EP1829241A1

EP1829241A1 - Emission power control for packet transmission

Info

Publication number: EP1829241A1
Application number: EP05823527A
Authority: EP
Inventors: Jürgen MICHEL; Bernhard Raaf
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2004-12-22
Filing date: 2005-12-20
Publication date: 2007-09-05
Also published as: KR101236908B1; US20080159255A1; WO2006067135A1; DE102004061904A1; US8170476B2; KR20070086165A

Abstract

The invention relates to a method for transmitting data packets in a radio system between an emitter and a receiver, said method comprising the following steps: a. a nominal emission power for a data packet is determined according to a desired reception quality; b. the data packet is transmitted with an effective emission power; c. a new nominal emission power defined according to the reception quality for the transmission is calculated, taking into account the effectively applied emission power and the pre-determined nominal emission power; and d. the data packet is retransmitted with the new nominal emission power.

Description

TRANSMISSION CONTROL FOR PACKET TRANSMISSION

description

The invention relates to a method for transmitting data packets

The invention relates to a method for transmitting data packets in a radio system and to a corresponding communication device, a base station and the corresponding radio system.

The future Enhanced UMTS Uplink (E-DCH) will use packet-oriented transmission with fast hybrid ARQ (HARQ), similar to that already standardized for HSDPA, but unlike HSDPA, the Enhanced UMTS Uplink is subject to fast power regulation as described in Release 99. The transmission power of each channel (Release 99 and E-DCH) to be used is determined by so-called performance offsets for the DPCCH (Dedicated Physical Control

Channel, reference channel). The power offsets are communicated to the mobile station by signaling ("higher layer signaling") or calculated from reference data by a specified method. This ensures that each channel achieves the required target error rate on average.

If the mobile station exceeds its maximum allowed transmit power during fast power control, the transmit signal is scaled. Like the fast power control, this scaling works on a "slot basis" and does not change the power ratios of the channels to the reference channel. In Release 6, in addition to one or more Dedicated Physical Data Channels (DPDCHs) and Dedicated Physical Control Channels (DPCCHs), the transmit signal additionally consists of one or more Enhanced Dedicated Physical Data Channels (E-DPDCHs). Equivalent, the "slot-based" scaling then reduces the total transmit power at the terminal in Release 6 without changing the power ratios of the individual channels to the DPCCH The "slot-based" scaling is shown in Figure 1. It takes place after the summation of the transmit signal.

Since the quality of service of the Release 99 DCH is prioritized in relation to the service quality of the E-DCH channel in Release 6, in addition to the "slot-based" scaling, an "E-DCH TTI-based" scaling is additionally provided, which starts at the beginning E-DCH TTIs is performed. Thus, there are the following scaling methods in Release 6:

• Scaling only the E DCH channel ("E-DCH TTI based")

• and Scaling the E DCH and DCH Channels ("Slot Based") The main reason for the scaling is to prevent the mobile station from interfering with data transmission in adjacent frequency bands, for example due to the non-linearity of the amplifiers at the transmit power limit Transmission power limit are:

• "bursty" occurrence of a transmission overlap of channels with packet characteristics (eg simultaneous transmission of an HSDPA ACK / NACK and an E-DCH data packet)

• Changing the data rate of one or more transport channels, in particular changing the data rate on the DCH channel. • Deteriorating channel properties and therefore higher required transmission power

As described above, the E-DCH is a packet channel. In the case of power scaling, the transmitted packet is with transmit less energy than the target energy, thereby increasing the block error rate of this transmission over the target block error rate.

Already in UMTS Release 99, it was specified that when a mobile station threatens to exceed its maximum transmit power, the performance of all channels is scaled; H . is evenly reduced. In the case that in Release 6 (E-DCH) a packet transfer has to be scaled due to the mobile station's performance limit, a Release 99 equivalent procedure is used - as described. In addition, for the E-DCH still the so-called. "E-DCH only TTI based" scaling proposed, which works similar to the R99 scaling, however, only the E-DCH signal is scaled here In the case of the transmission of the E-DCH packets, the disadvantage of the scaling and thus of the target block error rate had to be reduced The missing energy of a transmission at scaling is also not taken into account in the case of a retransmission and thus also leads to an increase in the error rate in the retransmission.

