JP3507826B2 - Communication regulation control method in communication system, and communication system and receiving apparatus using the same - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication regulation control method used for regulation control of transmission and reception of data signals in a communication system such as a fixed telephone network and a mobile communication network, and a communication system and a receiving apparatus using the same. Is.

[0002]

2. Description of the Related Art In a communication system using a fixed telephone network, a mobile communication network or the like, depending on the communication status (transmission / reception status) of data signals, per unit time (for example, per second) transmitted from a transmitting node to a receiving node. In some cases, the number of data items in 1) increases and a congestion state occurs.

On the other hand, in order to prevent the communication from becoming unstable and the communication quality from deteriorating due to the occurrence of congestion, FIG.
As shown in (a) to (c), communication regulation control is performed to regulate the transmission of the data signal from the transmission node according to the number of received data of the data signal received by the reception node.

In communication regulation control in a communication system including a transmitting node A and a receiving node B, first, a data signal transmitted from the transmitting node A is received by the receiving node B, and at the receiving node B per unit time. The number of data received is detected (FIG. 5A). And
When it is determined that the communication status from the transmitting node A to the receiving node B is in a congestion state, the receiving node B sends a regulation control request signal to the transmitting node A (FIG. 5).
(B)). The transmission node A performs regulation control on the transmission of the data signal in response to the regulation control request from the reception node B, thins out the data signal, and transmits the data signal (FIG. 5C).

[0005]

In the communication regulation control of data signals as shown in FIGS. 5 (a) to 5 (c), a regulation level for the constant monitoring period and the number of received data per unit time is conventionally used. Is set in advance, and the number of received data is monitored and the regulation of data signal transmission is controlled based on these settings.

FIG. 6 is a flow chart showing a conventional communication regulation control method in a communication system. here,
It is assumed that the receiving node B is a data storage node that stores the data from the transmission node A and delivers the data to a predetermined delivery destination as necessary.

First, the receiving node B, which is a data storage node, receives a data signal from the transmitting node A (step S501). The received data signal is distributed to a predetermined distribution destination if the distribution is possible, and is accumulated in the receiving node B as standby data if the distribution is impossible (S502).

Next, the number X of received data per unit time is detected for each monitoring cycle with respect to a preset constant monitoring cycle T (S503). Further, when the restriction control based on the number of standby data is simultaneously performed, the number of standby data accumulated in the receiving node B is also detected. Then, the received data number and the standby data number obtained in the monitoring cycle are compared with the regulation levels set as the regulation thresholds for the received data number and the standby data number, respectively (S504), and the regulation is strengthened or deregulated. to decide.

That is, when either the number of received data or the number of standby data exceeds the regulation level (S505)
On the other hand, it is assumed that the node is in the congestion state, and the restriction control for strengthening the restriction on the transmission of the data signal from the transmission node A is performed. The receiving node B sends to the transmitting node A a regulation control request signal for thinning regulation of data signal transmission (for example, thinning 50%) (S506). On the other hand, when both the number of received data and the number of standby data are below the regulation level (S507), regulation control is performed to relax the regulation on the transmission of the data signal from the transmission node A. The receiving node B sends a regulation control request signal for deregulation (thinning 0%) to the transmission node A (S508).

FIG. 7 is a graph showing an example of the communication status in the communication system when the communication regulation control method shown in FIG. 6 is applied. In this graph, the horizontal axis is time,
The vertical axis represents the number of data received at the receiving node B per unit time.

Here, as a regulation level used for regulation control by the number of received data, 50% regulation level X _50%
Is set. The regulation level X _50% is a regulation threshold value for making a regulation control request to thin out the transmission of the data signal from the transmission node A at 50%. The monitoring cycle for the number of received data is a fixed cycle T (= T ₁ , T ₂ , ...).
Is set to.

First, in the monitoring cycle T ₁ , the number of received data X ₁ per unit time is detected and compared with the regulation level X _50% . In the example shown in FIG. 7, the number X ₁ of received data exceeds the regulation level X _50% (X ₁ > X _50% ). For this reason,
At time t ₁ , the receiving node B sends a restriction control request signal requesting the restriction control (restriction) of the thinning 50% to the transmitting node A.

