells, Ethernet frames, or Frame Relay frames. Said communication stream typically consists of transmission frames transmitted sequentially over time. For example, in a situation where a communication stream transmits an audio and / or video signal, variation in the communication delay increases the need for buffering received communication frames in a receiving network element, which may be, for example, a router. Buffering increases the total latency experienced by said communication stream, which should be as small as possible. In offline communication systems, different communication frames of a traffic flow may travel from a source network element to a destination network element via different paths. In this case, the different transmission delays experienced by the different transmission frames may cause the temporal order of the transmission frames to change, i.e. the order in which the transmission frames are received differs from the temporal transmission order of the transmission frames. Also in interconnected communication systems, the traffic flow is often directed to two or more parallel routes, for example to load the different areas of the communication network (load balancing). A change in the temporal order of the communication frames increases the need for buffering of the received communication frames.

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It must be possible to detect differences between transmission delays experienced by data transmission frames in order to take the necessary corrective measures. Said corrective measures may include, for example, configuring the routing protocol to replace the use of high transmission latency portions or areas with other portions or areas of said transmission network and / or downgrading the portions or areas of the high latency use.

In one prior art method, a measure of transmission delay variation il10 is calculated by transmitting and receiving times of communication frames. To illustrate the method, two data transfer frames PDU1 and PDU2 are discussed. The communication frame PDU1 is transmitted from the source network element at time t_tx1 and the communication frame PDU2 is transmitted at time t_tx2. The communication frame PDU1 is received in the test element 15 of the target network at time t_rx1 and the communication frame PDU2 is received at time t_rx2. The transmission delay experienced by the communication frame PDU1 is d1 = t_rx1 -t_tx1 and the transmission delay experienced by the communication frame PDU2 is d2 = t_rx2 - t_tx2. The measure of the difference between said transmission delays is the difference of said transmission delays d1 - d2 = (t_rx1 - t_tx1) - (t_rx2 - t_tx2) = (t_rx1 - t_rx2) - (t_tx1 -20 t_tx2). It is seen from the latter form of the expression for transmission delay difference that the clocks in the source network element and the destination network element need not indicate a common time, but it is sufficient that said clocks are frequency locked with respect to each other, i.e. running at the same speed. The method requires, in addition to the requirement for frequency locking of the clocks, that a quantity indicating the time of transmission of each data transmission frame is transmitted to a destination network element. However, many telecommunication applications do not meet these conditions.

Summary

The invention relates to an arrangement for detecting differences in transmission delays experienced by received communication frames. Each communication frame is accompanied by a sequence indicator arranged to indicate the position of the communication frame in a sequential order between said communication frames. Each communication frame is transmitted earlier or at the same time as the next transmission frame in said sequential order. Said sequence indicator need not be information indicating the time of transmission of the communication frame, but it is sufficient that said sequence indicator is, for example, a sequence number attached to a communication frame, an alphabetical letter, or other information indicating the position of the communication frame in said sequential order. In the arrangement according to the invention, there is a processor unit arranged to: at the first receiving port of the network element and when the second communication frame is received at the second receiving port of said network element, in response to a situation where said first communication frame is in said sequential order below said second communication frame to calculate said second communication frame and the time difference, said time difference representing the smallest possible difference between the transmission delays experienced by said second data transmission frame and said first data transmission frame, and and, based on said time difference, the updated indicator value exceeds a preset threshold.

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The invention also relates to a network element adapted to receive communication frames. Each communication frame is associated with a sequence indicator arranged to indicate the position of the communication frame in a sequential order between said communication frames, and each communication-5 frame is transmitted earlier or simultaneously with the next communication frame in said sequential order. The network element according to the invention has a processor unit arranged: in a first receiving port and said second communication frame being received in a second receiving port of a network element, in response to a situation in which said first communication frame is in said sequential order below said second communication frame to calculate a time interval between said second communication frame and said first ro, said time difference representing a minimum difference between transmission delays experienced by said second communication frame and said first communication frame, and - lowering the quality classification used by the quality class-aware routing protocol associated with said second receiving port in response to said second communication frame being referred to as the data frame and the indicator value updated based on said time difference exceeds a preset limit.

