DE10133032A1 - Wireless network using common transmission channels that prevents packet collision on shared channel when both terminals accidentally select same collision elimination preamble - Google Patents

Abstract

Uses a common transmission channel that is available for access to several wireless terminals. A base station controls access to the common transmission channel. The terminals send an access signal to the base station for the purpose of obtaining access to the common transmission channel. At least two different start times can be assigned to the terminals for transmitting their respective access signals.

Description

The invention relates to a network with common transmission channels.

In the document 3GPP TS 25.211 V3.5.0, ^3rd Generation Partnership Project (3GPP) "Physical channels and mapping of transport channels Onto physical channels (FDD)" proposes a radio network, having the common broadcast channels for the common-demand usage are provided by several terminals. Such a channel can e.g. B. the channel referred to in the above document as CPCH channel (Common Packet Channel) or in the above document referred to as RACH channel (Random Access Channel).

The radio network consists of several radio cells, each with a base station and terminals or mobile stations located therein. After registration and The base station can synchronize a terminal as needed assign one or more common transmission channels. This happens in each case when the message requirements of a terminal exceed a certain threshold. The terminal then selects from those assigned to it if necessary Transmission channels one channel and first sends an access preamble (access Preamble). In the known radio network, the access preamble is provided in time intervals to send several times and to increase the transmission power each time a confirmation signal is sent from the base station to the terminal. With this Confirmation signal is signaled to the terminal that that sent by the terminal Signal from the base station with sufficient power is received. This method is also known as power ramping.

For handling collision cases, the CPCH channel provides that the Terminal sends a collision resolution preamble after receiving a confirmation signal. This collision resolution preamble is chosen at random. Also the reception of the Collision resolution preamble is sent from the base station by means of an acknowledgment signal approved. Only after receiving the confirmation signal for the collision resolution preamble the terminal is authorized to send the data part. Collisions occur at one such channel only if two terminals happen to have the same collision resolution preamble choose.

For the treatment of collisions, this is the case with the RACH channel Slotted ALOHA access method provided, in which collided data packets according to a randomly selected one Waiting time will be transmitted again.

It is an object of the invention to create networks with a different type of Collision.

For a first embodiment, this object is achieved according to the invention by a network
with at least one base station and several assigned terminals for the exchange of user and control data and
with at least one common transmission channel, which is provided for the access of several terminals,
the base station being provided for controlling access to the common transmission channel,
wherein the terminals are provided for sending at least one access signal to the base station for access to the common transmission channel, and wherein the terminals can be assigned at least two different starting times for sending the access signal.

Access signals are generally understood to be signals which the terminal connects to the Base station sends before the terminal sends the actual data part starts. By means of the access signals, the terminals request z. B. a common one Transmission channel at the base station. Access signals can also do this be used to avoid collisions if multiple terminals are on the same want to access the common transmission channel.

A base station is understood to mean a control station in general networks, which controls access to a common transmission channel of the network.

A wireless network with several is in particular as the network according to the invention Radio cells suitable, in each of which a base station and several control and Wireless transmission of user data. A wireless transmission is used to transmit Information e.g. B. via radio, ultrasound or infrared paths. However, the invention is also for wired networks with at least one common Transmission channel applicable.

According to the invention, the terminals assigned to a base station are at least two assigned different start times for sending the access signal. The Starting times are defined with reference to a reference frame of the network. On such reference frame is always for data synchronization of terminals and Base station required for TDMA, FDMA and CDMA processes. Such a Reference frames can contain different subframes or subframes or with several other successive frames form a super frame. The frame of reference can, for example, the frame with a duration of 10 ms in the UMTS system (UMTS = Universal Mobile Telecommunication System).

By means of the different start times for sending the access signal, a additional parameters created to the access signals sent by the terminals to be able to distinguish.

This makes it possible to provide various improved methods for collision treatment realize.

In the advantageous embodiment of the invention according to claim 2 it is provided that Terminals that want to send messages over a common transmission channel first send a request signal to the base station. With this Request signal is signaled to the base station that the terminal has a common Want to use the transmission channel. The request signal can e.g. B. information about it contain which of the common transmission channels is requested or with what data rate the terminal is sending over a common transmission channel would like to.

In particular, the request signal can be a request preamble (Access Preamble) as described in the document 3GPP TS 25.211 V3.5.0, ^3rd Generation Partnership Project (3GPP)) "Physical channels and mapping of transport channels Onto physical channels (FDD)" described. Accordingly, the request preamble is sent several times at intervals and the transmission power is increased in each case until a positive confirmation signal is sent from the base station to the terminal. With this positive confirmation signal, the terminal is signaled that the signal sent by the terminal is received by the base station with sufficient power. This process is also known as power ramping.

After a predefined time (time-out) can be provided, neither positive or a negative confirmation signal. This occurs e.g. B. on if the Base station could not detect the transmitted preamble. With a positive Confirmation signal, the terminal can set the data part of the message package with the Submit transmission power. For example, the base station sends a negative confirmation signal off if there is no or insufficient channel capacity for the transmission of the data part exists or if several terminals are shared on the same Want to access the transmission channel. In the case of a negative confirmation signal, a At a certain time, a retransmission with the original initial transmission power started and then gradually increased again.