In the monitoring cycle T ₂ , since the 50% regulation control is performed, the number of received data items thinned out by half (solid line) is below the regulation level X _50% . Similarly, in this monitoring cycle T ₂ , the number of received data X ₂ (dotted line) is detected and compared with the regulation level X _50% . In this example, the number of received data X ₂ exceeds the regulation level X _50% (X ₂ > X
_50% ), so 50% regulation control will continue.

In the monitoring cycle T ₃ , since the 50% regulation control is continuously performed, the number of received data which has been thinned out by half (solid line) is below the regulation level X _50% . In this monitoring cycle T ₃ , the number of received data X ₃ (dotted line) is similarly detected and compared with the regulation level X _50% . In this example, the received data count X ₃ is below the regulation level X _50% . Therefore, at time t ₃ , the receiving node B releases the 50% regulation control to the transmission node A and sends a regulation control request signal requesting regulation control (deregulation) without thinning (0% thinning). To do. As a result, in the next monitoring cycle T ₄ , the data signal is transmitted without being thinned out by the 0% regulation control.

Here, in the communication system, the number of data received by the receiving node from the transmitting node per unit time may increase instantaneously or periodically. On the other hand, in the communication regulation control method shown in FIGS. 6 and 7, the received data number averaged within the monitoring period is used for the regulation control, so that an instantaneous peak or the like of the received data number is not detected. . Therefore, if the number of received data does not exceed the regulation level as a whole of the monitoring cycle, the regulation control for the transmission of the data signal is not performed, and there is a problem that the congestion state due to an instantaneous peak of the number of received data cannot be eliminated.

The present invention has been made to solve the above problems, and in the transmission of a data signal from a transmitting node to a receiving node in a communication system, a congestion state in which the number of received data at the receiving node increases. An object of the present invention is to provide a communication regulation control method capable of suitably preventing the occurrence of the above, a communication system using the method, and a receiving device.

[0017]

In order to achieve such an object, a communication regulation control method in a communication system according to the present invention includes a transmitting node transmitting a data signal and a receiving node receiving a data signal from the transmitting node. A method for controlling communication regulation in a communication system including a node, comprising:
(1) First for the data signal received by the receiving node
When the basic cycle is set as the monitoring cycle of, the number of basic received data per unit time obtained for each basic cycle is compared with a predetermined regulation level, and when the number of basic received data exceeds the regulation level. , While controlling the transmission of the data signal from the transmitting node by the first regulation method,
(2) As the second monitoring cycle, a division cycle obtained by dividing the basic cycle into a plurality of cycles is set, and the maximum number of pieces of received data per unit time of the number of pieces of received data per unit time obtained in each division cycle. And the basic received data number are compared, and when the maximum received data number exceeds a predetermined level in view of the basic received data number, the transmission control of the data signal from the transmitting node is regulated by the second regulation method. It is characterized by doing.

A communication system according to the present invention is a communication system including a transmission node for transmitting a data signal and a reception node for receiving a data signal from the transmission node, and (1) reception node. The basic period is set as the first monitoring period for the data signal, and the number of basic received data per unit time obtained for each basic period,
When the number of basic received data exceeds the regulation level by comparing with a predetermined regulation level, transmission control of the data signal from the transmitting node is regulated by the first regulation method, and (2) the second regulation method is used. Set the minute cycle that divides the basic cycle into multiple cycles as the monitoring cycle, and determine the maximum number of minute received data in the basic cycle of the number of minute received data per unit time obtained for each minute cycle and the number of basic received data. In comparison with the above, when the maximum number of received data exceeds a predetermined level in view of the basic received data number, the transmission of the data signal from the transmission node is regulated and controlled by the second regulation method. .

A receiving device according to the present invention is a receiving device used as a receiving node in a communication system including a transmitting node for transmitting a data signal and a receiving node for receiving a data signal from the transmitting node,
(1) A basic cycle is set as a first monitoring cycle for a received data signal, the number of basic received data per unit time obtained for each basic cycle is compared with a predetermined regulation level, and basic reception is performed. When the number of data exceeds the regulation level, the regulation control request signal for controlling the transmission of the data signal from the transmission node by the first regulation method is sent to the transmission node, and (2) the second monitoring is performed. As a cycle, set a minute cycle that divides the basic cycle into multiple cycles, and set the maximum number of received data in the basic cycle of the number of minute received data per unit time obtained for each minute cycle and the number of basic received data. The regulation control for regulating the transmission of the data signal from the transmitting node by the second regulation method when the maximum number of received data exceeds a predetermined level in view of the basic received data. Characterized by sending a demand signal to the transmitting node.

