DE102006047717A1 - Data transmission between communication terminals through radio communication network, involves assigning time slot to common communication channel and transmitting data in accordance with determined length of time within assigned time slot - Google Patents

Abstract

The method begins by determining if a communication terminal is synchronized with a communication network. If the communication terminal is not synchronized with the communication network, a time slot is assigned to a common communication channel. The length of time at the start and end of the assigned time slot is then determined for transmitting data. The time at which the data are to be transmitted is then determined in accordance with the determined length of time. The data are then transmitted in accordance with the determined length of time within the assigned time slot. An independent claim is also included for the assignment of radio resources in a communication network.

Description

The The invention relates to methods for transmitting data, communication terminals, a Method for allocating radio resources and a network device.

In Cellular communication systems are typically next to dedicated communication channels also shared communication channels used by several Mobile subscriber devices, for example for signaling purposes be used. It may be necessary signaling data from a mobile subscriber device to a base station by means of a common communication channel are sent without the mobile subscriber unit with the Base station is synchronized in time. This includes efficient access procedures desirable.

According to one embodiment The invention relates to a method for transmitting data a communication terminal by means of a communication network in which radio resources for time slots assigned to a temporal sequence of time slots communication channels provided the steps of checking whether the communication terminal with the Communication network is synchronized, determining when the communication terminal with the Communication network is not synchronized, the beginning of a Time slot assigned to a common communication channel is, determining a period of time after the beginning or before which should be sent before the start of data, determining a Time at which the data according to the time period should be sent and sending the data at the time.

embodiments The invention are illustrated in the figures.

1 illustrates basic multiple access methods.

2 shows a communication system 200 according to an embodiment of the invention.

3 shows a time-frequency diagram 300 according to an embodiment of the invention.

4 shows a time-frequency diagram 400 according to an embodiment of the invention.

5 shows a time-frequency diagram 500 according to an embodiment of the invention.

6 shows a time-frequency diagram 600 according to an embodiment of the invention.

7 shows a flowchart 700 according to an embodiment of the invention.

8th shows a flowchart 800 according to an embodiment of the invention.

9 shows a flowchart 900 according to an embodiment of the invention.

10 shows a flowchart 1000 according to an embodiment of the invention.

11 shows a communication terminal 1100 according to an embodiment of the invention.

12 shows a flowchart 1200 according to an embodiment of the invention.

13 shows a communication terminal 1300 according to an embodiment of the invention.

14 shows a flowchart 1400 according to an embodiment of the invention.

15 shows a network device 1500 according to an embodiment of the invention.

at Second Generation Mobile Communication Systems, for example GSM (Global System for Mobile Communications) mobile communications systems, and the third generation, for example UMTS (Universal Mobile Telecommunications System) communication systems, the respective network operator offers the participants a multitude of communication services. In addition to the basic communication services such as voice telephony, SMS (Short Message Service) and MMS (Multimedia Messaging Service) will also provide video communication services and IP (Internet Protocol) -based communication services offered.

UMTS mobile communication systems according to the current Standard, which is referred to as Release 6, allow maximum net data transfer rates of 14 Mbps in the downlink and 2 Mbps in the uplink. As radio transmission technologies will be in accordance with the current UMTS standard FDD (Frequency Division Duplex) and TDD (Time Division Duplex) used. The applied multiple access method is based on CDMA (Code Division Multiple Access).

In view of the success of DSL (Digital Subscriber Line), the development in mobile communications is moving in the direction of mobile communication systems, which enable high data rates and are optimized for IP (Internet Protocol) applications such as VoIP (Voice over IP). As part of the standardization body 3GPP (Third Generation Partnership Project), the further development of UMTS communication systems into a mobile radio communication system optimized for packet data transmission is discussed by improving system capacity and spectral efficiency. This discussion is led by 3GPP under the name LTE (Long Term Evolution). The goal of the LTE is to significantly increase the maximum net data transfer rates possible with UMTS communication systems, specifically up to 100 Mbps in the downlink and 50 Mbps in the uplink.

For this new multiple access methods, channel structures, Method for optimized radio resource control and network architectures considered. For the data transmission in the downlink, for example, the combination of OFDMA (Orthogonal Frequency Division Multiple Access) with TDMA (Time Division Multiple Access) provided and for the data transfer in Uplink is provided a method based on SC-FDMA (Single Carrier Frequency Division Multiple Access) based.

Multiple access methods are used to control the use of available radio resources to regulate. Basic multiple access methods are discussed below explained

1 illustrates basic multiple access methods.

In 1 are a first time-frequency diagram 101 , a second time-frequency diagram 102 and a third time-frequency diagram 103 shown. It is the time to the right in the direction of a time axis 104 represented and the frequency is in the direction of a frequency axis 105 shown to the top.

The first time-frequency diagram 101 illustrates TDMA (Time Division Multiple Access). In the case of TDMA, the entire frequency band is available to each mobile radio user equipment, provided that it is intended for use by the mobile user equipment, but each mobile radio user equipment has only a defined transmission time interval (TTI). 106 assigned, in which the mobile radio user equipment can send and receive user data. During a transmission period in a mobile radio cell, only one mobile radio subscriber device is always active.

