JPH11220532A - Transmission system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent bidirectional loopback and to attain a remote test by transmitting the loopback pattern signal that is looped back by a transmitting device of the opposite side station to a test device, when no detection signal is inputted and looping the loopback pattern signal back to the said transmitting device when the detection signal is inputted. SOLUTION: A loopback pattern outflow preventing circuit 12 outputs a detection inhibiting signal Sa1 for inhibiting the detecting operation of a loopback detection circuit 13 when a loopback pattern signal Sr is detected. When an inhibiting signal Sc1 is inputted from the circuit 13, the operation of the circuit 12 is inhibited. When the circuit 13 detects the signal Sr that is inputted from a fast transmission line 6 via an MUX part 4, the circuit 13 outputs a loopback pattern detection signal Sb1 to a loopback circuit 3.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a transmission system having a loopback test function.

[0002]

2. Description of the Related Art FIG. 2 is a block diagram showing a configuration of a conventional transmission system. In this figure, reference numeral 1 denotes a DSU (Digital Service Unit: home data line terminal board) installed in the own station, which is suitable for transmitting a transmission signal from a terminal on the own station side (not shown) on the high-speed transmission line 6 side. It has the function of converting it into a transmission signal. That is, the DSU 1 has a function of interfacing between the terminal on its own side and the high-speed transmission path 6. Further, the DSU 1 sends out a loopback pattern signal Sr used in a loopback test described later.

[0003] Reference numeral 2 'denotes a 4-wire intra-office termination board (Office Channel Uni-directional) inserted between the DSU 1 and the high-speed transmission line 6.
t: OCU), which takes an interface between the DSU 1 and the high-speed transmission line 6. In the in-station terminal board 2 ', reference numeral 3 denotes a loopback circuit, which is controlled by a loopback detection circuit 5 described later to loop back the loopback pattern signal Sr during a loopback test. 4
Is an MUX (MUltipleXer) unit for multiplexing transmission signals. When detecting the loopback pattern signal Sr, the loopback detection circuit 5 outputs a loopback pattern detection signal Sd1 to the loopback circuit 3.

[0004] Reference numeral 7 'denotes an intra-office termination board provided on the opposite station side and having the same configuration as the intra-office termination board 2'.
And the DSU 11 described later. In the in-station terminal board 7 ', reference numeral 8 denotes a MUX section for multiplexing transmission signals. Reference numeral 9 denotes a loopback circuit that loops back the loopback pattern signal Sr during a loopback test under the control of the loopback detection circuit 10.

When the loopback detection circuit 10 detects the loopback pattern signal Sr, it outputs a loopback pattern detection signal Sd2 to the loopback circuit 9. The DSU 11 serves as an interface between a terminal on the opposite station (not shown) and the high-speed transmission line 6.

Next, an operation at the time of a loopback test in the above-described conventional transmission system will be described. Now, it is assumed that the intra-station terminal panel 7 'and the DSU 11 shown in FIG. 2 are not provided. In this state, if a failure occurs in the device, a measuring device for specifying the location of the failure is connected to the high-speed transmission line 6, and the measuring device outputs a loopback pattern signal Sr. Thereby, the loopback pattern signal Sr is transmitted to the high-speed transmission path 6 and the MUX.
The data is transmitted to the DSU 1 via the unit 4. At this time,
After detecting the loopback pattern signal Sr, the loopback detection circuit 5 outputs a loopback pattern detection signal Sd1 to the loopback circuit 3.

As a result, a loop-back circuit is formed in the loop-back circuit 3 for connecting the sending line and the receiving line, so that the loop-back pattern signal Sr is loop-backed by the loop-back circuit 3. Thereafter, the signal is input to the measuring instrument via the MUX unit 4 and the high-speed transmission path 6. Then, the failure location is specified based on the input signal of the measuring instrument.

