JP3003774B2 - Optical communication system having PDS configuration and loopback test method thereof - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical communication system having a passive double star (PDS) configuration, and more particularly, to a method for testing a loopback of a slave station using a new joining slot.

[0002]

2. Description of the Related Art FIG. 2 shows an optical communication system having a PDS configuration. The illustrated optical communication system includes one master station A and first to n-th (n is an integer of 2 or more) slave stations B ₁ , B ₂ , B ₃ ,
, _Bn are connected via the star coupler 1.
Generally, the distances from the master station A to the first to n-th slave stations B _{1 to} B _n are different.

Conventionally, a loopback test is performed as follows. First, the slave station B _i (1 ≦ i ≦ n)
At the time of joining, the address is designated from the master station A, and the delay time is measured using the joining slot. As not hit the transmission data of the sub-stations B _i in the master station A, to set the transmission delay time. Each of the slave stations B _i has a delay control unit. Upon receiving data from the master station A, the delay control transmits data to the master station after a set delay time.

Various prior arts related to the present invention are known. For example, Japanese Unexamined Patent Publication No.
In the optical subscriber line multiplexing apparatus of the optical subscriber transmission apparatus having the passive double star configuration, "optical subscriber transmission apparatus" which performs a loopback including an optical transmitting unit and an optical receiving unit. Is disclosed. In the prior art 1, an optical burst signal (transmission) from an optical transmission unit is transmitted to an optical fiber via an optical branch, and is also looped back to an optical reception unit via the optical branch. The optical burst signal (reception) from the optical fiber is supplied to the optical receiving unit via the optical branch. The received burst signal from the optical receiver is detected by the synchronization detector, and the transmission burst signal is detected by the transmitted signal synchronization detector. The data corresponding to the detected transmission burst signal is dropped by the drop unit, and either this signal or the reception burst signal is selected by the selection unit and becomes a loopback signal. The loopback control unit controls the drop unit and the selection unit.

In Japanese Patent Application Laid-Open No. Hei 5-244101 (hereinafter referred to as Prior Art 2), a loop island can be released, and a function of detecting a break in an input signal to cut off a light output becomes unnecessary. Provided are an optical amplification repeater in which a component mounting space is reduced, a loop-back method, and an optical amplification repeater capable of section preliminary switching. The optical amplification repeater of the prior art 2 includes an optical switch unit having first and second input terminals and first and second output terminals. First
The output of the upstream and downstream optical amplifiers is connected to the first and second input terminals, respectively, and the upstream and downstream optical transmission lines are connected to the first and second output terminals, respectively. Normally, this optical switch sends out an optical signal input from an upstream optical amplifier to an upstream transmission line, and sends an optical signal input from a downstream optical amplifier to a downstream optical transmission line. At the time of the loopback test, the optical switch switches so that the optical signal input from the upstream optical amplifier is transmitted to the downstream optical transmission line.

Further, Japanese Utility Model Laid-Open No. 2-28158 (hereinafter referred to as Prior Art 3) discloses a loopback path for returning a signal of a downstream optical line to an upstream optical line toward a center device of a remote device. The "optical transmission system fault isolation device" that enables a loopback test in the center-side device and enables simple, rapid, and remote fault isolation of the optical line and the transmission device is disclosed.

[0007]

The above-mentioned conventional PDS
The optical communication system having the configuration is a loopback from the master station to the slave station which is enabled when the delay time control is performed in the slave station. For this reason, there is a problem that the slave station cannot perform loopback from the master station to the slave station before the initial joining and when the delay time control cannot be normally performed.

Therefore, an object of the present invention is to enable loopback from a master station to a slave station regardless of the delay time control function of the slave station.

In the prior art 1, loopback is performed inside the optical line multiplexer, that is, in the master station, but not in the slave station.
Further, the prior art 2 is a technical idea related to the loopback method of the optical amplification repeater, and does not perform the loopback including the slave station similarly to the prior art 1.

The prior art 3 is similar to the present invention in that a loopback test is performed by folding a signal on a downstream optical line to an upstream optical line in a remote device, that is, a slave station. However, this prior art 3 has 1
This is a technical idea related to an optical transmission system in which one center-side device (master station) and one far-side device (slave station) are connected by a downstream optical line and an upstream optical line. This is different from the present invention in which the system is an optical communication system having a PDS configuration. That is, in the optical communication system of the PDS configuration, since a plurality of slave stations are connected to the master station via the star coupler, various problems occur if the slave station simply turns back as in the prior art 3. .

