WO2012147479A1 - 移動通信システムにおける基地局及びリソース割当方法 - Google Patents
移動通信システムにおける基地局及びリソース割当方法 Download PDFInfo
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- WO2012147479A1 WO2012147479A1 PCT/JP2012/059265 JP2012059265W WO2012147479A1 WO 2012147479 A1 WO2012147479 A1 WO 2012147479A1 JP 2012059265 W JP2012059265 W JP 2012059265W WO 2012147479 A1 WO2012147479 A1 WO 2012147479A1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/20—Control channels or signalling for resource management
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/20—Control channels or signalling for resource management
- H04W72/23—Control channels or signalling for resource management in the downlink direction of a wireless link, i.e. towards a terminal
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/50—Allocation or scheduling criteria for wireless resources
- H04W72/56—Allocation or scheduling criteria for wireless resources based on priority criteria
- H04W72/566—Allocation or scheduling criteria for wireless resources based on priority criteria of the information or information source or recipient
Definitions
- the present invention relates to a base station and a resource allocation method in a mobile communication system.
- One technique for improving frequency utilization efficiency in mobile communication systems is frequency scheduling.
- radio resources are dynamically allocated to users according to the priority according to the data type and the quality of the radio channel state. For example, which radio resource is allocated to which user is determined for each 1 ms subframe (TTI). Since how to allocate radio resources to users changes frequently, radio resources can be used flexibly.
- voice data data with a small amount of data is generated periodically.
- voice data data with a small amount of data is generated periodically.
- the semi-persistent scheduling method is a method that can cope with such concerns.
- one radio resource allocation is applied not only to one subframe but also to many subsequent subframes. That is, by periodically allocating a certain radio resource, overhead required for radio resource signaling is reduced. Therefore, if all user apparatuses in the mobile communication system are compatible with the semi-persistent scheduling method (SPS), the above-mentioned concerns can be solved by using SPS for voice data.
- the semi-persistent scheduling method is not essential according to the 3GPP rules, the user equipment in the mobile communication system does not always support semi-persistent scheduling. If all user apparatuses do not support SPS, it is necessary to allocate radio resources by the dynamic scheduling method after all. However, in that case, it is necessary to designate radio resources one by one for each piece of audio data with a small amount of data generated periodically, and in addition to increasing overhead, the radio resources cannot be effectively used. Is concerned.
- the amount of overhead is not constant, and in the case of a long-term evolution (LTE) mobile communication system, 1 to 3 symbols are transmitted from a control signal (PCFICH) in one subframe formed of 10 or more symbols. , PHICH, PDCCH, etc.) (overhead).
- PCFICH control signal
- PHICH PHICH
- PDCCH Physical Downlink Control Channel
- the amount of overhead varies depending on the number of users in the cell and the cell radius. The larger the number of users in a cell, the amount of data traffic, the number of simultaneously multiplexed users per subframe, the cell radius, etc., the larger the amount of overhead, which causes a decrease in throughput.
- the LTE system is described in Non-Patent Document 1, for example.
- scheduling is performed for each subframe (TTI) of 1 ms, and control information (for example, PDCCH) indicating radio resource allocation content is notified to the user apparatus.
- control information for example, PDCCH
- the user apparatus transmits an uplink signal (PUSCH) using the radio resource indicated by the control information.
- N the number of users who can specify radio resources in one subframe
- Figure 1 shows how various user equipments (UE1-UE60) are transmitting audio data in 20 ms.
- UE1-UE60 user equipments
- a base station is: A scheduling unit that generates uplink grant information indicating that uplink radio resources are allocated to a user equipment of a first multiplexing number or less; A transmission unit for transmitting a control signal including the uplink grant information to a user apparatus; A receiving unit that receives an uplink signal transmitted by a user apparatus according to the uplink grant information, and the user apparatus that transmits small data is present in a second multiplex number that is smaller than the first multiplex number and smaller. If there is a user device that transmits data that is not present, the scheduling unit has uplink radio resources between the second multiplex number of user devices that transmit periodic data and the user device that transmits data that is not small. This is a base station in a mobile communication system that generates uplink grant information indicating that it is assigned.
- uplink radio resources when radio resources are allocated to small data, uplink radio resources can be used effectively.
- the number of multiplexed voice users who transmit periodic data such as voice data is in principle limited to the maximum number of multiplexed voice users less than the “maximum number of multiplexed users” in the subframe.
- the “maximum number of multiplexed users” described here is fixedly set or the limit number of PDCCHs that can be multiplexed is considered.
