JP3587958B2 - Access control method and device - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
According to the present invention, in a transmission mode in which a master station and a plurality of slave stations are star-type, bus-type or one-to-one connection, but logically share a line, one logical line is divided and used by a plurality of slave stations. Access control method and device thereof.
[0002]
[Prior art]
FIG. 26 shows a conventional access control method and a conventional access control method in which one logical line is divided and used by a plurality of slave stations in a transmission mode in which a master station and a plurality of slave stations share a line in a star configuration. FIG. 2 is a configuration diagram showing a subscriber line to be applied, in which 100 is a slave station and 101 is a master station.
In the conventional access control method and apparatus, for example, as disclosed in Japanese Patent Laid-Open No. 2-10926, when communication is performed using a multiple access type channel, a master station is fixed to each slave station. The pre-assignment method in which each slave station performs data transmission using a dynamically allocated slot, or the master station dynamically allocates a slot in response to a slave station reservation request and uses the reserved slot to The station can be broadly classified into two types of demand assignment systems for transmitting data. In particular, in the technique disclosed in Japanese Patent Application Laid-Open No. 2-10926, one of the pre-assignment method and the demand assignment method is determined for each time slot to increase transmission efficiency.
[0003]
[Problems to be solved by the invention]
Since the conventional access control method and its apparatus are configured as described above, in the case of a subscriber line in which voice is the main stream, a pre-assignment method that always secures the line capacity up to the local exchange, and further increases the transmission efficiency It was sufficient to perform demand access on a call-by-call basis for the necessary parts.However, transmission capacity such as computer communication changed every moment, and in some cases there was almost no access to the network. When large amounts of data need to be sent and received via the network, the transmission efficiency cannot be expected to improve with the pre-assignment method, and the transmission path length is long even with the demand access method, and the amount of data to be transmitted changes every moment. Then, since the time required for the demand processing becomes long, there is a problem that the improvement of the transmission efficiency cannot be expected similarly to the pre-assignment method.
[0004]
Further, when there is no data to be transferred even if the line capacity is secured once on demand, there is a problem that the time during which valid information does not flow on the line increases and the line is not effectively used.
[0005]
SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and provides an access control method and apparatus capable of improving the transmission efficiency in a multiple access channel for highly bursty traffic such as computer communications. The purpose is to:
[0006]
[Means for Solving the Problems]
In the access control method according to the first aspect of the present invention, slot information about slots to be allocated to each slave station is fixedly set in advance, and a time interval between the slave station and the master station is determined based on the set slot information. The idle line is determined by the communication performed in the above, based on the idle line information about the determined idle line, for the set slot information, the slot assigned to the slave station determined as the idle line other A transfer relationship for transferring to the slave station is set, and based on the new slot information according to the set transfer relationship, each slave station knows its own assigned slot and sends information to be sent to the master station. The transmission is performed using the self-assigned slot.
[0007]
In the access control method according to the second aspect of the present invention, the idle control is performed based on the idle information of the line transmitted from each slave station to the master station using a slot known based on slot information fixedly set in advance. Determine the line, based on the determined idle line information on the idle line, for the fixedly set slot information, other than the slot assigned to the slave station determined as the idle line Setting of the transfer relationship when transferring to the slave station is performed on the master station side, and each slave station knows its own assigned slot based on the slot information according to the transfer relationship, and uses the own assigned slot. Information to be sent to the master station.
[0008]
In the access control method according to the third aspect of the present invention, the idle control is performed based on the idle information of the line transmitted from each slave station to the master station using a slot known based on slot information fixedly set in advance. A line is determined, and based on the idle line information about the determined idle line, the fixedly set slot information broadcast from the master station is a child determined to be the idle line. The setting of the transfer relationship for transferring the slot assigned to the station to another slave station is performed in each slave station, and each slave station uses the self-assigned slot by knowing its own assigned slot according to the transfer relationship. Then, information to be sent to the master station is transmitted.
[0009]
An access control method according to a fourth aspect of the present invention detects idle information of a line transmitted from each slave station to a master station using a slot known based on slot information fixedly set in advance. The slave station determines an idle line based on the detected idle information, and the fixed line information broadcast from the master station based on the determination result is used for the idle line. In the slave station, the assignment of the assignment when the slot assigned to the slave station determined to be assigned to another slave station is performed, and each slave station knows its own assigned slot according to the assignment relationship, and Information to be sent to the master station is transmitted by using an assigned slot.
[0010]
In the access control method according to the fifth aspect of the present invention, valid information included in a cell transmitted from a slave station to a master station exists using a slot based on slot information fixedly set in advance. The identification information indicating that there is no idle line is used as idle information for determining an idle line.
[0011]
Claim6The access control apparatus according to the invention described above includes a slot information setting unit that fixedly sets slot information about slots to be allocated to each slave station in advance, and the slot information set by the slot information setting unit to each slave station. A first broadcast means for broadcasting, and communication performed between the slave station and the master station based on the slot information broadcast to each slave station by the first broadcast means. Idle line determining means for determining an idle line; and, based on idle line information on the idle line determined by the idle line determining means, the slot information set by the slot information setting means is determined to be the idle line. Transfer relationship setting means for setting a transfer relationship for transferring a slot assigned to a slave station to another slave station; Based on the new slot information according to the transfer relationship set by the transfer relationship setting means, each slave station knows its own assigned slot, and transmits information to be sent to the master station using the own assigned slot. Transmission means.
[0012]
Claim7The access control device according to the invention described above determines an idle line based on idle information of a line that each slave station sends to the master station using a slot learned based on slot information set by the slot information setting means. Based on the idle line information on the idle line determined by the idle line determination unit, the slot information set by the slot information setting unit, the slave station determined to be the idle line Slot transfer relation setting means for setting a transfer relation for transferring an assigned slot to another slave station; and slot information according to the transfer relation set by the slot transfer relation setting means to each of the slave stations. A second broadcasting unit for broadcasting, and the slot information broadcast to each of the slave stations by the second broadcasting unit. Slave station knows its own allocated slot is using the self-assigned slot that so and transmission means for transmitting the information to be sent to the master station.
[0013]
Claim8The access control device according to the invention described above determines an idle line based on idle information of a line that each slave station sends to the master station using a slot learned based on slot information set by the slot information setting means. Based on the idle line information on the idle line determined by the idle line determination unit, and the first broadcast unit set by the slot information setting unit broadcasts from the master station. A slot assignment relation setting means for setting, in each slave station, an assignment relation for assigning a slot assigned to the slave station determined to be the idle line to another slave station, the slot assignment relation; Each slave station knows its own assigned slot based on the slot information according to the transfer relationship set by the setting means, and uses the own assigned slot to It is obtained by so and transmission means for transmitting the information to be sent to the master station.
[0014]
Claim9The access control apparatus according to the invention described above is characterized in that idle information for detecting idle information of a line transmitted from each slave station to a master station using a slot learned based on slot information set by slot information setting means. An idle line determination unit having a detection unit, a determination unit for determining an idle line on the slave station side based on the idle information detected by the idle information detection unit, and a determination result by the idle line determination unit. In the slot information set by the slot information setting means broadcast from the master station by the first broadcasting means, the slot assigned to the slave station determined to be the idle line is sent to another slave station. Slot assignment relation setting means for setting the assignment relation at the time of assignment on the slave station side; and each of the slot assignment relation setting means according to the assignment relation set by the slot assignment relation setting means. Stations know the self assigned slot is used the self-assigned slot that so and transmission means for transmitting the information to be sent to the master station.
[0015]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described.
Embodiment 1 FIG.
FIG. 1 is a block diagram showing a main configuration of a master station and a slave station of an access control device to which an access control method according to a first embodiment of the present invention is applied. (B) is a block diagram showing a configuration of a slave station. In the figure, reference numeral 1 denotes an idle line determination unit (idle line determination means) in a master station that monitors information from a slave station and determines whether or not the mobile station is an idle line. A pre-assigned TDMA slot information generator (slot information setting means) for determining a time slot for TDMA (Time Division Multiple Access) in advance based on the situation, etc. A TDMA slot information conversion unit (slot assignment setting means) for converting slot information to assign to a slave station of the same, and a multiplexing unit (first broadcast) for multiplexing the converted TDMA slot information into downlink data Means, second broadcast means).