In the communication regulation control method in the above communication system, the communication system using the same, and the receiving device, the normal monitoring period is used as the monitoring period for monitoring the number of received data at the receiving node (receiving device). Two types of monitoring cycles are set: a basic cycle that is a sub-cycle and a divided cycle that is a division of the basic cycle. Then, in addition to the normal communication regulation control based on the basic cycle, an instantaneous peak or the like of the received data number is detected by comparing the maximum received data number in the divided cycle with the basic received data number, and the second The communication regulation control is performed by the regulation method of.

By using such communication regulation control, the receiving node in the communication system includes the case where the number of received data per unit time from the transmitting node received by the receiving node increases instantaneously or periodically. It is possible to preferably prevent the occurrence of the congestion state in.

Regarding the concrete setting of the division period and the like, the communication regulation control method, the communication system, and the receiving device divide the division period T _Y into the basic period T _X with the division number N (N is an integer of 2 or more). It is preferable to set it as the divided cycle T _X / N and obtain the maximum number of received data by the maximum number of N received data in the basic cycle.

In the second regulation method, the regulation coefficient a is set, and when the maximum received data number Y exceeds the level aX which is a times the basic received data number X, the data signal from the transmitting node is set. Is controlled to 1 / a. According to such a regulation method, it is possible to favorably eliminate the congestion state due to an instantaneous peak of the number of received data.

Further, the receiving device includes (a) data signal receiving means for receiving the data signal from the transmitting node, and (b)
A control signal transmitting means for transmitting a regulation control request signal to a transmitting node, and (c) a first regulation method or a second regulation method for monitoring the number of received data of a data signal by the set basic cycle and division cycle. When the regulation control of the transmission of the data signal from the transmission node is required, the communication signal regulation control means for instructing the control signal transmission means to transmit the regulation control request signal is provided. By using the receiving device having such a configuration, in the communication system,
The communication regulation control method described above can be preferably realized.

[0025]

BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments of a communication regulation control method in a communication system according to the present invention, a communication system using the same, and a receiving apparatus will be described in detail below with reference to the drawings. In the description of the drawings, the same elements will be denoted by the same reference symbols, without redundant description. Also,
The dimensional ratios in the drawings do not always match those in the description.

FIG. 1 is a block diagram schematically showing an embodiment of a communication system according to the present invention. The communication system is configured to include a transmitting device 1 that functions as a transmitting node A that transmits a data signal, and a receiving device 2 that functions as a receiving node B that receives a data signal from the transmitting node A. In the configuration example shown in FIG. 1, as an example of the reception device 2, data that functions as a data storage node that stores data from the transmission device 1 and distributes the data to a predetermined distribution destination as needed. Assumes a storage device.

The receiving device 2 has a transmission / reception unit 20, a communication control unit 30, and a data distribution unit 40. Transmitter / receiver 20
Transmits or receives a signal between the transmitter 1 and the receiver 2. The data distribution unit 40 distributes data to a predetermined distribution destination, which is an external device. The communication control unit 30 also controls each communication operation in the receiving device 2, such as signal transmission / reception by the transmission / reception unit 20 and data distribution by the data distribution unit 40.

Specifically, the transmission / reception unit 20 comprises a data signal reception unit (data signal reception means) 21 and a control signal transmission unit (control signal transmission means) 22. The data signal receiving unit 21 receives the data signal transmitted from the transmitting device 1 to the receiving device 2. Further, the control signal sending unit 22 sends a regulation control request signal for controlling the transmission of the data signal from the transmission device 1 to the transmission device 1.

The communication control section 30 has a communication regulation control section (communication regulation control means) 31. The communication regulation control unit 31 controls the receiving device 2 according to the set monitoring cycle.
The number of received data of the data signal is monitored, and it is determined whether the regulation control of the transmission of the data signal from the transmission device 1 by the predetermined regulation method is necessary. Then, when the regulation control is necessary, the control signal transmission unit 22 is instructed to transmit the regulation control request signal to the transmission device 1.

Further, in the present embodiment, the communication control unit 30 further includes a data distribution unit 40 and a data storage unit 41.
Connected to. The communication control unit 30 determines whether the received data signal from the transmission device 1 can be distributed to a distribution destination. Then, if the distribution is possible, the data is distributed to the distribution destination via the data distribution unit 40. If distribution is not possible, the data is stored in the data storage unit 41 as standby data.