[0008]

By the way, in the conventional transmission system, the in-station terminal board 7 'and the DSU 11
However, there is a problem that a loopback pattern test cannot be performed because a bidirectional loopback state occurs in a state where is connected to the high-speed transmission line 6. That is, in FIG. 1, the loopback pattern signal S
r, the loopback pattern signal Sr
Is transmitted to the high-speed transmission path 6 via the loop-back circuit 3 and the MUX unit 4, and further input to the loop-back detection circuit 10 via the MUX unit 8. As a result, the loopback pattern signal Sr is detected by the loopback detection circuit 10, and the loopback detection circuit 10 outputs a loopback pattern detection signal Sd2 to the loopback circuit 9.

As a result, the loopback pattern signal Sr
Is looped back by the loopback circuit 9,
The signal is input to the loopback detection circuit 5 via the MUX unit 8, the high-speed transmission path 6, and the MUX unit 4. As a result, the loopback pattern signal Sr is detected by the loopback detection circuit 5, and the loopback detection circuit 5
The loopback pattern detection signal Sd1 is output to the loopback circuit 3. As a result, the loopback pattern signal Sr is looped back by the loopback circuit 3, and then input to the loopback detection circuit 10 via the MUX unit 4, the high-speed transmission path 6, and the MUX unit 8.

As a result, the loopback pattern signal Sr is detected again by the loopback detection circuit 10, so that the loopback pattern signal Sr is looped back by the loopback circuit 9. In the following state, the bidirectional loopback state in which the loopback pattern signal Sr is alternately looped back by the loopback circuit 3 and the loopback circuit 9 continues. Therefore, in this case, the loopback circuit 3
The bidirectional loopback state is not released unless the package such as is removed. That is, in the conventional transmission system, the loopback pattern signal S
When r flows out of the intra-station terminal panel 2 'to the intra-station terminal panel 7', there is a problem that an erroneous loopback test is performed and the state of the bidirectional loopback cannot be released. Furthermore, in the conventional transmission system, since the above-described bidirectional loopback is performed, there is a disadvantage that a loopback test cannot be remotely performed using the DSU1. The present invention has been made under such a background, and an object of the present invention is to provide a transmission system that can prevent bidirectional loopback and can perform a loopback test remotely.

[0011]

