JP2001358651A - Mobile communication system, base station unit and transmission power control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce effects of interference between uplink and downlink in a TDD mobile communication system, where a base station assigns an information slot for transmitting user information arbitrarily to an incoming or an outgoing line. SOLUTION: A base station 300 comprises a means (slot assignment conditions monitoring section 305) for collecting the assignment conditions of each information slot at a peripheral base station, and a means (target-receiving power setting section 304) for controlling the transmission power of a packet to be transmitted. When a outgoing packet is transmitted to a slot assigned to an in coming line at several peripheral base stations, target-receiving power of that packet is set higher, as compared with a case where a outgoing packet is transmitted to a normal slot assigned to a outgoing line at all peripheral base station.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cellular mobile communication system using a TDD (Time Division Duplex) system for performing communication by time division using the same frequency band in uplink and downlink, a base station apparatus, and transmission power. It relates to a control method.

[0002]

2. Description of the Related Art An example of a transmission power control system in a cellular mobile communication system using the TDD system is disclosed in Japanese Patent Laid-Open Publication No. Hei 6-30.
No. 3181, “Power control apparatus and method for wireless telephone”
(Known example 1), JP-A-7-226710, "CDM
A / TDD wireless communication system "(known example 2) and the like. The transmission power control described in these is generally called an open-loop transmission power control method. Such transmission power control is not essential for system operation in a cellular mobile communication system based on a frequency division multiple access (FDMA) system or a time division multiple access (TDMA) system. Mandatory in a based system.

[0003] Incidentally, the amount of traffic transmitted in a mobile communication system is not always the same between the upper and lower lines, and especially in data communication, the unevenness of the amount of traffic between the upper and lower lines becomes remarkable. As a method of efficiently accommodating such asymmetric traffic in the uplink and downlink, T
In a CDMA mobile communication system using the DD system, a method of allocating an information slot for transmitting user information to one of the lines according to the traffic ratio of the upper and lower lines is described in D.J.
eong, and W. Jeon, "CDMA / TDD system for wireless m
ultimedia services with traffic unbalance between
uplink and downlink ", IEEE J. Select. Areas Comm
un., vol. 17, no. 5, pp. 939-946, May 1999 (known example 3). W. Wong, and W. Sund
berg, "Shared time division duplexing: an approac
h to low-delay high-quality wireless digital speec
h communications ", IEEE Trans. Veh. Technol., vo
l. 43, no. 4, pp. 934-944, Nov. 1994 (Publication 4) discloses that the position of the TDD boundary in a TDD frame is changed according to the traffic ratio between the uplink and the downlink to reduce the efficiency of asymmetric traffic. A well-accommodating method is described.

[0004]

However, in the communication system described in the above-mentioned known example 3 or 4 in which the above-mentioned open-loop transmission power control is performed, the service area is divided into several communication areas (cells). When applied to a cellular mobile communication system in which communication is performed between a base station installed near the center and mobile stations located in each cell, geographical unevenness in the traffic ratio of uplink and downlink within the service area. Occurs, there are cases where slots used for different lines between cells adjacent to each other occur, for example, slots allocated to the uplink in the base station of the adjacent cell are allocated to the downlink in the base station. is there. In a mobile communication system that uses the same frequency band in all cells of a service area, such as a cellular CDMA system, packets transmitted in slots used for different lines between adjacent cells are adjacent in the downlink. The problem is that interference is caused by an uplink packet transmitted from a mobile station existing in a cell, and interference is caused by a downlink packet transmitted from an adjacent base station on the uplink, and these interferences cause deterioration in transmission characteristics. Exists.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an open-loop transmission power control is performed, and an information slot in which a base station transmits user information is arbitrarily increased or decreased. When a communication method that can be assigned to the downlink is applied to a cellular mobile communication system using the same frequency band in all cells, transmission characteristics of the downlink in slots used for different lines between cells adjacent to each other. It is an object of the present invention to provide an efficient cellular mobile communication system, a base station apparatus, and a transmission power control method that can suppress degradation of the mobile communication system.