FIG. 2 is a flowchart showing a communication regulation control method used in the communication system shown in FIG. In this communication regulation control method, the transmission node A (transmission device 1) is a regulated node and the reception node B (reception device 2).
Is a congestion detection node and a regulation invoking node. In the communication system having the configuration shown in FIG. 1, the communication regulation control method described below is mainly performed by the communication regulation control unit 31 of the receiving device 2.

Here, in this communication regulation control method,
A basic cycle (first monitoring cycle) that is a fixed cycle as a monitoring cycle for monitoring the number of data received by the receiving device 2.
T _X and a divided period T _{Y obtained} by dividing the basic period T _X into a plurality of periods
And two types of monitoring cycles are set. In addition, as a method of restricting the transmission of the data signal from the transmitter 1, a first restricting method used for monitoring the number of received data by the basic cycle T _X and a method of monitoring the number of received data by the division cycle T _Y are used. Two types of regulation methods, the second regulation method used correspondingly, are set.

First, in the receiving device 2 which is the receiving node B, the data signal from the transmitting device 1 which is the transmitting node A is received by the data signal receiving section 21 (step S101). The data from the received data signal is
The communication control unit 30 determines whether distribution to the distribution destination is possible. Then, if the distribution is possible, the data is distributed via the data distribution unit 40, and if the distribution is impossible, the data is accumulated in the data accumulation unit 41 as standby data (S102).

Next, with respect to the basic period T _X preset as the first monitoring period, the basic received data number X which is the received data number per unit time is detected for each basic period (S103). Further, when the restriction control based on the number of standby data stored in the data storage unit 41 is simultaneously performed, the number of standby data is also detected. Regarding the regulation control based on the number of standby data, the same regulation method as the conventional one is used also in this communication regulation control method.

Further, with respect to the minute cycle T _Y preset as the second monitoring cycle, the number of minute received data which is the number of received data per unit time is obtained for each minute cycle.
Further, the maximum number of received data items Y, which is the maximum number, is detected from the plurality of number of received data items obtained for each division period within the basic period (S104).

When the basic received data number X and the maximum received data number Y are detected by the basic period T _X and the divided period T _Y ,
With reference to these, it is determined whether or not the regulation control of the transmission of the data signal from the transmission device 1 is necessary.

[0037] In the example shown in FIG. 2, firstly, minute period T and the maximum content received data number Y found by _Y, are compared and the basic number of received data X, the maximum content received data number Y
Is judged from the basic received data number X whether it exceeds a predetermined level. Then, when the level exceeds the predetermined level, the transmission of the data signal from the transmission device 1 is regulated and controlled by the second regulation method.

Specifically, in the present embodiment, the regulation coefficient a is set for the second regulation method based on the maximum number of received data items _Y in the division cycle T _Y , and the maximum number of received data items Y is set. And the level aX, which is a times the basic received data number X, which is the restriction threshold in the second restriction method, are compared (S
105). Then, the maximum amount of received data Y is level aX
If it exceeds (Y> aX), it is regarded that the congestion state is seen from the division period T _Y, and the restriction control for strengthening the restriction on the transmission of the data signal from the transmission device 1 is performed (S).
106). Here, as the second regulation method, regulation control for thinning the transmission of the data signal from the transmission device 1 to 1 / a is performed. The control signal transmission unit 22 of the reception device 2 instructs the transmission device 1 based on the instruction of the communication regulation control unit 31.
A regulation control request signal for strengthening regulation (1 / a) is transmitted.

On the other hand, the maximum received data number Y is level aX.
If it is less than, then the restriction control by the first restriction method is performed using the basic reception data number X obtained by the basic cycle T _X.

[0040] Specifically, in the present embodiment, the first regulating process based on the basic data received number X in the basic period T _X, restriction level, for example 50% control level X
_50% is set, and the number X of basic received data is compared with the regulation level X _50% which is the regulation threshold in the first regulation method (S107). The regulation level X _50% is a regulation threshold value for making a regulation control request to thin out the transmission of the data signal from the transmission device 1 at 50%. Similarly, the number of pieces of standby data is also compared with the regulation level set as a regulation threshold for the number of pieces of standby data. Based on the results of these comparisons, it is judged that the regulation is strengthened, deregulated, or not regulated.