[0016]
Reference numeral 5 denotes a TDMA slot information receiving unit of the slave station that receives TDMA slot information broadcast by the master station, and 6 denotes a delay for holding the received TDMA slot information up to a predetermined transmission phase.Department,Reference numeral 7 denotes a FIFO unit (transmitting means) for storing upstream data in order to send data to the master station at the timing output from the delay unit 6.
[0017]
Next, the operation will be described.
In the TDMA slot information converting section 3 in the master station, the frame period T is predetermined, and the preassigned TDMA slot information predetermined by the preassigned TDMA slot information generating section 2 is selected at the beginning of the frame, and is sent to the multiplexing section 4. The pre-assigned TDMA slot information is output and distributed to all slave stations. In the slave station, the pre-assigned TDMA slot information receiving unit 5 receives the distributed and transferred pre-assigned TDMA slot information, and the uplink data waiting in the FIFO unit 7 is transmitted to the master station according to the received pre-assigned TDMA slot information. You.
The method of distributing the pre-assigned TDMA slot information includes a method of specifying each slot described in “Time slot allocation method in ATM-PDS, 1993 IEICE Autumn Meeting B-668”, and a method of collectively specifying a plurality of slots. By any of the methods.
[0018]
Uplink information is separated into blocks of information called cells, and information from the slave station to the master station is transferred in cell units. A code that does not include valid information is defined in the cell, and the idle line determination unit 1 recognizes the idle cell by receiving the defined code at the master station. Further, the idle line determination unit 1 determines whether or not the lines from all the pre-assigned slave stations are idle lines by, for example, the following two methods. The first method is a case where n consecutive idle cells are detected, and the second method is a case where one or more idle cells out of k cells are received m times or more.
[0019]
For the detected idle line, a conversion table indicating the transfer relationship is created in the TDMA slot information conversion unit 3 using, for example, a separately determined algorithm, the preassign slot number is changed by this conversion table, and the idle line is changed to the transfer line. Be changed.
[0020]
FIG. 2 is a flowchart illustrating an example of the algorithm. As shown in this flowchart, the determination condition of step ST101 is satisfied at the beginning of the frame, and the contents of the conversion table are cleared by the subsequent step ST102. In this case, the TDMA slot information is the pre-assigned TDMA slot information generated by the pre-assigned TDMA slot information generator 2 shown in FIG.
[0021]
When the idle line information Cid is detected by the idle line determination unit 1, the determination result becomes “Yes” with respect to the determination condition in step ST103, and in the subsequent step ST104, the conversion source idle described in the conversion table is described based on the idle line information Cid. Search the line information Cid. If it is not registered in the conversion table, it is determined that the line is a new idle line.
On the other hand, when the idle line information Cid has already been registered as the conversion source idle line information Cid in the conversion table, the determination result for the determination condition of step ST104 is “No”, and no processing is performed.
If the result of the determination in step ST103 is affirmative, and if it is determined in step ST104 that the line is a new idle line, then in step ST105, the pre-assignment ID immediately before or after the pre-assigned ID configured in the chain. The assignment ID is detected as the transfer destination Nid of the idle line.
[0022]
An example of this chain configuration is shown in FIG. In the example of FIG. 7A, it is assumed that six preassigned IDs of the slave stations 1, 3, 5, 6, 7, and 8 are currently valid. In FIG. 3A, the chains are configured in the ascending order by the pre-assigned ID, and the chain is configured such that the number following the last 8 is 1. In this case, a case is considered in which, when an idle line is detected, the next preassign ID is defined as the transfer destination Nid of the idle line. For example, when the preassign ID 3 is detected as new idle line information Cid, the preassign ID of 5 is the transfer destination Nid of the idle line.
[0023]
Returning to FIG. 2, when it is determined in step ST106 that the detected idle line information Cid matches the transfer destination Nid in step ST105, all the pre-assigned lines go through the chain configuration and become idle lines. If it is recognized, the process proceeds to the previous step ST107, in which all the conversion tables are reset, and the pre-assignment is set.
[0024]
On the other hand, when the determined result that the detected idle line information Cid does not match the transfer destination Nid in step ST105 is obtained in step ST106, in step ST108, the transfer destination Nid is set as a conversion source of the conversion table. It is determined whether or not it has already been registered. The case where the transfer destination Nid is already registered as the conversion source of the conversion table is a case in which the circuit has gone through the chain configuration and the line has been transferred to the conversion destination of the conversion table. It is assumed that the preassigned ID of the conversion destination of the idle line is the transfer destination Nid which has already been registered as the conversion source of the conversion table.
[0025]
FIG. 3B shows that all pre-assigned lines are recognized as idle lines and go around the chain configuration, and it is determined in step ST106 that the detected idle line information Cid matches the transfer destination Nid. This shows the state of the conversion table to be reset. That is, when all the pre-assigned lines are idle lines, the line with the pre-assign ID 3 is first detected as new idle line information Cid, the line with the pre-assign ID 5 becomes the transfer destination Nid of the idle line, and The line with the assignment ID 5 is detected as new idle line information Cid, and the line with the pre-assignment ID 6 becomes the transfer destination Nid of the idle line. As a result, the line with the preassign ID 1 is finally detected as new idle line information Cid, and the line with the preassign ID 3 becomes the transfer destination Nid of the idle line. The line of the pre-assignment ID 3 that has become the transfer destination Nid is already registered as the conversion source at the beginning of the conversion table. Accordingly, the determination result for the determination condition in step ST108 is "Yes", and in step ST109, the conversion source: preassign ID3 for the conversion source: preassign ID3 in the conversion table is set to preassign ID3. As a result, the determination result for the determination condition in step ST106 is “Yes”, and the conversion table is reset in step ST107.
[0026]
When the determination result of step ST108 is "No", the process proceeds to step ST110, and the conversion source is written into the conversion table as Cid, and the conversion destination is written as the transfer destination Nid found at step ST105.
[0027]
As a result, the conversion table for transferring the detected idle line to the transfer destination Nid of the non-idle line is updated.
[0028]
As described above, in the first embodiment, the TDMA slot of the idle line is changed to the pre-assigned slot number of the transfer destination line, assigned to the slave station via the multiplexing unit 4 and transferred, and transferred to the slave station. In this case, there is an effect that an access control method and an access control device can be obtained in which the bandwidth of the transferred line increases, the transmission efficiency increases, and the overall transmission efficiency between the slave station and the master station also improves.
[0029]
Embodiment 2 FIG.
FIG. 4 is a block diagram showing a main configuration of a master station and a slave station of an access control apparatus to which the access control method according to the second embodiment of the present invention is applied. (B) is a block diagram showing a configuration of a slave station. 4, the same or corresponding parts as in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted.
In contrast to the first embodiment in which the TDMA slot converter 3 is provided in the master station, in the second embodiment, a TDMA slot information converter is provided in the slave station. In FIG. 4, reference numeral 3a denotes the TDMA slot information conversion unit (slot transfer relationship setting means), and 8 denotes an idle line information receiving unit for receiving idle line information Cid sent from the master station.
[0030]
Next, the operation will be described.
The idle line number Cid detected by the idle line determination unit 1 of the master station is multiplexed by the multiplexing unit 4 and transferred to all slave stations. On the slave station side, the pre-assigned TDMA slot receiving section 5 receives the pre-assigned TDMA slot, the idle line information receiving section 8 receives the idle line information Cid sent from the master station, and the TDMA slot information converting section 3a. The transfer line Nid for the idle line of the idle line information Cid is determined by the same algorithm as in the first embodiment, and the line is transferred.
[0031]
As described above, in the second embodiment, since the TDMA slot information exchange unit 3a is provided in the slave station, the function of converting the TDMA slot information, which is a load on the master station in the first embodiment, is reduced. (1) There is an effect that an access control method and an access control device that can shorten the processing time of the master station, which is a problem when a large number of slave stations are connected to one master station, are obtained.
[0032]
Embodiment 3 FIG.
In the second embodiment, the function of the TDMA slot information conversion unit is realized on the slave station side. In the third embodiment, however, an idle channel determination unit is further provided on the slave station side. FIG. 5 is a block diagram showing a main configuration of a master station and a slave station of an access control device to which the access control method according to the third embodiment of the present invention is applied. (B) is a block diagram showing a configuration of a slave station. In FIG. 5, the same or corresponding parts as those in FIG. 4 are denoted by the same reference numerals, and description thereof will be omitted.