Based on this prior art, it is an object of the invention to provide a means of transmission, which ensures a high transmission quality with satisfactory transmission quality.

This object is solved by the independent claims. Advantageous developments are the subject of the dependent claims.

For the transmission of a data packet from a transmitter to a receiver is a target transmission power for this Data packet determined. This determination takes place as a function of a reception quality with which the data packet is to be available at the receiver.

Such a desired transmission power is predetermined, for example, in particular for each transmission and is signaled, for example, by the receiver to the transmitter.

A transmission of the data packet takes place with an actual transmission power. This actual transmission power may deviate from the desired transmission power, for example, due to certain conditions.

A new desired transmission power is derived, taking into account the actually applied transmission power and the predetermined desired transmission power, whereupon a renewed transmission of the data packet takes place.

This method reduces interference and increases the transmission capacity by taking a new setpoint transmit power taking into account already transmitted "energy" and not using the default setpoint values.

In particular, the method has advantages when a difference between the actual transmission power and the desired transmission power is determined and this difference is added to a predetermined desired transmission power for the subsequent transmission.

An adaptation of the transmission power can be carried out in particular only to feedback from the receiver with respect to the reception quality. Furthermore, this adaptation of the transmission power once in total for the transmission of the data packet respectively . Alternatively, it is provided that the adaptation takes place for each time slot. Here, the transmission of the data packet takes place in a certain time interval, which is divided into time slots.

The desired transmission power may be derived as a function of the reception quality intended for the transmission or predetermined by a central network element such as a base station or in general to the receiver.

The invention further relates to a communication device for carrying out such a method as well as a central network element, which in particular can signal desired transmission powers, can determine a reception quality of data packets as well as feedback with respect thereto

Send quality and / or the behavior of the communication terminal according to this invention considered (eg, in the decision of future resource allocations). Furthermore, the invention relates to a corresponding radio system.

Further advantages are illustrated by means of selected embodiments with reference to figures, of which show:

Fig. 1: Representation of a HARQ operation, where the transmitter is at the transmission power limit and an energy correction with a reduction of the retransmission power and a chase combining is used.

FIG. 2: A summation and scrambling of the transmission signal in the communication device or, respectively, FIG. Terminal, with a scaling after a common modulation several signals is made.

FIG. 3: A spread and subsequent separate scaling of the E-DPCCH and the E-DPDCH 's FIG. 4: A spreading and subsequent separate scaling of the DPCCH and the DPDCH

Fig. 5: A spread and then separate scaling of the DPCCH and the DPDCH

Fig. 6: An E-DCH sum signal, the transmitter transmitting at the transmission power limit via a so-called "Time Transmission Interval" TTI as a time interval.

Before a detailed consideration of the figures, the following should be noted only for the understanding and not the limitation of an area of application of the invention: For each data packet transmitted, in particular a certain total energy or energy is required. Target energy required to process the data packet correctly with a given probability. This total energy can now be done by a single transmission with high transmission power or a multiple transmission with low transmission power. In the former case, there is a slight delay until the predetermined probability is reached, but at the same time undesired interferences usually have to be accepted due to the high transmission power. Fulfilling the

"Total energy condition" with only one transmission is thus only considered with high quality requirements, in particular high demands on a small delay, in the second case results smaller ones

Interference with greater delay. The multiple transmission will therefore be considered if the quality requirements are not so high. By Optimization of the transmission powers for the transmissions, an optimal profile can be found, which represents a best possible compromise between reception probability and delay and the interference generated. In general, the requirements for different services will be different so that the optimal transmission power depends on both the service being transmitted and the transmission (or transmission number, ie first transmission, second, third ...). Furthermore, before a description of the figures, the environment in which the invention is applicable is described:

A transmission of data packets takes place in a radio system between a mobile station as transmitter and a base station as receiver.

In the radio system or. Communication network resp. Communication system is a structure for exchanging data. This may be, for example, a cellular mobile radio network, such as the GSM network (GSM: Global System of Mobile Communications) or the UMTS network (UMTS: Universal Mobile Telecommunications System).