[0006]

In order to achieve the above-mentioned object, a mobile communication system according to the present invention is a cellular mobile communication system composed of a plurality of base stations and a plurality of mobile stations and performing packet communication by a TDD system. In a mobile communication system in which a base station is capable of arbitrarily allocating an information slot for transmitting user information to an uplink or a downlink, in the mobile communication system, the base station is capable of allocating information slots in its neighboring base stations. And means for controlling the transmission power of a packet to be transmitted, wherein when the base station transmits a downlink packet to a slot assigned to an uplink in one or more peripheral base stations, Transmission power of the packet in comparison with the case where transmission is performed in the slot allocated to the downlink in the peripheral base station of It is obtained so as to rise.

[0007] Further, a base station apparatus of the present invention is a cellular mobile communication system configured by a plurality of base stations and a plurality of mobile stations and performing packet communication according to a TDD system.
A base station device in a mobile communication system in which a base station can arbitrarily assign an information slot for transmitting user information to an uplink or a downlink,
Means for collecting the allocation status of each information slot in the peripheral base station, and means for controlling the transmission power of the packet to be transmitted, wherein the base station is allocated to the uplink by one or more peripheral base stations When transmitting a downlink packet to a slot, the transmission power of the downlink packet is increased as compared with a case where a downlink packet is transmitted to a slot assigned to a downlink in all peripheral base stations. is there.

Further, a transmission power control method according to the present invention is a cellular mobile communication system comprising a plurality of base stations and a plurality of mobile stations and performing packet communication according to the TDD scheme, wherein the base station transmits user information. A transmission power control method in a base station in a mobile communication system in which a slot can be arbitrarily allocated to an uplink or a downlink, comprising: collecting an allocation status of each information slot in a peripheral base station; When transmitting a downlink packet to a slot assigned to the uplink in a peripheral base station, compared to transmitting to a slot assigned to a downlink in all peripheral base stations,
The transmission power of the packet is increased.

Further, the base station includes means for storing the number of transmissions of the packet to be transmitted, so that only the retransmitted packet is a downlink packet whose transmission power is to be increased. . Furthermore, as the number of retransmissions increases, the amount of increase in transmission power increases. Furthermore, the base station comprises:
Equipped with a means for estimating the location of the destination mobile station of the packet, the downlink packet to increase the transmission power,
Only packets to be transmitted to mobile stations located at a position whose distance from the base station is larger than a predetermined value are set. Furthermore, the greater the distance between the base station and the destination mobile station of the packet, the greater the increase in the transmission power. Furthermore, in a slot in which a base station transmits a packet, the larger the number of peripheral base stations that have assigned the slot to the uplink, the greater the increase in the transmission power of the transmission packet.

[0010]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is an overall conceptual diagram of a mobile communication system embodying the present invention. This system includes mobile stations 100, 110, 120,..., A radio channel 200, and base stations 300, 310,. Although not shown in FIG. 1, the base stations 300, 310,
... always transmit pilot signals, and have cells 400, 410,... In which the received power of the pilot signal transmitted by itself is larger than the received power of the pilot signal transmitted by another base station. Mobile stations 100 and 11
.. Belong to a cell of one of the base stations, and connect to the base station to transmit and receive packets via a TDD wireless channel 200 having a frame structure (TDD frame) shown in FIG.

FIG. 2 is a diagram showing the structure of a TDD frame of the radio channel 200. As shown in this figure, the radio channel 200 is provided with an uplink control slot 210, a downlink control slot 220, and an information slot 230 shared by uplink and downlink, which are time-division multiplexed. A TDD boundary 240 in which the station changes its position according to the traffic ratio between the uplink and the downlink.
Downlink slot 231 and uplink slot 23
Divided into two.

In such a mobile communication system, when there is a geographical non-uniformity in the traffic ratio between the uplink and downlink in the service area, the TDD frame of each base station is transmitted.
A mismatch occurs at the position of the DD boundary 240. This will be described with reference to FIG. For example, in the cell 400 in FIG. 1, the uplink and downlink traffic are almost the same amount, while in the adjacent cell 410, the downlink traffic volume is larger than the uplink traffic volume, as shown in FIG. The positions of the TDD boundaries 240 of the TDD frames at the stations 300 and 310 are different. Therefore, in the slot (the hatched slot in FIG. 3) sandwiched between both TDD boundaries 240, the above-described interference between the upper and lower lines occurs.

