JP2003018091A - Radio data communication system, radio data communication method and program thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radio data communication system, in which a base station carries out modulation of OFDM system by using the same frequency band as that of an adjacent base station, and to provide a radio data communication method and its program. SOLUTION: In the radio data communication system, employing a plurality of base stations each making communication with a mobile station by adopting the OFDM system for the modulation system, a transmission power control processing section 23 of the base station controls each sub channel for transmission with arbitrary transmission power. A wireless communication processing section 22 uses one or a plurality of sub channels to condnet communication with a mobile station. A data control processing section 24 applies packet multiple access to the mobile station, by using communication data comprising a plurality of packets, each of which includes access control information used for controlling the access.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless data communication system including a mobile station and a plurality of base stations for wireless data communication.

[0002]

2. Description of the Related Art Conventionally, wireless data communication is performed by OFDM (Orthogonal Frequency Division Multiplexing) in mobile communication using terrestrial waves.
The use of the method is useful when high-speed wireless data transmission is performed because intersymbol interference caused by the influence of multiple delay waves can be reduced. However, there is a problem that interference occurs when the OFDM modulation is performed by using the same frequency band as that of the adjacent base station in order to improve the frequency utilization efficiency in the cell configuration.

Therefore, in order to solve the problem of interference with adjacent base stations, OFDM-FH (frequency hopping), OFDM-CDMA (code division multiple access), etc. are considered. However, it is necessary to perform power control between the mobile station and the base station in order to improve the frequency utilization efficiency because it is necessary to minimize the influence of mutual interference between the base stations. Moreover, in order to maintain the utilization efficiency of higher frequencies, it was necessary to perform a careful zone design.
In such a precise zone design, it is almost necessary to change the surroundings when the base station is added or moved, so that the period required for the change is long and the cost is large. Further, complicated wireless communication management is performed by a method of allocating a unique condition to a user such as a hopping pattern in OFDM-FH or a code in OFDM-CDMA.

When power control is used, it is necessary to consider interference at cell boundaries. The power interference at the boundary changes momentarily in a short time (movement of a car etc.) or a long time (expansion of a building etc.) due to movement of surrounding objects, etc., so that a margin is required in advance to allow the fluctuation. As a result, the efficiency of the entire system is lowered by maintaining the efficiency lower than the ideal efficiency. This also means that maintenance is required to manage the zone design, which requires a cost burden.

The accuracy of power control differs depending on the speed of the moving body. For example, a CDMA method using DS-SS (direct sequence method-spread spectrum) is a method of detecting power at regular time, but the temporal characteristic of fading changes depending on the moving speed. ,
It is easily conceivable that not all can be satisfied at regular time intervals. The system margin is taken into consideration in order to deal with it, but the communication capacity is limited due to the interference limit, and as a result, the communication capacity is sacrificed.

Further, since the interference limit value, the measurement time interval, the feedback amount for power control, etc. are stochastically analyzed and determined, it is not possible to deal with a case where a special distribution occurs. Therefore, in the above-mentioned wireless data communication system, the operating state of the system is always exposed to an unstable state. In addition, since the peak power of OFDM is larger than the average power, a power amplifier with small transmission distortion is used. Therefore, the transmission power efficiency is low.

[0007]

As described above, the OFDM method has been conventionally used in mobile communication. However, the OFDM method is performed by using the same frequency band as that of an adjacent base station. There was a problem that interference would occur.

Further, when the base station controls the transmission power according to the movement of the mobile station, a margin for allowing the fluctuation of the communication state is required in advance, so that the efficiency of the entire system and the communication capacity are lowered. There was a problem. In addition, we can not cope with the case where a special distribution of mobile stations occurs,
There has been a problem that the entire wireless data communication system is constantly exposed to instability.

Further, when OFDM is used, it is difficult to satisfy frequency orthogonality due to the distortion due to the amplifier before supplying to the antenna and the phase shift due to the cable and filter to the antenna. There is a problem that sectorization cannot be performed using the same frequency band by the antenna.

The present invention has been made in consideration of the above-mentioned circumstances, and a radio data communication system, a radio data communication method and a program therefor, which perform OFDM modulation using the same frequency band as an adjacent base station. The purpose is to provide. It is another object of the present invention to provide a wireless data communication system, a wireless data communication method, and a program using the OFDM method, in which a base station does not need to perform power control of transmission power according to movement of a mobile station.
Another object of the present invention is to provide a wireless data communication system, a wireless data communication method, and a program therefor, which can be further sectorized by a directional antenna using the OFDM method.

[0011]

The present invention has been made to solve the above-mentioned problems, and in a wireless data communication system according to the present invention, communication is performed with a mobile station using an OFDM system as a modulation system. A wireless data communication system comprising a plurality of base stations, wherein each base station uses one or a plurality of sub-channels and a transmission power control means for controlling each sub-channel to transmit with arbitrary transmission power. The communication means for communicating with the station and the communication data with the mobile station are composed of a plurality of packets, the packet includes connection control information, and data for performing packet multiple access for controlling connection based on the connection control information. And a control means.

Thus, each base station has a transmission power control means for controlling each sub-channel to transmit with arbitrary transmission power, and a communication means for communicating with a mobile station using one or more of the sub-channels. Since the communication data with the mobile station is composed of a plurality of packets, the packet includes connection control information, and the data control means for performing packet multiple access for controlling connection based on the connection control information is provided. The transmission power can be controlled so that radio waves are transmitted to a distance that does not interfere with surrounding base stations. This allows each base station to perform communication in the OFDM method using the same frequency band. Regarding packet multiple access, Japanese Patent Application No. 11-0
1479.

Further, in the wireless data communication system according to the present invention, the communication means allocates a plurality of sub-channels to be transmitted with different transmission powers to one mobile station for communication. By this means, the communication means allocates a plurality of sub-channels to be transmitted with different transmission powers to one mobile station for communication, so that the communication amount can be controlled easily. Also, when subchannels transmitted with a large transmission power are assigned, the communicable area is expanded, and stable connection with the base station can be achieved.