By assigning different start times for sending the The base station can collide after the request signals have been received clearly recognize. This is a quick and early detection of collisions possible and subsequently there are various options for Realize collision handling and collision resolution.

In the advantageous embodiment of the invention according to claim 3, the terminals send a collision resolution signal to the base station if there have been collisions with the request signals received from the base station. This is e.g. B. the case when different terminals have sent the same request signal. This is recognized by the base station on the basis of the different start times of the request signals. A set of different collision resolution signals is provided for collision resolution, which are selected at random by the terminals and sent to the base station. Collision resolution signals can e.g. B. CR-preambles be (Collision Resolution preambles) in the document document 3GPP TS 25.211 V3.5.0, ^3rd Generation Partnership Project (3GPP) "Physical channels and mapping of transport channels Onto physical channels (FDD)" for the CPCH Channel are described in more detail. Different, exclusively assigned start times are also provided for the different terminals for sending the collision resolution signals. If collisions occur again when the collision resolution signals are transmitted, the base station can recognize this from the different starting times of the collision resolution signals. Such collisions in the collision resolution phase can e.g. B. occur when two terminals randomly select the same collision resolution signal or the same CR preamble. When a collision is detected in the collision resolution phase, the base station does not send a confirmation signal (transmission power zero) to the terminals involved in the collision, i.e. to the terminals that happened to have chosen the same collision resolution signal, within a predetermined period of time or in another implementation, a negative confirmation signal. Since the terminals do not receive a positive confirmation signal, they do not send any data. This completely prevents collisions.

In the advantageous embodiment of the invention according to claim 4 it is provided that the Base station sends a collision detection signal to the terminals when the base station has detected conflicting request signals. By means of the collision detection signals the terminals are signaled that the initiation of a collision resolution phase is required and that the terminals accordingly send collision resolution signals should send the base station. The transmission of a separate collision detection signal to initiate the collision resolution signals has the advantage that it ensures can be that a collision resolution phase is only initiated if it is absolutely necessary.

The separate collision detection signal can e.g. For example, be implemented using a CD / CA-ICH-channel (Collision Detection / Collision Avoidance indication channel) according to the document document 3GPP TS 25.211 V3.5.0, ^3rd Generation Partnership Project (3GPP) "Physical channels and mapping of transport channels onto physical channels (FDD) ", which is intended for positive or negative confirmation of CR preambles, is used only for this purpose. The reduction of the CD / CA-ICH channels available for the positive or negative confirmation of CR preambles by one channel and the associated reduction of the available CR symbols by one symbol does not represent a significant restriction, since there are no undetected collisions may occur.

The advantageous embodiment of the invention according to claim 5 represents a simple and represents reliable regulation by means of which the base station has access to the common Can regulate transmission channel. This rule ensures that the Access to the common transmission channel no collisions occur. Moreover sufficient reception performance is guaranteed. To check whether the respective specific request signal has only been sent from a single terminal the reference time frames of the wireless network are advantageous in access time frames divided up. Checking whether the respective request signal is only from a terminal has been sent, then only takes place within the access time frame.

In the advantageous embodiment of the invention according to claim 6 are Request signals are uniquely assigned to a common transmission channel. At this The terminals can be targeted by sending the corresponding variant Request signal request a certain common transmission channel.

If the request signal assigned to a specific transmission channel is only from is sent to a terminal and if this particular common continues Base channel is already in use, the base station can be a positive one Send confirmation signal to the terminal and the common transmission channel for it Release the terminal.

If the request signal of is sent to several terminals at different start times Base station sends a negative confirmation signal to the terminals and thus prevents the Access to the common transmission channel. This will cause collisions avoided. The individual terminals must then send a request signal to the Send base station. Alternatively, it is possible to post the negative Confirmation signals to provide a collision resolution phase in which the terminals Send collision resolution signals to the base station.

In the advantageous embodiment of the invention according to claim 7 are each one common transmission channel assigned several request signals. At this Variant, the base station can determine after receiving the request signals Resolve collision cases. Stand z. B. 16 different request signals are available, this set of 16 request signals can each be divided into 4 sets of 4 Request signals are divided. Accordingly, it is then possible to have 4 common ones To provide transmission channels, the 4 common transmission channels each 4 different request signals are assigned.

If z. B. two different terminals send two different request signals, but which are assigned to the same common transmission channel, the Base station sends a positive confirmation signal to one terminal and a negative one Send the confirmation signal to the other terminal. This will make the collision immediate dissolved.

But if e.g. B. two different terminals select the same request signal, which is assigned to the same common transmission channel, the Base station only recognize the collision, but no direct resolution of the collision carry out. In this case, the base station would have to send a negative confirmation signal to the Send terminals.

The individual terminals then have to send a request signal to the base station again send. Alternatively, it is possible to post the negative Confirmation signals to provide a collision resolution phase in which the terminals Send collision resolution signals to the base station.

Another possibility is that only one certain data rate is specified with which the terminal has a common Want to transmit transmission channel. The assignment of a certain common The transmission channel for the requested data rate is then carried out by the base station.