[0011]

A PD to which the present invention is applied
In the S configuration optical communication system, one master station and a plurality of slave stations are connected to a passive double star (PDS) via an upstream optical transmission line and an upstream star coupler and a downstream optical transmission line and a downstream star coupler. It is an optical communication system having a configuration. The master station transmits a downlink data frame composed of an overhead section, a downlink data time slot to each slave station, and a downlink subscription slot to a plurality of slave stations via a downstream optical transmission line and a downstream star coupler. Send. The plurality of slave stations are connected to the master station via an upstream optical transmission line and an upstream star coupler,
An uplink data frame composed of an uplink data time slot and an uplink subscription slot from each slave station is transmitted.

In an optical communication system having a PDS configuration according to the present invention, a master station transmits a slave station optical signal having an upstream data frame transmitted from a plurality of slave stations via an upstream optical transmission line and an upstream star coupler. As a master station received optical signal, and converts the master station received optical signal into a master station received electrical signal; a master station receiving section for receiving the master station received electrical signal; A master station transmission unit for transmitting a master station transmission electric signal having a frame, a master station electric / optical conversion unit for converting the master station transmission electric signal into a master station transmission optical signal, a master station reception unit and a master station transmission unit. A loopback control unit connected to perform loopback control. When performing a loopback test, the loopback control unit adds the loopback test information and the address of the slave station to be tested to the overhead part in the downlink data frame, and adds the downlink subscription slot in the downlink data frame. Then, the loop-back data addressed to the slave station to be tested is inserted, and the master station transmission unit is controlled to transmit the downlink data frame. Each of the plurality of slave stations receives a master station transmission optical signal transmitted from the master station via a downstream optical transmission line and a downstream star coupler as a slave station reception optical signal, and receives the slave station reception optical signal. A local station optical / electrical conversion unit for converting a local station transmission electric signal into a local station transmission optical signal; and a local station optical / electric conversion unit Unit and a return unit connected to the slave station electrical / optical conversion unit. The loopback means detects the address of its own station and the loopback test information in the overhead part in the slave station received electric signal,
As the slave station transmission electric signal, a signal in which the loopback data included in the downlink joining slot in the downlink data frame is directly inserted into the uplink joining slot in the uplink data frame is looped back to the slave station electrical / optical converter.

[0013] Further, a loopback test method for an optical communication system having a PDS configuration to which the present invention is applied is characterized in that one master station and a plurality of slave stations transmit an upstream optical transmission line, an upstream star coupler, and a downstream optical transmission line. This is a loopback test method in an optical communication system having a passive double star (PDS) configuration via a road and a downstream star coupler. The master station is
A downlink data frame including an overhead section, a downlink data time slot and a downlink subscription slot addressed to each slave station is transmitted to a plurality of slave stations via a downstream optical transmission line and a downstream star coupler. Each of the plurality of slave stations transmits, to the master station, an uplink data frame composed of an uplink data time slot and an uplink subscription slot from each slave station via an uplink optical transmission line and an uplink star coupler. .

In the loopback test method for an optical communication system having a PDS configuration according to the present invention, when performing a loopback test, the master station includes loopback test information and a test target to be tested in an overhead section in a downlink data frame. The downlink data frame is transmitted to a plurality of slave stations with the address of the test slave station added thereto and the loopback data addressed to the slave station under test inserted in the slot for downlink subscription in the downlink data frame. When each of the plurality of slave stations detects its own address and the loopback test information in the overhead section in the downlink data frame, the loop included in the downlink subscription slot in the downlink data frame as the uplink data frame. A signal in which the back data is directly inserted into the uplink joining slot in the uplink data frame is transmitted to the master station.

[0015]

Embodiments of the present invention will be described below in detail with reference to the drawings.

FIG. 1 shows a PDS according to an embodiment of the present invention.
1 shows an optical communication system having a configuration. The illustrated optical communication system has one master station A and first to n-th slave stations B ₁ , B ₂ ,.
, _Bn are connected by an optical transmission line via a star coupler. The star coupler comprises an up star coupler 1A and a down star coupler 1B. The optical transmission path includes an upstream optical transmission path 2A and a downstream optical transmission path 2B.