The second time-frequency diagram 102 illustrates SC-FDMA (Single Carrier Frequency Division Multiple Access). With FDMA, each mobile user equipment is the entire time frame, but only a fixed narrow frequency band 108 of the entire frequency band for sending and receiving payload data. In every narrow frequency band 108 Only one mobile subscriber device may be active at a time.

The third time-frequency diagram 103 illustrates CDMA (Code Division Multiple Access). With CDMA, each mobile subscriber device has the entire time period and the entire frequency band at its disposal. In order to avoid mutual interference of the transmitted data (interference) of the different transmitters, each mobile radio user equipment becomes a binary code pattern 107 assigned. The code patterns assigned to the different mobile radio user equipments 107 are orthogonal to one another and the useful signal sent or received by a mobile radio subscriber device is specific to this mobile radio subscriber device by means of the code pattern assigned to the mobile radio subscriber device 107 coded (spread).

OFDMA (Orthogonal Frequency Division Multiple Access) is a special case from FDMA and is a multi-carrier method, at the disposal of the whole standing frequency band with the bandwidth B divided into M orthogonal subbands becomes. Thus, there are M (narrow) frequency bands with the bandwidth f = B / M before. With OFDMA becomes one to be transferred Data stream is divided into a plurality of subcarriers corresponding to the subbands and with a correspondingly reduced data rate in parallel by means of Subcarrier transmitted. A mobile subscriber unit is a defined number of subcarriers for data transmission assigned.

According to one embodiment The invention relates to a method for transmitting data a communication terminal by means of a communication network in which radio resources for time slots assigned to a temporal sequence of time slots communication channels are provided, which check the steps whether the communication terminal with the Communication network is synchronized, determining when the communication terminal with the Communication network is not synchronized, the beginning of a Time slot assigned to a common communication channel is, determining a period of time after the beginning or before which should be sent before the start of data, determining a Time at which the data according to the time period should be sent and sending the data at the time.

According to a further embodiment of the invention, a communication terminal according to the above-described method for over provided by data.

Illustratively, the communication terminal checks, for example a mobile subscriber device, whether it is the communication network, such as a base station is synchronized in time or not with the communication network is synchronized. Is not it with the communication network synchronized, it is noted that determining the beginning of the time slot maybe is inaccurate and, for example, the data to be sent if they according to the determined Beginning of the time slot, not within the timeslot be received by the communication network and, for example, transmission errors due to interference. Such transmission errors can not only because of the inaccurate determination of the beginning of the time slot but also due to high signal transit times of the communication terminal to the Communication network occur. To avoid such transmission errors, fits the communication terminal according to the determined Duration of the transmission time. The duration can vary Types, for example, based on predetermined values or based on the geographical distance of the communication terminal from the communication network (For example, a base station) are determined.

The For example, sending the data after the time period after the Start of the time slot started or before the time before the Start of the time slot started. In one embodiment sending the data so done that it is completed after the period of time after the beginning of the timeslot is completed or before the time period before the start of the timeslot is.

According to one another embodiment of the The invention relates to a method for transmitting data by means of a communication network in which radio resources for time slots assigned to a temporal sequence of time slots communication channels provided the steps of determining a period of time, in the at least two according to the sequence consecutive time slots a common communication channel are assigned, and sending the data in the period by means of having common communication channel.

According to one another embodiment of the Invention is a communication terminal according to the method described above to submit provided by data.

According to one embodiment The invention relates to a method for allocating radio resources a communication network in which radio resources for time slots assigned to a temporal sequence of time slots communication channels are provided, comprising determining a period of time in at least two according to the sequence consecutive time slots a common communication channel Assign the at least two time slots to the common communication channel, and generating a message, which specifies that in the period at least two time slots assigned to the common communication channel.

According to one another embodiment of the The invention will be a network device according to the method described above for allocating radio resources.

clear are received by the communication network at selected times at least two consecutive time slots for the common communication channel (eg radio channel) and this in one embodiment the invention signals. This can be a communication terminal that it failed to succeed within a single time slot (or Time frame or time subframe) To transmit data at least two temporally successive time slots for data transmission use, what the probability of successful data transfer elevated. From the network device can also be signaled to which Time points only one time slot for the common communication channel is reserved. The signaling can be done by means of predetermined signal sequences will be realized.

The Further embodiments of the invention, in connection with a method of transmission are described by analogy also apply to the communication terminals, the method for allocating radio resources and the network device.

The For example, data has a request for assignment of radio resources for the communication terminal on. By means of the data, the communication terminal requests, for example, a dedicated radio link between the communication terminal and the Communication network is built.

The communication terminal is for example a mobile subscriber unit. Accordingly For example, the communication network is a cellular communication network.

The time period is determined, for example, based on the signal strength of the communication network sent by the communication terminal received signals detected. The time duration can also be determined based on at least one predetermined time duration information stored in the communication terminal.

In an embodiment is the time duration based on the geographic position of the communication terminal determined.

