JP3019855B2 - ATM transmission equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ATM cell transmission apparatus for performing communication using ATM cells, and more particularly to a technique for suppressing the use efficiency of a transmission line used for communication and the generation of invalid traffic.

[0002]

2. Description of the Related Art In a data transfer format called ATM, an ATM cell having a fixed data length is used as one unit of data to be transmitted. As shown in FIG. 5, this ATM cell is actually composed of 53 bytes of data consisting of a cell header composed of 5 bytes of data, followed by a 48 byte information field. Since the ATM cells to be transferred have a fixed length, in ATM data transmission, data can be transmitted only by repeating relatively simple processing, and high-speed data transmission is realized.

In some data communication services employing ATM, a TCP / IP protocol is used for an upper layer. Communication using this TCP / IP protocol is standardized (IP over ATM: RFC 1483).
And so on. In this case, AAL5 is used as the ATM adaptation layer (AAL). In the data communication using AAL5, since the packet size of the upper layer is generally larger than the data size (48 bytes) of the information field of the ATM cell, the packet of the upper layer is divided into a plurality of ATM cells. Will be transferred.

[0004] Normally, when data is transmitted by ATM, an AT switch is used by a node called an ATM switch.
The M cell is relayed, and the ATM cell is transmitted from the originating terminal to the target terminal. Here, the case where the ATM switch has a function of discarding invalid ATM cells as disclosed in JP-A-8-163141, and the case where a packet is transmitted from the transmitting terminal to the receiving terminal. Assuming that ATM cell congestion and buffer overflow occur in one ATM switch,
Although it is possible to suppress the generation of invalid traffic on the transmission line on the output side of the ATM switch,
Invalid traffic is still being transmitted on the transmission path on the input side of the M switch.

Further, in such a system, ATM cell congestion and buffer overflow in an ATM switch are used as triggers for invalid ATM cell discarding, and no consideration is given to ATM cell loss due to errors on a transmission line. For example, wireless is a transmission path with a very high probability of occurrence of an error. As an ATM system using wireless transmission lines, there is a wireless ATM. Below, the conventional wireless AT
M shows the system of FIG.

FIG. 11 shows a basic system configuration of a wireless ATM system. The system shown in FIG.
1, slave stations 12, 13, 14 and terminal devices 15, 16, 17
And a network 18.

In FIG. 11, a base station 11 and each slave station 12
Are connected by a wireless line. Each of the slave stations 12 to 14 is connected to terminal devices 15 to 17.
The base station 11 is connected to the network 18 via an optical fiber or a metal cable.

[0008] Terminal devices 15 to 17 and network 18
Transmit and receive data using an ATM cell as a minimum unit of data to be transmitted.

FIG. 12 shows a protocol stack configuration related to the user plane (U plane) of the wireless ATM system shown in FIG. The base station 11 is connected to a network 18 via a node 19.

As shown in FIG. 12, each of the terminal devices 15-1
7 are a physical layer "PHY", an ATM layer "ATM", and an ATM adaptation layer "AA".
L "and an application layer" AP ".

The protocols of the slave stations 12 to 14 and the base station 11 include a physical layer "PHY", an ATM layer "ATM", a wireless layer "Wireless", a data link layer "DLC", and a media access control layer "MA".
C ". The node 19 has a physical layer "PH
Y "and an ATM layer" ATM ".

The U-plane of the base station 11 and each of the slave stations 12 to 14 is provided with an ATM adaptation layer “AA”.
Layers above "L" do not terminate. The terminal devices 15 to 17
A node 19 included in the network 18
The connection is seamlessly performed in the layer of the M layer “ATM”.
The wireless communication path between the base station 11 and each of the slave stations 12 to 14 includes:
In each wireless communication path, the ATM layer "AT
There may be a plurality of virtual paths VP and virtual channels VC that are logical links of “M”.

FIG. 13 shows the flow of ATM cells C1 to C8 when data is transmitted from the terminal device 15 to the network 18 in the wireless ATM system shown in FIG. In the example of FIG. 13, the slave station 12 becomes a transmitting device, the base station 11 becomes a receiving device, and the terminal device 15
The situation where a TM cell is being transmitted is shown.

As shown in FIG. 13, the terminal device 15 sends the first ATM cell C1 to the eighth ATM cell C1 to the slave station 12.
When transmitting the cell C8 sequentially, the slave station 12 and the base station 1
1 in the radio section between the second ATM cell C2
Error occurs in the base station 11, the first ATM cell C
The first and third to eighth ATM cells C3 to C8 are received. Therefore, the base station 11
The first ATM cell C1 and the third to eighth ATM cells C3 to C8 are transmitted.

The base station 11 and the slave station 12 are provided with a transmitting device and a receiving device as shown in FIG. The transmission device is provided with an input unit for receiving an ATM cell, a transmission buffer and a transmission unit. ATM cells waiting to be transmitted are temporarily stored in the transmission buffer.

The receiving device includes a receiving unit, a receiving buffer, and an output unit. The ATM cells received by the receiving unit are temporarily stored in a receiving buffer, extracted as needed, and transmitted from the output unit.

FIG. 15 shows a transfer sequence of the ATM cells C1 to C8 in the wireless section in the example of FIG. Also,
In the example of FIG. 15, a TDMA (Time Division Multiplexing Communication) system is used for data communication in a wireless section between the slave station 12 and the base station 11, and three ADMAs per TDMA frame.
It is assumed that a TM cell can be transferred.

In the example of FIG. 15, the first to third ATM cells C1 to C3 are transferred in the first TDMA frame. At this time, an error has occurred in the second ATM cell C2 in the wireless section. Therefore, the base station 11 receives only the first ATM cell C1 and the third ATM cell C3.

When the transfer in the first TDMA frame is completed, five ATM cells C4, C5, C6, C7 and C8 remain in the transmission buffer of the slave station 12. And the next T
In the DMA frame, the fourth to sixth ATM cells C4 to C6 are transferred. By this transfer, the base station 1
One receive buffer has five ATM cells C1, C3, C4,
Receive C5 and C6.