The invention also relates to a method for detecting differences in transmission delays experienced by received communication frames. Each communication frame is accompanied by a sequence indicator arranged to indicate the position of said communication frame in a sequential order between said communication frames, and each communication frame being transmitted earlier or simultaneously with the next communication frame in said sequential order.

According to the method of the invention: - based on a first order indicator associated with a first received first data transmission frame and a second order indicator related to a second data frame subsequently received, whether said first data transmission frame is 15 - in response to a situation in which said first communication frame is in said sequential order hereinafter referred to as said second communication frame, calculating a time difference between the reception times of said second communication frame and said first communication frame, and - lowering the quality classification used by the quality class-aware routing protocol associated with said second receiving port if said first data frame is in said successive order and said second period of time set limit.

The invention also relates to a computer program for controlling a programmable processor to detect differences in transmission delays experienced by received communication frames, wherein each communication frame is associated with a sequence indicator arranged to indicate the position of said communication frame in said sequentially transmitting the next frame to be transmitted in reverse order. The computer program according to the invention has: - software means for controlling said programmable processor to detect, based on a first sequence indicator associated with a previously received first communication frame and a second sequence indicator related to a second received communication frame, whether said first communication frame is in said sequential order; the communication frame received at the first receiving port of the network element and the second communication frame receiving at the second receiving port of said network element, - software means for controlling said programmable processor to calculate a time difference between said second communication frame and said first communication frame said transmission frame is in said sequential order hereinafter referred to as said second communication frame, said time difference representing the smallest possible difference between the transmission delays experienced by said second communication frame and said first 20 communication frames, and in response to a situation in which said first communication frame is in a sequential order below said second communication frame and the indicator value updated based on said time difference exceeds a preset threshold.

Various embodiments of the invention are characterized by what is set forth in the dependent claims.

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Embodiments of the invention provide such an advantage over the prior art solution disclosed herein that the clock in the destination network test element need not be frequency locked relative to the clock in the source network test element, and there is no need to transmit the transmission time information of each data transmission frame to the destination network. If said information indicating the time of transmission is available to the destination network element, it may be used as a sequence indicator attached to the communication frame.

Brief description of the figures

Embodiments of the invention and their advantages will now be described in more detail with reference to the exemplary embodiments and the accompanying figures, in which: Figure 1 is a block diagram illustrating an example of a communication system having an embodiment of the transmission delays of FIG. 3 is a block diagram of a network element according to one embodiment of the invention, and FIG.

Description of Embodiments of the Invention

Fig. 1 is a block diagram illustrating an example of a communication system having an arrangement according to an embodiment of the invention for detecting differences in transmission delays experienced by received communication frames. Communication frames 130, 131, 132, 133, ... of the communication flow are transmitted from the source network element 101 through the communication network 103 to the destination network element 8 102. The communication frames are transmitted using two parallel paths 110 and 111 such as communication port 130 ) Is transmitted via transmission port 105 to route 111. Communication frame 130 is received at the ingress port 106 of the destination network test element 102 and communication frame 131 is received at the receiving port 107 of the destination network element 105. In the communication system 105 and ports 106 and 107 are described as physical ports. An example of looking at logical ports is shown in Figure 2. The communication frame 130 'represents the communication frame 10 after the communication frame 130 has been transferred from the source network element 101 to the destination network element 102. Similarly, the communication frame 131' represents the communication frame 131 transmitted from the source network element 101 to the destination network element 102. The communication frames may be, for example, Internet Protocol (IP) packets, Asynchronous Transfer Mode (ATM) cells, Ethernet frames, or Frame-Relay frames.

