JP2640593B2 - ISDN user / network interface device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention
The present invention relates to a network interface device, and particularly to establishing initial synchronization.

[0002]

2. Description of the Related Art The interface between an ISDN terminal device and a network terminating device is specified in the CCITT Recommendation I.400 series, and the physical layer of the basic interface is specified in Recommendation I.430. Recommendation I. 430
Then, the operation mode specifies that there is a one-to-one connection and a one-to-n connection, and the wiring model defines a transmission distance and a wiring form as shown in FIG. Here, (a) is a short-range passive bus (point / multipoint configuration),
(B) shows the case of the extended passive bus (point / multipoint configuration), and (c) shows the case of the point / point configuration. However, the specification of the wiring model is defined in order to specify the electrical characteristics between the terminal device and the network terminating device. In practice, other wiring forms are possible by confirming the operation.

According to Recommendation I.430, in the operation mode in which a plurality of terminals are connected on one bus, when a plurality of terminals simultaneously access the upstream D channel from the terminal device to the network terminal device, the following is performed. Defines contention control. Only one terminal can successfully transmit that information,
The other terminals temporarily stop the access and try again when the D channel becomes free, and finally all the terminals finish transmitting the information in order. In order to perform such D-channel contention control, when the network termination device receives an upstream signal frame from the terminal device, the network termination device transmits the D channel bits in the upstream signal frame to the next downstream signal frame to be transmitted to the terminal device. Copy to echo channel bits. Each terminal device determines the use state of the uplink D channel by observing the echo bits in the received downlink signal frame, and determines the D channel bits in the transmitted signal frame and the echo channel bits in the received signal frame. Are compared to perform collision detection. FIG. 9 shows an uplink signal frame configuration from the terminal device to the network termination device and a downlink signal frame configuration from the network termination device to the terminal device. In FIG. 9, frame U is an upstream signal frame transmitted from the terminal device to the network terminal device, and frame D is a downstream signal frame transmitted from the network terminal device to the terminal device.
D in the frame is a D channel bit, E is an echo channel bit, and the transmission time of one frame is 250 microseconds. Recommendation I.430 specifies the input delay characteristics of the network termination equipment as shown in Table 1, and if the transmission delay between the network termination equipment and the terminal equipment satisfies the specified value,
D-channel contention control between terminal devices and signal frame synchronization detection within the network termination device can be performed.

[0004]

[Table 1]

[0005]

In recommendation I.430 in the above prior art, the maximum number of terminal devices that can be connected to the passive bus of one network terminating device is specified as eight. Is performed, eight or more terminal devices can be connected to one network terminal device. However, when the buses are connected to each other, the distance between the network terminating device and the terminal device may exceed the value specified in Recommendation I.430. If the distance between the network terminating equipment and the terminal equipment is greater than the value specified in Recommendation I.430, the transmission delay time is also greater than the specified value, so that the reception timing of the signal frame in the network terminating equipment is shifted. . In the network termination unit, the synchronization of the received signal frame cannot be detected unless the reception timing is within the input delay range specified in Recommendation I.430. Also, if the connection between the buses is extended or encoded, and the transmission delay of the connection is 250 microseconds or more for one frame, the downlink signal frame received immediately after the transmission of the uplink signal frame in the terminal device. And the downstream signal frame transmitted in response to the upstream signal frame in the network terminating device, and the correspondence between the upper and lower signal frames in the terminal device is shifted. If the correspondence between the upper and lower signal frames is shifted in the terminal device, the correspondence between the D channel bits and the echo channel bits in the signal frame is also shifted, so that D channel contention control between the terminal devices cannot be performed. Therefore, in the above-described prior art, it is impossible to connect the buses in which the transmission delay time between the network terminating device and the terminal device is equal to or more than the specified value. Could not connect.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned drawbacks, and makes it possible to control D-channel contention between terminal devices and to detect frame synchronization in a network termination device even when a transmission delay exceeding a prescribed value occurs. , Which can realize connection between buses
It is an object of the present invention to provide an SDN user network interface device.

[0007]

In order to achieve this object, an ISDN user network interface device according to the present invention is provided between an ISDN network terminal device and a terminal device (S / T).
), The D channel bits in the upstream signal frame from the terminal device to the network terminal device are copied to the echo channel bits in the downstream signal frame from the network terminal device to the terminal device, and the upstream signal frame is stored in the buffer. The transmission is performed at a timing at which the synchronization of the network terminating device can be detected.

