DE10228145A1 - Optical link monitoring method uses feedback of optical control signal fed along monitored link after conversion into feedback control signal with altered characteristics - Google Patents

Abstract

The monitoring method has an optical control signal (KS) supplied to the optical link (LWL) at one end and supplied to a feedback device (RV) upon reception at the opposite end, with detection of the feedback signal at the initial end of the optical link. The feedback device provides a feedback control signal (RKS) from the received optical control signal in which at least one characteristic is altered relative to the optical control signal, facilitating detection of the feedback signal at the control signal supply end. An independent claim for a device for monitoring an optical link is also included.

Description

The invention relates to a method and a monitoring device an optical connection according to the features of the preambles of claims 1 and 10th

While Surveillance techniques optical transmission systems and networks such as pilot tone methods, narrow-band detection methods, Protection lines are known, the way remains from the terminal to Coupling point in the network usually without monitoring. Still is one such surveillance important to clearly assign responsibility in the event of an error can.

Out DE 195 22 166 C1 an optical switch is known which can also be used, inter alia, as an arrangement for monitoring optical fibers, for example in the event of a line break (see page 3, lines 33-41). Here, an optical control signal is fed into an optical waveguide on the transmission side and is coupled out of the optical waveguide on the receiving side and is fed there into a receiving device. The optical control signal is reflected and modulated in the receiving device and fed back into the optical waveguide. The reflected optical control signal is decoupled from the optical waveguide on the receiving side and fed to a photodiode, which identifies a line break in the absence of the signal. The disadvantage here is the required use of active components at the coupling or decoupling point.

Another solution to monitor an optical Connection is that in addition to a data signal a control signal is transmitted to the end user, which reflects there and back again transferred to the sending side becomes.

This control signal is then in an assigned decoupling point within the network is detected. Detection of light from the control signal means that the Connection to the transfer point is okay. The disadvantage of this method is that it is used for one Broken fibers also lead to a reflection of the control signal can and thus an intact line can be simulated.

Another method is also known at the additional transmit a control signal to the data point via a first fiber to the transfer point and in which this control signal coupled out there on a second Fiber - under circumstances together with another data signal - transmitted back to the sending point becomes. A major disadvantage with this method is that that a second fiber is needed and therefore it cannot be determined which of the fibers is broken.

The object of the invention is a Specify method and apparatus in which identification an error cause to monitor a optical connection is unique. Furthermore, the device for surveillance the optical connection on the side facing away from the transmitter only have passive components.

The problem is solved with regard to their Process aspect by a method with the features of the claim 1 and in terms of their device aspect by a device with the features of claim 10.

• – am Anfang der zu überwachenden optischen Verbindung ein optisches Kontrollsignal in die optische Verbindung eingespeist wird,
• – bei dem am Ende der zu überwachenden optischen Verbindung das optische Kontrollsignal aus der optischen Verbindung ausgekoppelt und in eine Rückkopplungsvorrichtung eingespeist wird,
• – bei dem das optische Kontrollsignal aus der Rückkopplungsvorrichtung wiederum in die optische Verbindung zurückgekoppelt wird,
• – bei dem das rückgeführte optische Kontrollsignal aus der optischen Verbindung am Anfang der zu überwachenden optischen Verbindung ausgekoppelt und detektiert wird,

wird erfindungsgemäß die Rückkopplungsvorrichtung das rückgeführte optischen Kontrollsignal aus dem optischen Kontrollsignal derart ableitet, dass im rückgeführten optischen Kontrollsignal wenigstens eine Eigenschaft geändert wird, die sich vom ursprünglichen optischen Kontrollsignal unterscheidet und erfolgt die Detektion des rückgeführten optischen Kontrollsignals im Bezug auf diese unterschiedliche Eigenschaft.Based on a method of monitoring an optical connection in which:

• An optical control signal is fed into the optical connection at the beginning of the optical connection to be monitored,
• In which, at the end of the optical connection to be monitored, the optical control signal is coupled out of the optical connection and fed into a feedback device,
• In which the optical control signal is in turn fed back from the feedback device into the optical connection,
• In which the returned optical control signal is decoupled and detected from the optical connection at the beginning of the optical connection to be monitored,

According to the invention, the feedback device derives the returned optical control signal from the optical control signal in such a way that at least one property that differs from the original optical control signal is changed in the returned optical control signal and the returned optical control signal is detected in relation to this different property.

A major advantage of the method according to the invention can be seen in the fact that a clear separation between z. B. through disruptive Reflections not at the transfer point returned and at the transfer point returned light e.g. in the event of a fiber break becomes. To change a characteristic light wave parameter of the control signal for the Coding of the returned control signal can be a device for changing the Frequency or a polarization rotator can be used. The transfer directions of data signals and monitoring signals can identical or opposite be d. H. it can outgoing and / or incoming fibers are monitored.