FIG. 4 is a block diagram showing a configuration of the base station apparatus according to the first embodiment of the present invention. Each of the base stations 300, 310, 320,... Has the same configuration. Here, the case where a packet addressed to the mobile station 100 is transmitted will be mainly described using the base station 300 as an example. In FIG. 4, when the base station 300 communicates with the mobile station 100, the downlink packet is a downlink information slot 231,
The upstream packet performs packet communication via the upstream information slot 232. The position of the TDD boundary 240 is
TDD boundary control unit 303 on the basis of information on traffic volume of uplink and downlink obtained from transmission / reception buffer 302 and transmission / reception buffer 302.
The position information is notified to the transmission / reception unit 301 and the target reception power setting unit 304. Also, the mobile station 10 connected to its own station via the downlink control slot 220
0, 110, 120,... Each packet is received by the receiving station (mobile station) by open-loop transmission power control.
The transmission power is controlled such that the reception power at the time becomes the target reception power value set by the target reception power setting unit 304.

A packet addressed to the mobile station 100 received by the base station 300 from an upper switching center or the like is temporarily stored in the transmission / reception buffer 3.
02 is stored. The packets stored in the transmission / reception buffer 302 are sequentially output to the transmission / reception unit 301. The transmission / reception section 301 transmits the packet to an arbitrary downlink information slot 231 at the transmission power determined by the transmission power control section 306. The transmission power control unit 306 determines the amount of attenuation on the propagation path received from the mobile station 100 via the uplink control slot 210 and the like and the target reception power setting unit 304
Then, the transmission power of the transmission packet is calculated based on the target reception power value notified from, and the transmission / reception unit 301 is notified.

The target reception power value of the transmission packet is determined by a target reception power setting section 304. The target reception power setting unit 304 refers to the transmission slot position of the transmission packet notified from the transmission / reception unit 301 and the allocation status information of each slot in the surrounding base station obtained from the slot allocation status monitoring unit 305, and determines the Calculate the target received power. A reference value P _{tgt-s of a} target reception power set in advance is set in the target reception power setting section 304, and slots in which packets are to be transmitted are allocated to downlinks in all peripheral base stations. In this case, the target reception power of the transmission packet is set to the reference value _Ptgt-s . Thereby, as described above, in the transmission power control unit 306, the transmission power is determined such that the packet is received at the destination mobile station at the reference value _Ptgt-s of the target reception power, and the transmission / reception unit Sent from 301.

On the other hand, when the slot in which a packet is to be transmitted is allocated to the uplink in the peripheral base station, the target reception power of the transmission packet is set to, for example, Δ
It is set to P _tgt-s + ΔP raised by P. In this case, the transmission power is determined by the transmission power control unit 306 such that the packet is received by the destination mobile station at the reception power of _Ptgt-s + ΔP.
Sent from 1. Therefore, compared to the case where the signal is transmitted to the slot allocated to the downlink in all the peripheral base stations, the signal is transmitted with higher transmission power.

The slot allocation status monitoring unit 305 includes:
It stores information on the status of assignment of each slot to the uplink and downlink in the peripheral base station for each TDD frame. The allocation status information may be exchanged between the base stations through a wired line, for example, or information on the TDD boundary position of a subordinate base station may be stored in a higher-level switching center or the like,
Each base station may periodically upload and download.

As described above, according to the present invention, when a slot for transmitting a packet is allocated to the uplink in one or more peripheral base stations, the transmission power of the packet is increased and transmitted. I have. Therefore, it is possible to reduce the influence of interference received from an uplink packet transmitted from a mobile station in a neighboring cell, and to improve downlink throughput. In addition, since the transmission power of the downlink packet is increased, conversely, in a peripheral base station that allocates the slot to the uplink, interference with the received signal increases. In this technology, the level of interference from other cells is reduced by beam tilting of a base station antenna, and the effect of an increase in transmission power of a downlink packet can be suppressed by beam tilting. Therefore, according to the present invention, the efficiency of the entire system can be improved.

Next, another embodiment of the present invention will be described. In the present embodiment, the target reception power setting unit 30
The calculation of the target received power in step 4 is controlled by the number of times of transmission of the packet to be transmitted, in addition to the above-described allocation status of the slot for transmitting the packet in the peripheral base station. FIG. 5 is a diagram illustrating a configuration example of a base station apparatus according to the present embodiment. Components that are the same as the components illustrated in FIG. 4 are given the same reference numerals, and descriptions thereof will be omitted. The following description focuses on the differences.

