DE10161135A1 - Method and device for dynamically regulating the allocation of resources to a plurality of data streams competing for these resources in a communication network - Google Patents

Abstract

A specific portion (RS) is taken from a resource pool (RP) for each competing data stream (RPS) and allocated. On the basis of measurement data, dynamic adjustments are made if necessary, in that the RPS involved return unneeded resources to the shared RP or larger portions of the shared RP are assigned to them. If the resource requirement reaches a predefined threshold value close to the assigned RS, then its share is increased insofar as there are still unassigned resources in the RP. If an increase in the RS is not possible, then it is only checked after a specified period of time whether an increase is necessary (measured demand has reached threshold value) and is possible. Conversely, a certain part of an RS is returned to the common RP if it was not needed for a predetermined period of time. If, however, the common RP is filled at least up to a predetermined threshold value, the return is not carried out and a first check is again carried out to determine whether the returned portion is not required for a further period of the predetermined length.

Description

The invention relates to a method and a correspondence rende device for dynamic control of resources Allocation to a number of competing for these resources Data streams in a communication network, the resources to be allocated in a resource pool from the competing data stream for each a share of resources is extracted and added to this data stream is arranged.

In future, IP networks that are in use today will be additional Offer transportation services that are subject to availability of bandwidth, delay, delay jitter and the Packet loss rate significantly below today's quality of service divorce.

The abbreviation IP stands for "Internet Protocol" Protocol of the TCP / IP family at layer 3 of the OSI reference model. IP is for the connectionless transport of data responsible from the sender over several networks to the receiver, whereby no error detection or correction takes place, d. H. IP care does not care about damaged or lost packages. The datagram is the central data-carrying unit in IP defined, which can have a length of up to 65535 bytes.

IP is used by several overlying protocols, mainly from TCP (Transmission Control Protocol, a connection-oriented transport protocol, which is a logical Full duplex point-to-point connection enables), but also by UDP (User Datagram Protocol, a connectionless application protocol for the transport of datagrams of the IP family).  

Data to be transferred are above such protocols accepted by IP and fragmented by the sender, d. H. in Disassembled datagrams. On the receiver side, these become again composed, whereby one speaks of defragmentation. IP is regardless of the medium used and also for LANs (Lo cal Area Networks), WANs (Wide Area Networks) and for mobi suitable networks.

Access to the new transportation services mentioned above is required protected by admission control (AC). This creates the problem with the transmission available in IP networks resources on competing transportation services and traffic currents must be divided. The resources need both on the various transport services, as well as on the con a transport service's increasing traffic flows different network accesses arising, can be divided.

Unfavorable allocations lead to poor utilization (if more resources are allocated to a traffic flow than he needs and therefore no longer needs these resources for others are available), or clearly perceptible to the user re quality losses (high blocking rate, large delays up to Packet loss if too few resources are allocated). he Adding to this is the fact that resource requirements are difficult highly fluctuating statistical quantity to be estimated.

This problem is solved in telephone networks by so-called hop-by Hop-AC solved by call. Transfer this solution to Today, experts consider IP networks to be impracticable assessed, at least not for large networks.

At the moment there is intensive work on solutions for resource management worldwide management for DiffServ network. According to the DiffServ basic ideas searched for solutions to the resource cen inside the network efficiently with little effort on aggregator split traffic flows.  

In the article "Adaptive Resource Control for QoS Using an IP-based Layered Architecture ", Martin Winter (Editor), EU Deliverable IST-1999-10077-WP1.2-SAG-1201-PU-0 / b0, June 2000, a concept is proposed, that with the help of so-called Resource pools a dynamic resource allocation in IP Introduces networks.

In "An Adaptive Algorithm for Resource Management in a Dif ferentiated Service Network ", E. Nikolouzou, G. Politis, P. Sampatakos, I.S. Venieris, National Technical University of Athens 2000, an associated process is described that does the actual resource allocation. This procedure However, simulation has proven difficult to control and not shown to be robust against overload. The real thing The goal of an automatic resource allocation becomes not reached because of the sensitivity of the tax para meters compared to the traffic load the administrator ver Drive constantly watch and set the parameters carefully must.

The object of the present invention is therefore to a way to create that available resource a lot of competing traffic flows are split up and this division dynamically the current condition conditions is adjusted.

