SE512310C2 - Method, device, base station system and radio unit for processing data frames in a packet data radio system - Google Patents

Abstract

The present invention relates to methods and means for processing data frames in a packet data radio system. Data frames (A1, B1-B2) with specified time out periods are submitted to a second protocol layer (PL2) and segmented into radio blocks (Rb) which are transmitted to users (A, B) over a radio link (L). Radio blocks (Rb) not correctly received are re-transmitted. The number of re-transmissions is recorded to calculate the BLER. A transmission time for each data frame (A1, B1-B2) in the second protocol layer (PL2) is estimated. Data frames (A1, B1-B2) with transmission times exceeding a remaining time of their respective time out periods are flushed. The remaining data frames are scheduled to minimise the number of time outs before they are transmitted. The flushed data frames are re-submitted from a first protocol layer (PL1) to the second protocol layer (PL2).

Description

15 20 25 ä 512 310 destination but does not need to know which radio protocols are used, or how the physical radio resources are used. On the contrary, the BSS ignores the overall network and switching structure. The BSS simply receives addressed data units from the SS and uses its radio resources, as it can transmit the received units to the correct address. The advantage of this division into SS and BSS parts is that one part can be improved, or even replaced, without affecting the other.

In e.g. a GPRS system, incoming data packets (eg IP packets) in an LLC protocol layer in the SS are segmented into smaller data packets, “LLC frames”. The LLC frames are addressed and output to an RLC protocol layer in the BSS where the LLC frames are segmented into smaller data units, “RLC blocks” - the RLC blocks are transmitted one by one via a radio link to a radio unit. When all RLC blocks in an LLC frame have been successfully received by the radio unit, the LLC frame is reconstructed in an RLC protocol layer in the radio unit and forwarded to the LLC protocol layer in the radio unit. When a radio unit has received a ständ complete and correct LLC frame, an acknowledgment is sent back to the LLC protocol layer in the SS.

An LLC frame that has not been acknowledged within a set time (in GPRS typically 3 seconds) is considered lost and retransmitted to the BSS from the SS. In the same way, an LLC frame that has received a negative acknowledgment of the radio unit is transmitted from the BSS to the radio unit.

From a user perspective, total throughput is the number of LLC frames successfully transmitted via the GPRS system per unit of time. Existing data packet processing methods are based on service quality, data packet arrival times and possible data packet deadlines, which are allocated to data packets based on associated service quality.

Said processing methods do not relate to the two-level protocol structure (with an LLC protocol layer and an RLC protocol layer) in a GPRS-like system.

Existing technology in a GPRS-like radio data system does not fully optimize the use of radio resources, leading to poor throughput.

US-A-5440545 discloses a packet switching system and method for acknowledging receipt of a number of packet fragments. A source device allocates extra bandwidth resources to retransmit packet ment agments lost or destroyed during the first transmission.

US-A-5 5 153 85 discloses an apparatus and method for limiting the delay in a communication system by eliminating the risk of duplicate data frames.

US-A-5487068 discloses a method for reducing transmission delays in a packet delayed data communication system by eliminating the need to make an additional request to allocate a channel when a segment retransmission is required. As will be seen herein, each of the device and methods described in these patents are of different types and construction than the methods and devices of the present invention.

Summary The present invention encounters some problems related to optimizing the processing of frame packet data where a data frame includes a number of data blocks.

A problem occurs when a data frame to be transmitted to a user / system via a radio link is timed out before the transmission is] incomplete.

Additional problems arise when data blocks sent to a user / system via a radio interface for the first time have to be retransmitted via the radio link when the associated data frame is timed out.

In light of the above, a primary object of the present invention is to provide methods and apparatus for processing data blocks in a packet data radio system.

A further object of the invention is to provide methods and devices for efficiently using the bandwidth in the system.

Another object is to process the data blocks in a packet data radio system in such a way that a maximum number of corresponding data frames transmitted via a radio interface are acknowledged before they are timed out. 10 15 20 25 i 512 510 Another object of the invention is to minimize the number of unnecessary transmissions via a radio link due to time out of the data frames.

In a method according to the invention, a transmission time for completely transmitting a data frame via a radio link is estimated and this information is used to determine whether the data frame can be completely transmitted before it is timed out. The method also uses the information to plan the schedule in which the data frames are to be transmitted.

According to one embodiment of the method, a second protocol layer sends data frames to a user. The block error rate (BLER) is measured in the second protocol layer by registering the proportion of the radio blocks sent to the user that must be retransmitted. Using this information and information about the radio resources to be allocated for the transmission, the transmission time of each data frame stored in or during the transmission from the second protocol layer is estimated. If the estimated transmission time of any data frame is greater than the remaining time of a time out period for that data frame, the data frame shall be flushed in the second protocol layer. The transmissions in the remaining data frames, from the second protocol layer, are planned to minimize the number of data frames that are timed out in the second protocol layer. According to a retransmission protocol in a first protocol layer, the first protocol layer retransmits a new data frame, identical to the flushed data frame to the second protocol layer.