According to a first aspect of the present invention, there is provided a transmission line connecting between a local station and an opposite station, and transmission of a signal through the transmission line provided on the local station side. The own-station-side transmission device that performs, the opposite-side transmission device that is provided on the opposite station side and transmits a signal through the transmission path, and transmits a loopback pattern signal to the own-station-side transmission device,
A loopback test device that receives the loopback pattern signal looped back by the opposite station side transmission device, which is input via the own station side transmission device, comprises: A loopback pattern outflow prevention circuit that detects the loopback pattern signal sent from the loopback test apparatus and outputs a detection inhibition signal, and a loopback that is input through the transmission path and is loopbacked by the opposite transmission apparatus. Detecting the detected loop-back pattern signal and outputting a detection signal, and when the detection inhibition signal is input, a loop-back detection circuit that inhibits the detection operation of the loop-back pattern signal; and When not input, the loopback pattern signal looped back by the opposite station side transmission device And a loopback circuit that loops back the loopback pattern signal to the opposite-station-side transmission device via the transmission line when the detection signal is input to the opposite-station-side transmission device while the detection signal is input to the transmission device. Features. Further, according to a second aspect of the present invention, in the transmission system according to the first aspect, the loopback test apparatus specifies a failure location based on a reception state of the loopback pattern signal. .
Further, the invention according to claim 3 is a transmission line connecting between the own station and the opposite station, and a transmission device on the local station that is provided in the local station and transmits a signal through the transmission line. An opposite transmission apparatus provided on the opposite station side for transmitting a signal via the transmission path, and transmitting a first loopback pattern signal to the own transmission apparatus; A first loop-back test apparatus for receiving the first loop-back pattern signal looped back by the opposite-station-side transmission device, which is input via the second communication device, and a second loop-back to the opposite-station-side transmission device A second loopback test apparatus that transmits the pattern signal and receives the second loopback pattern signal that is input via the opposite station side transmission apparatus and is looped back by the own station side transmission apparatus; With And a first loopback pattern for detecting the first loopback pattern signal transmitted from the first loopback test apparatus and outputting a first detection inhibition signal. An outflow prevention circuit, which outputs the first detection signal by detecting the first loopback pattern signal looped back by the opposite-side transmission device, which is input via the transmission path,
When the first detection prohibition signal is input, the first loopback pattern signal detection operation is prohibited.
And transmitting the first loopback pattern signal looped back by the opposite station side transmission device to the first loopback test device when the first detection signal is not input. On the other hand, when the first detection signal is input, a first loopback circuit that loops back the loopback pattern signal to the opposite station side transmission device via the transmission path, The opposite station side transmission device detects the second loopback pattern signal transmitted from the second loopback test device and outputs a second detection inhibition signal.
And detecting the second loopback pattern signal, which is input via the transmission line and is looped back by the local station side transmission device, and outputs a second detection signal. On the other hand, when the second detection prohibition signal is input, a second loopback detection circuit that prohibits the detection operation of the second loopback pattern signal, and the second detection signal is not input When the second loopback pattern signal looped back by the local station side transmission device is transmitted to the second loopback test device, the second loopback pattern signal is transmitted when the second detection signal is input. And a second loopback circuit for looping back the loopback pattern signal to the local station side transmission device via the transmission path. According to a fourth aspect of the present invention, in the transmission system according to the third aspect, the first loopback test apparatus specifies a failure location based on a reception state of the first loopback pattern signal. The second loopback test apparatus specifies a failure location based on a reception state of the second loopback pattern signal.

[0012]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing a configuration of a transmission system according to an embodiment of the present invention. In this figure, parts corresponding to the respective parts in FIG. 2 are denoted by the same reference numerals, and description thereof will be omitted. In FIG. 1, an intra-office termination panel 2 and an intra-office termination panel 7 are provided instead of the intra-office termination panel 2 'and the intra-office termination panel 7' shown in FIG.

Further, in the intra-office terminal board 2 shown in FIG. 1, a loop-back detection circuit 13 is provided instead of the loop-back detection circuit 5 shown in FIG. 2, and a loop-back pattern outflow prevention circuit 12 is newly provided. It is provided in. Further, in the in-station termination panel 7 shown in FIG.
A loopback detection circuit 14 is provided in place of the loopback detection circuit 10 shown in FIG. 1 and a loopback pattern outflow prevention circuit 15 is newly provided.

In the intra-office terminal board 2 shown in FIG. 1, when the loop-back pattern outflow prevention circuit 12 detects the loop-back pattern signal Sr, the loop-back detection circuit 1
No. 3 is a detection prohibition signal Sa for prohibiting the detection operation.
Outputs 1. Further, when an operation prohibition signal Sc1 described later is input from the loopback detection circuit 13, the operation of the loopback pattern outflow prevention circuit 12 is prohibited.

The loopback detection circuit 13 outputs a loopback pattern detection signal Sb1 to the loopback circuit 3 when detecting the loopback pattern signal Sr input from the high-speed transmission line 6 via the MUX unit 4. When detecting the loopback pattern signal Sr, the loopback detection circuit 13 disables the operation of the loopback pattern outflow prevention circuit 12 when the loopback pattern signal Sr is detected.
Outputs 1.

In the intra-station terminator 7, the loop-back detection circuit 14 has the same function as the loop-back detection circuit 13, and a loop-back pattern signal input from the high-speed transmission line 6 via the MUX unit 8. When Sr is detected, a loopback pattern detection signal Sb2 is output to the loopback circuit 9. The loopback detection circuit 14
The detection operation is prohibited when a detection prohibition signal Sa2 is input from a loopback pattern outflow prevention circuit 15 described later.

