JP3338640B2 - Wireless packet frequency selection method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a system for performing wireless communication between a wireless base station and a mobile station using a wireless packet. ), Autonomously reduce the transmission efficiency due to interference with adjacent radio base stations and mobile stations, and perform radio communication that can effectively utilize limited frequencies. The present invention relates to a packet frequency selection method.

[0002]

2. Description of the Related Art Conventionally, wireless LAN using wireless packets
In such cases, a system (IEEE 802.11 standard) for sharing the same frequency by using spread spectrum and communicating was generally used. However, in such a system, in order to perform high-speed data transmission, spread spectrum must be performed at a speed much higher than the transmission speed, and accordingly, a wideband frequency is required. This is difficult to achieve in limited radio frequency resources.

Therefore, it has been studied to use one or more frequencies in common for a plurality of radio cells without using spread spectrum, and to use the same frequency in a time division manner if necessary.
At this time, if the number of interference waves is large, the available time rate becomes low. Therefore, a method of dynamically selecting a frequency having the lowest level of the interference wave has been proposed (Reference: Ishii, Osawa, "Shared for Wireless LAN System"). -Proposal of PDCA ”, IEICE 1997 Communication Society Conference B-5-174, September 1997).

FIG. 7 shows an example of a specific algorithm when such a method is employed. In the figure, S-71
The symbols ~ S-7-5 correspond to those in parentheses below. First, it is checked whether or not the interference wave is below a specified level at all frequencies (carriers) (S-71). If the interference wave is below the specified level for all the carriers, a carrier is randomly selected (S-72).

[0005] If not, it is checked whether or not there is a carrier below the specified interference wave level (S-73). If there is a carrier whose interference wave level is equal to or less than the specified value, the carrier having the lowest interference wave level is selected (S-74). If there is no carrier whose interference wave level is equal to or lower than the specified value, the carrier having the lowest interference wave level is selected.

[0006]

As described above, in a system using spread spectrum, it is difficult to secure a frequency band for performing high-speed data transmission, and at the same time, hardware that operates with a high-speed clock is realized. Was also difficult. Further, when the hardware is operated with a high-speed clock, the power consumption increases, and it is difficult to reduce the size and weight of the mobile device, which is not suitable for mobile communication.

In a system in which the same frequency is shared by time division, when there is no frequency at which the interference wave level is equal to or lower than a specified value, a frequency having a low interference wave level is selected. Since it is true that interference exists at least, the frequency cannot be used at the same time when the interference wave is being transmitted, so that there is a problem that the frequency utilization efficiency cannot be improved.

[0008] This is because between radio base stations that interfere with each other,
This phenomenon occurs because the distance between the radio base station and the mobile station or between the mobile stations cannot be sufficiently separated. In this case, since the reception level of the interference wave is selected as low as possible, the same frequency is shared between cells which are separated to some extent,
Everywhere that frequency will have interference.

At this time, since cells using the same frequency are distant from each other, they interfere with each other, but cannot demodulate correctly, so that the communication state in the cell cannot be intercepted, and the information cannot be used. There is a problem that the interference avoidance control cannot be performed.

[0010] In order to solve the above-mentioned conventional problems, the present invention devises a frequency selection algorithm in a system in which a radio base station and a mobile station perform radio communication using radio packets to improve the efficiency of each cell. In each case, a wireless packet frequency selection method capable of performing communication by effectively using limited frequencies to reduce a reduction in transmission efficiency due to interference with adjacent wireless base stations and mobile stations It is intended to provide.

[0011]

According to the present invention, the above-mentioned object is attained by means described in the claims.