A system and a radio unit include means for using the method of the present invention. According to an embodiment of the radio unit, the radio unit comprises means for estimating radio resources to be allocated for transmissions; measure the block error rate (BLER); estimating the transmission time of each data frame in the second protocol layer of the radio unit; detect in advance whether timeouts will occur; and plan the order in which the data frames are to be transmitted from the radio unit.

If a timeout for a data frame is detected in advance, the radio unit has means for stopping and rewinding that data frame immediately.

According to an embodiment of the system, the system comprises means for estimating the radio resources to be allocated for transmissions; measure the block error rate (BLER); estimating the transmission time of each data frame in the second protocol layer of the system; plan the order in which the data frames are to be transmitted from the system; and detect in advance if a timeout will occur. If a timeout of a data frame is detected in advance, the system means to immediately stop and flush that data frame.

An advantage of the invention is that the radio resources are not wasted on data frames which are estimated to be time-triggered and which are to be retransmitted anyway. Thus, the bandwidth in the system is more often used for useful transmission, which in turn increases the data throughput and reduces the delay.

Another advantage is that the transmission is less sensitive to periodic interference which can completely block a connection to one user, thus causing long delays to other users in the system. 5 15 310 Another advantage is the risks of sending the same computer twice due to retransmission to a second protocol layer of a data frame which is still transmitted the first time is eliminated.

Brief description of the device Fig. 1 is a view of a block diagram of a GPRS system.

Fig. 2 shows an LLC frame segmented into a number of RLC blocks.

Figs. 3a-c show an example of a known data frame processing scenario.

Figs. 4a-b show a circuit diagram of the first embodiment of a method according to the invention.

Figs. Sa-d show a data frame processing scenario using the first embodiment of the method in Figs. 4a-b.

Figs. 6a-b show a circuit diagram of a third embodiment of the method according to the invention.

Fig. 7 shows a block diagram of an embodiment of the device according to the invention.

Detailed Description of Embodiments The present invention relates to methods and apparatus for processing data frames in a packet data radio system in a manner that results in more efficient use of the radio resources and good throughput. The packet data radio system should preferably comprise a protocol layered structure, where in a specific layer, a first packet data unit delivered to the specified layer is further segmented (divided) into smaller second packet data units before transmission via a radio link to a user / system. The first packet data unit delivered to the specified layer is sent to the specified layer unless it has been acknowledged that it has been correctly received by the user / system within a certain time.

The packet data radio system may, for example, comprise a first subsystem and a second subsystem serving a number of users with radio units, the first subsystem, the second subsystem and the radio units comprising a first and a second protocol layer.

Fig. 1 shows a schematic block diagram of a GPRS system 100 which is an example of a packet data radio system comprising an LLC protocol layer PL1 as the first protocol layer, and an RLC protocol layer PL2 as the second protocol layer (LLC = logical link control and RLC = radio link control). .

The GPRS system 100 in this example includes a switching system SS, a base station system BSS and a number of users A-C with radio units RU1-RU3.

The LLC and RLC protocol layers PL1 and PL2, respectively, in radio units RU2 and RU3 are not shown in Fig. 1. At least one radio link L is used for radio transmissions between the base station system BSS and the users A-C. The base station system BSS is 10 15 20 25 -_ 512 310 connected to the switching system SS via a trunk line T1. The switching system SS can, for example, be connected via a trunk line T2 to a fixed data communication network, for example an Intranet, Internet or to the public telecommunications network (PSTN).

In the GPRS system 100, incoming data packets (eg IP packets) are segmented via a trunk line T2 to SS to data frames (LLC frames) with a maximum length of 1.5 kbytes. The LLC frames are processed in the LLC protocol layer PL1 within the SS.

The LLC frames are sent via a trunk line T1 to the RLC protocol layer PL2 in BSS where they are segmented into data blocks, RLC blocks. The number of RLC blocks that include an LLC frame depends on the size of the LLC frame and the (radio block) encoding used. In GPRS, an LLC frame is typically segmented into 30 to 80 RLC blocks. The RLC blocks are adapted to be transmitted one by one via the radio link L.

The LLC protocol layer, defined in the technical specifications of GPRS TS GSM 04.64, is a protocol layer that operates between a switching node and a radio device. According to one aspect of GPRS, the LLC protocol layer is segmented and addresses incoming data packets from all applications that use GPRS (eg TCP / IP) to LLC packet data devices ("LLC frames"). The LLC protocol layer then uses more primitive radio interface protocols, e.g. an RLC protocol that a carrier service used to transmit the LLC frames to the par [peer] LLC logical device in the radio device. In the LLC protocol layer of the radio unit, the LLC frames are received, the application data units are reconstructed and forwarded to the application. The LLC protocol layer can operate in acknowledgment mode, in which case each LLC frame is acknowledged upon successful receipt at the receiving end. In this mode, LLC frames that have not been acknowledged to the transmission side within a certain time are timed and retransmitted to the receiving side. 10 15 20 25 -g 512 310 10 The RLC protocol layer, defined in the technical specification for GPRS TS GSM 04.60, is a protocol layer operating between a BSS node and the radio unit. According to one aspect of GPRS, the RLC protocol layer is segmented and LLC frames received from the LLC protocol layer are addressed to radio blocks ("RLC blocks"). The radio blocks are then transmitted via the radio interface, possibly using an acknowledgment mechanism in the RLC protocol. In a receiving radio unit, the RLC protocol layer is responsible for reconstructing LLC frames and for forwarding the LLC frames to the LLC protocol layer in this unit.