Of the common communication channel is for example a communication channel for sharing by multiple communication terminals for transmission of signaling data in the uplink. The common communication channel is, for example, an RACH of a communication system designed according to LTE is. The communication system may also be in accordance with other standards, for example GSM (Global System for Mobile Communications), UMTS (Universal Mobile Telecommunications System) or CDMA2000 be designed.

In an embodiment will be used to determine the period in which at least two will be following the episode consecutive time slots a common communication channel are assigned receive a message by means of which at least two according to the episode consecutive timeslots corresponding to the common communication channel assigned are specified.

2 shows a communication system 200 according to an embodiment of the invention.

The communication system 200 shows the architecture of a UMTS radio network, also referred to as UMTS Terrestrial Radio Access Network (UTRAN).

The communication system 200 includes a plurality of radio network subsystems (RNS) 201 . 202 , on which in each case by means of an Iu interface 203 . 204 with the UMTS core network (Core Network) 205 are coupled.

The RNA 201 . 202 each have a radio network controller (RNC) 207 . 208 and one or more base stations 209 . 210 . 211 . 212 on. A UMTS base station is also referred to as NodeB.

The RNCs 207 . 208 different RNA 201 . 202 are by means of a lur interface 213 coupled together.

Every base station 209 . 210 . 211 . 212 a RNA 201 . 202 is by means of a Iub interface 226 . 227 . 228 . 229 with the RNC 207 . 208 of the RNA 201 . 202 coupled. Every base station 209 . 210 . 211 . 212 a RNA 201 . 202 operates one or more mobile radio cells (CE) by radio 214 to 225 within the RNA 201 . 202 , The RNC 207 . 208 a RNA 201 . 202 monitors the allocation of radio resources of mobile radio cells 214 to 225 in the RNA 201 . 202 ,

Between a base station 209 . 210 . 211 . 212 , and a mobile user equipment (UE) 206 in a mobile radio cell 214 to 225 message signals and data signals are transmitted via an air interface (Uu) 230 transmitted by means of a radio transmission technology. For example, in the FDD (Frequency Division Duplex) mode, separate signal transmission in the uplink and downlink directions is achieved by a corresponding separate assignment of frequencies or frequency ranges. Under uplink is the signal transmission from the mobile subscriber unit 206 to a base station 209 . 210 . 211 . 212 and downlink is the signal transmission from a base station 209 . 210 . 211 . 212 to the mobile subscriber device 206 to understand.

As there are several mobile subscriber devices 206 in the same mobile radio cell 214 to 225 a multiple access method is used. In this embodiment, a multiple access method based on a combination of SC-FDMA and TDMA or a multiple access method based on a combination of OFDMA and TDMA is employed. This is a mobile subscriber unit 206 for Nutzdatenübertragung a certain frequency range (for example, certain subcarriers) and certain transmission periods (transmission time intervals) assigned.

An allocation of frequency ranges and transmission periods to mobile radio user equipment or to users is in 3 illustrated.

3 shows a time-frequency diagram 300 according to an embodiment of the invention.

In the direction of the horizontal axis 301 is the time and in the direction of the vertical axis 302 the frequency is plotted. In this example, there are six consecutive transmission time intervals 303 to 308 specified with TTI-1 to TTI-6 (TTI: Time Transmission Interval). There are also four frequency ranges 309 to 312 determined, in order of increasing frequencies, denoted by F1 to F4.

A pair from a transmission time interval 303 to 308 and a frequency range 309 to 312 forms a so-called radio resource block (Physical Resource Block, PRB), which is assigned to a user or to the user from the Be user used mobile subscriber unit, can be assigned. For example, the radio resource block is that of the transmission time interval 305 with the name TTI-3 and the frequency range 312 is formed with the designation F4, the sixth user assigned to "user F".

The radio resource blocks 313 can be from the mobile network, for example from the base station 209 to 212 that the respective mobile radio cell 213 to 225 operates to be dynamically assigned to the users. Radio resource blocks 313 may also be reserved by the mobile network for special purposes, for example for the transmission of signaling information. Such radio resource blocks 313 are in 3 marked with an X, for example the radio resource block belonging to the frequency domain 309 with the designation F1 and the transmission time interval 306 is formed with the name TTI-4.

The mobile subscriber device 206 shares with other mobile subscriber devices that are in the same mobile cell 214 to 225 like the mobile subscriber unit 206 for the transmission of signaling data to the base station 209 to 212 that the mobile radio cell 214 to 225 operates a common radio channel for the uplink (ie for the data transmission direction mobile subscriber unit to the base station), which is referred to as RACH (Random Access Channel).

at UMTS communication systems according to REL-99 (Release 99) was up to Release 6 for setting up a communication connection between mobile subscriber device and base station and for transmission signaling data and payload in RRC (Radio Resource Control) state CELL FACH of the mobile subscriber device the so-called RACH procedure used. As part of LTE, this RACH procedure is due to the changed transmission method, the for the uplink and the downlink (ie for the transmission direction base station to mobile subscriber unit) to be used, probably no longer used. At LTE A RACH procedure is expected to be used for other purposes.