Each communication frame 130, 131, 132, 133, ... is associated with a sequence indicator arranged to indicate the position of said communication frame in a sequential order between said communication frames. The sequence indicator may be, for example, a transmission time stamp of the transmission frame 20 indicating the time of transmission of the communication frame, a sequence number of the communication frame or another symbol associated with the communication frame in a predetermined order such as an alphabetical letter. By means of said sequence indicator, the destination network element is able to reconstruct the original sequential order of said communication frames even if the temporal order of reception of the communication frames is not the same as said original sequential order. Each communication frame is transmitted from the source network element earlier or at the same time as the next communication frame in said sequential order. In the example situation shown in Figure 1, the communication frame 131 is in said sequential order after the communication frame 130. The communication frames 130 and 131 in the source network element 30 are transmitted to the transmission ports 104 and 105 either substantially simultaneously or by transmitting the communication frame 130 to the transmission port 104 earlier than the communication frame 131 being transmitted to the transmission port 105.

9, in order to detect the difference in transmission delays experienced by the received communication frames, the processor unit 108 is arranged to: and - in response to a situation in which said first communication frame is in said sequential order hereinafter referred to as said second communication frame, to calculate a time difference between the reception time of said second communication frame and the reception time of said first communication frame.

Said time difference represents the smallest possible difference between the transmission delays experienced by said second communication frame and said first communication frame.

To illustrate the operation of the arrangement, it is assumed, for example, that the communication frame 131 'has been received earlier than the communication frame 130'. On the other hand, based on the sequence indicators, the communication frame 131 'is below the communication frame 130' in said sequential order of the communication frames. Thus, there is a situation in which the first received communication frame (13T) previously received is in a sequential order below the second received communication frame (130 '). Without limiting the generality, it can be assumed that: - the transmission time 130 '(130) of the transmission network element 101 is t_tx1, 25 - the transmission time 131' (131) of the transmission network element 101 is t_tx2, - the transmission frame 130 '(130) 10 - The time of reception of the communication frame 131 '(131) in the destination network element 102 is t_rx2.

Since the communication frame 131 'is assumed to be received before the communication frame 130, t_rx1> t_rx2. Further, t_tx2> t_tx1, since the data transmission frame 131 'is in the said data transmission frame sequentially below the data transmission frame 130'. The transmission delay 130 'experienced by the communication frame 130' is d1 = t_rx1 - t_tx1 and the transmission delay 131 'experienced by the communication frame 131' is d2 = t_rx2 - t_tx2. The measure of the difference between said transmission delays d1 and d2 is the difference between said transmission delays: 10 d 1 - d2 = (t_rx1 - t_tx1) - (t_rx2 - t_tx2), (1) which can be converted to: d1 - d2 = (t_rx1 - t_rx2) ) + (t_tx2 - t_tx1). (2)

The difference between the transmission delays d1 -d2 holds for: d1 - d2> t_rx1 - t_rx2, (3) 15 since t_tx2> t_tx1, i.e. t_tx2 - t_tx1> 0 (the data transmission frame 131 'is in a sequential order below the data transmission frame 130'). Thus, the time difference between the reception time of the subsequently received communication frame 130 'and the reception time of the previously received communication frame 131' represents the smallest possible difference between the transmission delays d1 and d2. Said time difference 20 is the same as the difference in transmission delays if the transmission frames 130 'and 131' are transmitted simultaneously. As shown in equation 3, information about the transmission times t_tx1 and t_tx2 is not required.