In the advantageous embodiment of the invention according to claim 8, the terminals send the request signals only at the beginning of an access time frame. At this Variant can be the base station in the first phase, in which the request signals from the Terminals are sent at the same time, do not detect collisions, d. H. it cannot can be recognized when several terminals send the same request signal.

Access timeframes are understood to mean timeframes, at the beginning of which all Terminals are authorized to send a request signal.

An advantageous implementation of the access time frame exists, for. B. two successive reference frames of the UMTS system each of 10 ms duration in 15 to split equally long access time frames of 5120 chips each.

Since collisions cannot be detected in the first phase, a positive confirmation of a request signal automatically provides for a collision resolution phase to be carried out as the second phase. A set of different collision resolution signals is provided for collision resolution, which are selected at random by the terminals and sent to the base station. Collision resolution signals can e.g. B. CR-preambles be (Collision Resolution preambles) in the document document 3GPP TS 25.211 V3.5.0, ^3rd Generation Partnership Project (3GPP) "Physical channels and mapping of transport channels Onto physical channels (FDD)" for the CPCH are described in more detail. Different, exclusively assigned starting times within the access time frame are provided for the various terminals belonging to the group of users of the CPCH for sending the collision resolution signals. If collisions occur again when the collision resolution signals are transmitted, the base station can recognize this from the different starting times of the collision resolution signals. Such collisions in the collision resolution phase can e.g. B. occur when two terminals randomly select the same collision resolution signal or the same CR preamble. Upon detection of a collision in the collision resolution phase, the base station does not send a confirmation signal (zero transmission power) to the terminals involved in the collision, i.e. to the terminals that happened to have chosen the same collision resolution signal, within a predetermined time period or in another implementation, a negative confirmation signal. Since the terminals do not receive a positive confirmation signal, they do not send any data. This completely prevents collisions.

By means of the exclusive assignment of different starting times according to claim 9 the base station based on the timing of the access signal within the Reference frame recognize which of the terminals sent the access signal. Also if several terminals send the same access signal and thus e.g. B. the same request common transmission channel, the base station can do this due to the recognize different timing of these identical access signals and Prevent collisions. Exclusive assignment means that the individual start times are exclusively assigned to only one terminal.

In the advantageous embodiment of the invention according to claim 10, the terminals a combination of at least two collision resolution preambles and at least a start time or a sub-access frame for access to the assigned common transmission channel.

Such a combined assignment increases the flexibility and the number of possible terminals and enables a variety of access methods.

The two different collision resolution preambles according to claim 11 reduce that Probability that two terminals will send the same CR preamble at random. This Probability becomes in the advantageous embodiment of the invention according to claim 12 further reduced by giving each terminal a different combination is assigned by collision resolution preambles.

In the advantageous embodiment of the invention according to claim 13, the type of Access to the common transmission channel depending on the number of Terminals assigned to this common transmission channel have been changed. Is not the number of terminals assigned to a common transmission channel The terminals become larger than the number of available preambles advantageously assigned a preamble exclusively.

If the number of terminals exceeds the number of preambles, one can initially exclusive allocation of start times or sub-access frames may be advantageous, provided the time interval between the start times or sub-access frames is therefore not too small becomes. If there are a large number of terminals, there are combinations of start times and sets of preambles advantageous.

Claim 14 relates to a base station according to the invention, claim 15 to a Terminal according to the invention and claim 16 to a method according to the invention.

The object of the invention is achieved in a further embodiment of the invention by a network according to claim 17.

In this network, the number of a common transmission channel assigned terminals not larger than the number of available Preambles. This enables an exclusive allocation of the preambles. This will Collisions completely avoided.

Some schematically illustrated exemplary embodiments of the invention are explained in more detail below with reference to FIGS. 1 to 5. Show it:

Fig. 1 shows a wireless network with several base stations and terminals,

Fig. 2, two consecutive radio frames according to the UMTS standard, each of 10 ms duration, with the two radio frames at 15 frames are divided access (corresponding to 5120 chips),

Figures 3a to 3c show three consecutive access frames which are each divided into 20 sub-access frame (corresponding to 256 chips), the sub-access frames are each assigned to an individual terminal for transmitting an access signal.,

Fig. 4 is a flow chart for explaining the assignment of a common transmission channel for the transmission of a data packet from a terminal for a first embodiment of the invention,

Fig. 5 is a flow chart for explaining the assignment of a common transmission channel for the transmission of a data packet from a terminal for a second embodiment of the invention.

In Fig. 1 is a wireless network, e.g. B. radio network, with several base stations 1 to 3 and several terminals 4 to 14 . Certain terminals 4 to 14 are assigned to a base station 1 to 3 . In the example shown in FIG. 1, terminals 4 to 7 are assigned to base station 1 , terminals 8 to 10 to base station 2, and terminals 11 to 14 to base station 3 . Control data is exchanged at least between the base station and the terminals. User data can be exchanged between the base station and the terminals as well as directly between the terminals. In both cases, the connection to the transmission of user data is established by the base station. Terminals 4 to 14 are generally mobile stations that are controlled by a permanently installed base station 1 to 3 . A base station 1 to 3 may, however, also be movable or mobile.

In the wireless network, for example, radio signals according to the FDMA, TDMA or CDMA method (FDMA = frequency division multiplex access, TDMA = time division multiplex access, CDMA = code division multiplex access) or after one Transfer combination of procedures.