When the transfer in the second TDMA frame is completed, two ATM cells C7 and C8 remain in the transmission buffer of the slave station 12. Then, in the third TDMA frame, the remaining two ATM cells C7 and C8 are transferred.

Consequently, in this example, the base station 11 receives seven ATM cells C1, C3, C4, C5, C6, C7 and C8. Then, the base station 11 sends seven ATM cells C1, C3, C4, C5, C6, C7 to the network 18.
And C8.

[0022]

At present, various services can be provided by a network employing ATM. As an example, it is required that a user's terminal device be connected seamlessly to an ATM network by wireless.

However, in a data communication system using wireless communication, errors may occur in ATM cells at a relatively high frequency in a transmission path in a section where wireless communication is performed.

In a certain data communication service employing ATM, a TCP / IP protocol is used for an upper layer. The communication using the TCP / IP protocol is realized according to a standardized protocol (IP over ATM: RFC1483). In this case, “AAL type 5” is used as the ATM adaptation layer (AAL).

This ATM adaptation layer (AA)
L) In data communication using type 5, since the packet size of the upper layer is generally larger than the data size (48 bytes) of the information field of the ATM cell, the packet of the upper layer is divided into a plurality of ATM cells. Is transmitted in the form of

As described above, one packet includes a plurality of ATs.
When divided into M cells and transmitted, one or more ATM cells among them cause an error in the transmission path, and the packet data of the terminal device is controlled by error control (forward error correction: FEC). Otherwise, the packet itself becomes an invalid packet containing errors.

When retransmission is performed in the control of an upper layer, retransmission of a packet occurs as a result. in addition,
When a wireless section exists in the transmission path, the error probability of the ATM cell is significantly higher than that in the wired section, and thus there is a high possibility that an invalid packet as described above will occur.

As described above, if at least one erroneous ATM cell is included in a packet transferred as a plurality of ATM cells, the entire packet is finally discarded as an invalid packet. Transmission of other ATM cells that have not occurred is wasted as a result.

An object of the present invention is to suppress the occurrence of invalid traffic in an ATM transmission device in which the size of a packet used for data transfer is larger than the size of an ATM cell.

[0030]

A feature of the present invention to achieve the above object is that an ATM cell is transmitted and received via a communication path including a transmitting device and a receiving device, and information of an ATM cell header is referred to. An ATM transmission device in which a plurality of ATM cells constituting a protocol data unit are continuously input to a transmission device by performing data communication using a packet by using an AAL that can identify a PDU boundary of an ATM adaptation layer (AAL). AT on device
A cell arrival identifying unit for identifying the success or failure of the arrival of the M cell; a cell arrival notifying unit for notifying the identification result of the cell arrival identifying unit as an ATM cell arrival confirmation notification from the receiving device to the transmitting device; By referring to the transmission buffer for temporarily storing the ATM cell and the payload type, virtual channel identifier and virtual path identifier fields included in the header of the ATM cell, one protocol data unit of the common convergence sublayer is formed. Group management means for managing a plurality of ATM cells as one group; arrival notification receiving means for receiving the ATM cell arrival acknowledgment notification from the receiving device to the transmitting device;
ATM where non-delivery was detected by TM cell arrival confirmation notification
A group data deletion unit for deleting all ATM cells belonging to the group including cells from the transmission buffer; and a protocol data unit of a deletion target group when the group data deletion unit deletes ATM cells from the transmission buffer. ATM cell (End of Packet cell) having a flag in the payload type field of the ATM cell header indicating that it is the last ATM cell to be processed.
l: EOP cell transmitting means for transmitting the EOP cell to the receiving apparatus, and means for discarding the corresponding ATM cell when an ATM cell belonging to the discarded PDU is inputted.
It is in the TM transmission device.

According to the present invention, when the ATM cell constituting the protocol data unit (PDU) is continuously input to the transmitting device when one or a plurality of virtual channels exist on the line, The transmitting device determines an invalid ATM cell and discards it.

The transmission buffer of the transmission device stores the AT before transmission.
Store the M cell temporarily. The group management means of the transmission device determines the payload type included in the header of the ATM cell.
(PT), virtual channel identifier (VCI) and virtual path identifier (VPI) by referring to the fields, a plurality of ATM cells constituting one protocol data unit (PDU) of the common convergence sublayer (CPCS) can be converted into one ATM cell. Manage as a group.

The cell arrival identifying means of the receiving device identifies whether the ATM cell has arrived at the receiving device. The identification result is notified from the receiving device to the transmitting device as an ATM cell arrival confirmation notification by the cell arrival notifying means.

[0034] The arrival notification receiving means of the transmitting device receives the ATM cell arrival confirmation notification notified from the receiving device to the transmitting device. The group data deletion means of the transmission device deletes from the transmission buffer all the ATM cells belonging to the group including the ATM cells whose non-delivery is detected by the ATM cell arrival confirmation notification received by the arrival notification receiving means.

Further, the group data deleting means may be an AT.
When the M cell is deleted from the transmission buffer, the EOP cell transmitting means sets a flag indicating that it is the last ATM cell constituting the protocol data unit (PDU) of the deletion target group to the payload type (PT ) Generate an ATM cell in the field, and transmit the generated ATM cell as an EOP cell to the receiving device.

The terminal device to which the packet is transmitted is notified of the boundary of the protocol data unit (PDU) by the EOP cell. That is, this EOP cell is one P
It can be recognized that this is the last ATM cell of the DU.

The ATM belonging to the group to be deleted
When a cell is entered, the corresponding A
Discard the TM cell.

Therefore, if an error occurs in one or more ATM cells and the ATM cells do not reach the receiving device correctly, the same protocol data unit (PDU) is used.
Are invalidated by the transmitting device.

Since the transmitting apparatus determines and discards the invalid ATM cell before transmission, it is possible to suppress transmission of invalid traffic to the transmission path and the network.

Preferably, a number adding means for adding a sequence number to an ATM cell to be transmitted is provided, and in the receiving device, the cell arrival identifying means determines whether or not the ATM cell has arrived based on the received sequence number. To detect.