Currently, two different RACH procedures are discussed in the 3GPP standardization groups, one for unsynchronized access to the RACH and one for synchronized access to the RACH. The RACH procedure for the unsynchronized access to the RACH shall be used if a mobile subscriber unit for a data transmission in uplink is not yet synchronized with the base station or the mobile subscriber unit has lost the synchronization for a data transmission in the uplink. This can be done in the RRC states RRC Idle and RRC Connected. The access to the RACH by a mobile radio user equipment that is not synchronized with the corresponding base station is in 4 illustrated.

4 shows a time-frequency diagram 400 according to an embodiment of the invention.

To the right are in the time-frequency diagram 400 a variety of radio subframes 401 shown, each having a length of 0.5ms. 20 radio subframes each 401 make a radio frame 402 the length of 10ms. Similar to the in 3 illustrated time-frequency diagram 300 are in the time-frequency diagram 400 in the vertical direction frequency ranges 403 represented, which can use the mobile radio user equipment for data transmission.

The mobile radio user equipment is not synchronized with the base station in the sense that it is the respective beginning of the radio subframe 401 only roughly known. The unsynchronized access to the RACH takes place by transmission of a so-called preamble 404 (obliquely hatched) corresponding to one of the mobile radio user equipment within a radio subframe 401 selected transmission time, in this example after a protection time interval 405 (Guard Time) is sent from the mobile subscriber unit.

through the preamble becomes a signature, that is a predefined signal sequence transmitted by the mobile subscriber unit from a predefined one Set of signatures, for example, from a set of 64 signatures, is selected. By means of the preamble the mobile subscriber unit can also provide additional information transmit to the base station, For example, the specification of a desired channel quality (Channel Quality Indicator, CQI) or specifying a type for one Access requested by the mobile subscriber unit, for example the establishment of a communication link for the transmission of small amounts of data or big ones Data volumes in the uplink.

Was the access to the RACH by the mobile subscriber unit successful, that is, no collision has occurred, for example, by data transmission of other mobile subscriber units, the base station transmits in response information about radio resources, the mobile subscriber unit for data transmission in the uplink available and a reserve value (timing advanced value, TA value). The reserve value is used for a (more precise) synchronization of the mobile radio user equipment with the base station for a data transmission in the uplink and indicates to the mobile radio user equipment a period to the mobile subscriber device data in advance (in the case of a negative Vorhaltewerts) or delayed (in the case of a positive Vorhaltewertes) in relation to the beginning of a radio subframe or a Radio frame data must send so that the data in the base station at the right time, for example be received synchronously with radio subframes in the base station. Otherwise, for example, could occur the problem that the data sent in the uplink due to long signal delays in a transmission in a radio subframe only in the course of the subsequent radio subframe reach the base station and thus it comes to interference with the data transmission in the subsequent subframe. The occurrence of a problem of this nature is in 5 illustrated.

5 shows a time-frequency diagram 500 according to an embodiment of the invention.

Analogous to 3 and 4 in the horizontal direction is the time and in the vertical direction the frequency is plotted. They are a first radio subframe 501 , a second radio subframe 502 and a third radio subframe 503 shown. Further, a first frequency range 504 and a second frequency range 505 shown. The first frequency range 504 corresponds to a first subcarrier and the second frequency range 505 corresponds to a second subcarrier. The first radio subframe 501 is in an access time interval 506 followed by a protection time interval 507 (referred to as Tguard). Within the access time interval (designated T _RA for Time Random Access), a mobile subscriber device accesses the RACH and begins sending a preamble 508 , It is assumed that the first subcarrier during the first radio subframe 501 intended for the RACH. In other words, the radio resource block passing through the first frequency range 504 and the first radio subframe 501 assigned to the RACH.

In this example, the transmission is the preamble 508 at the end of the first radio subframe 501 not completed but continues into the second radio subframe 502 continued. In this way, interference may occur, for example, when the first subcarrier in the second radio subframe 502 is not intended for use for the RACH but is assigned to another mobile radio user equipment for a dedicated radio connection. Submitting the preamble 508 continues, for example, to the second radio subframe because the amount of data of the first preamble is relatively large or because the mobile subscriber unit due to the lack of synchronization (ie the only inaccurate knowledge of the beginning of the first radio subframe 501 ) with the base station in an unsynchronized access to the RACH too late within the first radio subframe 501 with the sending of the preamble 508 starts.

Because it can cause interference when sending the preamble into the second radio subframe 502 continues and thus the access to the RACH by the mobile radio user equipment is not successful, since the base station is the preamble 508 can not receive error-free and accordingly does not send a positive acknowledgment message to the mobile subscriber unit, in one embodiment of the invention the mobile subscriber unit uses a Timing Advanced value for an unsynchronized RACH access which it estimates in advance or calculates for used an already known value again. This increases the chance of successful RACH access.

To successful access to the RACH, the base station can Mobile subscriber unit subsequently transmit an exact timing value, use it for further access to the RACH or other channels should.

The mentioned above RACH procedure for a synchronized access to the RACH is performed when the mobile user equipment in the uplink is synchronized in time, for example, for access to the RACH to request additional Resources for a data transfer in the uplink and / or downlink. This may be, for example, in the RRC state RRC Connected happen. In the future, however, will be more specific to the unsynchronized access to the RACH received.