Fig. 2 shows a view of radio block Rb belonging to a segmented LLC frame Lf in a packet data radio system, e.g. a GPRS system. The LLC frame Lf and its radio block Rb are an example of a data frame comprising a number of data blocks.

Figs. 3a-c show an example of a prior art data frame processing scenario used in the GPRS system 100 in Fig. 1. The details of the SS, the first protocol layer PL1, user C and the radio units of users A, B, and C are not shown in these fl gures. Users A and B share a radio link L with a capacity of 50 radio blocks per second. The block error rate (BLER) is 25% for both users.

An ARQ (Automatic Repeat Request) protocol is used, so that a radio block that has not been received correctly by a radio device in the system is retransmitted. LLC frames A1 and B1-B2 have a timeout period set to 3 seconds. If the SS does not receive a receipt from the BSS within 3 seconds of an LLC frame being sent from the SS to the BBS, this LLC frame will be retransmitted to the BSS. 10 15 20 25 '_ 512 510 ll Times T are introduced in the text below to simplify the description of the scenario and make it clearer and easier to understand. The times T are not shown in the figures.

According to Fig. 3a (T = 0), the BSS is busy sending an LLC frame B 1, one radio block Rb at a time, to user B via the radio link L. The RLC protocol layer PL2 in the BSS receives an LLC frame A1 addressed to user A from the SS. LLC frame A1 is stored and segmented into 60 radio blocks in the RLC protocol layer PL2. The radio blocks are not shown in the figure.

Upon completion of the transmission of the LLC frame B 1, in Fig. 3b (T = 1.6 seconds), the BSS starts sending the LLC frame A1, one radio block Rb at a time, to user A via the radio link L. At the same time, after confirmation fi from an LLC protocol layer in the radio unit of user B to SS to have successfully sent LLC frame B1 to user B, a second LLC frame B2 is sent to user B to the RLC protocol layer PL1 in the BSS from the SS. With a BLER of 25%, it takes 80 radio blocks to complete the transmission of LLC frame A1.

IFig. 30 (T = 3.0 seconds), the BSS is still busy transmitting the LLC frame A1. Three seconds have now passed since the LLC frame A1 was sent from the SS to the RLC protocol layer PL2 in the BSS and no acknowledgment of A1 has been sent to the SS. In accordance with the GPRS protocol, the timeout period of 3 seconds for LLC frame A1 has expired (timeout). The remaining radio block Rb in the RLC protocol layer BL2 in the BSS belonging to LLC frame A1 is washed (deleted).

LLC frame A1 is transmitted to the RLC protocol layer PL2 in the BSS from the SS and stored. The flushed data frame A1 is marked with an X in the figure. The BSS starts sending the LLC frame B2 to user B. 10 15 20 25 1 512 310 12 The only useful radio blocks that have been transmitted over the radio interface at the time period = 3 seconds are those belonging to the LLC frame B 1, see user B in fi gur 3c. Useful radio blocks are defined as undamaged radio blocks that belong to complete LLC frames transmitted to a radio device. No radio blocks from the LLC frame A1 are usable as the LLC frame A1 is not transmitted via the radio link L fi completely. LLC frame A1 must be retransmitted.

In the example, both users A and B know a BLER of 25% which means that on average 25% of the radio blocks must be retransmitted via radio link L. This means a maximum efficient throughput via the radio link of 75% of the total link capacity. With the prior art according to Figs. 3a-c, 60 of 150 radio blocks transmitted between T = 0 and T = 3 seconds are usable, leading to a throughput of 40% during this time period. This is largely due to the loss of radio resources on LLC frames that are timed out (in the example LLC frame Al).

Figs. 4a-b show a circuit diagram of a first embodiment of the method according to the invention for processing data frames in a packet data radio system comprising the LLC protocol layer PL1 and the RLC protocol layer PL2. The LLC protocol layer PL1 and the RLC protocol layer PL2 are examples of a first and a second protocol layer. Some of the steps in the first embodiment will also be described in connection with Figs. Sa-d below where the method is used in a data frame processing scenario.

In a step 40 1 a in Fig. G 4a, the LLC protocol layer PL1 in the SS sends new LLC frames to the RLC protocol layer PL2 in the BSS. In a step 401b, the RLC protocol layer PL2 segments each LLC frame into a number of radio blocks, e.g. 50 radio blocks and stores the LLC frames in the order in which they are received.

