JPH10200948A - Communication system, terminal device and base station device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent re-collision of control signals from plural terminals toward a base station and to improve transmission efficiency by controlling retransmission of control information based on random numbers when the control information is estimated not to be efficiently transmitted. SOLUTION: A terminal to which no communication timing is allocated in spite of generating the control signal of call originating request (S604), the control signal of call receiving request (S608), the control signal of position registration (610) and transmitting these signals (S605) recognizes that the collision occurs when the control signals are transmitted to the base station and fails in transmission to the base station. The terminal which failed in transmission adds one to a value of a counter indicating frequency of the collision, when the value of the counter exceeds a predetermined frequency of the collision (S616), informs a control part that a blocking occurs (S617) and after that, a transmission/reception part is suspended until the next timing of cell scanning (S618). The terminal which passes no frequency of the collision decides whether or not to transmit the control signals in the next timing of scanning by a random number generator (S619).

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is applied to the field of wireless communication such as a portable telephone.

[0002]

2. Description of the Related Art In a wireless communication system such as a cellular system,
A range called a location registration area is set, and when the terminal moves to a different location registration area due to movement, location registration is performed to grasp the approximate location of the terminal. One location registration area usually corresponds to a plurality of cells. The “cell” here refers to a communication area covered by one base station.

A transmission signal from a terminal in a location registration area can be received by any of the base stations in the area. Also, if a simultaneous call is made to the location registration area where the location of the terminal has been registered, the called terminal can be detected.

By the way, in such a system, it is required to reduce the power consumption by suppressing the transmission power of the terminal. For this purpose, it is conceivable to use an antenna with a high gain in the base station.

[0005] However, when a cell is constituted by an antenna having a high gain, the diameter of the cell becomes small. Therefore, an area equivalent to an area of a radio communication system constituted by using an antenna having a low gain is used by using an antenna having a high gain. In order to cover, more cells need to be deployed, which requires more base stations. And
This means that the number of base stations included in one location registration area is increased, and a long time is required for outgoing / incoming call control.

[0006]

Therefore, the present inventors have proposed that a communication area in which communication is possible between a base station and a terminal includes a plurality of cells, and that the base station can operate a beam for each cell. The base station performs a control communication including a communication timing in position registration or information communication in a cell unit with a terminal by sequentially operating an antenna beam for each cell, and Based on this, we proposed a communication system for information communication with terminals. That is,
According to this communication system, in each cell, the beam of the antenna of the base station is sequentially operated, so that the terminal located at an arbitrary position is switched to the cell where the terminal is located within a certain time by the antenna beam of the base station. Since this is set, wireless communication itself becomes possible, and the terminal frequently moves through the cell due to the small diameter of the cell. Since transmission is possible, it is possible to achieve the same effect as simultaneous paging to a location registration area in a general wireless communication system, and further, by sequentially operating an antenna beam to a cell, the presence of a calling terminal and the location of the calling terminal are detected , It is possible to reduce the number of times of communication required for terminal position detection, and to perform wireless communication for mobile terminals without deteriorating transmission efficiency. Can be present, is that.

According to the present invention, the transmission efficiency is further improved in the above-mentioned invention.

[0008] That is, an object of the present invention is to provide a communication system and a terminal device capable of preventing re-collision of control signals from a plurality of terminals to a base station and further improving transmission efficiency.

[0009] It is an object of the present invention to provide a communication system and a base station apparatus capable of further reducing the amount of control information transmitted and improving transmission efficiency.

[0010] Another object of the present invention is to provide a communication system and a base station apparatus that can improve the acquisition rate of mobile terminals.

It is still another object of the present invention to provide a communication system and a base station apparatus that can achieve a reduction in a forced disconnection rate.

[0012]

In order to solve the above-mentioned problems, a communication system according to the present invention is characterized in that a base station directs a beam to a plurality of cells sequentially, and the cell is directed at the timing when the beam is directed. A communication system for communicating control information and real information with a nearby terminal, comprising: estimating means for estimating whether control information destined for the base station from the terminal has been transmitted; and a random number for generating a random number. Generating means, and means for controlling retransmission of the control information based on a random number generated by the random number generating means when it is estimated that the control information is not effectively transmitted from the terminal to the base station by the estimating means. .

The "cell" in the present invention does not correspond one-to-one with a base station. That is, a plurality of cells correspond to one base station. However, it is also possible that a plurality of cells correspond to a plurality of base stations, for example, two to twenty.

