JP2008047996A - Communication device, and time slot allocating method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To increase the possibility that time slots are connected in TDMA type multislot communication. <P>SOLUTION: A base station device 10 which performs time-division multiplex communication by using one or more of a plurality of time slots for each mobile station device includes a selector 15 which selects a time slot adjacent to a time slot of interest in terms of time, and a time slot allocator which allocates the time slot selected by the selector 15 to a mobile station device of interest using the time slot of interest. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a communication apparatus and a time slot allocation method, and more particularly to a time slot connection technique.

  In communication systems that employ a TDMA (Time Division Multiple Access) system (for example, Patent Documents 1 to 4), each time a connection request is generated, the communication requested by the connection request is sequentially free. Assign time slots.

  Conventionally, one time slot has been set for one communication partner device, but in response to the increase in communications that send and receive large amounts of data such as video communication in recent years, one communication partner device has Multi-slot communication for assigning a plurality of time slots is performed.

In the communication system, as in the case of, for example, Patent Document 3, when a plurality of time slots allocated to one communication partner device are adjacent in time in the multi-slot communication, Some have time slots concatenated. Communication control information is shared between the linked time slots, and fine communication control for each time slot cannot be performed. However, communication data can be efficiently transmitted and received because the communication control information is shared.
JP-A-6-61937 JP 9-512151 A JP 10-510111 A Special table 2003-529284

  However, in the conventional multi-slot communication, a plurality of time slots assigned to one communication partner apparatus are not necessarily adjacent in time. When it is not adjacent, time slot connection cannot be performed, and efficient transmission and reception of communication data cannot be performed.

  Accordingly, one of the objects of the present invention is to provide a communication apparatus and a time slot allocation method that can increase the feasibility of time slot connection in multi-slot communication using the TDMA scheme.

  A communication apparatus according to the present invention for solving the above-described problem is a communication apparatus that performs time division multiplex communication using any one or more of a plurality of time slots for each communication partner apparatus, and includes a time of interest. A selection unit that selects a time slot that is temporally adjacent to the slot, and a time slot allocation unit that allocates the time slot selected by the selection unit to a target communication partner apparatus that uses the target time slot. Features.

  According to this, in multi-slot communication in the TDMA system, one communication partner device can use a plurality of time slots that are temporally adjacent, so that the feasibility of time slot connection can be improved. .

  The communication device further includes a use state determination unit that determines whether or not the time slot selected by the selection unit is used by another communication partner device, wherein the time slot allocation unit includes the use slot When the state determination unit determines that the time slot selected by the selection unit is being used by another communication counterpart device, the other time slot is assigned to the other communication counterpart device, and the selection unit The selected time slot may be assigned to the communication partner apparatus of interest.

  According to this, even if the time slot selected by the selection unit is being used by another communication counterpart device, the other communication counterpart device can be moved to another time slot, so that the realization of the time slot connection is realized. The possibility is further increased.

  Further, in this communication apparatus, when the time slot allocating unit determines that the time slot selected by the selecting unit is being used by another communication partner apparatus by the use state determining unit, One of one or more time slots used by the communication partner device of interest may be assigned to the other communication partner device.

  According to this, another communication partner apparatus can be moved to another time slot by exchanging time slots.

  In each of the communication apparatuses, the selection unit may use the time slot of interest when a time slot other than at least one time slot that is temporally adjacent to the time slot of interest is also used by the target communication counterpart apparatus. It is also possible to select time slots that are adjacent in time.

  According to this, when it is necessary during communication, the feasibility of time slot connection can be increased.

  In addition, the communication apparatus includes a plurality of radio units, each of the radio units performs a plurality of communications multiplexed by time division multiplexing, and the selection unit includes a time belonging to the radio unit to which the target time slot belongs. A time slot that is temporally adjacent to the time slot of interest may be selected from the slots.

  According to this, even if the communication device has a plurality of radio units, one communication partner device can use a plurality of time slots adjacent in time within the same radio unit. The feasibility of time slot connection can be increased.

  Further, in each of the communication devices, in each time slot, communication is performed using one frequency selected from the plurality of frequencies for each time slot, and the communication device is used in the time slot of interest. A frequency determination unit that determines whether or not a frequency to be used is different from a frequency used in the time slot selected by the selection unit, and the time slot of interest according to a determination result of the frequency determination unit Or it is good also as including further the frequency change part which changes a use frequency about at least one of the time slots selected by the said selection part.

