DE19957655A1 - Wireless network with several access probabilities, forwarding at least one received reservation message by base station dependent on at least one further access probability - Google Patents

Abstract

The network includes at least one base station (1, 2, 3) and several associated terminals (4-14) for exchanging profit- and control data. A reservation message is send to an associated base station dependent on a first access probability for an assignment of a transmission capacity for at least one data packet. A forwarding of at least one received reservation message by the base station is dependent on at least one further access probability. An Independent claim is provided for a corresponding base station and a terminal used in the network.

Description

The invention relates to a wireless network with at least one base station and several assigned terminals for the exchange of user and control data in each case for sending a dependent on a first access probability Reservation message to assign transmission capacity for at least one Data packet are provided to the assigned base station.

The document "TSG-RAN Working Group 2 (Radio Layer 2 and Layer 3 Radio), Sophia-Antipolis, France, 16 ^th to 20 ^th August 1999, TS 25.321, V3.0.0 (1999-06), ^3rd Generation Partnership Project (3GPP); Technical Specification Group (TSG) RAN; Working Group 2 (WG2); MAC protocol specification ", a MAG protocol (MAC = Medium Access Protocol) is proposed for a radio network. The radio network consists of several radio cells, each with a base station and terminals or mobile stations located therein. After registering and synchronizing a terminal, a terminal sends, for example, a request packet for a user channel (random access burst) via a collision-related channel, which is referred to as the RACH channel (RACH = Random Access Channel). The notification package consists of a preamble part and a data part. Before a message packet can be sent from a terminal to the base station, only a preamble is used to test whether e.g. B. the transmission power of the terminal is sufficient. Before the transmission, a terminal must check whether a random value formed by the terminal is smaller than an access probability value (persistency probability) sent to the terminal by the base station. If the random value is less than the access probability value, the preamble may be sent. If the terminal sending a preamble has not received a message from the base station within a certain time, a retransmission with a higher transmission power is started after a certain time. If necessary, the transmission power is increased up to a predetermined maximum value. In the other case, the terminal receives either an assignment or rejection message or, after a predefined time (time-out), neither an assignment or a rejection message. In the latter case, for example, the base station was unable to detect the preamble sent. In the case of an assignment message, the terminal can send the data part of the message package with the set transmission power. For example, the base station sends out a rejection message if there is no channel capacity for the transmission of the data part. In the event of a rejection message, a retransmission with the original initial transmission power is also started after a certain time and this is then successively increased (power ramping). When a new transmission attempt is made, a random value must first be compared with the access probability value. This access procedure described applies to all terminals. This does not differentiate between terminals that are trying to send a message package for the first time and those that have already received a rejection message from the base station, as well as those that have received neither an assignment nor a rejection message. This can lead to unacceptable waiting times in the network for sending message packets.

The invention has for its object to provide a wireless network in which the waiting time for sending message packages is reduced.

The task is solved by a wireless network of the type mentioned at the beginning
that the further transmission of a reservation message received at least once by the base station is dependent on at least one further access probability,
that the base station is intended to send a factor only after a complete data packet has been rejected and
that a terminal is provided for forming the further access probability from the received factor and the first access probability.

Under the wireless network according to the invention is a network with several To understand radio cells, in each of which a base station and several terminals control  and transmit user data wirelessly. A wireless transmission is used for transmission of information e.g. B. via radio, ultrasound or infrared paths.

According to the invention, different access probabilities are used to to be able to customize the access type. Here are reservation requests treated differently. A data packet contains a preamble and a data part and sends out a preamble as a reservation request from a terminal. A Allocation of transmission capacity means that a terminal is part of a data Message packet can be transmitted via the RACH channel. A terminal is upon receipt an allocation message for sending the data part of the data packet is provided.

If a terminal expires after a defined time after sending a data part issues a preamble for the first time, there is an access type of the first type. An access type second type means that a terminal sends a preamble Has received a rejection notice. With a third-type access type, a terminal sends a preamble within the defined time after sending a piece of data. If a terminal after submitting a preamble and gradually increasing the Transmitting power up to the maximum transmitting power (power ramping) is neither an allocation nor has received a rejection message, there is a fourth type of access. Here are the access probabilities for the access types first, third and fourth type periodically sent to all terminals via the broadcast or distribution channel, while the Access probability for the access type of the second type only if one Rejection message was sent, is formed in a terminal. For this the Base station only a factor above that after receiving a rejection message Broadcast or distribution channel to the terminal. From the received factor and the With the first access probability, the terminal forms the second access probability possibility. In the latter case, the rejection notification is sent to the rejected Preamble bound, so that the access probability for the access type of the second type can be determined differently according to preambles.