According to the present invention, in the receiving apparatus, the ATM
In addition to the presence or absence of a cell error, it is possible to detect the loss of an ATM cell. This makes it possible for the transmitting device to discard invalid ATM cells even when ATM cells are lost in the transmission path.

Preferably, when a plurality of virtual channels exist on a line between a transmitting device and a receiving device and ATM cells having different virtual path identifiers and virtual channel identifiers are mixedly inputted, the transmitting device And the receiving device are AT
A different logical transmission link is established for each virtual channel of the M layer, and the group management means independently manages transmission and reception of ATM cells for each established logical transmission link.

According to the present invention, a plurality of virtual channels exist on a radio line between a transmitting device and a receiving device, and different virtual path identifiers (VPIs) and different virtual channel identifiers (VCIs).
Even in a case where ATM cells having the following are mixed, the transmitting apparatus and the receiving apparatus must perform a virtual channel (VP / VP) of the ATM layer in order to discard invalid ATM cells in the transmitting apparatus.
A different logical transmission link is established for each VC). And
The success or failure of the arrival of the ATM cell is confirmed for each established logical transmission link.

Each logical transmission link, ie, virtual channel
For each (VP / VC), the transmitting device manages the success or failure of the ATM cell transmission, and the receiving device manages the success or failure of the ATM cell reception. As a result, a plurality of virtual channels (VP
/ VC) exists, the transmission device is invalid A
The TM cell can be discarded.

Preferably, when a plurality of virtual channels exist on a line between a transmitting device and a receiving device, and ATM cells having different virtual path identifiers and virtual channel identifiers are mixedly inputted, the receiving device receives the data. A sequence number notifying means for notifying the transmission device of the sequence number of the ATM cell whose reception has failed from the reception device to the transmission device; a table holding the association between the sequence number and the group in the transmission device; A group specifying unit is provided for specifying a group to which the unreachable ATM cell belongs based on the sequence number notified from the unit and the contents of the table.

According to the present invention, the association between the sequence number and the group is held in the table of the transmitting device. By referring to this table, the sequence number corresponding to the sequence number notified from the sequence number notifying means is referred to. The group to which the undelivered ATM cell belongs can be specified.

Therefore, even if a plurality of virtual channels exist on the transmission path between the transmitting device and the receiving device, and ATM cells having different virtual path identifiers and virtual channel identifiers are mixed, the transmitting device becomes invalid. ATM cells can be discarded.

In the ATM transmission apparatus of the present invention, an ATM cell which becomes invalid even if transmitted is transmitted to the transmission apparatus without terminating an upper layer located above the ATM layer.
Judgment can be made using only the information of the TM layer and discarded. In addition, a plurality of virtual channels (VP / VC)
, It is possible to discard invalid ATM cells before transmission.

That is, since invalid ATM cells are not transmitted on the transmission line, the band of the transmission line can be used effectively, and transmission of invalid traffic to the network is suppressed.

[0050]

DESCRIPTION OF THE PREFERRED EMBODIMENTS (First Embodiment) A of this embodiment
The configuration and operation of a wireless ATM system assumed to be a TM transmission device are shown in FIGS. 1 to 5, FIGS. 11 and 12.

In the present invention, the transmission path between the transmitting device and the receiving device may be wired or wireless. Here, a case where the present invention is applied to a wireless ATM system will be described, taking as an example a case of wireless having a high probability of occurrence of an error on a transmission path.

FIG. 1 shows a base station 11 and slave stations 12 of this embodiment.
FIG. 2 is a block diagram illustrating a configuration of a transmission device 100 and a reception device 200 of an ATM transmission device installed in the system. FIG. 2 shows FIG.
5 is a flowchart showing the operation of the transmission device 100 and the reception device 200 of FIG.

FIG. 3 shows the transmitting apparatus 100 and the receiving apparatus 2 shown in FIG.
It is a sequence diagram which shows the example of ATM cell transmission during 00. FIG. 4 is a schematic diagram showing the flow of ATM cells transferred from the terminal device 15 to the node 19 in the ATM transmission device of this embodiment. FIG. 5 is a map showing the configuration of the ATM cell.

FIG. 11 is a block diagram showing the basic configuration of a wireless ATM system. FIG. 12 shows a wireless ATM of this embodiment.
It is a protocol stack figure in a system.

As shown in FIG. 4, the wireless ATM of this embodiment
The system includes a base station 11, a slave station 12, a terminal device 15, a network 18, and a node 19. In order to secure a wireless communication line between the base station 11 and the slave station 12, a transmission device 100 and a reception device 200 are installed in each of the base station 11 and the slave station 12.

Referring to FIG. 1, a transmitting apparatus 100 includes an input unit 101, a transmission buffer 102, a transmitting unit 103, and a receiving unit 1.
04, transmission cell management unit 105 and EOP (End of Packe
t) It is composed of a cell generator 106. The receiving device 200 includes a receiving unit 201, a receiving buffer 202, an output unit 2
03, a reception cell management unit 204 and a transmission unit 205.

ATM cells input to transmitting apparatus 100 are temporarily stored in transmission buffer 102 via input section 101. ATM held in transmission buffer 102
The cells are read out in order as needed, and
Is transmitted as a wireless signal to the receiving apparatus 200. In practice, one or more ATM cells are transferred using an arbitrary slot on a TDMA signal frame.

The ATM cells received by the receiving device 200 on the base station 11 are temporarily stored in the receiving buffer 202, read as necessary, and sent to the node 19 via the output unit 203. .

The ATM transmission device of this embodiment is based on the premise that packet data transfer is performed using the type 5 of the ATM adaptation layer (AAL). ATM
In the type 5 of the adaptation layer (AAL), data is managed for each unit called a protocol data unit (PDU).

In this embodiment, it is assumed that the size of the unit packet (PDU) managed in the upper layer is larger than the size of the ATM cell. Each packet is decomposed into a plurality of ATM cells and transferred, so that a plurality of ATM cells are continuously input to the transmission device 100.