According to the present invention, this object is achieved by a method for dynamically regulating a resource allocation to a plurality of data streams competing for these resources in a communication network, the resources to be allocated being made available in a resource pool from which for each competing data stream a resource share is taken and assigned to this data stream, whereby

• - a dynamic adjustment of resource requirements for one Data flow takes place when resource requirements increase  if possible, a correspondingly larger share of resources is assigned or resources no longer required to the Resource pool are returned for what
• - a temporal course of the resource requirements of the data current is determined and with a predetermined threshold will compare with
• - as soon as the resource requirement reaches the threshold or exceeds
• - The allocated resource share with still existing white other resources in the resource pool is increased, or
• - otherwise only after a specified period of time it is checked again whether the resource requirements still exist or again reaches or exceeds the threshold and whether again resources in the resource pool ready for allocation hen.

The resources do not have to be physically in a Res resource pool provided, taken from or to there to be returned. That's just the perspective of the resource Administration. The resource pool is used to manage the resources shared by all competitors.

A reduction of resources is carried out according to the present invention by

• - a resource portion of the resource that is no longer required cen pool is returned if
• - This was not needed for a given period of time and if
• - The resource pool is not at least up to one threshold is filled.

It has proven to be beneficial if, in the event that the resource pool at least up to the predetermined second threshold is filled, first checked again whether the share of resources to be returned for a white tere second period of the specified length is not required  becomes.

The above measures of the invention can be preferably se can also be combined.

For the allocation of free resources, it has gone further than it is advantageous if one is no longer required Resource share is returned to the resource pool if the resource needs a predetermined lower threshold value reached or fallen below.

This can be further improved by automatically adapting the lower threshold value to the resource requirements, where at

• - This lower threshold is reduced when resources returned to the resource pool more often than necessary become, or
• - this lower threshold is increased if in a no predetermined portion of resources in the third predetermined period Resource pool was returned.

In many cases, it is particularly recommended that the first Threshold close to the currently allocated share of resources is specified.

To verify local synchronization of resource adjustment avoid, is further according to the present invention suggest that the first period and / or the second time span and / or the third time span continuously by addition or subtracting random values, especially small ones Random values, is varied.

Furthermore, the object of the invention is also achieved by a corresponding device, in particular a resource management system, with the following features:

• - a pool of resources for the provision of shares to be shared Resources from which to compete for each data stream  Share of resources can be extracted and assigned to this data stream is where
• - a means of dynamically adjusting resource needs is provided for a data stream with which increased If possible, a correspondingly larger resource requirement Resource share can be allocated or res resources can be returned to the resource pool, for what
• - a temporal course of the resource requirements of the data current is determined and with a predetermined threshold will compare with
• - as soon as the resource requirement reaches the threshold or exceeds
• - The allocated resource share with still existing white other resources in the resource pool is increased, or
• - otherwise only after a specified period of time it is checked again whether the resource requirements still exist or again reaches or exceeds the threshold and whether again resources in the resource pool ready for allocation hen.

The means for dynamically adapting the resource requirement for a data stream can further be designed such that if resource requirements increase, if possible

• - A correspondingly larger proportion of resources can be allocated or resources that are no longer required to the resource pool are returnable, whereby
• - a resource portion of the resource that is no longer required cen pool is returned if
• - This was not needed for a given period of time and if
• - The resource pool is not at least up to one threshold is filled.

Furthermore, it has proven to be advantageous if through the means for dynamic adjustment of resource requirements in the event that the resource pool at least up to that predetermined second threshold is filled, first again  it is checked whether the resource portion to be returned for another second time span of the specified length is not is needed.

According to a further advantageous development of the inventor device according to the invention is dynamic by the means Adjustment of resource needs a no longer needed Resource share (RS) returned to the resource pool (RP) bar if the resource requirement is a predetermined lower Threshold reached or fallen below.

It has proven to be advantageous if the means for dynamically adapting the resource requirement can be used to automatically adapt the lower threshold value to the resource requirement by

• - This lower threshold can be reduced if resource cen returned to the resource pool more often than necessary be, or
• - This lower threshold can be increased if in one no predetermined portion of resources in the third predetermined period Resource pool was returned.

The measures according to the invention described the Resource usage optimized and an elaborate and difficult to do dominant manual control is superfluous. network utilization and transmission quality are optimized.