Further, the wireless data communication system according to the present invention is a wireless data communication system comprising a plurality of base stations which communicate with a mobile station using the OFDM system as the modulation system, wherein each base station is , A transmission power control means for controlling each sub-channel to be transmitted at an arbitrary transmission power, the transmission power control means using a sub-channel different from that of an adjacent base station, in a cell of the adjacent base station. The transmission power is equal to or higher than a predetermined value that can reach

Thus, each base station is provided with a transmission power control means for controlling each sub-channel to transmit with an arbitrary transmission power, and the transmission power control means uses a sub-channel different from that of an adjacent base station. Then, since transmission is performed with a transmission power of a predetermined value or more that can reach the cell of the adjacent base station, a sub-channel transmitted from each base station with a transmission power of a predetermined value or more between adjacent base stations. Can prevent interference from occurring.

Further, in the wireless data communication system according to the present invention, when there are a plurality of adjacent base stations, each of the base stations has a sub-channel which is transmitted with a transmission power of a predetermined value or more from the adjacent base stations. , A subset of its own subchannels that are transmitted at a transmission power of a predetermined value or less in the own station, and the subchannels of adjacent base stations are disjoint between the base stations. .

As a result, even if the own station sub-channel transmitted at a transmission power of a predetermined value or less and the sub-channel of the base station adjacent in a certain direction overlap (subset), the own station From the viewpoint, the subchannel cannot be used in the area in the direction, but other subchannels (other than the subset) can be used. Furthermore, the subchannels used by neighboring base stations that are transmitted with a transmission power higher than the specified value are different (are disjoint) among the base stations, so from the perspective of the own station, subchannels that cannot be used in each direction. Is a partial channel. That is, it is possible to use most of the sub-channels used by the surrounding base stations with the transmission power equal to or higher than the predetermined value and used by the local station with the transmission power lower than the predetermined value.

Further, in the wireless data communication system according to the present invention, each base station uses a sub-channel which is transmitted by an adjacent base station with a transmission power of a predetermined value or more and a transmission power which is not more than a predetermined value of its own station. It is characterized by further comprising a correction code adding means for adding a correction code to the data transmitted on the sub-channel in a radio zone where the sub-channel to be transmitted interferes.

As a result, each base station has a sub-channel which the adjacent base station transmits with a transmission power of a predetermined value or more,
In a radio zone where a sub-channel transmitting with a transmission power not higher than a predetermined value of its own station interferes, a correction code adding means for adding a correction code to the data transmitted on the sub-channel is further provided. It is possible to correct the signal whose deterioration is due to the correction code.

Further, in the wireless data communication system according to the present invention, each base station further comprises a plurality of directional antennas, and the plurality of directional antennas have a minimum overlap of radio waves from the directional antennas. A subchannel that is installed so as to cover the surroundings of the base station and that is provided by the surrounding base stations and that is transmitted with power equal to or more than a predetermined value from the facing directional antenna and a predetermined directional antenna from the facing directional antenna It is characterized in that the subchannels transmitted with the power equal to or higher than the value are different.

As a result, each base station further includes a plurality of directional antennas, and sub-channels which are provided by surrounding base stations and which are transmitted from opposing directional antennas at a power of a predetermined value or more, Since the subchannels transmitted from the directional antennas of the station facing each other with a power of a predetermined value or more are different, the subchannels transmitted with the power of a predetermined value or more from the directional antenna of the own station and the directional antennas facing the subchannel It is possible to prevent interference from occurring in subchannels transmitted with power of a predetermined value or more. In addition, it is possible to form a cell configuration in which the same band is shared by sharing the base station according to the directivity, and the frequency utilization efficiency can be improved.

Further, in the wireless data communication system according to the present invention, the transmission power control means controls the transmission power according to the communication traffic of the base station. With this, the transmission power control means controls the transmission power according to the communication traffic of the base station, so that the communication amount can be controlled according to the distribution of the communication traffic.

Further, in the radio data communication system according to the present invention, in each base station, when the transmission power control means controls to transmit one or a plurality of sub-channels with the transmission power equal to or lower than a predetermined power value, It is characterized by further comprising a modulation control means for converting the modulation of the sub-channel into multiple levels. Thereby, each base station, when the transmission power control means controls to transmit one or a plurality of sub-channels with the transmission power equal to or lower than the predetermined power value, further modifies the modulation of the sub-channels. Since the control means is further provided, when transmitting only to a short distance where the influence of multipath fading is small, it is possible to modulate the subchannel to be transmitted with a transmission power of a low power value by a modulation method in which the value is multivalued.

In the wireless data communication system according to the present invention, the transmission power control means transmits the transmission power at a plurality of predetermined power values, and controls each power value so as to follow a lognormal distribution. To do. This allows
The transmission power control means transmits the transmission power at a plurality of predetermined power values, and controls so that each power value follows a logarithmic normal distribution, so that the reach of radio waves exponentially corresponding to the transmission power are at equal intervals. Can be controlled.

Further, in the wireless data communication system according to the present invention, each of the base stations further comprises receiving means for removing interference of the received signal by the transmitted signal of the own station, by using the transmitted signal of the own station. The mobile station is characterized by performing transmission / reception using a subchannel in the same frequency band as the base station. As a result, each base station further comprises receiving means for removing interference of the received signal due to the transmitted signal of the own station by using the transmitted signal of the own station, and the mobile station has a subchannel of the same frequency band as the base station. Since transmission / reception is performed using, the transmission signal from the mobile station using the same frequency band as the frequency band used for transmission by the base station can be received.

Further, in the wireless data communication system according to the present invention, each of the base stations further comprises mobile station control means for transmitting a control instruction for controlling transmission power in the mobile station, and the mobile station comprises: It is characterized by further comprising communication control means for receiving a control instruction from the base station and controlling the transmission power according to the control instruction. This allows
Each base station further comprises mobile station control means for transmitting a control instruction for controlling the transmission power in the mobile station, the mobile station receiving the control instruction from the base station, and transmitting power according to the control instruction. Since the communication control means for controlling is further provided, the transmission power of the mobile station can be optimized by the control from the base station.

Further, in the mobile station according to the present invention, the mobile station used in the above-mentioned radio data communication system comprises a detecting means for detecting one or a plurality of subchannels receivable from the base station, and a detecting means. It is characterized by comprising sub-channel deciding means for deciding a sub-channel to be used from the detected one or more sub-channels, and notifying means for notifying the decided sub-channel to the base station. Thereby, the detection means for detecting one or a plurality of subchannels receivable from the base station, and the subchannel determination means for determining a subchannel to be used from the one or a plurality of subchannels detected by the detection means are determined. Since the mobile station is provided with a notification means for notifying the base station of the sub-channel, the sub-channel desired to be used by the mobile station can be designated.