In a step 402a, the LLC protocol layer PL1 transmits previously timed LLC frames (see steps 407 and 410) to the RLC protocol layer PL2.

In a step 402b, the RLC protocol layer PL2 segregates and stores the retransmitted LLC frames along with the new LLC frames.

In a step 403, the RLC protocol layer PL2 estimates the radio resources to be allocated over a period of time, e.g. 3 seconds, for transmission of each LLC frame stored in the RLC protocol layer PL2.

In a step 404, the LLC protocol layer PL2 estimates a remaining transmission time for each LLC frame currently transmitted from the RLC protocol layer. Remaining transmission time is the time to successfully transmit all remaining RLC blocks in the BSS belonging to an LLC frame during transmission. The LLC frames are transmitted one RLC block at a time. The BSS can e.g. use previously obtained information about BLER, new information about BLER (see step 415) and estimate radio resources in step 403 to estimate the remaining transmission time.

If in a step 405 an LLC frame has an estimated remaining transmission time exceeding a time remaining of its timeout period, then it is detected in advance that the LLC frame will be timed (ie the detection of an upcoming timeout is performed before the actual timeouts occur) and the procedure proceeds to step 406. If in step 405, no timeout has been detected in advance, the method continues to transmit the remaining data blocks of the LLC frame during transmission and proceeds to a step 408.

In step 406, the RLC protocol layer PL2 interrupts the transmission of the LLC frame which has been previously detected that it will be timed out (step 405) before any fl era RLC blocks belonging to the LLC frame are transmitted.

In step 407, the RLC protocol layer PL2 coils (deletes) all remaining RLC blocks belonging to the LLC frame which have been previously detected that it will be timed according to step 405. The procedure continues with step 408.

In step 408, the RLC protocol layer PL2 estimates a transmission time for each LLC frame currently stored in the RLC protocol layer. The transmission time of an LLC frame is the time it would take to successfully transmit via the radio link L, all the RLC blocks that include the LLC frame. As in step 404, previously obtained information about BLER (Block Error Rate), new information about BLER (See step 415 and the estimated radio resources according to step 404 are used to estimate the transmission time).

If in a step 409 in Fig. 4b, a stored LLC frame has an estimated transmission time exceeding its time release period, then it is detected in advance that this LLC frame will be time triggered and the procedure continues with a step 410.

If in step 409, no timeout has been detected in advance, the procedure proceeds to a step 41 1.

In step 410, the RLC protocol layer PL2 coils (erases) all LLC frames detected in step 409 that they will be timed. This process proceeds to step 41 1. In step 411, the RLC protocol layer PL2 plans the order in which the stored LLC frames will be sent to their respective users.

This scheduling is performed in such a way that a maximum number of the LLC frames in the RLC protocol layer will be transmitted in full before the timeout. The method uses the estimated transmission times obtained in step 408 and the remaining time of the LLC frames' timeout periods to schedule the stored LLC frames.

In a step 412, the RLC protocol kit PL2 sends one or more of its RLC blocks to one or two of its LLC frames belonging to one or more of its users as planned in step 411.

According to a step 41a, the RLC protocol layer PL2 receives an ACK or NACK for each of the RLC blocks transmitted in step 412 (ACK = a positive acknowledgment, NACK = a negative acknowledgment according to the ARQ protocol).

In step 413b, transmitted RLC blocks for which a NACK has been received are retransmitted according to known ARQ protocols.

In step 414, the RLC protocol layer PL2 records the number of retransmissions required to transmit each radio block.

In step 415, the RLC protocol layer PL2 calculates the BLER for each transmission where an ACK or NACK has been received according to step 413a, using the number of retransmissions recorded in step 414. These BLER values are then used in steps 404 and 408 to estimate the transmission times.

In a second embodiment of the method according to the present invention, which is not shown in any figure, a negative acknowledgment is sent from the RLC protocol layer PL2 to the LLC protocol layer PL1 or is that an LLC frame has been detected in advance that it will be timed and flushed in step 407 or step 410.

An identical LLC frame to the coiled LLC frame is retransmitted from the LLC protocol layer PL1 to the RLC protocol layer PL2 immediately after the negative acknowledgment is received due to the coiled LLC frame. The process continues as in the first embodiment in Figs. 4a-b with step 408 or step 41 1.

Figs. Sa-d show a view of a data frame processing scenario where the first embodiment of the method according to Figs. 4a-b is used. The scenario is identical to that in Fig. G. 3. Reference is made to both Figs. Sa-b and the corresponding steps in Figs. 4a-b. 15 20 25 -g 512 510 16 Times T are introduced in the text below to make the scenario clearer and easier to understand. The times T are not shown in the figures.

In Fig. 5a (T1 = 0), in step 40la, the RLC protocol layer PL2 has received the new LLC frame A1 from the LLC protocol layer PL1. The RLC protocol layer PL2 segments the LLC frame A1 into 60 radio blocks in step 40 lb. The RLC protocol layer PL2 is busy sending LLC frame B 1, one radio block Rb at a time, to user B in step 412.

