JP2011147184A - Communication resource assignment method and system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a communication resource assignment system and a method used for a multi-user cellular communication system. <P>SOLUTION: The present invention relates to a method for assigning communication resources in a multi-user cellular communication system in which the communication resources are divided into a plurality of time zones and a plurality of frequency sub-bands in a time domain and a frequency domain, partial communication resources are used for a frequency-localized channel and partial communication resources are used for a frequency-distributed channel. The method further includes a step for classifying a part of the frequency sub-bands into frequency sub-bands to package the frequency-distributed channel and classifying the remaining part of the frequency sub-bands into frequency sub-bands to package the frequency-localized channel. The present invention further relates to a system, a transmitter and a communication system. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a radio communication system, and more particularly to a communication resource allocation method that can be used in a multi-user cellular communication system based on data packets.

  In a multi-user cellular communication system based on a data packet, for example, a multi-user orthogonal frequency division multiplexing (OFDM) system, which radio resource is allocated to which user at what time is determined by a scheduler apparatus. Users always report their radio channel quality to the base station, and the base station makes scheduling decisions based on the reported channel quality. In the uplink, the base station can measure channel quality, for example, channel quality is measured by a pilot signal transmitted from a user. The scheduler takes advantage of the independence of different user channel changes, i.e. one or more users' channels are decaying, or one or more channels assigned to a particular user are decaying Meanwhile, scheduling can be performed by utilizing the fact that the channels of other users do not decay. Generally, radio resources are allocated to users only when the user channel condition is good. Therefore, system performance (in terms of cell throughput) is improved by scheduling compared to a system that does not utilize user channel quality due to scheduling.

  In the downlink, how much the scheduler improves system performance is determined by the quality of the feedback information, where high quality, detailed and accurate channel quality feedback is required. However, in some cases, accurate and timely feedback information cannot be acquired. For example, there is a possibility that the user moves at high speed, and in this case, the channel quality metric value is already wasted when it reaches the base station. Also, for example, for users around the cell, the signal-to-noise ratio of the up-feedback channel is so bad that an error occurs when the base station receives the fed back channel quality metric, and the feedback metric obtained in this case is reliable. Can not.

  If the channel changes rapidly at one transmission time interval, for example, when the Doppler spread is large, the efficiency of scheduling is very low. Certain types of data, such as low latency requirements and low data rates, do not need to be scheduled. Feedback data is a typical representative of this type of data. In this case, it is more appropriate to use a dedicated channel.

  For these cases, the system can provide a frequency discrete channel to obtain high diversity link performance. Therefore, a user who can provide reliable channel quality feedback and can apply transmission data to scheduling is assigned time-frequency resources with good radio channel conditions, and frequency-discrete channels are assigned to other users.

  However, how to enable a high link diversity (frequency-distributed) channel and a high multi-user diversity (frequency-localized) channel simultaneously. Providing it is a problem at this time.

  The IEEE standard 802.16-2004, “Local Area Network and Metropolitan Area Network Standard”, Chapter 16, “Air Interface for Fixed Broadband Access Systems”, so-called “Air Interface for Fixed Broadband Access Systems”. There are attempts to propose a method to solve the problem by using “zones”. One zone is a time zone for transmitting one specific type of channel. Each radio frame includes two zones, one transmitting a frequency localized channel and the other transmitting a frequency discrete channel, both employing simple time multiplexing. Each message header of the radio frame is attached with specific information indicating when to switch from one zone to the next.

The disadvantage of this solution is that link diversity is limited.
Therefore, there is a need for a system that provides improved link diversity.

  An object of the present invention is to provide a communication resource allocation system and method used in a multi-user cellular communication system. Compared with the prior art, its link diversity performance is improved.

  According to the first aspect of the present invention, the object can be achieved by a method as defined in claim 1 and a system as defined in claim 12.

According to the present invention, communication resources are divided into time zones and frequency subbands that are different in the time domain and the frequency domain, some communication resources are used for frequency discrete communication channels, and some communication resources are used as frequency stations. Used for existing channels. Specifically, the method includes:
Classifying the frequency subbands into subbands mounting frequency discrete channels and subbands mounting frequency localized channels.