As can be seen from the example above, the time difference t_rx1 - t_rx2 between the reception times indicates the smallest possible difference between the transmission delays d1 and d2 if the order of reception of the communication frames 25 is different from the sequential order determined by the order indicators of the communication frames. In other words, the chronological order of the transmission frames has changed during transmission. The above principle can be used to indicate the magnitude of latency fluctuations in a communication stream 11 if the timing order of the communication frames may change during data transmission and said communication frames have a sequential order to be communicated to the destination network element. The principle can be used to compare the delay characteristics of different sub-components of a communication stream by selecting the first data-5 transmission frame to be considered from the first quarter and the second data transmission frame to be considered from the second quarter. For example, different frames may be represented by communication frames arriving at different physical or logical receiving ports. In the example above, the minimum value of the transmission delay difference was determined in a situation where the first communication frame to be considered belongs to the first sub flow of the communication stream arriving at the first receive port 107 and the second considered communication frame to the second sub flow of said communication flow arriving at the second receiving port 106.

The above principle can also be used in a situation where more than two receiving ports arrive at communication frames representing a communication stream. For example, suppose a communication stream arrives at the receiving ports P1, P2, ..., PN. In a situation where the communication frame PDU (a) arrives at the receiving port Pi and the communication frame PDU (b) arrives at the receiving port Pi and the timing order of said communication frames PDU (a) and PDU (b) is changed, the transmission paths 20 difference (time difference between the reception times of PDU (a) and PDU (b)), where i = 1, ..., N and j = 1, ..., N. In other words, the transmission delay difference of the communication paths quantities are obtained for each pair of receiving ports Pi, Pj. For example, by looking at the measures of transmission delay difference measured for different receiving port pairs, it is possible to identify the receiving port or ports that are or are associated with the highest number of transmission delays.

The reception times of the communication frames can be measured by the clock signal produced by the clock generator 109. In the telecommunication system shown in Figure 1, the clock generator is part of the destination network element 102. The reception times of the communication frames can also be measured by the clock signal received from outside the destination network element 102.

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In an arrangement according to an embodiment of the invention, processor unit 108 is arranged to remove receive port 106 from a plurality of available receive ports in the routing protocol in response to a previously received data transmission frame 130 'and a the updated indicator value based on the time difference exceeds the preset limit. Thus, path 110 causes greater communication delays than route 111. Said routing protocol may be, for example, an Internet routing protocol (IP), by means of which the test network 101 of the source network 10, the network element 102 and the network elements of the communication network 103 maintain their routing tables. In an arrangement according to another embodiment of the invention, processor unit 108 is arranged to downgrade the quality classification used by the quality class aware routing protocol associated with receive port 106 in response to a previously received data transmission frame 131 '15 being sequentially transmitted and 131 ', based on the time difference between the reception times, the updated indicator value exceeds a preset limit. In other words, the routing protocol is configured to replace the use of high transmission latency portions or areas 20 with other portions or regions of said transmission network and / or to downgrade portions or areas of the high latency transmission region to avoid using quality domain specific routing.

There are 25 different ways in which the procedure for updating this indicator value can be selected. For example, processor unit 108 may be arranged to compare the time difference of reception times with the old indicator value and set said time difference of reception times as a new indicator value in response to a situation where said time difference between reception times and a predetermined corresponding time difference For example, processor unit 108 may be arranged to use the time difference of reception times as such as an indicator value. For example, processor unit 108 may be configured 13 to use the time difference between reception times as an input for low pass filtering and an output for said low pass filtering as said indicator value.

Fig. 2 is a block diagram illustrating an example of a communication system having an arrangement according to an embodiment of the invention for detecting differences in transmission delays experienced by received communication frames. Communication frames 230, 231, 232, 233, ... included in the communication flow are transmitted from the source network element 201 through the communication network 203 to the target network element 202. Some of the communication frames are transmitted through the logical 10 transmission port 212 of the source network element 201. The communication frames transmitted through the logical transmission pot 212 are routed to the path 210 between the network elements 221 and 222 and received at the logical receive port 214 of the destination network element 202. The order of the data transfer frames 230, 231, 232, 233, ... may change during transmission between the network elements 221 and 222. The logical transmission ports 212 and 213 are implemented on the physical transmission port 204 and the logical reception ports 212 and 213 are implemented on the physical reception port 207. The logical port may be represented, for example, by an IP-20 tunnel (Internet Protocol), ATM-VC (Asynchronous Transmission Protocol-Virtual Circuit). ), MPLS-LSP (Multiprotocol Label Switching-Label Switched Path), or any other predefined connection to the data network. The communication frame 230 'represents the communication frame 230 after the communication frame 230 has been transferred from the source network element 201 to the destination network element 202. Similarly, the communication frame 231' represents the communication frame 231 after the communication frame 231 has been transferred from the source network element 201.