The radio system comprises at least two connection nodes, so there are also so-called point-to-point connections under this term. In a radio system, mobile stations are generally provided, which communicate with each other via a radio interface. In UMTS, the radio system has at least base stations, which are also called Node B here, as well as radio network control units or radio stations. Radio Network Controller (RNC) for connecting the individual base stations. The terrestrial radio access network resp. "Universal Terrestrial Radio Access Network" UTRAN is the radio-technological part of a UMTS network in which, for example, the radio interface is made available. A radio interface is always standardized and defines the entirety of physical and protocol

Specifications for data exchange, such as the modulation method, the bandwidth, the frequency deviation, access methods, backup procedures or switching techniques. The UTRAN thus comprises at least base stations and at least one RNC.

Base stations, in addition to RNCs, etc., are to be understood as central units in a communication network which, in the case of a cellular mobile network, serve mobile stations or communication devices within a cell, for example the first cell or the second cell via one or more radio channels. The base station provides the air interface between base station and mobile station, including at least one transmitting and / or receiving unit.

A communication device, in particular a mobile station or. Terminal can be any communication terminal over which a user communicates in a radio system FS. There are, for example, mobile terminals, such as mobile phones or portable computers with a wireless module, including. In UMTS, a mobile station is often referred to as user equipment.

In mobile communications, a distinction is made between two connection directions. The downlink or "Downlink" (DL) denotes the transmission direction from the base station to the mobile station. The opposite direction, the Upwards connection resp. "Uplink" (UL) denotes the opposite direction of transmission from the mobile station to the base station.

In broadband transmission systems, such as a UMTS mobile radio network, a channel is a subset of an available total transmission capacity, for example a frequency range. As a radio channel or channel is referred to in the context of this application, a wireless communication path.

In a mobile radio system, for example UMTS, two types of channels are provided for the data transmission: permanently assigned channels resp. "Dedicated Channels" and shared channels resp. "Common Channels". With the Dedicated Channels, a physical resource will only be used for the

Transmission of information reserved for a particular mobile station. The Common Channels can transmit information intended for all terminals, such as the primary common physical control channel PCCPCH in the downlink or all

Mobile stations share this physical resource.

The E-DCH through which a mobile station UE is allowed to send data to the base station when it receives a transmission permission from the base station may be considered as a kind of hybrid. On the one hand, the E-DCH is a dedicated channel because it connects exactly one mobile station to one or more base stations. On the other hand, as in the case of a common channel, a transmission permission is given by the base station. This is necessary so that the signal level at the base station does not become so high that it can not correctly decode the signals received from different mobile stations. In the following, reference will now be made to the exemplary embodiments.

In the case of a packet transfer with scaled

Transmission power is negatively confirmed by the base station (a NACK ("Not ACKnowledge") is transmitted to the mobile station by the base station), the repetition of the higher power (= energy) packet is transmitted according to the invention as the nominal power, at least if this is due to It has already been proposed to send retransmissions at lower energy than the first transmission, in which case it may well be possible that there is no transmit power limitation in the retransmission, but also a channel state change may result in the repetition scaling is no longer necessary, so that the packet energy can even be adjusted according to the scaling in the first transmission.The goal is to ensure that the total energy from scaled transmission and repetition at the receiver (= base station) equals the sum meneergie without scaling is. The remaining residual error rate after receipt of the repetition then corresponds to the targeted target rate (the residual error rate after the second transmission is then exactly the same as if no scaling had taken place during the first transmission and the second transmission with the nominal power had been sent). According to the invention, it is thus ensured that the sum energy from first transmission and

Repeat transmission at the receiver in case of scaling equal to the sum energy without scaling is. The remaining residual error rate after a packet transfer with scaling and "packet energy adjustment" to NACK thus corresponds to the residual error rate of a transmission as if no scaling had taken place.

In Fig. 1 is a representation of a HARQ operation at the transmit power limit with energy correction when using a HARQ with "Retransmission Power Reduction" and "Chase Combining".

A HARQ operation is a packet - oriented data transmission in which the correct or incorrect reception of a packet with a corresponding acknowledgment, an "Acknowledge" or ACK with correct and an "Emergency Acknowledge" resp. NACK is confirmed in case of incorrect reception. Furthermore, a forward error correction resp. FEC, which is realized for example by a convolution coding or turbo coding.