In FIG. 5, reference numeral 9 denotes an idle cell detection unit for detecting an idle cell on the master station side, 1a denotes an idle line determination unit (determination means) provided on the slave station side, and 10 denotes an idle cell provided on the slave station side. It is an information receiving unit.
[0033]
Next, the operation will be described.
In the third embodiment, the idle cell detecting section 9 detects an idle cell in the master station, and further multiplexes information on whether or not an idle cell has been detected in the multiplexing section 4 and transfers the information to the slave station. On the slave station side, the transferred information is received by the idle cell information receiving unit 10, and the idle line determining unit 1a determines which line is the idle line. The determination of the idle line is performed by one of the two methods described in the first embodiment. Then, similarly to the second embodiment, the TDMA slot information conversion unit 3a determines the transfer line Nid for the idle line Cid by the same algorithm as that described in FIG. 2 of the first embodiment, and realizes the transfer of the line.
[0034]
As described above, in the third embodiment, since the TDMA slot information exchange unit 3 is provided in the slave station, the TDMA slot information conversion function, which has been a load on the master station in the first embodiment, is implemented as described above. In the same manner as in Embodiment 2, the slave station is provided with an idle line determination unit 1a, and the slave station determines the idle line, and the processing is decentralized. Thus, there is an effect that an access control method and an access control device that can further reduce the processing time of the master station, which becomes a problem when is connected, are obtained.
[0035]
Embodiment 4 FIG.
As described above, in the first to third embodiments described above, the configuration of the TDMA slot information conversion unit 3 that determines a transfer line is configured, for example, by a pre-assigned ID of a line number, and based on the chain configuration. Although the configuration is such that the detected idle line is transferred to the line having the pre-assigned ID immediately before or after, the fourth embodiment has the highest load in the pre-assignment state or the line assignment state after the transfer. Is determined by monitoring information from the slave station at the master station, and a transfer line Nid is determined for the highest load line. In this method, the line can be transferred to a line with a higher load, so that higher transmission efficiency can be improved.
[0036]
FIG. 6 is a block diagram showing a main configuration of a master station of an access control device to which the access control method according to Embodiment 4 of the present invention is applied. 6, the same or corresponding parts as those in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted. In FIG. 6, reference numeral 11 denotes a highest load line detecting unit for detecting a highest load line based on information from a slave station, and 19 denotes a TDMA slot information conversion for determining a transfer line Nid for the highest load line detected by the highest load line detecting unit 11. Department.
[0037]
FIGS. 7, 8, and 9 are block diagrams showing configurations for realizing the function of detecting the highest load line by the highest load line detection unit 11, as shown in FIGS. 7, 8, and 9, respectively. With such a configuration, the highest load line can be detected.
In FIG. 7, reference numerals 12 and 13 denote idle cell counting units for monitoring and counting idle cells to be transferred when there is no valid information regarding information from the child station for each child station. This is a minimum value detection unit that detects the minimum value among the counted numbers of idle cells counted in each case, that is, the child station of the least idle cell among the currently used child stations.
In FIG. 8, reference numerals 15 and 16 denote valid cell count units for monitoring and counting valid cells other than idle cells for each slave station, and 17 denotes a count of valid cells counted by the valid cell count units 15 and 16 respectively. Is the maximum value, that is, the maximum value detection unit that detects the slave station having the largest number of valid cells among the slave stations currently used.
In FIG. 9, reference numeral 18 denotes the maximum cell coverage expressed as the number of valid cells with respect to all cells (total of valid cells and idle cells) from the count numbers of both idle cells and valid cells used in FIGS. Is the maximum cell capacity detection unit that is obtained by calculating.
[0038]
Next, the operation of the master station and the TDMA slot information converter 19 of the master station according to the fourth embodiment will be described. When the highest load line detecting section 11 detects the highest load line by the method shown in FIG. 7, the TDMA slot information converting section 19 outputs the TDMA slot information converting section 19 among the currently used slave stations based on the detection result of the highest load line detecting section 11. The line of the slave station with the least number of idle cells is the highest load line. When the highest load line detecting unit 11 detects the highest load line by the method shown in FIG. 8, the TDMA slot information conversion unit 19 outputs the currently used slave station based on the detection result of the highest load line detecting unit 11. The line of the slave station of the largest effective cell is set as the highest load line. When the highest load line detection unit 11 detects the highest load line by the method shown in FIG. 9, the TDMA slot information conversion unit 19 outputs the currently used slave station based on the detection result of the highest load line detection unit 11. Of these, the line of the slave station having the highest cell capacity is set as the highest load line.
[0039]
In the master station, the highest load line detection unit 11 detects the highest load line based on the information from the slave station by one of the methods shown in FIGS. The TDMA slot information is changed so that the idle line detected by the line determination unit 1 is transferred to the slave station of the detected highest load line. The configuration of the slave station is the same as that of FIG. 1 shown in the first embodiment, and the operation is also the same.
[0040]
In FIG. 7, FIG. 8, and FIG. 9, when the next highest load line is determined after the highest load line is once determined, a method of including the once determined highest load line as a candidate for the next highest load line, Alternatively, a method of not recognizing the second highest load line for the once determined highest load line until all the remaining lines not determined as idle lines are determined as the highest load line is also an option. It is considered as.
[0041]
As described above, in the fourth embodiment, since the idle line is transferred to the slave station of the highest load line detected by the highest load line 11, the idle line is transferred to the slave station transmitting the largest amount of information. As a result, there is an effect that an access control method and an access control apparatus which can appropriately improve the transmission efficiency of the slave station having the largest amount of information and the overall transmission efficiency by expanding the bandwidth of the line of the slave station.
[0042]
Reference Example 1.
In the fourth embodiment, the detection of the highest load line is determined by monitoring information from the slave station in the master station.Reference Example 1Then, the slave station notifies the master station of the remaining amount of information in the slave station, and the master station determines the transfer line based on the notification of the remaining amount.
[0043]
FIG.Reference Example 1FIG. 2 is a block diagram illustrating a main configuration of a master station and a slave station of an access control device to which the access control method is applied. 10, the same or corresponding parts as those in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted. In FIG. 10, reference numeral 20 denotes a remaining amount extraction comparison provided at the master station for comparing the remaining amount transmitted from each slave station at the beginning of a frame.In the departmentis there. Reference numeral 21 denotes a frame end remaining amount monitor provided on the slave station side for monitoring the amount of information remaining in the upstream FIFO unit 7 at the end of the frame.Department,A multiplexing unit 22 multiplexes data on the amount of the remaining information to notify the master station of the amount of the remaining information monitored by the remaining amount monitoring unit 21 at the end of the frame.In the departmentis there.
[0044]
Next, the operation will be described.
In the slave station, the remaining amount of information stored in the upstream FIFO unit 7 at the end of the frame or the like is monitored by the frame end time remaining amount monitoring unit 21 and slots for notifying the slave stations in order are allocated in advance. The multiplexing unit 22 multiplexes data on the remaining amount to notify the master station of the remaining amount.
[0045]
The master station compares the remaining amount transmitted from each slave station at the beginning of the frame and ranks the load lines. There are many possible ways of assigning priorities. For example, priorities are assigned by the following method, and the idle channels are assigned in the TDMA slot information conversion unit 19 in the descending order of the priorities.
There are, for example, the following four methods of allocation according to the transmitted remaining amount.
(1) Remaining quantity * Coefficient order
(2) in order of (remaining amount * coefficient-1 frame allocation amount)
(3) In descending order of (remaining amount * coefficient / allocated amount of one frame)
(4) The order of decreasing (remaining amount * coefficient-1 frame allocation amount) * coefficient / 1 frame allocation amount).
The method (1) evaluates the remaining amount in descending order, and the method (2) multiplies the remaining amount by an appropriate coefficient to subtract the allocated amount of one frame. The remaining amount after one frame is predicted by subtracting the allocation amount of one frame after prediction. The method of (3) multiplies the method of (1) by a coefficient and divides it by the allocated amount of one frame. Therefore, the remaining amount is the normalized amount by the allocated amount. The method of (4) is the method of (2). The value is obtained by normalizing the method with the assigned amount.