Each communication frame 230, 231, 232, 233, ... is associated with a sequence indicator arranged to indicate the position of said communication frame in a sequential order between said communication frames. Each data transmission-30 hys is transmitted from the source network element earlier or at the same time as the next data transmission frame in said sequential order. In the exemplary vibration of Fig. 2, in the exemplary situation, the communication frame 231 is in said sequential order after the communication frame 230.

In an arrangement for detecting differences in transmission delays experienced by received communication frames, the processor unit 208 is arranged to: 5 - detect a first order indicator associated with a first received first communication frame (230 'or 231') and a second received communication frame (231 'or 230') based on whether said first data transmission frame is in said sequential order below said second data transmission frame, and time difference.

Said time difference represents the smallest possible difference between the transmission delays experienced by said second communication frame (231 or 230 ') and said first communication frame (230' or 231 ').

Figure 3 is a block diagram illustrating a network test element 300 according to an embodiment of the invention, which may be, for example, an Internet router, an Ethernet switch, an Asynchronous Transfer Mode (ATM) switch, a cellular network access point, or an MPLS. Multi Protocol Label Switching. The network element is adapted to receive communication frames 330, 331. Each communication frame is associated with a sequence indicator arranged to indicate the position of the communication frame in question in a sequential order between said communication frames, and each communication frame being transmitted earlier or sequentially as the data sequence. The network element has a processor unit 308 arranged to: indicate, based on a first order indicator associated with a first received first communication frame 30 and a second order indicator associated with a second received communication frame subsequently received, whether said first communication frame is in said second order and in response to a situation where said first data transmission frame is in said sequential order below said second data transmission frame, to calculate a time difference between receiving times of said second data transmission frame and said first data transmission frame, said time difference representing said second data transmission difference.

Without limiting the generality, it can be assumed that said first communication frame is a communication frame 331 and said second communication frame is a communication frame 330.

In a network element according to an embodiment of the invention, said first communication frame is a communication frame received at a first ingress port 307 of said network element and said second communication frame is a communication frame received at a second receiving port 306 of the network element. The receiving port 306 may be a physical or logical receiving port. Similarly, the receiving port 307 may be a physical or logical receiving port 20.

In a network element according to an embodiment of the invention, said processor unit 308 is arranged to remove the reception port 306 from the available reception ports of the routing protocol in response to a previously received data transmission preset limit. As will be apparent from the description of Figure 1, there are several ways of selecting the procedure to be used for updating said indicator value.

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In a network element according to an embodiment of the invention, said processor unit 308 is arranged to downgrade the quality classification used by the quality class-aware routing protocol associated with the receiving port 306 in response to a previously received data transmission frame 331 the updated indicator value based on the time difference exceeds the preset limit.

A network element according to an embodiment of the invention has a processor for executing said routing protocol. Said processor may be a processing unit 308 or another processor in the network element. The network element according to one embodiment of the invention has an output port 324 for supplying data to external equipment for indicating differences in transmission delays.

The network element according to one embodiment of the invention has a clock generator 309 arranged to produce a clock signal for measuring the reception times of the communication frames 15. The network element according to one embodiment of the invention has an input port 323 for receiving a clock signal from outside the network element.