  In order to perform time slot concatenation, the frequency of the time slots to be concatenated must be the same. According to the communication apparatus, since the frequency of the time slots to be connected can be made uniform, the feasibility of time slot connection is further increased.

  The time slot allocation method according to the present invention is a time slot allocation method for performing time division multiplex communication by using any one or more of a plurality of time slots for each communication partner device. A selection step of selecting a time slot that is temporally adjacent to the time slot; and a time slot allocation step of allocating the time slot selected in the selection step to a target communication counterpart device that uses the target time slot. It is characterized by.

  Embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a diagram showing a system configuration of a mobile communication system 1 according to the present embodiment. As shown in FIG. 1, the mobile communication system 1 includes a base station device 10 and a plurality of mobile station devices 20.

  Each of the base station device 10 and the mobile station device 20 is a computer including a CPU and a memory. The CPU is a processing unit for executing a program stored in the memory, performs processing for controlling each unit of each device, and implements each functional unit described later. The memory stores programs and data for carrying out the present embodiment. It also operates as a work memory for the CPU.

  The base station apparatus 10 performs multiplexed communication with a plurality of mobile station apparatuses 20 by the TDMA method. That is, among the plurality of time slot sets (a set of uplink time slots and downlink time slots; hereinafter, when simply referred to as a time slot without adding uplink or downlink, it indicates a time slot set) Communication using one or more. In each time slot, communication is performed using one frequency selected for each time slot from among a plurality of frequencies. Note that, here, it is assumed that one frequency is selected for each time slot, but the frequency may be selected separately for the uplink time slot and the downlink time slot.

  In addition, the base station apparatus 10 transmits and receives control signals to and from the plurality of mobile station apparatuses 20 separately from the above communication. A part of the time slot (referred to as a control signal time slot) is used for transmission and reception of control signals.

  FIG. 2 is a diagram showing a specific example of time slot allocation to each mobile station apparatus 20. As shown in the figure, in this embodiment, four time slots belong to each of four radio units 11 described later. That is, 16 time slots can be assigned, and one or more of these can be assigned to each mobile station apparatus 20. The base station device 10 and the mobile station device 20 communicate using the time slot thus assigned.

  In the present embodiment, four frequencies can be used. Since the radio units 11 cannot use the same frequency at the same time, as shown in FIG. 2, different frequencies are used in the four time slots transmitted simultaneously.

  Hereinafter, details of the functions of the base station apparatus 10 will be described.

  FIG. 3 is a diagram illustrating functional blocks of the base station device 10. As shown in the figure, the base station device 10 functionally includes radio units 11-1 to 4, frequency control units 12-1 to 4, a communication processing unit 13, an allocation state storage unit 14, a selection unit 15, and a time slot. An allocation unit 16 and a frequency allocation unit 17 are included. The time slot allocation unit 16 includes a use state determination unit 161, and the frequency allocation unit 17 includes a frequency determination unit 171 therein.

  Each radio unit 11 includes an antenna, and transmits and receives time slots to and from the mobile station apparatus 20. Specifically, each wireless unit 11 modulates downlink time slots sequentially input from the communication processing unit 13 and wirelessly transmits them in the input order. Also, each radio unit 11 demodulates radio signals that sequentially arrive at the antenna, acquires an uplink time slot, and sequentially outputs it to the communication processing unit 13.

  The allocation state storage unit 14 stores an allocation table for storing time slot and frequency allocation for each mobile station apparatus 20. Details of this allocation table will be described later.

  The communication processing unit 13 acquires the time slot allocated to each mobile station device 20 by referring to the allocation table. Communication data to be transmitted to each mobile station device 20 is acquired, included in the downlink time slot assigned to each mobile station device 20, and sequentially output to each radio unit 11. In addition, the communication processing unit 13 includes predetermined communication control data such as modulation scheme information indicating a modulation scheme in addition to the communication data in principle for each downlink time slot.