[0046]
Note that thisReference Example 1In the same manner as in the fourth embodiment, once the highest load line is determined and then the next highest load line is determined, a method of including the once determined highest load line as a candidate for the next highest load line, A new evaluation value is determined by subtracting the value of the transferred line capacity or a value obtained by multiplying the value by a specific coefficient from the value in the above method (1), (2) or (3), and changing the priority order. There are ways to do it.
[0047]
As mentioned above, thisReference Example 1Then, based on the amount of information remaining in the upstream FIFO unit 7 at the end of the frame monitored by the remaining frame monitoring unit 21 at the end of the frame, the remaining amount comparison unit 20 of the master station starts the next frame. In the above, the remaining amounts transmitted from each slave station are compared, the priorities are assigned to the load lines based on the comparison result, and the transfer destination of the idle line is determined in descending order of the priorities. An access control method and access control capable of accurately improving the transmission efficiency of the slave station having a large amount of information and the overall transmission efficiency by transferring the idle line in the order of the slave stations having a large amount and increasing the bandwidth of the line of the slave station. There is an effect that the device can be obtained.
[0048]
Reference Example 2.
SaidReference Example 1In the slave station, at the end of the frame at the end of the frame, the remaining amount of the FIFO unit 7 is monitored and transferred to the master station. Based on this information, the line which is considered to have the highest load is determined.Reference Example 2Then, the inflow amount per frame of the FIFO unit 7 of the slave station is monitored, and the remaining amount of the FIFO unit 7 at the end of the next frame is predicted based on the inflow amount and the remaining amount. To estimate a high load line.
[0049]
FIG.Reference Example 2FIG. 2 is a block diagram illustrating a main configuration of a master station and a slave station of an access control device to which the access control method is applied. In FIG. 11, the same or corresponding parts as in FIGS. 1 and 10 are denoted by the same reference numerals, and description thereof is omitted. In FIG. 11, reference numeral 23 denotes an inflow monitor for measuring the inflow x of one frame into the FIFO unit 7.Department,Reference numeral 24 denotes a parent at the end of the next frame based on the remaining amount b of the FIFO unit 7 monitored by the remaining amount monitoring unit 21 at the end of the frame and the inflow amount x monitored by the inflow amount monitoring unit 23. Prediction calculation for predicting the predicted remaining amount y when nothing is transferred to the stationIn the departmentis there.
[0050]
Next, the operation will be described.
At the end of the frame, the remaining amount b of the FIFO unit 7 is detected, and the inflow amount x is measured. The prediction calculation unit 24 predicts a predicted remaining amount y when nothing is transferred to the master station at the end of the next frame based on these two measured values. For example, when the linear prediction is applied, the prediction remaining amount y is calculated by multiplexing the prediction remaining amount y determined by y = a · x + b, where a is the prediction coefficient, b is the remaining amount, and x is the inflow amount. Multiplexing unit 22 for multiplexing.
[0051]
In the master station, the predicted remaining amount y sent from the slave station at the beginning of the frame indicates thatReference Example 1Prioritize each slave station in the same way as described above.Reference Example 1Each time the idle line determination unit 1 determines an idle line in the same manner as described above, the idle line is allocated to a slave station having a higher priority, thereby improving the overall transmission efficiency.
[0052]
thisReference Example 2Then, based on the remaining amount b of the FIFO unit 7 and the predicted remaining amount y when nothing is transferred to the master station at the end of the next frame, which is obtained by linear prediction, based on the predicted remaining amount y of the next frame, At the first time, the priority given to each slave station when the idle line is transferred to the slave station is determined, so that the information amount to be transmitted and the line load amount in the slave station to which the idle line is transferred are determined. It is possible to accurately determine and set a higher priority for a slave station having a large amount of information and the load amount to increase a bandwidth for the slave station, and to set a priority order according to the information amount and the load amount. Thus, there is an effect that an access control method and an access control device that can improve the transmission efficiency more accurately are obtained.
[0053]
Reference Example 3.
From the first embodimentReference Example 2In this configuration, only the line determined to be an idle line by the idle line determination unit 1 of the master station is transferred to another slave station. Therefore, when it takes time to determine the idle line, wasteful traffic due to idle cells during the line determination time. , Transmission efficiency may be reduced.
[0054]
In addition,Reference Example 2Since the remaining amount of the FIFO unit 7 of the slave station at the end of the next frame can be predicted,Reference Example 3Then, the transmission efficiency is improved by changing the allocation of TDMA slots using only the predicted remaining amount.
[0055]
FIG.Reference Example 3FIG. 2 is a block diagram illustrating a main configuration of a master station and a slave station of an access control device to which the access control method is applied. 12, parts that are the same as or correspond to those in FIG. 11 are given the same reference numerals, and descriptions thereof will be omitted. In FIG. 12, reference numeral 21 denotes a remaining amount monitor at the end of a frame.Department,23 is the inflow rate monitorDepartment,Reference numeral 25 denotes TDMA slot information generation for generating TDMA slot information based on the remaining amount prediction value from the slave station received by the remaining amount extraction / comparison unit 20.Department,26 is a selection for selecting one of the TDMA slot information generated by the TDMA slot information generation unit 25 and the TDMA slot information generated by the pre-assigned TDMA slot information generation unit 2.Department,4a, the first slot information generated and set by the pre-assignment TDMA slot information generation unit 2 selected by the selection unit 26, or the second slot information generated by the slot information generation unit 25, Multiplexing to broadcast to each slave stationIn the departmentis there.
The configuration of the slave station is as described above.Reference Example 2The configuration is exactly the same.
[0056]
Next, the operation will be described.
The remaining amount extraction comparing section 20 of the master station receives the predicted remaining amount value sent from the slave station, and the TDMA slot information generating section 25 generates TDMA slot information from the predicted remaining amount value. FIG. 13 shows an example of this algorithm.
[0057]
In FIG. 13, the pre-assigned value of the n-th slave station is a_n, The predicted remaining value of the nth slave station is x_nThen, if the condition of step ST121 is not satisfied, that is, if the total predicted remaining amount is smaller than the total number of TDMA slots, this predicted remaining amount is set to the number of allocated TDMA slots, and there are no unallocated slots. As a result, TDMA slots remain. Therefore, it is necessary to increase the predicted remaining amount value in step ST122 to determine the TDMA slot allocation value. When step ST121 is satisfied, that is, when the total predicted remaining amount is larger than the total number of TDMA slots, it is necessary to determine the TDMA slot allocation quantity by subtracting the predicted remaining amount. FIG. 14 shows an example of a method of increasing and decreasing TDMA slots from these predicted remaining values.
[0058]
FIG. 14 shows three methods. First, in the first method, in the case of an increase, the number of time slots to be increased is divided by the number n of active slave stations, that is, y / n is allocated to each subscriber to increase the number of slots. In the case of the decrease, similarly, the number of slots of each slave station is decreased by y / n.
[0059]
The second method is to sequentially select slave stations to be increased or decreased for each frame, and FIG. 15 shows an example of an algorithm for this increase. In FIG. 15, first, the amount Y to be increased is defined in step ST124, and in step ST125, the initial value x 'of the TDMA slot allocation amount is defined._nIs the estimated remaining amount xn of the n-th subscriber. If Y is equal to or smaller than zero, that is, if there is no more slots to be increased in step ST126, the TDMA slot allocation amount is set to x ′ in step ST128._nTo end. If Y is larger than zero, the process proceeds to step ST127, and the number of slots is increased by the maximum increment c per slave station in which the slots of slave stations of the corresponding numbers are defined in advance by the chain or the like shown in FIG. This operation is continued until Y becomes zero. When Y approaches zero and becomes smaller than the maximum increase amount c, the increase amount is not the maximum increase amount c but the number of slots increases by the remaining amount of Y. This is expressed by a processing expression shown in step ST127. In this way, the lines are increased in the order of the slave station numbers until Y becomes zero, and the number of allocated TDMA slots x '_nIs determined.
[0060]
FIG. 16 shows an example of an algorithm for reducing the number of slots in the second method in FIG. In FIG. 16, the value of the number of slots Y to be decreased is represented by the processing equation of step ST129 since the sum of the predicted remaining amount is larger than the sum of the pre-assigned values. In step ST126, if Y is larger than zero, the assigned band is reduced to zero in the order determined by the slave stations. The value of Y decreases, and the estimated remaining amount x ′_KIf it becomes smaller than the above, the number of slots is reduced by Y.
