EP1661329A1

EP1661329A1 - Improvement of a link and communication network load with access control

Info

Publication number: EP1661329A1
Application number: EP03788811A
Authority: EP
Inventors: Michael Menth; Joachim Charzinski
Original assignee: Siemens AG; Nokia Siemens Networks GmbH and Co KG
Current assignee: Nokia Solutions and Networks GmbH and Co KG
Priority date: 2003-09-05
Filing date: 2003-11-21
Publication date: 2006-05-31
Also published as: DE10319310B4; CN1879358A; WO2005027432A1; DE10319310A1; US20060274653A1

Abstract

The invention relates to two methods which improve the load of a link with access control and/or a communication network with access control. According to the invention, overbooking according to the ratios of the measuring values of transferred aggregated traffic is determined according to the face values of aggregated transferred traffic. The ratios of measuring values in relation to face values are weighted according to the variable of either the measuring value or the face value such that with smaller measuring values and/or face values the ratios thereof have a slightly lower effect on the determination of overbooking than the ratios of greater measuring values and face values in relation to each other. The invention provides systematic access for the improved use of wave bands. Representative situations, wherein a high charge of the wave band is predominant, are taken into to account to a greater extent during the determination of the overbooking factor than by phases characterised by a small load.

Description

description

Improved utilization of links and communication networks with access control

The invention relates to a method for improving the load on a link in a communication network and a method for improving the load on a communication network.

The invention is in the field of network technology and is primarily aimed at better utilization of packet-oriented networks with real-time traffic.

In many current networks there are methods of overload control to ensure the transmission quality in these networks. One way of congestion control is to subject admission controls to traffic being transmitted. A bandwidth reservation for registered traffic is carried out for each link or for the entire network. Newly registered connections are rejected if there is no longer sufficient bandwidth available for the requested transmission service.

As a rule, the total bandwidth reserved according to admission controls is higher than the bandwidth actually used. Networks with access controls often also use so-called policers, which measure the real bandwidth used and discard packets when the reserved bandwidth is exceeded. Bandwidth reservations are therefore usually made conservatively so that traffic peaks do not lead to the requested bandwidth being exceeded. In addition, connections often have an on / off character, ie there are pauses during which no data is be sent. Finally, data streams begin to send after a delay after the reservation is established.

Because of the discrepancy between the reserved and the actually used bandwidth, network operators sometimes allow more traffic based on measured values than the bandwidth reservation would guarantee.

The invention has for its object to provide a systematic method for improved utilization of the available transmission capacities.

The task is for a link or a connection section with access control by claim 1 and for a

Communication network with access control solved by claim 2.

The communication network is, for example, an IP (Internet Protocol) network. The access control takes place either for at least one communication link in the network or for aggregated traffic transmitted over the communication network. Access control allows only a limited amount of data to use the network as a communication medium to protect it from overload. One possibility is also to subject only traffic of one (or more) traffic classes to an access control (for example, traffic classes for real-time traffic can be harxdeln). Traffic that is not subject to access control is then transmitted, for example, in accordance with a “best effort” approach, that is to say transmission without quality features. The invention allows, based on empirical values or.

Measured values controlled allow more traffic than the pure control procedure would allow due to the displayed traffic volume. According to the invention, the overestimation of the displayed traffic descriptions (i.e. the bandwidth used according to the reservation) is at least partially compensated for.

The basic idea of the method is to determine an empirical value or measured value for the data rate actually used by reservations in relation to the declared rate (nominal value). Measured values are included in this determination the more significant the more significant they are. For this purpose, measured values from phases with high utilization of the reservable budget are taken into account more than measured values from phases with little

Traffic. The ratios or quotients of measured values of all traffic transmitted via the link to nominal values of all traffic permitted for access control for transmission via the link are weighted according to the (absolute) size of either the measured value or the nominal value. For an overbooking based on determined relationships between measured values and nominal values, the values that relate to a traffic situation with high utilization are obviously the most significant. A high load leads to large values for the registered accumulated traffic volume (nominal value) or the measured accumulated traffic volume (measured value). The weighting takes greater account of situations with a high workload when determining an overbooking factor.