Further, in the mobile station according to the present invention, the detecting means also detects information on the transmission power of each sub-channel, and the sub-channel determining means has a transmission power lower than that of the sub-channels with which communication is possible. It is characterized in that the sub-channels are sequentially selected and the sub-channel to be used is determined. As a result, the detecting means also detects the information regarding the transmission power of each sub-channel, and the sub-channel determining means selects and uses the sub-channels from the sub-channels with which the communication power is communicable in the ascending order. Since the sub-channel is determined, it is possible to minimize the influence of interference due to the transmission signal from the mobile station.

Further, the wireless data communication method according to the present invention is a wireless data communication method using a plurality of base stations that communicate with a mobile station using the OFDM system as a modulation system, and each base station The first step of controlling to transmit the sub-channel with arbitrary transmission power, the second step of communicating with the mobile station using one or more of the sub-channel, the communication data with the mobile station is a plurality of And a third step of performing packet multiple access for controlling connection based on the connection control information.

In the wireless data communication method according to the present invention, the second step is characterized in that a plurality of sub-channels to be transmitted with different transmission powers are assigned to one mobile station for communication.

The wireless data communication method according to the present invention is a wireless data communication method using a plurality of base stations that communicate with a mobile station using the OFDM method as a modulation method, and each sub-channel is arbitrarily selected. When transmitting with the transmission power of, the sub-channel different from that of the adjacent base station is used, and the transmission power is equal to or higher than a predetermined value that can reach the cell of the adjacent base station.

Further, in the wireless data communication method according to the present invention, when there are a plurality of adjacent base stations, the sub-channel transmitted from each adjacent base station with the transmission power equal to or higher than the predetermined value is transmitted by the local station. It is characterized in that it is a subset of sub-channels of its own station transmitted at a transmission power of a predetermined value or less, and the sub-channels of adjacent base stations are disjoint between the base stations.

Further, the program according to the present invention is a program for a base station in a wireless data communication system having a plurality of base stations which communicate with a mobile station using the OFDM system as a modulation system, and each sub channel The first step of controlling to transmit at a desired transmission power, the second step of communicating with the mobile station using one or more of the sub-channel, the communication data with the mobile station is from multiple packets And the packet contains connection control information,
And a third step of performing packet multiple access for controlling connection based on the connection control information.

Further, the program according to the present invention is characterized in that the second step allocates a plurality of subchannels to be transmitted with different transmission powers to one mobile station for communication, and the program according to the present invention is , Modulation method, O
A program for a base station in a wireless data communication system including a plurality of base stations that communicate with a mobile station using the FDM system, the base stations being adjacent to each other when transmitting each sub-channel with arbitrary transmission power. And a sub-channel different from that for transmitting with a transmission power of a predetermined value or more that can reach the cell of the adjacent base station.

[0035]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described through embodiments of the invention. However, the following embodiments do not limit the invention described in the claims, and all of the combinations of features described in the embodiments are required for the solution means of the invention. Not necessarily. First, a schematic configuration of a base station included in a wireless data communication system according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing a schematic configuration of a base station included in a wireless data communication system according to an embodiment of the present invention. In the figure, reference numeral 21 is a control unit for controlling the flow of data in the base station A. A wireless communication processing unit (communication means) 22 communicates with the mobile station using one or more of the mobile station and subchannels. The wireless communication processing unit 22 can also allocate and transmit a plurality of sub-channels to be transmitted with different transmission powers to one mobile station. In addition, the wireless communication processing unit 22 also has a function of removing interference of a reception signal with a transmission signal of its own station by using the transmission signal of its own station.

Reference numeral 23 is a transmission power control processing unit for controlling each sub-channel to transmit with arbitrary transmission power. The transmission power control processing unit 23 can control the transmission power according to the communication traffic of the base station. Reference numeral 24 denotes communication data between the base station and the mobile station as a plurality of packets,
The packet is a data control processing unit that includes connection control information in the packet and performs packet multiple access for controlling connection based on the connection control information. An OFDM processing unit 25 performs OFDM processing by modulating each sub-channel with a unique frequency. In the wireless zone 26, a sub-channel transmitted by an adjacent base station with a transmission power equal to or higher than a predetermined value interferes with a sub-channel transmitted with a transmission power lower than the predetermined value of the local station, and the sub-channel transmits with the sub-channel. A correction code addition processing unit that adds a correction code to data.

When the transmission power control processing unit 23 controls to transmit one or a plurality of sub-channels with a transmission power having a small power value, the control unit 27 controls the OFDM processing unit 25 to make the sub-channels of the sub-channels. It is a modulation control processing unit that further multi-values the modulation. The small power value is, for example, a power value at which radio waves reach only a distance close to a base station that is less affected by fading. In addition, the multilevel modulation means that the OFDM processing unit 25 uses QPSK (Quadrature Phase).
16-value QAM (Quadrature Ampli) when processing using Shift Keying
control is performed so as to use a more multilevel modulation method such as a tude modulation). Reference numeral 28 denotes a mobile station control processing unit that transmits a control instruction for controlling the transmission power of the mobile station.

Each processing unit shown in FIG. 1 described above may be realized by dedicated hardware, and each processing unit is composed of a memory and a CPU (central processing unit), The function may be realized by loading a program for realizing the function of the processing unit into a memory and executing the program. Also, the memory is
A hard disk device, a magneto-optical disk device, a nonvolatile memory such as a flash memory, a read-only recording medium such as a CD-ROM, a RAM (Random A)
volatile memory such as access memory),
Alternatively, it may be composed of a computer-readable and writable recording medium by a combination of these.

Next, the radio data communication system according to the first embodiment of the present invention will be described with reference to the drawings schematically showing the effect in the case of hexagonal cells. FIG. 2 is a block diagram schematically showing an effect in the case of the hexagonal cell of the wireless data communication system according to the embodiment of the present invention. In this figure, reference characters A, B, C, D, E, F, G
Is a base station that performs wireless data communication by an OFDM modulation method having radio zones 1A, 1B ... 1G of hexagonal cells (hereinafter, 7 base stations are collectively referred to as base stations AG). Is.

The radio communication processing unit 22 of the base stations A to G
Performs wireless data communication with a mobile station using seven channels (consisting of one or a plurality of subchannels) having different frequency bands. The numbers in FIG. 2 indicate the number of channels used in the area partitioned by line segments. In addition, for example, the transmission power control processing unit 23 of the base station A sets channel 1 as the maximum transmission power, and transmits the other channels with the transmission power capable of communicating with the mobile station within the range shown in the cell 1A. Further, the same transmission power control is applied to the base stations BG.