"Retransmission Power Reduction" means that transmissions following the first transmission result in a reduction of the transmission power, which is due to the fact that for a correct decoding of a received data packet, this must be received by the receiver with a certain total energy more to provide the total transmit power when decoding is based on different received versions of the received data packet, the latter being called "chase combining". Of course, the invention is not limited to the example Chase Combining, but also applicable to other methods, eg. B. so-called . "Incremental Redundancy" or "Fill Incremental Redundancy". In Fig. l the packet transmission of a transmitter is shown in the upper part 1, in case no scaling is necessary. In this case, the energy used for a transmission is shown in each case as a rectangle.

The middle part of the image in area 2 shows the packet transmission of a transmitter which has to be scaled due to the transmission power limit. The illustrated rectangles again correspond to energies.

The lower part 3 shows the energy IEE in the soft buffer of the receiver for the case without scaling, which corresponds to the energy IES of the first transmission of the data packet on the receiver side.

Furthermore, the energy 2EE is represented in the soft buffer of the receiver, which represents the received portion of the energy 2ES for the case with scaling. It can be seen that, due to the scaling, the energy in the soft buffer of the receiver after receiving the first transmission in case b) is lower than in case a).

According to one embodiment of the invention, a power correction is performed, whereby after the retransmission the energy in the soft buffer of the receiver is the same in case c) without original scaling (case a) and in case d) with original scaling (case b) and corresponds to the intended one Target energy. In case c), a power control takes place here, that the energy IES on the transmitter side is increased by dlES by the energy dlEs is spent in the first retransmission for the packet. Thus, the target energy ETotal is achieved as the sum of DLEE and IEE. In case d), in the retransmission, the energy ES reduced by scaling during the first transmission is added to the energy dlES for the repetitive data packet. Thus, on the receiver side, the total energy ETotal is the sum of 2EE, DLEE, EE.

The methods described above offer the following advantages for a data transmission method in the case of power scaling:

• Compensate for the lack of energy due to scaling in a subsequent repetition

• The residual error rate, d. H . the probability that a packet can not be received correctly even after receiving the retransmission, also corresponds to the targeted target residual error rate when scaling

• Preventing Higher Layer Retransmissions Increase Due to Power Scaling Higher layer retransmissions are necessary, even if a maximum number of retransmissions does not allow error-free reception, then higher levels typically initiate a repetition of a larger Dante block, which is significantly more costly is as a repetition of a (sub) package at Layer 1 level.

• Reduction of transmission delay due to power scaling FIG. 2 explains embodiments in a UMTS system:

Fig. 2 shows the generation of the UMTS transmission signal in the terminal, as described in particular in the specification 25.213 v6.1.0

(Version 6.1.0), which describes the introduction of E-DCH for Release 6. The DPCCH, one or more DPDCHs, the HS-DPCCH and one or more E-DPDCHs are replaced as shown in FIG. 2 summed up.

A) According to a first embodiment, a scaling S, which is time slot based in this case, takes place after a summation and a common modulation.

The in Fig. 2 not shown in detail spreading is for DCH, HS-DPCCH and E-DCH in Fig. 3 to 5 shown. In "slot-based" scaling, the power of the transmission signal S is scaled by a constant factor β, and the ratios of the amplification factors in the individual branches (β _hs ^ βd, and β _e d, k to β _c ) change In this case, according to a first embodiment, this does not occur, that is to say a saccination takes place only as shown in FIG. 2 after the common modulation.

B) According to another embodiment, a

Scaling on the E-DCH-TTI boundary ("E-DCH TTI based" scaling), with a correction made as follows:

• There is data with a specific transport format.

• At the time of transmission, the required transmission power for the transport format already in place is higher than the maximum available power for the E-DPDCH (s) in the terminal.

• Instead of the β _ed , k values calculated (or signaled from signaled reference values), reduced (lower) β values β _e d, k, sz are calculated on the basis of the "TTI-based" scaling. B. used during the initial transmission of a packet. The reduction is chosen so that the transmission power limit is not exceeded when using the reduced beta values.

• If there is a retransmission, the energy transmitted in the initial transmission is not taken into account. The correspondingly corrected ß values for the repetition ß _e d, k, korr are calculated as follows (for which only "E-DCH TTI based

Scaling ", γ is equal to 1 in the following):

• Consideration also for others

Repetitive transmissions the energy lacking in the previous transmissions due to scaling results for the nth transmission = (n-1) th repetition (we start at the counting method with the 0th transmission as initial transmission) the following corrected β value:

respectively .