To direct a beam to a cell means, for example, to direct a beam of a beam antenna capable of changing the direction of the gain and directivity to the cell, and to make the reception electric field strength of a terminal in the cell equal to or higher than a predetermined value. The direction of directivity can be represented by a diameter and a phase in a polar coordinate system. The directivity can be varied in the radial direction and / or the phase direction in the polar coordinate system. Varying the gain is particularly required when varying the beam in the phase direction in the polar coordinate system. When the beam is shaken far, higher gain is required to make the reception electric field strength of the terminal equal to or higher than a predetermined value, and when the beam is shaken close, the reception electric field intensity is equal to or higher than the predetermined value. This is because a wide beam, that is, a lower gain is required. However, the gain can be fixed.

The communication of control information includes, for example, communication for incoming and outgoing calls in addition to communication timing in location registration and information communication in units of cells.

The real information is, for example, voice information or data information which is the purpose information of the actual communication. The estimating means estimates, for example, a collision of control information. This estimation is performed, for example, by assuming that a collision has occurred when predetermined control information expected on the terminal side is not transmitted from the base station. However, it goes without saying that other methods may be used, and that the base station side may estimate the collision.

The random number may be generated on either the terminal side or the base station side.

Controlling retransmission of control information based on random numbers means
For example, it refers to canceling retransmission when the random number has a predetermined value.

According to the present invention, when it is estimated that control information is not effectively transmitted from the terminal to the base station, retransmission of control information is controlled based on a random number, so that a plurality of connection requesting terminals exist in the same cell. As a result, it is possible to reduce the discard of the control signal caused by the above, and it is possible to further improve the transmission efficiency. In addition, even when a plurality of stationary terminals exist in the same cell, connection failure due to steady collision can be avoided, and a control signal can be transmitted. Furthermore, if a control signal such as a call request is transmitted to the base station, the base station can adjust the antenna directivity to the cell in which the terminal exists, so that wireless communication with reduced transmission power of the terminal can be realized. It becomes possible.

According to a second aspect of the present invention, there is provided a terminal device comprising:
A timing setting means for setting a timing in a second period for performing communication of real information with the base station during the period, and the base station and the base station at the set timing in the second period. And means for controlling resetting of the timing based on the generated random number when the timing setting means fails to set the timing.

The terminal device of the present invention is used, for example, in the communication system of claim 1. The random number may be generated by the terminal device itself, or may be generated by the base station.

According to a third aspect of the present invention, there is provided a communication system comprising:
A communication system in which a base station sequentially directs a beam to a plurality of cells, and performs communication of control information and real information with a terminal near the cell at a timing at which the beam is directed, wherein the base station passes the plurality of cells. Means for estimating the mobility of the terminal to perform, and means for controlling the timing relating to the actual information based on the estimated mobility.

The mobility of the terminal is grasped by position information obtained by a control signal transmitted from the terminal to the base station, for example.

In the communication system according to the present invention, the terminal frequently moves between cells due to the small cell area. However, the base station can know the frequency of cell movement from past position information of the terminal, for example. it can. Since the base station can grasp the mobility of the terminal, for example, it is possible to allocate the communication timing optimally, thereby making it possible to reduce the control information for capturing the terminal.

According to a fourth aspect of the present invention, a base station apparatus according to the present invention directs a beam to each of a plurality of cells, and communicates control information and actual information with terminals near the cell at the timing of directing the beam. The base station apparatus includes: a unit for estimating a mobility of a terminal passing through the plurality of cells; and a unit for controlling the timing related to the actual information based on the estimated mobility.

The base station apparatus according to the present invention is used, for example, in a communication system according to claim 3.

The communication system according to the fifth aspect of the present invention provides:
A communication system in which a base station sequentially directs a beam to each of a plurality of cells, and performs communication of control information and actual information with a terminal near the cell at a timing at which the beam is directed. The system includes means for estimating the amount of real information transmitted from the terminal to the base station, and means for controlling a communication allocation amount for the real information based on the estimated amount of real information. Information about the amount of actual information transmitted from the terminal to the base station can be transmitted to the base station by, for example, a control signal transmitted from the terminal to the base station.

Here, if the communication time is long, the movement time of the terminal becomes long, so that the occurrence of movement between cells increases.
In the present invention, since the base station can estimate the frequency of occurrence of inter-cell movement, it is possible to optimize, for example, communication timing allocation, and consequently reduce the amount of control information transmission.

According to a sixth aspect of the present invention, there is provided a base station apparatus for sequentially directing a beam to each of a plurality of cells, and communicating control information and actual information with terminals near the cell at the timing of directing the beam. A base station device for performing, based on the control information, means for estimating an amount of real information transmitted from the terminal to the base station; and a communication allocation amount for the real information based on the estimated amount of real information. Means for controlling the

The base station apparatus according to the present invention is used, for example, in a communication system according to claim 5.

The communication system of the present invention according to claim 7 is
A communication system in which a base station sequentially directs a beam to each of a plurality of cells, and performs communication of control information and actual information with a terminal near the cell at a timing at which the beam is directed. Means for detecting the position of the cell in which the terminal is located for a terminal newly belonging to the communication area of the base station during the first period for performing, and a second for performing communication of the control information. Means for confirming the position of the cell in which the terminal is located for a terminal already belonging to the communication area of the base station during the period.