  The advantage of this method is that the delay to the above two types of channels due to the “zone” configuration in the prior art is eliminated, so that frequency discrete communication and frequency localized communication can be performed simultaneously and there is no mutual interference. is there. And since continuous transmission of data is permitted in the present invention, link diversity performance can also be improved. This is because even if the signal quality in a certain time zone in one transmission frame is extremely poor, good signal quality in another time zone in the transmission frame can sufficiently guarantee correct transmission. A further advantage of the present invention is that it does not introduce delays in discrete or localized transmission data. This is because the two types of channels always exist at the same time, and the effect of the advantage is particularly remarkable for packet data transmission that requires early retransmission.

  After classifying the frequency subbands, the subband classification may be changed in each time zone after a predetermined number of time intervals or after a predetermined time interval. The subband type can be transmitted on the broadcast channel when one time period starts or before one time period starts. The advantage of the method is that the frequency localized communication resource and the frequency discrete communication resource can be divided at any time based on a scheme that optimizes the system throughput.

  One code indicating a specific communication resource arrangement can be transmitted to the receiver, and the receiver can obtain a communication resource allocation scheme to be used by using the code. The advantage of this method is that it can inform the receiver of a complex communication resource scheme without using signals.

  Frequency subband classifications can be maintained in different time zones. The advantage of doing so is that certain subbands can be used all the time for a particular type of communication.

  The frequency discrete channel may be a frequency hopping channel, a time multiplexed channel or a code multiplexed channel, or a frequency interleaved multiplexed channel. The advantage of such a setting is that the diversity gain of the frequency discrete channel can be further increased.

  The invention also relates to a transmitter and a multi-user cellular communication system.

It is a figure which shows the method of transmitting the frequency localization channel and frequency discrete channel which concern on a prior art. FIG. 2 is a diagram illustrating a communication resource scheme suitable for the present invention. It is a figure which shows one Example based on this invention. It is a figure which shows the other Example which concerns on this invention.

  As described above, in a multi-user communication system based on a data packet, communication can be performed using a frequency localized channel, that is, a frequency localized channel assigned to a user based on the fed back channel quality. Similarly, as described above, in a specific case, for example, when the user moves fast and the fed back channel quality metric has already been wasted late when reaching the base station, or When both the communication data delay requirement and the data rate are extremely low, the frequency localized channel cannot be applied. In this case, in general, communication tends to be performed using a frequency discrete channel.

  Therefore, it is necessary for the system to be able to use the two types of communication simultaneously.

  When using frequency localized channels and frequency discrete channels simultaneously, these channels should be complemented (ie, the resources used by these channels do not overlap each other) and as many physical radio resources as possible are available to the user. Should be allocated (ie there should be no idle resources).

  FIG. 1 is a diagram showing a conventional solution. As shown in FIG. 1, the entire frequency band is divided into a plurality of subbands, that is, subbands 10a to 10j, and each subband includes a plurality of subcarriers (not shown). Further, the assigned subband is divided into a plurality of transmission frames, and one transmission frame is shown in FIG. Each transmission frame includes a certain time zone and is divided into a plurality of time slots. FIG. 1 shows TS1 to TS8, and each time slot is also divided into a plurality of symbols. When frequency localized communication and frequency discrete communication are required, each frame is divided into two zones. The first zone Z1 is used as a frequency localized channel, and the second zone Z2 is used as a frequency discrete channel. Used, both zones adopt a simple time multiplexing method. As described above, specific information indicating when to switch from one zone to the next zone is attached to each message header of the radio frame. As described above, the disadvantage of the solution is that frequency localized communication and frequency discrete communication cannot be performed simultaneously. The “zone” configuration introduces a delay in the two types of channels. In addition, since each frequency discrete channel uses only one of the zone Z1 and the zone Z2, the diversity gain in the frequency discrete channel is reduced.