Fig. 4 is a flow chart illustrating a method for detecting differences in transmission delays experienced by received communication frames according to an embodiment of the invention. Each communication frame is associated with a sequence indicator arranged to indicate the position of the communication frame in a sequential order between said communication frames, and each communication frame is transmitted earlier or simultaneously with the next communication frame in said sequential order. In step 401, the mutual order of the first communication frame received previously and the second communication frame subsequently received is determined on the basis of a first order indicator associated with said first data transmission frame and a second order indicator associated with said second data transmission frame. If said first communication frame 30 is in said sequential order below said second communication frame, proceeding to step 402 calculating the time difference between the reception times of said second communication frame 17 and said first communication frame. Said time difference represents the smallest possible difference between the transmission delays experienced by said second communication frame and said first communication frame.

In a method according to an embodiment of the invention, said first communication frame is a communication frame received at a first ingress port of a network element and said second communication frame is a communication frame received at a second receiving port of said network element. Said first receiving port may be a physical or logical receiving port and said second receiving port may be a physical or logical receiving port.

In a method according to an embodiment of the invention, said second reception port is removed from the available reception ports of the routing protocol if said previously received first communication frame is in said sequential order below said later received second communication frame and updated by a time offset value.

In a method according to an embodiment of the invention, the quality classification used by the quality class-aware routing protocol associated with said second receiving port is downgraded if said previously received first data transmission frame is later than said later received second data transmission .

25 There are several ways to choose the procedure to be used to update this indicator value. In the procedure of the first example, said time difference between reception times is used as such as said indicator value. In the procedure of the second example, said time difference between reception times is compared with said indicator value, and if said time difference between reception times and a predetermined number of previously calculated corresponding time differences are greater than said indicator value, said time difference is set as a new indicator value. In the procedure of the third example, said time difference between reception times is used as an input for low-pass filtering and said output for said low-pass filtering is said indicator value.

In a method according to an embodiment of the invention, said first communication frame and said second communication frame are one of the following alternatives: Internet Protocol (IP) packets, Asynchronous Transfer Mode (ATM) cells, Ethernet frames, and Frame-Relay frames.

In a method according to an embodiment of the invention, the order indicator associated with each communication frame is one of the following: a transmission time stamp indicating the time of transmission of the communication frame and the sequence number of the communication frame.

A computer program according to an embodiment of the invention has software means for controlling a programmable processor to detect differences in transmission delays experienced by received communication frames, wherein each communication frame is associated with a sequence indicator arranged to indicate the position of existing road-20 donation frame. Said software means are: - software means for controlling said programmable processor to detect a first order indicator associated with a first received first data transmission frame and a second order indicator related to a second data frame subsequently received, whether said first data transmission frame is in said sequential order, for controlling said programmable processor to calculate a time difference between receiving times of said second communication frame and said first communication frame in response to a condition wherein said first communication frame is in said sequential order hereinafter referred to as said second communication frame, said first data transmission and said second data transmission rt the smallest possible difference between delays.

The said software tools may be, for example, subroutines or functions. For example, the processor unit 308 shown in Figure 3 may be said programmable processor.

A computer program according to an embodiment of the invention is stored on a readable storage medium of a programmable processor, such as, for example, an optical disk (Compact Disk).

A computer program according to an embodiment of the invention is encoded into a signal which can be received from a telecommunications network such as the Internet.

As will be apparent to a person skilled in the art, the inventions and their embodiments are not limited to the above-described embodiment examples, but the invention and its embodiments can be modified within the scope of the independent claim. The expressions describing the existence of the features contained in the claims, for example, '' has a processor unit in the arrangement ', are open so that the disclosure of the features does not exclude the existence of other features not set forth in the independent or independent claims.