A feature of the present invention is that the terminal device receives the D channel bits in the uplink signal frame transmitted from the terminal device irrespective of the correspondence of the signal frame while monitoring the use state of the D channel. The difference lies in that the signal is copied to the echo channel bits in the downstream signal frame, and that the upstream signal frame is stored in a buffer and transmitted at a timing at which the network termination device can perform synchronization detection.

[0009]

According to the present invention, when connecting buses in the connection form specified in Recommendation I.430, even if the distance between the network terminating device and the terminal device is longer than the specified distance of Recommendation I.430. In addition, it is possible to perform D-channel contention control between terminal devices and detect synchronization of a received signal frame in the network termination device.

[0010]

FIG. 1 is a functional block diagram of a repeater according to the present invention, wherein a is a determination unit, b is a buffer, c is a buffer control unit, d is a copy unit, e is a D channel bit detection unit, f
Is a bit comparator, g is an echo channel bit detector, h
Is a timing control unit, i is a frame synchronization detection unit, j is a copy control unit, k is a D channel bit copy unit, l is an input driver, and m is an output driver. The upstream signal frame transmitted from the terminal device is received by the input driver 1 and sent to the D channel bit detection unit e. The D channel bit detection unit e detects the D channel bits in the signal frame and sends the detected D channel bits to the D channel bit copy unit k. The upstream signal frame from which the D channel bit has been detected is sent to and stored in the buffer b. The downstream signal frame transmitted from the network terminating device is received by the input driver 1, and the frame bit is detected by the frame synchronization detector i. The timing control unit h creates a timing of a 2-bit offset with respect to the frame timing detected by the frame synchronization detection unit i, and sends it to the buffer control unit c. The buffer control unit c transmits a transmission command of the upstream signal frame in the buffer b at the timing received from the timing control unit h. The upstream signal frame transmitted from the buffer b is output to the D channel bit detector e.
The channel bit is detected and sent to the network terminating device via the output driver m. In the downstream signal frame, after the frame synchronization is detected by the frame synchronization detection unit i, the echo channel bits are detected by the echo channel bit detection unit g. The detected echo channel bits are compared with the D channel bits detected by the D channel bit detection unit e by the bit comparison unit f. The comparison result is sent to the copy control unit j, and the D channel bit copy unit k is controlled according to the comparison result. As a result of the comparison, if the D channel bit and the echo channel bit are equal, the copy control unit j continues copying. However, if the D channel bit and the echo channel bit are different, the copy control unit j sends a copy stop command. The downstream signal frame is sent to the D channel bit copy unit k after the echo channel bit detection unit g. The D channel bit copy unit k copies the D channel bits in the upstream signal frame received from the D channel bit detection unit e to the echo channel bits in the downstream signal frame according to the control command of the copy control unit j. The downstream signal frame is transmitted to the terminal device through the output driver m after the D channel bit copy unit k. The above is the processing of each functional unit in the repeater according to the present invention.

Next, a description will be given of a relationship between signal frames between a network terminating device and a terminal device when a repeater is used. FIG. 2 is a diagram showing a signal frame relationship between a network termination device using a repeater according to the present invention and a terminal device, and FIG. 3 is a connection diagram between a network termination device using a repeater according to the present invention and a terminal device. 1 is a repeater, 2 is a network terminator,
3 is a terminal device, 4 is an electrical characteristic terminating device, and each device is connected by four wires. The bus directly connected to the network terminating device 2 is B1, and the bus connected to the bus B1 via the repeater 1 is B2. The terminal device 3 and the repeater 1 on the bus B1 are within the distance specified in Recommendation I.430 from the network termination device 2. The terminal device 3 on the bus B2 has a distance from the repeater 1 according to Recommendation I.430.
Is less than or equal to the distance between the network terminating device and the terminal device specified in (1). The electrical characteristic terminating device 4 between the bus B1 and the repeater 1 is a device for terminating the repeater 1 so as to show the same electrical characteristics of Recommendation I.430 as the terminal device 3 when viewed from the bus B1. The electrical characteristic terminating device 4 between the repeater 1 and the repeater 1 is connected to the repeater 1 when viewed from the bus B2.
Is a device that terminates to show the same electrical characteristics of Recommendation I.430 as the network termination device 1. In this case, the electrical characteristics specified in Recommendation I.430 can be maintained in each bus, but there is a possibility that a transmission delay more than the specified value may occur between the network terminating device 2 and the terminal device 3 on the bus B2. . Recommendation I.4
Even if a transmission delay exceeding the specified value of 30 occurs,
The connection between the network terminating device 2 and the terminal device 3 becomes possible by applying the repeater 1 according to the present invention.

