Abstract:
The present invention relates to methods and arrangements for facilitating an efficient connection setup. The present invention specifies rules for defining the signaling of connection setup messages from user equipments such as to apply one single transmission if an assigned uplink transmission grant for transmitting the connection setup messages is sufficiently large while applying separate transmissions if the size indicated in said uplink transmission grant is not sufficient. Thus, a sufficiently large grant allows a parallel execution of the connection setup messages.

Description:
TECHNICAL FIELD 
       [0001]    The present invention relates to a method and arrangement in a mobile communication system, in particular to the connection setup in evolved universal terrestrial radio access networks (E-UTRAN). 
       BACKGROUND 
       [0002]    One of the basic functions in all types of telecommunication networks is the setup of communication connections such that a user end terminal desiring to establish a communication connection to another, remote terminal is provided with the necessary share of resources. In wireless communication systems, e.g. as illustrated in  FIGS. 1 a  and 1 b   , allocation of resources implies on the one hand the allocation of radio resources in the radio access network  15   a , 15   b  and, on the other hand, resources in the core network  11   a , 11   b .  FIG. 1 a    illustrates a part of a Universal Terrestrial Radio Access Network (UTRAN) as specified in Release 99 of the specifications issued by the 3 rd  Generation Partnership Project (3GPP). A user equipment  14   a  is connected via a radio connection to at least one radio base station  13   a  (or NodeB), where in turn several base stations are controlled by a radio network controller  12   a,  which also provides a connection interface to the core network  11   a.    FIG. 1 b    illustrates correspondingly a part of an evolved Universal Terrestrial Radio Access Network (E-UTRAN) as specified in Release 8 of the specifications issued by the 3 rd  Generation Partnership Project (3GPP). 
         [0003]    User equipments  14   b  are connected to an evolved Node B (eNB)  13   b,  which in turn is connected to an entity  12   b  that is responsible for mobility management, user plane activities, and handles the necessary connections to the core network  11   b.    
         [0004]    The signalling protocols used between the network and the user equipment (terminal) are divided into Access Stratum (AS) and Non-Access Stratum (NAS) protocols. The Non-Access Stratum protocols, e.g. Session Management (SM), Mobility management (MM), are terminated in the terminal (UE) and core network (CN) and are sent transparently via the Radio Access Network (RAN). The Access Stratum protocols (e.g. Radio Resource Control (RRC), Radio Link Control (RLC), Medium Access Control (MAC)) are terminated in the UE and RAN, and are not visible in the CN. Additionally there is an Iu-like signalling between the RAN and CN which is not visible to the UE. 
         [0005]    Connection setup is done by a random access procedure on a special channel Random Access Channel (RACH). Basically, as several users can make use of this channel it is necessary, in case of more than one access request, to resolve which user may momentarily use it. For optimization of the accessibility of the network to the user equipments it is desirable that the access procedure is performed without undue delays. The connection setup procedure as performed in UTRAN and applying a sequential approach is illustrated in  FIG. 2 a   . The user equipment sends the “RRC Connection Request” message to the Node B and finalizes this procedure by sending a “RRC Connection Setup Complete” message after having received a “RRC Connection Setup” message from the Node B. Then, subsequently, the user equipment sends the “Initial NAS Message” and, possibly, further optional NAS Signaling and waits for a “NAS Response” message delivered via the Node B. Correspondingly,  FIG. 2 b    illustrates the connection setup procedure as currently assumed for E-UTRAN where “RRC Connection Request” message and “Initial NAS Message” are sent in parallel. 
         [0006]    In general it has been focused to optimize the connection setup by fastening the initial setup procedures. One means to fasten said setup is to allow a parallel execution of the RRC Connection Request procedure and the subsequent Non-Access Stratum procedures, which is shown in  FIG. 2 b    whereas in UTRAN, as shown in  FIG. 2 a   , RRC Connection Request and NAS signaling are performed sequentially. Thus, E-UTRAN provides a faster way of setting up a connection. 
       SUMMARY 
       [0007]    Although the parallel processing of RRC Connection Request procedures and Non-Access Stratum procedures fastens the connection setup procedure it has been observed to be a problem that the size of messages to be transmitted by the Non-Access stratum procedure can vary substantially. Also, it is possible that the size of messages varies due to variations of the link quality, i.e. the size relative to the link quality/capacity can vary substantially. 
         [0008]    Thus, when large messages need to be transmitted during connection establishment several problems may occur: The transmission occurs at a time when a potential contention has not yet been resolved, i.e. more than one user equipment may be trying to transmit on the same resource, making it difficult to use a retransmission scheme, e.g. HARQ, for enhancing reliability. Further, mandating a low rate of transmission, it is difficult to estimate the uplink quality that is suitable for all users in the cell. 
         [0009]    It is thus the basic idea of the present invention to specify rules for defining the signaling of connection setup messages by the user equipment such as to apply one single transmission if the assigned uplink transmission grant for transmitting said connection setup messages is sufficiently large while applying separate transmissions if the size indicated in said uplink transmission grant is not sufficient. Thus, a sufficiently large grant allows a parallel execution of the connection setup messages by the user equipment. 
         [0010]    The present invention allows usage of the advantages of a fast connection setup on the one hand while also providing a reliable fallback mechanism in cases where a fast setup is not applicable. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0011]      FIG. 1 a    illustrates a part of a UTRAN as specified in Release 99 of the 3GPP-specifications while  FIG. 1 b    illustrates a part of an E-UTRAN as specified in Release 8 of the 3GPP-specifications. 
           [0012]      FIG. 2 a    illustrates the connection setup procedure in UTRAN while  FIG. 2 b    illustrates the connection setup procedure in E-UTRAN. 
           [0013]      FIG. 3  illustrates the method according to the present invention performed in the UE for providing an improved connection setup. 
           [0014]      FIG. 4  illustrates the method according to the present invention for implementing said rule as performed in a node of the radio access network. 
           [0015]      FIG. 5  illustrates arrangements in the network node and user equipment to perform the method according to the present invention. 
       