- the maximum number of multiplexed voice users may be dynamically changed according to the number of voice users, the voice bearer control channel (PDCCH) usage rate, and the like.
- the maximum voice user multiplexing number when the maximum user multiplexing number is 4, the maximum voice user multiplexing number may be set to 3 and the maximum multiplexing number of data other than voice data may be set to 1 at the time of congestion.
- the maximum number of multiplexed audio data may be set to 2 during non-congested times, and the maximum number of multiplexed data other than audio may be set to 2.
- voice data or voice packets will be described. However, voice data or voice packets are only an example, and this embodiment can be applied to all bearers that generate only small data. It is.
- the number of multiplexed voice users is limited to a maximum number of multiplexed voice users that is less than the maximum number of multiplexed users.
- radio resources are not allocated to voice users beyond that.
- the audio data includes not only audio data at the time of initial transmission but also audio data by retransmission (which consumes PDCCH).
- radio resources are allocated to voice users exceeding the maximum number of multiplexed voice users.
- Base station 2 Example of operation 2.1 When there are voice users and non-voice users 2.2 When there are only voice users Modified example 3.1 Modified example considering retransmission 3.2 Modified example considering PDCCH resource allocation
- FIG. 2 shows a functional block diagram of a base station used in the embodiment.
- FIG. 2 shows processing units particularly related to the embodiment, among the processing units that realize various functions provided in the base station of the mobile communication system.
- the illustrated base station is a base station in a long-term evolution (LTE) mobile communication system, but may be a base station in another mobile communication system.
- FIG. 2 shows an uplink signal reception unit 201, an uplink quality measurement unit 203, a user multiplexing number control unit 205, a scheduling unit 207, a TFR selection unit 211, a downlink signal generation unit 213, and a downlink signal transmission unit 215.
- LTE long-term evolution
- the uplink signal reception unit 201 receives an uplink signal from the user apparatus UE and converts it into a baseband signal. Therefore, the uplink signal reception unit 201 has a function of filtering the received radio signal, a function of converting an analog signal into a digital signal, a function of demodulating the received signal, a function of channel decoding the received signal, and the like.
- the uplink signal generally includes a control signal, a pilot signal, a data signal, and the like.
- the user apparatus UE may be any appropriate communication apparatus that communicates with a base station through a radio link, and may be a mobile terminal or a fixed terminal. Specifically, the user apparatus UE is a mobile phone, an information terminal, a high-function mobile phone, a smartphone, a tablet computer, a personal digital assistant, a portable personal computer, or the like, but is not limited thereto.
- the uplink quality measurement unit 203 measures the uplink radio channel state based on the received uplink signal.
- the uplink radio channel state may be derived from the reception level of the pilot signal included in the received uplink signal.
- the reception level may be expressed in any suitable amount known to those skilled in the art. As an example, the reception level is broadly defined as an amount representing the quality of the radio channel state regardless of whether it is an instantaneous value or an average value.
- the received electric field strength RSSI, the desired wave received power RSCP, the path loss, It may be expressed by SNR, SIR, SINR, Ec / N 0 , RSRP, RSRQ, E b / N 0 or the like.
- the desired wave in RSCP, SNR, SIR, SINR, etc. may be, for example, the power of a shared data channel (PUSCH, PDSCH), pilot signal (sounding reference signal (SRS), demodulation reference signal (DMRS), cell-specific The power of the reference signal or user-specific reference signal may be
- the user multiplex number control unit 205 controls the maximum voice user multiplex number N VOICE which is smaller than the maximum user multiplex number N MAX and notifies the scheduling unit 207 of it.
- the maximum user multiplexing number N MAX is the maximum number of user apparatuses that can transmit data in the same subframe in the uplink.
- the maximum voice user multiplexing number N VOICE is the maximum number of user apparatuses that can transmit periodic data in the same subframe in the uplink.
- Periodic data is data that occurs periodically and is typically audio data. In the following description, for the sake of simplification, the case where the user communicates audio data will be described as an example. However, the present embodiment is not limited to audio data, and is applicable to any communication in which data of a small size is periodically generated. Is possible.
- the maximum user multiplexing number N MAX is maintained at a constant value, but the maximum voice user multiplexing number N VOICE may be variably controlled or may be maintained constant. In the case of variable control, for example, the maximum user multiplexing number N MAX is 4, and the maximum voice user multiplexing number N VOICE is set to 3, 2, 1 depending on the number of users transmitting voice data in the cell. May be controlled (Maximum voice user multiplexing number N VOICE is 3 when the number of users transmitting voice data is large, and Maximum voice user multiplexing number N VOICE is 1 when the number of users transmitting voice data is small. is there).