An important aspect of the invention lies in the way in which the measured values are evaluated and actions for changing the resource allocation are derived:

• - limiting the return of unnecessary resources in the RP,
• - The use of time periods to avoid unnecessary activity brakes,
• - the way in which it is determined whether resources are available should be returned,  
• - Determining the proportion of resources that go into the pool to be returned.

Further advantages and details for realizing the present The invention can be seen from the following description benen advantageous embodiments and in connection with the figures. In principle, it shows:

Fig. 1 shows a section of a larger IP network, the ver different transport services with different quality of service (Quality of Service QoS) supports.

FIG. 2 is an example of the activity of a Leaky Share in a resource management system (resource share manager RSM) based on the processing of an AC request,

FIG. 3 is an example of the activity of a Leaky Share in a resource management system (resource share manager RSM) based on the processing of an AC release,

Fig. 4 is an example of the activity of a Leaky Share in a resource management system (resource share manager RSM) using a call to the method AC release, when an activated release timer expires,

Fig. 5 a reaction of a resource management system RSM to an AC request; If the proportion of resources used exceeds the threshold values w _h , the RP requests additional resources,

Fig. 6 is a processing of a resource request in a resource pool manager (resource pool manager RPM)

Fig. 7 is a processing of a resource release in a resource pool manager (resource pool manager RPM)

Fig. 8 is a reaction of a resource management system RSM to an AC release,

Fig. 9 shows an embodiment of a retry filter on the processing of an AC requests in the resource management system RSM,

Fig. 10 is an example of the activity of the adaptive-Watermark process in a resource management system RSM, based on a processing of an AC Request

Fig. 11 shows an embodiment of an adaptive filter on the RETRY processing an AC requests in the resource management system RSM,

FIG. 12 is an example of the activity of an adaptive leaky Share's in a resource management system RSM to manage the processing of an AC request,

Fig. 13 based on the processing of an AC release for the activity of an Adaptive Leaky Share,

FIG. 14 is a call to the method AC-release for the activity of an Adaptive Leaky Share when an activated release timer expires and

Fig. 15 is a processing to a timeout of a release timer in the RSM.

For the individual exemplary embodiments, the English-language concise terms introduced above are assigned to the individual embodiments of the invention as follows:

The embodiments can be divided as follows:

The illustration in Fig. 1 shows a detail from a larger IP network with network nodes 1 to 5, the different transport services supported (with different QoS). For a specific transport service, 20 Mbps of the connection from node 4 to 5 are reserved there. Traffic flows or data flows that want to use these resources are controlled by a respective access control or admission control AC assigned to nodes 1 , 2 and 3 . A resource manager RSM (resource share manager) is added to each of the AC modules.

Each RSM controls the resource allocation for that of him represented traffic flow, controlled by the associated AC is gated. The RSM shares this via the interface to the AC AC with the available resources and vice versa Measured values necessary for resource control. If necessary an RSM gets additional resources from the joint Res resource pool RP (resource pool).

For this purpose, in this exemplary embodiment node 4 is assigned a resource pool manager RPM (resource pool manager) which manages the common resource pool RP. The RP contains the available resources. Initially, the RP contains the 20 Mbps to be shared (available resources on the node 4 to 5 link) and the resource portion of each RSM is 0 Mbps.

During network operation, the RSM resources pull out the common RP and give resources that are no longer needed back there.

To dynamically regulate the allocation of resources according to the invention, each of the two modules RSM and RPM now each requires a method for the allocation and a method for the release of resources:
RSM release: A process that decides whether and how many resources are returned to the RP. Returns resources to the RP using the RPM-release function if required (eg "Leaky Share" or "Adaptive Leaky Share").

RSM request: A procedure that decides whether and how many additional resources are requested from the RP. Get if necessary using the function RPM request resources from the RP (e.g. "Retry Filter" or "Adaptive Retry Filter").

RPM-release: A process that is no longer available on request withdraws necessary resources and into the managed RP provides.

RPM request: A procedure that decides whether on request and how many resources from the managed RP to an RSM to be shared.