That is, when either the number of received data or the number of standby data exceeds the regulation level (S108).
In step S109, the restriction control is performed to strengthen the restriction on the transmission of the data signal from the transmission device 1, assuming that the congestion is seen from the basic cycle T _X (S109). Here, the first
As a regulation method, the regulation control for thinning out the transmission of the data signal from the transmission device 1 by 50% is performed. The control signal transmission unit 22 of the reception device 2 strengthens the regulation (50%) to the transmission device 1 based on the instruction of the communication regulation control unit 31.
The regulation control request signal of is transmitted.

On the other hand, when both the number of received data and the number of standby data are below the regulation level (S110),
For the transmission of the data signal from the transmitter 1, thinning out 0
% (No thinning) is performed to reduce the regulation (S
111). The control signal transmission unit 22 of the reception device 2 instructs the transmission device 1 based on the instruction of the communication regulation control unit 31.
A regulation control request signal for regulation relaxation (0%) is transmitted. Further, when it is determined that the regulation is not required to be strengthened and the regulation control is not performed at that time, and the regulation is not relaxed, the regulation is not required.

The effect of the communication regulation control method in the communication system according to the present embodiment, and the communication system and receiving apparatus using the method will be described.

In the communication system, the receiver shown in FIG. 1, and the communication regulation control method shown in FIG. 2, the monitoring cycle for monitoring the number of received data in the receiver 2 which is the receiving node B is usually The two types of monitoring cycles are set: a basic cycle T _X which is a monitoring cycle of the basic cycle T _X and a divided cycle T _Y obtained by dividing the basic cycle T _X. Then, in addition to the normal communication regulation control based on the basic period T _X , the maximum peak received data number Y in the divided period T _Y is compared with the basic received data number X to determine the instantaneous peak of the received data number, etc. It is detected and the communication regulation control is performed by the second regulation method.

By using such communication regulation control, in the communication system including the case where the number of received data per unit time from the transmitter 1 received by the receiver 2 increases instantaneously or periodically. It is possible to preferably prevent the occurrence of a congestion state in the receiving device 2 which is the receiving node B.

Here, regarding the specific setting of the monitoring cycle, the division cycle T _Y is set as the cycle T _X / N obtained by dividing the basic cycle T _X by the division number N (N is an integer of 2 or more), It is preferable to obtain the maximum number of received data items Y by the maximum number of N number of received data items in the basic cycle. By setting the basic cycle T _X and the division cycle T _Y in this way, it is possible to reliably detect the occurrence of a congestion state in the receiving device 2 as a whole or instantaneously, and to perform necessary regulation control.

In the communication regulation control method shown in FIG. 2, the regulation coefficient a is set in the second regulation method using the division period T _Y , and the maximum amount of received data Y is equal to the basic received data number X. When the level exceeds the ax level aX, the transmission of the data signal from the transmitter 1 is regulated to 1 / a. According to such a regulation method, it is possible to favorably eliminate the congestion state due to an instantaneous peak of the number of received data.

FIGS. 3A and 3B are graphs showing an example of the communication status in the communication system when the communication regulation control method shown in FIG. 2 is applied. In these graphs, the horizontal axis represents time and the vertical axis represents the number of received data per unit time in the receiving device 2 which is the receiving node B.
The graph of FIG. 3A shows the time change of the number of basic received data _X according to the basic cycle T _X , and the graph of FIG.
The time change of the minute reception data number and the maximum minute reception data number _Y by the division cycle T _Y is shown, respectively.

In the example of the communication status of FIG. 3, the 50% regulation level X used for the regulation control by the first regulation method.
For each regulation condition such as _50% , and the regulation coefficient a used for the regulation control in the second regulation method, the same regulation condition as that described above with reference to FIG. 2 is used.

Regarding the setting of the division period T _Y , the number of divisions of the basic period T _X is N = 4, and the division period is T _Y = T _X /
It is set to 4. At this time, as a specific example, if the basic cycle is T _X = 20 seconds, the minute cycle is T _Y = 5 seconds. The regulation coefficient a used in the second regulation method can be appropriately set based on specific conditions such as the performance of each receiving device 2 and the communication characteristics of the communication system. 3 shows the case where a = 2 as an example.

[0051] First, in the monitoring period T ₁ according to the fundamental period T _X, as shown in FIG. 3 (a), the basic number of received data X ₁ by the fundamental period T _X is detected. In addition, as shown in FIG. 3B, the number of pieces of received data for four pieces by the four division cycles T _Y included in the monitoring cycle T ₁ and the maximum number of pieces of received data Y ₁ that is the maximum number of them are detected. To be done.