Further, in order to schematically show and explain the wireless data communication system, the following preconditions are set. -For the base station A of the central cell 2A, the surrounding base stations B-
Let G be an interfering station. The interference from the surrounding base stations BG to the cell 1A inside the base station A is only the interference from each base station BG in the opposite direction, and there is no interference from other base stations. To do. The inner cells 1A, 1B, 1C, ..., 1G are assumed to have independent communication ranges because they have low power and do not interfere with adjacent base stations.

When the above conditions are satisfied, cell 1 of base station A
A is divided into 6 areas by a line segment representing an area facing each of the surrounding base stations BG. Then, for example, in the area facing the base station B, the communicable channels are 3ch to 7ch other than the maximum communication power channel (1ch) and the maximum communication power channel (2ch) used by the facing base station B. Yes, as shown. The same applies to other areas.

Here, assuming that the communication capacity of one channel is C, the following calculation result can be derived.・ Communication capacity of cell 2A (maximum power): C ・ Communication capacity of cell 1A: 5/6 × 6C = 5C ・ Communication capacity of base station A: C + 5C = 6C From the above, theoretically from the seven channels used The maximum amount of communication that can be transmitted is 7C, and the ratio of the communication capacity that can be transmitted without interference is calculated to be 85.7% from 6/7.

A generalization of the above calculation with the number of channels: N, the number of cells forming a cluster: S, and the communication capacity of one channel as C is shown below. -Communication capacity of outermost cell: NC / S (N≥S) (Equation 1) -Communication capacity of inner cell: ((S-2) / (S-1)) x (NN-S) C = ((S-2) / S) NC (Equation 2) Communication capacity of the base station: (S-2) / (S-1) * NC- (S-2) / (S-1) × NC / S + NC / S = {(S-2) / (S-1)-(S-2) / (S-1) / S + 1 / S} NC = ((S-1) / S) NC ... ( (Equation 3) Suppose that all independent channels are used for the outermost shell cell,
Since the theoretical maximum capacity is NC, if the capacity ratio that allows transmission without interference is R, then R = (S−1) / S = 1−1 / S (Equation 4). From this (Equation 4), it can be said that if the number S of cells forming one cluster is increased, the same frequency can be repeatedly used with almost 100% capacity.

The above equation will be described below. First,
Regarding (Equation 1), since the channel transmitted with the maximum transmission power is different from the channel transmitted with the maximum transmission power of the adjacent base station (in other words, the modulation frequency is different), one base station The communication capacity of the outermost cell that can be used is NC / S.

Next, (Equation 2) will be described. Consider the channel used in the inner cell of the adjacent base station because it is the channel that is transmitted with the transmission power that allows communication even if the channel overlaps with the adjacent base station (interior cell). No need. Therefore, when each base station uses a channel other than the channel used in the outermost cell, the number of channels is NN / S. However, since adjacent base stations, which are located at opposite positions, receive the interference of the channel transmitted with the maximum transmission power, the data is lost by the interference for one channel (S-2) / (S
Multiply by -1). From the above, (Equation 2) is obtained.

(Equation 3) showing the communication amount of the base station is obtained from the sum of the above (Equation 1) and (Equation 2), and the communication capacity NC of the base station when the channel can be used with this (Equation 3) (Equation 4) is obtained by obtaining the ratio of From this (Equation 4), it is possible to repeatedly use the same channel in a channel in which the loss due to interference is very small due to the control of the transmission power with the adjacent base station, and the efficient communication capacity close to 100% is achieved. It shows that a wireless data communication system can be constructed.

As described above, in the first embodiment of the present invention, even if the same channel as that of the adjacent base station is used, two types of power amounts are selectively used to control the transmission power,
The loss due to interference was suppressed and the channel could be used. However, it is difficult to actually perform a system that completely tolerates the loss of interference by controlling two types of transmission power. Therefore, as a second embodiment of the present invention, a wireless data communication system in which the control of the transmission power of the channel is made more functional is shown and described below with reference to the drawings. The above control means
The transmission power of channels is used hierarchically, and the hierarchy is made variable. With this, the range of the inner cell and the number of channels are flexibly set.

FIG. 3 is a diagram showing layering of transmission power of a wireless data communication system according to a second embodiment of the present invention. In this figure, reference numeral 31 conceptually shows the antenna of the base station A, and also shows the hierarchy of the transmission power of 1 to 5 stages. Similarly, 32 conceptually shows the antenna of the base station B and shows the hierarchy of the transmission power. Also, a number indicating the distance from the base station A to the base station B in five stages is given. The radio wave transmitted with the transmission power of 5 stages (maximum transmission power) is in the communication range up to the distance of 5, and the same applies to the following 4 to 1.

Although not shown, base station A and base station B
Also, assuming that there are base stations in the surroundings, in each base station, a channel different from that of an adjacent base station is used as a channel for transmitting at the maximum communication power forming the outermost cell (similar to the first embodiment. ). In addition, each base station performs transmission using any one of the transmission powers of the five levels of hierarchy allocated for each channel. Therefore, in a signal transmitted from the same base station, channel interference between layers does not occur. The interference rate of the channel between adjacent base stations is “the number of interference channels with the channel / the number of constituent channels”.

In the two base stations, the mutual interference rate between the layers is "the mutual interference channel number / the constituent channel number". Mutual interference between two base stations is evaluated using the cumulative number of interference channels of each hierarchical channel. here,
Furthermore, preconditions are added as follows. -The outermost shell cells do not interfere with each other because they use different channels. In a mobile station located at a certain location, 1 / the number of constituent channels (M) when the reception power of an interference wave for an arbitrary channel is equal to or larger than the reception power of the channel.
Occurs in. -When the received power at the mobile station is attenuated below a predetermined value, no interference occurs and no transmission is performed. -Number the hierarchical transmission power in ascending order from the lowest hierarchy (class). : Class 1 to Class L-The number M of constituent channels in each class has a relationship of M = L.

As described above, 1 / M interference is accumulated in each class as the distance from the own class or more increases, and transmission becomes impossible at a position further away from the class or more. When the communication capacity C in the base station shown above is obtained, the following equation is obtained.