In Fig. 5b (T = 1.6 seconds), the transmission of the LLC frame B1 to user B is complete. Following an acknowledgment from user B of the successfully transmitted LLC frame B1, the LLC protocol layer PL1 sends LLC frame B2 to the RLC protocol layer PL2 in step 401a. The LLC frame B2 is segmented into 60 radio blocks and stored in the RLC protocol layer PL2 in step 40lb. There are now two LLC frames (Al and B2) stored in the RLC protocol layer PL2. No time-triggered LLC frame is issued in step 402a. The RLC protocol layer PL2 estimates the radio resources to be a GPRS channel, corresponding to a free bandwidth of 50 radio blocks per second in step 403.

No LLC frame is currently being transmitted and the process proceeds to step 408 where the RLC protocol layer PL2 estimates the transmission times for the stored LLC frames A1 and B2. During previous transmission of the LLC frame B1, the BLER of user B was measured to be 25% and thus the RLC protocol layer PL2 estimates the transmission time for B2 to be 1.6 seconds (80 radio blocks, including 25% retransmissions). No BLER related information is available to user A, so the transmission time for Al is optimistically estimated at 1.2 seconds (60 radio blocks, no retransmissions). 10 15 20 25 f 512 310 17 The time remaining before timeout is for A1 and B2 is 1.4 seconds and 3.0 seconds respectively. This is more than the estimated transmission times, which means that no time trip has been detected in advance according to step 409. In step 411, the LLC frame A1 is planned for immediate transmission and the LLC frame B2 is planned to follow. With this scheduling, according to estimated transmission times in step 408, both A1 and B2 will be transmitted completely before the respective timeout.

The procedure continues with steps 412 - 415, in which the RLC protocol layer starts sending the LLC frame A1, one radio block Rb at a time, to user A via the radio link L. ACK / NACK information for each transmitted RLC block is received from user A. the protocol layer PL2 registers the number of retransmissions and calculates BLER.

According to the scenario in Fig. 5c (T = 1.84 seconds), 12 radio blocks of the LLC frame A1 have been transmitted. With true BLER of 25%, 9 of the 12 radio blocks have been received correctly, while 3 have been damaged when they were transmitted over the radio link L.

Based on this successful speed, the RLC protocol layer PL2 has calculated BLER for user A to be 25%.

The procedure again follows the fate diagram in Fig. 4a-b. No new LLC frames are sent in steps 401a and 402a. In step 403, the radio resources are again estimated to be 50 radio blocks per second.

With a BLER of 25% for user A, the estimated transmission time, in step 404, of the 51 remaining radio blocks belonging to the LLC frame A1 during transmission is 1.36 seconds. When the remaining time of the timeout period for the LLC frame A1 is 5.16 seconds, a timeout of the LLC frame A1 (in advance) is detected in step 405.

The transmission of LLC frame A1 is interrupted and the remaining radio blocks in PL2 belonging to LLC frame A1 are flushed in steps 406 and 407, respectively. The flushed portion of LLC frame A1 in RLC protocol layer PL2 is marked with an X in Fig. 5c.

In step 408, the transmission time of the stored LLC frame B2 is again estimated at 1.6 seconds. When the remaining time of the time-out period is 2.76 seconds, no time-out of the LLC frame B2 is detected in step 409. With only the LLC frame B2 stored in the RLC protocol layer PL2, the planning in step 411 is trivial and the procedure continues with steps 412-415. to transmit the RLC blocks belonging to the LLC frame B2.

According to the scenario in Fig. 4d (T = 3 seconds), the BSS is busy transmitting the LLC frame B2. Three seconds have now elapsed since the LLC protocol layer PL2 transferred the LLC frame A1 to the RLC protocol1 layerPL2. User A has not received the LLC frame A1 (which was flushed at T = 1.84 seconds, see Fig. 5c) and thus no acknowledgment of the reception of the LLC frame A1 has been sent from user A to the LLC protocol layer PL1. The timeout period of 3 seconds for acknowledgment of LLC frame A1 has expired (timeout), and thus the LLC frame A1 is transmitted to the RLC protocol PL2 in step 402 a.

The useful radio blocks that have been transmitted via the radio links are those belonging to the LLC frame B1 and B2 (provided that the remaining radio blocks of LLC frame B2 in Fig. Sd are completely transmitted within the next 1.6 seconds) to user B. Of the total of 150 the radio blocks transmitted during the 3-second period shown in Figs. 5a-d, with 25% BLER, 75% of the 138 radio blocks transmitted to 512 510 19 users B contributed to the transmission. The transfer is thus 67%, which is to be compared with the transfer of 40% in the same scenario used according to the prior art in Figs. 3a-c. The improvement depends solely on the method according to the invention which enables the BSS to stop the transmission of A1.

The block error rate (BLER) is an example of a transmission parameter for the RLC protocol layer PL2 that can be used to estimate the transmission time to successfully transmit a stored LLC frame according to step 408 in Fig. 4a, or an LLC frame currently transmitted, according to step 404.