In this monitoring cycle T ₁ , the basic received data number X ₁ is below the regulation level X _50% . Therefore,
The regulation control by the first regulation method in which the transmission of the data signal from the transmission device 1 is thinned out by 50% is not performed. On the other hand, the maximum received data number Y ₁ exceeds the predetermined level aX ₁ = 2X ₁ in view of the basic received data number X ₁ (Y ₁ > 2
X ₁ ). Therefore, at time t ₁ , the receiving device 2 requests the transmitting device 1 to perform the controlling control (restriction strengthening) for thinning the transmission of the data signal from the transmitting device 1 to 1 / a = 1/2. Send a signal.

In the monitoring cycle T ₂ , since the 1/2 regulation control is performed, the number of received data which is thinned to be half (solid line) is the number of basic received data which is thinned and the maximum amount of received data is received. Both numbers of data are small enough. In this monitoring cycle T ₂ , similarly, the number of basic received data X ₂ (FIG. 3A, dotted line) in the basic cycle T _X is detected. Further, the number of received data of four minutes by the four divided cycles T _Y included in the monitoring cycle T ₂ and the maximum number of received data Y ₂ (the dotted line in FIG. 3B) which is the maximum number of them are detected. It Even in this monitoring cycle T ₂ , the maximum amount of received data Y ₂ is the predetermined level a when viewed from the number of basic received data X _2.
Since X ₂ = 2X ₂ is exceeded (Y ₂ > 2X ₂ ), the 1/2 regulation control is continued as it is. In the monitoring period T _{3 and} thereafter, similarly, the number of received data is monitored, and the regulation control of the transmission of the data signal from the transmission device 1 is performed.

As shown in FIG. 3A, in the control control of the data signal transmission at the basic cycle T _X and the restriction level X _50% , the average number of basic received data _X within the monitoring cycle T X is restricted. Used for control. Therefore, when a congestion state in which the basic received data number X increases as a whole, 50% regulation control is required based on the regulation level X _50% , but the received data number increases instantaneously or periodically. It may not be possible to sufficiently cope with the congestion state that occurs.

On the other hand, as shown in FIG.
_In the control control of the data signal transmission by _Y , the basic cycle T _X
By dividing the divided period T _Y into 1/4 into the second monitoring period, the congestion state due to the instantaneous and periodic peak of the number of received data that is generated almost in synchronization with the basic period T _X Has become apparent within each monitoring cycle T _{1 to} T ₃ . Such an instantaneous congestion state is, for example, an ISP.
IS when connected to (Internet Service Provider)
It is caused by peak traffic due to the on-time notification information from P.

As described above, the basic cycle T _X which is the first monitoring cycle and the restriction control by the first restriction method, and the division cycle T _Y which is the second monitoring cycle and the restriction control by the second restriction method According to the communication regulation control method that uses the combination of and, it is possible to suitably eliminate both the long-term and overall congestion state and the instantaneous and periodic congestion states.

The above-mentioned communication system, receiving device, and communication regulation control method are, concretely, a fixed telephone network, a mobile communication network, or a communication system combining them.
It can be applied to various communication systems.

FIG. 4 is a block diagram showing an example of a concrete configuration of the communication system shown in FIG.

This communication system is a PDC (Personal Digital Cellular) network 6 which is a wireless communication network up to the second generation.
And IMT (Internat) which is a wireless communication network of the third generation or later.
It is a communication system configured to include the ional mobile telecommunication network 7.

In the PDC network 6, data such as a message transmitted from the mobile station (MS) 61 is transmitted to the radio base station (B
S) 62, and is transmitted to the short message storage system (MPS) 90 via the subscriber exchange (MLS) 63, the gateway exchange (MGS) 64, and the mobile communication information storage system (MIS) 60. In addition, the gateway switch 64 includes a public switched telephone network (PST) which is a fixed telephone network.
N) 65 is connected via a connection point (POI) 66.

On the other hand, in the IMT network 7, the mobile station (MS) 7
The data transmitted from 1 is the wireless base station (BTS) 72.
Received at the subscriber multimedia switching system (L-
It is sent to the short message storage system (MPS) 90 via the MMS) 73 and the gateway multimedia switching system (G-MMS) 70. These PDC
The network 6 and the IMT network 7 are common line signaling systems (CCSN).
o. 7) It is linked by 80.