The method according to the invention means that atypical or less frequent events are given less weight. In this way, a less conservative value can be determined for the overbooking but which takes into account the important events. This is necessary, for example, to make the determination of the overbooking factor robust against atypical situations in times of little traffic:

For example, a connection that happens to be active on its own may require all of its reserved bandwidth. This means that the ratio of measured value to nominal value is equal to one. In the event that this is atypical behavior, the weighting according to the invention scarcely takes it into account if the bandwidth used is small compared to the total available bandwidth.

An attacker could corrupt the system by holding reservations and sending significantly more than what is intended by the nominal values. This may damage the quality of service of the active connections. Such an approach would only be promising if the attacker could use a large part of the available bandwidth. Otherwise, the attack is intercepted by the weighting when determining the overbooking factor.

According to a further development, the measured values are weighted in such a way that more current measurements are taken into account to a greater extent. Weighting can be done by multiplying the measured values by an aging factor. For example, all measured values are multiplied by the aging factor at fixed time intervals. Another procedure is the multiplication by an aging factor of the old measured values each time a flow is newly registered. In this case, the aging factor can be selected from the bandwidth reserved for the new flow. The invention can be easily combined with various types of access control schemes that utilize displayed traffic descriptions.

The access control is carried out by means of a limit for the aggregated traffic on the link or by means of a limit for aggregated traffic transmitted via the communication network. Which aggregated traffic is measured in the communication network and compared with a nominal value for aggregated traffic depends on the access control used. Three options are outlined below:

• The admission control is carried out by means of a limit for the data traffic transmitted between two boundary points of the communication network and the measured values and the nominal values relate to the aggregated data traffic transmitted between the two boundary points.

• Two admission checks are carried out by means of a limit for the data traffic entering the communication network at an edge point or with a limit for the data traffic exiting at an edge point. Data traffic is allowed if both admission controls are positive. The measured values and the nominal values then relate to the aggregated approved data traffic, i. H. to the aggregated data traffic that entered the network at the corresponding edge point or to the aggregated data traffic that leaves the network at the other edge point.

• Two admission controls are carried out for each link affected by the transmission of data traffic by means of a link Boundary for the data traffic entering the communication network at a boundary point or with a boundary for the data traffic emerging at a boundary point. Data traffic will be allowed if all admission controls are positive. The measured values and the nominal values then relate to the aggregated permitted data traffic transmitted via an affected link, ie the aggregated data traffic transmitted via the link that entered the network at the corresponding boundary point, or to the aggregated, Data traffic transmitted via the link, which leaves the network at the other edge point.

However, the method according to the invention is not limited to the above cases, but can be flexibly adapted for any access controls. In general, the limit used for access control for aggregated traffic or used. Limits lead to the measured values to be determined. The nominal values for aggregated traffic are compared with the limit (s); s and the measured values must correspond. For example, in the last case mentioned above - limits, which depend in each case on an edge node and a link - the aggregated traffic transmitted via the link can be measured, which has entered or is to leave the network at the corresponding edge node. Measured values should correlate with the limits. A clear correspondence is not necessary. Knowledge of the traffic distribution in the network and statistical properties of the network can be used, for example, to reduce the number of measurements required. When determining the limit for an access control

In addition to an overbooking factor determined according to the invention, the registration of a flow at the network boundary can include the following variables: The available bandwidth of links to be used for the transmission of the flow.

• A security factor, which is chosen to be less than one and defines a security margin in the allocation of bandwidth. Such a safety factor can e.g. Intercept previous fluctuations in flows that exceed the nominal value.