In the CDMA method, which is a special code spreading method, binary information (data signal) originating from a user is modulated with a different code sequence in each case. Such a code sequence consists of a pseudo-random square-wave signal (pseudo noise code), the rate of which, also called the chip rate, is generally significantly higher than that of the binary information. The duration of a square-wave pulse of the pseudo-random square-wave signal is referred to as the chip interval T _C. 1 / T _C is the chip rate. The multiplication or modulation of the data signal by the pseudo-random square-wave signal results in a spreading of the spectrum by the spreading factor N _C = T / T _C , where T is the duration of a square-wave pulse of the data signal.

User data and control data between at least one terminal and a base station are transmitted via channels specified by the base station. A channel is through a frequency range, a time range and z. B. in the CDMA process by a Spreading code determined. The radio connection from the base station to the terminals is referred to as a downlink and from the terminals to the base station as an uplink. Consequently data are transmitted from the base station to the terminals and via downlink channels Uplink channels data sent from terminals to the base station. For example, a Downlink control channel may be provided which is used to get from the base station Distribute control data to all terminals before establishing a connection. Such a Channel is called the downlink broadcast control channel. to Transmission of control data from a terminal to a connection before it is established The base station can, for example, be an uplink control channel assigned by the base station can be used, but can also be accessed by other terminals. An uplink Channel that can be used by several or all terminals is considered as common Common uplink channel. After establishing a connection z. B. user data is transmitted between a terminal and the base station via a downlink and transmit an uplink useful channel. Channels that are only between a transmitter and a receiver are called dedicated channels. Usually is a user channel is a dedicated channel that is used by a dedicated control channel Transmission of connection-specific tax data can be accompanied.

For data transmission between the base station and the terminals, the wireless network has common transmission channels, which are provided for the shared, demand-dependent use of several terminals. Such common transmission channels can e.g. As described in the document 3GPP TS 25.211 V3.5.0, ^3rd Generation Partnership Project (3GPP) "Physical channels and mapping of transport channels Onto physical channels (FDD)" called the CPCH channels (common packet channel) channels or RACH Channels (Random Access Channel). Access to these common transmission channels is controlled by the base station.

So that user data is exchanged between the base station and a terminal the terminal must be synchronized with the base station. For example, from the GSM system (GSM = Global System for Mobile communication), in which a combination of FDMA and TDMA methods is known is used that after determining a suitable frequency range based on predetermined parameters the temporal position of a frame is determined (Frame synchronization), with the help of which the chronological sequence for the transmission of data he follows. Such a framework is always for data synchronization of terminals and Base station required for TDMA, FDMA and CDMA processes. Such a framework can contain different subframes or subframes or with several others successive frames form a super frame. For reasons of simplification In the following, a framework is assumed which is referred to as the reference framework becomes. This reference frame can be, for example, the frame with a duration of 10 ms be in the UMTS system (UMTS = Universal Mobile Telecommunication System).

To be able to carry out a frame synchronization, all terminals must be on the Base station with the aid of pulses emitted by the base station be synchronized. If no code spreading procedure (e.g. CDMA procedure) is applied (e.g. a TDMA method is used) corresponds to the pulse duration exactly the time interval required for sending a bit. When using a The code spreading method corresponds to the pulse duration of a chip interval. A bit interval corresponds to several chip intervals. The program is for frame synchronization a special pulse sequence required by the base station. The start time of the Pulse sequence corresponds to the start time of a frame.

FIG. 2 shows two successive radio frames 20 and 21 according to the UMTS standard, each of 10 ms in duration. These form a double radio frame 22 . The two radio frames 20 and 21 are divided into a total of 15 access frames # 0 to # 14. The radio frame 20 has the access frames # 0 to # 6 and the first half of access frames # 7. The radio frame 21 has the access frames # 8 to # 14 and the second half of the access frame # 7. The individual access frames # 0 to # 14 are each 5120 chips long.

FIGS . 3a to 3c show the three successive access frames # 0 to # 2 according to FIG. 2, which are each divided into 20 sub-access frames. The access frame # 0 according to FIG. 3a is in the 20 sub-access frames * 0 to * 19, the access frame # 1 according to FIG. 3b in the 20 sub-access frames * 20 to * 39 and the access frame # 2 according to FIG. 3c is in the 20 sub-access frames * 40 to * 59 split. The sub-access frames can each be assigned to an individual terminal for sending access signals. For example, in the system according to FIG . B. Terminal 4 the sub-access frame * 0, Terminal 5 the sub-access frame * 1, Terminal 6 the sub-access frame * 2, Terminal 7 the sub-access frame * 3 and, accordingly, Terminals 8 to 10 the sub-access frame * 4 to * 6 and Terminals 11 to 14 are assigned to sub-access frames * 7 to * 10.

A total of 60 sub-access frames are thus provided in this example and thus can provide 60 different terminals with a sub-access framework and thus an individual, exclusively assigned start time for sending the access signals.