Exemplary embodiments of the invention are explained in more detail below with reference to the figure. Show it:  

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

FIGS. 2 to 5 are flow charts for explaining the sequence assignment of the RACH channel for the transmission of a data packet from a terminal.

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 (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 with 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 can 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. For Transmission of control data from a terminal to a connection before it is established Base station can be, for example, an uplink control channel assigned by the base station can be used, but other terminals can also access it. 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 one transmitter and one Receiver are set up are called dedicated channels. Usually is a Payload channel is a dedicated channel used by a dedicated control channel for transmission can be accompanied by connection-specific tax data.

A collision channel is used to connect a terminal to a base station responsible, hereinafter referred to as the signaled RACH channel (RACH = Random Access Channel) is called. You can also use such a signaled RACH channel Data packets are transmitted.

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 Method is used that after determining an appropriate frequency range  the temporal position of a frame is determined on the basis of predetermined parameters (Frame synchronization), with the help of which the time sequence for the transmission of Data is done. Such a framework is always for the data synchronization of terminals and base station necessary for TDMA, FDMA and CDMA processes. Such a Frame 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 that 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 help of pulses emitted by the base station be synchronized. If no code spreading procedure (e.g. CDMA procedure) is used (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.

If, after synchronization, a terminal receives a message packet (random access burst), which consists of a preamble part and a data part, via a collision-prone channel called the RACH channel (RACH = Random Access channel), various steps are carried out in the terminal, which are indicated by a flow chart in FIG. 2. Block 15 in FIG. 2 indicates the start (S) of the flowchart. The reception of various control parameters in the terminal (BS → P _I , P _III , Mmax) from the assigned base station is shown in block 16 . For example, the base station sends the access probability values P _I , P _III and a maximum value Mmax, which specifies the maximum number of successive attempts to access the RACH channel. First, a counter variable M is set to zero (block 17 ). This counter variable M denotes the number of consecutive attempts to send the terminal that have already started.

The next step in the flowchart is a loop. The beginning of the loop is identified by a block 18 in which the counting variable M is incremented. It is then checked in block 19 whether the counter variable M is less than or equal to the maximum value Mmax. If this is not the case, a first loop end results (block 20 ). Block 20 indicates an error E. In the other case (block 21 ) it is checked which access type ZT it is. An access type ZT _{I of the} first type exists when the terminal tries for the first time to issue a preamble.

If there is an access type ZT _{I of the} first type (block 22 ), the parameters PI and Mmax transmitted periodically by the assigned base station via a broadcast or distribution channel are updated (U: P _I , Mmax; U = update). An update means that the parameters P _I and Mmax last received by the assigned base station are then valid. Subsequently (block 23 ), the terminal takes a random value RN (RN ∈ [0, 1]) from a random generator (not shown in more detail).

In the present case (access type ZT _{I of the} first type), the random value RN ( FIG. 3: block 25 ) is next compared with the access probability value P _I in block 24 (in this case, the terminal belongs to the access type ZT _{I of the} first type). . If the random value RN is greater than the access probability value P _I , the terminal cannot send the preamble and starts again after a waiting time TI (1) ( FIG. 3: block 26 ) with the step specified in block 22 . In the other case ( Fig. 3: Block 27 ), the terminal may issue the preamble (T → PRE). The terminal then checks ( FIG. 3: block 28 ) whether a rejection message or an assignment message has been received from the assigned base station (RES?) Within a certain time. If no message has been received (No ACK), after a waiting time TI (2) ( FIG. 3: block 29 ), the step in block 18 ( FIG. 2) is continued again (start of loop). If a rejection message is received (NACK), after a waiting time TI (3) ( FIG. 3: block 30 ), the loop also continues. In the case of an allocation message (ACK), as shown in block 31 ( FIG. 2), the data part of the message packet is sent (TX). This ends the first branch of the loop (block 32 ).

If it is determined in block 21 that an access type ZT _{II of the} second type exists, the parameters P _II and Mmax received by the assigned base station via a broadcast or distribution channel are reacted next (block 33 ) in response to the previously received rejection message ( NACK) taken (R: P _I , Mmax; R = Read). The parameter P _II , unlike the parameter P _{I, is} not sent periodically in order not to unnecessarily use capacity on the broadcast or distribution channel. Periodic sending can be dispensed with, because the respective value of P _II only becomes relevant shortly after a rejection message has been sent by the base station. A removal means that the parameters P _II and Mmax taken from the terminal are valid for the first time or from then on. As in the previous case, the terminal then takes (block 23 ) a random value RN (RN ∈ [0, 1]) from the random generator (not shown in more detail).