• A delay limiting factor, which is chosen small: *: one and which is chosen so that the expected delay in the transport of data packets does not exceed a selected threshold. Erfahrungsgen AESS cause fluctuations in the packet size and the carry ^~ te ungsra- mean that transport time or delay in the transport of packets through the network increases greatly when the utilization of the network approaches the Gesamtkapaz ity. The delay limiting factor ensures that the load on the network (possibly for the I-routes to be used by the registered traffic) remains below the threshold where the delay in the data packets affects the quality of the transmission.

If all of the factors listed above are used for train control, a new flow fnew with a maximum transfer rate r (fnew) can be permitted if

r (fnew) + ∑ r (old) <c (l) * θ (t) * p * χ,

where ∑ r (old) is the sum of the maximum transfer rates of the already permitted flows, c (l) the available band width on link 1, θ (t) is the overbooking factor, p is the delay limitation factor and χ is the safety factor. Such access control can be carried out link-related, route-related or network-related.

In the case of a communication network, the route of the network (e.g. the route between two edge nodes) for which measured values are determined can be viewed as a virtual link with access control. The traffic flows between the two peripheral nodes run on physical links, which in some cases also provide bandwidth for traffic flows transmitted between other peripheral accounts. A virtual: link can also include alternative physical links. A peripheral node is also understood to be a node within the network that represents a source (or transmitter) or sink (or receiver) for data traffic. For traffic flows b> between Flows or connections that are to be transmitted via the link or between the peripheral nodes of the communication network are checked whether the transmission of the announced traffic volume (nominal value) would lead to the limit being exceeded.

The weighting of the ratios of measured values to nominal values can be carried out using a distribution function for the weighted ratios of measured values to nominal values. The weighting can be carried out using a weighting function. The weighting function is, for example, proportional to the n-fold power of the measured value or the nominal value. A reference value for the weighted ratios is determined in accordance with a truth value, so that the probability of the weighted ratios of measured values to nominal values exceeding the reference value is equal to the probability value. If there are multiple values for which the probable If the weighted ratios of measured values to nominal values exceeding the respective value is equal to the probability of water, it makes sense to determine the reference value as the minimum or infimum of these values. This rule applies, for example, if you set the probability value to zero. In this case, the reference value would be the largest ratio of measured value to nominal value that occurs. However, you can get a better utilization if you set the probability value to a small, finite value. The overbooking factor can then be set in proportion to the reciprocal of the reference value.

Another less elaborate way of setting weights is to take the weight one for measured values or nominal values above a threshold and to set the value zero for the weight below) the threshold. This means that ratios of measured values to nominal values with a low absolute value of the measured value or the nominal value are not taken into account for the determination of the overbooking factor.

According to a further development, the method differentiates between different traffic classes. I.e. Measured values are determined depending on the traffic class and overbooking actuators _determined for the different traffic classes. For traffic classes with high demands on the

Quality of service (eg so-called real-time traffic) can thus be a more conservative overbooking than for other ^" traffic classes ^" .

Measured values for calculating an overbooking factor can be determined for the entire network and used to calculate a network-wide overbooking factor. Old natively, overbooking factors can be calculated depending on the route. For example, the access control for a new one

Flow refer to traffic that has the same exit and exit node as the registered flow. In this

In this case, measured values can be determined for the links which are used by the traffic between the input node and the output node, and an overbooking factor for this traffic can be calculated.

The subject matter of the invention is explained in more detail below in the context of two exemplary embodiments. The first exemplary embodiment explains the principle of the invention on the basis of an access control relating to a link. The second exemplary embodiment explains which changes can be made to the first exemplary embodiment if the access control is not a link but a link

Network concerns. For this purpose, an example of an access control to this network is given with the help of a figure.

For better comprehensibility and for use in form, some sizes are introduced below:

• The parameter D is the average volume of traffic that is supplied to the system as an offer during the so-called busy hour. The parameter D is assumed to be constant for a longer time, but it can change over hours, days and weeks.

