SE514361C2 - Method and device in mobile packet data network - Google Patents

Abstract

The present invention relates to a mobile radio network that includes a packet service. The invention also relates to a method for controlling transmission quality over the radio connection downlink. This quality control is effected by receiving mobile terminal measurements. Measurement reports (MR) are sent in uplink at given intervals (IL). According to the method, the interval (IL) is varied in accordance with variations in transmission quality. The invention also relates to a packet control unit (PCU) that includes means for requesting measurement reports at intervals which are varied in accordance with the information contained in received measurement reports.

Description

20 25 30, 2 a Base Station Controller for evaluation.

In mobile radio networks built according to the TDMA principle, a physical radio channel, ie a certain time slot on a certain carrier frequency, is divided into a number of logical channels. The logical channels have access to the physical channel according to a strict schedule that is repeated cyclically. This is necessary for the receiver to know what type of logical channel son1 is being received and to process the received data correctly.

Each logical channel transmits a certain type of information. The largest access to the physical (Traffic Channel). logical channel that has the channel is the traffic channel It transmits information, such as speech between users. Another logic for transmitting measurement reports in the uplink SACCH channel was used from the mobile station, in the GSM system the channel is called (Slow Associated Control Channel). Both the traffic channel and SACCH use a physical channel dedicated to the connection with the mobile station. The interval with which measurement reports are sent uplink is thus governed by how often the SACCH channel is given access to the physical channel according to the schedule.

U.S. Pat. The node consists of a radio base station or a switch and has the task together with the included microprocessor to evaluate the transmission quality of radio connections. The evaluation is based on the results of measurements on each of these connections and may lead to a change of radio channel for one or more of the connections. The traffic load varies stochastically and especially during peak hours, the risk is imminent that not the need. the processor's capacity corresponds to the Node and the processor also has other traffic monitoring and control functions that suffer from overloading the processor. US 5,335,356 provides a solution to this problem in which the intervals at which the ndcroprocessor evaluates the transmission quality of a particular radio link varies depending on the result of previous evaluations of the measurement result.

Within standardization commissions for the GSM system, work is currently underway to standardize a new packet data service called GPRS (General Packet Radio Service).

Unlike a circuit-switched connection, a physical channel used for GPRS is available for transmission to from a downlink thus listening a number of mobile stations to a certain channel or a plurality of mobile stations. In order to find out if any of the packets sent over the channel are intended for your own mobile phone.

In the same way as with packet transmission over a fixed network, the receiver sends a response to the sender as to whether the content of received packets is correct or not. In the downlink, the mobile station is the receiver and sends in the uplink response in the form of messages ACK / NACK In the ACK / NACK message (acknowledge / not acknowledge). the mobile station also sends a measurement report of the transmission quality for a measurement period corresponding to the received packet (s).

Thus, for the radio channels used for GPRS, a different scheme was used for mapping logical channels on physical radio channels than that used for traditional circuit-switched connections in GSM.

According to GPRS, the measurement report is sent to a packet control unit for evaluation of the transmission quality. With GPRS, a new, additional, possibility is added to adapt the radio connection to the prevailing radio environment in order to maintain the desired transmission quality. The. new is that four different alternative coding schemes are available to protect the information on the radio link from being misinterpreted. Previously the same coding scheme was used for the radio connection. a coding scheme good good protection data and used that provides the information. The increased transmission capacity. transmitted price of redundancy in lower In good radio conditions, the data was used and as a coding scheme with lower redundancy in thus provides good transmission capacity on a given channel. Maintaining the right transmission quality by choosing a coding scheme thus means a balance between conflicting performance requirements. Operators of new car radio networks according to American standards, such as ADC (American Digital Cellular), also intend to introduce GPRS in their networks.

DISCLOSURE OF THE INVENTION The present invention addresses a problem1 which consists in maintaining sufficiently good quality at a fast, that, a mobile terminal even when radio environments due to radio channel change eg the terminal is moved, the terminal must always send night reports by the radio channel. frequent intervals. The measurement reports take some resources from other information that is transferred.

In addition, it costs battery capacity to send measurement reports.

An object of the present invention is thus to limit the number of measurement reports transmitted from the terminal, while maintaining a sufficiently good possibility of maintaining the quality of the downlink radio connection.