As previously mentioned, BLER is calculated for a user / system by occupying the proportion of the radio blocks transmitted via the radio copy L to a user / system that must be retransmitted, according to step 414. The method can use BLER as an example of most recently transmitted LLC frame or radio block via radio link L or an average value of BLER of a number of previously transmitted LLC frames or radio blocks. The transmission time can e.g. calculated as (time to send a block) x (number of blocks remaining) / (1-BLER).

Other examples of transmission parameters an RLC protocol layer PL2 may use to estimate the transmission time according to step 404 and step 408 in Fig. 4a are the bit error rate (BER) and the cell average of BLER and BER. A lower requirement for the transmission time for any LLC frame is always given by the number of remaining radio blocks of the LLC frame divided by the capacity of the packet radio system (radio block / second) in the cell.

If no current information about BLER, BER or the time delay is available, e.g. If there is a long interruption in the transmission via the radio link L, the RLC protocol layer can be used, e.g. an old BLER value, a measured average value or a preset value.

The first embodiment of the method has been described for downlink transmission, see Figs. Sa-d, where at least one user with a radio unit is a receiver of transmitted LLC frames from a BSS. The methods can also be applied to an uplink transmission where a BSS is the receiver of transmitted LLC frames from at least one radio unit.

The method in Figs. 4a-b can be used on an uplink transmission where a radio unit plans to transmit its LLC frames in a situation where the LLC frames belong to different data fl fates.

An example of such a situation is when a user runs fl your applications simultaneously via a GPRS channel, so that the LLC frameworks belonging to different data fl fights compete for resources on the radio link L.

Another example of such a situation is when your users share a radio device. The radio unit plans the LLC framework for different users via the (by the BSS) allocated uplink resources.

The main difference from downlink transmission is that only one radio link L is used, so that the estimated BLER is identical for all users.

A radio unit for using the first and second embodiments of the method may, for example, comprise an LLC layer as the first protocol layer and an RLC protocol layer as the second protocol layer.

On top of the LLC layer, one or more of your applications can work in parallel.

The method according to Figs. 4a-b can also be applied to an uplink transmission where the BSS registers uplink transmission from different radio units, ie 10 15 20. 25 30 35 40 512 310 21 determines which user is to have access to the radio link for uplink transmission.

Figs. 6a-b show a circuit diagram of a third embodiment of the method according to the invention for processing data frames in a packet radio system, where the BSS registers uplink transmissions from different radio units. The uplink working mode according to Figs. 6a-b operates in the BSS which requires exactly the same information regarding the uplink transmissions required for the downlink transmissions shown in Figs. 4a-b.

In a step 601, the BSS receives information (about the length and time of timeout) from the radio units for new data frames delivered to the RLC protocol layer PL2 in each radio unit.

In a step 602, the BSS receives information (about the length and time of time tripping) from the radio units about previous data frames as time tripped, which is retransmitted to the RLC protocol layer PL2 in each radio unit.

Steps 603-605 are the same as steps 403-405 in Fig. 4a. In case of a detected timeout in step 605, the BSS instructs the radio unit in a step 606 to interrupt the transmission of the LLC frame that will time out. This automatically induces a flush of this LLC frame in the radio unit at the time of the timeout.

Alternatively, when detecting a frame from a user / system that timers in step 605, the BSS simply cannot allocate radio resources to the user / system until the frame has actually timed. This will also induce a flushing and retransmission of the frame to PL1 in the radio unit.

In a step 607, the BSS estimates the transmission times of data frames stored in the RLC protocol layer in each radio unit. The estimation is performed in the same manner as in step 408 in Fig. 4a.

In a step 608, the BSS plans the transmission of the data frames stored in each radio unit. The planning is performed in the same way as in step 411 in Fig. 4b.

In a step 609, the BSS instructs each radio unit to transmit one or more radio blocks from scheduled data frames.

In a step 610, the RLC protocol layer PL2 in each radio unit retransmits damaged radio blocks to the BSS. 10 15 20 25 30 35 40 -g 512 310 22 In a step 611, the BSS registers the number of damaged radio blocks received * from the radio units.

In a step 612, the BSS calculates the BLER on the transmissions fi from each radio unit.

The calculation is performed in the same way as in step 415 in Fig. 4b.

The crucial difference in uplink transmission in Fig. 6a-b compared to downlink transmission in Fig. 4a-b is that for each LLC frame output to the RLC protocol layer PL2 in each radio unit, information about the LLC frame length and time of time release must be provided. reported to the BSS.

The procedures according to the invention can be repeated automatically to provide continuous re-evaluation of which LLC frame is to be sent next. As an example, the procedures can be repeated once every 240 ms.

The methods may alternatively be incident affected, for example the arrival of an LLC frame to the RLC protocol layer PL2 or after a predetermined number of transmitted radio blocks Rb.

Fig. 7 shows a block diagram of an embodiment of device 700 for using the method according to the invention.