According to a first embodiment of a method for dynamically regulating the allocation of resources in communication networks according to the invention, the so-called "leaky share", the resource pool (RP) initially contains the resources to be shared (for example a certain proportion of the capacity a connecting line as between the two nodes 4 and 5 ). For each of the traffic flows competing for the pool, called RPS (resource pool shareholder), a certain share, called RS (resource share), is extracted from this RP and assigned to it.

Based on measurement data, as described below, if necessary, dynamic adjustments made by the be RPS shared unnecessary resources in the common Return RP, or give them larger shares from the common assigned to RP.

For each RPS, the time course of the resources measured as required (e.g. based on the bandwidths of the AC requests and AC releases). If the resource requirement reaches a pre given threshold near the assigned RS, then will be Share increased, insofar as resources not yet allocated in the RP are present. If an increase in the RS is not possible, then it is only after a predetermined period of time again checked whether an increase is necessary (measured demand has reached the threshold) and is possible.

Conversely, a certain part of an RS is sent to the common men RP returned if this for a given time span was not needed. Is the common RP however filled at least up to a predetermined threshold value, then the return will not be made and first again checked whether the portion to be returned for another time span of the specified length is not required.

In the following, the operations for the above-described method according to the invention are described in more detail using a pseudo code of a programming language. The following parameters are used for this.

Each running in a RSM and an RPM after-described actions are also shown in Fig. 2 to Fig. 7, as follows in the form of respective flowcharts Darge provides, particularly with respect to a software implementation of the invention.

Processing in the RSM module

With each AC request, the AC module informs the RSM of the additionally required bandwidth r _a and triggers the following processing:
if (u + r _a ≧ w _h r AND t _req ≦ t) then request additional re sources of size of n _req .r _a from RPM;
if (returned bandwidth b = 0)
then t _req = t + d _req ;
else r → r + b;

With each accepted AC request, an AC module informs the RSM of the additionally required bandwidth r _a and triggers the following processing:
u → u + r _a ;
if (u <r - n _rel ) then t _rel → t _rel + d _rel ;

With each AC release, the AC module notifies the RSM of the bandwidth r _a no longer required and triggers the following processing:
u → u - r _a ;
if (u ≦ r - n _rel AND t _rel ≦ t)
then
offer RPM to give resources of size of n _rel back to RP;
if (release was accepted) then r → r - n _rel ;
t _rel → t _rel + d _rel ;
fi;
if (u = 0) then activate a timer that triggers next resource release after d _rel ;

The figures Fig. 2 to Fig. 4 show corresponding steps for a RSM in flow chart form with the above-feed-th parameters. FIG. 2 shows the activity of a leaky Share's in a resource management system RSM based on the processing of an AC request, the FIG. 3, the activity of a Leaky Share in an RSM based on the processing of an AC release, FIG. 4 finally the activity of a Leaky Share in an RSM using a call to the method AC-release, when an activated release timer expires.

The illustration in FIG. 5 shows a response of a resource management system RSM to an AC request; transfrontier tet the proportion of resources used to threshold values w who requested the additional resources from the RP _h.

Processing in the RPM module

For each resource request with an additional required bandwidth r _a :
R → R - min (n _req r _a , R);
return size of bandwidth assigned additionally, which is min (n _req r _a , R);

For each resource release with bandwidth r _b :
if (R ≧ R _max )
then refuse release;
else accept release and set R → R + r _b ;

FIG. 6 shows a corresponding processing of a resource request in a resource pool manager RPM, FIG. 7 shows a processing of a resource release in a resource pool manager RPM.

A variant for an RSM request is to use a so-called "retry filter". There are only differences in the function of the RSM, the actions of the RPM remain unchanged. The associated actions are shown in Fig. 2 to Fig. 4 and Fig. 9 as follows in the form of respective flowcharts shown.

The illustration according to FIG. 8 shows a corresponding reaction of a resource management system RSM to an AC release. If the proportion of resources used falls below the threshold value w ₁ , some of the resources that are not required are returned to the RP. FIG. 9 finally shows the Ver processing of an AC request in the resource management system RSM for a Retry filter.

To avoid synchronization, the used Differences of time by adding small random values be decorated.

An alternative embodiment of the invention is based on dynamic regulation of resource allocation in Communication networks with adaptive threshold values.