According to the present invention, by using the cell position confirmation together, for example, once the connection request transmission is achieved in the cell scan, it is not necessary to reserve the line again by random access. Thus, the transmission efficiency can be improved, and the transmission efficiency can be further improved.

According to the eighth aspect of the present invention, the base station apparatus sequentially directs a beam to each of a plurality of cells, and communicates control information and real information with a terminal near the cell at the timing when the beam is directed. A base station apparatus for performing, during a first period for performing communication of the control information, a terminal newly belonging to a communication area of the base station, for detecting a position of a cell in which the terminal is located. And a means for confirming the location of the cell in which the terminal is located for a terminal already belonging to the communication area of the base station during the second period in which the control information is communicated.

[0034] The base station apparatus of the present invention is used, for example, in a communication system according to claim 7.

[0035]

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

FIG. 1 is a diagram schematically showing a communication system according to one embodiment of the present invention. In FIG. 1, 1 is a base station, and 2 is a terminal. The base station 1 can communicate with the terminal 2 in the communication area 3. The communication area 3 includes a plurality of cells 4, 4,..., And the base station 1 has an antenna 6 capable of operating a beam 5 for each cell 4.

FIG. 2 shows an example of cell arrangement in the communication system according to the embodiment. FIG. 2 shows the communication area 3
Is a range of an angle of, for example, a maximum of 100 m and 60 degrees from the base station 1.

By changing the beam 5 of the antenna 6 of the base station 1, that is, the directivity direction and the gain of the antenna 6, the cells are arranged so that the received electric field strength becomes a predetermined value or more in all of the communication areas 3. . Here, communication area 3
Is composed of, for example, 201 cells.

Further, in order to make the reception electric field strength equal to or more than a predetermined value in all the cells 4 in the communication area 3, the base station 1
The antenna gain for the farther cell 4 is set high. On the other hand, in the cell 4 close to the base station 1, the distance to the base station 1 is short, and the propagation loss is smaller than that in the distant cell.
The antenna gain is set small.

Each cell has a unique number (4 ₁ to 4 ₁ ).
4 _n ), and 1 to n coincide with the cell numbers added to the signal transmitted from the base station 1 to the terminal 2 at the time of cell scanning described later.

FIG. 3 is a diagram showing a configuration of a frame of a transmission / reception signal between the base station 1 and the terminal 2.

As shown in FIG. 3A, one frame is
Cell scan period 7 as a period for communicating control information
And a communication timing assignment period 8 and an information communication period 9 as a period for performing communication of real information.

In the cell scan period 7, in order to register a location between the base station 1 and the terminal 2, detect a terminal call, and notify the terminal of a call, the antenna beam for each cell is sequentially operated, that is, the cell is scanned. . Cell scan period 7 is
Determined from the allowable values of call connection delay and communication delay. Reducing the delay time can be achieved by shortening the interval between cell scans, but this is a trade-off with transmission efficiency. If the cell scan period 7 is fixed and scanning is performed periodically, the terminal 2 can receive a signal only at the time of scanning, and can perform intermittent reception with a shorter reception period. Therefore, this contributes to lower power consumption of the terminal 2.

The calling terminal transmits a terminal calling request to the base station 1 when scanning a cell. Since the base station 1 knows to which cell the antenna beam is directed, it can know the position of the calling terminal. The terminal 2 exists in an arbitrary cell (position) in the area, and moves from one cell to another. However, the terminal 2 can grasp the position by performing scanning. The base station 1 that has received the terminal call request allocates communication timing to the calling terminal in the communication timing allocation period 8. Then, in the information communication period 9, information communication is performed between the call requesting terminal or the called terminal and the base station 1 based on the communication timing. For example, in the communication timing allocation period 8, when the base station 1 allocates the period A in the information communication period 9 as the communication timing to the terminal 2 that made the call, the base station 1 transmits the beam of the antenna 6 of the base station 1 in the period A. Is directed to the cell in which the calling terminal 2 is located. Then, information communication is performed between the terminal 2 and the base station 1.

FIG. 3B shows details of the cell scan period 7.

As shown in FIG. 3B, the cell scan period 7 includes, for example, n (n = the number of cells, 201 in the example of FIG. 2) beam periods 10 ₁ to 10 _n. You. The base station 1 sets the beam of the antenna 6 of the base station 1 in the direction of each of the cells 4 ₁ to 4 _n in each of the beam periods 10 ₁ to 10 _n (see FIG. 2). For example a beam of the antenna 6 is set in the direction of the cell 4 ₁ in the beam period 10 _1, in the beam period 10 ₂ sets the beam of the antenna 6 in the direction of the cell 4 _2, the beam period 10 ₃ antennas 6 It is set the beam direction of the cell 4 _3.
Each of the beam periods 10 ₁ to 10 _n corresponds to a transmission period Tx in which the base station 1 transmits a control signal to the terminal 2 and a base station 1
Is a reception period Rx during which a control signal is received from the terminal 2.