• B is the limit or budget for admission control. Budget B can be calculated using a traffic model based on D. For example, the calculation is based on the criterion that an incoming request is only rejected with a blocking probability of 10 ^{~ 3} . The parameter B is as firm as D. If D changes, B should also be redetermined in order to achieve the targets regarding the blocking probability.

• The variable A stores the aggregate rate of the permitted connections (i.e. all traffic transmitted via the link) according to the displayed traffic descriptions, i.e. according to the reservation request. A corresponds to the nominal value of all traffic permitted for transmission via the link. Approval is dynamic on request, which is why A (t) is a time-dependent variable. Let p≤l be the targeted maximum utilization of the resource (link capacity). Since not too much traffic may be permitted on a link, A (t) <θ * p * B (t) applies, where θ is an overbooking parameter or overbooking factor that is determined from time to time by the method according to the invention. The overbooking parameter is intended to compensate for the fact that the permitted connections usually do not send at their maximum rate but at a lower rate. With θ> 1 the reservable capacity of the resource can be increased.

• The variable M stores the measured aggregate rate on the link, ie M is the measured value of the total traffic permitted for transmission via the link. Rates can be measured as transported data per unit of time. A moving average over a measurement window of length I _M can be used to measure the aggregate rate. Like A (t), M (t) is a time-dependent ^" variable. There are M (t) <A (t). There are several reasons for this: o If the actual rate of an aggregate is greater than A (t), its packets are discarded by the policer at the network edge or at the node upstream of the link and its rate is therefore reduced to A (t). o Data streams begin to send after a reservation has been set up. o The traffic description of a connection is given conservatively in order to avoid losses due to rate checking in the network. o Connections have an on / off character, ie they do not always have something to send.

• The time-dependent variable Q (t) describes the quotient Q (t) = M (t) / A (t). Since M (t) is the measurement of permitted and rate-controlled traffic, (t) should be ≤l (whereby measurement errors are not considered). Q (t) is a measure of the inefficiency of access control, although it should be noted that Q (t) is usually less than 1 for the reasons mentioned above.

Since Q (t) fluctuates over time, this quantity cannot be used directly for overbooking (e.g. by choosing Θ = l / Q). In order to be able to maintain the required quality of service for the reservations even when overbooking with Θ> 1, a reference value U is used instead of Q (t), which is rarely exceeded accordingly. In the simplest case, U could be assumed, for example, as the maximum in time of Q (t): U = axQ (t). U is the maximum utilization of the system in typical condition, should represent a long-term value and be conservative. The following shows how a better value for U is determined according to the invention can be provided that typical measured values are the

Influence determination of U the most.

If A (t) and M (t) are small compared to B, with a setting U = maxQ (t) few compounds with an atypical M / A ratio can influence Q (t) very strongly. This is taken into account in the method according to the invention for the determination of U. The M / A ratios are weighted for this.

By correlating A (t) and M (t), the occupancy of the reservations can be determined relatively precisely. Average values would be very imprecise, a direct utilization of the transmission capacities would distort the picture due to the capacity of unused reservations.

The weight function W (t) assesses the meaningfulness of Q (t). For example, W (t) = M (t) ⁿ (n a natural number) can be selected. The size of M (t) (and over M (t) ≤A (t) also A (t)) is important and correlates this with the informative value of Q (t). For example, the number of active compounds or other quantities not mentioned here can also be included in this weight function.

The function leg is defined by. It the weight W (t) for Q (t) is defined via a measuring function j ^" W (x) dx θΩ.R (t) = = ^, so that for Q a distribution radio JW (x) dx

tion P (Q <u) can be learned. R (t) <l applies, thus also P (Q≤u) ≤l and thus P (Q≤u) is a distribution that is continuous

Measured value weighted with —— and thus proportional to W (t). dt

This method with continuous measurements is also on

Measuring method adaptable to discrete measuring points:

P (Q ≤ u) = ∑leq (Q (t _J ), u) -dR (t _J ) = _J leq (Q (t _] ), u) -, ^> '. ∑W (t _k ) k = -∞

Here it is assumed that all measuring intervals are of the same length. However, the method can also be easily adapted to measuring intervals of different lengths.