For the resources to be shared, e.g. B. a certain proportion of the capacity of a connecting line between the network nodes 4 and 5 , a resource pool (RP) is also set up. From this, RSM (resource share manager) can extract resources for the traffic flows they represent and, conversely, return resources that are no longer required. Each RSM, in turn, continuously checks on the basis of measurement data whether, on the one hand, the allocated resources can be used to meet the demand and, on the other hand, it is possible to forego some of the allocated resources.

As soon as the measured bandwidth requirement a certain (above If the threshold value is reached or exceeded, the RSM catches up additional resources from the common RP, if this is not empty. Is a resource increase because of a lee RPs not possible, another demand for one locked for a period of time to avoid unnecessary load the.  

As soon as the measured bandwidth requirement reaches or falls below a second (lower) threshold value, the RSM returns part of the unneeded resources to the shared RP. According to the invention, the RSM automatically adjusts this threshold value to the traffic load as follows:
If an RSM detects that it is returning resources too often, the threshold is reduced. If an RSM determines that it does not return any resources within a certain time interval, the threshold value is increased.

The main training here is adaptation the threshold for the return of resources and in Braking the activity after an unsuccessful attempt, additional to get resources from the joint RP.

In the following, the operations for the method described above with adaptive threshold values according to the invention are again shown in more detail in the form of respective flow charts. The following extended parameters are used for this.

The processes occurring in an RSM and an RPM respectively actions in adaptive thresholds are also shown in FIG. 5 to FIG. 7 and in Fig. 10 as follows in the form of the respective flow charts.

The illustration according to FIG. 10 shows the essential steps for the activity of the adaptive watermark method in a resource management system RSM based on the processing of an AC request.

A variant for an RSM request for this purpose is to use a so-called "adaptive retry filter". Differences only exist in the function of the RSM, the actions of the RPM remain unchanged. The related actions of RSM are indicated in FIG. 2 to FIG. 4 and FIG. 11 as follows in the form of respective flowcharts shown.

The Fig. 2 to Fig. 4 have already been described. The illustration according to FIG. 11 shows the processing of an AC request in the resource management system RSM for an adaptive retry filter.

Another advantageous alternative according to the present Invention is based on dynamic regulation of the Resource allocation in communication networks using a dynamic release rate. For the resources to be shared the already known Resource Pool (RP) is set up. From this, RSM (resource share manager) for the If necessary, resources and ge Conversely, resources that are no longer needed are returned there back. Each RSM uses measured data to continuously check whether On the one hand, the needs are met with the allocated resources can be allocated and whether on the other hand to a part of the resources can be dispensed with.

An RSM determines that more resources are needed than are available to him, e.g. B. in that the measured Bandwidth requirement reaches or exceeds a threshold, then he gets additional resources from the common one RP, insofar as it is not empty. Is a resource increase Hung not possible because of an empty RP, another can Demand locked for a period of time in order to be unnecessary to avoid heavy loads.

To determine if part of the allocated resources can be dispensed with, the RSM checks according to the invention  ongoing whether a certain share of resources for a certain Number of consecutive AC requests not required becomes. Only then will this share of resources be returned.

An essential step lies in the procedure according to which a decision is made about the release of resources and after which the activity is slowed down after an unsuccessful attempt to obtain more resources from the shared resource pool RP:

• a) Is for a sequence immediately consecutive AC requests with a certain length a certain res resource share is not required, then this share will be returned given. After each return, the same procedure is followed rechecked whether another portion will be returned can.
• b) In the event that none for a certain period of time AC requests arrive, e.g. B. the time span in which the test sequence according to (a) would be expected, as in (a) a be certain share of resources returned.
• c) Proposes an attempt to extract additional resources from the ge to get joint RP, then further attempts will be made Restrict resources from increasing until a certain number successive AC requests arrived is.

In the following, the operations for the above-described method with dynamic release rate according to the invention are again illustrated in the form of respective flow diagrams. The following parameters are used for this.

The processes occurring in an RSM and an RPM respectively actions in adaptive thresholds are also shown in FIG. 5 to FIG. 7 and in Fig. 12 to Fig. 14 as follows in the form of the respective flow charts.

The illustration in Fig. 5 has already been explained. FIG. 12 now shows an example of the activity of an adaptive leaky share in a resource management system RSM based on the processing of an AC request. FIG. 13 shows this on the basis of the processing of an AC release for the activity of an adaptive leaky share and FIG. 14 finally shows a call of the method AC release for the activity of an adaptive leaky share when an activated one Release timer expires. Finally, FIG. 15 illustrates an alternative for processing a timeout of such a release timer in the RSM.