In this embodiment, when a plurality of ATM cells are continuously input to the transmitting apparatus 100, the transmitting apparatus 100
Is characterized in that invalid ATM cells are determined and discarded.

ATM adaptation layer (AAL)
When transmitting a packet using type 5, the transmitting apparatus 100 refers to the payload type PT field in the ATM cell header and the fields of the virtual channel identifier VCI and the virtual path identifier VPI to thereby form one packet, that is, the common CS. (Convergence sublayer CS) unit Protocol data unit (CPCS-PD
A plurality of ATM cells constituting U) are managed as one group (see FIG. 5).

That is, the transmitting apparatus 100 manages the ATM cells by grouping them in packet units of the upper layer, but does not terminate the upper layer for this purpose. This is 1
Looking at the two logical links (VPI, VCI), AT
In the M adaptation layer (AAL) type 5, a packet, ie, a common CS unit protocol data unit
This means that a payload type (PT) field is used to identify an ATM cell located at the boundary of (CPCS-PDU).

In FIG. 1, received cell management section 204 of receiving apparatus 200 transmits ATM transmitted from transmitting apparatus 100.
Identify whether the cell was successfully received. Upon successful reception of the ATM cell, the reception cell management unit 204 transmits a signal ACK indicating successful reception to the transmission device 100 via the transmission unit 205. When detecting the failure of the reception of the ATM cell, the reception cell management unit 204 transmits a signal NAK indicating the failure of the reception to the transmission device 100 via the transmission unit 205.

Signal ACK or NAK transmitted by transmitting section 205 of receiving apparatus 200 is transmitted to receiving section 10 of transmitting apparatus 100.
4 and is notified to the transmission cell management unit 105.

The transmission cell management unit 105 has a payload type (PT) in the ATM cell header, a virtual channel identifier
By referring to the fields of (VCI) and virtual path identifier (VPI), one packet (CPCS-PDU)
Are managed as one group.

When the transmission cell management unit 105 detects an ATM cell that has failed in transmission due to the signal NAK input from the reception unit 104, all the ATM cells belonging to one group including the ATM cell (untransmitted ATM cells) CPCS-
PDU) is discarded from the transmission buffer 102.

The transmission cell management unit 105 controls the transmission buffer 10
If the ATM cell is discarded from EOP2, then EOP
The cell generation unit 106 generates an EOP cell, and transmits the EOP cell to the reception device 200 via the transmission buffer 102 and the transmission unit 103.

EOP generated by EOP cell generating section 106
The cell has the same logical link identifier (VPI, VCI) as the discarded ATM cell, and one bit (SDU type) included in the payload type (PT) field is set to 1.

By transmitting the EOP cell, the receiving terminal device receives one packet (CPCS-
It is possible to identify that the transfer of all the plurality of ATM cells constituting the PDU has been completed.

The processing procedure of the transmitting device 100 and the receiving device 200 will be described with reference to FIG.

When an ATM cell is input from the terminal device 15 or the node 18 into the transmission buffer 102, the transmission cell management unit 105 of the transmission device 100 refers to each field (PT, VCI, VPI) in the ATM cell header. Thus, a plurality of ATM cells constituting one packet (CPCS-PDU) are divided into one group (S10).

Next, it is checked whether the ATM cell belongs to the discarded PDU (S10A). Y
In the case of ES, the ATM cells belonging to the group are discarded from the transmission buffer, and the processing is terminated (S10B).

The transmitting apparatus 100 sequentially transmits ATM cells to the receiving apparatus 200 in accordance with the allocated radio band for each frame of the TDMA signal (S11).

Subsequently, transmitting apparatus 100 transmits the transmitted AT
A response signal ACK or NAK for the M cell is received from the receiving device 200 using the control radio line (S1).
2).

If the response signal NAK has not been received, that is, if the transmitted ATM cell has been successfully transmitted, the transmission cell management unit 105 stores the transmitted ATM cell in the transmission buffer 102 in step S14. Remove from.

However, depending on the construction of the device, there is a method in which the ATM cell is discarded from the transmission buffer immediately after transmission without waiting for a response signal.

Further, when there is an untransmitted ATM cell in the transmission buffer 102, the process returns to step S11, and the transmission of the ATM cell is continued. When the transmission of all the ATM cells in the transmission buffer 102 is completed, the transmission processing ends.

If the transmitting apparatus 100 receives a response signal NAK for the transmitted ATM cell from the receiving apparatus 200, the process proceeds to step S16, where the transmitting cell management unit 10
5 is an ATM belonging to a group including the corresponding ATM cell
All cells remaining in the transmission buffer among the cells are discarded.

In the next step S 17, the EOP cell generated by EOP cell generating section 106 is
Send to This EOP cell is one ATM cell, and one bit included in the PT field of the cell header.
(SDU type) is set to 1.

In the receiving apparatus 200, when receiving the ATM cell, in step S20, the receiving cell managing section 204
Determines the success or failure of reception. If the reception is successful, the signal ACK is transmitted to the transmitting device 100 in step S21, and if the reception is unsuccessful, the signal NAK is transmitted in step S22.

The ATM cells that have been successfully received are sequentially transmitted to the node 19 or the terminal device 15 in step S23.

A specific operation example of transmitting an ATM cell using a radio section between transmitting apparatus 100 and receiving apparatus 200 will be described with reference to FIG. Transmission device 1
Between 00 and the receiving apparatus 200, a wireless line for transmitting user information for transmitting an ATM cell is provided, and a control wireless line for notifying the arrival result of the ATM cell is also provided.

In the example of FIG. 3, in order to simplify the description,
The number of ATM cells transmitted in one TDMA frame is 3
Two cases are assumed. Also, one packet (PD
U) is composed of eight ATM cells C1 to C8, and it is assumed that an error occurs in the second ATM cell C2 on the radio line. Further, in FIG. 3, the change of the state over time is represented in the axial direction from left to right.