- the maximum user multiplexing number N MAX and the maximum voice user multiplexing number N VOICE are merely examples, and other values may be used. Furthermore, the maximum number of multiplexed voice users N VOICE may be controlled depending on the traffic volume as well as the number of voice users.
- the number of users who communicate voice data may be the number of users for which voice bearers are set, or may be a user whose voice bearer is set for the current time in the talk spurt period.
- a talk spurt period that is an occurrence period
- a silent period that is a silent period alternately occur
- the talk spurt period for example, at a constant cycle such as 20 ms. Audio data is generated.
- the logical channel group LCG has a priority according to the logical channel to which specific data is mapped.
- the priority of the LCG associated with the voice data is the LCG associated with the data for data communication. Higher than the ones.
- the scheduling coefficient may be calculated by, for example, the MaxC / I method or the proportional fairness method.
- the base station receives a notification of a quality of service class indicator (QCI) from the core network regarding information communicated by the user.
- QCI quality of service class indicator
- This QCI represents the priority of the traffic type.
- the base station multiplies the user's scheduling coefficient by a factor according to the QCI so that the scheduling coefficient takes a value according to the priority of the QCI. Further, by changing parameters used for calculating the scheduling coefficient based on the QCI, the scheduling frequency and the like can be controlled in accordance with the QCI. Scheduling is performed based on a plurality of logical channel groups LCG corresponding to the QCI.
- radio resources are allocated from data belonging to the LCG having a higher priority. Note that this embodiment can be widely applied not only when radio resources are allocated based on a scheduling coefficient, but also when radio resources are allocated based on an arbitrary algorithm that prioritizes a voice bearer separately from the scheduling coefficient.
- Scheduling section 207 preferentially allocates radio resources to users whose scheduling coefficients are relatively large (or hard-decisionally determined to have high priority). The way of allocating radio resources in the uplink is notified to the user apparatus by the control signal as uplink grant information.
- the scheduling unit 207 has user devices that transmit voice data more than the voice user multiplexing number N VOICE and user devices that transmit aperiodic data that is not voice data. In this case, uplink radio resources are allocated to the user equipment of the voice user multiplexing number N VOICE that transmits voice data and one or more user apparatuses that transmit aperiodic data.
- radio resources are allocated according to priority to the number of user apparatuses calculated by subtracting the number of user apparatuses performing retransmission from the total number of user apparatuses that have calculated scheduling coefficients. It is done. As will be described in the modification, in the allocation of radio resources, retransmission data has higher priority than non-retransmission data.
- the downlink signal generation unit 213 generates a downlink signal including a control signal and a data signal.
- the control signal indicates how radio resources are allocated to the user equipment.
- this control signal includes at least a physical downlink control channel (PDCCH). More precisely, the channel to which the control signal is sent is not only the PDCCH, but also PCFICH for transmitting a format indicator (CFI) indicating the number of OFDM symbols to which the PDCCH is mapped, and uplink data received by the base station It includes a channel (PHICH) for sending acknowledgment information indicating an acknowledgment or a negative response to the signal (PUSCH). .
- the control signal in this embodiment includes uplink or downlink grant information.
- the base station determines the priority of each user apparatus UE to be scheduled.
- the user apparatus that is the target of scheduling is a user apparatus that has data to be transmitted in the uplink.
- the priority is determined according to the logical channel group LCG and the scheduling coefficient of data transmitted by the user apparatus UE.
- the priority of periodically generated periodic data such as audio data is higher than the priority of non-periodic data that does not occur at periodic timing. Strictly speaking, the data is retransmitted periodic data, retransmitted aperiodic data, non-retransmitted periodic data, and non-retransmitted aperiodic data in descending order of priority.
- each user apparatus that transmits periodic data or non-periodic data is determined according to a scheduling coefficient.
- a scheduling coefficient For simplification of explanation, a case where the user communicates voice data will be described as an example. However, the present embodiment is not limited to voice data, and can be applied to any signal that is generated periodically. is there. For example, a ping signal (PING) transmitted periodically to test the normality of the communication connection may be used.
- PING ping signal
- the base station determines a radio resource to be allocated to the user apparatus UE # x1 in a target subframe and a transmission format (data modulation scheme and channel coding rate) to be used.