The solution is based on the observation that for packet-oriented data services it is possible to variably control the interval between the measurement reports that a certain terminal sends.

The above problems are solved according to the present invention by a method where the terminal is controlled to send measurement reports at an interval selected after evaluation of received measurement reports from the terminal.

(Packet arranged to during transmission of packet data The above problem is also solved by a packet data anode Control Unit) to a mobile terminal control the terminal to send at certain intervals, measurement reports in the uplink and with. means to be obtained during transmission select »interval based on measurement reports.

The independent requirements also state the solution to the problem.

The invention has the advantage that the speed in the link adaptation of the downlink is adapted to the radio environment in which each individual terminal is located. moves fast, the radio environment can change quickly. In an urban environment with so-called street corner effects, interference and thus the radio environment change very quickly when the terminal travels in a car that turns around a street corner. In such an environment, it is important that the link adaptation can be done quickly. obtained slow means that it is sometimes not adapted to radio conditions data At other times it means that data It requires measurement reports at short intervals. Makes the link adaptation too impaired and does not reach the mobile station. transmitted with too much redundancy and that the full capacity of the radio channel is thus not used.

For a terminal that moves slowly or is stationary, according to the invention, measurement reports will be sent at relatively long intervals in between. It has the advantage of drawing small battery capacity in the nw car. An additional advantage is that a smaller amount of measurement reports contributes to reduced total interference in the system.

A further advantage is that the operator of the car radio network does not have to adjust the interval so that a suitable compromise is obtained between different conflicting performance requirements.

This makes the radio network easier to operate.

The invention will now be described in more detail by means of preferred embodiments and with reference to the accompanying drawing.

FI GURE DESCRIPTION Figure 1 shows a block diagram of nodes in a known mobile radio network that supports a packet data service.

Figure 2a illustrates a stream of downlink radio blocks and some uplink radio blocks according to a previously known principle.

Figure 2b illustrates the corresponding current as in figure 2a but with a principle according to the invention.

Figure 3 shows a flow chart of the steps in a method according to the invention.

Figure 4a shows a diagram of the selected coding scheme at different times.

Figure 4b shows a diagram of the signal / interference ratio at different times.

Figure 4c shows a diagram of the signal variance at different times.

Figure 4d shows a diagram of interference at different times.

Figure 5 shows a block diagram of a packet data anode modified according to the invention.

Figure 6 shows in principle the format of a radio block.

Figure 7 illustrates a stream of radio blocks. 10 15 20 25 30 PREFERRED URMN ROOMS Figure 1 shows nodes in a GSM network PLMN that supports a packet data service called GPRS. The GSM network PLMN comprises a switch MSC connected to a line (General Packet Radio Service). base station switches BSC (Base Station Controlers). For simplicity, only one base station switch BSC is shown in Figure 1. The base station switch BSC connects to a series of base stations of which only one is shown in the figure to a BTS (Base Tranceiver Station) 1. The base station BTS has access to a set of radio channels for communication with a number of terminals MS.

Figure 1 shows only one terminal MS.

The switch MSC and the base station switch BSC are used for a circuit-switched connection between the terminal MS and a fixed telephone network PSTN.

The GSM network PLMN in Figure 1 also comprises a GGSN ll (Gateway connecting the GSM network PLMN to external GSM network PLMN comprises GPRS Support Node) packet data network, also an SGSN 12 to GGSN ll and a packet data node PCU SGSN 12, for example Internet.

(Serving GPRS Support Node) that connects (Packet Control Unit).

GGSN II and the packet data node PCU are used by the packet data service GPRS for the transmission of packet data between external packet data networks such as the Internet and the terminal MS. The packet data node PCU is connected to SGSN 12 and to the radio base station BTS.

In a practical system, a series of packet data nodes PCU are connected to SGSN 12, to a packet data node PCU, only one packet data node PCU and a base station BTS. as a series of base stations BTS are connected but for simplicity are shown here. Most important for this invention is the packet data node PCU and how it controls the terminal MS and the base station BTS when transmitting a stream S of packet data to the terminal MS. and SGSN 12 from ie in downlink. dataramar DF that comes via the Internet. These data frames DF are too large to be transmitted over a radio link and are therefore repackaged into smaller radio blocks RB in the PCU. PCU radio blocks RB to Between the base station BTS and the terminal MS, radio channel RDL radio blocks RB are downlinked.