In FIG. 5, reference numeral 307 denotes the transmitting / receiving section 3
The transmission number monitoring unit monitors the number of transmissions of the packet transmitted at 01 and notifies the target reception power setting unit 304 of the number. Usually, in this type of communication system, as an error control method, an ARQ method in which an error is detected by an error detection code on a reception side and a retransmission is requested to a transmission side when an error is detected, is adopted. The buffer in the transmission / reception unit 301 or the transmission / reception buffer 30
By monitoring No. 2, the number of transmissions can be known for each transmission packet. The transmission number monitoring unit 307
Stores the number of transmissions for each transmission packet. The target reception power setting unit 304 determines the target reception power of the packet by using the transmission slot of the transmission packet notified from the transmission / reception unit 301. The position and the allocation status information of the slot allocation status monitoring unit 305 are referred to, and the transmission count of the packet in the transmission count monitoring unit 307 is referred to. Then, when there is a peripheral base station that has allocated a slot for transmitting a packet to the uplink and this packet is transmitted for the second time or later (in the case of retransmission), the first embodiment is used. Similarly to the operation, the target reception power of the transmission packet is increased by, for example, ΔP and set to P _tgt-s + ΔP. Therefore, only the retransmission packet is transmitted with its transmission power increased. Alternatively, the increase amount ΔP of the target reception power may be changed according to the number of times of transmission of the packet. That is, the greater the number of retransmissions, the greater the amount of increase in the transmission power.

By performing such transmission power control, when a downlink packet is transmitted to a slot allocated to an uplink in one or more peripheral base stations, a packet that is retransmitted due to an error due to interference or the like is generated. Only the target reception power of the packet is set to be large, so that the influence of the interference by the uplink packet transmitted from the mobile station existing in the neighboring cell can be reduced, and the peripheral base station allocating the slot to the uplink. The chance of interference with the station can be reduced as compared with the case of the first embodiment, and a more efficient system can be achieved.

Next, still another embodiment of the present invention will be described. In this embodiment, the target reception power, that is, the transmission power is controlled based on the distance from the mobile station that is the destination of the transmission packet, in addition to the above-described slot allocation status in the peripheral base station. is there. In FIG. 5, reference numeral 308 denotes a position of each mobile station, and the estimated position information is used as the target reception power setting unit 3.
This is a position estimating unit for notifying to 04. This position estimating unit 30
8, the method of estimating the position of the mobile station based on the amount of shift (delay) of the uplink packet transmitted from the mobile station with respect to the designated slot position, A method of estimating the position of the mobile station by notifying its transmission power value and estimating the amount of attenuation from the received power, or the reception power of a pilot signal transmitted from the base station by the mobile station at the position. To estimate its location from
There is a method of measuring the position using a position measuring means such as S, and notifying the position information to the base station via an uplink control slot or the like.

In this embodiment, when the target reception power setting section 304 determines the target reception power, the transmission slot position of the transmission packet notified from the transmission / reception section 301 and the slot allocation status monitoring section 305 With reference to the allocation status information, the position estimating unit 30 is referred to.
8, there is a peripheral base station that has assigned a slot for transmitting a packet to the uplink, and the destination mobile station of the packet and its own base station 3.
When the distance from the transmission packet is larger than a predetermined value, the target reception power of the transmission packet is set to, for example, ΔP
And set it to P _tgt-s + ΔP. As a result, it is possible to increase the transmission power of a transmission packet to a mobile station located in the periphery of a cell where interference from a mobile station located in a neighboring cell is large.

In the above description, the transmission power is increased by the same amount for mobile stations whose distance from the base station is equal to or greater than a predetermined value. However, the amount of power to be increased is increased in accordance with the distance. You may make it change. That is, the distance to the mobile station is determined by referring to the position information from the position estimating unit 308, and the larger the distance to the mobile station, the greater the increase ΔP in the target reception power of the transmission packet. In this case, ΔP may be increased stepwise, or may be increased continuously.
According to these embodiments, it is possible to increase the transmission power for mobile stations located near the cell boundary where the amount of interference by mobile station transmission signals in neighboring cells is large, and to improve the downlink throughput more efficiently. It is possible to do.