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Claims (18)

An arrangement for indicating mutual differences in transmission delays of received data transfer frames (130 ', 131', 230 ', 231'), to which is attached to each data transmission frame, an order indicator which is arranged to indicate the position of the data transfer frame in question. said sequential order of said data transfer frames, and each data transfer frame has been transmitted earlier than or at the same time as the next data transfer frame in said sequential order, and which arrangement has a processor unit (108, 208) arranged to: 10. indicate on the base of a first order sequence indicator connected to a previously received first data transfer frame (131 ', 231') and a second order indicator connected to a later received second data transfer frame (130 ', 230'), if said first data transfer frame in said sequential order follows data transfer frame, when said first data transfer frame is received in the first receiving port (107, 214) of a network element and said second data transfer frame is received in the second receiving port (106, 215) of said network element, and - in response to a situation where said first data transfer frame in said sequential order, after said second data transmission frame, calculates the time difference between the receiving times of said second data transmission frame and said first data transfer frame, said time difference representing the smallest possible difference in data transfer frame second transmission delay as said transmission delay , characterized in that said processor unit is arranged to lower the quality rating used by a quality class conscious routing protocol, which quality rating is associated with said second receiving port (106, 215) in response to a situation where said first data transfer frame (131 ', 231') in said sequential order comes after said second data transfer frame (130 ', 230') and the indicator value updated on the basis of said time difference exceeds a pre-set limit value. Arrangement according to claim 1, characterized in that said first receiving port is a physical receiving port (107) or a logical receiving port 5 (214) and said second receiving port is a physical receiving port (106) or a logical receiving port (215). Arrangement according to claim 1, characterized in that said processor unit is arranged to remove said second receiving port (106, 215) from the receiving ports that the routing protocol can use in response to a situation, wherein said first data transfer frame (131 ', 231) ') in said sequential order, after said second data transmission frame (130', 230 '), and the indicator value updated on the base of said time difference exceeds a predetermined limit value. Arrangement according to claim 1, characterized in that said processor unit is arranged to compare said time difference with said indicator value and to expose said time difference as said indicator value in response to a situation where said time difference and a predetermined amount of previously calculated corresponding time differences are greater than said indicator value. Arrangement according to claim 1, characterized in that said processor unit is arranged to use said time difference as the input size for low pass filtering, where the output size for said low pass filtering is said indicator value. Arrangement according to claim 1, characterized in that said first data transfer frame and said second data transfer frame are any of the following alternatives: Internet Protocol (IP) packets, Asynchronous Transfer Mode (ATM) cells, Ethernet frames, and Frame-Relay frames. Arrangement according to claim 1, characterized in that said order sequence indicator connected to each data transmission frame is one of the following: transmission time stamp indicating the transmission time of the data transfer frame and the order number of the data transfer frame. 28 8. A network element (300) adapted to receive data transfer frames (330, 331), to each of which data transfer frames is connected an order sequence indicator, which is arranged to indicate the position of the data transfer frame in the respective sequential order of the data transfer frame 5, of each data transmission frame has been transmitted earlier than or at the same time as the next data transmission frame in said sequential order, and which network element has a processor unit (308) arranged to: - indicate on the base of a first order sequence indicator which has been connected to a previously received first data transfer frame (331) and a second order sequence indicator which is connected to a later received second data transfer frame (330), if said first data transfer frame in said sequential order sequence follows said second data transfer frame, said first data transfer frame is received in the first receiving port (307) of said network element and said second data transmission frame being received in said second element's second receiving port (306), and - in response to a situation where said first data transmission frame in said sequential order follows the second data transmission frame, calculating the time difference between reception times for said second data transfer frame and said first data transfer frame, wherein said time difference represents the smallest possible difference in the transmission delays as said second data transfer frame and said first data transfer frame, characterized in that said processor unit is adapted to a quality standard which is used to lower quality classification. , which quality rating is associated with said second receiving port (306) in response to a situation where said first data transfer frame (331) in said the sequential order arrives after said second data transmission frame (330) and the indicator value updated on the base of said time difference exceeds a predetermined limit value. 