  FIG. 2 is a diagram showing a communication resource scheme applicable to the present invention. The system shown in FIG. 2 is a multi-carrier OFDM system with a two-dimensional configuration (time and frequency). The frequency band of the OFDM system is divided into 10 subbands, that is, 20a to 20j, and the bandwidth of each subband is preferably equal. Subbands with equal bandwidth are advantageous for resource management (eg, scheduling allocation of available resources can be simplified). However, it goes without saying that the frequency band may be divided into subbands having unequal bandwidths. Each subband is divided into a plurality of subcarriers. For example, each subband may include 20 subcarriers (not shown), but one subband may be one, five, 100, or any number. Subcarriers can also be included.

  In the time domain, the frequency band is divided into a plurality of time slots, and each time slot includes a plurality of OFDM symbols. The time slot shown in FIG. 2 comprises 8 OFDM symbols, ie S1 to S8. The frequency spectrum / time spectrum constitutes a set of communication resource arrangements, where the minimum resource unit that can be allocated to one user is one subband in one OFDM symbol period (used for frequency discrete communication, and further described below). Will be described in detail).

  In the present invention, one transmission frame is divided into different time zones as in the prior art, and is not used for frequency localized communication and frequency discrete communication, but communication resources are divided based on frequencies.

  In the embodiment of the present invention, the subbands 20a, 20c, 20e, 20g, and 20i are used for frequency localized communication, and the subbands 20b, 20d, 20f, 20h, and 20j are used for frequency discrete communication. Then, as shown in FIG. 2, three users, that is, UE1 to UE3 (UE1 is in subband 20e, UE2 is in subbands 20c and 20i, and UE3 is in 20a and 20g) are communicating in the frequency localized channel. In the frequency discrete channel, two users, UE4 and UE5, are communicating. In the present invention, all users can enjoy continuous data transmission regardless of which type of communication they use. And the advantage of continuous transmission is that data transmission using frequency discrete channels can be extended to all time slots, i.e. not only using part of one frame, but to all time in one frame. It can be expanded to improve the diversity gain of the channel. Not only that, the present invention also improves system throughput, for example by allowing frequency localized communication to be performed all the time, and therefore between users with good channel quality, whether or not in one transmission frame. There is also an advantage that communication can be realized.

  In actual applications, a scheduler is employed to multiplex frequency localized channels into subbands used for frequency localized channels and frequency discrete channels to subbands used for frequency discrete channels.

  It will be apparent to those skilled in the art that the frequency localized channel and the frequency discrete channel can be arbitrarily assigned. In the example shown in FIG. 1, each type of communication is allotted half of the resources. However, for those skilled in the art, it is clear that the frequency localized channel and the frequency discrete channel can be arbitrarily divided if there are at least one subband in the two types of communication. For example, if the data traffic in a cell changes with time, the channel division can also change with time. However, it is preferable that the channel division change rate is not fast, that is, it is preferable to use the same channel division for a plurality of consecutive frames, which can significantly reduce the signal required by the system. Each time slot or whenever the channel split changes, the base station can transmit information on the broadcast channel to explain which subband is used for which type of communication. Based on the usual practice in systems using frequency localized channels, the scheduler determines which frequency localized channels are assigned to which users, and then the information is transmitted to the users via the control channel. It is necessary to publish in the system which frequency discrete channel is assigned to which user.

  For data transmission in frequency discrete channels, a number of different methods can be employed to further improve diversity gain. For example, as shown in FIG. 2, users UE4 and UE5 can use frequency hopping. In this case, the base station and the user use the same algorithm to determine the frequency hopping sequence adopted for the frequency hopping channel. One user can be assigned two or more subbands used for frequency discrete transmission.