The packet data node The BTS packet data node transmits the terminal MS via the radio base station. According to GPRS, transmission downlink and uplink are independent of each other and thus a radio channel downlink RDL is independent of a radio channel RUL used for uplink connection, i.e. from the terminal MS.

An important task for the packet data node PCU is Link Adaptation. This means evaluating the radio environment and the quality of the transmission over the radio link RDL and choosing a coding scheme for the transmission that is adapted to the radio conditions so that the desired quality is maintained during the transmission. For this purpose, the transmission and the radio environment are continuously measured. The measurement bit error content quality includes, for example, interference, and signal strength. For the downlink RDL, these measurements are performed in the terminal MS. The results of the measurements are sent as measurement data reports MR in uplink RUL, ie from the terminal MS to the packet data node, when the packet data node PCU so requests.

The packet data node PCU requests to receive a measurement report MR by providing a radio block RB with a request MR_req for one, whereupon the radio block RB is transmitted downlink. In order for the packet data node PCU measurement report MR, obtain a measurement report MR must be sold first request such a report MR. This is also called polling MRI measurement reports.

Using the most recently obtained measurement report MR, the packet data node PCU evaluates the quality (Link Estimation) of the radio link RDL downlink. The packet data node PCU designates one of four alternative coding schemes suitable for maintaining a desired downlink RDL quality in the current radio environment. In a difficult radio environment, a hard-coded schedule is selected. This means increased redundancy in the data, with a lower transmission rate for a certain bit error rate at the receiving terminal MS. With good radio conditions increased During, a scheme with less coding and thus transmission capacity is maintained at a bit error rate maintained. transmission of a stream of radio blocks RB sometimes the radio conditions change, rapidly, when the terminal MS is moved, while they are fairly stationary if the terminal MS is stationary.

The above is a previously known function of the GSM network PLMN.

In Figures 2a and 2b, each shows a stream S of radio block RB transmitted downlink from the packet data node PCU. Some of the radio blocks RB are provided with a request MR_req for measurement report and are shown shaded in the figure. In response to each MR_req request for measurement report, a measurement report MR is sent uplink from the terminal MS to the packet data node PCU.

Figure 2a shows, in a previously known manner, that radio blocks RB provided with request MR_req occur at constant interval IL.

Figure 2b shows that, according to the invention, the MR_req request for measurement report is sent downlink from the packet data node PCU at intervals IL having varying length.

Figure 3 shows, in a flow chart, the steps in a method according to the invention for selecting the length of the interval IL with which measurement reports MR are polled in dependent variations of the quality of the radio link RDL.

In a first step S1, a number of radio blocks are transmitted. RB in a current S downlink from the packet data node PCU to the terminal MS.

According to a subsequent step S2, the packet data node PCU supplies a subsequent radio block RB in the stream S, with a request MR_req for measurement report MR, whereupon the radio block RB is sent downlink.

The terminal MS receives the MR_req request for a measurement report and creates one. measurement report MR sent uplink, according to a following step S3. The measurement report MR is based on measurements 10 15 20 25 30 in 10 made in the terminal during the period after a previous measurement report. The measurement report contains measurements of signal strength, interference, signal variance and bit error content during the period.

PCU and buffer.

In a next step S4, the packet data anode receives measurement report MR. The measurement report MR is saved in a The measurement report MR is used as a basis for evaluating and selecting the coding scheme in a subsequent step S5.

The transmission of a stream S of radio blocks in downlink RDL continues. According to a subsequent step S6, a first number of radio blocks RB are retransmitted without request. measurement report MR from the packet data node PCU to the terminal MS. The first number corresponds to a certain predetermined length of the interval IL. Thereafter, the packet data node PCU again supplies a radio block RB in the stream with a request MR_req for measurement report MR, according to step S7.

The request MR_req for measurement report is received by the terminal MS and which then creates an additional measurement report MR, according to step S8. The additional measurement report is sent uplink.