• This can also be represented iteratively:

These formulas can be interpreted as follows: The transmission power used is the nominal transmission power plus the difference between the power actually used and the power previously provided.

Another embodiment is to approach the root in a serial iteration in the above iterative approach, or even a linear one

Approximation to use, z. B.

This series development brings particular advantages because the exact calculation of the root requires a very complex algorithm. However, the calculation of the beta values must be carried out very frequently, namely for every time slot. In addition, there is very little time available for the calculation since it can only be performed when the power control command has been received. Furthermore, it has to be considered that the beta values are only used in a quantized way and that the multiplications with these values have to be carried out even one or more times per chip (chip: duration after spreading). The loss of accuracy due to this discretization is i .A. greater than the loss of accuracy due to the approximation of the root function.

C) According to a further embodiment, a scaling in the TTI ("slot-based" scaling) with correction takes place, as will be explained below:

• Within a transmission block (E-DCH TTI), the power limit of the mobile station is reached in at least one slot and "slot-based" scaling is performed.

• Figure 6 shows the behavior of an UE at the

Due to the power control, the E-DCH UE transmission power limit is exceeded in slot 11. The transmission proportion is highlighted, which is scaled accordingly, ie the proportion that is not sent Mobile station in such a case, not exactly, with how much power it sends too little, only that it sends too low power. According to the invention, the required power is estimated with a step size of the power control. This is usually a conservative estimate, d. H . i. a. In fact, the performance will actually be too low by a larger proportion.

Determination of the ratio of the scaled packet energy received at the base station to the packet energy received without scaling at least at the base station:

Since the packet energy received at the base station can only be estimated without scaling, it is also possible to take this into account in the γ factor by means of the correction factor K:

Number of time slots to be scaled OC Increment of fast power control (linear, i.e. the power after applying a step to increase the power behaves to the power before the step like 1: OC, so OC> 1. In the usual IdB Steps is OC = 1, 26. N _TTI number of time slots of an E-DCH TTI K correction factor

• Compensation of the energy in the repetitive transmission by correction of the β values as described in B), but with the γ factor calculated here and β _e d, k, s, i = βed, k, i - where γ ₀ refers to the in the initial transfer performed "slot-based" scaling and Ji on the in the first

Retransmission carried out "slot-based" scaling, etc. D) According to another embodiment both a scaling at the TTI limit ("E-DCH TTI based" scaling) and in the TTI ("slot-based" scaling) with correction takes place:

This embodiment combines the consideration of the two scalings, so it is a combination of the two previous embodiments.

• There is data with a specific transport format

(i.e., the number of data in the burst is present), at the time of transmission the required transmit power is higher than the maximum available E-DPDCH power

• In addition, within a transmission block (E-DCH TTI) in at least one slot, the power limit of the mobile station is reached and carried out "slot-based" scaling

• Compensation of energy as described in B) and with the γ factors as described in C).

E) According to a further embodiment, the scaling is limited to maximum values

• Especially in the case that multiple transmissions, so z. B. First transmission and one or more retransmissions must be scaled, it may be that by taking into account the past scaling for the current transmission of ß value is relatively increased, z. B. by more than 3dB. Although such a high increase is in principle necessary to achieve the nominal error rate, but a transmission with quite high power also brings disadvantages: It produces increased interference for other transmissions, which might also have not been foreseen there. Furthermore, the transmission energy will then usually be too large in the sense that in a large part of the cases, a much lower energy for a successful

Transmission would have been sufficient. The surplus part of the energy was then used uselessly.

• In this case, it can be provided that the power resp. the ß values are maximally increased by a certain amount (or a maximum factor) compared to the nominal values. The value used is thus calculated from the maximum of this maximum value and the value calculated according to a preceding exemplary embodiment.

• Note: Especially in this case, the error will not be noticeable by the approximation of the root, since in this case the deviation from the nominal β value will be quite small, and the

Approximation for small x only a small one

Has errors.

Furthermore, it should be noted that mobile stations are subject not only to restrictions in terms of maximum transmission power, but also to minimum transmission power, ie. H . that the mobile station always must send with a certain minimum power, even if the base station signals that the power should be reduced. The reason for this is that elements of the signal generation can not be cost-effectively built with any dynamics. For example, the

Dynamics of a digital-to-analog converter limited. In this case, a scaling of the total signal is also made, only naturally to the (then higher) minimum power. In the foregoing, it has always been assumed in the examples of the embodiments that too little energy was expended. Of course you can use the formulas and methods even if too much energy was used.