ATM cells transmitted from transmitting apparatus 100 to receiving apparatus 200 are stored in transmission buffer 102 before transmission. In this example, it is assumed that all eight ATM cells C1 to C8 are initially held in the transmission buffer 102.

First, at the transmission timing of the first TDMA frame, the first to third ATM cells C1 to C8 of the eight ATM cells in the transmission buffer 102 are transmitted.
1, C2 and C3 are transmitted.

By transmitting the three ATM cells C1 to C3, five ATM cells C4
~ C8 remain.

When an error occurs in the second ATM cell C2 in the wireless section in the first TDMA frame, the receiving apparatus 200 detects that the reception of the ATM cell has failed, and transmits a response signal NAK indicating the failure. Transmit to the device 100.

Receiving the response signal NAK from receiving apparatus 200, transmitting apparatus 100 recognizes that the transmission of the ATM cell has failed. And the transmission buffer 1
The ATM cells C4 to C8 remaining after the fourth in 02 are discarded from the transmission buffer 102 as invalid cells.

Further, transmitting apparatus 100 transmits EOP cell CD
Is generated and transmitted to the receiving apparatus 200 in the next TDMA frame.

[0091] The EOP cell CD is an ATM cell for notifying the terminal device of the packet destination of the boundary of the packet (PDU). In this EOP cell CD, the bits (S
DU type) is set to 1.

As a result, the radio section and the receiving device 200
Is followed by two ATM cells C1, C3 and one EOP
Only the cell CD will be transmitted as one packet (PDU).

As described above, since the number of ATM cells actually transmitted for a packet including an ATM cell in which an error has occurred is reduced, the number of ATM cells transmitted is significantly larger than that in a case where all the ATM cells C1 to C8 are transmitted. A reduction in traffic is realized.

A packet (PDU) composed of the eight ATM cells C1 to C8 shown in FIG.
FIG. 4 shows a flow of an ATM cell when transmitting to an ATM cell. In FIG. 4, the transmitting device 10 provided in the slave station 12 is illustrated.
0 and A using the receiving apparatus 200 provided in the base station 11.
Transfer the TM cell.

Under the same conditions as in the example of FIG. 3, if an error occurs in the second ATM cell C2 in the radio section between the slave station 12 and the base station 11, the slave station 12 sends three ATMs to the base station 11. After transmitting the cells C1 to C3, the EOP cell CD
Send

Therefore, the base station 11 receives the three ATs
M cells C1, C3 and CD are transferred to node 19 of network 18
To send to.

[0097] Here, an example is described in which the EOP cell is separately generated and transmitted after all the corresponding ATM cells are discarded. However, when the ATM cell is deleted, the EOP cell input to the transmitting apparatus is deleted. The present invention can also be realized by leaving in the buffer without performing.

(Second Embodiment) FIG. 6 shows the configuration of the main part of the ATM transmission apparatus of this embodiment.

In FIG. 6, the same elements as those in the first embodiment are denoted by the same reference numerals. In addition, the configuration and operation of the parts whose illustration and description are omitted
This is the same as the embodiment of FIG.

In this embodiment, the receiving device 200B is configured to be able to detect a reception failure even when a loss (destruction) of an ATM cell occurs in a radio section between the transmitting device 100B and the receiving device 200B. It is.

As shown in FIG. 6, transmission cell management section 105
B has a sequence number adding unit 107. The sequence number adding unit 107 adds, to each ATM cell input to the transmission buffer 102, a sequence number for distinguishing a plurality of ATM cells.

The ATM cells to which the sequence numbers are respectively added are sequentially transmitted to the radio section via the transmitting section 103.

In receiving apparatus 200B, A
The TM cell is transmitted to the reception buffer 202 via the reception unit 201.
Is input to This ATM cell is stored in the reception cell management unit 20.
After the success or failure of the arrival at the ATM cell is confirmed by 4B, it is output from the output unit 203.

The reception cell management section 204B
In addition to the error in the received data detected in step (1), whether or not the ATM cell has arrived in the wireless section is checked for the success or failure of the ATM cell arrival.

That is, A received by receiving apparatus 200B
Since the TM cell contains the information of the sequence number, the ATM cell is determined based on the context of the sequence number.
The presence or absence of cell loss can be confirmed.

For example, the ATM cells C1, C2,
000 for C3, C4, C5, C6, C7 and C8 respectively
1,0002,0003,0004,0005,000
When the sequence numbers 6,0007 and 0008 are added, the sequence numbers of the ATM cells received by the receiving device 200B of the base station 11 usually appear in the order of 0001, 0002, 0003,.

Accordingly, when the second ATM cell is lost, the third ATM cell having the sequence number of 0003 is detected following the first ATM cell having the sequence number of 0001. The received cell management unit 204B recognizes the lost ATM cell based on the arrangement order of the sequence numbers of the ATM cells that have reached the device 200B.

Error in received ATM cell or AT
Upon detecting the disappearance of the M cell, the reception cell management unit 204B sends a signal NAK indicating error detection to the transmission device 100B via the transmission unit 205.

As in the first embodiment, the transmitting apparatus 10
The transmission cell management unit 105B of 0B manages a plurality of ATM cells constituting one packet (CPCS-PDU) as one group by referring to the PT, VCI, and VPI fields in the cell header of the ATM cell.

When the ATM cell from which the transmission has failed is detected by the signal NAK from the receiving device 200B, all the ATMs belonging to the group including the ATM cell are detected.
The cell is discarded from the transmission buffer 102.

Thereafter, the EOP cell generated by EOP cell generating section 106 is transmitted from transmitting apparatus 100B via transmitting buffer 102 and transmitting section 103. The VPI and VCI fields of the cell header of this EOP cell contain the same information as the discarded ATM cell. The bit SDU type in the PT field is set to one.

(Third Embodiment) FIG. 7 shows the configuration of the main part of the ATM transmission apparatus of this embodiment.

In FIG. 7, the first embodiment and the second embodiment
The same elements as those of the embodiment are denoted by the same reference numerals. Portions not shown and portions whose description is omitted are the same as those in the first embodiment or the second embodiment.