The frame relationship between the network terminating device 2 and the terminal device 3 when the present device repeater 1 is used will be described below. In FIG. 2, the input delay of repeater 1 is t
₁ microsecond, the input delay of the network termination device 2 is t ₂ microseconds, and the input delay range of the network termination device specified in Recommendation I.430 is T ₁ microsecond to T ₂ microseconds, and the transmission time of one frame is 250 microseconds. All of the terminal device 3 transmits the uplink signal frame in accordance with the synchronization timing of the downlink signal frame transmitted from the network terminating device 2 2 bit offset timing (T ₁ microsecond). The terminal device 3 on the bus B2 also transmits the upstream signal frame UFi at a 2-bit offset timing after receiving the downstream signal frame. The transmission delay t ₁ in the repeater 1 of the upstream signal frame UFi transmitted from the terminal device on the bus B 2 is between the repeater 1 and the terminal device 3 according to the recommendation I.
Since it is within the prescribed distance of 430, T ₁ <t ₁ ≦ T ₂ . However, if the upstream signal frame UFi is transmitted as it is, the transmission delay t ₂ in the network termination device ₂ is t ₂ > T
_May be ₂ . Therefore, the repeater 1 stores the upstream signal frame in the buffer, and transmits the next downstream signal frame at a 2-bit offset timing. By this operation, the transmission delay t ₂ in the network termination device 2 becomes the sum of the transmission delay t ′ between the network termination device 2 and the repeater 1 and the transmission time of one frame. This transmission delay t 'is also between the network termination device 2 and the repeater 1 according to Recommendation I.43.
Since it is within the specified distance of 0, T ₁ <t ′ ≦ T ₂ .
Therefore, frame synchronization detection in the network termination device 2 becomes possible.

However, if the upstream signal frames are stored in the repeater 1, the correspondence between the upstream signal frames and the downstream signal frames in the terminal device 3 on the bus B2 is shifted. Downlink signal frame DF transmitted immediately after reception of uplink signal frame UFi-1 in network termination device 2.
i-1 is received by the terminal device 3 on the bus B2 immediately after transmitting the upstream signal frame UFi. Therefore, even if the D channel bits are copied to the echo channel bits for the D channel contention control in the network termination device 2, the correspondence between the upper and lower signal frames is shifted in the terminal device 3 on the bus B2, and The D channel bits and the echo channel bits in the above also do not correspond. Therefore, the D channel bits in the upstream signal frame received in the repeater 1 are copied to the echo channel bits in the downstream signal frame transmitted immediately thereafter. By this operation, even if the correspondence between the upstream signal frame and the downstream signal frame in the terminal device 3 is shifted, the correspondence between the D channel bit and the echo channel bit in the signal frame is the same.
D-channel contention control between the terminal devices 3 above can be performed.

The repeater 1 must perform D-channel contention control with the terminal device 3 on the bus B1 in addition to the adjustment of the signal frame transmission timing and the copying of the D-channel bits. The D-channel contention control is performed by the determination unit a, and the buffer control unit c and the copy unit d operate based on the determination result. When the repeater 1 is selected by the contention control on the bus B1, the terminal device 3 selected by the contention control on the bus B2 is connected to the network terminating device 2. However, when the repeater 1 is not selected by the contention control, the terminal device 3 on the bus B2 cannot be connected to the network terminating device 2, so that the transmission of the signal frame to the upstream D channel must be stopped. No.
Therefore, when it is determined that the repeater 1 has not been selected by the contention control, the repeater 1 stops copying the D channel bits in the upstream signal frame to the echo channel bits in the downstream signal frame, The downstream signal frame is transmitted to the bus B2 as it is. Network termination device 2
In the terminal device 3 on the bus B2 that has received the downstream signal frame as it is, since the D channel bits in the upstream signal frame and the echo channel bits in the downstream signal frame are different, it is determined that they were not selected by the D channel contention control. Then, the transmission of the signal is stopped. In addition, although the upstream signal frame is accumulated in the buffer b of the repeater 1,
The signal frame is deleted. Repeater 1 in a signal frame transmission stop state and terminal device 3 on bus B2
Can receive the downstream signal frame from the network terminating device 2 and monitor the echo channel bit, so that the use state of the D channel of the bus B1 can be grasped. The repeater 1 monitors the state of use of the D channel of the bus B1 by the determination unit a, and upon detecting the vacancy of the D channel, transmits the D channel bits in the upstream signal frame to the copy unit d and returns the echo channel in the downstream signal frame to the copy unit d. It instructs copying to bits and sending out the buffered signal frame to the buffer control unit c. By repeating the above operation, frame synchronization detection in the network termination device 2 and D-channel contention control between the terminal devices 3 at the time of connection between buses are realized. By using the repeater 1 according to the embodiment of the present invention, the connection between the bus B1 and the bus B2 becomes possible.