[0047] Then, the base station 1 first, the beam of the antenna 6 is set in the direction of the cell 4 ₁ in the beam period 10 ₁ at the time of cell scan cell 4 in the transmission period Tx
A control signal is transmitted to _one terminal 2. Terminal 2 present in the cell 4 ₁ receives a control signal from the base station 1, transmits a control signal to the base station 1 in the reception period Rx. Hereinafter, the same operation is sequentially performed on each cell.

In the radio communication system that suppresses the transmission power of the terminal, the transmission from the terminal is not transmitted to the base station unless the direction of the beam of the antenna of the base station is set to the position where the terminal is located. According to this embodiment, the terminal 2 changes the beam direction of the antenna 6 of the base station 1 if the received electric field strength when receiving the transmission signal from the base station 1 is equal to or greater than the threshold (or equal to or greater than the reception sensitivity). It is determined that the terminal 2 is set at the existing position. This allows wireless communication with the base station 1 even if the transmission power of the terminal 2 is suppressed. Further, if the cell scan period 7 is provided periodically at regular intervals, the terminal 2 does not need to constantly monitor the signal from the base station 1. Further, since the above cell scan is performed for all cells 4 in the communication area 3, the terminal 2
Wireless communication with the base station 1 is possible even if is located at an arbitrary position in the communication area 3.

FIG. 4 shows a control flow of the base station 1.

The base station 1 first detects the position of the terminal 2 by scanning a cell.

Next, the base station 1 can recognize the cell number where the connection requesting terminal exists. Communication timing is assigned to the connection requesting terminal. In the communication timing assignment, first, the beam of the antenna 6 is set in the direction corresponding to the cell in which the terminal A is located, and then the communication timing is notified. Hereinafter, the terminal B, C... Are similarly notified.
Then, the process proceeds to the specific terminal communication in the information communication period 9. In the specific terminal communication, the beam of the antenna is set in the direction corresponding to the cell number where the terminal A is located, and thereafter communication with the terminal A is performed. Hereinafter, communication is similarly performed with respect to the terminals B, C,.

FIG. 5 is a block diagram showing an example of the transmitting section of the terminal 2.

Reference numeral 11 in FIG. 5 is a request signal for transmitting a control signal. In the control unit 12, the transmission request signal 1
When 1 is received, the random number generator 13 is operated. The random number generator 13 generates a signal of “0” or “1”. The output 14 from the random number generator is input to the control unit 12, and determines whether to operate the control signal generation circuit 15 based on the random number.

When the control signal generation circuit 15 operates (for example, when the output 14 is “1”), the output from the control signal generation circuit 15 is input to the transmitter 16. The transmitter 16 performs modulation, frequency conversion to a desired RF band, and
It is amplified to power. The output from the transmitter 16 is radiated from the antenna 17. On the other hand, when the control signal generation circuit 15 is not operated (when the output 14 is “0”), no signal is input to the transmitter 16.

The occurrence probability (occurrence distribution) of “1” of the random number generator 13 may be a fixed value or may be transmitted from the base station 1. It is also possible to transmit the threshold value of the uniform random number from the base station 1. Further, it is also possible that the base station 1 transmits random number information to the terminal 2 and the terminal 2 generates a random number by performing an operation on the terminal ID and the random number information.

FIG. 6 is a flowchart showing the operation of the terminal 2 configured as described above.

The terminal 2 operates the transmission / reception unit before the cell scan timing (start-up time of the transmission / reception unit) (step 601), and prepares a system capable of receiving a signal from the base station 1. If the base station 1 performs the cell scan periodically, the terminal 2 can operate the transmitting / receiving unit only at the time of the cell scan, which contributes to lower power consumption.

When the calling terminal, the called terminal, and the location registration terminal receive the cell scan signal from the base station 1 at the time of cell scanning (step 602), they transmit to the base station 1. That is, when the terminal 2 makes a call request (step 603), a control signal for the call request is generated (step 6).
04), the control signal is transmitted to the base station 1 (step 605), and the procedure shifts to receiving a communication timing assignment signal (step 606).

The terminal 2 whose called terminal ID included in the control signal from the base station 1 matches its own ID (step 60)
7) Generate a control signal for the incoming call response (step 60).
8) The control signal is transmitted to the base station 1 (step 605), and the procedure shifts to receiving a communication timing assignment signal (step 606).