Simulations have shown that these methods are in accordance with the invention work reliably and robust and easy to taxes are.

In the RSM, each of the above and in the Figures shown method used for who alone the. Each of the release procedures can theoretically work with anyone the request procedure can be combined: e.g. B. "Leaky Share" with "retry filter" (see table above). Processing in RPM is the same in all exemplary embodiments.

Claims (14)

1. A method for dynamically regulating a resource allocation to a plurality of data streams (RPS) competing for these resources in a communication network, the resources to be allocated being made available in a resource pool (RP) from which for each competing data stream (RPS ) a resource share (RS) is extracted and this data stream is assigned, whereby
A dynamic adaptation of the resource requirements for a data stream takes place by allocating a correspondingly larger proportion of resources if possible, or returning resources that are no longer required to the resource pool (RP), for what purpose
a time course of the resource requirements of the data stream (RPS) is determined and compared with a predetermined threshold value, wherein
as soon as the resource requirement reaches or exceeds the threshold,
the allocated resource share (RS) is increased if there are still other resources in the resource pool (RP), or
otherwise, it is only checked again after a specified period of time whether the resource requirement still reaches or exceeds the threshold value again and whether resources are again available for allocation in the resource pool (RP). 2. Method for dynamically regulating a resource allocation to a plurality of data streams (RPS) competing for these resources in a communication network, the resources to be allocated being made available in a resource pool (RP) from which for each competing data stream (RPS ) a resource share (RS) is extracted and this data stream is assigned, whereby
A dynamic adaptation of the resource requirements for a data stream takes place by allocating a correspondingly larger proportion of resources, if possible, or returning resources that are no longer required to the resource pool (RP), if resource requirements increase
a no longer required share of resources (RS) is returned to the resource pool (RP) if
this (RS) was not needed for a predetermined period of time and if
the resource pool (RP) is not at least filled up to a given threshold. 3. Method for dynamically regulating a resource allocation to a plurality of data streams (RPS) competing for these resources in a communication network, the resources to be allocated being made available in a resource pool (RP) from which for each competing data stream (RPS ) a resource share (RS) is extracted and this data stream is assigned, whereby
A dynamic adaptation of the resource requirements for a data stream takes place by allocating a correspondingly larger proportion of resources if possible, or returning resources that are no longer required to the resource pool (RP), for what purpose
a time course of the resource requirements of the data stream (RPS) is determined and compared with a first predetermined threshold value, wherein
as soon as the resource requirement reaches or exceeds the first threshold,
the allocated resource share (RS) is increased if there are still other resources in the resource pool (RP), or
otherwise it is only checked again after a first predetermined period of time whether the resource requirement still or again reaches or exceeds the first threshold value and whether resources are again available for allocation in the resource pool (RP), and where
a no longer required share of resources (RS) is returned to the resource pool (RP) if
this (RS) was not needed for a second specified period of time and if
the resource pool (RP) is not filled to at least a second predetermined threshold. 4. Procedure for the dynamic regulation of a resource allocation on a variety of competing for these resources Data streams (RPS) in a communication network according to claim 2 or 3, in the event that the resource pool (RP) at least up to the predetermined second threshold ge is filled, it is first checked again whether the withdrawn resource share (RS) for another second time span of the specified length is not required. 5. Procedure for the dynamic regulation of an allocation of resources on a variety of competing for these resources Data streams (RPS) in a communication network according to claim 1, where a no longer required share of resources (RS) the resource pool (RP) is returned when the Res resource requirement reaches a predetermined lower threshold or falls below. 6. A method for dynamically regulating a resource allocation to a plurality of data streams (RPS) competing for these resources in a communication network according to claim 5, wherein the lower threshold value is automatically adapted to the resource requirement by
this lower threshold is reduced if resources are returned to the resource pool more often than necessary, or
this lower threshold value is increased if no resource portion has been returned to the resource pool in a third predetermined time period. 7. Procedure for the dynamic regulation of a resource allocation on a variety of competing for these resources Data streams (RPS) in a communication network according to claim 1, 3, 4, 5 or 6, the first threshold being close to the current allocated resource share is specified.   8. Procedure for the dynamic regulation of a resource allocation on a variety of competing for these resources Data streams (RPS) in a communication network according to one of the preceding claims, wherein the first period and / or the second period and / or the third period continuously by adding or subtracting random values, in particular which is varied by small random values. 9. Device for dynamically regulating a resource allocation to a plurality of data streams (RPS) competing for these resources in a communication network ( 1 ... 5 )