The short message storage system 9
0 is the information storage system 60 of the PDC network 6 or IMT
It functions as a data storage node for data such as messages transmitted as data signals from the gateway MMS 70 of the network 7. The short message storage system 90
The received data signal is accumulated in the system 90, or the data is distributed to the incoming call notification gateway server 95 which is the distribution destination.

In the communication system shown in FIG. 4, the information storage system 60 in the PDC network 6 and the gateway M in the IMT network 7
The MS 70 corresponds to the transmission node A (transmission device 1) shown in FIG. 1, respectively. The short message storage system 90 corresponds to the receiving node B (receiving device 2). In the communication system having such a configuration, by applying the above-mentioned communication regulation control method, it is possible to suitably eliminate both long-term and overall congestion states, and instantaneous and periodic congestion states. It will be possible.

The communication regulation control method in the communication system according to the present invention, and the communication system and the receiving apparatus using the communication regulation control method are not limited to the above-described embodiments, but various modifications are possible. For example, the specific configurations of the communication system and the receiving device are not limited to those shown in FIGS. 1 and 4, and various configurations are possible. Further, the receiving device that is the receiving node may be configured to function as a receiving node other than the data storage node.

Further, the communication regulation control method may be modified in various ways such as a concrete regulation method. For example, in the first regulation method based on the basic cycle T _X , a plurality of regulation methods such as regulation methods having different thinning rates may be set, and a plurality of regulation levels may be set correspondingly. In the second regulation method based on the division cycle T _Y , the regulation method using the preset regulation coefficient a in the regulation control method described above has been described, but a regulation method other than this can also be used. .

[0066]

As described in detail above, the communication regulation control method in the communication system according to the present invention, and the communication system and the receiving apparatus using the same obtain the following effects. That is, two types of monitoring cycles, a basic cycle and a minute cycle, are set as monitoring cycles for monitoring the number of received data at the receiving node, and in addition to the normal communication regulation control by the basic cycle, A communication regulation control method for detecting a momentary peak or the like of the number of received data by comparing the number of received data with the number of basic received data, and performing communication regulation control by the second regulation method, and communication using the same According to the system and the receiving device, the occurrence of congestion in the receiving node in the communication system, including the case where the number of received data per unit time from the transmitting node received by the receiving node increases instantaneously or periodically. Can be preferably prevented.

[Brief description of drawings]

FIG. 1 is a block diagram schematically showing an embodiment of a communication system including a transmitter and a receiver.

2 is a flowchart showing a communication regulation control method in the communication system shown in FIG.

FIG. 3 is a graph showing an example of the communication status when the communication regulation control method shown in FIG. 2 is applied.

FIG. 4 is a block diagram showing a specific configuration example of the communication system shown in FIG.

FIG. 5 is a schematic diagram showing communication regulation control in a communication system.

FIG. 6 is a flowchart showing a conventional communication regulation control method in a communication system.

7 is a graph showing an example of a communication situation when the communication regulation control method shown in FIG. 6 is applied.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Transmitting device (transmitting node), 2 ... Receiving device (receiving node), 20 ... Transmitting / receiving unit, 21 ... Data signal receiving unit, 22
Control signal sending unit, 30 Communication control unit, 31 Communication restriction control unit, 40 Data distribution unit, 41 Data storage unit, 6
... PDC network, 60 ... Information storage system, 61 ... Mobile station,
62 ... Wireless base station, 63 ... Subscriber switch, 64 ... Gateway switch, 65 ... Public telephone network, 66 ... Connection point, 7 ... IMT
Network, 70 ... Gate MMS, 71 ... Mobile station, 72 ... Wireless base station, 73 ... Subscriber MMS, 80 ... Common line signaling system,
90 ... Short message storage system, 95 ... Incoming call notification gateway server.