[Equation 1] In this equation, the second term on the right side is the communication capacity of the channel of the highest layer (maximum power). i is the distance from the base station. The third term on the right side is the communication capacity in the hierarchy that is not the highest. k is the value of the class of each hierarchy.

Next, since M = L, the above equation is calculated as follows. C = [L- (L-1) / 2L] + [L (L-1) / 2- (1 / 2L) {(L (L-1) / 2) + L-1}] = [(2L ² -L-1) / 2L] + ^{[(2L 3 -2L 2 -L + 2} ) / 4L ] ^{= (2L 2 + 2L-3} ) / 4 = (L + 1/2) 2 / 2-7 / 8 above equation, It is a monotonically increasing function with respect to the number of layers L (L: natural number, L> 0).

Next, when the ratio of the communication capacity C obtained by removing the interference is calculated with respect to the communication capacity T assuming that there is no interference, the following equation is obtained: C / T = {(2L2 + 2L-3) / 4} / {L (L + 1) / 2} (capacity after interference) / (capacity before interference) = (2L2 + 2L-3) / 2L (L + 1) = 1- [3 / 2L (L + 1) Lim _{L → ∞} [C / T] = 1−0 = 1 In other words, by increasing the number of layers L, the efficiency is 100%.
Approach.

The channel configuration shown in the first embodiment,
By performing the transmission power layering shown in the second embodiment together, the channels in the uppermost layer of cells adjacent to each other in each of the six directions of the hexagonal cell are different channels. Further, in the hierarchy for inner cells excluding the channel configuration, it is possible to allow collision due to mutual interference with the channels of the highest hierarchy of adjacent and opposing base stations. From the above, OFDM
In the above, the cell configuration by repeating the same frequency band enables transmission with almost 100% efficiency.

In the above-described embodiment, since the transmission power is hierarchical, the peak power becomes smaller than the average power, so that the transmission power efficiency is improved.
As a result, the communication area range is expanded and transmission power efficiency is improved as compared with the conventional method when the same power amplifier is used. In addition, in a wireless zone in which a sub-channel transmitted by the adjacent base station with the maximum transmission power and a sub-channel transmitted with the transmission power of its own station which is not the maximum interfere with each other, the correction code addition processing unit 26 transmits on the sub-channel. The S / N deterioration due to interference may be improved by adding a correction code to the data to be processed.

Regarding the transmission capacity of the base station according to the above configuration, the number of OFDM subchannels is 400.
In the case of a channel, calculation is performed using the following conditions as an example.・ Transmission rate: QPS with a symbol rate of 12.5 kHz
K, 25 (kbit / se per subchannel)
c) ・ Number of layers: L = 19 ・ Transmission capacity per layer: 21 ch × 25 kbps = 525
kbps-Capacity ratio: C / T = 0.996 From the above, the effective transmission capacity per cell is calculated as 19 × 525 kbps × 0.996 = 9.935 Mbps.

Next, when the cell structure is 7 cells, the effective transmission capacity per cell is as follows by repeatedly using the same frequency band: 9.935 Mbps × 6/7 = 8.571 (Mbit / sec) Furthermore, in a layer with low transmission power, since the propagation distance is short, reflected waves are less likely to be included in the process of reaching the terminal, so the SN ratio due to multiple waves is improved. By utilizing this, the transmission control signal can be multi-valued by the modulation control processing unit 27, so that the transmission capacity per sub-channel can be increased. It should be noted that the multi-valued number can be increased within the range of SN. Here, 1 is assigned to the half of the hierarchy with low transmission power.
An example using 6QAM will be described. -When 16QAM is used for signal modulation of the sub-channel,
Since it is 50 kbps per channel, the effective transmission capacity per cell is 1.5 times, 8.571 Mbps x
1.5 = 12.8565 Mbps.

In addition, in the hierarchization of the transmission power performed by the transmission power control processing unit 23 of each base station, the logarithmic normal distribution is used, so that the hierarchies of radio waves can be hierarchized with a constant distance. Generally, the terrestrial radio propagation characteristics can be approximated to a lognormal distribution. Therefore, it is necessary to give the transmission power for each class according to the log-normal distribution in order to obtain the uniform reach of radio waves. By hierarchizing the transmission power, it is possible to maintain the relationship of the cell configurations described above, so that an efficient area configuration is possible and uniform throughput can be given to the entire area.

Considering an example of the wireless data communication system according to the embodiment of the present invention, a mobile station corresponding to the above-mentioned base station is required. FIG. 4 is a block diagram showing a schematic configuration of a mobile station in the wireless data communication system according to the embodiment of the present invention. Reference numeral 41 is a control unit that controls the flow of data in the mobile station. 42 is
A wireless communication processing unit that performs wireless communication with a base station using the OFDM method. 43 is a layer (class) of receivable transmission power
It is a detection processing unit (detection means) for detecting one or a plurality of. Reference numeral 44 denotes a layer determination processing unit (sub-channel determination unit) that determines a layer to be used from the layers detected by the detection processing unit 43. 45 receives the control instruction from the base station,
The communication control processing unit (communication control means) controls the transmission power according to the control instruction. The wireless communication processing unit 42
It is also possible to perform transmission / reception using a subchannel in the same frequency band as the base station. The detection processing unit 43 can also detect information about the transmission power of each sub-channel. In this case, the hierarchy determination processing unit 44 selects subchannels in ascending order of transmission power from among communicable subchannels and determines the subchannel to be used.

Next, the operation when the base station and the mobile station of the wireless data communication system according to the embodiment of the present invention communicate with each other will be described below. First, when the base station and the mobile station communicate with each other, the mobile station detects a plurality of receivable layers in the detection processing unit 43. Next, the layer determination processing unit 44 determines the layer to be used for communication from the plurality of layers detected by the detection processing unit 43. Next, the mobile station transmits, via the wireless communication processing unit 42, information on the layer to be used to the base station. Based on the information, the base station communicates with the mobile station using a layer that can communicate with the mobile station. At this time, the method of transmitting information from the mobile station to the base station is not limited to OFDM described above, but narrow band transmission or wide band transmission such as CDMA may be used.

As described above, in the wireless data communication system of the OFDM system in which the same frequency band can be repeatedly used in each base station, the flexibility of the base station network can be secured. In addition, network management can be facilitated. Further, the problem of interference is solved, the communication capacity is not impaired, and the cost for maintenance and the like can be reduced as compared with the conventional case. In addition, power control
By not performing between mobile stations, system efficiency does not decrease and data communication becomes possible even when moving at high speed. It also helps to ensure system stability and improve transmission power efficiency.