In block 34 , the random value RN ( FIG. 4: block 35 ) is compared with the access probability value P _II (in this case, the terminal belongs to the access type ZT _{II of the} second type). If the random value RN is greater than the access probability value P _II , the terminal cannot send the preamble and, after a waiting time TII (1) ( FIG. 4: block 36 ), starts again with the step specified in block 33 . In the other case ( Fig. 4: Block 37 ), the terminal may issue the preamble (T → PRE). The terminal then checks ( FIG. 4: block 38 ) whether a rejection message or an assignment message has been received from the assigned base station (RES?) Within a certain time. If no message has been received (No ACK), after a waiting time TII (2) ( FIG. 4: block 39 ), the step indicated in block 18 is continued (start of loop). If a rejection message is received (NACK), after a waiting time TII (3) ( FIG. 4: block 40 ), the loop also continues. In the case of an allocation message (ACK), as shown in block 41 ( FIG. 2), the data part of the message packet is sent (TX). This ends the second branch of the loop (block 42 ).

If it is determined in block 21 that an access type ZT _{III of the} third type is present, the corresponding steps are carried out as for the access type ZT _{I of the} first type (blocks 22 to 32 ).

If it is determined in block 21 that an access type ZT _{IV of the} fourth type exists, the parameters P _IV and Mmax which are periodically transmitted by the assigned base station via a broadcast or distribution channel are updated next (block 43 ) (U: P _IV , Mmax; U = update). As before, the terminal then takes (block 23 ) a random value RN (RN ∈ [0, 1]) from the random generator (not shown in more detail).

In block 44 , the random value RN ( FIG. 5: block 45 ) is compared with the access probability value P _IV (in this case, the terminal belongs to the fourth type of access type ZT _IV ). If the random value RN is greater than the access probability value P _IV , the terminal cannot send the preamble and, after a waiting time TIV (1) ( FIG. 5: block 46 ), starts again with the step specified in block 43 . In the other case ( Fig. 5: Block 47 ), the terminal may issue the preamble (T → PRE). The terminal then checks ( FIG. 5: Black 48 ) whether a rejection message or an assignment message has been received from the assigned base station (RES?) Within a certain time. If no message has been received (No ACK), after a waiting time TIV (2) ( FIG. 5: block 49 ), the step indicated in block 18 is continued (start of loop). If a rejection message is received (NACK), after a waiting time TIV (3) ( FIG. 5: block 50 ), the loop also continues. In the case of an allocation notification (ACK), as shown in block 51 ( FIG. 2), the data part of the notification packet is sent (TX). This ends the third branch of the loop (block 52 ).

The base station receives preambles within an access period which can be part of a frame of reference. The base station specifies the access probabilities P _I to P _IV , which depend, for example, on the traffic load, interference situation, a high load for the signal processing of certain circuit parts of the base station when receiving dedicated and BACH channels and on the level during preamble reception.

Different access probabilities are used in order to Treat wishes. If the terminal after a defined time after  Sending a piece of data for the first time sends a preamble is the first access type Type before (first access probability). If the terminal after sending a Preamble has received a rejection message, this means a type of access of the second type (second access probability). If the terminal within the defined time After sending a piece of data again sends a preamble, there is an access type third type before (third access probability). If the terminal after sending a preamble and gradual increase in transmission power up to one Maximum transmit power (power ramping) is neither an assignment or a rejection message received, there is a fourth type of access (fourth access probability). How already mentioned, the access probabilities for the access types first, third and fourth types periodically via the broadcast or distribution channel to all terminals sent, while the access probability for the access type second type only if a rejection message was sent via the broadcast or distribution channel to all terminals is sent.

Is z. For example, if the interference or traffic load is too high, the base station sends a rejection message (NACK) to at least one terminal. Information about parameter P _II is also sent via the previously mentioned broadcast or distribution channel for the terminals which have received the rejection message (NACK) after sending their preamble. In this case, the base station chooses the access probability P _II less than the access probability P _I. Here, the parameters P _II can have different values for each preamble acknowledged with a rejection message.

The access probability P _II determined by the base station, on the other hand, is higher than the access probability P _I if there is a high load on the signal processing of certain circuit parts of the base station when receiving dedicated and RACH channels.

If the level of preamble reception is unacceptably high compared to the other reception levels, then the base station sets the access probability P _II to a significantly lower value than the access probability P _I because the too high level has already led to a noticeable reception disturbance in the base station. An unacceptably high preamble reception level can exist if a terminal is very close to the base station.