In each of the above embodiments,
As described above, if there is at least one peripheral base station that has allocated the slot to the uplink, the transmission power of the transmission packet is increased, but the increase amount of the target reception power Δ
P may be increased in accordance with the number of peripheral base stations allocating the slot to the uplink. That is, taking the first embodiment shown in FIG. 4 as an example,
The target reception power setting section 304 sets the target reception power of a transmission packet based on the allocation status information from the slot allocation status monitoring section 305, where n is the number of peripheral base stations that have allocated the slot to the uplink. Is α × n ×
Increase by ΔP (α is a predetermined coefficient), and P _tgt-s + α
× n × ΔP. According to this embodiment, the interference power from the mobile station belonging to the peripheral cell to the mobile station that receives the downlink packet of the slot increases as the number of the peripheral base stations that allocate the slot to the uplink is increased. It is possible to more effectively eliminate the influence of interference.

Although various embodiments of the present invention have been described, packet transmission power can be controlled by combining the above embodiments. For example, when there is a peripheral base station allocating the slot to the uplink, the mobile station located remotely from the base station 300 is referred to by referring to the outputs of both the transmission count monitoring unit 307 and the position estimating unit 308. The transmission power of only the retransmission packet to the station may be increased. In this case, it is possible to reduce the chance of the downstream packets transmitted by the base station 300 causing interference with the upstream packets of the neighboring base stations.

In each of the above embodiments,
Although the transmission power of the packet in the slot is increased by increasing the target reception power value in the target reception power setting section 304, the present invention is not limited to this. The received power is set to a constant reference value P _tgt-s ,
The transmission power control section 306 may eventually increase the calculated transmission power by a predetermined value.

In each of the above embodiments,
Although the case where the position of the TDD boundary 240 for separating the downlink information slot and the uplink information slot in the information slot is made variable has been described, the present invention provides a TDD boundary as described in the above-mentioned known example 3. Instead, the present invention can be similarly applied to the case of a method of allocating each slot to the uplink or downlink. However, in the case of the system using the TDD boundary 240, the allocation status information only needs to be the position information of the TDD boundary 240. In the case of this system, the allocation status information indicating the allocation status of each slot is used. Required. Furthermore, the present invention provides a TDD, FDMA,
The present invention can be applied to any of the CDMA multiple access systems.

[0029]

As described above, according to the mobile communication system and the transmission power control method of the present invention, a base station transmits a downlink packet in a slot allocated to an uplink by some of the peripheral base stations. In this case, the target reception power of the packet is set to be larger than that in the case where the packet is transmitted to the normal slot allocated to the downlink in all the neighboring base stations. Therefore, there is provided a cellular mobile communication system for performing packet communication according to the TDD system that implements open-loop transmission power control, wherein a base station arbitrarily allocates an information slot for transmitting user information to an uplink or downlink. In the system, there is an effect that a packet transmitted to a downlink information slot allocated to an uplink by a peripheral base station can reduce the influence of interference received from an uplink packet transmitted from a mobile station existing in a peripheral cell. . With this effect, an improvement in downlink throughput in the slot can be expected.

[Brief description of the drawings]

FIG. 1 is an overall conceptual diagram of a mobile communication system in which the present invention is implemented.

FIG. 2 is a diagram illustrating a frame configuration example of a wireless channel in which the present invention is implemented.

FIG. 3 is a diagram illustrating TDD boundary control in a mobile communication system in which the present invention is implemented.

FIG. 4 is a schematic block diagram illustrating a configuration of a base station device according to the first embodiment of the present invention.

FIG. 5 is a schematic block diagram illustrating a configuration of a base station device according to another embodiment of the present invention.

[Explanation of symbols]

 100, 110, 120, 130, 140 Mobile station 200 Radio channel 210 Uplink control slot 220 Downlink control slot 230 Information slot 231 Downlink information slot 232 Uplink information slot 240 TDD boundary 300, 310, 320 Base station 301 Transmission / reception unit 302 Transmission / reception buffer 303 TDD boundary control unit 304 Target reception power setting unit 305 Slot allocation status monitoring unit 306 Transmission power control unit 307 Transmission count monitoring unit 308 Location estimation unit

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 5K033 AA01 AA07 CB01 CB17 CC01 DA01 DA19 DB17 DB20 EA07 5K067 AA03 BB03 BB04 CC04 CC08 DD42 EE02 EE10 EE23 EE71 GG07 GG08 GG09 GG11 HH23 JJ53 LL01

Claims (18)