[0061]
The first method and the second method in FIG. 14 are configured as described above, and the increase and decrease in the number of slots of all slave stations are considered to be equal on average. If they are almost equal, they will be assigned without unfairness to the slave station.However, if the pre-assigned value changes significantly and the usage fee is set by the pre-assigned value, the number of slots will be regardless of the pre-assigned value. It is not preferable because it can be changed.
[0062]
The third method solves this drawback. FIG. 17 shows an example of the algorithm of the third method when the bandwidth is increased. The algorithm shown in FIG. 17 has a configuration similar to that of FIG. The difference is that in step ST125 in FIG. 15, the definition of the difference Dn between the preassigned value and the predicted remaining amount for each slave station is added as in step ST131 in FIG. If the number of allocated slots still needs to be increased in step ST126 (if Y is larger than zero), in step ST132, the smallest D_nThat is, a process of increasing the number of slots of the slave station assigned the smallest amount compared to the pre-assignment value by "1" is performed, and this process is repeated Y times in total, and all slots are assigned to each slave station. Process.
[0063]
FIG. 18 shows an example of a case where the bandwidth is reduced in the algorithm of the third method. In the figure, as in the case of the second method, the amount of band reduction is represented by step ST129. Compared to the case of increasing the bandwidth in FIG. 17, when it is necessary to reduce the number of allocated slots in step ST126 (when Y is larger than zero), the largest D defined in step ST134 is used._nThat is, a process of reducing the number of slots of the slave station assigned the largest amount to the pre-assigned value by "1" is performed, and this process is repeated Y times in total, and all slots are assigned to each slave station. Process.
[0064]
Returning to FIG. 12, the information on the number of TDMA slots determined by estimating the buffer amount in the slave station by such various methods is selected and controlled by the selection unit 26 as soon as it is determined.
[0065]
FIG. 19 shows an example of the contents of this selection control. FIG. 19 assumes a case where an uplink signal from a slave station to a master station and a downlink signal from the master station to a slave station have logically different transmission paths. In addition, there are a plurality of slave stations and the arrangement positions are various, and the distance between the slave station and the master station is different, but the transmission timing of the slave stations at other close positions is determined based on the transmission phase of the slave station at the farthest place. Transmission control for delaying is known. In FIG. 19, the above method is assumed and the timing of the farthest slave station is described as a representative.
[0066]
In FIG. 19, reference numeral 140 denotes a transmission timing in a child station uplink, 141 denotes a reception timing in a parent station uplink, 142 denotes a transmission timing in a parent station downlink, and 143 denotes a reception timing in a child station downlink.
[0067]
Here, the notification timing of TDMA slot information will be described. In FIG. 19, at time T1, the predicted remaining amount counted in the slave stations up to that time is sequentially notified for the number of slave stations. Assuming that the time required for the notification for the number of slave stations is WS1 and the delay time of the transmission path is S2, the master station finishes receiving these at time T4 after a lapse of (S1 + S2) time from time T1. At T4, the reception of the predicted remaining amount from all the slave stations ends. Thereafter, in the period S3, the TDMA slot allocation is determined by the algorithm shown in FIG. 13 described above, and the determined information is distributed to each slave station at the time T5, or the TDMA slot information is sequentially transferred after the time T5. Each slave station receives this, and from time T6, the slave station transfers information in the uplink direction according to the TDMA slot assignment value.
[0068]
According to this algorithm, in the uplink transmission from the slave station, information cannot be transferred using the TDMA slot determined based on the estimated remaining amount at times T1 to T6. As a result, the operation of the selecting unit 26 in FIG. 12 is such that, at times T1 to T6, the transfer is performed according to the pre-assignment information determined in advance in the pre-assigned TDMA slot information generating unit 2, and at other times, the TDMA by the above algorithm The TDMA slot information generated by the slot information generator 25 is selected.
[0069]
As mentioned above, thisReference Example 3Then, the idle channel is determined by changing the TDMA slot allocation using the remaining amount of information to be transmitted from the FIFO unit 7 of the slave station predicted at the last time point of the next frame, and the idle channel determination is required. There is an effect that an access control method and an access control device that can eliminate time and eliminate wasteful traffic due to idle cells during the idle line determination time and avoid a decrease in transmission efficiency can be obtained.
[0070]
Reference example 4.
SaidReference Example 3Although the configuration shown in FIG. 12 includes the inflow amount monitoring unit 23 and uses the predicted remaining amount y determined by the equation y = ax + b as the predicted remaining amount,Reference Example 2The calculation result of only the remaining amount described inReference Example 3It is also possible to introduce the exact same algorithm as. in this case,Reference Example 3Although the accuracy of the predicted value is slightly deteriorated as compared with the above, the inflow amount monitor unit 23 becomes unnecessary, and the circuit scale can be reduced.
FIG.Reference example 4FIG. 2 is a block diagram illustrating a main configuration of a master station and a slave station of an access control device to which the access control method is applied. 20, parts that are the same as or correspond to those in FIG. 12 are given the same reference numerals, and descriptions thereof will be omitted. In FIG. 20, 25 isReference Example 1The TDMA slot information generation unit 27 according to the methods (1), (2), (3), and (4) described in Prediction calculation for predicting the remaining amount of information remaining in the slave station at the endIn the departmentis there.
[0071]
thisReference example 4Thus, there is an effect that an access control method and an access control device that can reduce the circuit scale by eliminating the inflow amount monitoring unit 23 in the slave station are obtained.
[0072]
Embodiment 5.
FIG. 21 shows the structure of the present invention.Embodiment 5FIG. 2 is a block diagram illustrating a main configuration of a master station and a slave station of an access control device to which the access control method is applied. In FIG. 21, the same or corresponding parts as those in FIG. 1 are denoted by the same reference numerals, and description thereof is omitted. In FIG. 21, reference numeral 28 denotes an idle line storage unit for storing the number of an idle line when the idle line determination unit 1 determines an idle line; A TDMA slot information conversion unit (slot transfer relationship setting unit) that changes the allocation of the allocation slot generated by the assignment TDMA slot information generation unit 2 to a line that is not determined to be another idle line.
[0073]
Next, the operation will be described.
When the idle line determination unit 1 determines an idle line, the line number is stored in the idle line storage unit 28, and the pre-assigned capacity of the idle line is transferred to another non-idle line and distributed by the TDMA slot information conversion unit 30. Is done.
[0074]
As a first method of distributing the pre-assigned capacity of the idle line in this case, there is a method of securing a fixed amount as the minimum capacity and equally distributing the remaining capacity to other non-idle lines.
As a second method, there is a method of securing a fixed amount as a minimum capacity and distributing the remaining capacity in proportion to the preassign value of another non-idle line.
[0075]
FIG. 22 is an explanatory diagram showing the first method. In FIG. 22, reference numeral 31 indicates a state in which respective values are indicated on the lines A to D as the pre-assignment capacity. Reference numeral 32 denotes the capacity of the lines A to D after the slot information conversion. Now, when the line A is determined to be an idle line, when the minimum capacity is set to 2, the line capacity of the line number A becomes 2. Of the pre-assigned capacity of the line A, twelve are equally distributed to the other lines B, C, and D, and each is increased by four.
Thereafter, when information from the slave station arrives on the line A and it is determined that the line is not idle, the capacity returns to the original allocated capacity as indicated by 31.
The first method is characterized in that when there is an unused line, the remaining pre-assigned capacity excluding the minimum capacity of the line is evenly distributed to other lines, so that the increased bandwidth is set to be increased fairly. .
[0076]
FIG. 23 is an explanatory diagram showing the second method. In FIG. 23, reference numeral 33 denotes the capacity of the lines A to D after the slot information conversion.
When the line A is determined to be an idle line, and when the minimum capacity is set to 2, the capacity of the line A becomes 2 as in the first method. The remaining capacity 12 of the pre-assigned capacity 14 of the line A except for the minimum capacity 2 becomes 33 in proportion to the pre-assigned capacities 6, 12, and 18 assigned to the other B, C, and D lines, respectively. As shown, the capacity of the line A is increased by a minimum capacity of 2, the capacity of the line B is increased by 4, and the capacity of the line C is increased by 6.