A radio resource estimator 701 is connected, to allocate radio resources for transmitting LLC frames, to a transmission time estimator 702, for estimating the transmission times of the LLC frames.

The transmission time estimating means 702 is connected to a remote erasing unit 703 and a scheduling means 704.

The frame erasing unit 703 is arranged to detect in advance if a timeout will occur, interrupt the transmission of the LLC frames and flush LLC frames. The frame erasing unit 703 may also alternatively send negative acknowledgments to a frame emitting unit 709 when data frames have been detected in advance that they will be timed out. The remote erasing unit 703 is connected to a queuing device 705.

The frame delivery unit 709 is also connected to the queuing device 705. The frame delivery unit 709 is arranged to supply data frames to the queuing device 705 and transmit identical data frames to the flushed data frames when the time tripping periods of the flushed data frames have expired and / or when a negative acknowledgment is received from the frame erasing unit 703. 10 15 20 25 30 i .512 310 23 The scheduling means 704, for determining the order in which the LLC frames are to be transmitted from the queuing device 705 is also connected to the queuing device 705.

The queuing device 705, in which the LLC frames are to be transmitted is stored in a queue and segregated into RLC blocks, is connected to a transmitter 706, for transmitting and receiving RLC blocks.

A receiver 707, arranged to receive ACK / NACK signals, is connected to a link quality estimator 708, which records the number of retransmissions required to successfully transmit each RLC block and calculates BLER.

The link quality estimator 708 is connected to the transmission time estimator 702.

The invention can be fully or partially implemented as software in at least one microprocessor. As an example, the radio resource estimator 701, the transmission time estimator 702, the frame eraser 703, the scheduler 704, the queuing device 705 and the link quality estimator 708 may be logical units in at least one computer system.

The packet data radio system described in connection with Figs. 4a-6b is a GPRS system comprising an LLC protocol layer PL1 and an RLC protocol layer PL2. As previously mentioned, this is only an example of a packet data radio system where the invention can be used and an example of how such a system can be arranged. The invention can be used for all types of packet data radio systems that have a protocol-layered structure.

A system or device where the invention can be used can be divided into any number of protocol layers, function blocks, units, subsystems or the like that could transfer packet data from one place to another.

As an example, the switching system SS and the base station system BSS, in Fig. 1, may be integrated in a single system.

Claims (1)