That is, according to the first aspect of the present invention, when there is data to be transmitted in a wireless section in a system including a plurality of wireless base stations and a mobile station that performs wireless communication therewith, the data is generated. In a system for performing time-division multiple access in which data is selected as one wave from a plurality of slots and the frequency is transmitted as a radio packet shared by a plurality of radio base stations or mobile stations,

The radio base station periodically transmits a beacon for establishing a timing synchronization between a broadcast signal to the mobile station and a radio packet signal at a frequency selected by the following method, and the radio base station transmits all available beacons. Measure the interference wave level of the frequency, if the interference wave level is below the level allowed at all those frequencies, select the highest interference wave level of all the frequencies,

If packet communication is performed between the radio base station and the mobile station at that frequency, and the result of the interference wave level measurement is lower than the allowable interference wave level at some but not all frequencies, the allowable interference level is determined. The frequency at which the interference wave level is the highest among the interference waves at or below the wave level is selected, packet communication is performed between the radio base station and the mobile station at that frequency, and the interference wave level measurement results are obtained at all frequencies. When the interference wave level is equal to or higher than the allowable interference wave level, the number of interference waves equal to or higher than the allowable interference wave level is counted by receiving the beacon,

If the frequency with the least number of interference waves is one, the frequency is selected and packet communication is performed between the radio base station and the mobile station at that frequency, and the frequency with the least number of interference waves is two. The above case is a radio packet frequency selection method of selecting a frequency having the highest interference wave level and performing packet communication between the radio base station and the mobile station at that frequency.

According to a second aspect of the present invention, when there is data to be transmitted in a wireless section in a system including a plurality of wireless base stations and a mobile station performing wireless communication with the plurality of wireless base stations, the data is transmitted in a slot after the data is generated. In a system for performing time division multiple access in which one wave is selected from a plurality of radio waves and the frequency is transmitted as a radio packet shared by a plurality of radio base stations or mobile stations,

[0017] The radio base station measures the interference wave level of all available frequencies, and if the level is lower than the allowable interference wave level at all the frequencies, the interference wave level is the highest among all the frequencies. Select a frequency with a higher level and perform packet communication between the radio base station and the mobile station at that frequency,

If the interference wave level measurement result is less than the allowable interference wave level at some but not all of the frequencies, the frequency having the highest interference wave level among the frequencies that are the interference waves below the allowable interference wave level is determined. Select and perform packet communication between the radio base station and the mobile station at that frequency,

When the result of the interference wave level measurement is equal to or higher than the allowable interference wave level at all frequencies, the time rate at which the interference wave equal to or higher than the allowable interference wave level is received at all or a plurality of frequencies is set to a predetermined time. If the frequency at which the interference wave reception time rate is the smallest is one wave, the frequency is selected and packet communication is performed between the radio base station and the mobile station at that frequency,

If the frequency at which the interference wave reception time rate is the least is two or more, the frequency having the highest interference wave level among the frequencies is selected, and a packet is transmitted between the radio base station and the mobile station at that frequency. This is a wireless packet frequency selection method for performing communication.

According to a third aspect of the present invention, there is provided a system comprising a plurality of radio base stations and a mobile station which performs radio communication with them, and when there is data to be transmitted in a radio section, a slot after the data is generated. In a system for performing time division multiple access in which the data is selected from a plurality of waves and transmitted as a radio packet shared by a plurality of radio base stations or mobile stations,

The radio base station periodically transmits a beacon for establishing a timing synchronization between a broadcast signal to the mobile station and a radio packet signal at a frequency selected by the following method. Measure the interference wave level of the frequency, if the interference wave level is below the level allowed at all those frequencies, select the highest interference wave level of all the frequencies,

If packet communication is performed between the radio base station and the mobile station at that frequency, and the result of the interference wave level measurement is lower than the allowable interference wave level at some but not all frequencies, the allowable interference level is determined. Select the frequency at which the interference wave level is the highest among the interference waves below the wave level, and perform packet communication between the radio base station and the mobile station at that frequency,

If the interference wave level measurement result is equal to or higher than the allowable interference wave level at all frequencies, the number of interference waves equal to or higher than the allowable interference wave level is counted by receiving the beacon,
If the frequency with the least number of interference waves is one, select that frequency and perform packet communication between the radio base station and the mobile station at that frequency,

If the frequency with the least number of interference waves is two or more, the frequency with the lowest interference wave reception time rate is selected from the frequencies, and packet communication is performed between the radio base station and the mobile station at that frequency. This is a wireless packet frequency selection method for performing the following.