In this embodiment, it is assumed that a plurality of virtual channels exist between the terminal device 15 and the node 19 as shown in FIG. In this case, ATM cells of different virtual channels (VPI / VCI) are mixed in the wireless line.

Therefore, in this embodiment, individual logical transmission links L1 and L2 are assumed for each virtual channel between the transmitting apparatus 100C and the receiving apparatus 200C.
It manages transmission and reception of ATM cells for each L2. Accordingly, even when ATM cells of different virtual channels (VPI / VCI) are mixed, invalid ATM cells can be discarded in transmitting apparatus 100C.

In FIG. 9, the terminal device 15 and the slave station 12 are connected by a wired transmission line 53, and the slave station 12 and the base station 11 have a user radio line 58 and a control information radio line 59. And the base station 11 and the node 19 are connected by a wired transmission line 63.

[0117] Two virtual channels 51 and 52 are formed between the terminal device 15 and the slave station 12.
And two virtual channels 54, 55 between the
And a control link 56 are formed, and two virtual channels 61 and 62 are formed between the base station 11 and the node 19.

For the virtual channels 51, 54 and 61, the virtual path identifier VPI is "A" and the virtual channel identifier VCI is "B". Also, virtual channel 5
For 2, 55 and 62, the virtual path identifier VPI is “C” and the virtual channel identifier VCI is “D”.

Although the virtual channel (VP / VC) is not terminated in the slave station 12 or the base station 11 here, where to terminate the virtual channel (VP / VC) is considered when designing the actual device. In the slave station 12 and the base station 11, the identifier (VP
I / VCI) can be replaced.

As shown in FIG. 9, the slave station 12 and the base station 11
Between them, a user wireless line 58 for transmitting ATM cells and a control information wireless line 59 for passing through the control link 56 are established.

The result of confirming the arrival of the ATM cell from the receiving device 200C to the transmitting device 100C is transmitted and received via the control link 56. Between the terminal device 15 and the node 19, two sets of virtual channels 51-54-61 and 52-5
5-62 have been established.

Accordingly, the virtual path identifier VPI is set to “A” for the wired transmission lines 53 and 63 and the user wireless line 58.
ATM cell using the virtual channel whose virtual channel identifier VCI is "B" and the virtual path identifier VPI is "C"
Thus, ATM cells using the virtual channel with the virtual channel identifier “D” of “D” are transmitted together.

Here, a case where an ATM cell is transmitted from the terminal device 15 to the node 19, that is, a case where the slave station (12) is a transmitting device and the base station (11) is a receiving device will be described.

When ATM cells constituting a packet are transmitted from the terminal device 15 to the slave station 12, the ATM cells are temporarily stored in the transmission buffer in the slave station 12. The slave station 12 manages ATM cells individually for each virtual channel, and establishes a logical transmission link L1, L2 with the base station 11 in the user wireless line 58 for each virtual channel.

On the other hand, the base station 11
The TM cell is managed for each virtual channel. And child station 1
2, the base station 11 independently checks the reception of the ATM cell and notifies the success or failure of the arrival of the ATM cell for each of the logical transmission links L1 and L2.

As described above, even when a plurality of virtual links exist in a wireless line, the slave station 12 and the base station 11
And the logical transmission link L1,
By setting L2 and managing the sequence numbers independently of each other, invalid ATM cells can be discarded.

FIG. 7 shows the configuration of the transmitting apparatus 100C and the receiving apparatus 200C when two virtual channels exist. As shown in FIG.
A pair of transmission buffers 102A and 102B are provided.

The ATM cells input to the transmitting apparatus 100C are temporarily stored in the transmission buffer 102A or 102B for each virtual channel via the input unit 101. The two sets of transmission buffers 102A and 102B may be configured so that one physical memory is virtually divided into a plurality, or a plurality of physical memories may be prepared in advance. The same applies to the reception buffers 202A and 202B.

The transmission cell management unit 105C manages a plurality of ATM cells constituting one packet (CPCS-PDU) as one group by referring to the PT, VCI, and VPI fields in the ATM cell header.

The sequence number adding unit 107C adds, to each ATM cell, a sequence number for confirming the arrival of each logical transmission link and a logical transmission link identifier indicating the logical transmission link.

[0131] The ATM cell to which the sequence number and the logical transmission link identifier are added is transmitted as a wireless ATM cell to the wireless section via the transmitting unit 103. This wireless ATM cell is received by receiving apparatus 200C.

Radio ATM cells received by receiving apparatus 200C are transmitted to receiving buffer 202A or 202B via receiving section 201 for each virtual channel.

Receiving cell management section 204 of receiving apparatus 200C
C confirms the sequence number of the ATM cell for each logical transmission link. And the ATM that has been successfully received
A signal ACK is sent to the cell and A
A signal NAK is transmitted to the TM cell via transmitting section 205.

A signal A output from transmitting section 205
The reception cell management unit 204C adds information indicating which logical transmission link the corresponding ATM cell belongs to to CK and NAK.

Transmission cell management section 105 of transmission apparatus 100C
C receives the signal ACK / NAK output from the transmitting unit 205 of the receiving device 200C and information about the logical transmission link via the receiving unit 104.

The transmission cell management unit 105C manages a plurality of ATM cells constituting one packet (CPCS-PDU) as one group by referring to the fields PT, VCI, and VPI in the ATM cell header.

When the transmission cell management unit 105C detects an ATM cell that has failed to transmit, it discards all ATM cells belonging to the group including the ATM cell from the transmission buffer 102A or 102B.

[0138] Thereafter, the EOP cell generated by EOP cell generating section 106C is output via transmitting section 103.
The virtual path identifier VPI and the virtual channel identifier VCI of this EOP cell are the same as the discarded ATM cell. However, the bit SDU of the PT field is set to 1.

An example of the flow of ATM cells when ATM cells of two virtual channels are transmitted in a mixed manner will be described with reference to FIG. In FIG. 10, the slave station 12 sends the base station 1
It is assumed that an ATM cell is transmitted toward 1.