[0015]

[Embodiment 2] FIG. 4 is a diagram in which a functional unit of a repeater 1 according to an embodiment of the present invention is divided into two. A bus B1 corresponding unit R1 including a determination unit a, a buffer b, and a buffer control unit c, and a bus B2 corresponding unit R2 including a copy unit d.
And divided into Bus B1 corresponding part R1 and bus B2 corresponding part R2
Between them, transmission of upper and lower signal frames and transmission of the determination result obtained by the determination unit a are performed. FIG. 5 shows the present repeater 1
FIG. 2 is a connection diagram between the network terminating device 2 and the terminal device 3 in a case where the connection between the bus B1 corresponding unit R1 and the bus B2 corresponding unit R2 is extended. The buses B1 and B2 are in accordance with Recommendation I.43, respectively.
0, but the bus B1 corresponding part S1 and the bus B
2. Since the interval between the corresponding units S2 is extended, the distance between the network terminating device 2 and the terminal device 3 on the bus B2 is longer than a specified distance. Therefore, between the network terminating device 2 and the terminal device 3 on the bus B2,
Signal waveform distortion and transmission delay exceeding a specified value occur. The distortion of the signal waveform can be solved by applying an existing technology such as the waveform shaping circuit 5 and the amplifier 6. The transmission delay can be solved by applying the present repeater 1.
Hereinafter, the operation of the present device repeater 1 will be described.

The operation of each functional unit in the repeater 1 is the same as that of the first embodiment, but the transmission delay time between the bus B1 corresponding unit R1 and the bus B2 corresponding unit R2 corresponds to the transmission time of n signal frames. . Therefore, when the upstream terminal frame 2 receives the upstream signal frame UFi, the terminal device 3 on the bus B2 transmits the upstream signal frame UFi + (n + 1) after the upstream signal frame UFi (n + 1). . When the downstream signal frame DFi is transmitted by the network termination device 2, the terminal device 3 on the bus B2 transmits the downstream signal frame DFi.
N-th downstream signal frame DFi-n is received.
That is, the terminal device 3 on the bus B2 immediately transmits the upstream signal frame UFi + (n + 1) immediately after transmitting the downstream signal frame DFi- (n + 1).
n will be received. Even if the correspondence of the signal frames is shifted in the bus B2, the copy unit in the bus B2 corresponding unit R2 copies the D channel bits of the upstream signal frame UFi + (n + 1) to the echo channel bits in the downstream signal frame DFi-n. Therefore, contention control of the D channel can be performed. Also,
In the bus B1 corresponding section R1, terminals on the bus B1 and D
Channel contention control is performed. The determination unit a compares the D channel bits in the upstream signal frame with the echo channel bits in the downstream signal frame, and transmits the determination result to the buffer control unit and the copy unit. If the D channel bits in the upstream signal frame and the echo channel bits in the downstream signal frame are the same in the determination unit a, the buffer control unit c issues a transmission command of the upstream signal frame in the buffer to the buffer b. Further, the copy unit d copies the D channel bits in the upstream signal frame to the echo channel bits in the downstream signal frame. When the determination unit a determines that the D channel bit in the upstream signal frame is different from the echo channel bit in the downstream signal frame, the buffer control unit c issues an instruction to the buffer b to delete the upstream signal frame in the buffer. Also, the copy unit d
Stops copying the D channel bits in the upstream signal frame to the echo channel bits in the downstream signal frame. However, when the determination unit a in the bus B1 corresponding unit R1 compares the upstream signal frame UFi with the downstream signal frame DFi, the copy unit d in the bus B2 corresponding unit R2 uses the upstream signal frame UFi + (n + 1). Are copied to the echo channel bits in the downstream signal frame DFi-n. Therefore, bus B1 corresponding section R1
Even if it is decided to stop sending the upstream signal frame within
2 The corresponding unit R2 has already transmitted n uplink signal frames to the bus B1.
Since the signal is transmitted to the corresponding unit R1, the bus B1 corresponding unit R1 receives n uplink signal frames after the transmission is stopped. The n uplink signal frames received after the transmission is stopped are deleted in the buffer b. In the bus B1 corresponding unit R1, after receiving n uplink signal frames, the bus B2
The transmission signal from the corresponding unit R2 becomes no signal, but at that time, the transmission of the signal frame from the repeater 1 and the terminal device 3 on the bus B2 has been stopped. When the terminal device 3 on the bus B2 detects a vacant state of the D channel of the bus B1 and calls again, the determination unit a of the bus B1 corresponding unit R1 detects the vacant state of the D channel of the bus B1, and The fact that the channel is vacant indicates that the copy section d in the bus B2 corresponding section R2.
Is transmitted to the buffer control unit c. The copy unit d, which is notified that the D channel of the bus B1 is empty, copies the D channel bits in the upstream signal frame transmitted from the terminal device 3 on the bus B2 to the echo channel bits in the downstream signal frame. I do. The buffer control unit c issues a transmission command of the signal frame in the buffer to the buffer b. Thus, D-channel contention control on buses B1 and B2 is performed. Repeater 1 according to an embodiment of the present invention
To extend the distance between bus B1 and bus B2,
It becomes possible to connect.