- the base station allocates radio resources to the user equipment up to the maximum user multiplexing number N MAX , even if there are more first and third user apparatuses than the maximum voice user multiplexing number N VOICE ,
- the total number of first and third user apparatuses to which is assigned is limited to the maximum number of voice user multiplexing N VOICE .
- PHICH control signal
- NACK negative acknowledgment
- PHICH retransmission is performed using the same number of resource blocks and MCS as before.
- this retransmission method is referred to as “PHICH retransmission”. That is, in the case of PHICH retransmission, the base station can notify that the user apparatus should retransmit without using the PDCCH resource.
- FIG. 6A and FIG. 6B show a flowchart of an operation example used in this modification. Generally, it is the same as that shown in FIGS. 3A and 3B, except that step S601 is added.
- step S601 when the data of the user apparatus UE # x is not transmitted by PHICH retransmission, the flow proceeds to step S315, and the described processing is performed.
- the case other than the PHICH retransmission is specifically a grant retransmission or non-retransmission.
- the flow proceeds to step S319, the number of assigned users I is increased, and radio resources are secured in step S321.
- the described processing is performed.
- the value to be set may be a fixed value as in the case of the voice user multiplexing number N VOICE , or may be variably controlled according to the number of voice users in the cell. Also, the amount of PDCCH radio resources (number of CCEs) I VOICE and PDCCH actually allocated to the voice user is set to zero. Regardless of whether or not the user is a voice user, the radio resource amount (number of CCEs) I PDCCH of PDCCH actually allocated is set to zero. The value of priority m is set to 1.
- the present invention has been described above with reference to specific embodiments, they are merely illustrative and those skilled in the art will appreciate various variations, modifications, alternatives, substitutions, and the like.
- the present invention may be applied to any appropriate mobile communication system that transmits and receives voice data.
- the present invention has been described using specific numerical examples to facilitate understanding of the invention. However, unless otherwise specified, these numerical values are merely examples, and any appropriate value may be used. .
- specific mathematical formulas have been described to facilitate understanding of the invention, these mathematical formulas are merely examples, unless otherwise specified, and any appropriate mathematical formula may be used.