The additional measurement report MR is received by the packet data node PCU and stored in the buffer, in a subsequent step S9. Then, the coding scheme for the radio link RDL is selected according to a step S10. The selection is also saved in a buffer for use in a subsequent step S11.

In step S11, the variation in the transmission quality is evaluated and based on the evaluation, a length is selected for the interval IL. The one radio block RB, selected length corresponding to the second number counted from the last sent request MR_req for measurement report to the next radio block to be provided with the request MR_req for measurement report. The evaluation is described further down after the method steps.

According to a next step S12, a second number of radio blocks RB are transmitted in downlink, without being provided with a request for measurement report MR. The last of these radio blocks RB in the stream S is provided with a request for measurement report MR, according to the following step S13.

Then repeat step S9 and subsequent steps in a loop.

The buffers used to save obtained measurement reports MR and selection of coding scheme are "of a certain When the buffer is filled the oldest data to make room for new when a new measurement report is obtained length. The saved is discarded and a new code is selected.

The loop S8-S13 is interrupted if the flow of data frames DF stops or if. the transmission is moved to another radio channel RDL. In the latter case, the steps in the method are started again with step 1 for the new radio channel RDL.

As a basis for the selection of intervals according to step S11, a change in transmission quality is evaluated. For this, the latest and previously received measurement reports MR and the most recent and previously made choices of the coding scheme are used. Figures 4a-4d each show a diagram. The horizontal axis in all diagrams does not correspond to time, but the time here is not stated on a linear scale but should be seen as a result of discrete points each corresponding to a measurement report obtained.

The diagram in. Figure 4a 'shows the selected coding scheme Cod, there are four alternative choices.

The diagrams in Figures 4b-4d show quantities obtained with the measurement reports MR. Figure 4b shows the signal interference ratio C / I. and in Figure 4c the signal variance sig_var Figure 4d shows the interference level I. In the evaluation, a value is determined for each of the diagrams. For example, based on the information in the Value, a first value V1 diagram is determined which shows the signal / interference ratio C / I. based on how large differences have occurred in the signal / interference ratio C / I for a number of measurement reports, on 10 15 20 25 30 12 if the differences have a tendency to increase or decrease and how fast and which direction the tendency has.

A second value V2 based on the information in the diagram sig_var soul shows the signal variance calculated with. using a sliding window. The sliding window WV is shown as a triangle with dashed lines in Figure 4b. The bars stp that fit within the window are multiplied individually by the height of the window located above the bar, the second value V2 is obtained by adding the products. Correspondingly, a third value V3 is calculated based on the diagram of interference I and a fourth value V4 based on the diagram Cod of selection of coding.

Each of the values V1-V4 is multiplied by a corresponding weight factor kl-k4 and added according to the following formula to obtain a value L: L = k1 * V1 + k2 * V2 + k3 * V3 + k4 * V4 The interval IL for requesting a measurement report MRI is determined on the basis of the value L. Possible values for I, are in advance divided into areas that correspond to possible lengths for the interval IL.

When selecting the weight factors kl-k4 in the formula above, it is appropriate to give the largest weight to the fourth factor SEK, ie the one that indicates the meaning of the value V4 corresponding to the diagram Cod for selection of coding. If, for example, the same coding has been chosen for a longer period, great importance should be attached to this and the interval IL for measurement reporting is thus chosen far.

Figure 5 shows the packet data node PCU modified according to the invention. The packet data node VPCU comprises a protocol converter 61 which connects to and to SGSN via a Gb interface the base station BTS via an Abis interface.

The protocol converter 61 receives in downlink, ie from the Gb interface a stream of data frames DF, repackets the information obtained from the data frames DF in radio block RB 10 15 20 25 30 13 which is transmitted in a string S downlink. The protocol converter 61 performs the reverse uplink operation, but for the invention, the downlink is primarily of interest. data frames DF received also include some SGSN 12.

In the control commands from Some of these control signals are intended for the packet data node PCU, others for the terminal MS. The radio blocks RB which are transmitted in downlink and received in uplink also include control signals. It is the task of the protocol converter 61 to identify these control signals and, if they are intended for the packet data node PCU, forward the control signals to the correct unit within the packet data node PCU.