[0017]

[Embodiment 3] FIG. 6 shows a bus B1 corresponding portion R1 and a bus B2 in the repeater 1 according to the present invention described in Embodiment 2.
FIG. 9 is a functional configuration diagram in a case where a signal frame transmitted and received between corresponding units R2 is encoded and transmitted. Bus B1 corresponding part R1
A pair of codecs n is inserted in the transmission path between the bus B2 and the corresponding section R2, and the upper and lower signal frames are transmitted using encoded signals corresponding to the codec n. The codec n is a device that converts a signal form according to a transmission path, and includes a digital modem and the like. The operation of each functional unit is the same as in the second embodiment.

[0018]

[Embodiment 4] FIG. 7 shows a bus B1 corresponding portion R1 and a bus B2 in the repeater 1 according to the present invention described in Embodiment 2.
Signal frame transmitted / received between corresponding unit R2 and judgment unit a
FIG. 7 is a functional configuration diagram in the case of encoding and transmitting the determination result of FIG. A pair of codecs n is inserted in the transmission path between the bus B1 corresponding unit R1 and the bus B2 corresponding unit R2, and the upper and lower signal frames and the determination result of the determination unit a are transmitted by an encoded signal corresponding to the codec n. The operation of each functional unit is the same as in the second embodiment.

[0019]

As described above, the present invention relates to Recommendation I.
430 can be connected to each other in the connection mode. As a connection method, wiring extension or encoding can be applied.

[Brief description of the drawings]

FIG. 1 is a functional configuration diagram of a repeater according to the present invention.

FIG. 2 is a diagram illustrating a frame relationship between a network terminal device and a terminal device when the present invention is applied.

FIG. 3 is a connection diagram of a network terminating device and a terminal device to which the present invention is applied.

FIG. 4 is a functional configuration diagram of a repeater according to the present invention.

FIG. 5 is a connection diagram of a network terminating device and a terminal device to which the present invention is applied.

FIG. 6 is a functional configuration diagram of a repeater according to the present invention.

FIG. 7 is a functional configuration diagram of a repeater according to the present invention.

FIG. 8 is a connection diagram between a conventional network termination device and a terminal device.

FIG. 9 is a configuration diagram of a signal frame between a conventional network terminating device and a terminal device.

[Explanation of symbols]

 Reference Signs List 1 repeater 2 network termination device 3 terminal device 4 electrical characteristic termination device 5 waveform shaping circuit 6 amplifier a determination unit b buffer c buffer control unit d copy unit e D channel bit detection unit f bit comparison unit g echo channel bit detection unit h timing Control unit i Frame synchronization detection unit j Copy control unit k D channel bit copy unit l Input driver m Output driver n Codec

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Masanobu Fujioka 2-3-2 Nishi-Shinjuku, Shinjuku-ku, Tokyo International Telegraph and Telephone Corporation (56) References JP-A-4-237234 (JP, A) JP-A-63-240240 (JP, A) JP-A-62-200858 (JP, A)

Claims (1)

(57) [Claims] 1. An ISDN network termination device and a terminal device (S
/ T point), the D channel bits in the upstream signal frame from the terminal device to the network termination device are copied to the echo channel bits in the downstream signal frame from the network termination device to the terminal device, and the upstream signal frame is stored in the buffer. Characterized in that transmission is performed at a timing at which the synchronization can be detected by the network terminating device.
Network interface device.