The master station A is a master station optical / electrical converter (O / E).
Unit) 3A, TDMA receiving unit 4A, TDMA transmitting unit 5
A, a master station electrical / optical converter (E / O unit) 6A, and a loopback controller 7A. O / E section 3A is a slave station B
_It receives the slave station transmission optical signal from the upstream optical transmission line 2A transmitted from _{1 to Bn} as a master station reception optical signal, and converts the master station reception optical signal into a master station reception electrical signal. The TDMA receiver 4A receives the master station received electric signal from the O / E unit 3A. The TDMA transmission unit 5A performs transmission control and transmits a master station transmission electric signal. The E / O section 6A converts the master station transmission electrical signal into a master station transmission optical signal. Loopback control unit 7
A is connected to the TDMA receiving unit 4A and the TDMA transmitting unit 5A, and performs loopback control as described later.

Each of the slave stations B _{1 to} B _n includes a slave station optical / electrical conversion unit (O / E unit) 3B, a subscription slot loopback unit 4B, a delay control unit 5B, and a slave station electric / optical unit. Conversion unit (E
/ O section) 6B. The O / E unit 3B receives the master station transmission optical signal transmitted from the master station A from the downstream optical transmission line 2B as a slave station reception optical signal, and converts the slave station reception optical signal into a slave station reception electrical signal. Convert. The E / O unit 6B converts the local station transmission electrical signal into a local station transmission optical signal. The joining slot loopback unit 4B includes an O / E unit 3B and an E / O unit 6B.
And performs loopback control of the data in the joining slot as described later. The delay control unit 5B is connected to the subscription slot loopback unit 4B and controls the transmission delay time to the master station A as described above.

FIG. 3 shows a format of a data frame transmitted and received between the master station A and the slave stations B _{1 to} B _n in the optical communication system shown in FIG. In FIG.
(A) shows a format of a downlink data frame to be transmitted from the master station A to each slave station B ₁ ~B _n, (B) it is transmitted from each slave station B ₁ .about.B _n to the master station 3 shows the format of an upstream data frame. As shown in FIG. 3A, the downlink data frame includes an overhead section OH, a downlink data time slot addressed to each of the slave stations B _{1 to} B _n ,
And a downlink slot. FIG.
As shown in (B), the upstream data frame is transmitted to each slave station B.
_{1 to} B _n, which are composed of uplink data time slots and uplink subscription slots.

Next, the operation of the optical communication system according to the present embodiment will be described with reference to FIGS. Here, a case where a loopback test is performed from the master station A to the n-th slave station _Bn will be described as an example.

In the master station A, the loopback control section 7A
The address of the n-th slave station _Bn and the loopback test information are added to the overhead section OH of the downlink data frame shown in FIG. 3A, and the loopback data to the _n- th slave station Bn is added to the downlink data frame. TDMA transmitting section 5A so as to insert data into the
Control. TDMA transmission unit 5A transmits the data having the downlink data frame having such a configuration via the E / O section 6A to the slave station B _n of the n.

On the other hand, in the n-th slave station B _n , the slot loopback unit 4B for joining adds its address and loopback test information from the overhead unit OH of the signal received via the O / E unit 3B. Upon detection, loopback data received in the downlink subscription slot of the downlink data frame (FIG. 3A) is looped back, and the downlink subscription slot of the uplink data frame (FIG. 3B) is used as it is. The data is transmitted to the master station A via the E / O unit 6B.

As described above, at the time of loopback, a loopback test can be performed without the intervention of the delay control unit 5B.

The present invention is not limited to the above-described embodiment, and various changes and modifications can be made without departing from the spirit of the present invention.

[0025]

As described above, according to the present invention, the loopback test can be performed without the intervention of the delay control unit of the slave station to be tested, so that the maintenance of the optical communication system can be easily performed. Can be.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an optical communication system having a PDS configuration for realizing a loopback test method according to an embodiment of the present invention.

FIG. 2 is a block diagram illustrating a schematic configuration of an optical communication system having a PDS configuration.

3A and 3B are diagrams showing a frame format of data transmitted and received in an optical communication system having a PDS configuration. FIG. 3A shows a downlink data frame, and FIG. 3B shows an uplink data frame.