Next, the case where the base station is sectorized in the wireless data communication system according to the third embodiment of the present invention will be described below. FIG. 5 is a block diagram showing sectorization of a base station in a wireless data communication system according to the third embodiment of the present invention. In this figure, reference symbols A, B, C, D, E, F, and G are base stations having hexagonal cells and provided with three directional antennas oriented in three directions. Also, the numbers in FIG. 5 indicate that the base station A has a directional antenna that performs transmission with the maximum transmission power on channels 1, 6, and 9. The same applies to the numbers in the other base stations BG.

As shown in FIG. 5, it is considered as a partial configuration in the case of 7 cells except that a certain number of channels (9 in FIG. 5) is required for sectorization. be able to. That is, it can be considered in the same manner as the case where the frequency band is repeatedly used by using the hierarchy of the channel configuration and the transmission power shown in the first embodiment and the second embodiment. Therefore, in sectorization, the shared base station can simply have a capacity that is twice the number of sectors. Therefore, when the effective transmission capacity per sectorized cell is calculated, 400 × 6/7 × 25 × 3 = 2
It becomes 5.713 (Mbit / sec).

In the third embodiment described above, it is assumed that the service area has uniform traffic. That is, it is not taken into consideration for the biased traffic distribution. Therefore, as a fourth embodiment of the present invention, a case of dealing with a biased traffic distribution in a wireless data communication system will be described below. FIG. 6 is a diagram showing a biased traffic distribution in the wireless data communication system according to the fourth embodiment of the present invention. If the lower right hatched portion in contact with the sector 60 of the hatched sector 60 is outside the service area (for example, when it is the sea), there will be no interference from the adjacent area. Therefore, in the hatched sector 60, it is not necessary to stratify the transmission power, and it is possible to transmit all subchannels with the same power. This means that all the throughput can be used in the propagation range.

The fourth embodiment described above describes the extreme case where the sector 60 is adjacent to the outside of the service area, but this can be applied to the above-described sectorized cell. That is, if the hierarchical structure can be adaptively changed, the traffic distribution can be flexibly dealt with. For example, if the traffic is biased in two adjacent sectors, the one with the larger traffic volume
Many channels in the upper layer (higher transmission power) may be used.

Further, in FIG. 1, a program for realizing the function of a processing unit for performing various processes is recorded in a computer-readable recording medium, and the program recorded in this recording medium is read by a computer system, Each process may be performed by executing it. The “computer system” mentioned here includes an OS and hardware such as peripheral devices.

The "computer-readable recording medium" means a flexible disk, a magneto-optical disk,
A portable medium such as a ROM or a CD-ROM, or a storage device such as a hard disk built in a computer system. Furthermore, "computer-readable recording medium"
Is a volatile memory (RAM) inside a computer system that serves as a server or a client when a program is transmitted via a network such as the Internet or a communication line such as a telephone line, and holds the program for a certain period of time. It also includes things.

Further, the above program may be transmitted from a computer system in which the program is stored in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. Here, the "transmission medium" for transmitting the program refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line. Further, the program may be for realizing a part of the functions described above. Further, it may be a so-called difference file (difference program) that can realize the above-mentioned functions in combination with a program already recorded in the computer system. Although the embodiment of the present invention has been described in detail above with reference to the drawings, the specific configuration is not limited to this embodiment, and includes a design and the like within a range not departing from the gist of the present invention.

[0070]

As described above, in the wireless data communication system according to the present invention, each base station controls transmission power control means for transmitting each sub-channel with arbitrary transmission power, and one of the sub-channels. Alternatively, the communication means for communicating with a mobile station using a plurality of packets and the communication data with the mobile station are composed of a plurality of packets, and the packets include connection control information, and the connection is controlled based on the connection control information. Since the data control means for performing packet multiple access is provided, it is possible to control the transmission power so as to transmit radio waves to a distance that does not interfere with surrounding base stations. This allows each base station to perform communication in the OFDM method using the same frequency band. Therefore, the communication capacity of each base station can be increased and can be efficiently used.

Further, in the wireless data communication system according to the present invention, the communication means allocates a plurality of sub-channels to be transmitted with different transmission powers to one mobile station for communication, so that the communication amount can be controlled easily. It can be carried out.
Also, when subchannels transmitted with a large transmission power are assigned, the communicable area is expanded, and stable connection with the base station can be achieved. From the above, it is possible to solve the problem of delayed waves outdoors by using OFDM,
Furthermore, by power management and channel configuration and cell configuration,
By allowing a certain amount of interference, it is possible to construct a highly efficient wireless system that solves the problem of interference and does not impair the capacity. Since the layer with which the mobile station can communicate can be dynamically selected, it is possible to maintain the optimal communication state at the location where the mobile station has moved. That is, in mobile communication, efficient wireless data communication that is not affected by the state of the user becomes possible, and high frequency utilization efficiency can be obtained.

Further, in the wireless data communication system according to the present invention, each base station modulates with a frequency unique to each sub-channel and transmission power for controlling each sub-channel with arbitrary transmission power. Since the modulating means modulates the sub-channels transmitted with a transmission power equal to or higher than a predetermined value at different frequencies between adjacent base stations, the modulating means includes a controller It is possible to prevent interference from occurring by a sub-channel transmitted with a transmission power equal to or higher than a predetermined value. By considering the configuration of the sub-channel of the outermost shell cell,
Since the base station arrangement can be handled organically, the flexibility of the base station network can be secured.

Further, in the radio data communication system according to the present invention, when there are a plurality of adjacent base stations, each of the base stations has a sub-channel which is transmitted with a transmission power of a predetermined value or more. , A subset of its own subchannels transmitted at a transmission power of a predetermined value or less at its own station, and the subchannels of adjacent base stations are disjoint between the base stations, so at its own station , Even if the own-station sub-channel transmitted with a transmission power of a predetermined value or less and the sub-channel of a base station adjacent in a certain direction overlap (subset), the Subchannels cannot be used, but other (non-subset) subchannels can be used. further,
The subchannels used with the surrounding base stations and transmitted with a transmission power higher than the specified value are different (coprime) between the base stations. Channel. That is,
It is possible to use most of the sub-channels that are used by the surrounding base stations with the transmission power equal to or higher than the predetermined value and that are used by the local station with the transmission power equal to or lower than the predetermined value. As a result, in a limited number of sub-channels in a limited frequency band,
The effect that the utilization efficiency of each sub-channel becomes high is obtained.