  Further, the communication processing unit 13 classifies the uplink time slots sequentially input from the radio units 11 for each mobile station device 20 based on the acquired time slot assignment. Based on this classification, communication data transmitted from each mobile station apparatus 20 from each uplink time slot is acquired. Note that the mobile station apparatus 20 also includes predetermined communication control data such as modulation scheme information indicating a modulation scheme in addition to communication data for each uplink time slot in principle, as in the base station apparatus 10. When acquiring communication data from an uplink time slot, the communication control data included in the uplink time slot is also acquired.

  Furthermore, the communication processing unit 13 acquires a control signal to be transmitted to each mobile station device 20, includes the control signal in the time slot for the control signal, and sequentially outputs the control signal to each radio unit 11. Further, the communication processing unit 13 extracts a control signal time slot from the uplink time slots sequentially input from the radio units 11, and acquires the control signal transmitted from each mobile station apparatus 20 therefrom.

  Each frequency control unit 12 controls the frequency when the corresponding radio unit 11 wirelessly transmits the downlink time slot based on the allocation table. Further, based on the allocation table, the corresponding radio unit 11 controls the frequency to be received in order to receive the uplink time slot. Specifically, each frequency control unit 12 has an oscillator of a signal having a predetermined frequency, and a signal oscillated by this oscillator is multiplied by a radio signal in the corresponding radio unit 11. Each frequency control unit 12 controls the frequency of the signal oscillated by the oscillator based on the allocation table so that the corresponding radio unit 11 receives the frequency and the uplink time slot when the downlink time slot is wirelessly transmitted. Control the frequency to be received.

  The control signal transmitted by the mobile station apparatus 20 may include a time slot allocation request (a call request at the start of communication. A request to increase the allocated time slot during communication). When the communication processing unit 13 acquires the time slot allocation request transmitted by the mobile station device 20, the time slot allocation unit 16 allocates a time slot to the mobile station device 20, stores the result in the allocation table, and moves It is included in the control signal and transmitted to the station apparatus 20. Specifically, referring to the allocation table, time slots that have not been allocated to other mobile station apparatuses 20 are allocated to the mobile station apparatus 20.

  Further, when the communication processing unit 13 acquires the time slot allocation request transmitted by the mobile station device 20, the frequency allocation unit 17 sets the frequency in the time slot newly allocated to the mobile station device 20 by the time slot allocation unit 16. And the result is stored in the allocation table and transmitted to the mobile station apparatus 20 as a control signal. Specifically, among the above four frequencies, a frequency that has not yet been assigned to any one or more time slots transmitted / received simultaneously with the time slot assigned to the mobile station apparatus 20 by the time slot assigning unit 16. assign.

  When the mobile station device 20 receives the control signals, there is a communication interference factor that interferes with communication performed by the mobile station device 20, such as a transmission radio wave of another communication device, in the assigned time slot. Processing (carrier sense) for confirming that there is no data is performed. Specifically, in the assigned time slot, a search is made as to whether or not a radio wave having a frequency assigned to the time slot and a frequency in the vicinity thereof exist. The mobile station device 20 starts communication in the assigned time slot when a radio wave having a predetermined power or more is not detected as a result of this search. On the other hand, when a radio wave with a predetermined power or higher is detected, it is determined that there is a communication interference factor, and the base station apparatus 10 is requested to reassign. Receiving this request, the base station apparatus 10 executes the assignment process again.

  Here, the connection of time slots will be described. As described above, the communication processing unit 13 includes the predetermined communication control data in addition to the communication data in principle for each downlink time slot. However, when a plurality of time slots assigned to one mobile station apparatus 20 are temporally adjacent and have the same frequency, the communication processing unit 13 performs the above predetermined time slot for each adjacent time slot. Include communication control data. This process is called concatenating time slots.

  Note that the communication processing unit 13 measures a frequency error and a phase error in a time slot over a predetermined time, and calculates an effectiveness evaluation value for evaluating the effectiveness of time slot connection based on the measurement result. Also good. When the effectiveness evaluation value is equal to or greater than a predetermined value, it is preferable to connect the time slots.

  Similarly, the mobile station apparatus 20 performs a process of connecting time slots. In such a case, the communication processing unit 13 acquires one communication control data from a plurality of uplink time slots.

  The time slot concatenation process is performed only when a plurality of time slots assigned to one mobile station apparatus 20 are temporally adjacent to each other, belong to the same radio unit 11, and have the same use frequency. Therefore, the base station apparatus 10 has a plurality of time slots allocated to one mobile station apparatus 20 that are temporally adjacent to each other and belong to the same radio unit 11 so that time slots can be connected. Time slots and frequencies are assigned so that the frequencies are the same. Hereinafter, the process for this will be described in detail.