In the subsequent access frames # 3 to # 5, # 6 to # 8, # 9 to # 11, # 12 to # 14, the assignment of the sub-access frames is repeated periodically in a corresponding manner, ie the access frame # 3 is in the 20 sub-access frames * 0 to * 19, the access frame # 4 divided into the 20 sub-access frames * 20 to * 39, the access frame # 5 into the 20 sub-access frames * 40 to * 59, the access frame # 6 into the 20 sub-access frames * 0 to * 19 etc. The individual sub-access frames therefore recur periodically after 3 access frames. This makes it possible to run through the sub-access frames * 0 to * 59 five times over a period of 2 radio frames 20 and 21 with a total length of 20 ms.

This is necessary for so-called power ramping. The transmission power of the Access signals can be increased 4 times within 2 radio frames each time after 3 access frames until the reception power that arrives at the base station is sufficient. The Power ramping can also continue in the subsequent radio frames if necessary become.

In a first embodiment of the invention it is provided that the individual Terminals already have the request signals by means of which the terminals have a common Request the transmission channel from the base station during the terminal send assigned sub-access frame. For example, as request signals Access preambles sent. The access preambles can either be one assigned to a specific common transmission channel, or a group of access Preambles are each assigned to an individual common transmission channel.

As in the above example the terminal 4 of FIG. 1 the sub-access frame * 0 is assigned, then this terminal can five times an access preamble in each case in the sub-access frame * 0 of the access frame # 0, # 3, # 6, # 9 and # 12 transmit, the transmission power can be increased successively with each step. In total, 5 power ramping steps are possible in this example.

In the first embodiment of the invention, it can be used to simplify the evaluation be favorable that the terminals only at the beginning of a double radio frame Duration 20 ms begin sending access preambles, i.e. H. only in the Access frame # 0 to # 2.

If a terminal that has been assigned by the network to the group of users of the common transmission channel referred to as CPCH wants to send a message packet via the CPCH after synchronization, various steps are carried out in the terminal, which are a flowchart for the first embodiment of the invention in FIG. 4 indicates.

Block 30 in FIG. 4 indicates the start of the flow chart. In block 31 , the base station checks whether the data requirement to be sent by a terminal exceeds a certain amount of data. If this is the case, the base station assigns the respective terminal one or more common transmission channels for any access. This allows the terminal to access the assigned common transmission channel (s) if necessary. At the same time, the base station assigns a sub-access frame to the respective terminal, within which the terminal may send request signals to the base station for requesting a common transmission channel. This means that an individual start time within the radio frame is set for each terminal to send the request signals.

If a terminal wishes to access one of the common transmission channels assigned to it, it sends an access preamble to the base station in block 32 as a request signal.

In block 32 it is provided to send the access preamble up to 5 times at intervals of 3 access frames each time and to successively increase the transmission power. This ensures that the base station receives the signals from the terminal with sufficient power (power ramping).

Each terminal sends the access preamble within the sub-access frame assigned to it by the base station, it being possible to simplify the evaluation that the terminals may only begin transmitting at the beginning of a double radio frame with a duration of 20 ms, ie only within the access frame # 0 to # 2 according to FIG. 2.

In block 33 , the base station checks whether at least one access preamble with sufficient power is received.

If this is the case, it is checked in the following block 34 whether the respective access preamble has occurred only once within the respective access frame.

If this condition is also met, the base station sends, for example two access frames later, a positive confirmation signal to the respective terminal and thus releases the common transmission channel assigned to the access preamble to this terminal. This is represented by block 35 .

Sends Terminal 4 in the sub-access frame * 0 of the according to the example above Access frame # 0 is an access preamble with sufficient transmission power this access preamble in access frame # 0 is not from another terminal sent during a sub-access frame * 1 to * 19, the base station transmits for example two access frames later, i. H. during access frame # 2 positive confirmation signal to Terminal 4. In this case, Terminal 4 has already before the access frame # 3, at which a new transmission of the access Preamble with increased transmission power would be provided, a positive confirmation signal receive. This allows Terminal 4 to send the data part via the Access preamble associated shared transmission channel begin.

If an access preamble within the access frames # 0 to # 2 is not received with sufficient power, the terminal does not receive a positive or negative confirmation signal from the base station and a return is made to block 32 . Accordingly, the terminal again sends the access preamble with increased transmission power within the subsequent access frames # 3 to # 5 in the sub-access frames * 0 to * 59 assigned to the terminal.

This increase in transmit power may occur during access frames # 6 through # 8, # 9 to # 11 and # 12 to # 14 repeated.

If one or more access preambles are received with sufficient performance the respective access preamble at least twice within the the respective access time frame has occurred, d. H. of at least two different ones Terminals are sent at different start times within the access time frame a collision resolution phase must be initiated.

The base station decides whether a collision resolution phase is required. If the base station has detected a collision upon receipt of the access preambles and a collision resolution phase is to be carried out accordingly, the base station sends a collision detection signal to the terminals. Block 36 is provided for this purpose. By means of the collision detection signals sent in block 36 , the terminals are signaled that the initiation of a collision resolution phase is necessary and that the terminals should send collision resolution signals to the base station.