The protocol converter 61 also supplies control signals to radio block RB on behalf of other units within the packet data node PCU.

For the invention, it is only of interest with certain control signals that have to do with link adaptation and therefore only these control signals are described. The link adaptation is controlled by a separate unit 62 within the packet data node PCU.

The unit 62 receives measurement reports MR obtained in uplink via a connection from the protocol converter 61. In the unit 62, the transmission quality is evaluated and a coding scheme for the radio connection RDL is selected. The selection of the coding scheme Cod is transmitted via a connection to the protocol converter 61. The selected coding scheme Cod is then transmitted as a control signal to the base station BTS in a radio block RB in the stream S.

The packet data node PCU also includes a buffer unit 63.

The buffer unit 63 is connected. against the connections between the link adaptation unit 62 and the protocol converter 61 and receives copies of the measurement reports MR and selection of coding scheme Cod. In the buffer unit 63, the reported interference I, the signal-to-noise ratio C / I, the signal variance itself_var and the selection of coding scheme Cod are stored in buffers comprising a number of recently obtained values. An evaluation unit 64 is connected to the buffer unit 63. In the evaluation unit 64 the 'values \ h-V4, a' value I. are calculated as above and an interval IL is designated, each time a new network report MR and selection of code Cod are stored in buffer unit 63.

Via a connection, the selected interval IL is sent to the unit 62 for link adaptation. the unit 62 After a period corresponding to the interval IL transmits to a request MR_req for measurement report the protocol converter 61. From the protocol converter 61 the request MR_req is sent to the terminal MS in a radio block RB. Only the buffer unit 63 and the evaluation unit 64 with associated connections need to be supplied to exercise the packet data node PCU for the invention. Other devices in the packet data node PCU are already known.

The components described above in the packet data anode PCU are realized as separate physical components.

Alternatively, they are designed as software blocks controlled by a common central processor.

In the case of link adaptation, the radio channel is treated separately for the connection with the terminal MS. By a radio channel is meant for a TDMA system such as the GSM network PLMN a certain time slot on a certain carrier. With GPRS it is possible to use several radio channels for the connection with the terminal MS. To cope with this, the buffer unit 63 must have separate sets of buffers for each radio channel that is link-adapted.

Figure 6 shows the principle of the format of a radio block RB which contains a request MR_req for measurement report. The radio block RB comprises a number of octets of eight bits each. The initial octet is a MAC head (Medium Access Control) with information that the following radio block RB is of the MAC head's fifth and type downlink radio link control. sixth bit was used to possibly indicate request MR_req of 10 15 20 25 30 'length for 15 measurement report, in GSM terms these bits are called "RRBP field".

V6.3.0E l0.2.l.

This is also described by the specification GSM 04.60 The radio block transmitted in the uplink and contains a measurement report MR also comprises a number of octets, the first a MAC header indicating that the radio block RB is of the type end of the radio block RB used for the measurement report MR. The content of the radio block RB is called an ACK / NACK message containing confirmation, uplink radio link control. The octets in also because because also or absence thereof, on that a number of radio blocks are received correctly by the terminal MS. The radio block RB which contains a night report MR is described in more detail in the specification GSM 04.60 V6.3.0E 10.2.2.

A radio block RB contains a quantity of data intended to be transmitted over a radio channel to the terminal MS in four bursts. Each burst is transmitted in a corresponding time slot. Each time slot has space in a corresponding TDMA frame. Each TDMA frame corresponds to a period of 4.6 ms and a radio block RB thus corresponds to a transmission period over the radio channel of almost 20 ms. The amount of data that can be transmitted during this period depends on the coding scheme Cod selected for the radio link. downlink to the selected coding scheme The amount of data transmitted in the radio blocks RB in from the packet data node PCU is adapted to Cod.

Figure 7 shows a principle where the length IL of the interval can be varied in steps of five radio blocks RB. The smallest possible interval IL is thus 5 radio blocks, ie closer to 100 ms between each request MR_req on, and obtaining a n fi trapping MR. The length of the interval IL is likely to be increased in steps of 5 radio blocks RB up to a maximum length of 10 fl; gßny. , '_ å' 'i 16 50 radioblock RB. a MR_req request for measurement report per second.