In the second method, if there is a line that is not being used, it is proportionally distributed to other lines, so that in the case where charging is performed according to the pre-assignment band, an increase band can be set according to the charging amount. It has the feature.
[0077]
As mentioned above, thisEmbodiment 5With any of the above methods, there is an effect that an access control method and an access control device that can improve transmission efficiency for information having a long idle period with extremely high burstiness such as computer communication can be obtained.
[0078]
Reference example 5.
FIG.Reference example 5FIG. 2 is a block diagram illustrating a main configuration of a master station and a slave station of an access control device to which the access control method is applied. In FIG. 24, reference numeral 4b denotes multiplexing for generating and multiplexing the time lot allocation information of the slave stations to downlink information and distributing and transmitting the information to each slave station.Department,Numeral 34 denotes an inflow amount receiving unit for periodically receiving an inflow amount of information per unit time inputted to the FIFO unit in each slave station, and 35 denotes a number of the slave stations in a fair manner of an information amount to be transmitted by a plurality of slave stations. A common queue composed of FIFO and other data stored together-Reference numeral 36 denotes allocation information generation for generating allocation information of time slots by the number of stored information in the order of the numbers of the child stations stored in the common queue 35.In the departmentis there.
5 is the first embodiment andReference Examples 1, 2, 3, 4, and Fifth Embodiment, The TDMA slot information receiving unit indicated by,Department,7 is a FIFO unit, 22a is multiplexing on the slave station sideDepartment,23 isReference Example 2andReference Example 3This is the inflow amount monitor section indicated by.
[0079]
Next, the operation will be described.
FIG. 24 (b) shows the configuration of each slave station. In the slave station, information to be transmitted to the master station, which is input to the FIFO unit 7, is monitored by the inflow amount monitor unit 23 at regular intervals. The inflow amount thus added is added to a part of the transfer information to the master station and transferred to the master station.
[0080]
In the master station, the inflow amount receiving section 34 receives information such as the inflow amount from a plurality of slave stations, and stores information such as the numbers of the respective slave stations and the inflow amount in the common queue 35 in order. The allocation information generating unit 36 generates time lot allocation information of the slave stations in the order written in the common queue based on the information on the inflow amount, and multiplexes the information.Part 4In b, the information is multiplexed with the downlink information and distributed to each slave station.
[0081]
In each slave station, the pre-assigned TDMA slot information receiving unit 5 receives this time slot allocation information, delays the transmission timing by the delay unit 6a until the time slot to be transmitted by each slave station arrives, and sets the FIFO unit 7 Read the information stored in.
[0082]
As mentioned above, thisReference example 5According to the above, when a large amount of data is stored in the FIFO unit in a plurality of slave stations, more information is stored in the common queue 35 in the master station than in the generation cycle of the allocation information. It has the feature that the use efficiency of the transmission line becomes 100%, and thus there is an effect that an access control method and an access control device in which the use efficiency at the time of congestion of the transmission line is improved can be obtained.
[0083]
Reference Example 6.
SaidReference example 5Has the advantage that the efficiency is improved at the time of congestion.On the other hand, when the use of the transmission path is small, the information to be transmitted to the newly generated master station is notified to the master station of the amount of inflow to the FIFO unit, and Since transmission becomes possible after the allocation information has been sent to the slave station, it takes a long time before the transmission and the use efficiency of the transmission path is reduced.
thisReference Example 6In the case where the use of the transmission line is small and there is no information to be used for time slot allocation, the time slots are equally allocated to the slave stations. Work around.
[0084]
FIG.Reference Example 6FIG. 2 is a block diagram illustrating a main configuration of a master station and a slave station of an access control device to which the access control method is applied. In FIG. 25, the same or corresponding parts as those in FIG. 24 are denoted by the same reference numerals, and description thereof will be omitted. In FIG. 25, reference numeral 37 denotes an empty detection unit for detecting that no information is accumulated in the common queue 35, and reference numeral 38 denotes a uniform allocation signal generation for generating a uniform allocation signal for equally allocating a time slot to a slave station which is powered on. The unit 39 controls the timing of the equal allocation signal output from the equal allocation signal generation unit 38 by the time from when the equal allocation signal is distributed to the slave station, when the information is transmitted from the slave station, and transferred to the master station. A delay unit 40 for delaying is a selector for selecting either the allocation information generated by the allocation information generation unit 36 or the equal allocation signal generated by the equal allocation signal generation unit 38.TaReference numeral 41 denotes an effective cell detection unit for detecting that effective information is inserted in uplink data from a slave station, and reference numeral 51 denotes an allocation information deletion unit.
The configuration of the slave station is the same as that of FIG.
[0085]
In the master station shown in FIG. 25A, when the empty detection unit 37 detects that there is no allocation information to be generated from the contents of the common queue 35, the equal allocation signal generation unit 38 sends a signal to the slave station that is powered on. An allocation signal is generated evenly, and even when information is not accumulated in the common queue 35, information transmission in the down direction is performed. The information transferred from the slave station in accordance with the allocation signal from the equal allocation signal generation unit 38 is based on the timing at which the equal allocation signal output from the equal allocation signal generation unit 38 is transferred by the delay unit 39 to the information from the slave station. Is delayed until. When the valid cell detecting unit 41 detects that the information transmitted according to the equal allocation signal of the equal allocation signal generating unit 38 is a valid cell, the allocation information deleting unit 51 writes the information already written in the common queue 36. It has an allocation information deletion function for reducing the amount of information to be transmitted by one of the slave station numbers to be transmitted.
[0086]
Since this embodiment is configured as described above, it is not clear from which slave station the information to be transmitted in the upstream direction may be transmitted, that is, there is information for generating allocation information in the common queue 35. If not, by generating the allocation information equally for the slave stations, the use efficiency of the transmission path can be improved even if the information of each slave station does not accumulate much. Since the information transmitted from the slave station in accordance with the equal allocation signal is already notified to the master station in the sense of slot reservation and stored in the common queue, the information of the already allocated common queue is transmitted. By performing the rewriting that only the number of channels is reduced, it is possible to obtain an access control method and an access control apparatus that can secure more uplink channels for other slave stations and can further effectively use a transmission path. effective.
[0087]
Embodiment 6.
Each block in each of the above embodiments may be configured by hardware or realized by software.
[0088]
【The invention's effect】
As described above, according to the first aspect of the present invention, the slot information setting step for fixedly setting the slot information for the slot to be allocated to each slave station in advance, and the slot information set in the slot information setting step are An idle line determination step of determining an idle line based on communication performed between the slave station and the master station based on idle line information about the idle line determined in the idle line determination step. For the slot information set in the slot information setting step, a slot transfer relation setting step of setting a transfer relation for transferring a slot assigned to the slave station determined to be the idle line to another slave station; Based on the new slot information according to the transfer relationship set in the slot transfer relationship setting process, each of the slave stations can And transmitting the information to be sent to the master station using the self-assigned slot, so that the slot of the idle line is changed to the slot number of the transfer destination line, and the transfer destination In the slave station having the above, the band due to the transferred line is increased and the transmission efficiency is increased, and the overall transmission efficiency between the slave station and the master station is also improved.
[0089]
According to the second aspect of the present invention, the idle channel is determined based on the idle information of the channel transmitted from each slave station to the master station using the slot learned based on the slot information set in the slot information setting process. Determining an idle line in the process, and based on the idle line information on the idle line determined in the idle line determining process, based on the slot information set in the slot information setting process, the slave station determined to be the idle line. Setting of the transfer relationship when transferring the slot assigned to another slave station is performed on the master station side by a slot transfer relationship setting process, and according to the transfer relationship set by the slot transfer relationship setting process. Each slave station knows its own assigned slot based on the slot information, and sends information to be sent to the master station using the assigned slot. Since the transmission is performed in the process, the slot of the idle line determined based on the idle information sent from each of the slave stations to the master station is changed to the slot number of the transfer destination line, and the slave station that has become the transfer destination In this case, the bandwidth of the transferred line is increased, so that the transmission efficiency is increased, and the overall transmission efficiency between the slave station and the master station is also improved.