The separate collision detection signal can e.g. For example, be implemented using a CD / CA-ICH-channel (Collision Detection / Collision Avoidance indication channel) according to the document 3GPP TS 25.211 V3.5.0, ^3rd Generation Partnership Project (3GPP) "Physical channels and mapping of transport channels Onto physical channels (FDD) ", which is provided for positive confirmation or non-confirmation (transmission power zero within a predetermined time period) of CR preambles. The reduction of the CD / CA-ICH channels available for positive or non-confirmation of CR preambles by one channel and the associated reduction of the available CR symbols by one symbol does not represent a significant restriction, since there are no undetected ones Collisions can occur.

In the subsequent block 37 , the terminals each send a collision resolution signal to the base station. A set of different collision resolution signals is provided for collision resolution, which are selected at random by the terminals and sent to the base station. Collision resolution signals can e.g. B. CR preambles (Collision Resolution preambles). Different starting times are also provided for the different terminals for sending the collision resolution signals.

In block 38 , the base station checks whether collisions have occurred again during the transmission of the collision resolution signals. The base station can recognize this from the different start times of the collision resolution signals, each start time being assigned to exactly one terminal. Such collisions in the collision resolution phase can e.g. B. occur when two terminals randomly select the same collision resolution signal or the same CR preamble.

Upon detection of a collision in the collision resolution phase, the base station sends in block 39 to the terminals involved in the collision, that is to say to the terminals that have chosen the same collision resolution signal by chance, no confirmation signal (transmission power zero) within a predetermined time period or in another implementation a negative one confirmation signal. Since the terminals do not receive a positive confirmation signal, they do not send any data on the common transmission channel. This completely prevents collisions. In this case, the terminals involved must request a common transmission channel again by sending the access signals or access preambles again.

If no collisions have occurred in the collision resolution phase, the base station sends in block 40 a positive confirmation signal for one of the CR preambles and no confirmation signal (transmission power zero) within a predetermined period of time or in another implementation a negative confirmation signal for another CR preamble. The terminal that sent the positively confirmed CR preamble can thus use the common transmission channel. The terminals whose CR preamble has not received a confirmation signal (transmission power zero) within a predetermined period of time or, in another implementation, a negative confirmation signal must request a common transmission channel again by sending the access signals or access preambles again.

Basically, in this first embodiment it can be allowed that under In certain circumstances, more than one terminal receives a positive confirmation signal Response to the sent CR preamble is sent, if no collision occurs, so that two or more terminals can continue to send the data part: Send for example, a terminal A and a terminal B the same access preamble P1, and a Terminal C and Terminal D have the same access preamble P2, each of them exclusive allocated sub-access frames, so both preambles can be positive Confirmation signal are acknowledged, which also indicates that a Collision resolution phase must follow. The base station now knows from the phase in which the Access preambles have been sent which terminals are common around the same Transmission channel (in the UMTS of the CPCH) compete. If the terminals are around the same common transmission channel compete (here Terminal A and B, or Terminal C and D) different collision resolution preambles in the collision resolution phase send (for example Terminal A collision resolution preamble K1, Terminal B K2, Terminal C K2 and Terminal D K3), the base station can, for example, the Answer collision resolution preamble K2 with a positive confirmation, which then turns on Terminal B and Terminal C judge while K1 and K3 are not confirmed. There Terminal B and Terminal C do not share the same common transmission channel compete, they can both send their data part at the same time. Alternatively, the Base station also confirm K1 and K3 positively and K2 do not confirm, so that terminal A and Terminal D on different common transmission channels Data section.

Fig. 5 shows a flow chart for a second embodiment of the invention. In this second embodiment of the invention, the access preambles are uniformly sent from all terminals only at the beginning of an access frame. In this second embodiment, individual start times for the terminals within the access frames for sending the access preambles are not assigned. In this second embodiment, a collision resolution phase is provided in each case, with the individual terminals being assigned different start times within the access frames for sending the collision resolution signals.

Block 50 in FIG. 5 shows the start of the flow chart. In block 51 , the base station checks whether the data requirement to be sent by a terminal exceeds a certain amount of data. If this is the case, the base station assigns the respective terminal one or more common transmission channels for any access. This allows the terminal to access the assigned common transmission channel (s) if necessary. At the same time, the base station assigns a sub-access frame to the respective terminal, within which the terminal may send the collision resolution signals to the base station. An individual start time within the radio frame is thus defined for each terminal for sending the collision resolution signals. Such a method is described for example in the document "CPCH Access procedures", Golden Bridge Technologies, Tdoc TSGR2 # 5 (99) 598, TSG-RAN-WG2 # 5, Sophia Antipolis, France, July 5-9, 1999.

If a terminal wishes to access one of the common transmission channels assigned to it, it sends an access preamble to the base station in block 52 as a request signal.

In block 52, it is provided that the access preamble is sent up to 5 times at intervals of 3 access frames each time and the transmission power is increased successively in the process. This ensures that the base station receives the signals from the terminal with sufficient power (power ramping).

In this second embodiment of the invention, each terminal may only send an access preamble at the beginning of one of the access frames # 0 to # 14 according to FIG. 2. In this embodiment, it is therefore not provided to assign the terminals individual start times within the access frames for sending the access preambles.

In block 53 , the base station checks at the beginning of each access frame whether an access preamble with sufficient power is received.

If this is the case, the base station sends in block 54, for example two access frames later, a positive confirmation signal to the respective terminal.