If the terminal 2 differs from the previously received base station ID (step 609), the terminal 2 determines that it is necessary to update the location registration area, and generates a location registration control signal (step 609). 610), the control signal is transmitted to the base station 1 (step 605), and the procedure shifts to receiving a communication timing assignment signal (step 606).

FIG. 7 shows control signals generated in this manner. The control signal includes an ID indicating the type of the control signal (call request, call notification response, location registration request), an ID of the own terminal,
It consists of other information (quality of service (QOS), terminal mobility, amount of information to be transmitted, etc.).

The terminal 2 that has transmitted such a control signal,
A signal transmitted from the base station 1 at the time of communication timing allocation is monitored, and if the terminal ID included in the signal matches the own ID, it is determined that communication timing has been allocated (step 611). The signal transmitted from the base station 1 when the communication timing is allocated includes an ID indicating the type of the control signal, a cell number, an ID of the base station, an ID related to communication timing, an ID of a mobile terminal, and other information.

Terminal 2 that has received the communication timing assignment notification transmits a response signal to base station 1 (step 612). Thereafter, the location registration terminal suspends the transmission / reception unit until the timing of the next cell scan (step 6).
13, 614). The calling terminal and the called terminal communicate with the base station 1 at the notified timing (steps 613 and 615).

The terminal 2 to which the communication timing has not been assigned despite transmitting the control signal, reports that a collision has occurred when transmitting the control signal to the base station 1 and the transmission to the base station 1 has failed. recognize. The transmission failure terminal 2 increments the value of the counter indicating the number of collisions by +1. When the predetermined number of collisions has elapsed (step 616), the terminal 2 notifies the control unit of the terminal 2 that blocking has occurred (step 616). 617) Then, the transmission / reception unit is suspended until the timing of the next cell scan (step (618). The terminal 2 whose collision count has not elapsed uses the random number generator 13 to determine whether to transmit a control signal at the next scan timing. (Step 619).

As described above, the probability of transmitting the control signal from the terminal 2 to the base station 1 can be made random, and the frequency of discarding the control signal transmitted from the terminal 2 to the base station 1 during cell scanning. Can be suppressed.

Here, the reason why the control signal transmitted from the terminal 2 to the base station 1 is discarded will be described with reference to FIG.

In this system, the cell scan period 7
A cell scan is performed (see FIG. 3). When the received electric field strength at the time of receiving the control signal from base station 1 is equal to or greater than the threshold value and the received signal includes an ID indicating cell scan, terminal 2 Is determined to be set at the position where the terminal exists, and transmission to the base station 1 is performed.

However, the terminal 2 is located at a position as shown in FIG.
If there are _A and terminal 2 _B, each of the terminals 2 _A, 2 _B outputs a control signal to the base station 1, a collision occurs,
The control signal is discarded. That is, if there are a plurality of terminals 2 that transmit control signals in the same cell, the control signals are discarded due to collision. In a mobile terminal, transfer of a control signal to a different cell may be achieved, but in a stationary terminal, the control signal is discarded forever.

On the other hand, according to the present invention, it is possible to prevent a collision from occurring permanently. The frequency of occurrence of discards due to control signal collisions varies depending on the number of terminals in the area and the reception sensitivity of the terminals. The increase in discards due to the increase in the number of terminals in the area is obvious. As shown in FIG. 9, the reason for the increase in discard due to the improvement of the reception sensitivity of the terminal is that the area where the terminal 2 transmits the control signal to the base station 1 is (2).
(From 0 to 21). That is, the probability of discarding the control signal varies due to the variation in the receiving sensitivity of the terminal 2. According to the present invention, as described above, the occurrence probability of “1” of the random number generation circuit 13 can be controlled from the base station 1, whereby the transmission from the terminal 2 to the base station 1 at the time of cell scan is performed. Since it is possible to change the frequency of occurrence of discarded control signals, it is possible to absorb variations in the probability of collision occurrence due to variations in terminal reception sensitivity.

Next, a communication timing allocating method according to the present invention will be described with reference to FIG.

The base station 1 can grasp the position of the communicating terminal 2 by cell scanning. Therefore, the mobility of the terminal 2 can be known by calculating the difference between the existing positions of the terminal 2 during the cell scan. In this system, instead of transmitting the position information of the terminal 2 every time the cell moves, the terminal 2 scans the cell periodically.
By obtaining the position, the control signal required for capturing the movement (detecting the position of the terminal 2) is reduced.

In order to cope with the terminal 2 moving at high speed, it is necessary to shorten the cell scan interval, but this causes a reduction in transmission efficiency. Therefore, in the present system, communication between the terminal 2 and the base station 1 is performed during a period from the cell scan to the next cell scan. However, as the time elapses from the cell scan, the moving terminal 2 has a higher probability of leaving the cell.

Therefore, as shown in FIG.
Calculates the mobility using the difference between the terminal positions obtained in the cell scan period 7, and allocates communication timings with different lapses from the cell scan period 7 to each terminal 2 according to the mobility.