  The selection unit 15 pays attention to a specific time slot. Hereinafter, the time slot thus noticed will be referred to as the attention time slot, and the mobile station apparatus 20 using the attention time slot will be referred to as the attention mobile station apparatus 20. The selection unit 15 determines whether or not the target mobile station device 20 uses a time slot other than at least one time slot that is temporally adjacent to the target time slot and belongs to the same radio unit 11 . If it is determined that the time slot is in use, a time slot that is temporally adjacent to the time slot of interest is selected from the time slots belonging to the radio unit 11 to which the time slot of interest belongs. Hereinafter, the time slot thus selected is referred to as a selected time slot.

  In the example of FIG. 2, the selection unit 15 pays attention to, for example, TS2 of the radio unit 11-1. In this case, the target mobile station device 20 is the mobile station device 20-1. Since the mobile station apparatus 20-1 uses TS2 of the radio unit 11-1 and TS4 of the radio unit 11-1 which is a time slot other than TS1 and TS3 of the radio unit 11-1, the selection unit 15 selects one of TS1 and TS3 of the wireless unit 11-1 adjacent to TS2 of the wireless unit 11-1. In the following description, it is assumed that TS1 of the radio unit 11-1 is selected.

  The selection unit 15 instructs the time slot allocation unit 16 to allocate the selected time slot selected as described above to the mobile station device 20 of interest. Further, the frequency allocation unit 17 is instructed to align the frequency used in the selected time slot with the frequency used in the target time slot.

  The time slot allocating unit 16 allocates the selected time slot to the target mobile station device 20 in accordance with the instruction from the selecting unit 15. Specifically, the use state determination unit 161 determines whether or not the selected time slot is assigned to another mobile station device 20. Then, when the use state determination unit 161 determines that the selected time slot is allocated to another mobile station device 20, the time slot allocation unit 16 allocates another time slot to the other mobile station device 20. At the same time, the selected time slot is assigned to the mobile station device 20 of interest. In a more specific example, the time slot allocation unit 16 allocates one of the one or more time slots that have been used by the mobile station device 20 of interest to the other mobile station device 20. That is, the time slot assignment is exchanged between the mobile station device 20 of interest and the other mobile station device 20.

  In the example of FIG. 2, the time slot allocation unit 16 allocates TS1 of the radio unit 11-1 to the mobile station device 20-1, and among the time slots allocated to the mobile station device 20-1 so far. One TS4 is selected and assigned to the mobile station apparatus 20-4 assigned to TS1 of the radio unit 11-1.

  Note that when time slots are allocated by the time slot allocation unit 16 as described above, it is preferable that the frequency be maintained. For example, in the example of FIG. 2, after changing the assignment as described above, the frequency used in TS1 of the radio unit 11-1 is maintained at f1, and the frequency of TS4 of the radio unit 11-1 is maintained at f4. .

  In exchanging time slot assignments, the time slot assigning unit 16 transmits a control signal for notifying a change in time slot assignment to each of the target mobile station apparatus 20 and the other mobile station apparatus 20 described above. It is preferable to do so. In this case, each mobile station apparatus 20 that has received the control signal performs the carrier sense. Specifically, the noted mobile station device 20 performs carrier sense in the selected time slot, and the other mobile station device 20 performs carrier sense in the other time slot. Each mobile station device 20 transmits a control signal for notifying the base station device 10 of the carrier sense result. The base station apparatus 10 performs time slot allocation exchange only when the carrier sense result indicates that a radio wave with a predetermined power or higher has not been detected.

  The frequency allocation unit 17 performs processing for aligning the frequency used in the selected time slot and the frequency used in the time slot of interest in accordance with an instruction from the selection unit 15. Specifically, the frequency determination unit 171 determines whether or not the frequency used in the time slot of interest is different from the frequency used in the selected time slot. Then, the frequency allocation unit 17 changes the use frequency for at least one of the time slot of interest or the selected time slot according to the determination result of the frequency determination unit 171. In a more specific example, the frequency allocation unit 17 acquires a time slot that is another time slot that is transmitted and received at the same timing as the selected time slot and uses the same frequency as the time slot of interest. Exchange frequency assignments between time slots and selected time slots.