- the classification of the examples or items is not essential to the present invention, and the items described in two or more items may be used in combination as necessary.
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Abstract
Description
上りリンクの無線リソースが第1の多重数以下のユーザ装置に割り当てられることを示す上りグラント情報を生成するスケジューリング部と、
前記上りグラント情報を含む制御信号をユーザ装置に送信する送信部と、
前記上りグラント情報にしたがってユーザ装置が送信した上り信号を受信する受信部と
を有し、小さなデータを送信するユーザ装置が前記第1の多重数より少ない第2の多重数以上存在し、かつ小さくないデータを送信するユーザ装置が存在していた場合、前記スケジューリング部は、周期データを送信する前記第2の多重数のユーザ装置と小さくないデータを送信するユーザ装置とに上りリンクの無線リソースが割り当てられることを示す上りグラント情報を生成する、移動通信システムにおける基地局である。
2.動作例
2.1 音声ユーザ及び非音声ユーザが存在している場合
2.2 音声ユーザしか存在していなかった場合
3.変形例
3.1 再送を考慮する変形例
3.2 PDCCHリソース割当量を考慮する変形例
図2は、実施例において使用される基地局の機能ブロック図を示す。図2には、移動通信システムの基地局に備わる様々な機能を実現する処理部の内、実施例に特に関連する処理部が示されている。図示の基地局は、説明の便宜上、例えばロングタームエボリューション(LTE)方式の移動通信システムにおける基地局であるとするが、他の移動通信システムの基地局でもよい。図2には、上り信号受信部201、上り品質測定部203、ユーザ多重数制御部205、スケジューリング部207、TFR選択部211、下り信号生成部213、下り信号送信部215が示されている。
図3Aおよび図3Bは、図2に示されているような基地局における動作例を示すフローチャートである。フローはステップS301から始まり、ステップS303に進む。
最大音声ユーザ多重数: NVOICE=2
割り当てを受けた音声ユーザの数:IVOICE=0
割り当てを受けたユーザの数: I=0
優先度: m=1
ステップS309において、基地局は、m番目に優先度が高いユーザ装置UE#xを選択する。目下の例の場合、m=1なので、優先度が最高のユーザ装置UE#x1が選択される。例えば、音声データを送信するユーザ装置と音声以外のデータを送信するユーザ装置とがセルに存在していた場合、音声データを送信するユーザ装置が選択される。
説明の便宜上、7台のユーザ装置がスケジューリングの対象となっており、優先度mが1-4のユーザ装置UE#x1-4が、音声データを送信するユーザ装置であり、優先度mが5-7のユーザ装置UE#x5-7が、音声データではないデータを送信するユーザ装置であるとする。
ステップS321において、基地局は、対象のサブフレームにおいてユーザ装置UE#x1に割り当てる無線リソース、及び使用される伝送フォーマット(データ変調方式及びチャネル符号化率)を決定する。
最大音声ユーザ多重数: NVOICE=2
割り当てを受けた音声ユーザの数:IVOICE=1
割り当てを受けたユーザの数: I=1
優先度: m=2
ステップS309において、基地局は、m番目に優先度が高いユーザ装置を選択する。目下の例の場合、m=2なので、優先度が2番目に高いユーザ装置UE#x2が選択される。
最大音声ユーザ多重数: NVOICE=2
割り当てを受けた音声ユーザの数:IVOICE=2
割り当てを受けたユーザの数: I=2
優先度: m=3
ステップS309において、基地局は、m番目に優先度が高いユーザ装置を選択する。目下の例の場合、m=3なので、優先度が3番目に高いユーザ装置UE#x3が選択される。
最大音声ユーザ多重数: NVOICE=2
割り当てを受けた音声ユーザの数:IVOICE=2
割り当てを受けたユーザの数: I=2
優先度: m=4
ステップS309において、基地局は、m番目に優先度が高いユーザ装置を選択する。目下の例の場合、m=4なので、優先度が4番目に高いユーザ装置UE#x4が選択される。
最大音声ユーザ多重数: NVOICE=2
割り当てを受けた音声ユーザの数:IVOICE=2
割り当てを受けたユーザの数: I=2
優先度: m=5
ステップS309において、基地局は、m番目に優先度が高いユーザ装置を選択する。目下の例の場合、m=5なので、優先度が5番目に高いユーザ装置UE#x5が選択される。
なお、上記の例においては、音声データを送信するユーザ装置UE#x1-4と、音声データ以外のデータを送信するユーザ装置UE#x5-7とが存在していたが、仮に、音声データを送信するユーザ装置UE#x1-4しか存在していなかった場合は、ユーザ装置UE#x1-3に無線リソースが割り当てられる。そのような場合、ステップS327からステップS317にフローが進む。
最大音声ユーザ多重数: NVOICE=2
割り当てを受けた音声ユーザの数:IVOICE=2
割り当てを受けたユーザの数: I=2
優先度: m=3
ステップS309において、基地局は、m番目に優先度が高いユーザ装置を選択する。目下の例の場合、m=3なので、優先度が3番目に高いユーザ装置UE#x3が選択される。
<<3.1 再送を考慮する変形例>>
上りリンクの無線リソースを優先度にしたがってユーザ装置に割り当てる場合、再送のデータの優先度は、再送でないデータの優先度より高い。したがって、一般的には、周期データを再送する第1のユーザ装置、非周期データを再送する第2のユーザ装置、再送ではない周期データを送信する第3のユーザ装置、及び再送ではない非周期データを送信する第4のユーザ装置の順に優先度は低くなる。基地局は、最大ユーザ多重数NMAXに至るまでユーザ装置に無線リソースを割り当てる場合において、第1及び第3のユーザ装置が最大音声ユーザ多重数NVOICEより多く存在していたとしても、無線リソースが割り当てられる第1及び第3のユーザ装置の総数は最大音声ユーザ多重数NVOICEに制限される。