According to the present invention, in a system using time division multiple access enabling high-speed data communication without using a spread spectrum system, if there are many radio base stations and the same frequency is not shared by a plurality of cells, In such a situation, cells that interfere with each other are placed as close as possible. This allows
Cells that interfere with each other can be limited, and the frequencies can be prevented from interfering with each other over a wide range.

As a specific example, FIG. 1A shows a situation in which three frequencies are shared by seven cells. In the figure, there are four cells using the frequency f1. Although the two cells of group A using f1 interfere with each other, the cells of group A and the cells of group B do not interfere with each other because of the distance.

Therefore, the cells of both groups share one frequency with two cells. In addition, cells of group B using f2 also share one frequency because the cells interfere with each other. The cell using f3 occupies one frequency because there is no cell using the same frequency in the vicinity.

When a time rate of use (occupation) of a frequency on a time axis in a cell is referred to as a use rate, in a total of six cells of group A, group B and group C, f1
Is １ ／, since one frequency is shared by two cells. The value of the cell using f3 is 1. Therefore, 1/2 × 6 + 1 = 4 in the whole system. That is, the usage rate of one cell average is 4/7.

In the prior art, since the interference waves are used so as to be as low as possible, there is a sufficient frequency,
It is good when it is not necessary to share one frequency among a plurality of cells. However, as shown in an example shown in FIG. 1 (b), a central cell using f1 is shared by three stations,

Since the cells at both ends using f1 do not interfere with each other, f1 is shared by the central cell and two stations, respectively.
Considering the case where two stations share the same frequency at f2 and f3, the usage rate per cell is 1/2 × 6 + ／ = 10/3. That is, the usage rate of one cell average is 10/21, which is inferior to FIG. This difference becomes significant when the number of cells is increased and the cells are arranged in a two-dimensional manner.

In FIG. 1 (b), cells using the same frequency are located in the interference area with each other, and if they are used at the same time, they interfere with each other. When a signal is transmitted in one of the shared cells, the signal cannot always be received correctly in another cell using the same frequency.

This is because they are in the interference area. On the other hand, in the case of FIG. 1A, since the cell that causes interference is adjacent, the signal level is high, and the probability of correct reception is high. If this can be received correctly, the other party can be notified of the time occupying the shared frequency in order to communicate with each other, and one frequency can be used efficiently.

For example, in IEEE802.11, when another wireless station performs communication under the condition that there is no packet collision, a method of instructing another wireless station not to transmit until a designated time is defined. ing. According to the present invention, cells sharing the same frequency are adjacent to each other, so that this standardized rule can be fully utilized.

[0035]

FIG. 2 is a diagram showing a first example of an embodiment of the present invention, and corresponds to the first aspect of the present invention. Reference numerals S-21 to S-28 in the figure indicate steps, respectively, and correspond to the description in the following description.

In the figure, first, the interference wave level is measured at all the carriers (frequency) to be used or available, and the measured value is equal to or less than a predetermined value (level) allowed as the interference wave. It is checked whether or not there is (S-2)
1). If the interference wave is equal to or lower than the specified level in all the carriers, the carrier having the highest interference wave level is selected from among them (S-22). By selecting the carrier having the highest interference wave level in this way, the carrier can be repeatedly used at a short distance without the influence of interference.

When the interference wave is not lower than the specified level in all the carriers, but there is a carrier lower than the specified interference level (S-23), the interference wave level is the highest among the carriers lower than the specified interference level. Select a carrier (S-
24). If there is no carrier equal to or lower than the specified interference wave level in S-23, the number of interference waves Ni exceeding the specified level is counted by receiving the beacon (S-25).

If the frequency (carrier) having the smallest number of interference waves Ni is one (S-26), the carrier is selected (S-27). If there are two or more carriers having the smallest Ni, the carrier having the largest interference wave level is selected from the carriers having the smallest Ni (S-28).