Loop back pattern outflow prevention circuit 15
Has a function similar to that of the loopback pattern outflow prevention circuit 12. When the loopback pattern signal Sr sent from the DSU 11 through the loopback circuit 9 is detected, the loopback detection circuit 14 A detection prohibition signal Sa2 for prohibiting the detection operation is output. When the operation prohibition signal Sc2 is input from the loopback detection circuit 14, the operation of the loopback pattern outflow prevention circuit 15 is prohibited.

In the above configuration, when a loopback pattern signal Sr is sent from the DSU 1 to perform a loopback test, the loopback pattern signal Sr is
The signal is input to the loopback pattern outflow prevention circuit 12 via the loopback circuit 3. As a result, the loopback pattern outflow prevention circuit 12 outputs the detection inhibition signal Sa1 to the loopback detection circuit 13 after detecting the loopback pattern signal Sr. As a result, the detection operation of the loopback detection circuit 13 is prohibited.

The loopback pattern signal S
r is input to the loopback detection circuit 14 via the MUX unit 4, the high-speed transmission path 6, and the MUX unit 8. Thus, after detecting the loopback pattern signal Sr, the loopback detection circuit 14 outputs the loopback pattern detection signal Sb2 to the loopback circuit 9 and sends the operation prohibition signal Sc2 to the loopback pattern outflow prevention circuit 15. Output.

Thus, in the loopback circuit 9, a loopback circuit for looping back the loopback pattern signal Sr is formed, and the loopback pattern signal Sr is looped by the loopback circuit 9 to the high-speed transmission line 6 side. Will be back. Here, in this case, since the detection inhibition signal Sa1 is input, the operation of the loopback pattern outflow prevention circuit 15 is inhibited. Therefore, the loopback pattern signal Sr is detected by the loopback pattern outflow prevention circuit 15 without being detected by the loopback pattern signal Sr.
The data is transmitted to the high-speed transmission line 6 via the UX unit 8.

The loopback pattern signal S
r is input to the loopback detection circuit 13 via the MUX unit 4. In this case, since the detection inhibition signal Sa1 is input, the detection operation of the loopback detection circuit 13 is inhibited. Accordingly, since the loopback pattern detection signal Sb1 is not output from the loopback detection circuit 13, the loopback circuit 3 does not include a loopback circuit. For this reason, the loopback pattern signal Sr is input to the DSU 1 via the loopback detection circuit 13 and the loopback circuit 3. DS
In U1, the failure location is specified based on the reception state of the loopback pattern signal Sr. Note that DSU11
The operation when the loopback pattern signal Sr is transmitted from is the same as the operation in the case of DSU1 described above.

As described above, according to the transmission system of the above-described embodiment, a bidirectional loopback can be prevented, and a loopback test can be remotely performed by the DSU1 or DSU11.

[0023]

As described above, according to the present invention,
Since the loopback pattern outflow prevention circuit is provided, the bidirectional loopback state is avoided when the loopback test is performed on the own station side, while the loopback test is performed on the opposite station side. Loopback is normally executed by the loopback circuit. Therefore,
According to the present invention, it is possible to obtain an effect that a loopback test can be performed remotely without occurrence of a situation where a loopback generated due to a conventional bidirectional loopback state cannot be canceled. Further, according to the present invention, since a loopback test can be remotely performed on the transmission device on the local station side, the transmission line, and the transmission device on the opposite station side, the maintainability can be improved. can get.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of a transmission system according to an embodiment of the present invention.