With the help of this distribution function, the 1-quartile for U can now be used: U = min {w \ P (Q ≤ u) ≥ l -ά]. The smallest value that is only exceeded by Q with a probability α is thus chosen for U.

The control method can be set more or less progressively using the α parameter. (α = 0 is the most conservative choice, where the maximum of Q is used for U. Larger values of α do the procedure conservative, but also less secure against violations of the guaranteed quality of service.) This makes it particularly suitable for real-time traffic. A safe starting value for the operation of a network is θ = l.

After some time (if there is enough statistical data to calculate U with a certain degree of certainty) Θ = l / U can be set. The value of U should be recalculated from time to time and θ adjusted accordingly. All data from the past can be included, or a selection can be made (e.g. time window or selection of the most relevant values of Q, i.e. those for which A or M were particularly large).

As an alternative or in addition to the calculation of Q (t) or U (t) shown above, a weighting function can be used that does not take measured values from small A (t) or M (t) into account at all. This step could also be introduced in the determination of θ:

If A (t) or M (t) is below a defined threshold (e.g. 0.1 * B), the measured value U is rejected and θ is left at the old value instead.

The parameters used in the process can be selected as follows:

The duration of a measurement interval I _M should be of the order of magnitude below a connection duration (<10s), since otherwise some connections cannot be recorded at all.

However, it should also be large enough that as many connections as possible send within this period (> 500ms). The duration of a measuring circuit should be chosen so large that sufficient statistical data are available to estimate U well. The method can also be given more or less memory by keeping the statistics for Q (t) over a more or less long time (several measurement cycles).

This procedure can be transferred from the access control of a pipe or a link to the access control of a network.

The figure shows a communication network with access control. Edge nodes are indicated by filled circles, inner nodes by empty circles. On the left are represented by connections between the nodes. An input node is labeled I, an output node E, and a link L, for example. Part of the traffic between nodes I and E is transmitted via link L. An access control at the input node I and at the output node E together with access controls at other edge nodes ensure that no overload occurs at the link L. The access control is carried out by means of a limit or a budget B (I, E) for the traffic transmitted between the nodes I and E.

The method described for a link can be used for the communication network by extending the variables to border-border (b2b) relationships or edge-to-edge relationships between the access node I and the output node E. In principle, any such relationship is considered a virtual link. o D becomes D (I, J) o B becomes B (I, J) o A becomes A (I, J) o M becomes M (I, J). M (v, w) can be determined on the policer, for example. But if that's through If measurements are to be made on links, one can measure their overall rate and divide this proportionally over all active border-b2b relationships proportional to A (I, J). The maximum of these measured values could then be taken for M (I, J), for example. o Q becomes Q (I, J). o U becomes U (I, J).

If one assumes that the statistical properties of traffic are the same everywhere, the aggregation of border-border b2b relationships can give maxi more statistically meaningful values. In this case, the variables are no longer managed using a b2b relationship, but e.g. only via access router or network-wide.

Claims

claims

1. A method for improving the utilization of a link in a communication network, wherein for data traffic to be transmitted via the link at least one traffic class, access control is carried out by means of a limit for all data traffic to be transmitted via the link, in which the link is overbooked Determination of the ratios of measured values of all traffic transmitted via the link to nominal values of all of the traffic authorized for access for transmission via the link, a plurality of ratios of measured values to nominal values depending on the size of either the measured value or the nominal value, so that for smaller measured values or nominal values their ratio has less of an impact on the determination of the overbooking than ratios of larger measured values and nominal values to one another.