  In the example of FIG. 2, the frequency allocation unit 17 changes the frequency f1 allocated to TS1 of the radio unit 11-1 to the frequency f2 allocated to TS1 of the radio unit 11-4. -1 and TS1 of the radio unit 11-4 exchange frequency assignments.

  In exchanging the frequency allocation, the frequency allocation unit 17 changes the frequency allocation for each of the mobile station apparatus 20 to which the selected time slot is allocated and the mobile station apparatus 20 to which the acquired time slot is allocated. It is preferable to transmit a control signal for notifying the user. In this case, each mobile station apparatus 20 that has received the control signal performs the carrier sense for the changed frequency. Each mobile station device 20 transmits a control signal for notifying the base station device 10 of the carrier sense result. The base station apparatus 10 performs the frequency allocation exchange only when the carrier sense result indicates that a radio wave with a predetermined power or higher has not been detected.

  The selection unit 15 changes the time slot of interest while a plurality of time slots assigned to one mobile station device 20 are temporally adjacent to each other, belong to the same radio unit 11, and have the same use frequency. The time slot selection is repeated until it becomes. As a result, as an example, a time slot and a frequency are assigned to each mobile station apparatus 20 as shown in FIG. That is, for each mobile station device 20, a state is created in which a plurality of assigned time slots are temporally adjacent to each other, belong to the same radio unit 11, and have the same use frequency. In this manner, the time slots can be connected by the above processing. FIG. 5 shows a state where time slots are actually connected.

  The processing described above will be described in more detail with reference to the processing flow of the base station apparatus 10.

  6 to 11 are diagrams illustrating a processing flow of the base station apparatus 10.

  As shown in FIG. 6, the base station apparatus 10 performs normal time slot / frequency allocation processing (S1). For example, periodically, frequency reassignment processing (S2) and time slot reassignment processing (S3) are performed. After that, time slot connection processing (S4) is performed. Here, the base station apparatus 10 periodically performs the processing of S2 to S4. For example, the timing at which a time slot is allocated to the mobile station apparatus 20 and the processing resources of the base station apparatus 10 are a predetermined amount or more. It may be performed when the space becomes empty.

  FIG. 7 shows a detailed flow of the frequency reallocation process (S2). First, the base station apparatus 10 pays attention to the time slot TSj (referred to as S0) of the radio unit 11-i (referred to as U0) (S201), and the frequency used in this noticed time slot is defined as f (U0S0). (S202). The base station apparatus 10 further selects a time slot TSk (referred to as S1) from one or two time slots adjacent to the time slot TSj among the four time slots of the radio unit 11-i (refer to S1). S203), the frequency used in this selected time slot is set to f (U0S1) (S204). When the processing up to S204 is completed, the base station apparatus 10 performs frequency exchange processing (S205).

  FIG. 8 shows a detailed flow of the frequency exchange process (S205). First, the base station apparatus 10 sets the time slot TSk of the radio unit 11-1 (l ≠ i, U1) as a comparison target (S221), and sets the use frequency to f (U1S1) (S222). Then, f (U0S0) and f (U1S1) are compared (S223), and if they are equal, the used frequency of the time slot TSk is exchanged between the radio unit 11-i and the radio unit 11-1 (S226). ). The base station apparatus 10 repeats the process from S221 until the process of S226 is completed or all the l are processed (S224, S225).

  In the frequency exchange process, when the frequency exchange is successful (the process of S226 is performed) (positive determination of S206), the base station apparatus 10 advances the process to S211. On the other hand, if it fails (the process of S226 is not performed) (negative determination of S206), the base station apparatus 10 performs a free frequency confirmation process (S207).

  FIG. 9 shows a detailed flow of the free frequency confirmation process (S207). First, the base station apparatus 10 acquires a frequency (free frequency) that is not used in the time slot TSk (S231). If f (U0S0) is included in the free frequency, the frequency used in the time slot TSk of the radio unit 11-i is changed to f (U0S0) (S232, S233).

  If the frequency change succeeds in the free frequency confirmation process (the process of S233 is performed) (positive determination of S208), the base station apparatus 10 advances the process to 211. On the other hand, if it fails (the process of S233 is not performed) (No determination of S208), the base station apparatus 10 repeats the processes from S203 until all the k are processed (S209, S210). That is, the base station apparatus 10 confirms whether the frequency can be set to f (U0S0) for both of two adjacent time slots.