[Claims] 1. A cellular mobile communication system comprising a plurality of base stations and a plurality of mobile stations and performing packet communication according to a TDD system, wherein an information slot in which a base station transmits user information is arbitrarily assigned to an uplink or a downlink. In a mobile communication system that can be assigned, the base station comprises means for collecting the allocation status of each information slot in its surrounding base station, and means for controlling the transmission power of the packet to be transmitted, When the base station transmits a downlink packet to a slot allocated to an uplink in one or more peripheral base stations, compared to a case where the base station transmits to a slot allocated to a downlink in all peripheral base stations. And increasing the transmission power of the packet. 2. The base station further comprises means for storing the number of times of transmission of a packet to be transmitted, wherein only the retransmitted packet is a downlink packet whose transmission power is to be increased. 2. The mobile communication system according to 1. 3. The mobile communication system according to claim 2, wherein the higher the number of retransmissions, the greater the amount of increase in transmission power. 4. The base station further comprises means for estimating a location of a destination mobile station of the packet, wherein a distance between the base station and a downlink packet whose transmission power is to be increased is smaller than a predetermined value. 2. The mobile communication system according to claim 1, wherein only a packet to be transmitted to a mobile station existing at a large position is used. 5. The mobile communication system according to claim 4, wherein the larger the distance between the base station and the destination mobile station of the packet, the larger the increase in the transmission power. 6. The slot in which a base station transmits a packet, wherein the larger the number of peripheral base stations that have assigned the slot to the uplink, the greater the increase in the transmission power of the transmission packet. Item 6. The mobile communication system according to any one of Items 1 to 5. 7. A cellular mobile communication system comprising a plurality of base stations and a plurality of mobile stations and performing packet communication according to a TDD scheme, wherein the base station arbitrarily sets an information slot for transmitting user information to an uplink or a downlink. A base station apparatus in a mobile communication system which can be allocated, comprising: means for collecting allocation status of each information slot in a peripheral base station; and means for controlling transmission power of a packet to be transmitted, When the base station transmits a downlink packet to a slot assigned to an uplink in one or more peripheral base stations,
A base station apparatus wherein the transmission power of a downlink packet is increased as compared with a case where a downlink packet is transmitted to a slot allocated to a downlink in all peripheral base stations. 8. The apparatus according to claim 7, further comprising means for storing the number of transmissions of the packet to be transmitted, wherein only the retransmitted packet is the downlink packet whose transmission power is to be increased. Base station device. 9. The base station apparatus according to claim 8, wherein the higher the number of retransmissions, the larger the amount of increase in the transmission power. 10. The apparatus further comprises means for estimating the location of the destination mobile station of the packet, wherein the downlink packet whose transmission power is to be increased is located at a location whose distance from the base station is greater than a predetermined value. The base station apparatus according to claim 7, wherein only the packet addressed to the mobile station to be transmitted is set. 11. The base station apparatus according to claim 10, wherein the larger the distance between the base station and the destination mobile station of the packet, the larger the increase in the transmission power. 12. The transmission power of the transmission packet is increased as the number of peripheral base stations that allocate the slot to the uplink in the slot in which the own station transmits the packet is increased. Item 12. The base station device according to any one of Items 7 to 11. 13. A cellular mobile communication system comprising a plurality of base stations and a plurality of mobile stations and performing packet communication according to a TDD system, wherein the base station arbitrarily sets an information slot for transmitting user information to an uplink or a downlink. What is claimed is: 1. A transmission power control method in a base station in a mobile communication system adapted to be allocated, comprising: collecting an allocation state of each information slot in a peripheral base station; When a downlink packet is transmitted to a slot being assigned, the transmission power of the packet is increased as compared with a case where the packet is transmitted to a slot assigned to the downlink in all peripheral base stations. Transmission power control method. 14. The transmission power control method according to claim 13, wherein only the retransmitted packets are downlink packets to be increased in transmission power. 15. The packet transmission apparatus according to claim 14, wherein the higher the number of retransmissions, the greater the amount of increase in transmission power.
3. The transmission power control method according to 1. 16. Estimating the existence position of a destination mobile station of a packet, and setting only downlink packets targeted for increase in transmission power to packets addressed to a mobile station whose distance from the base station is equal to or more than a predetermined value. 14. The transmission power control method according to claim 13, wherein: 17. The transmission power control method according to claim 16, wherein the larger the distance between the base station and the destination mobile station of the packet, the larger the increase in the transmission power. 18. A slot for transmitting a packet from the base station, wherein the larger the number of peripheral base stations that have assigned the slot to the uplink, the greater the increase in transmission power of the transmission packet. Item 18. The transmission power control method according to any one of Items 13 to 17.