  In addition, in one embodiment according to the present invention, one or more channel resource allocation schemes are set in advance in the base station and the receiver. In this way, the base station can transmit one code indicating the currently used resource allocation scheme by a scheme such as a broadcast channel, and the receiver can look up the channel resource in the scheme by drawing a table. The allocation method can be acquired. Each time the channel resource allocation scheme changes, the base station should send a code indicating the new resource allocation scheme. The advantage of this method is that the amount of signal is minimized. In another embodiment according to the present invention, the base station can transmit information indicating which subband is used for transmitting which type of signal. This step can be performed periodically and / or whenever resource allocation (frequency localization or frequency discrete) changes based on a preset interval. In other embodiments according to the present invention, the communication system standard can only include one kind of arrangement, and that arrangement should be used all the time, and the advantage of doing so is to send a signal to the communication resource arrangement scheme. There is no need to instruct.

  As described above, the frequency hopping scheme is used only for subbands assigned to frequency discrete channels. However, in a system including a plurality of base stations, generally, frequency hopping tends to be employed to optimize interference between base stations to some extent. When the adopted frequency hopping pattern is arranged based on the allocation of base station channels, the frequency hopping patterns of neighboring base stations use different channel allocation schemes and may cause mutual interference. Therefore, as shown in the embodiment of FIG. 3, a general-purpose frequency hopping pattern can be adopted and used for all types of subbands. Since the generated frequency hopping sequence has a limitation that subbands used for the frequency localized channel cannot be included, these frequency bands are excluded from the frequency hopping pattern.

  A general-purpose frequency hopping sequence has the following advantages. Adoption of a general-purpose frequency hopping sequence can be arbitrarily assigned based on the channel quality without any restrictions on the assignment of non-frequency hopping (frequency localized) channels that highly demand the channel quality . In addition, the frequency hopping pattern designed for finite mutual interference can be directly used, and there is no need for correction, which actually improves inter-cell interference in different frequency hopping modes. As shown in FIG. 3, the frequency hopping pattern of UE4 indicates that subband 30a should be used in TS2 and subband 30e should be used in TS6. However, according to the present invention, in these time slots, UE4 does not transmit any data, and frequency localization data in UE2 TS2 and frequency localization data in UE1 TS6 are preferentially processed.

  The advantage of the solution is that the amount of downlink signal is reduced because the same frequency hopping pattern is adopted regardless of the channel assignment. The requirements for the frequency discrete channel and the frequency localized channel in different cells are different from each other, and the requirements for the two types of channels in the same cell are different at different times. Thus, it is better to use different resource allocation schemes for different cells in order to provide services to users more efficiently. Similarly, in order to improve efficiency, resource allocation in the same cell should also change with time.

  FIG. 4 is a diagram showing another embodiment according to the present invention. In FIG. 4, the upper three subbands 40a to 40c are used for frequency localized channels, and the lower three subbands 40d to 40f are used for frequency discrete channels. However, in this embodiment, frequency diversity is adopted without using frequency hopping to realize channel diversity, that is, each user of UE4 to UE6 is assigned a channel in subbands 40d to f. Each user is assigned one or more subcarriers in one subband. Channel diversity can also be achieved by other schemes (not shown), eg, time multiplexing or code multiplexing.

Claims (21)