FIG. 2 is a block diagram illustrating a configuration of a conventional transmission system.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 DSU 2 In-station termination board 3 Loop-back circuit 4 MUX section 6 High-speed transmission line 7 In-station termination board 8 MUX section 9 Loop-back circuit 11 DSU 12 Loop-back pattern outflow prevention circuit 13 Loop-back detection circuit 14 Loop-back detection circuit 15 Loop-back Pattern outflow prevention circuit

──────────────────────────────────────────────────の Continuation of the front page (51) Int.Cl. ⁶ Identification symbol FI H04L 29/14 H04L 13/00 315A (72) Inventor Hitoshi Sakurai 7-1, Shiba 5-chome, Minato-ku, Tokyo NEC Corporation Inside

Claims (4)

[Claims] A transmission line connecting between the own station and the opposite station; a transmission device provided on the side of the own station for transmitting a signal via the transmission line; An opposite-side transmission device that transmits a signal through the transmission line provided, and transmits a loopback pattern signal to the own-station-side transmission device, and is input via the own-station-side transmission device.
A loopback test apparatus for receiving the loopback pattern signal looped back by the opposite station side transmission apparatus, wherein the own station side transmission apparatus transmits the loopback pattern signal transmitted from the loopback test apparatus. And a loopback pattern outflow prevention circuit that outputs a detection inhibition signal, and a detection signal that detects the loopback pattern signal that is input via the transmission line and is looped back by the opposite-side transmission device. On the other hand, when the detection prohibition signal is input, a loopback detection circuit that prohibits the operation of detecting the loopback pattern signal, and when the detection signal is not input, While sending the loopback pattern signal looped back to the loopback test apparatus,
A transmission system, comprising: a loopback circuit that loops back the loopback pattern signal to the opposite-station-side transmission device via the transmission path when the detection signal is input. 2. The transmission system according to claim 1, wherein the loopback test apparatus specifies a failure location based on a reception state of the loopback pattern signal. 3. A transmission line connecting between the own station and the opposite station; a transmission device provided on the own station side for transmitting a signal via the transmission line; An opposite-side transmission device provided for transmitting a signal via the transmission path, and a first loopback pattern signal transmitted to the own-station-side transmission device and input via the own-station-side transmission device A first loopback test device that receives the first loopback pattern signal looped back by the opposite station transmission device, and a second loopback pattern signal that is transmitted to the opposite station transmission device. Receiving the second loop-back pattern signal, which is input through the opposite station-side transmission device and is looped back by the own-station-side transmission device,
Wherein the local station side transmission device detects the first loopback pattern signal transmitted from the first loopback test device and generates a first detection inhibition signal. A first loopback pattern outflow prevention circuit to be output, and a first detection signal that detects the first loopback pattern signal that is input via the transmission path and is looped back by the opposite-side transmission device. And a first loopback detection circuit for prohibiting an operation of detecting the first loopback pattern signal when the first detection prohibition signal is input, and receiving the first detection signal. If not, the first loopback pattern signal looped back by the opposite station side transmission device is sent to the first loopback test device while the first loopback pattern signal is sent to the first loopback test device. And a first loopback circuit that loops back the loopback pattern signal to the opposite station side transmission device via the transmission line when the detection signal is input. A second loopback pattern outflow prevention circuit that detects the second loopback pattern signal sent from the second loopback test device and outputs a second detection inhibition signal; The second loopback pattern signal, which is looped back by the local station side transmission device, is input through the second loopback pattern signal to output a second detection signal, while the second detection inhibition signal is input. A second loopback detection circuit that inhibits the detection operation of the second loopback pattern signal when the second detection signal is not input; While the second loopback pattern signal looped back by the device is sent to the second loopback test device, when the second detection signal is input, the second loopback pattern signal is sent to the second loopback test device. A second loopback circuit for looping back to the local station side transmission device via a transmission path. 4. The first loop-back test apparatus specifies a failure location based on a reception state of the first loop-back pattern signal, and the second loop-back test apparatus includes a second loop-back test apparatus. 4. The transmission system according to claim 3, wherein a failure point is specified based on a reception state of the loopback pattern signal.