30 Network element according to claim 8, characterized in that said processor unit is arranged to remove said second receiving port (306) from the receiving ports which the routing protocol can use in response to a situation where said first data transmission frame (331) in said sequential order sequence follows after said second data transmission frame (330) and the indicator value updated on the base of said time difference exceeds a pre-set limit value. Network element according to claim 8, characterized in that the network element is one of the following: Internet Protocol (IP) router, Ethernet switch, Asynchronous Transfer Mode (ATM) switch, mobile network base station and MPLS switch (English) .Multi Protocol Label Switching). 10 11. A method for indicating mutual differences in transmission delays of received data transfer frames, wherein a sequence order indicator is provided for each data transmission frame arranged to indicate the position of the respective data transfer frame, the data transfer sequence of each of said data transfer frame, and earlier than or at the same time as the next data transmission frame in said sequential order, and in which method: - indicating (401) on the base of a first order sequence indicator connected to a previously received first data transfer frame and a second order sequence indicator connected to a later received second data transfer frame, if said first data transfer frame in said sequential order follows after said second data transfer frame, said first data transfer frame is received in the network element first receiving port and said second data transfer frame are received in said second receiving port of said network element, and 25. in response to a situation where said first data transfer frame in said sequential order follows said second data transfer frame, (402) calculates the time difference between said second time points data transfer frame and said first data transfer frame, wherein said time difference represents the smallest possible inequality in the transmission delays as said second data transfer frame and said first data transfer frame, characterized in that the method is lowered in the quality classification which is used according to a quality classification according to a quality class standard. second receiving port, if said first data transfer frame in said sequential order follows said second data transfer frame and indicator v the value updated on the base of said time difference exceeds a predetermined limit value. Method according to claim 11, characterized in that said first receiving port is a physical or a logical receiving port and said second receiving port is a physical or a logical receiving port. 10 Method according to claim 11, characterized in that said second receiving port is removed from the receiving ports which the routing protocol can use if said first data transfer frame in said sequential order comes after said second data transfer frame and the indicator value updated at the base of said time difference above limit value. Method according to claim 11, characterized in that said time difference is compared with said indicator value and, if said time difference and a predetermined amount of previously calculated corresponding time differences are greater than said indicator value, said time difference is stated as said indicator value. 20 15. A method according to claim 11, characterized in that said time difference is used as the input quantity for low pass filtering, since the output quantity for said low pass filtering is said indicator value. The method of claim 11, characterized in that said first data transfer frame and said second data transfer frame are any of the following alternatives: Internet Protocol (IP) packets, Asynchronous Transfer Mode (ATM) cells, Ethernet frames, and Frame-Relay frames. Method according to claim 11, characterized in that said order sequence indicator connected to each data transmission frame is one of the following: transmission time stamp indicating the transmission time of the data transfer frame, and the order number of the data transfer frame. 31 18. Computer programs for controlling a programmable processor to indicate mutual inequalities of transmission delays of received data transfer frames, where a sequence order indicator is provided, which is arranged to indicate the position of the relevant data transfer frame in the data transfer frame's order transfer data, in said data transfer frame. each data transmission frame has been transmitted earlier than or at the same time as the next data transmission frame in said sequential sequence, and which computer program has program means for controlling said programmable processor to: - indicate on the base of a first order sequence indicator which has been connected to a previously received first data transfer frame and a second order sequence indicator which has been connected to a later received second data transfer frame, if said first data transfer frame in said sequential order follows after said second data transmission frame, when said first data transfer frame is received in the first receiving port of the network element and said second data transmission frame is received in the second receiving port of said network element, and - calculate the time difference between the reception times of said second data transfer frame and said first data transfer frame, in response to said first data transfer frame in said sequential sequence, after said second data transfer frame, said time difference represents the smallest possible difference in the transmission delays that said second data transfer frame and said first data transfer frame have undergone, said program program for having said program program therefor lowering the quality rating used by the quality class-aware routing protocol, which quality rating is associated with said a second receiving port, in response to a situation where said first data transmission frame in said sequential order arrives after said second data transmission frame and the indicator value updated on the basis of said time difference exceeds a predetermined limit value.