[0090]
According to the third aspect of the present invention, the idle line is set by the idle information of the line transmitted from each slave station to the master station using the slot learned based on the slot information set in the slot information setting process. Determined in the idle line determination step, based on the idle line information on the idle line determined in the idle line determination step, based on the slot information set in the slot information setting step broadcast from the master station, The setting of the transfer relationship for transferring the slot allocated to the slave station determined to be the idle line to another slave station is performed in each slave station in the slot transfer relationship setting process, and is set in the slot transfer relationship setting process. Each slave station knows its own assigned slot based on the slot information according to the transfer relationship, and should use the own assigned slot to send to the master station. Since the information is transmitted in the transmission process, the transfer relationship is set in each slave station, so that the burden on data processing of the master station is reduced as compared with the case where the transfer relationship is set in the master station. effective.
[0091]
According to the fourth aspect of the present invention, the idle detecting unit detects idle information of a line transmitted from each slave station to the master station by using a slot learned based on the slot information set in the slot information setting process. An information detection step, an idle line determination step having a determination step of determining an idle line on the slave station side based on the idle information detected in the idle information detection step, and a determination result by the idle line determination step. Originally, regarding the slot information set in the slot information setting process broadcast from the master station, the assignment relationship when assigning the slot assigned to the slave station determined to be the idle line to another slave station. Is set in the slot assignment relationship setting process on the slave station side, and each slave station knows its own assigned slot in accordance with the assignment relationship set in the slot assignment relationship setting process. Since the information to be sent to the master station is transmitted in the transmission process using the self-assigned slot, the determination of the idle line and the setting of the transfer relationship are performed in each slave station. And the burden on the data processing of the master station is further reduced as compared with the case of performing the above determination and the setting of the transfer relationship.
[0092]
According to the invention described in claim 5, there is no valid information included in the cell transmitted from the slave station to the master station using the slot according to the slot information set in the slot information setting process. Is used as idle information for determining an idle line in the idle line determination process, the idle line is determined based on the identification information included in the information transmitted from the slave station to the master station on a cell basis. There are effects that can be done.
[0093]
Claim6According to the described invention, slot information setting means for fixedly setting slot information on slots to be allocated to each slave station in advance, and the slot information set by the slot information setting means are broadcast to the slave stations. An idle line is established by a first broadcast means and communication performed between the slave station and the master station based on the slot information broadcast to each slave station by the first broadcast means. An idle line determining means for determining, and a slave station determined to be the idle line with respect to the slot information set by the slot information setting means based on idle line information on the idle line determined by the idle line determining means. Transfer setting means for setting a transfer relationship for transferring a slot assigned to another slave station, and the slot transfer relationship setting means And transmitting means for transmitting the information to be sent to the master station using the self-assigned slot, based on the new slot information in accordance with the set transfer relationship. Since the idle line slot determined by the idle line determination unit is changed to the slot number of the transfer destination line, the band assigned by the transferred line increases in the slave station serving as the transfer destination. And the transmission efficiency increases, and the overall transmission efficiency between the slave station and the master station also increases.
[0094]
Claim7According to the invention described above, the idle line is determined by the idle line determination unit based on the idle information of the line that each slave station sends to the master station using the slot known based on the slot information set by the slot information setting unit. Determined in the above, based on the idle line information about the idle line determined by the idle line determination means, for the slot information set by the slot information setting means, assigned to the slave station determined to be the idle line Setting of a transfer relationship for transferring a slot to another slave station is performed by slot transfer relationship setting means, and slot information according to the transfer relationship set by the slot transfer relationship setting means is transmitted to each slave station in a second manner. Broadcasting is performed by the broadcasting means, and each of the slave stations is self-allocated based on the slot information broadcast to each of the slave stations by the second broadcasting means. A transmission means for knowing a slot and transmitting information to be transmitted to the master station using the self-allocated slot, so that the idle line determination means is transmitted from each slave station to the master station. The slot of the idle line determined from the incoming idle information is changed to the slot number of the transfer destination line, and the transfer destination slave station increases the band due to the transferred line, thereby increasing the transmission efficiency. This has the effect of improving the overall transmission efficiency between the station and the master station.
[0095]
Claim8According to the invention described above, the idle line is determined by the idle line determination unit based on the idle information of the line that each slave station sends to the master station using the slot known based on the slot information set by the slot information setting unit. The slot broadcasted from the master station by the first broadcast means set by the slot information setting means based on the idle line information on the idle line determined by the idle line determination means. With respect to the information, the setting of the transfer relationship for transferring the slot assigned to the slave station determined to be the idle line to another slave station is performed by each slave station by the slot transfer relationship setting means, and the slot transfer relationship setting means performs the setting. Each slave station knows its own assigned slot based on slot information according to the set transfer relationship, and uses the own assigned slot to Since the information to be transmitted is configured to be transmitted by the transmitting means, the setting of the transfer relation is performed by the slot transfer relation setting means in each slave station. This has the effect of reducing the data processing burden on the master station.
[0096]
Claim9According to the described invention, idle information detecting means for detecting idle information of a line transmitted from each slave station to the master station using a slot learned based on slot information set by the slot information setting means, An idle line determination unit having a determination unit that determines an idle line on the slave station side based on the idle information detected by the idle information detection unit, based on a determination result by the idle line determination unit, When the slot information set by the slot information setting means broadcast from the master station by the first broadcasting means is transferred to another slave station, the slot assigned to the slave station determined to be the idle line. Is set by the slot assignment relation setting means, and each of the slave stations assigns its own assigned slot according to the assignment relation set by the slot assignment relation setting means. The transmitting means transmits the information to be sent to the master station using the self-assigned slot, so that the judgment of each slave station determines the idle line, and the slot assignment relation setting means sets the idle line. Since the setting of the transfer relationship is performed, there is an effect that the burden on the data processing of the master station is further reduced as compared with the case where the determination of the idle line and the setting of the transfer relationship are performed at the master station.
[Brief description of the drawings]
FIG. 1 is a block diagram showing main parts of a master station and a slave station of an access control device to which an access control method according to Embodiment 1 of the present invention is applied.
FIG. 2 is a flowchart illustrating an algorithm for creating a conversion table indicating a transfer relationship of an access control device to which the access control method according to the first embodiment of the present invention is applied;
FIG. 3 is an explanatory diagram showing an example of a chain configuration and a conversion table of an access control device to which the access control method according to the first embodiment of the present invention is applied;
FIG. 4 is a block diagram showing main parts of a master station and a slave station of an access control device to which an access control method according to a second embodiment of the present invention is applied.
FIG. 5 is a block diagram showing main parts of a master station and a slave station of an access control device to which an access control method according to Embodiment 3 of the present invention is applied.
FIG. 6 is a block diagram showing a main part of a master station of an access control device to which an access control method according to a fourth embodiment of the present invention is applied.
FIG. 7 is a block diagram illustrating each configuration for realizing a function of detecting a highest load line by a highest load line detection unit of the access control device to which the access control method according to the fourth embodiment of the present invention is applied;
FIG. 8 is a block diagram showing each configuration for realizing a function of detecting a highest load line by a highest load line detection unit of an access control device to which the access control method according to the fourth embodiment of the present invention is applied;
FIG. 9 is a block diagram showing each configuration for realizing a function of detecting a highest load line by a highest load line detection unit of the access control device to which the access control method according to the fourth embodiment of the present invention is applied;
FIG. 10Reference Example 1FIG. 2 is a block diagram showing main parts of a master station and slave stations of an access control device to which the access control method of FIG. 1 is applied.
FIG. 11Reference Example 2FIG. 2 is a block diagram showing main parts of a master station and slave stations of an access control device to which the access control method of FIG. 1 is applied.
FIG.Reference Example 3FIG. 2 is a block diagram showing main parts of a master station and slave stations of an access control device to which the access control method of FIG. 1 is applied.
FIG. 13Reference Example 35 is a flowchart illustrating an algorithm for generating TDMA slot information from a predicted remaining amount value in an access control device to which the access control method of FIG.
FIG. 14Reference Example 3FIG. 4 is an explanatory diagram showing a method of increasing and decreasing a band in an access control device to which the access control method of FIG.
FIG.Reference Example 35 is a flowchart showing an algorithm when increasing a band in an access control device to which the access control method of FIG.
FIG.Reference Example 310 is a flowchart showing an algorithm when a bandwidth is reduced in an access control device to which the access control method of the present invention is applied.
FIG.Reference Example 35 is a flowchart showing an algorithm when increasing a band in an access control device to which the access control method of FIG.