In a further preferred embodiment, however, a distinction is made as to whether too much or too little energy has been expended. If too little energy is used, the correction is performed as described. But if too much energy was used, then the correction is not performed, or only moderately.

This suggestion, which is at first sight unreasonable, can be explained in this way. B. On the other hand, the question of energy for retransmission is only raised if the previous one

Transmission could not be successfully performed. In this case, even too much energy was not enough to transmit the packet correctly. It is then not useful to provide the retransmission with too little energy. This is particularly clear when you look at a special case: It may be that in the first transmission already so much Energy was expended, as was intended for first transmission and the next transmission. In this case, if you apply the correction, you would send the retransmission with energy 0, which of course is nonsensical. In this case, there should be no reduction of the transmission power / energy to 0, but it should be sent with a certain minimum power. Advantageously, it is thus possible to use a method similar to the method of limiting the correction shown above, except that a limitation of the correction is to be applied to a certain minimum. D. H . one selects the transmission power as the maximum of a predetermined minimum power and the reduced power transmitted in the previous transmission taking into account the excessive transmission power.

Claims

claims

A method of transmitting data packets in a radio system, between a transmitter and a receiver, comprising the steps of: a. Determining a desired transmit power for a data packet in response to a desired receive quality; b. Transmitting the data packet with an actual transmission power; c. Deriving a new target transmission power taking into account the actual transmission power and the target transmission power; d. Repeated transmission of the data packet with the new target transmission power.

2. The method of claim 1, wherein for the derivation in step c) the difference between the desired transmission power and the actual transmission power for at least one previous transmission is determined and this

Difference is added to the desired transmission power.

3. The method of claim 1 or 2, wherein the data packet is transmitted during a time interval, which is divided into a plurality of time slots and the receiver of the data packet the transmitter for each time slot transmitted a power control feedback, which indicates whether a power control of the transmission power should take place and the new target transmission power in step c) for a subsequent time slot below

Considering the actually used transmission power for the data component is derived in the time slot.

4. The method according to any one of the preceding claims, in which for each jerte packet for each transmission a reception quality for the reception at the receiver is provided and the predetermined target transmission power for the subsequent transmission in step d) depending on the intended for the transmission Reception quality is defined.

5. The method according to any one of the preceding claims, wherein a maximum transmission power in the transmission of a data packet is predetermined and a deviation of the actual transmission power from the target transmission power is caused by exceeding the maximum transmission power.

6. The method of claim 5, wherein for deriving in step c) it is assumed that in time slots, in which the power control does not lead to exceeding the maximum transmission power, the actual

Transmission power equal to the target transmission power is selected and it is assumed that in time slots in which the power control would lead to exceeding the maximum transmission power, the actual transmission power by a certain ratio is less than the target transmission power.

7. The method according to the preceding claim 6, wherein the power control is performed in predetermined increments and the determined ratio corresponds to a power control step size.

8. Method in which a plurality of data transmission channels are provided, the data of which are transmitted in common data packets and a desired transmission power is adjusted after a common modulation of the data in the data packets.

9. A method in which a plurality of data transmission channels are provided, the data is transmitted in common data packets and a target transmission power is performed before merging the individual data transmission channels.

10. The method according to any one of the preceding claims, wherein in d) the repeated transmission on request.

11. A communication device having a transceiver for transmitting and / or receiving data and a processor unit configured to perform the steps of: a. Determining a desired transmit power for a data packet in response to one of the desired receive qualities; b. Transmitting the data packet with an actual transmission power; c. Deriving a new target transmission power taking into account the actually applied transmission power and the predetermined target transmission power, which is defined in dependence on the intended for the transmission reception quality; d.

Repeated transmission of the data packet with the new target transmission power.

12. Central network element, in particular base station with a transmitting / receiving unit for transmitting and / or receiving data and a processor unit, which is set up for performing the following steps: a. Receiving data packets; b. Examining data packets for their reception quality; c. Transmitting a feedback regarding the reception quality to a sender of the data packet.

13. A radio system with at least one communication device according to claim 11 and a central network element according to claim 12.