In the example of FIG. 10, the logical transmission link L
1 and a virtual transmission link L
It is assumed that the second virtual channels corresponding to No. 2 are mixed.

Of the 16 ATM cells C01 to C16 input to the slave station 12, eight ATM cells C01 and C0 are provided.
4, C06, C07, C12, C13, C15 and C16 are transmitted using the logical transmission link L1. Also, the remaining eight ATM cells C02, C03, C05, C08, C0
9, C10, C11 and C14 are transmitted using the logical transmission link L2.

The eight ATM cells C01, C04, C06,
C07, C12, C13, C15 and C16 are 1 according to ATM adaptation layer (AAL) type 5
One packet is disassembled and converted into the form of eight ATM cells.

Further, eight ATM cells C02, C03, C
05, C08, C09, C10, C11 and C14 are obtained by disassembling another packet and converting it into the form of eight ATM cells.

In the ATM transmission apparatus shown in FIG.
Since control such as arrival confirmation for the TM cell is performed for each logical transmission link, the ATM cell is transmitted as shown in FIG.

In FIG. 10, if there is no error, 16 ATM cells C01 to C16 are sequentially transmitted from the slave station 12 to the base station 11. However, in the example of FIG. 10, the eight ATM cells C01, C04, C0 managed by the logical link L1.
An error has occurred in the second ATM cell C04 among 6, C07, C12, C13, C15 and C16.

If an error is detected after transmitting the third ATM cell C06 managed by the logical transmission link L1, the remaining ATM cells C07, C12, C13, C15 managed by the logical transmission link L1 are detected. And C16 are discarded from the transmission buffer 102A, and the EOP cell CD1 is transmitted.

On the other hand, 8 managed by the logical transmission link L2
ATM cells C02, C03, C05, C08, C09,
As for C10, C11 and C14, no error occurs, so all cells are transmitted to the base station 11.

Therefore, different virtual channels (VP
I, VCI), when the ATM cells of a plurality of sets of packets transmitted in a mixed manner are transmitted, the ATM which failed to receive
Untransmitted ATM belonging to the group (packet) that joins the cells
Only cells are discarded.

(Fourth Embodiment) FIG. 8 shows the configuration of the main part of an ATM transmission apparatus of this embodiment.

In FIG. 8, the same elements as those in the first, second, and third embodiments are denoted by the same reference numerals. Portions not shown and portions whose description is omitted are the same as those in the first embodiment.

In this embodiment, as in the third embodiment, it is assumed that a plurality of virtual channels exist between terminal device 15 and node 19. Therefore, a plurality of sets of ATM cells having different virtual path identifiers VPI and virtual channel identifiers VCI coexist in a wireless line.

In this embodiment, as shown in FIG. 8, a table 108 is provided in the transmission cell management unit 105D. This table 108 holds a correspondence between a sequence number for arrival confirmation and a group divided for each packet (PDU). The contents of the table 108 are updated successively.

[0153] The transmission cell management unit 105D
The group (packet) to which the unsuccessfully transmitted ATM cell belongs is specified from the sequence number of the failed ATM cell notified from 0D and the contents of the table 108. Therefore, the transmission cell management unit 105D can discard only the remaining ATM cells constituting the invalidated packet.

Description will be made with reference to FIG. Transmission device 100
The ATM cell input to D is input to the transmission buffer 102 via the input unit 101 and held.

The transmission cell management unit 105D assigns a sequence number for arrival confirmation to the ATM cell input to the transmission buffer 102. Also, the transmission cell management unit 1
05D is the field P in the cell header of the ATM cell.
By referring to T, VCI and VPI, a plurality of ATM cells constituting one packet (CPCS-PDU) are managed as one group.

Then, the relationship between the group indicating the specific packet and the sequence number included in the group is written in the table 108.

[0157] The ATM cell to which the sequence number is added is transmitted from the transmitting section 103 to the wireless section as a wireless ATM cell.

[0158] Receiving apparatus 200 D receives a wireless ATM cell in receiving section 201 and sends it to reception buffer 202. After the reception cell management unit 204D confirms the success or failure of the arrival of the ATM cell, the ATM cell in the reception buffer 202 is output to the output unit 20.
3 is sent out.

The reception cell management unit 204D sends a signal ACK to an ATM cell that has been successfully received and a NAK to an ATM cell that has detected a reception failure.
05 to the transmitting apparatus 100D.

The signal NAK transmitted from the transmitting unit 205 includes
It contains the sequence number added to the ATM cell.

Transmission cell managing section 105 of transmitting apparatus 100D
D receives the signal ACK / NAK and the sequence number from the receiving device 200D via the receiving unit 104. When detecting the ATM cell whose transmission has failed by the signal NAK, the transmission cell management unit 105D
Sequence number and table 10 notified from 0D
A that failed in transmission based on the data held in
Identify the group to which the TM cell belongs.

Then, transmission cell management section 105D discards, from transmission buffer 102, all ATM cells belonging to the group to which the failed ATM cell belongs.

Thereafter, the EOP cell generated by EOP cell generating section 106C is transmitted from transmitting section 103 to receiving apparatus 200D.
Sent to. The PT field, VPI and VCI fields of the cell header of this EOP cell contain the same data as the discarded ATM cell. However, the bit SDU of the field PT is set to 1.

[0164]

As described above, according to the present invention, invalid ATM cells can be determined by the transmitting apparatus and discarded before transmission to the transmission line. Therefore, transmission of invalid ATM cells to the transmission line can be suppressed, so that the transmission line band can be effectively used, and transmission of invalid traffic to the network and the terminal device can be suppressed. In particular, when a radio having a high possibility of occurrence of an error and having a limited band is used as a transmission path, the effect of the present invention is great.

In the present invention, even when a plurality of virtual channels (VP / VC) coexist on a transmission line, invalid ATM cells can be discarded. Further, when an invalid ATM cell is determined by a transmitting apparatus, termination of an upper layer is not required, and processing can be performed by processing of only the ATM layer. Therefore, the apparatus can be reduced in size and control can be simplified. .