As in the case of No (N) in S-23, when the interference wave is higher than the specified level in all carriers, the same frequency must be shared by a plurality of cells. Therefore, the number of interference waves exceeding a prescribed interference wave level is counted. By selecting the carrier with the least number of interference waves, the number of shared cells can be minimized. However, when the number of cells to be shared is the same, the carrier having the highest beacon level of the shared cell, that is, the highest carrier as the interference wave is selected. With these procedures, the same carrier can be autonomously selected in a nearby cell as shown in FIG.

FIG. 3 is a diagram showing a second example of the embodiment of the present invention, and corresponds to the second aspect of the present invention. Reference numerals S-31 to S-38 in the figure indicate steps, respectively, and correspond to the description in the following description.

In the figure, first, the interference wave level is measured at all the carriers (frequency) to be used or available, and the measured value is equal to or less than a predetermined value (level) allowed as the interference wave. Check whether or not there is (S-3)
1). If the interference wave is equal to or lower than the specified level in all the carriers, the carrier having the highest interference wave level is selected from among them (S-32). By selecting the carrier having the highest interference wave level in this way, the carrier can be repeatedly used at a short distance without the influence of interference.

When the interference wave is not lower than the specified level in all the carriers, but there is a carrier lower than the specified interference level (S-33), the interference wave level is the highest among the carriers lower than the specified interference level. Select a carrier (S-
34). If the interference wave level measurement result is equal to or higher than the allowable interference wave level at all frequencies, that is, if there is no carrier equal to or lower than the specified interference wave level at S-33, the interference wave exceeding the specified level is preliminarily detected at all frequencies. The time during which the signal is received within the determined fixed time is checked, and the time rate ρ is determined from this (3-35).

If the frequency (carrier) with the smallest time rate ρ is one wave (S-36), the carrier is selected (S-37). If there are two or more carriers with the smallest time rate ρ, the carrier with the largest interference wave level is selected from the carriers with the smallest time rate ρ (S-38).

As in the case of No (N) in S-33, when the interference wave is at or above the specified level in all carriers, the same frequency must be shared by a plurality of cells. Therefore, a time rate ρ exceeding a prescribed interference wave level is examined. By selecting the carrier with the smallest time rate ρ, the number of shared cells can be minimized. However, when the number of shared cells is the same, the carrier having the highest interference wave level is selected. By these procedures, the same carrier can be autonomously selected in a nearby cell as shown in FIG.

The difference between the example of the present embodiment and the first example of the above-described embodiment is that, instead of counting the number of beacons having a high level as interference waves, the level of the interference waves is not less than a specified value. The point is to measure the time rate that When the time rate is high, there is a high probability that the carrier is used, and when the carrier is used, the throughput of the packet becomes low. Therefore, a frequency having a low time rate is selected instead of the selection.

FIG. 4 is a diagram showing a third example of the embodiment of the present invention, and corresponds to the third aspect of the present invention. Reference numerals S-41 to S-48 in the figure indicate steps, respectively, and correspond to the description in the following description.

In the figure, first, the interference wave level is measured for all the carriers (frequency) to be used or available, and the measured value is equal to or less than a predetermined value (level) allowed as an interference wave. Check whether there is any (S-4)
1). If the interference wave is below the specified level in all the carriers, the carrier having the highest interference wave level is selected from among them (S-42). By selecting the carrier having the highest interference wave level in this way, the carrier can be repeatedly used at a short distance without the influence of interference.

When the interference wave is not lower than the specified level in all the carriers, but there is a carrier lower than the specified interference level (S-43), the interference wave level is the largest among the carriers lower than the specified interference level. Select a carrier (S-
44). If there is no carrier equal to or lower than the specified interference wave level in S-43, the number Ni of interference waves exceeding the specified level is obtained at all frequencies (S-45).