  When the use frequency of the time slot TSk of the radio unit 11-i is f (U0S0) or when processing has been completed for all k, the base station apparatus 10 changes the time slot of interest and repeats the processing from S201 ( S211, S212). The base station apparatus 10 repeats the above processing until all the time slots have been processed.

  FIG. 10 shows a detailed flow of the time slot reassignment process (S3). First, the base station apparatus 10 pays attention to the time slot TSj (referred to as S0) of the radio unit 11-i (referred to as U0) (S301), and the mobile station apparatus 20 that is using this focused time slot is referred to as P ( U0S0) (S302). The base station apparatus 10 further selects a time slot TSk (referred to as S1) from one or two time slots adjacent to the time slot TSj among the four time slots of the radio unit 11-i (refer to S1). In S303, the mobile station apparatus 20 that is using the selected time slot is set to P (U0S1) (S304). When the processing up to S304 is completed, the base station apparatus 10 performs mobile station apparatus replacement processing (S305).

  FIG. 11 shows a detailed flow of the mobile station apparatus exchange process (S305). First, the base station apparatus 10 uses the time slot TSn (referred to as S2) of the radio unit 11-m (referred to as U2) as a comparison target (S321), and selects the mobile station apparatus 20 that is using the time slot as P ( U2S2) (S322). Note that the base station apparatus 10 determines whether the combination of m and n (m, n) is any one of (i, j), (i, j−1), and (i, j + 1) in the process of S321. Do not select.

  Next, the base station apparatus 10 compares P (U0S0) and P (U2S2) (S323), and if they are equal, the time slot TSj of the radio unit 11-i and the time slot TSn of the radio unit 11-m The mobile station apparatus 20 to be allocated is exchanged between them (S326). The base station device 10 repeats the processing from S321 until the processing of S326 is completed or until all the combinations of m and n are processed (S324, S325).

  In the mobile station apparatus exchange process, when the exchange of the mobile station apparatus 20 is successful (the process of S326 is performed) (Yes determination in S306), the base station apparatus 10 advances the process to S309. On the other hand, if it fails (the process of S326 is not performed) (No determination in S306), the base station apparatus 10 repeats the processes from S303 until all the k are processed (S307, S308). That is, the base station apparatus 10 confirms whether the mobile station apparatus 20 can be exchanged for both of two adjacent time slots.

  When the mobile station apparatus 20 assigned to the time slot TSk of the radio unit 11-i becomes P (U0S0) or when all the k have been processed, the base station apparatus 10 changes the time slot of interest, and from S301 This process is repeated (S309, S310). The base station apparatus 10 repeats the above processing until all the time slots have been processed.

  When the frequency reassignment process (S2) and the time slot reassignment process (S3) are completed as described above, the base station apparatus 10 performs the time slot concatenation process (S4).

  As described above, according to the base station apparatus 10, in multi-slot communication in the TDMA system, one mobile station apparatus 20 can use a plurality of time slots that are temporally adjacent. The feasibility of time slot connection can be increased.

  Further, even if the time slot selected by the selection unit 15 is in use by another mobile station apparatus 20, the other mobile station apparatus 20 can be moved to another time slot, so that the time slot connection is realized. The possibility is further increased.

  Further, the other mobile station apparatus 20 can be moved to another time slot by exchanging the time slots.

  Further, when necessary during communication with the mobile station device 20, the possibility of time slot connection can be increased.

  The base station apparatus 10 includes a plurality of radio units 11. However, within the same radio unit 11, one mobile station apparatus 20 may use a plurality of time slots that are temporally adjacent. As a result, the feasibility of time slot connection can be increased.

  Further, in order to perform time slot concatenation, the frequency of the time slot to be concatenated needs to be the same. However, according to the base station apparatus 10, since the frequency of the time slot to be concatenated can be aligned, Is more feasible.

  In addition, when switching the frequency between time slots, the EVM (modulation accuracy) is likely to deteriorate. In this regard, according to the base station apparatus 10, since the frequencies between the adjacent time slots are equal, the opportunity to switch the frequency between the time slots is reduced, and as a result, the EVM can be prevented from deteriorating.