FIG.Reference Example 310 is a flowchart showing an algorithm when a bandwidth is reduced in an access control device to which the access control method of the present invention is applied.
FIG.Reference Example 3FIG. 5 is a sequence diagram showing notification timing of TDMA slot information in an access control device to which the access control method of FIG.
FIG.Reference example 4FIG. 2 is a block diagram showing main parts of a master station and slave stations of an access control device to which the access control method of FIG. 1 is applied.
FIG. 21 of the present invention.Embodiment 5FIG. 2 is a block diagram showing a main part of a master station of an access control device to which the access control method of FIG.
FIG. 22 of the present invention.Embodiment 5FIG. 4 is an explanatory diagram showing a first method of distributing pre-assigned capacity of an idle line in an access control device to which the access control method of FIG.
FIG. 23 of the present invention.Embodiment 5FIG. 11 is an explanatory diagram showing a second method of distributing the pre-assigned capacity of the idle line in the access control device to which the access control method is applied.
FIG. 24Reference example 5FIG. 2 is a block diagram showing main parts of a master station and slave stations of an access control device to which the access control method of FIG. 1 is applied.
FIG. 25Reference Example 6FIG. 2 is a block diagram showing main parts of a master station and slave stations of an access control device to which the access control method of FIG. 1 is applied.
FIG. 26 is a configuration diagram showing a subscriber line to which a conventional access control method and device are applied.
[Explanation of symbols]
1 idle line determination unit (idle line determination unit), 1a idle line determination unit (determination unit), 2 pre-assigned TDMA slot information generation unit (slot information setting unit), 3, 3a, 30 TDMA slot information conversion unit (slot transfer) Relationship setting means), 4 multiplexing unit (first broadcasting means, second broadcasting means), 4a multiplexingDepartment,4b MultiplexingDepartment,6,6a delayDepartment,7 FIFO (transmission means), 20 remaining amount extraction comparisonDepartment,21 Frame remaining monitor at end of frameDepartment,22 multiplexingDepartment,22a multiplexingDepartment,23 Inflow monitoringDepartment,24,27 Prediction operationDepartment,25 TDMA slot information generationDepartment,26 choiceDepartment,35 Common Cu-36 Assignment information generationDepartment,40 selectTa.

Claims (9)

In an access control method for connecting a master station and a plurality of slave stations via a transmission line and performing time-division digital communication from the slave station to the master station using a slot assigned to each slave station,
A slot information setting step of fixedly setting slot information about slots to be assigned to each slave station in advance;
An idle line determining step of determining an idle line by communication performed between the slave station and the master station based on the slot information set in the slot information setting step;
Based on the idle line information on the idle line determined in the idle line determination step, the slot information set in the slot information setting step is used to determine whether the slot assigned to the slave station determined to be the idle line is different. A slot transfer relationship setting process for setting a transfer relationship for transfer to a slave station of
Based on the new slot information according to the transfer relationship set by the slot transfer relationship setting process, each slave station knows its own assigned slot, and sends information to be sent to the master station using the own assigned slot. An access control method, comprising: a transmitting step of transmitting. In the idle line determination step, the idle line is determined by the idle information of the line sent from each slave station to the master station using the slot learned based on the slot information set in the slot information setting step,
In the slot transfer relationship setting step, based on the idle line information on the idle line determined in the idle line determination step, based on the slot information set in the slot information setting step, the slave station determined to be the idle line Perform the setting of the transfer relationship when transferring the assigned slot to another slave station, the master station side,
In the transmission step, each slave station knows its own assigned slot based on the slot information according to the assignment relation set in the slot assignment relation setting step, and sends it to the master station using the assigned slot. 2. The access control method according to claim 1, wherein information to be transmitted is transmitted. In the idle line determination step, the idle line is determined by the idle information of the line sent from each slave station to the master station using the slot learned based on the slot information set in the slot information setting step,
In the slot transfer relationship setting step, based on the idle line information on the idle line determined in the idle line determination step, based on the slot information broadcast from the master station set in the slot information setting step, Perform the setting of the transfer relationship to transfer the slot assigned to the slave station determined to be an idle line to another slave station in each slave station,
In the transmission step, each slave station should know its own assigned slot based on the slot information according to the assignment relation set in the slot assignment relation setting step, and send it to the master station using the assigned slot. The access control method according to claim 1, wherein the information is transmitted. An idle information detecting step of detecting idle information of a line transmitted from each slave station to the master station using a slot known based on the slot information set in the slot information setting step; An idle line determination step having a determination step of determining an idle line on the slave station side based on the idle information detected in,
In the slot assignment relationship setting step, based on the determination result of the idle line determination step, the slot information broadcast from the master station set in the slot information setting step is allocated to the slave station determined to be the idle line. The setting of the transfer relationship when transferring the slot being transferred to another slave station is performed on the slave station side,
In the transmitting step, each of the slave stations knows the self-assigned slot according to the assignment relation set in the slot assignment relation setting step, and transmits information to be sent to the master station using the self-assigned slot. The access control method according to claim 1, wherein The idle information for determining the idle line in the idle line determination step is valid information included in a cell transmitted from the slave station to the master station using the slot according to the slot information set in the slot information setting step. The access control method according to any one of claims 2 to 4, wherein the access control information is identification information indicating that the user does not exist. An access control device that connects a master station and a plurality of slave stations via a transmission line such as an optical fiber and performs time-division digital communication from the slave station to the master station using a slot assigned to each slave station,
Slot information setting means for fixedly setting in advance slot information about the slot to be allocated to each slave station,
First broadcasting means for broadcasting the slot information set by the slot information setting means to each of the slave stations;
Based on the slot information broadcast to each of the slave stations by the first broadcast means, an idle line determination means for determining an idle line by communication performed between the slave station and the master station; ,
Based on the idle line information about the idle line determined by the idle line determination unit, the slot information set by the slot information setting unit is used to determine the slot assigned to the slave station determined to be the idle line. Slot transfer relationship setting means for setting a transfer relationship for transfer to a slave station of
Based on the new slot information according to the transfer relationship set by the slot transfer relationship setting means, each slave station knows its own assigned slot, and sends information to be sent to the master station using the own assigned slot. An access control device, comprising: a transmission unit for transmitting. The idle line determining means determines the idle line based on the idle information of the line that each slave station sends to the master station using the slot learned based on the slot information set by the slot information setting means,
The slot assignment relation setting means, based on the idle line information on the idle line determined by the idle line determination means, based on the slot information set by the slot information setting means, to the slave station determined to be the idle line Set transfer relationship to transfer the assigned slot to another slave station,
A second broadcast unit that broadcasts slot information according to the transfer relationship set by the slot transfer relationship setting unit to each of the slave stations;
The transmitting means, based on the slot information broadcast to each of the slave stations by the second broadcasting means, allows each of the slave stations to know its own assigned slot, and uses the own assigned slot to 7. The access control device according to claim 6, wherein information to be sent to the access control device is transmitted. The idle line determining means determines the idle line based on the idle information of the line that each slave station sends to the master station using the slot learned based on the slot information set by the slot information setting means,
The slot assignment relationship setting means is broadcasted from the master station by the first broadcasting means set by the slot information setting means, based on the idle line information on the idle line determined by the idle line determining means. For each of the above-mentioned slot information, setting of a transfer relationship for transferring a slot assigned to the slave station determined to be the idle line to another slave station is performed in each slave station,
The transmitting means should be such that each slave station knows its own assigned slot based on the slot information according to the transfer relation set by the slot transfer relation setting means, and sends it to the master station using the own assigned slot. 7. The access control device according to claim 6, wherein information is transmitted. Idle information detecting means for detecting idle information of a line transmitted from each slave station to the master station using a slot known based on the slot information set by the slot information setting means; Idle line determination means having determination means for determining an idle line on the slave station side based on the detected idle information,
The slot assignment relation setting means, based on the determination result by the idle line determination means, for the slot information broadcast from the master station by the first broadcast means set by the slot information setting means, Setting of the transfer relationship when transferring the slot assigned to the determined slave station to another slave station is performed on the slave station side,
The transmitting means is characterized in that each of the slave stations knows its own assigned slot according to the transfer relation set by the slot transfer relation setting means, and transmits information to be sent to the master station using the own assigned slot. The access control device according to claim 6, wherein

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