For example, the period D in the information communication period 9 in which the time lapse from the cell scan period 7 is short is assigned to the terminal 2 which moves fast, and the period F in the information communication period 9 in which the time lapse from the cell scan period 7 is long moves slowly. Terminal 2
Assign to

The communication timing is notified in the communication timing allocation period 8.

The operation flow of base station 1 in this case is shown in FIG.
Shown in

That is, the base station 1 has a terminal location information file for managing the location information of each terminal 2, and obtains the location of each terminal 2 by scanning the cell periodically (step 1101). The location information file is updated (step 1102). Then, the mobility of each terminal 2 is obtained from the difference in the location information of the terminal location information file (step 1103), and communication timings having different time lapses from the cell scan period 7 are assigned to each terminal 2 according to the mobility. (Step 1104), the communication timing is notified to each terminal 2 using the communication timing allocation period 8 (Step 1105).

As described above, depending on the mobility of the terminal 2,
By allocating communication timings with different lapses of time from the cell scan period 7, it is possible to suppress the probability that the terminal 2 will deviate from a cell existing at the time of scanning before the allocated communication timing. For example, FIG. 12 shows the probability that the terminal 2 exists in the previously registered cell with respect to the elapsed time from the cell scan. From this, it can be seen that the effective use of the wireless communication channel can be achieved by assigning the terminal 2 having a high mobility to the specific terminal communication timing in which the elapsed time from the cell scan is short.

Note that the terminal 2 can obtain the position information from the information transmitted from the base station 1 at the time of cell scanning, so that the terminal 2 itself can know the mobility, and A method of reporting to the Bureau 1 is also possible.

The mobility information reported by the terminal 2 is calculated from the position information from the base station 1 described above,
It is also possible to use the mobility measurement means (speedometer, GPS information, etc.) possessed by.

Next, still another communication timing allocating method according to the present invention will be described with reference to FIG.

As described above, in this communication system, as time elapses from the cell scan, terminal 2
Is less likely to be present in cells that existed at the time of scanning. Therefore, in this communication system, as shown in FIG. 13, communication timing is assigned according to the amount of information transmitted by the terminal 2.

For example, the period G in the information communication period 9 in which the time lapse from the cell scan period 7 is short is allocated to the terminal 2 having a small amount of information, and the period I in the information communication period 9 in which the time lapse from the cell scan period 7 is long is determined as the information amount. Is assigned to the terminal 2 having the largest number.

The operation flow of base station 1 in this case is shown in FIG.
Shown in

The base station 1 has a terminal information amount file for managing the information amount of each terminal 2, and obtains the information amount from each terminal 2 by scanning the cell periodically (step 14).
01), the terminal information amount file is updated (step 1402). After such a cell scan, the base station 1 sorts the communication information amount reported from the terminal in descending order. After that, a terminal having a small amount of information is assigned to a specific terminal communication timing having a short elapsed time from the cell scan (step 1403). Then, the communication timing is notified to each terminal 2 using the communication timing allocation period 8 (step 1404).

According to this communication system, the terminal 2 with a small amount of information is assigned to the communication timing with a short elapsed time from the cell scan, so that the terminal 2 with a small amount of information has a high probability of existence in the cell. , The probability of terminating the communication increases. Therefore, the number of continuous connection requests during the next cell scan is reduced, so that the amount of control signal transmission can be reduced, and as a result, the probability of collision occurrence can be reduced. That is, the probability of collision occurrence is reduced by reducing the number of terminals reserved for uplink random access.

Further, according to this system, the base station 1 manages the assignment of the communication timing, so that the bandwidth of the line can be managed by the quality of service (QOS).
In other words, it is possible to handle dynamically changing traffic, and it is also possible to provide a variable bandwidth service in which the information transmission amount changes with time.

It is also possible to raise or lower the priority of communication timing assignment of the terminal 2 once assigned, thereby making the assignment fair.

Next, a control signal transmission method according to the present invention will be described with reference to FIG.

This system includes, in one frame, a cell scan period 7 and a communication timing assignment period 8 as a period for communicating control information, and an information communication period 9 as a period for communicating actual information. The specific terminal scan period 31 is provided at the beginning of each period of the communication period 9.

The specific terminal scan period 31 is performed to detect the position of the called terminal or the terminal 2 that has made the call request during communication.

In such a communication system, the position of the terminal 2 is detected during the cell scan period 7, but the terminal having a high moving speed has a high probability of being out of the cell during one frame (one cell scan interval). In order to reduce the deviation from the cell, it is only necessary to shorten the one-cell scan interval, but this degrades the transmission efficiency.

According to the present invention, the position of an unspecified (still unknown) terminal 2 is detected by the cell scan period 7, and the terminal 2 is tracked (detection of movement between cells) by the specific terminal scan period 31. )I do.