  Further, the base station apparatus 10 may perform multiplexed communication by space division multiplexing with a plurality of mobile station apparatuses 20. In this case, the base station apparatus 10 calculates a weighting parameter using the radio signal received from each mobile station apparatus 20. In this calculation, it is known that the weighting parameter can be calculated more accurately as the continuous reception time of the radio signal is longer. However, if the time slot is connected, the continuous reception time of the radio signal becomes longer. The weighting parameters can be calculated well. In this regard, according to the base station apparatus 10, since the possibility of time slot connection is increased, the possibility that the weighting parameter can be calculated with high accuracy is also increased.

It is a figure which shows the system configuration | structure of the mobile communication system concerning embodiment of this invention. It is a figure which shows the specific example of allocation of the time slot with respect to each mobile station apparatus concerning embodiment of this invention. It is a figure which shows the functional block of the base station apparatus concerning embodiment of this invention. In the state shown in FIG. 2, it is a figure which shows the specific example of allocation of the time slot with respect to each mobile station apparatus after performing the process concerning embodiment of this invention. It is a figure which shows the state with which each time slot shown in FIG. 4 was connected. It is a figure which shows the processing flow of the base station apparatus concerning embodiment of this invention. It is a figure which shows the detailed flow of the frequency reallocation process concerning embodiment of this invention. It is a figure which shows the detailed flow of the frequency exchange process concerning embodiment of this invention. It is a figure which shows the detailed flow of the empty frequency confirmation process concerning embodiment of this invention. It is a figure which shows the detailed flow of the time slot reallocation process concerning embodiment of this invention. It is a figure which shows the detailed flow of the mobile station apparatus exchange process concerning embodiment of this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Mobile communication system, 10 Base station apparatus, 11 Radio part, 12 Frequency control part, 13 Communication processing part, 14 Allocation state memory | storage part, 15 Selection part, 16 Time slot allocation part, 17 Frequency allocation part, 20 Mobile station apparatus 161 Usage state determination unit, 171 Frequency determination unit.

Claims (7)

A communication device that performs time division multiplex communication using any one or more of the plurality of time slots for each communication partner device,
A selector for selecting a time slot that is temporally adjacent to the time slot of interest;
A time slot allocation unit that allocates the time slot selected by the selection unit to a target communication partner apparatus that uses the target time slot;
A communication device comprising: The communication device according to claim 1,
A use state determination unit that determines whether or not the time slot selected by the selection unit is used by another communication partner device;
Further including
The time slot allocating unit, when the use state determining unit determines that the time slot selected by the selecting unit is being used by another communication partner device, assigns the other time slot to the other communication partner. And assigning the time slot selected by the selection unit to the target communication partner device.
A communication device. The communication device according to claim 2,
The time slot allocating unit is used by the communication partner device of interest until then when the use state determining unit determines that the time slot selected by the selecting unit is being used by another communication partner device. Assigning one of the one or more time slots to the other communication partner device,
A communication device. The communication device according to any one of claims 1 to 3,
The selection unit uses a time slot that is temporally adjacent to the target time slot when the target communication counterpart device uses a time slot other than at least one time slot that is temporally adjacent to the target time slot. Select
A communication device. The communication device according to any one of claims 1 to 4,
The communication apparatus has a plurality of radio units, and each radio unit performs a plurality of communications multiplexed by time division multiplexing,
The selection unit selects a time slot that is temporally adjacent to the time slot of interest from among the time slots that belong to the radio unit to which the time slot of interest belongs.
A communication device. The communication device according to any one of claims 1 to 5,
In each time slot, communication is performed using one frequency selected for each time slot from among a plurality of frequencies.
The communication device
A frequency determination unit that determines whether or not the frequency used in the time slot of interest is different from the frequency used in the time slot selected by the selection unit;
According to the determination result of the frequency determination unit, a frequency changing unit that changes a use frequency for at least one of the time slot of interest or the time slot selected by the selection unit;
Further including
A communication device. A time slot allocation method for performing time division multiplex communication using any one or more of a plurality of time slots for each communication partner device,
A selection step of selecting a time slot that is temporally adjacent to the time slot of interest;
A time slot assigning step of assigning the time slot selected in the selecting step to a target communication partner apparatus using the target time slot;
A time slot allocation method comprising:

Images