The advantage of using different access probabilities for each preamble lies in the individual adaptation to the respective situation for each terminal and leads to a reduction in access time. Because the access probability P _{II is} only issued after a rejection message (NACK) has been sent, there is a very low signaling load on the broadcast or distribution channel, so that a suitable choice of P _I can be achieved so that a rejection message only rarely has to be sent. However, individual treatment of the respective causes for sending out the rejection message is not waived.

For example, one embodiment of a wireless network currently can discussed UMTS radio access network (UTRAN). Access types of the first and second type can then be used here. The access Third and fourth type types are counted as first type access type in this example. In this system, a base station can have a logical node called Node B. will be assigned, and a radio network controller. The logical node is for the radio transmission in at least one radio cell is responsible and is via a Interface connected to the radio network controller. The radio network controller is responsible for the control of all components involved in radio communication and builds z. B. each have a connection for the transmission of user data.

The physical layer is terminated in the logical node. Denial notifications (NACK) are generated directly from the physical layer and sent to the terminals sent. There are a total of 8 access slots in one frame to which 16 preambles can be sent. Thus lie per frame in total 128 parallel RACH channels. For each of these channels there can be a rejection notification sent. A rejection notice relates precisely to a preamble and the Access time slot in which the preamble was sent.  

Furthermore, system information (e.g. interference situations) that is common must be updated directly in the logical node (Node B) and not only in the Insert radio network control (RNC) into a broadcast or distribution channel. This is necessary because, due to the difference between the logical node (Node B) and the Radio network controller (RNC) interfaces lie to large delays would arise. That means time-critical system information is not timely could be sent to the radio interface.

This possibility of inserting system information into the distribution channel in the logical node (Node B) is used in the invention in order to insert an information element IE into the distribution channel in the event of a rejection message during frame n after m further frames, which for each in frame n sent rejection message contains the value of the access probability P _II . The value m is fixed (e.g. m = 2), and this is because at least the duration of 2 frames is provided as the transmission time for the distribution channel. The value m can be distributed as part of the system information.

In particular, two cases for the access probability P _{II have} to be considered. In a first case (in the case of prioritization), the rejection message was sent because all hardware resources are temporarily in use for processing packets already received in the RACH channel. This bottleneck will have disappeared in the next or the next frame. The rejected preamble should then be transferred into this frame. For this purpose, the access probability P _II is chosen to be greater than the access probability P _I. A possible value for the access probability P _I would even be the value 1.

In the second case (case of greater delay), it is possible that a terminal has chosen the initial power for the transmission of a preamble (preamble power) too high due to inaccurate estimation of data losses during transmissions via uplink channels. In this situation, the terminal should not attempt to send the preamble until there is a better estimate of data loss. In this case, the access probability P _{II is} chosen to be significantly smaller than the access probability P _I.

To encode these various possibilities, a factor α <1 is regularly distributed to all terminals with P _I. The factor α is determined such that P _II = min (α P _I , 1) in the case of prioritization of a previously rejected preamble and P _II = P _I / α if a transmission of this preamble is to be delayed longer after rejection of a preamble.

There is a little more design freedom if, for both cases, a second access probability P _II is explicitly sent to the terminals on the broadcast or distribution channel. In this case, three instead of two parameters must be distributed: P _I , P _{II, 1} (for prioritization), P _{II, 2} (for greater delay).

In the case of the transmission of rejection messages in frame n, the preamble is coded in the frame for each rejection message sent with 4 bits and with 3 bits the access slot to which the rejection message referred. Another bit indicates whether P _{II, 1} (for prioritization) or P _{II, 2} (for greater delay) at the sender of the respective preamble should apply to the next attempt to send this preamble.

In this way, one needs only 8 bits in total for coding the access probability to be used 1% (second type of access type). However, additional bits are required to identify the entire information element IE. If it is set to zero, this means that the preamble power sent was too high and the terminal may only send a preamble again after a further reduction in the transmission power, in which case P _I controls the sending of the next preamble.

Claims (1)

1. The wireless network, characterized by at least one base station and a plurality of assigned terminals for exchanging user data and control data, which are respectively provided for emitting a frequency dependent on a first access probability reservation message for allocating transmission capacity for at least one data packet to the associated base station characterized ,
that the further transmission of a reservation message received at least once by the base station is dependent on at least one further access probability,
that the base station is intended to send a factor only after a complete data packet has been rejected and
that a terminal is provided for forming the further access probability from the received factor and the first access probability.