As mentioned above, a Timing Advanced value should be used for an unsynchronized access to the RACH. This is variable, that is, can be re-selected by the mobile subscriber unit for each access to the RACH. Using the bias value, the mobile radio user equipment may begin to transmit the preamble 508 in relation to the beginning of the first radio subframe. By way of example, the mobile subscriber unit can use a positive provisional value to start the transmission of the preamble 508 delay. This can be useful if the preamble 508 (unlike it in 5 is shown) is sent too early, so sending the preamble 508 (for example due to coarse synchronization with the base station) already before the start of the first radio subframe 501 lies.

Similarly, the mobile subscriber unit by a negative Vorhaltewert the beginning of Sending the preamble 508 vorverlegen. This is for example in the in 5 presented case useful when sending the preamble 508 is not completed at the end of the first radio subframe. If the default value is selected appropriately, the transmission of the preamble shifts 508 in 5 vividly to the left and, where appropriate, sending the preamble 508 at the end of the first radio subframe 501 , for example within the guard time interval 507 completed.

Using the reserve value can thus be achieved that the preamble 508 can be received by the base station in the correct period of time and so interference with the data transmission by other mobile subscriber units or by the base station itself can be avoided.

• – Das Mobilfunk-Teilnehmergerät ermittelt den Vorhaltewert basierend auf der Signalstärke, mit der es Signale von der Basisstation empfängt und/oder basierend auf der geographischen Position des Mobilfunk-Teilnehmergeräts. Eine niedrige Signalstärke eines von der Basisstation empfangenen Signals kann bedeuten, dass sich das Mobilfunk-Teilnehmergerät verhältnismäßig weit von der Basisstation entfernt befindet. Da aufgrund der hohen Entfernung zur Basisstation auch eine hohe zeitliche Verzögerung eintritt, kann in diesem Fall ein Vorhaltewert geeignet sein, gemäß welchem das Mobilfunk-Teilnehmergerät das Senden der Präambel 508 vorverlegt.
• – Das Mobilfunk-Teilnehmergerät verwendet einen bereits bekannten Vorhaltewert. Beispielsweise kann der letzte von der Basisstation mitgeteilte Vorhaltewert für einen RACH-Zugriff verwendet werden. Dies kann besonders dann geeignet sein, wenn das Mobilfunk-Teilnehmergerät kurz vor dem durchzuführenden unsynchronisierten RACH-Zugriff noch mit der Basisstation synchronisiert war oder wenn es sich noch an dem selben Ort befindet oder in der Nähe des Ortes, an dem es mit der Basisstation synchronisiert war, da in diesem Fällen der Vorhaltewert, der verwendet wurde, als das Mobilfunk-Teilnehmergerät mit der Basisstation synchronisiert war, mit hoher Wahrscheinlichkeit wieder geeignet ist.
• – Das Mobilfunk-Teilnehmergerät verwendet vordefinierte Vorhaltewerte. Beispielsweise verwendet das Mobilfunk-Teilnehmergerät nach einem erfolglosen RACH-Zugriff einen anderen Vorhaltewert als bei dem erfolglosen RACH-Zugriff, beispielsweise aus einer Liste von Vorhaltewerten, die in dem Mobilfunk-Teilnehmergerät gespeichert ist. Beispielsweise verwendet das Mobilfunk-Teilnehmergerät bei einem ersten Zugriff auf den RACH den Vorhaltewert null, bei einem zweiten RACH-Zugriff, falls der erste RACH-Zugriff erfolglos war, einen Vorhaltewert von –0,1ms, bei einem dritten RACH-Zugriff, falls der zweite RACH-Zugriff erfolglos war, einen Vorhaltewert von +0,1ms und bei einem vierten RACH-Zugriff einen Vorhaltewert von –0,2ms, falls der dritte RACH-Zugriff erfolglos war usw.

For example, the tentative value is set by the mobile user equipment in the following ways:

• The mobile radio user equipment determines the reserve value based on the signal strength with which it receives signals from the base station and / or based on the geographical position of the mobile radio user equipment. A low signal strength of a signal received by the base station may mean that the mobile radio user equipment is relatively far away from the base station. Since due to the high distance to the base station also enters a high time delay, in this case, a Vorhaltewert be suitable, according to which the mobile radio user equipment sending the preamble 508 advanced.
• - The mobile subscriber unit uses an already known Vorhaltewert. For example, the last reserved value communicated by the base station may be used for RACH access. This may be particularly useful if the mobile subscriber unit was still synchronized with the base station just before the unsynchronized RACH access to be performed, or if it is still in the same location or near the location where it synchronizes with the base station In this case, because the latency value used when the mobile user equipment was synchronized with the base station was high, it was highly likely to be suitable again.
• The mobile subscriber device uses predefined default values. For example, after an unsuccessful RACH access, the mobile subscriber unit uses a different default value than in the case of the unsuccessful RACH access, for example from a list of advance values stored in the mobile subscriber unit. For example, in a first access to the RACH, the mobile subscriber unit uses the default value zero, in a second RACH access, if the first RACH access was unsuccessful, a default value of -0.1 ms, in a third RACH access, if the second RACH access was unsuccessful, a reserve value of + 0.1ms and in a fourth RACH access a reserve value of -0.2ms in case the third RACH access was unsuccessful etc.