a resource pool (RP) for the provision of resources to be allocated, from which for each competing data stream (RPS) a resource portion (RS) can be taken and assigned to this data stream, where
a means for dynamically adapting the resource requirement for a data stream is provided, with which, if possible, a correspondingly larger proportion of resources can be allocated in the event of an increased resource requirement or resources that are no longer required can be returned to the resource pool (RP), for which purpose
a time course of the resource requirements of the data stream (RPS) is determined and compared with a predetermined threshold value, wherein
as soon as the resource requirement reaches or exceeds the threshold,
the allocated resource share (RS) is increased if there are still other resources in the resource pool (RP), or
otherwise, only after a predetermined period of time is checked again whether the resource requirement still or again reaches or exceeds the threshold value and whether resources in the resource pool (RP) are again available for allocation. 10. Device for dynamically regulating a resource allocation to a plurality of data streams (RPS) competing for these resources in a communication network ( 1 ... 5 )
a resource pool (RP) for the provision of resources to be allocated, from which for each competing data stream (RPS) a resource portion (RS) can be taken and assigned to this data stream, where
a means for dynamically adapting the resource requirement for a data stream is provided, with which, in the event of an increased resource requirement, a correspondingly larger proportion of resources can be allocated if possible or resources that are no longer required can be returned to the resource pool (RP), wherein
a no longer required share of resources (RS) is returned to the resource pool (RP) if
this (RS) was not needed for a predetermined period of time and if
the resource pool (RP) is not at least filled up to a given threshold. 11. Device for dynamically regulating a resource allocation to a plurality of data streams (RPS) competing for these resources in a communication network ( 1 ... 5 )
a resource pool (RP) for the provision of resources to be allocated, from which for each competing data stream (RPS) a resource portion (RS) can be taken and assigned to this data stream, where
a means for dynamically adapting the resource requirement for a data stream is provided, with which, if possible, a correspondingly larger proportion of resources can be allocated in the event of an increased resource requirement or resources that are no longer required can be returned to the resource pool (RP), for which purpose
a time course of the resource requirements of the data stream (RPS) is determined and compared with a first predetermined threshold value, wherein
as soon as the resource requirement reaches or exceeds the first threshold,
the allocated resource share (RS) is increased if there are still other resources in the resource pool (RP), or
otherwise it is only checked again after a first predetermined period of time whether the resource requirement still or again reaches or exceeds the first threshold value and whether resources are again available for allocation in the resource pool (RP), and where
a no longer required share of resources (RS) is returned to the resource pool (RP) if
this (RS) was not needed for a second specified period of time and if
the resource pool (RP) is not filled to at least a second predetermined threshold. 12. Apparatus for dynamic control of a resource allocation to a plurality of data streams competing for these resources (RPS) in a communication network ( 1 ... 5 ), according to claim 10 or 11, wherein the means for dynamically adapting the resource requirement for in the event that the resource pool (RP) is filled at least up to the predetermined second threshold, it is first checked again whether the resource portion (RS) to be returned is not required for a further second period of the predetermined length. 13. Device for dynamic control of a resource allocation to a plurality of data streams competing for these resources (RPS) in a communication network ( 1 ... 5 ), according to claim 9, wherein the means for dynamic adjustment of the resource requirement is no longer a required resource share (RS) can be returned to the resource pool (RP) if the resource requirement reaches or falls below a predetermined lower threshold value. 14. Device for dynamically regulating a resource allocation to a plurality of data streams (RPS) competing for these resources in a communication network ( 1 ... 5 ), according to claim 13, wherein the means for dynamically adapting the resource requirement to the lower threshold value is automatically adaptable to the resource requirements by
this lower threshold can be reduced if resources are returned to the resource pool more frequently than necessary, or
this lower threshold value can be increased if no resource portion has been returned to the resource pool in a third predetermined time period.