    
    
     DETAILED DESCRIPTION 
       [0016]    In order to transmit a connection setup message, a user equipment has to use the random access procedure, which generally consists of a Random Access Request sent by the user equipment and followed by a Random Access Response from the network. The Random Access Response contains a grant for an uplink transmission, whereby the size of this initial grant should be large enough to allow the transmission of the initial message by the user equipment. However, it may from the network side not be possible to exactly determine the size of the uplink grant such as to match the radio conditions and buffer status of the user equipment. First, the network is typically not able to determine the quality of the uplink accurately (or at all) based on the Random Access Request, and will therefore have to assign the initial grant based on other parameters, e.g., the estimated channel quality at the edge of the cell. Second, as the size of the initial NAS message varies, it may also be difficult for the network to allocate the uplink grant to exactly match the size of the UE initial message. Thus the network will respond (at least occasionally) with a grant that will not allow the transmission of the whole initial message. 
         [0017]    Furthermore, it is the nature of the Random Access procedure that there may be several UEs attempting at the same time, in which case they all will receive the Random Access Response, and will all transmit the initial message at the same time, leading to a collision. For this reason, it may not be desirable to transmit large messages before possible contention of such colliding user equipments has been resolved. 
         [0018]    The present invention suggests implementing a rule in the user equipment such that the network, as illustrated by  FIG. 4 , in the Random Access Response can assign  42  a grant with a size that is autonomously determined  41  by the network node. The size of this grant can be determined  41  either statically or dynamically. A static size of the grant can be based, e.g., on the cell deployment such that, for instance, large initial grants are used in small cells in which the data rate at the cell border is large. A dynamic size determination can be based, e.g., on parameters like system load, possible information about the size of the UE message, estimated channel quality, etc. 
         [0019]      FIG. 3  illustrates the method according to the present invention for implementing said rule as performed in the UE: Upon receiving  31  from the network a grant message for uplink transmission the UE determines  32  the size S of the grant and determines  33  whether this size allows transmission of both the RRC Connection Request with size S RRC  and the Initial NAS message having a size S NAS . If the grant size is large enough,  33 Yes, the UE can immediately transmit  34  both messages in parallel. If the grant is not large enough,  33 No, the UE only transmits  35  the RRC Connection Request and holds the Initial NAS message even if it would have been possible to partly transmit the NAS message. The UE indicates  36  to the network that it has further data to transmit. This can be done by means of scheduling information method or by using a normal scheduling request. According to one embodiment of the present invention, scheduling information can be enabled to be sent in the same transmission as the RRC Connection Request. 
         [0020]    Upon receiving the RRC Connection Request message the network can, if necessary, perform a contention resolution when more than one user equipment have provided a connection request. This can be resolved, e.g., by transmitting separate contention resolution messages in the downlink. Further, if there was a scheduling request or scheduling information included in the indication message from the UE the network assigns an additional grant for the requesting UE. After having received the contention resolution message the UE can use, e.g., HARQ to improve the reliability of the transmission. The reception of the additional grant from the eNodeB finally triggers the transmission  37  of the NAS message that did not fit in the initial message. 
         [0021]    The method according to the present invention as described above is implemented in a network node, typically the radio base station (or eNodeB), and a user equipment in a radio access network.  FIG. 5  shows such a network node  52  in a radio access network  50  including a first electrical circuitry  521  that is adapted to determine the size of an uplink transmission grant to a user equipment  51 , whereby said size is autonomously determined by the node based on cell-specific or load-specific parameters; and including a second electrical circuitry  522  that is adapted to assign said uplink transmission grant in a random access response to said user equipment  51 . The user equipment  51  on the other hand includes a first electrical circuitry  512  that is adapted to determine the size of the assigned uplink transmission indicated by a received uplink transmission grant and a second electrical circuitry  513  adapted to initiate a parallel transmission of said RRC Connection Request and the initial NAS message if the size indicated by the initial grant allows transmission of both messages. It further comprises a transmitter part  514  that is adapted to send an indication to transmit further data if the initial NAS-message could not be transmitted in parallel to the RRC Connection Request.