A method of allocating communication resources for communication between a transmitter and a receiver in a multi-user cellular communication system, wherein the communication is across frequency discrete channels that provide link diversity or frequency localization that provides multi-user diversity. It is performed across channels, dividing communication resources into multiple time zones and multiple frequency subbands in the time domain and frequency domain, respectively , and using some communication resources for frequency localized channels in one time zone , Use some communication resources for frequency discrete channels,
Classifying a part of the frequency subbands into frequency subbands carrying frequency discrete channels;
Further comprising transmitting the remainder of the frequency subbands are classified into frequency subbands for mounting the frequency localization channel, one code indicating whether to receivers used communication resource allocation to the receiver A method characterized by that.   The method of claim 1, further comprising: changing the classification of the subbands at each of the time periods after classifying the frequency subbands, after a certain number of time intervals, or at a predetermined time interval. The method according to claim 1, further comprising broadcasting a frequency subband type on a broadcast channel when one of the plurality of time zones starts or before one of the time zones starts. the method of. The method according to claim 1 or 2 , wherein a receiver obtains a communication resource arrangement scheme to be used with the code.   The method of claim 1, further comprising maintaining a classification of implemented frequency subbands in the different time zones after classifying the frequency subbands.   The method of claim 1, wherein the frequency discrete channel comprises a frequency hopping channel. The method of claim 6 , wherein the frequency hopping channel is based on a frequency hopping sequence, and subbands used by non-frequency hopping channels are excluded from the frequency hopping sequence. The method according to any one of claims 1 , 2 , 5 , 6 , and 7 , wherein the frequency discrete channel includes one of a time multiplexed channel, a code multiplexed channel, and a frequency interleaved multiplexed channel. A scheduler is employed to multiplex the frequency localized channel into the frequency subband used for the frequency localized channel, and to multiplex the frequency discrete channel to the frequency subband used for the frequency discrete channel. The method according to any one of 1 , 2 , 5 , 6 , and 7. The method according to claim 1 , wherein the time zone is one time slot or one transmission frame. The method according to claim 1, wherein the communication resource arrangement corresponds to a classification of the frequency subband. A system for allocating communication resources for communication between a transmitter and a receiver in a multi-user cellular communication system, wherein the communication is across frequency discrete channels that provide link diversity or frequency localization that provides multi-user diversity It is performed across channels, dividing communication resources into multiple time zones and multiple frequency subbands in the time domain and frequency domain, respectively , and using some communication resources for frequency localized channels in one time zone , Using some communication resources for frequency discrete channels, the system
Classifying a part of the frequency subbands into frequency subbands carrying frequency discrete channels;
The remainder portion of said frequency subbands are classified into frequency subbands for mounting the frequency localization channels, a processor,
The system further Ru comprising a device that transmits one code indicating to the receiver using a communication resource allocation to the receiver,
A system characterized by that. The processor or a predetermined time interval after after a certain number of time intervals, according to the classification of the sub-bands in claim 12 which is further configured to change at each said time slot system. The apparatus is further configured to broadcast a frequency subband type on a broadcast channel when one of the time periods starts or before one of the time periods starts . The system according to claim 12 or 13 . The processor system of claim 12 configured to hold the classification of the frequency sub-bands at different said time period in said plurality of time zones.   The system according to any one of claims 12, 13, and 15, wherein the frequency discrete channel includes a frequency hopping channel. It said frequency hopping channel is a frequency hopping sequence to the base, wherein the processor is system according to the frequency hopping sequence, to claim 16 which is further configured to exclude subbands non-frequency-hopping channel uses. The system according to any one of claims 12 , 13 , and 15 , wherein the frequency discrete channel includes one of a time multiplexed channel, a code multiplexed channel, and a frequency interleaved multiplexed channel. Transmitter for a multi-user cellular communication system, characterized in that it comprises a device for performing the method according to any one of claims 1 to 11. A transmitter scheduler for a multi-user cellular communication system comprising:
  Place multi-frequency localized channels in multiple frequency subbands determined to be used for frequency localized channels, and multi-frequency discrete in multiple frequency sub-bands used for multi-frequency discrete channels Means for arranging the channels,
  Classify some of the frequency subbands into frequency subbands with frequency discrete channels,
  Classify the remainder of the frequency subband into frequency subbands with frequency localized channels;
  A scheduler, characterized in that a code indicating a communication resource arrangement used by a receiver is transmitted to the receiver.   A receiver for a multi-user cellular communication system, comprising:
  Means for receiving a code indicating a communication resource arrangement used by the receiver;
  The receiver communicates with a transmitter;
  The communication is performed via frequency discrete channels that provide link diversity or frequency localized channels that provide multi-user diversity;
  Dividing communication resources into multiple time zones and multiple frequency subbands, using one communication resource for frequency localized channel and one communication resource for frequency discrete channel in one time zone,
  Classifying a part of the frequency subbands into frequency subbands carrying frequency discrete channels;
  The receiver, wherein the remainder of the frequency subband is classified into a frequency subband equipped with a frequency localized channel.

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