If the frequency (carrier) with the smallest number Ni of the interference waves is one (S-46), the carrier is selected (S-47). If the number of interference waves N
If there are two or more carriers having the smallest i, the time rate ρ of the interference wave exceeding the specified level is measured, and the carrier having the smallest ρ is selected (S-48).

As in the case of No (N) in S-43, when the interference wave is equal to or more than the specified level in all the carriers, the same frequency must be shared by a plurality of cells. Therefore, the number Ni of interference waves exceeding the specified interference wave level is counted. The number of cells to be shared can be minimized by selecting the carrier with the smallest Ni.

These are the same as in the first example of the embodiment described above. The difference between the example of the present embodiment and the first example of the above-described embodiment is that, when there are a plurality of cells sharing the same carrier, the carrier with less traffic is selected. Is a point. This is realized by measuring a time rate exceeding a prescribed interference wave level and selecting a carrier having a lower time rate.

FIG. 5 shows (9 stations in the vertical direction × 9 stations in the horizontal direction = 81).
An example of frequency selection at a station is shown below. This is also a result of confirming the operation of the present invention. Nine cells are arranged vertically and horizontally, for a total of 81 cells. These 81 cells share 4 carriers, and the propagation loss is reduced in inverse proportion to the 2.5th power of the distance.
The evaluation by simulation was performed under the condition that (the desired signal power to the interference signal power ratio) was 20 dB.

When the frequency is shared by 81 cells, the same frequency (carrier) can be used between distant cells because no interference occurs. According to the method of the present invention, FIG. , The same frequency is often used in adjacent cells.

On the other hand, as shown in the left side of FIG. 1B, when the conventional technique is applied, the same carrier is rarely selected in the vicinity. The result of comparing the number of interference waves of each cell is the number on the right side of FIG. According to the present invention, it can be seen that there is at most about 10 waves of interference near the center of interference, but there is more than 20 waves of interference in the prior art.

FIG. 6 shows the result of evaluating this with the average number of shared cells of 81 stations. As the required CIR increases, the number of cells that must share the same carrier increases, but it is shown that the number is significantly reduced by the present invention. In a typical system, the required CIR is 1
It is about 5 to 25 dB, and the improvement is high in this range.

The algorithm shown in FIG. 7 was used for evaluation of the prior art. The above evaluation is a result of each cell autonomously selecting a carrier. By thus autonomously selecting a frequency, it is possible to select an optimal carrier according to traffic, that is, according to an interference state.

[0057]

As described above, in a system for performing wireless packet communication, according to the present invention, a small number of frequency resources can be efficiently shared by a plurality of cells. As a result, the frequency utilization efficiency of the system increases, and interference (collision) between packets for the user occurs.
Therefore, there is an advantage that the throughput is increased because of the decrease in

[Brief description of the drawings]

FIG. 1 is a diagram illustrating a basic principle of the present invention.

FIG. 2 is a flowchart showing a first example of an embodiment of the present invention.

FIG. 3 is a flowchart showing a second example of the embodiment of the present invention.

FIG. 4 is a flowchart showing a third example of the embodiment of the present invention.

FIG. 5 is a diagram showing a frequency selection result according to the present invention.

FIG. 6 is a diagram showing the effect of the present invention.

FIG. 7 is a flowchart showing an example of a conventional carrier selection method.

[Explanation of symbols]

S-21-S-28, S-31-S-38, S-41
S-48: Steps indicating frequency selection procedure

Continuation of the front page (58) Field surveyed (Int. Cl. ⁷ , DB name) H04B ^7/ 24-7/26 102 H04Q ^7/ 00-7/38

Claims (3)

