Telecommunications – Transmitter and receiver at same station – Radiotelephone equipment detail
Reexamination Certificate
2000-10-27
2004-08-03
Urban, Edward F. (Department: 2685)
Telecommunications
Transmitter and receiver at same station
Radiotelephone equipment detail
C455S561000, C455S452100, C370S534000
Reexamination Certificate
active
06771987
ABSTRACT:
TECHNICAL FIELD OF THE INVENTION
The present invention relates generally to methods for using adaptive antennas in cellular mobile telephone systems, and more particularly the invention relates to a method for performing uplink scheduling of packet data when using adaptive antennas.
The invention also relates to an arrangement for carrying out the method.
BACKGROUND OF THE INVENTION
It is anticipated that a large part of the future growth of wireless communication will be data traffic. Due to the “burstiness” of data traffic, the spectrum is more effectively used if the users share a common resource. An efficient way of sharing a resource is to use packet data. Thus, a great effort has been made in standardising a protocol for transmitting packet data in a GSM mobile communication network. This protocol is called GPRS (General Packet Radio Service) with future enhancements in EGPRS (Edge GPRS).
The GPRS protocol enables more than one mobile station to use the same timeslot or timeslots. This is done by time multiplexing users on the same radio resource. When starting a transmission the mobile station is assigned one or more timeslots in up- and downlink. In the assignment the mobile stations are given a temporal bit flow identity (TFI) and an uplink state flag (USF). The TFI is attached to the data blocks in order to identify the terminating mobile station of the transmitted block. In the downlink all mobiles are listening to the assigned timeslots and try to decode all blocks but only considers the blocks with corresponding TFI's.
The preferred method for scheduling the uplink is to use the USF, which is attached to user data in a downlink block. A mobile station is allowed to transmit an uplink block on a following time slot or a number of following timeslots if it detects its USF in the corresponding downlink block. This method is called dynamic assignment. Another method for scheduling the uplink is to use an entire downlink block, i.e. when a mobile station is signalling uplink channel request, the reply from the network is a bitmap telling the mobile station what timeslots in what TDMA-frames the mobile station should use. The bitmap is transmitted to the mobile station in a dedicated data block. This method is called fixed assignment.
Adaptive antennas, here defined to be an antenna system that is able to change its characteristics to changes in the network, have several interesting properties. One of the most important features of an adaptive antenna system is that the base station is able to detect the direction to the mobile station and can thus transmit dedicated information in an antenna beam towards a desired mobile station. An antenna beam is defined as any signal transmission deliberately covering only a part of a cell, and a cell is defined as the total coverage area of a base station. This implies that the downlink signal is not transmitted in the entire cell resulting in lower interference in the system. Adaptive antennas have been shown to increase the system downlink C/I as much as 6 dB compared to a regular system using sector-antennas. The interference level generally determines the channel reuse patterns. Because the interference level is reduced a channel reuse pattern can be formed in which channels are reused more frequently, thus increasing the capacity of the network. If the reuse pattern is left unchanged the C/I of the communication links is increased. Thus, the reduced downlink interference can be used either for increasing the number of users in the system or for increasing the C/I of the communication links.
The increased C/I of the communication links can in its turn be used to produce a significant throughput increase in a system carrying GPRS/EGPRS traffic. This is mainly due to link adaptation, which transforms communication link improvements into a throughput increase. In EGPRS a number of different coding schemes and two modulation methods are used to ensure maximum throughput at the current communication link quality C/I, i.e. the payload per transmitted data block varies with the quality of the communication link. A communication link having high quality can be used for a higher data transmission rate either by applying higher modulation or lower coding. Thus, it is obvious that there is a large potential in applying adaptive antennas in systems carrying GPRS/EGPRS traffic.
However, a problem exists with uplink scheduling when using adaptive antennas since user data and scheduling information usually terminates at different mobile stations. If the mobile stations are spatially separated there is a problem transmitting in an antenna beam since communication is optimised for only one of the mobile stations.
One possible solution of scheduling the uplink is found in WO-99/41918, which is especially advantageous with adaptive antennas, when all radio blocks on the downlink transmissions do not have to be broadcast to all users on a certain channel. Two possibilities are discussed first to use fixed allocation where the initial setup signalling specifies when users are allowed to transmit on the uplink. The second possibility is to transmit the scheduling information on a broadcast channel so that it is certain that the correct mobile station receives the scheduling information and transmit all other data blocks in antenna beams to the mobile stations for which the data is intended.
Another possible solution of forming antenna beams, which permit other remote communication stations to detect the communication signals transmitted to a selected remote station, is described in WO-98/33233. More particularly the document solves the problem by using at least two antenna beams active at the same time to also cover mobile stations for which the transmission is not intended. The purpose is mainly to use the signal energy transmitted in the downlink for enabling complexity reduction in the mobile station and for facilitating the tracking of the downlink signal in a successive timeslot, such as e.g. in D-AMPS (Digital Advanced Mobile Phone System).
The solution according to WO-98/33233 has the disadvantages of having to use two antenna beams active at the same time causing interference and overhead. The main purpose is also not to perform uplink scheduling as in the present invention, but instead to use the signal energy received for, e.g. AGC (Automatic Gain Control) adjustments and for reducing the complexity in the mobile station.
There is a need for flexible and efficient solutions for uplink scheduling when using adaptive antennas.
SUMMARY OF THE INVENTION
The present invention thus provides a solution to the protocol problems concerning how to perform uplink scheduling of packet data when using adaptive antennas.
In the preferred uplink-scheduling mode of GPRS/EGPRS the scheduling information is attached to user data. It is likely that the user data and the scheduling information are terminated at different mobile stations. Hence, if the mobile stations are separated the communication does not reach every intended receiver of the data.
One object of the present invention is thus to provide uplink scheduling of packet data in a radio communication system using adaptive antennas.
Another object of the invention is to reduce the amount of overhead necessary for uplink scheduling of packet data in a communication system with adaptive antennas.
The above mentioned objects are achieved by transmitting the data blocks containing scheduling information in an antenna beam towards the mobile station for which the scheduling information is intended and by scheduling mobile stations with similar position on the same radio resource, i.e. the same Packet Data Channel (PDCH). All other data blocks are transmitted in an antenna beam towards the mobile station for which the data are intended.
In the first embodiment of the invention when the data blocks containing the scheduling information is transmitted in an antenna beam towards the mobile station for which the scheduling information is intended, there is a risk for a larger block error probability at t
Berg Magnus
Dam Henrik
Chow C.
Telefonaktiebolaget LM Ericsson (publ)
Urban Edward F.
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