As described above, by using the cell scan period 7 and the specific terminal scan period 31 together, it is possible to reduce the amount of control signal transmission required for detecting the position of the terminal 2.

That is, the calling terminal 2 transmits a signal to the base station 1 during the cell scan period 7 to notify the base station 1 of the terminal position. The notification of the terminal incoming call is performed in the cell scan period 7. The terminal 2 notified of the incoming call from the base station 1 transmits a signal to the base station 1. Thereby, the position detection of the terminal 2 is achieved. For the terminal 2 to which the communication request has been transmitted once, the position is detected in the specific terminal scan period 31 thereafter.

FIG. 16 shows a frame configuration in the specific terminal scan period 31. FIG. 17 shows the beam area arrangement of FIG.

When the mode shifts to the specific terminal scan mode, first, a beam is set in the position registration beam area of the terminal A (beam A701). The base station 1 notifies the terminal A that the scan is a specific terminal scan (designates the terminal A and transmits it), and the terminal A returns a response signal to the base station 1.

Next, the base station 1 sets a beam in the position registration beam area of the terminal B (beam B702). The base station 1 notifies the terminal B that it is a specific terminal scan. If there is no response from the terminal B in the next slot, scanning is performed sequentially around the beam area of the terminal B registered previously. That is, the base station 1 scans the beam area (beam B1 703, beam B2 704,...) Around the beam B702 until there is a response from the terminal B. In FIG. 16, a response signal from the terminal B is received at the time of the beam B4 706, and the location registration data of the terminal B is updated.

After receiving the response signal from the terminal or completing the search of all the beam areas around the previously registered beam area, the process proceeds to the next terminal position detection.

By providing the specific terminal scan period 31 as described above, it is possible to improve the capture rate of mobile terminals, and furthermore, it is possible to extend the interval of the cell scan period 7, thereby improving the transmission efficiency. . Further, once the connection request is transmitted in the cell scan, random access is eliminated, so that the forced disconnection rate can be reduced as compared with the above-described method.

The specific terminal scan period 31 can be set any number of times at any time. Increasing the set number of times (that is, increasing the number of specific terminal scans) increases the probability of capturing a mobile terminal, but decreases transmission efficiency. These are, of course, in a trade-off relationship.

Next, another method of capturing a terminal in the specific terminal scan period 31 will be described with reference to FIG.

In the specific terminal scan period 31, a base station antenna beam is set for the registered cell of the terminal, and a signal indicating that the base station is performing the specific terminal scan and the I / O signal of the terminal are set.
A signal indicating D is transmitted, and the terminal returns a response signal to the signal to grasp the terminal position (terminal capture).

FIG. 18 shows that if no terminal exists in a cell in which a terminal has been previously registered, it is checked whether or not a terminal exists in a cell registered for all terminals. 1 shows an example of scanning around
In the examples of FIGS. 5 to 16, when the terminal is not present in the previously registered cell, scanning is performed before confirming the presence of the next terminal.) In the specific terminal scan, when the terminal is not in the previously registered cell, a cell search is performed to acquire the terminal. Therefore, the time required for the specific terminal scan period 31 varies. Therefore, in the frame configuration shown in FIG. 18, the minimum value of the time required for the specific terminal scan period 31 is set, and the terminal that has shifted to the specific terminal scan mode always receives a signal from the base station 1 during this period. . As a result, the terminal existing in the previously registered cell is always captured. That is, intermittent reception of the specific terminal scan period 31 is possible.

[0105]

As described above, according to the present invention, it is possible to reduce discard of a control signal caused by a plurality of connection requesting terminals existing in the same cell. For this reason, even when a plurality of stationary terminals exist in the same cell, connection failure due to steady collision can be avoided, and a control signal can be transmitted. If a control signal such as a call request is transmitted to the base station, the base station can adjust the antenna directivity to the cell in which the terminal exists, so that it is possible to realize wireless communication with reduced transmission power of the terminal. .

Further, in the present invention, since the optimum communication timing is assigned based on the mobility and the amount of information of the terminal, it is possible to reduce the control information for capturing the mobile terminal.

Further, according to the present invention, by simultaneously using the cell position confirmation, for example, once the connection request transmission is achieved in the cell scan, it is not necessary to reserve the line again by random access. A reduction in the disconnection rate and an improvement in the terminal capture rate can be achieved, and the transmission efficiency can be further improved. In addition, a reduction in the forced disconnection rate and an improvement in the capture rate of mobile terminals can be achieved.

As described above, a control signal transmission system capable of high-speed demand assignment control can be realized, and a base station can handle dynamically changing traffic in order to allocate communication timing. Can also be provided.

[Brief description of the drawings]

FIG. 1 is a diagram schematically illustrating a communication system according to an embodiment of the present invention.