If no access preamble with sufficient power is received, the terminal does not receive a positive confirmation signal from the base station and a return is made to block 52 . Accordingly, the terminal 3 access frame later sends the access preamble again with increased transmission power. This increase in transmission power may be repeated up to four times. Since collisions cannot be recognized in the first phase of the access procedure, in which the access preambles are sent, due to the uniform transmission times of the terminals, if an access preamble is confirmed positively, the second phase is to carry out a collision resolution phase as the second phase. It is not necessary to initiate the collision resolution phase from the base station by sending collision detection signals in this second embodiment of the invention.

Terminals that have received a positive confirmation signal after sending an access preamble automatically send a collision resolution signal to the base station in block 55 . A set of different collision resolution signals is provided for collision resolution, which are selected at random by the terminals and sent to the base station. Collision resolution signals can e.g. B. CR preambles (Collision Resolution preambles). For the transmission of the collision resolution signals, for example, 20 different start times are provided within the access frames for the different terminals, one start time being exclusively assigned to one terminal.

In block 56 , the base station checks whether collisions have occurred again during the transmission of the collision resolution signals. The base station can recognize this from the different starting times of the collision resolution signals. Such collisions in the collision resolution phase can e.g. B. occur when two terminals randomly select the same collision resolution signal or the same CR preamble.

If a collision is detected in the collision resolution phase, the base station sends in block 57 to the terminals involved in the collision, i.e. to the terminals that have chosen the same collision resolution signal by chance, no confirmation signal (transmission power zero) within a predetermined period of time or in another implementation a negative one confirmation signal. Since the terminals do not receive a positive confirmation signal, they do not send any data on the common transmission channel. This completely prevents collisions. In this case, the terminals involved must request a common transmission channel again by sending the access signals or access preambles again.

If no collisions have occurred in the collision resolution phase, the base station sends in block 58 a positive confirmation signal for one of the CR preambles and no confirmation signal (transmission power zero) within a predetermined time period or in another implementation for another CR preamble negative confirmation signal. The terminal that sent the positively confirmed CR preamble can thus use the common transmission channel. The terminals whose CR preamble has not received a confirmation signal (transmission power zero) within a predetermined time period or in another implementation has a negative confirmation signal must request a common transmission channel again by sending the access signals or access preambles again.

Further embodiments of the invention relate to networks in which one common transmission channel or a set of common transmission channels an increased number of terminals can be assigned with the same number of sub-access frames are.

One possibility is to use the 16 available for example Collision resolution preambles in 2, 4 or 8 sub-sets of 8, 4 or 2 Subdivide collision resolution preambles. In this embodiment, then a subset of collision resolution preambles and a start time for each terminal or sub-access frame assigned to send the collision resolution preambles. at In this embodiment, it is then possible for terminals which are provided with different Sets are assigned, the same start time or the same sub-access frame at Use the collision resolution preamble. This means that at the 20th Sub-access frames 40, 80 or 160 terminals on a common transmission channel or assigned to a set of common transmission channels for use can.

The following tables show an example of the assignment of the individual terminals to a start time or sub-access frame and to a sub-set of collision resolution preambles for 20, 40, 80 and 160 terminals that are assigned to a set of common transmission channels (CPCH) for use. The individual terminals are labeled UE (User Equipment). Table 1 A maximum of 20 terminals UE1 to UE 20 can be assigned to a set of common transmission channels (CPCH set)

Table 2 A maximum of 40 terminals UE1 to UE40 can be assigned to a CPCH set

Table 3 A maximum of 80 terminals UE1 to UE 80 can be assigned to a CPCH set

In a further embodiment of the invention it is provided assign standing collision resolution preambles directly and exclusively to the terminals, provided the number of available collision resolution preambles is smaller or is the number of terminals that a common transmission channel or are assigned to a set of common transmission channels (CPCH) for use. For example, if 16 collision resolution preambles are available, the Terminals are exclusively assigned a collision resolution preamble, if not there are more than 16 terminals in the user group of the CPCH set. This simplifies implementation of collision resolution for a small number of terminals.

In a further embodiment of the invention, the access frames are each only divided into a few sub-access frames, e.g. B. in 2, 3 or 4 sub-access frames. This facilitates the time synchronization between transmitter and receiver with regard to Under Access frame.

Are z. B. 2 sub-access frames are provided, 32 terminals can be divided into 2 Sub-sets of 16 units each, the 16 terminals of the first sub-set being the first Sub-access frame and each exclusively assigned a collision resolution preamble is. Correspondingly, the 16 terminals of the second subset is the second Sub-access frame and each exclusively assigned a collision resolution preamble.

However, a collision resolution preamble is then two terminals each assigned, a terminal of the first subset and a terminal of the second subset. If these two terminals happen to be the common at the same time Request transmission channel, the collision can be based on the different Sub-access frames or start times are recognized but not resolved. Therefore, access to the common transmission channel for both terminals to be denied.