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of a transmitting device 100 and a receiving device 200 installed in a base station 11 and a slave station 12 of a wireless ATM system according to a first embodiment.

FIG. 2 is a flowchart showing an operation of the transmitting device 100 and the receiving device 200 of FIG.

FIG. 3 is a sequence diagram illustrating an example of transmitting an ATM cell between a transmitting device 100 and a receiving device 200 in FIG. 1;

FIG. 4 is a schematic diagram showing a flow of ATM cells transferred from the terminal device 15 to the node 19 in the wireless ATM system according to the first embodiment.

FIG. 5 is a map showing a configuration of an ATM cell.

FIG. 6 is a block diagram illustrating a configuration of a main part of an ATM transmission device according to a second embodiment.

FIG. 7 is a block diagram illustrating a configuration of a main part of an ATM transmission device according to a third embodiment.

FIG. 8 is a block diagram illustrating a configuration of a main part of an ATM transmission device according to a fourth embodiment.

FIG. 9 is a block diagram showing a configuration of a logical link when a plurality of virtual channels exist.

FIG. 10 is a schematic diagram showing an example of the flow of an ATM cell when cells of a plurality of logical links are transmitted in a mixed manner.

FIG. 11 is a block diagram showing a basic configuration of a wireless ATM system.

FIG. 12 is a protocol stack diagram in the wireless ATM system of this embodiment.

FIG. 13 is a schematic diagram showing an example of ATM cell transmission.

FIG. 14 is a block diagram illustrating a basic configuration of a transmission device and a reception device.

FIG. 15 is a sequence diagram showing an example of transferring an ATM cell.

[Explanation of symbols]

 Reference Signs List 11 base station 12, 13, 14 slave station 15, 16, 17 terminal device 18 network 19 node 51, 52 virtual channel 53, 63 wired transmission line 54, 55 virtual channel 56 control link 58 user wireless line 59 control information Wireless channel 61,62 Virtual channel 100,100B, 100C, 100D Transmitter 101 Input unit 102 Transmission buffer 103 Transmitter 104 Receiver 105,105B, 105C, 105D Transmission cell manager 106,106C EOP cell generator 107 Sequence number Addition unit 108 Table 200, 200B, 200C, 200D Receiving device 201 Receiving unit 202 Receiving buffer 203 Output unit 204, 204B, 204C, 204D Receiving cell management unit 205 Transmitting unit L1, L2 Logical transmission link AAL ATM adaptation layer DU protocol data unit PT payload type VC Virtual Channel VCI Virtual Channel Identifier VP Virtual Path VPI Virtual Path Identifier CS Convergence Sublayer CPCS common CS unit

────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-10-190679 (JP, A) JP-A-9-168012 (JP, A) JP-A-10-51458 (JP, A) JP-A 9-190 162893 (JP, A) JP-A-9-247155 (JP, A) 1998 IEICE B-5-74 IEICE technical report SSE96-88 IEICE technical report SSE94-94 IEICE technical report SSE94-24 ( 58) Field surveyed (Int.Cl. ⁷ , DB name) H04L 12/28 H04L 12/56

Claims (5)

(57) [Claims] An ATM cell is transmitted and received through a communication path including a transmitting device and a receiving device, and information of an ATM cell header is referred to.
An ATM transmission device in which a plurality of ATM cells constituting a protocol data unit are continuously input to a transmission device by performing data communication by packet using an AAL that can identify a boundary of a PDU of an adaptation layer (AAL), Cell arrival identification means for identifying the success or failure of the arrival of the ATM cell, cell arrival notification means for notifying the identification result of the cell arrival identification means from the receiving device to the transmitting device as an ATM cell arrival confirmation notification, By referring to the transmission buffer for temporarily storing the previous ATM cell and the fields of the payload type, virtual channel identifier and virtual path identifier included in the header of the ATM cell, one of the common convergence sublayers is obtained.
Multiple ATMs that make up one protocol data unit
Group management means for managing cells as one group; arrival notification receiving means for receiving the ATM cell arrival confirmation notice notified from a receiving device to a transmitting device; and the ATM cell arrival confirmation received by the arrival notification receiving means. Group data deleting means for deleting from the transmission buffer all ATM cells belonging to the group including the ATM cell for which the non-delivery is detected by the notification; and when the group data deletion means deletes the ATM cell from the transmission buffer, An ATM cell (End of Packet cell: EOP) having a flag in the payload type field of the ATM cell header indicating that it is the last ATM cell constituting the protocol data unit of the group to be deleted.
An ATM transmission device, comprising: an EOP cell transmitting means for transmitting an ATM cell belonging to a discarded PDU; and a means for discarding an ATM cell belonging to a discarded PDU. 2. The transmitting device of an ATM transmission device according to claim 1, further comprising: a number adding unit that adds a sequence number to an ATM cell to be transmitted. An ATM transmission device for detecting the success or failure of arrival of an ATM cell based on a number. 3. The ATM transmission device according to claim 2, wherein a plurality of virtual channels exist on a line between the transmission device and the reception device, and ATM cells having different virtual path identifiers and virtual channel identifiers are mixed and input. In this case, the transmitting device and the receiving device establish different logical transmission links for each virtual channel of the ATM layer, and the group management means independently performs AT for each established logical transmission link.
An ATM transmission device for managing transmission and reception of M cells. 4. The ATM transmission device according to claim 2, wherein a plurality of virtual channels exist on a line between the transmission device and the reception device, and ATM cells having different virtual path identifiers and virtual channel identifiers are mixed and input. In this case, the receiving device is provided with sequence number notifying means for notifying the transmitting device of the sequence number of the ATM cell which the receiving device has failed to receive, and the transmitting device associates the sequence number with the group. An ATM transmission apparatus comprising: a table to be held; and a group identification unit that identifies a group to which an unreachable ATM cell belongs based on the sequence number notified from the sequence number notification unit and the contents of the table. . 5. The AT according to claim 1, wherein the transmitting device is a wireless transmitting device, and the receiving device is a wireless receiving device.
M transmission device.