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Claims (10)

(57) [Claims] 1. A communication regulation control method in a communication system comprising a transmitting node transmitting a data signal and a receiving node receiving the data signal from the transmitting node, wherein the data received by the receiving node. A basic cycle is set as a first monitoring cycle for a signal, the number of basic received data per unit time obtained for each basic cycle is compared with a predetermined restriction level, and the number of basic received data becomes the restriction. When the level is exceeded, the transmission of the data signal from the transmission node is regulated and controlled by the first regulation method, and a division period obtained by dividing the basic period into a plurality of periods is set as the second monitoring period. However, the maximum number of received data in the basic cycle of the number of minute received data per unit time obtained for each of the minute cycles, and the basic received data number In comparison,
When the maximum received data number exceeds a predetermined level as viewed from the basic received data number, transmission control of the data signal from the transmission node is controlled by a second regulation method. Control method. 2. The division cycle T _Y is set as a cycle T _X / N obtained by dividing the basic cycle T _X by a division number N (N is an integer of 2 or more), and the maximum reception data number is set as 2. The communication regulation control method according to claim 1, wherein the communication regulation control method is obtained by the maximum number of the N received data items within a basic period. 3. The transmission node according to the second regulation method, wherein a regulation coefficient a is set, and when the maximum received data number Y exceeds a level aX which is a times the basic received data number X. 3. The communication regulation control method according to claim 1, wherein the transmission of the data signal from the vehicle is regulated to 1 / a. 4. A communication system, comprising: a transmitting node transmitting a data signal; and a receiving node receiving the data signal from the transmitting node, wherein a first node for the data signal received by the receiving node is provided. A basic cycle is set as a monitoring cycle, and the number of basic received data per unit time obtained for each basic cycle is compared with a predetermined regulation level, and the number of basic received data exceeds the regulation level. At this time, the transmission of the data signal from the transmitting node is regulated and controlled by the first regulation method, and a division period obtained by dividing the basic period into a plurality of periods is set as the second monitoring period. By comparing the maximum number of received data in the basic cycle of the number of received data per unit time obtained for each and the number of basic received data,
A communication system characterized in that when the maximum received data number exceeds a predetermined level as viewed from the basic received data number, transmission control of the data signal from the transmission node is regulated by a second regulation method. . 5. The division cycle T _Y is set as a cycle T _X / N obtained by dividing the basic cycle T _X by a division number N (N is an integer of 2 or more), and the maximum reception data number is set as 5. The communication system according to claim 4, wherein the communication data is obtained by the maximum number of N pieces of received data in the basic cycle. 6. The transmitting node according to the second regulation method, wherein a regulation coefficient a is set, and when the maximum received data number Y exceeds a level aX which is a times the basic received data number X. 6. The communication system according to claim 4, wherein the transmission of the data signal from the terminal is regulated to 1 / a. 7. A receiving device used as the receiving node in a communication system comprising a transmitting node transmitting a data signal and a receiving node receiving the data signal from the transmitting node, wherein the received data is received. A basic cycle is set as a first monitoring cycle for a signal, the number of basic received data per unit time obtained for each basic cycle is compared with a predetermined restriction level, and the number of basic received data becomes the restriction. When the level is exceeded, a regulation control request signal for regulating and controlling the transmission of the data signal from the transmission node by the first regulation method is sent to the transmission node, and the basic monitoring is performed as a second monitoring cycle. The division cycle is set by dividing the cycle into a plurality of cycles, and the basic cycle of the number of minutes reception data per unit time obtained for each division cycle is set. The maximum amount Received data in, by comparing the basic Received data,
When the maximum reception data number exceeds a predetermined level in view of the basic reception data number, the regulation control request signal for controlling the transmission of the data signal from the transmission node by the second regulation method is transmitted. A receiving device characterized by transmitting to a node. 8. The division cycle T _Y is set as a cycle T _X / N obtained by dividing the basic cycle T _X by a division number N (N is an integer of 2 or more), and the maximum reception data number is set as 8. The receiving apparatus according to claim 7, wherein the number is obtained by the maximum number of the N received data items within a basic period. 9. The transmission node according to the second regulation method, wherein a regulation coefficient a is set, and when the maximum received data number Y exceeds a level aX which is a times the basic received data number X. 9. The receiving apparatus according to claim 7, wherein the transmission of the data signal from the terminal is regulated to 1 / a. 10. A data signal receiving means for receiving the data signal from the transmitting node, a control signal transmitting means for transmitting the regulation control request signal to the transmitting node, the set basic period and the division. The number of received data of the data signal is monitored by a cycle, and the control signal transmission is performed when the regulation control of the transmission of the data signal from the transmission node by the first regulation method or the second regulation method is necessary. 10. The receiving apparatus according to claim 7, further comprising communication regulation control means for instructing the means to send out the regulation control request signal.