A method for processing data frames (Lf, A1, B1-B2) in a packet data radio system, each frame (Lf, A1, B1-B2) having a specified time-out period for a complete transmission. to a receiver (A, B, C, RU1-RU3, BSS), the data frames (Lf, A1, B1-B2) being segmented into a number of data blocks (Rb) which are transmitted (412) one by one via a transmission medium to their respective receivers (A, B, C, RU1-RU3, BSS), characterized in that the transmission time of at least one of said data frames (Lf, Al, B1-B2) is estimated (404, 408, 604, 607) based at least one transmission parameter was detected in advance if a time trip will occur (405, 409, 605), said data frame (Lf, A1, B1-B2) being determined in advance that it will be time triggered if the estimated transmission time exceeds the remaining time. of its time-out period. . Method according to claim 1, characterized in that the transmission order of the data frames (Lf, A1, B1-B2) is planned (411, 608) for the data frames to be transmitted to their respective receivers (A, B, C, RU1-RU3, BSS) in a such an order that the number of data frames expiring in time (A1) is minimized, the scheduling (411, 608) being based on said estimated transmission times (408, 607) and the remaining time of the time tripping periods. . Method according to Claim 1 or 2, characterized in that a data frame (A1) which has been detected in advance that it will be time-triggered (405, 409, 605) is flushed (407, 410, 606). 10 15 20 25 512 310 25. Method according to one of Claims 1 to 3, characterized in that if a part of the data blocks (Rb) is not received correctly by the receiver (A, B, C, RU1-RU3, BSS), they are retransmitted (413b, 610) and that the number of retransmissions needed to successfully transmit each data block (Rb) to its receiver (A, B, C, RU1-RU3, BSS) is recorded (414, 611), the recorded number being used to calculate (415, 612) said transmission parameters as is used when estimating (404, 408, 604, 607) the transmission time. . Method according to one of Claims 1 to 4, characterized in that the estimated transmission time is the transmission time for successfully transmitting all data blocks (Rb) belonging to a data frame (Lf, A1, B 1-B2). . Method according to one of Claims 1 to 5, characterized in that an identical data frame for the flushed data frame (A1) is retransmitted (402a) when the time tripping period for the flushed data frame (A1) has expired. . Method according to one of Claims 1 to 5, characterized in that a negative acknowledgment is transmitted if a data frame (Lf, A1, B1-B2) has been detected in advance that it will be time-triggered. . Method according to claim 7, characterized in that an identical data frame to the flushed data frame (A1) is retransmitted (402a) if the negative acknowledgment is received. . Method according to one of Claims 3 to 8, characterized in that the data frame (B2) which is soled is flushed before any of the data blocks (Rb) belonging to the data frame are transmitted. 512 20 25 512 310 26 10. A method according to any one of claims 1-9, characterized in that the method uses transmission parameters which include a bit error rate when the transmission time is estimated (404, 408, 604, 607). Method according to any one of claims 1-10, characterized in that the method uses transmission parameters which comprise a transmission delay when the transmission time is estimated (404, 408, 604, 607). Method according to one of Claims 1 to 11, characterized in that the transmission medium is a radio link (L). Method according to one of Claims 1 to 12, characterized in that the transmission of a data frame (A1) during transmission, which has been detected in advance that it will be timed (405, 605), is interrupted (406, 606). Method according to one of Claims 1 to 13, characterized in that the radio resources to be allocated for the transmission are estimated (403, 603). Method according to one of Claims 1 to 14, characterized in that the information on the length of the data frames (Lf, A1, B 1-B2) and their time tripping periods is received (601, 602). Method according to one of Claims 1 to 15, characterized in that instructions concerning the order in which one or more of your data blocks are to be transmitted from planned data frames are received (609). An apparatus for processing data frames (Lf, Al, B1-B2) in a packet data radio system, wherein each of the data frames (Lf, Al, B1-B2) has a fixed time-out period for a complete transmission to a receiver (A, B, C, RU1-RU3, BSS), the device comprising means for: storing (705) the data frames (Lf, A1, B1-B2); segment (705) the data frames (Lf, A1, B 1-B2) into a number of data blocks (Rb); transmitting (706) the data frames (Lf, A1, B 1-B2) via at least one radio link (L) to at least one receiver (A, B, C, RU1-RU3, BSS); and retransmitting (706) data blocks (Rb) not correctly received by the receiver (A, B, C, RU1-RU3, BSS); 2. characterized in that the device comprises means for estimating (702) the transmission time of at least one of the data frames (Lf, A1, B 1-B2) and means for detecting in advance (703) whether a time trip will occur for any of the data frames (Lf, A1, B1-B2), the estimate being based on at least one transmission parameter, and wherein said data frame (Lf, A1, B1-B2) is determined in advance that it will be time triggered if the estimated transmission time exceeds the remaining time. of its time-out period. Device according to claim 17, characterized in that the device comprises means for planning (704) the transmission order of the data frames (Lf, A1, B1-B2) for the data frames to be transmitted to their respective receivers (A, B, C, RU1-RU3). , BSS) in such an order that the number of data frames (L fi A1, B 1-B2) being time-triggered is minimized, the scheduling being based on the estimated transmission times and the remaining time of the time-out periods. Device according to claim 17 or 18, characterized in that the device comprises means for flushing (703) the data frames (A1) detected before they are time-triggered. Device according to any one of claims 17-19, characterized in that the device comprises means (708) for recording the number of retransmissions required to send each data block (Rb) to the receiver (A, B, C, RU1-RU3, BSS), and means for calculating (708) the transmission parameter used when the transmission time is estimated by using said number of recorded retransmissions. Device according to any one of claims 17-20, characterized in that the device comprises means for interrupting (703) transmissions of data frames (A1) which are detected in advance that they will be time-triggered. Device according to any one of claims 17-21, characterized in that the device comprises means for transmitting (709) identical data frames to the flushed data frames (A1) when the time tripping period for the flushed data frames has expired. Device according to one of Claims 17 to 21, characterized in that the device comprises means for transmitting negative receipts (703) for data frames (A1) which have been detected in advance that they will be time-triggered. Device according to claim 23, characterized in that the device comprises means for retransmitting data frames (709) which are identical to the flushed data frames (A1) if negative receipts have been received due to data frames detected before they are timed out. Device according to any one of claims 17-24, characterized in that the device comprises means for estimating radio resources (701) to be allocated for the transmission. Base station system in a packet data radio system for processing the data (Lf, A1, B1-B2), characterized in that the base station system (BSS) comprises a device according to any one of claims 17-25. Base station system according to claim 26, characterized in that the base station system (BSS) comprises means for receiving information from radio units (RU1-RU3) regarding the length and time tripping periods of the data (Lf, A1, B1-B2) to be transmitted from the radio units (RU1- Ru3). The base station system of claim 26 or 27, characterized in that the base station system (BSS) comprises means for transmitting (706) instructions for scheduling the data frames (Lf, A1, B 1-B2) to the radio units (RU1-RU3). Radio unit for processing data frames (Lf, A1, B 1-B2) in a packet data radio system, characterized in that the radio unit (RU1-RU3) comprises a device according to any one of claims 17-25. Radio unit according to claim 29, characterized in that the radio unit (RU1-RU3) comprises means for transmitting information to a base station system (BSS) regarding time tripping periods and the length of data frames (Lf, A1, B 1-B2) in the radio unit (RU1-RU3). ). 512 310 30. A radio unit according to claim 29 or 30, characterized in that the radio unit (RU1-RU3) comprises means for receiving instructions from the base station system (BSS) regarding the planning of data frames (Lf, A1, B1-B2) to be transmitted to the base station system. (BSS).