Further, in the wireless data communication system according to the present invention, each base station uses a sub-channel which is transmitted by an adjacent base station with a transmission power of a predetermined value or more and a transmission power which is not more than a predetermined value of its own station. In a wireless zone where a sub-channel to be transmitted interferes, correction code adding means for adding a correction code to the data to be transmitted on the sub-channel is further provided, so that a signal whose S / N is deteriorated due to interference is corrected by the correction code. You can

Further, in the wireless data communication system according to the present invention, each base station further includes a plurality of directional antennas, and the surrounding directional antennas are provided with electric power of a predetermined value or more from the directional antennas facing each other. Since the sub-channel transmitted by the sub-channel and the sub-channel transmitted by the directional antenna facing the own station with a power of a predetermined value or more have different modulation frequencies, the directional antenna of the time station has a predetermined value or more. It is possible to prevent interference from occurring between the sub-channel transmitted with electric power and the sub-channel transmitted with electric power of a predetermined value or more from the opposing directional antenna. In addition, it is possible to form a cell configuration in which the same band is shared by sharing the base station according to the directivity, and the frequency utilization efficiency can be improved.

Further, in the wireless data communication system according to the present invention, the transmission power control means controls the transmission power according to the communication traffic of the base station, so that the communication amount is controlled according to the distribution of the communication traffic. You can This makes it possible to maintain uniform efficiency with respect to the traffic distribution within the service area by adaptively controlling the layering according to the traffic distribution, and obtain high frequency utilization efficiency.

Further, in the radio data communication system according to the present invention, in each base station, when the transmission power control means controls to transmit one or a plurality of sub-channels with the transmission power equal to or lower than a predetermined power value, Since it further includes modulation control means for converting the modulation of the sub-channel into multiple levels, when transmitting only to a short distance where the influence of fading is small, the number of sub-channels to be transmitted with the low transmission power is increased. It can be modulated by the modulation method.

Further, in the wireless data communication system according to the present invention, the transmission power control means transmits the transmission power at a plurality of predetermined power values and controls each power value so as to follow a lognormal distribution. It is possible to control so that the arrival distances of the radio waves that correspond exponentially to are evenly spaced. As a result, since the power hierarchization follows a normal distribution, the areas can be hierarchized at regular distance intervals, and uniform throughput can be given to the user distribution in the area.

Further, in the wireless data communication system according to the present invention, each base station further comprises receiving means for eliminating interference of the received signal by the transmitted signal of the own station, by using the transmitted signal of the own station, Since the station performs transmission / reception using the subchannel having the same frequency band as the base station, it can receive the transmission signal from the mobile station using the same frequency band as the frequency band used by the base station for transmission. This allows
Corresponding to asymmetrical communication, by allocating the same frequency band to upstream and downstream communication, it is possible to provide a wireless data communication system that effectively uses the frequency band.

In the wireless data communication system according to the present invention, each base station further comprises mobile station control means for transmitting a control instruction for controlling the transmission power of the mobile station, and the mobile station is a base station. Received control instructions from
Since the communication control means for controlling the transmission power according to the control instruction is further provided, the transmission power of the mobile station can be optimized by the control from the base station. By this means, it is possible to use subchannels that are transmitted with a transmission power that is equal to or higher than a predetermined value from adjacent base stations, so that it is possible to improve the utilization efficiency of frequency bands.

Further, in the mobile station according to the present invention, the detecting means for detecting one or a plurality of sub-channels receivable from the base station and the sub-channels used from the one or a plurality of sub-channels detected by the detecting means. Since the subchannel determining means for determining and the notifying means for notifying the determined subchannel to the base station are provided, the subchannel desired to be used by the mobile station can be designated.

Further, in the mobile station according to the present invention, the detecting means also detects information regarding the transmission power of each sub-channel, and the sub-channel determining means determines the order of transmission power from the sub-channels in which communication is possible. Since the sub-channel is selected more and the sub-channel to be used is determined, the influence of the interference due to the transmission signal from the mobile station can be minimized. As a result, when it is possible to communicate with an adjacent base station at the same time, it is possible to perform communication with high efficiency due to minimum interference.

[Brief description of drawings]

FIG. 1 is a block diagram showing a schematic configuration of a base station included in a wireless data communication system according to an embodiment of the present invention.

FIG. 2 is a block diagram schematically showing an effect in the case of a hexagonal cell of the wireless data communication system according to the embodiment of the present invention.

FIG. 3 is a diagram showing layering of transmission power of a wireless data communication system according to a second embodiment of the present invention.

FIG. 4 is a block diagram showing a schematic configuration of a mobile station in the wireless data communication system according to the embodiment of the present invention.

FIG. 5 is a block diagram showing sectorization of a base station in a wireless data communication system according to a third embodiment of the present invention.

FIG. 6 is a diagram showing a biased traffic distribution in a wireless data communication system according to a fourth embodiment of the present invention.

[Explanation of symbols]

21 Control unit 22 Wireless communication processing unit 23 Transmission power control processing unit 24 Data control processing unit 25 OFDM processing unit 26 Correction Code Addition Processing Unit 27 Modulation control processing unit 28 Mobile station control processor 41 Control unit 42 wireless communication processing unit 43 Detection Processing Unit 44 Layer determination processing unit 45 Communication control processing unit

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Yasushige Ueoka             3-5-1, Otemachi, Chiyoda-ku, Tokyo             Ryo Materials Corporation Mobile Business Promotion Division             Within (72) Inventor Kazuyoshi Tasato             1-8-10 Honcho, Kichijoji, Musashino City, Tokyo               Mitsubishi Materials Corporation Mobile Business Development             In the center (72) Inventor Kenzo Nakamura             1-8-10 Honcho, Kichijoji, Musashino City, Tokyo               Mitsubishi Materials Corporation Mobile Business Development             In the center (72) Inventor Yoshihiro Matsuno             1-8-10 Honcho, Kichijoji, Musashino City, Tokyo               Mitsubishi Materials Corporation Mobile Business Development             In the center (72) Inventor Takeshi Hattori             3-12-21-205 Seta, Setagaya-ku, Tokyo F term (reference) 5K067 AA03 AA11 CC08 EE02 EE10                       EE45 EE46 GG08 HH21 KK02