FIG. 2 is a diagram illustrating an example of an arrangement of cells in a communication system according to an embodiment.

FIG. 3 is a diagram illustrating a configuration of a frame of a transmission / reception signal according to the embodiment;

FIG. 4 is a diagram showing an example of a control flow of a base station in one embodiment.

FIG. 5 is a block diagram illustrating an example of a transmission unit of the terminal according to the embodiment.

FIG. 6 is a flowchart illustrating an operation of the terminal according to the embodiment.

FIG. 7 is a diagram illustrating an example of a control signal according to the embodiment;

FIG. 8 is a diagram for explaining the reason why a control signal transmitted from a terminal to a base station is discarded.

FIG. 9 is a diagram for explaining a reason for an increase in discarding due to an improvement in reception sensitivity of a terminal.

FIG. 10 is a diagram for explaining a communication timing allocating method according to the present invention.

FIG. 11 is a diagram illustrating an example of a control flow of a base station in one embodiment.

FIG. 12 is a diagram illustrating a probability that a terminal is present in a cell registered earlier with respect to an elapsed time from a cell scan.

FIG. 13 is a diagram for explaining still another communication timing assignment method according to the present invention.

FIG. 14 is a diagram illustrating an example of a control flow of a base station in one embodiment.

FIG. 15 is a diagram for explaining a control signal transmission method according to the present invention.

FIG. 16 is a diagram illustrating a frame configuration during a specific terminal scan period according to an embodiment.

FIG. 17 is a diagram showing the beam area arrangement of FIG. 16;

FIG. 18 is a diagram for explaining another terminal capturing method based on a specific terminal scanning period according to the present invention.

[Explanation of symbols]

Reference Signs List 1 base station 2 terminal 3 communication area 4 cell 5 beam 6 antenna 7 cell scan period 8 communication timing assignment period 9 information communication period 10 ₁ to 10 _n beam period 12 control unit 13 random number generator 15 control signal generation circuit 16 transmitter 17 antenna

Claims (8)

[Claims] 1. A communication system in which a base station sequentially directs a beam to each of a plurality of cells, and communicates control information and real information with a terminal near the cell at a timing at which the beam is directed, Estimating means for estimating whether or not control information from the terminal to the base station has been transmitted; random number generating means for generating a random number; estimating means estimating that control information is not effectively transmitted from the terminal to the base station. And a means for controlling retransmission of the control information based on the random number generated by the random number generating means. 2. A timing setting means for setting a timing in a second period for performing communication of real information with a base station during a first period, wherein the timing setting unit sets the timing in the second period. Means for performing communication of real information with the base station at timing, and means for controlling resetting of the timing based on a generated random number when the timing setting means fails to set the timing. A terminal device comprising: 3. A communication system in which a base station directs a beam to each of a plurality of cells sequentially, and performs communication of control information and real information with a terminal near the cell at a timing at which the beam is directed, A communication system comprising: means for estimating the mobility of a terminal passing through a plurality of cells; and means for controlling the timing related to the actual information based on the estimated mobility. 4. A base station apparatus for sequentially directing a beam to each of a plurality of cells and performing communication of control information and real information with a terminal near the cell at a timing at which the beam is directed, A base station apparatus comprising: means for estimating the mobility of a terminal passing through a cell; and means for controlling the timing relating to the actual information based on the estimated mobility. 5. A communication system in which a base station sequentially directs a beam to each of a plurality of cells, and communicates control information and real information with a terminal near the cell at a timing at which the beam is directed, Means for estimating the amount of real information transmitted from the terminal to the base station based on control information; and means for controlling a communication allocation amount for the real information based on the estimated amount of real information. A communication system characterized by the above-mentioned. 6. A base station apparatus for sequentially directing a beam to each of a plurality of cells and performing communication of control information and real information with a terminal near the cell at a timing at which the beam is directed, the control station comprising: Means for estimating the amount of real information transmitted from the terminal to the base station based on the information, and means for controlling a communication allocation amount for the real information based on the estimated amount of real information. Base station device. 7. A communication system in which a base station sequentially directs a beam to each of a plurality of cells, and communicates control information and real information with a terminal near the cell at a timing at which the beam is directed, A terminal newly belonging to the communication area of the base station during a first period in which control information is communicated,
Means for detecting the position of the cell in which the terminal is located, and for a terminal already belonging to the communication area of the base station, A communication system comprising: means for performing position confirmation. 8. A base station apparatus for sequentially directing a beam to each of a plurality of cells and communicating control information and real information with a terminal near the cell at a timing at which the beam is directed, the control station comprising: For a terminal newly belonging to the communication area of the base station during the first period for performing the communication of
Means for detecting the position of the cell in which the terminal is located, and for a terminal already belonging to the communication area of the base station, A base station device comprising: means for performing position confirmation.