2. Method for improving the utilization of a communication network formed with nodes, wherein for data traffic to be transmitted via the communication network, at least one traffic class is controlled by means of a limit for data traffic to be transmitted, in which

- An overbooking is determined according to the ratios of measured values of transmitted aggregated traffic to nominal values of aggregated traffic to be transmitted, whereby a plurality of ratios of measured values to nominal values are weighted according to the size of either the measured value or the nominal value, so that for smaller measured values or nominal values whose ratio is used to determine the over- booking has less impact than ratios of larger ones

Measured values and nominal values to each other.

3. The method according to claim 2, characterized in that - the admission control is carried out by means of a limit for the data traffic transmitted between two edge points of the communication network, and

- The measured values and the nominal values relate to the aggregated data traffic transmitted between the two boundary points.

4. The method according to claim 2, characterized in that

- two admission checks are carried out by means of a limit for the data traffic entering the communication network at an edge node or with a limit for the data traffic exiting at an edge node, and

- Data traffic is permitted if both approval controls are positive, and - The measured values and the nominal values relate to the aggregated approved data traffic.

5. The method according to claim 2, characterized in that - two admission controls are carried out for each link affected by the transmission of the data traffic by means of a limit for the data network entering at a peripheral node or with a limit for data traffic exiting at a peripheral node , and - traffic is allowed if all admission controls are positive, and - The measured values and the K-specific values relate to the aggregated permitted data traffic transmitted via an affected link.

6. The method according to any one of the preceding claims, characterized in that

- a distribution is defined for the weighted ratios of measured values to nominal values,

a reference value for the weighted ratios is determined in accordance with a probability value, so that the probability for weighted ratios of measured values to nominal values that exceed the reference value is essentially the probability value.

7. The method according to any one of the preceding claims, characterized in that

- the ratios of measured values to nominal values are weighted by means of a weight function which is proportional to the n-fold power of the respective measured value or nominal value, and

- n is a natural number.

8. The method according to any one of claims 1 to 6, characterized in that the ratios of measured values to nominal values are weighted by means of weights which are equal to one for ratios with measured values or nominal values above a limit and which are zero for ratios with measured values or nominal values below the limit.

9. The method according to claim 6 and 8, characterized in that it s s

- the probability value is zero.

10. The method according to any one of claims 6 to 9, characterized gekennz ei chne t, since ss - If there are several values, so that the probability for weighted ratios of measured values to nominal values exceeding the respective value is essentially the probability value, the reference value is defined as the minimum or infimum of these values.

11. The method according to any one of the preceding claims 6 to 10, characterized in that the overbooking is determined in accordance with the reciprocal of the reference value.

12. The method according to any one of the preceding claims, characterized in that the ratio of the measured value to the nominal value is equal to the quotient of the two values.

13. The method according to any one of claims 3 to 5, characterized in that the method is carried out for all paaxes of input nodes and output nodes of the communication network.

14. The method according to any one of the preceding claims, characterized in that a security factor is used in the access control, by which a security margin is defined for the bandwidth used, which should prevent full utilization of the existing Bandbxeite.

15. The method according to any one of the preceding claims, characterized in that a delay limiting factor is used in the access control, which is selected so that the expected delay in the transport of data packets does not exceed a selected threshold.

16. The method according to any one of the preceding claims, characterized in that the measured values used to determine the overbooking are aged.

17. The method according to claim 16, characterized in that the aging is carried out by multiplying the measured values used by an aging factor.

18. The method according to any one of the preceding claims, characterized in that

- a plurality of traffic classes is used and

- an overbooking is defined for each traffic class.

19. The method according to any one of the preceding claims, characterized in that

- Measured values are measured in relation to the entire communication network and an overbooking related to the entire communication network is determined, or - Measured values are measured in relation to a subset of the links in the communication network and an overbooking related to the subset of the links in the communication network is established.

20. The method according to claim 19, characterized in that

- The subset of the links is given by those links _Λ which are used by traffic transmitted between a fixed input node and a fixed output node.