[Explanation of symbols]

A master station B _{1 to} B _n slave station 1A, 1B star coupler 2A, 2B optical transmission path 3A, 3B O / E section 4A TDMA receiving section 4B slot loopback section for joining 5A TDMA transmitting section 5B delay controlling section 6A, 6B E / O section 7A Loopback control section

Claims (3)

(57) [Claims] 1. A passive double star (PDS) in which one master station and a plurality of slave stations are connected via an upstream optical transmission line and an upstream star coupler and a downstream optical transmission line and a downstream star coupler.
In the optical communication system having the configuration described in the above, the master station transmits the downlink data to the plurality of slave stations via the downstream optical transmission line and the downstream star coupler, and an overhead unit and each slave station. A downlink data frame composed of a time slot for downlink and a slot for downlink subscription is transmitted, and the plurality of slave stations are transmitted from the slave stations to the master station via the upstream optical transmission line and the upstream star coupler. In an optical communication system having a PDS configuration, which transmits an uplink data frame composed of an uplink data time slot and an uplink subscription slot, the master station transmits the upstream optical transmission path from the plurality of slave stations to the upstream optical transmission line. A slave station transmission optical signal having the uplink data frame transmitted through the uplink star coupler is received as a master station reception optical signal, and the master station reception optical signal is converted into a master station reception electrical signal. A master station optical / electrical conversion section, a master station receiving section for receiving the master station reception electric signal, a master station transmitting section for transmitting a master station transmission electric signal having the downlink data frame, and the master station transmission electric signal. A master station electrical / optical conversion unit that converts a signal into a master station transmission optical signal; and a loopback control unit that is connected to the master station reception unit and the master station transmission unit and performs loopback control. The back control unit, when performing a loopback test, adds loopback test information and an address of a slave station to be tested to the overhead unit in the downlink data frame, and performs the downlink in the downlink data frame. Inserting the loopback data addressed to the slave station under test into the joining slot, and controlling the master station transmission unit to transmit the downlink data frame, wherein each of the plurality of slave stations includes the master station. The base station receives the master station transmission optical signal transmitted from the station via the downstream optical transmission line and the downstream star coupler as a slave station reception optical signal, and converts the slave station reception optical signal into a slave station reception electrical signal. Substation light /
An electrical converter, a slave station electrical / optical converter that converts a slave station transmitted electrical signal having the uplink data frame into the slave station transmitted optical signal, the slave station optical / electrical converter, and the slave station electrical / optical. And a loopback unit connected to a conversion unit, wherein the loopback unit detects the address of the local station and the loopback test information in the overhead section in the local station received electric signal. A signal in which the loopback data included in the downlink subscription slot in the downlink data frame is directly inserted into the uplink subscription slot in the uplink data frame as a transmission electrical signal is transmitted to the slave station electrical / optical converter. PDS characterized by folding back
An optical communication system having a configuration. 2. The optical communication system having a PDS configuration according to claim 1, wherein each of the plurality of slave stations includes a delay control unit connected to the loopback unit and performing delay time control. 3. A passive double star (PDS) in which one master station and a plurality of slave stations are connected via an upstream optical transmission line and an upstream star coupler and a downstream optical transmission line and a downstream star coupler.
A loopback test method in an optical communication system having a configuration of, wherein the master station, through the downlink optical transmission line and the downlink star coupler to the plurality of slave stations,
A downlink data frame composed of an overhead unit, a downlink data time slot addressed to each slave station, and a downlink subscription slot is transmitted, and each of the plurality of slave stations transmits the uplink optical transmission path to the master station. Transmitting an uplink data frame composed of an uplink data time slot and an uplink subscription slot from each slave station via the uplink star coupler, and a loopback test method for an optical communication system having a PDS configuration, When performing a loopback test, the master station adds loopback test information and an address of a slave station to be tested to the overhead section in the downlink data frame, and adds the downlink subscription in the downlink data frame. With the loopback data destined for the slave station under test inserted in the slot for use, the downlink data frame is sent to the plurality of slave stations. Transmitting, each of the plurality of slave stations, when detecting its own address and the loopback test information in the overhead section in the downlink data frame, as the uplink data frame, in the downlink data frame Transmitting a signal in which the loopback data included in the downlink subscription slot is directly inserted into the uplink subscription slot in the uplink data frame to the master station, to the master station. Back test method.