ところで、下りリンク又は上りリンクの共有データチャネルの無線リソースを割り当てるための制御信号は、PDCCHにより各ユーザ装置に通知される。1つのサブフレーム(単位伝送期間又は送信時間間隔TTI)に含まれるPDCCHには、複数のユーザ装置宛の制御情報が含まれてもよい。この場合、ユーザ装置各々に使用されるPDCCHの無線リソース量は同じであるとは限らない。PDCCHの受信品質(例えば、受信誤り率)を一定値に保つために必要な無線リソース量は、ユーザ装置各々の通信状況に依存して異なるからである。例えば、基地局近辺のユーザ装置の場合、無線チャネル状態が良いので、チャネル符号化率が大きくても所要品質を満たすことができる。したがって、この場合、PDCCHの無線リソース量は少なくてもよい。逆に、セル端のユーザ装置の場合、無線チャネル状態が悪いので、チャネル符号化率を小さくしなければ所要品質を満たすことができない。したがって、この場合、PDCCHの無線リソース量を多く必要とする。LTE方式の移動通信システムの場合、PDCCHの無線リソースは、制御チャネルエレメント(CCE)と呼ばれる単位で各ユーザ装置に割り当てられ、1つのCCEは9個のリソースエレメントグループ(REG)に対応する。例えば、CCEの具体的な数として、1(2/3)、2(1/3)、4(1/6)及び8(1/12)が挙げられる。カッコ内の数はチャネル符号化率である。
203 上り品質測定部
205 ユーザ多重数制御部
207 スケジューリング部
211 TFR選択部
213 下り信号生成部
215 下り信号送信部
Claims (6)
- 上りリンクの無線リソースが第1の多重数以下のユーザ装置に割り当てられることを示す上りグラント情報を生成するスケジューリング部と、
前記上りグラント情報を含む制御信号をユーザ装置に送信する送信部と、
前記上りグラント情報にしたがってユーザ装置が送信した上り信号を受信する受信部と
を有し、周期的に発生する周期データを送信するユーザ装置が前記第1の多重数より少ない第2の多重数以上存在し、かつ周期的ではないタイミングで発生する非周期データを送信するユーザ装置が存在していた場合、前記スケジューリング部は、周期データを送信する前記第2の多重数のユーザ装置と非周期データを送信するユーザ装置とに上りリンクの無線リソースが割り当てられることを示す上りグラント情報を生成する、移動通信システムにおける基地局。 - 当該基地局のセルにおいて周期データを送信するユーザ装置の数に応じて、前記第2の多重数を制御するユーザ多重数制御部をさらに有する、請求項1記載の基地局。
- 前記スケジューリング部が、
周期データを再送する第1のユーザ装置、
非周期データを再送する第2のユーザ装置、
再送ではない周期データを送信する第3のユーザ装置、及び
再送ではない非周期データを送信する第4のユーザ装置
の優先度の順に、前記第1の多重数に至るまでユーザ装置に無線リソースを割り当てる場合において、前記第1及び第3のユーザ装置が前記第2の多重数より多く存在していたとしても、無線リソースが割り当てられる第1及び第3のユーザ装置の総数は前記第2の多重数に制限される、請求項1に記載の基地局。 - 前記周期データを送信するユーザ装置が前記第2の多重数以上存在し、かつ前記非周期データを送信するユーザ装置が第3の多重数だけ存在していた場合において、前記第2の多重数及び前記第3の多重数のユーザ装置に無線リソースが割り当てられた後、割り当て可能な無線リソースが残っていた場合、前記スケジューリング部は、前記周期データを送信する前記第2の多重数より多いユーザ装置と非周期データを送信する第3の多重数のユーザ装置とに上りリンクの無線リソースが割り当てられることを示す上りグラント情報を生成する、請求項1に記載の基地局。
- 前記周期データが音声データである、請求項1に記載の基地局。
- 上りリンクの無線リソースが第1の多重数以下のユーザ装置に割り当てられることを示す上りグラント情報を生成するステップと、
前記上りグラント情報を含む制御信号をユーザ装置に送信するステップと、
前記上りグラント情報にしたがってユーザ装置が送信した上り信号を受信するステップと
を有し、周期的に発生する周期データを送信するユーザ装置が前記第1の多重数より少ない第2の多重数以上存在し、かつ周期的ではないタイミングで発生する非周期データを送信するユーザ装置が存在していた場合、前記上りグラント情報を生成するステップにおいて、周期データを送信する前記第2の多重数のユーザ装置と非周期データを送信するユーザ装置とに上りリンクの無線リソースが割り当てられることを示す上りグラント情報を生成する、移動通信システムにおけるリソース割当方法。
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JP2017521911A (ja) * | 2014-06-13 | 2017-08-03 | 京セラ株式会社 | ユーザ装置(ue)デバイス間の通信のための、セルラ通信リンクとデバイス間(d2d)通信リンクとの間の選択 |
JP7034999B2 (ja) | 2014-12-11 | 2022-03-14 | クゥアルコム・インコーポレイテッド | Lteおよび超低レイテンシーlte通信において衝突する複数の送信の優先順位決め |
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US9215744B2 (en) * | 2014-05-15 | 2015-12-15 | Telefonaktiebolaget L M Ericsson (Publ) | Discontinuous transmission for a mobile phone network node |
US9936469B2 (en) | 2014-11-03 | 2018-04-03 | Qualcomm Incorporated | User equipment-centric medium access control layer-based signaling between a base station and UE |
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