(57) [Claims] In a system including a plurality of radio base stations and a mobile station that performs radio communication with them, when there is data to be transmitted in a radio section, the data is transmitted in a slot after the data is generated. In a system for performing time division multiple access in which one wave is selected from a plurality and the frequency is transmitted as a radio packet shared by a plurality of radio base stations or mobile stations, the radio base station is selected by the following method. A beacon that periodically establishes the timing synchronization between the broadcast signal to the mobile station and the radio packet signal at the frequency is transmitted, and the radio base station measures the interference wave levels of all available frequencies, and the interference wave levels are If the level is equal to or lower than the level permitted at all frequencies, the frequency having the highest interference wave level among all the frequencies is selected, and the frequency between the radio base station and the mobile station is selected at that frequency. If the interference wave level measurement result is less than the allowable interference wave level at some but not all frequencies, the interference wave level is the highest among the interference waves at the allowable interference wave level or lower. When a frequency is selected, packet communication is performed between the radio base station and the mobile station at that frequency, and when the interference wave level measurement result is equal to or higher than the allowable interference wave level at all frequencies, the allowable interference wave level The above number of interference waves is counted by receiving the above beacon. If the frequency having the least number of interference waves is one, the frequency is selected and packet communication is performed between the radio base station and the mobile station at that frequency. If the frequency with the least number of interference waves is two or more, select the frequency with the highest interference wave level and perform packet communication between the radio base station and the mobile station at that frequency. A radio packet frequency selection method characterized by the above-mentioned. 2. When there is data to be transmitted in a radio section in a system including a plurality of radio base stations and a mobile station that performs radio communication with them, one of the plurality of radio base stations is transmitted in a slot after the data is generated. In a time division multiple access system in which a wave is selected and the frequency is transmitted as a radio packet shared by a plurality of radio base stations or mobile stations, the radio base station measures interference wave levels of all available frequencies. If the level is below the allowable interference level at all those frequencies, select the frequency with the highest interference level among all the frequencies, and select the frequency between the radio base station and the mobile station at that frequency. If the interference wave level measurement result is less than the allowable interference wave level at some but not all frequencies, the frequency of the interference wave is equal to or lower than the allowable interference wave level. The frequency at which the interference wave level is the highest among the wave numbers is selected, and packet communication is performed between the radio base station and the mobile station at that frequency, and when the interference wave level measurement result is equal to or higher than the allowable interference wave level at all frequencies. In some cases, the time rate at which the interference wave at or above the permissible interference wave level is received at all frequencies or a plurality of frequencies is determined by measuring a predetermined time, and the frequency with the lowest interference wave reception time rate is one wave. In that case, select that frequency and perform packet communication between the radio base station and mobile station at that frequency. If the frequency with the lowest interference wave reception time rate is two or more, the interference wave within that frequency A radio packet frequency selection method, comprising selecting a frequency having the highest level and performing packet communication between the radio base station and the mobile station at that frequency. 3. In a system including a plurality of radio base stations and a mobile station that performs radio communication with them, when there is data to be transmitted in a radio section, the data is transmitted in a slot after the data is generated. In a system for performing time division multiple access in which one wave is selected from a plurality and the frequency is transmitted as a radio packet shared by a plurality of radio base stations or mobile stations, the radio base station is selected by the following method. A beacon that periodically establishes the timing synchronization between the broadcast signal to the mobile station and the radio packet signal at the frequency is transmitted, and the radio base station measures the interference wave levels of all available frequencies, and the interference wave levels are If the level is equal to or lower than the level permitted at all frequencies, the frequency having the highest interference wave level among all the frequencies is selected, and the frequency between the radio base station and the mobile station is selected at that frequency. If the interference wave level measurement result is less than the allowable interference wave level at some but not all frequencies, the interference wave level is the highest among the interference waves at the allowable interference wave level or lower. Select a frequency, perform packet communication between the wireless base station and the mobile station at that frequency, and if the interference wave level measurement result is at or above the allowable interference wave level at all frequencies, exceed the allowable interference wave level The number of interference waves is counted by receiving the above-mentioned beacon, and when the frequency with the least number of interference waves is one, the frequency is selected and packet communication is performed between the radio base station and the mobile station at that frequency, If the frequency with the least number of interference waves is two or more, the frequency with the lowest interference wave reception time rate is selected from those frequencies, and packet communication is performed between the radio base station and the mobile station at that frequency. A radio packet frequency selecting method.