According to a further embodiment of the invention, an unsuccessful unsynchronized access to the RACH is avoided in that, for example, at regular time intervals, more than one radio subframe, that is a plurality of temporally successive radio subframes, are reserved for the RACH. This is in 6 shown.

6 shows a time-frequency diagram 600 according to an embodiment of the invention.

Analogous to the in 5 the time is plotted in the horizontal direction and the frequency in the vertical direction. Furthermore, analogous to 5 a first radio subframe 601 , a second radio subframe 602 , a third radio subframe 603 , a first frequency range 604 and a second frequency range 605 shown.

Both the first radio subframe 601 as well as the second radio subframe 602 are reserved for the RACH and are therefore available to the mobile radio user equipment for an unsynchronized RACH access.

Accordingly, an access time interval extends 606 to the second radio subframe 602 and a protection time interval 607 is only at the end of the second radio subframe 602 intended. In this example too, the transmission of a preamble continues 608 into the second radio subframe, but since the second radio subframe is also reserved for the RACH, a collision only occurs if at the same time another mobile radio user device wants to access the RACH but not the second radio Subframe may be used for another channel. This increases the likelihood of a successful RACH access by the mobile subscriber unit.

According to one exemplary embodiment of the invention, it is provided that the base station signals it when several successive radio subframes are reserved for the RACH. This is done for example by common downlink channels that can be received by all in the mobile station operated by the base station, for example by means of the pSCH (Primary Syn Chronization Channel) or by means of the BCH (Broadcast Channel). It can also be provided that several consecutive radio subframes are regularly reserved for the RACH. For example, two consecutive radio subframes are reserved for the RACH, followed by 15 individual, non-consecutive radio subframes followed by two consecutive radio subframes, etc.

In contrast, has However, the procedure, dynamically possibly several temporally successive following radio subframes for to reserve the RACH and this by means of a common downlink channel to signal the advantage that can be taken into account whether for example, due to the size of the mobile radio cell or structural conditions requires that multiple radio subframes, which are consecutive in time for which RACH will be reserved. For example, does not it require that time each other following radio subframes for reserved to the RACH, it can be compared to a static procedure, for example, reserving two consecutive ones Radio subframe for the RACH every 15 or 10 for the RACH reserved radio subframe bandwidth be saved.

The Signaling by means of the pSCH or the BCH can be done, for example, via predefined Signal sequences performed become. For example, you can be defined two signal sequences, one indicates that just a radio subframe for the RACH is reserved and the other that two consecutive Radio subframe for the RACH are reserved.

Further, with reference to 7 . 8th and 9 possible processes for access attempts by a mobile subscriber device to the RACH explained. First, with reference to 7 explains the use of a reserve value.

7 shows a flowchart 700 according to an embodiment of the invention.

At the beginning, in step 701 , the mobile radio user equipment is in a non-synchronized state with the base station, which is referred to as non-sync.

In step 702 For example, transmission power (TX Power) is determined for the unsynchronized access to the RACH parameter, which is determined by the mobile radio user equipment based on the signal strength of signals received by the base station. For example, with a low received signal strength, that is to say with a low signal strength of the signals received by the base station, a high transmission power is selected.

In step 703 a reserve value is determined. This may be done in the above-mentioned ways, for example, based on the received signal strength of signals transmitted from the base station based on already known preset values, on predefined values based on the synchronization with downlink channels or based on other factors.

In step 704 an unsynchronized access is made to the RACH using the in step 703 calculated reserve value. In this case, a preamble is sent to the base station, which contains, for example, the identification of the mobile radio user equipment in the form of a signature and further information.

In step 705 it is checked whether the access to the RACH was successful and accordingly from the base station a response message with the correct signature and information required for the synchronization with the base station was received. If this is the case, then the mobile subscriber unit is in step 706 synchronized with the base station and is in the synchronized state called sync.

• – Die maximale Sendeleistung ist erreicht und kann nicht weiter erhöht werden.
• – Die maximale Anzahl von Versuchen, auf den RACH zuzugreifen wurde erreicht.

If access to the RACH was unsuccessful, the mobile subscriber unit checks in step 707 whether it continues to attempt to access the RACH successfully or whether a request criterion is met. Possible termination criteria include:

• - The maximum transmission power has been reached and can not be increased any further.
• - The maximum number of attempts to access the RACH has been reached.

If one of these abort criteria is met or another abort criterion, then the access attempt to the RACH in step 708 aborted and the synchronization failed (state sync failed).

If the attempt to access the RACH and thus to synchronize with the base station is not aborted, then in step 708 the reserve value adjusted. By way of example, the reserve value is increased or decreased, for example, in accordance with a list stored in the mobile radio subscriber device or according to an algorithm implemented in the mobile radio subscriber device.