At maximum length of the interval IL is transmitted Steps S4-S7, alternatively to what is shown and described in connection with Figure 3, can be repeated a few times before selection of the interval IL length is started. By repeating steps S4-S5 a few times when the radio channel has started to be used, information is collected in the buffers from several measurement reports MR to be used in the evaluation and selection according to step S11.

In Figure 1, the packet data anode PCU is located next to the base station switch BSC. station switch BSC.

The packet data node PCU is independent relative to base packet data. The packet data node PCU then also handles control of the radio link for the radio channels used for packet data in the same way as the base station switch BSC handles control of the radio link for other channels used for circuit-switched connections. architectures are possible, however.

Sonx's example of packet data service in a mobile radio system1, the GPRS service in a GSM network has been used as an example. According to newspaper reports, the GPRS service will also be introduced in (American limited to the American mobile radio system ADC Digital Cellular). however, used only for GPRS but also used to advantage for the invention, packet data services with other names are not also implemented in mobile radio networks other than GSM networks PLMN.

The invention is of course not limited to the embodiments described above and shown in the drawing, but can be modified within the scope of the appended claims.

Claims (14)

10 15 20 25 30 i i '' 17 PAYMENT REQUIREMENTS A packet data anode (PCU) in a cellular radio network (PLMN) arranged to support a packet oriented data service, the packet data node, (61) first format from an external packet data network, repacking received data into blocks said block (RB) comprises means for taking receiving data frames (DF) with one (RB) having a second format and transmitting downlink, and is arranged to control a mobile terminal receiving said block (RB) (IL) (MS) over a radio link RDL, that at a certain interval transmit measurement reports (MR) over measured quality (RDL), characterized by (62, 63.64) measurement reports (MR) (IL) for the radio link to control the terminal by means of the content of said (MS) transmission of said measurement reports to adjust the length of the interval (MR). The packet data anode (PCU) according to claim 1, wherein said means (62, 63,64) comprises a buffer unit (63) the contents of obtained measurement reports (MR). to save Packet data anode (6l, 62,63) evaluation of the change in the quality of the radio link (RDL). (PCU) according to claim 2, wherein said means comprises an evaluation unit (64) for Packet data anode (PCU) according to claim 1 or 2, wherein said for link adaptation with means to (Cod). means comprises a unit (64) designating a channel coding scheme The packet data anode (PCU) according to claim 4, wherein (Cod) at least one of said measurement reports is designated based on evaluation of (MR). the channel coding scheme The packet data anode (PCU) (MS) is controlled to send a measurement report according to claim 1, wherein the terminal (MR) is supplied with a measurement report request (MR_req) for a measurement report, which is then sent downlink. A mobile radio network (PLMN) with a packet data anode PCU according to any one of claims 1-6. Method in a mobile radio network (PLMN) supporting a packet data service, comprising the steps of: - transmitting downlink (S1, S2, S6, S7) of a stream (S) of blocks (RB) to a receiving mobile terminal (MS) wherein also a request (MR_req) for measurement report is sent (S7, S13) at a certain interval (IL); - receiving (S4, S9) a measurement report (MR) in response to said request (MR_req), containing results of measuring the transmission quality downlink; know the following additional steps: selection (S11) of length for said interval (IL) based on an evaluation (S) of at least one obtained measurement report. Method according to claim 8, wherein said evaluation and selection (S11) is made each time a measurement report (MR) is obtained. (MR) (Cod) Method according to claim 8, wherein the measurement reports are also to be designated for (RDL). was used for coding scheme the radio link downlink A method according to claim 10, wherein the latest ones designated by said coding schemes (Cod) are saved for use in the evaluation and selection (S11). Method according to claim 8, wherein a sequence of the most recently obtained measurement reports (MR) is saved for the evaluation (S11). relatively short (Cod) Method according to claim 11, wherein an interval (IL) is selected if the coding scheme is changed 4? Üaä fi. 19 relatively often and a relatively long interval (IL) is selected if the coding scheme has not changed frequently. Method according to claim 11, wherein the length of the interval is selected relatively short in the case of large variations in transmission quality and relatively long in the case of small variations in transmission quality.