Claims (20)

[Claims] 1. A wireless data communication system comprising a plurality of base stations communicating with a mobile station using an OFDM method as a modulation method, wherein each base station transmits each sub-channel with arbitrary transmission power. Transmission power control means for controlling so that, the communication means for communicating with the mobile station using one or more of the sub-channel, the communication data with the mobile station consists of a plurality of packets,
A wireless data communication system, characterized in that the packet includes connection control information, and data control means for performing packet multiple access for controlling connection based on the connection control information. 2. The communication means performs communication by allocating a plurality of subchannels to be transmitted with different transmission powers to one mobile station.
The wireless data communication system according to. 3. A wireless data communication system comprising a plurality of base stations that communicate with a mobile station by using an OFDM method as a modulation method, wherein each base station uses each sub-channel with arbitrary transmission power. A transmission power control unit for controlling transmission, wherein the transmission power control unit uses a sub-channel different from that of an adjacent base station to transmit a predetermined value or more that can be reached in a cell of the adjacent base station. A wireless data communication system characterized by transmitting with electric power. 4. In each of the base stations, when there are a plurality of adjacent base stations, the subchannel transmitted from each adjacent base station with the transmission power of the predetermined value or more is equal to or less than the predetermined value in the own station. 4. The radio according to claim 3, wherein the sub-channels of the base station are sub-sets of the sub-channels transmitted with the transmission power of 1, and the sub-channels of adjacent base stations are disjoint between the base stations. Data communication system. 5. In each of the base stations, a sub-channel transmitted by an adjacent base station with a transmission power equal to or higher than the predetermined value interferes with a sub-channel transmitted by an adjacent base station with a transmission power equal to or lower than the predetermined value. The wireless data communication system according to claim 3 or 4, further comprising a correction code adding means for adding a correction code to the data to be transmitted on the sub-channel in the wireless zone. 6. Each of the base stations further comprises a plurality of directional antennas, wherein the plurality of directional antennas are arranged so that the overlapping of radio waves from the directional antennas is minimum and the surroundings of the base station are covered. A sub-channel that is installed and is transmitted from the directional antennas that the surrounding base stations have and that face each other, and that is transmitted with power equal to or higher than the predetermined value,
The wireless data communication system according to any one of claims 1 to 5, wherein the sub-channels transmitted from the directional antennas of the own station facing each other at a power equal to or higher than the predetermined value are different. 7. The wireless data communication system according to claim 1, wherein the transmission power control means controls the transmission power according to communication traffic of the base station. 8. Each of the base stations further increases the modulation of the subchannel when the transmission power control unit controls to transmit one or a plurality of subchannels with a transmission power of a predetermined power value or less. 8. The wireless data communication system according to claim 1, further comprising modulation control means for digitizing. 9. The transmission power control means transmits the transmission power at a plurality of predetermined power values, and controls each power value so as to follow a log-normal distribution. A wireless data communication system according to claim 1. 10. Each of the base stations further comprises receiving means for removing interference of a received signal by a transmitted signal of the own station by using the transmitted signal of the own station, and the mobile station is the same as the base station. The wireless data communication system according to any one of claims 1 to 9, wherein transmission and reception are performed using subchannels in a frequency band. 11. Each of the base stations further comprises mobile station control means for transmitting a control instruction for controlling transmission power in the mobile station, wherein the mobile station receives the control instruction from the base station. The wireless data communication system according to claim 10, further comprising communication control means for controlling transmission power according to the control instruction. 12. A mobile station used in the wireless data communication system according to any one of claims 1 to 11, wherein the detecting means detects one or a plurality of subchannels receivable from the base station, and the detecting means. A mobile station comprising: a subchannel determining means for determining a subchannel to be used from one or a plurality of subchannels detected by the means, and a notifying means for notifying the base station of the determined subchannel. . 13. The detecting means also detects information about the transmission power of each of the sub-channels, and the sub-channel determining means selects sub-channels in ascending order of transmission power from among communicable sub-channels. The mobile station according to claim 12, wherein the mobile station determines which sub-channel to use. 14. A wireless data communication method using a plurality of base stations that communicate with a mobile station using an OFDM method as a modulation method, wherein each sub-channel is transmitted at an arbitrary transmission power in each of the base stations. A first step of controlling to, a second step of communicating with the mobile station using one or more of the sub-channel, the communication data with the mobile station consists of a plurality of packets,
The packet includes connection control information, and a third step of performing packet multiple access for controlling the connection based on the connection control information. 15. The second step is characterized in that a plurality of sub-channels to be transmitted with different transmission powers are assigned to one mobile station for communication.
4. The wireless data communication method according to item 4. 16. A wireless data communication method using a plurality of base stations that communicate with a mobile station using an OFDM method as a modulation method, wherein adjacent sub-channels are used when transmitting each sub-channel with arbitrary transmission power. The wireless data communication method is characterized in that transmission is performed with a transmission power that is equal to or higher than a predetermined value that can reach the cell of the adjacent base station using a subchannel different from that of the base station. 17. When there are a plurality of adjacent base stations, a sub-channel transmitted from each adjacent base station with a transmission power equal to or higher than the predetermined value is transmitted at its own station with a transmission power equal to or lower than the predetermined value. 17. The wireless data communication method according to claim 16, wherein the sub-channels of the sub-channels of the local station are adjacent to each other, and the sub-channels of adjacent base stations are disjoint between the base stations. 18. A program for a base station in a wireless data communication system comprising a plurality of base stations communicating with a mobile station using the OFDM system as a modulation system, wherein each sub-channel is transmitted with arbitrary transmission power. A first step of controlling to transmit, a second step of communicating with a mobile station using one or more of the sub-channel, communication data with the mobile station consists of a plurality of packets,
A program that causes the computer to execute a third step of performing packet multiple access for controlling connection based on the connection control information in the packet. 19. The communication according to claim 2, wherein the second step allocates a plurality of sub-channels to be transmitted with different transmission powers to one mobile station for communication.
8. The program according to 8. 20. A program for a base station in a wireless data communication system comprising a plurality of base stations communicating with a mobile station using the OFDM method as a modulation method, wherein each sub-channel is transmitted with arbitrary transmission power. A program for transmitting at a transmission power equal to or higher than a predetermined value that can reach the cell of the adjacent base station by using a subchannel different from that of the adjacent base station.