In step 710 Optionally, the transmit power may be increased to increase the likelihood that the base station will successfully receive the preamble. After the adjustments in step 709 and optionally in step 710 will be back with step 704 continued and accessed the RACH again.

The following is with reference to 8th a procedure described in which optionally several temporally successive radio subframes are reserved for the RACH.

8th shows a flowchart 800 according to an embodiment of the invention.

The steps 801 and 802 become analogous to the steps 701 and 702 carried out.

In step 803 the mobile radio user equipment sends a preamble to the base station. In contrast to that with respect to 7 described procedure no Vorhaltewert is used in this embodiment.

The steps 804 . 805 . 806 and 808 correspond to the steps 705 to 708 of in 7 illustrated sequence.

In step 807 It is determined whether at certain times, if necessary, several radio subframes are reserved for the RACH. If this is the case, the mobile radio subscriber device plans the next access attempt to the RACH at the time at which a plurality of temporally successive radio subframes are reserved for the RACH, which is signaled for example by the base station by means of a common downlink channel. In step 809 becomes analogous to the step 710 optionally increases the transmit power and in step 803 the next access attempt is made to the RACH, possibly at a time when several radio subframes are reserved for the RACH.

The following is with reference to 9 a combination of using a Latency and the use of multiple temporally successive radio subframes for accessing the RACH explained.

9 shows a flowchart 900 according to an embodiment of the invention.

The steps 901 to 903 correspond to the steps 701 to 703 , In step 904 sends the mobile subscriber unit a preamble analogous to the step 704 using the in step 903 certain reserve value. The steps 905 to 908 correspond to the steps 705 to 708 , In step 908 checks the mobile radio user equipment analogous to the step 807 whether at certain times several radio subframes are reserved for the RACH. If so, it plans the next access attempt to the RACH for a time when multiple radio subframes are reserved for the RACH and incremented in step 909 optionally the transmission power analogous to the step 710 , If this is not the case, it will be in step 910 analogous to the step 709 adjusted the reserve value and in step 909 increases the transmission power. Subsequently, with step 904 and accessing the RACH again, optionally at a time when multiple radio subframes are reserved for the RACH, or using the in step 910 adjusted reserve value.

Further embodiments The invention will be explained below.

10 shows a flowchart 1000 according to an embodiment of the invention.

Of the Sequence illustrated illustrates a method for transmitting data through a communication terminal via a communication network, at the radio resources for Timeslots assigned to a temporal sequence of time slots communication channels be, according to one embodiment the invention.

In step 1001 it is checked whether the communication terminal is synchronized with the communication network.

In step 1002 the beginning of a time slot assigned to a common communication channel is determined when the communication terminal is not synchronized with the communication network.

In step 1003 a period is determined after which data is to be sent after the start or before the start.

In step 1004 a time is determined at which the data should be sent according to the time duration.

In step 1005 the data is sent at the time determined.

11 shows a communication terminal 1100 according to an embodiment of the invention.

The communication terminal 1100 has a testing device 1101 configured to check whether the communication terminal is synchronized with a communication network in which radio resources for time slots of a time series of time slots are allocated to communication channels.

The communication terminal 1100 has Furthermore, a determination device 1102 adapted to determine the beginning of a time slot associated with a common communication channel when the communication terminal is not synchronized with the communication network and a first detection means 1103 configured to determine a period of time after which data is to be sent after the beginning or before the beginning.

A second determination device 1104 the communication terminal 1100 is arranged to determine a time at which the data is to be sent according to the time duration and a transmitting device 1105 the communication terminal 1100 is set up to send the data at the time.

12 shows a flowchart 1200 according to an embodiment of the invention.

Of the Sequence illustrated illustrates a method for transmitting data by means of a communication network in which radio resources for time slots assigned to a temporal sequence of time slots communication channels be according to one embodiment the invention.

In step 1201 a period is determined in which at least two consecutive time slots according to the sequence are assigned to a common communication channel.

In step 1202 the data is sent in the period by means of the common communication channel.

13 shows a communication terminal 1300 according to an embodiment of the invention.

The communication terminal 1300 has a determination device 1301 configured to determine a period of time in which at least two time slots consecutive according to a time series of time slots for which radio resources are allocated to communication channels are assigned to a common communication channel.

The communication terminal 1300 also has a transmitting device 1302 configured to send the data in the period by means of the common communication channel.

14 shows a flowchart 1400 according to an embodiment of the invention.

Of the The flow illustrated illustrates a method for allocating radio resources a communication network in which radio resources for time slots assigned to a temporal sequence of time slots communication channels become.

In step 1401 a period is determined in which at least two consecutive time slots according to the sequence are to be assigned to a common communication channel.

In step 1402 the at least two time slots are assigned to the common communication channel.

In step 1403 a message is generated specifying that at least two time slots are allocated to the common communication channel in the period.

These Message is sent, for example, from the network device.

15 shows a network device 1500 according to an embodiment of the invention.

The network device 1500 is, for example, part of a communication network in which radio resources for time slots are assigned to a channel of time slots of communication channels.

The network device 1500 has a determination device 1501 configured to determine a period in which at least two consecutive time slots are to be assigned to a common communication channel according to the sequence.