To the number of terminals in the user group of a common To double the transmission channel, but at the same time to have a randomization, d. H., that at least two selectable collision resolution preambles for each terminal are available, according to one embodiment of the invention, are at least 4 Access frame provided. Each of the four sub-access frames is 8 Terminals assigned, with each terminal a pair of two Collision resolution preambles is assigned. Each sub-access frame with the assigned terminals and the collision resolution assigned to the terminals Preambles form a set. The pairs of assigned to the individual terminals Collision resolution preambles are advantageously chosen so that they are different from all distinguish other pairs. This improves the randomization and thus reduces it the probability of a collision. The improved randomization is based on the following example clearly: Try two terminals A and B of a radio cell multiple times to access a common transmission channel with a high data rate. If these terminals A and B each have the same pair of collision resolution If preambles are assigned to CR1 and CR2, an occurring collision cannot be resolved if both choose CR1 or both CR2. However, if Terminal A is assigned CR1 and CR2 and Terminal B CR2 and CR3, a collision cannot be resolved only if Terminal A and select Terminal B CR1. CR3 is also another terminal assigned.

An example of 4 sub-access frames is shown in Table 4. The terminals UE1 to UE8 are assigned to a first sub-access frame and form the set 1. The terminals UE9 to UE16 are assigned to a second sub-access frame and form the set 2, the terminals UE17 to UE24 are assigned to a third sub-access frame and form the set 3 and the terminals UE25 to UE32 are assigned to a fourth sub-access frame and form the set 4. Each of the terminals 1 to 32 is assigned a different pair of collision resolution preambles. Table 4 Each set corresponds to a sub-access frame

A corresponding division for 8 sub-access frames is shown in Table 5. With 8 sub-access frames, 64 terminals can be assigned, each of which can choose between two collision resolution preambles at random. Table 5 Each set corresponds to a sub-access frame

Claims (17)

1. Network
with at least one base station and several assigned terminals for the exchange of user and control data and
with at least one common transmission channel, which is provided for the access of several terminals,
the base station for controlling access to the common transmission channel
is provided,
wherein the terminals are provided for sending at least one access signal to the base station for access to the common transmission channel, and wherein the terminals can be assigned at least two different starting times for sending the access signal. 2. Network according to claim 1, characterized, that the terminals for sending a request signal to the base station for Requirement of a common transmission channel are provided that the Base station is provided for sending a confirmation signal to the respective terminal and that the terminals each have different start times for sending the Request signal are assigned. 3. Network according to claim 2, characterized, that the terminal sends a Collision resolution signal is provided and that the terminals are different Start times for sending the collision resolution signal are assigned. 4. Network according to claim 3, characterized, that the base station sends a Collision detection signal is provided to the terminals, which the terminals indicates that the subsequent sending of a collision resolution signal is required. 5. Network according to claim 2, characterized, that the base station sends a positive confirmation signal to a terminal is provided if the request signal of this terminal with sufficient power is received and if the respective request signal from only one terminal has been sent within an access time frame. 6. Network according to claim 2, characterized, that each request signal is assigned to a common transmission channel is. 7. Network according to claim 2, characterized, that in each case a common transmission channel has several request signals assigned. 8. Network according to claim 1, characterized, that the terminals for sending a request signal each at the beginning of an access Timeframes are provided to the base station for the base station to transmit a Confirmation signal to the respective terminal is provided that the terminal upon receipt a positive confirmation signal for sending a collision resolution signal is provided and that the terminals each have different start times for sending are assigned to the collision resolution signal. 9. Network according to claim 1, characterized, that the terminals each have an exclusive start time for sending the access signal is assigned. 10. Network according to claim 1, characterized, that is intended to access the terminals to the common Transmission channel a set of collision resolution preambles and at least assign a start time. 11. Network according to claim 1, characterized, that at least 4 start times are provided, that a set of terminals is assigned to each start time and that a set of at least two different collision resolution preambles for each terminal assigned. 12. Network according to claim 10, characterized, that the sets of collision resolution preambles assigned to the individual terminals are selected so that they differ from the sets of all other terminals. 13. Network according to claim 1, characterized, that is provided, the type of assignment of collision resolution preambles and / or Starting times for the individual terminals depending on the number of Terminals that are allowed to access a common transmission channel. 14. Base station in a wireless network for the exchange of user and control data with several assigned terminals, the base station for controlling access to at least one common one Transmission channel is provided, which is provided for the access of several terminals, wherein the base station for receiving access signals from the terminals for the Access to the common transmission channel is provided and the terminals having at least two different start times for sending the Access signal are assignable. 15. Terminal for a wireless network for the exchange of user and control data with at least one base station and further terminals via at least one common one Transmission channel intended for access by several terminals the terminals being intended for access to the common Transmission channel to send at least one access signal to the base station and wherein the terminals each have at least two different starting times Sending the access signal are assignable. 16. Method for exchanging user and control data in a network between at least one base station and several assigned terminals via at least one common transmission channel, which is provided for the access of several terminals.
the base station being provided for controlling access to the common transmission channel,
the terminals being provided to send at least one access signal to the base station for access to the common transmission channel
and wherein the terminals can be assigned at least two different start times for sending the access signal. 17. Network
with at least one base station and several assigned terminals for the exchange of user and control data and
with at least one common transmission channel, which is provided for the access of several terminals,
the base station being provided for controlling access to the common transmission channel,
the terminals being provided for sending at least one access signal to the base station for access to the common transmission channel
and it is provided that a collision resolution preamble is exclusively assigned to the terminals as an access signal.