The network device 1500 also has an assignment device 1502 adapted to assign the at least two time slots to the common communication channel and a message generator 1503 configured to generate a message specifying that at least two time slots are allocated to the common communication channel in the period.

101

first Time-frequency chart

102

second Time-frequency chart

103

third Time-frequency chart

104

timeline

105

frequency axis

106

Transfer period

107

binary code pattern

108

frequency band

200

communication system

201 202

Radio network subsystems

203 204

Iu interface

205

UMTS core network

206

Mobile subscriber unit

207 208

Radio network controller

209-212

base stations

213

Lur interface

214-225

radio cells

226-229

Iub interfaces

230

Uu interface

300

Frequency-time diagram

301

horizontal axis

302

vertical axis

303-308

Transmission time intervals

309-312

frequency ranges

313

Radio resource blocks

400

Time-frequency diagram

401

Radio subframe

402

radio frame

403

frequency ranges

404

preamble

405

Protection time interval

500

Time-frequency chart

501-503

Radio subframe

504 505

frequency ranges

506

Access time interval

507

Protection time interval

508

preamble

600

Time-frequency chart

601-603

Radio subframe

604 605

frequency ranges

606

Access time interval

607

Protection time interval

608

preamble

700

flow chart

701-710

process steps

800

flow chart

801-809

process steps

900

flow chart

901-910

process steps

1000

flow chart

1001-1005

process steps

1100

communication terminal

1101

test equipment

1102

determiner

1103 1104

detecting means

1105

transmitting device

1200

flow chart

1201-1202

process steps

1300

communication terminal

1301

determining device

1302

transmitting device

1400

flow chart

1401-1403

process steps

1500

Network Setup

1501

determiner

1502

assignor

1503

News generator

Claims (16)

Method of transmitting data by communication terminal by means of a communication network in which radio resources for time slots assigned to a temporal sequence of time slots communication channels are having - Check if that communication terminal is synchronized with the communication network, Determine if the communication terminal with the communication network is not synchronized, the beginning a time slot associated with a common communication channel is - Determine a period of time after the beginning or before the beginning Data should be sent - determining a time, to which the data according to the duration to be sent - Send the data at the time. Method according to claim 1, wherein the data is a request for the allocation of radio resources for the communication terminal exhibit. Method according to claim 1 or 2, wherein the communication terminal is a mobile subscriber unit. Method according to one the claims 1 to 3, wherein the time duration is determined based on the signal strength of sent from the communication network, received by the communication terminal Signals. Method according to one the claims 1 to 4, wherein the time period is determined based on at least a predetermined stored in the communication terminal Time indication. Method according to one the claims 1 to 5, wherein the time period is determined based on the geographical Position of the communication terminal. Method according to one the claims 1 to 6, wherein the common communication channel is a communication channel for sharing by multiple communication terminals for transmission of signaling data in the uplink. Method of transmission data by means of a communication network in which radio resources for time slots a time series of time slots are assigned to communication channels, having - Determine a period in which at least two successive successive episodes Time slots are assigned to a common communication channel, - Send the data in the period by means of the common communication channel. Method according to claim 8, wherein a message is received to determine the period, by means of which at least two successive successive Time slots assigned to the common communication channel are to be specified. Method according to claim 8 or 9, where the data is a request for the allocation of radio resources for a Have communication terminal. Method according to one the claims 8 to 10, wherein the communication terminal is a mobile subscriber unit. Method according to one the claims 8 to 11, wherein the common communication channel is a communication channel for sharing by multiple communication terminals for transmission of signaling data in the uplink. Communication terminal having A testing device, which is set up to check if the communication terminal with a communication network in which radio resources for time slots assigned to a temporal sequence of time slots communication channels be synchronized, A determination device, which is set up, the beginning of a time slot, the one common communication channel is assigned to determine, if the communication terminal is not synchronized with the communication network, - a first one Determining device that is set to a period of time determine after the beginning or before the beginning Data should be sent A second detection device, which is set up to determine a time at which the data according to the time period to be sent - one Transmitter that is set up the data at the time to send. Communication terminal having - a detection facility, which is set up to determine a period in which at least two time slots, which according to a time sequence of time slots for which radio resources are assigned to communication channels will follow one another, a common communication channel are assigned, - one Transmitter, which is set up to be transmitted data in the period to send by means of the common communication channel. Method for allocating radio resources of a Communication network, in which radio resources for time slots assigned to a temporal sequence of time slots communication channels be having - Determine a period in which at least two successive successive episodes Time slots are assigned to a common communication channel should, - To assign the at least two time slots to the common communication channel, - Produce a message that specifies that during the period at least two time slots assigned to the common communication channel are. Network device of a communication network, at the radio resources for Timeslots assigned to a temporal sequence of time slots communication channels being, having, - one Determining device that is set to a period of time determine in which at least two consecutive successions Time slots are assigned to a common communication channel should, - one Assignment device that is set up, the at least two Allocate time slots to the common communication channel, A message generator, which is set up to generate a message specifying that in the period at least two time slots the common Communication channel are assigned.