One or more characteristic properties, such as a lightwave parameter - frequency, polarization, etc. - of a transmitted control signal are changed after transmission via the optical connection to be monitored so that after Reflection and subsequent reception of the light signal at the network end of the optical connection between the network node and the transfer point can be clearly determined whether a reflection has taken place at the transfer point or whether the reflection was caused by another interference from the optical connection. Only one optical fiber is advantageously required. In addition to the laser for generating the control signal, the device advantageously has only passive components. Further advantages result from a simple installation of this monitoring device and from the fact that no calibration of the optical connection is necessary. The transmission fiber itself or another additional line can be used as a duplex line as an optical connection for monitoring the transmission. All types of waveguides and free-beam connections such as an optical air connection can be provided as the optical connection. Modulation of the control signal or of the feedback control signal is possible to achieve a more sensitive detection. As a result, the signal level of the control signal can be selected to be smaller. In addition, a transmitted data signal can be used as an optical control signal. When using visible light for the control signals, a simple display on the end device can be implemented. For example, instead of a reflector, a polished and / or coated end face of an optical fiber can be used as a mirror.

Advantageous further developments of Invention are in the subclaims specified.

Embodiments of the invention are explained in more detail below with reference to the drawing.

Show:

1 a first realization according to the invention of monitoring an optical connection by doubling the frequency at the reflection point,

2 a second realization according to the invention of monitoring the optical connection by a polarization rotation at the reflection point,

3 : a variant of the device for returning the optical control signal into the optical connection.

In 1 A first device is shown, in which an optical connection LWL is monitored, the end of which forms a transfer point UP of a transmitted data signal DS. At the beginning of the optical connection LWL, a transmission unit SE is arranged, which generates a control signal KS by means of a light source LQ. Light from the light source LQ is fed via a coupler KO3 into an optical fiber, the end of which is connected to the input of the optical link LWL. The control signal KS is fed into the optical connection LWL by means of a first coupling unit KO1. At the end of the optical connection LWL, a second coupling unit KO2 is arranged, which decouples the control signal KS from the optical connection LWL to a feedback device RV. The control signal KS which is coupled out at the end of the optical link LWL to be monitored before or at the transfer point UP is fed to an element KE designed as a device for frequency change and a downstream reflector R which has the feedback device RV. For example, a frequency doubler is used as the frequency adjuster. The element KE and the reflector R form a receiving unit for the control signal KS, from which the optical control signal RKS, which is returned in this case by reflection, is fed back into the optical connection LWL. The reflected optical control signal RKS is coupled into the optical connection LWL by means of the second coupling unit KO2. The reflected optical control signal RKS is transmitted in the opposite direction from the optical control signal KS into the optical connection LWL, from which it is coupled out again at the first coupling unit KO1 and is led via the coupler KO3 to a receiving unit EE. However, the receiving unit EE can be an internal module of the transmitting unit SE. The receiving unit EE contains an isolation module IM, which is provided in the event of a frequency change to the original frequency of the optical control signal KS as a spectral filter F, which is only permeable to the changed frequency of the returned optical control signal RKS. The optical filter F is followed by an optical-electrical converter OEW, such as a photodiode. When using visible light, the optical-electrical converter OEW is not necessary. A polished section of a fiber downstream of the filter F is sufficient as a light indicator for an eye check. To avoid or reduce interference on a data signal DS and to achieve low attenuation values, the coupling units KO1, KO2 can be used as wavelength-selective coupling and decoupling elements. Only a single optical fiber is used in this device. However, the reflected or returned optical control signal RKS could also be transmitted to the transmission unit via a second optical waveguide. Furthermore, the optical control signal KS and / or the returned optical control signal RKS need not necessarily be transmitted on the same optical waveguide. In addition, the data signal DS can be used as an optical control signal K5. A bidirectional transmission of data signals for the optical connection LWL is also provided.

In 2 is another according to the invention Device shown, the characteristics of 1 contains, with the difference that the element KE is a polarization rotator. As a polarization rotator z. B. uses a Faraday rotator with 45 degrees rotation in the plane of polarization. As a result, the reflected optical control signal RKS is rotated by a 90 degree polarization plane during the feedback at the end of the optical connection LWL. Since the light passes through the same transmission path after the reflection as before the reflection, the received light from the reflected optical control signal RKS is polarized orthogonally to the transmitted control signal KS. However, the receiving unit EE no longer has a spectral filter F as an isolation module IM, but a polarization beam splitter PST for separating signals rotated by 90 degrees in the polarization. In this way, the reflected optical signal RKS is led to a first optical-electrical converter OEW1 and separated from the original optical control signal KS. A second optical-electrical converter OEW2 can also be assigned to the second output of the polarization beam splitter PST with a downstream coupler KO3, so that on the one hand the reflected optical control signal RKS with polarization direction rotated by 90 degrees to the 0 degree polarized reflected light arriving from an interference point at the optical connection LWL is clearly detected and separated. The light source LQ for generating the optical control signal KS is also connected to the decoupler KO3. The optical connection LWL is recognized as fault-free if the light output in the orthogonal polarization direction exceeds the light output detected by the second optical-electrical converter OEW2 by a predetermined factor. In addition to the polarization beam splitter PST, polarization filters can also be used for better separation of the control signals KS, RKS. A polarizer can also be connected downstream of the transmitter unit SE.

The two embodiments according to 1 and 2 can of course also be combined. The control signals and the reflected control signals can also be transmitted via an additional line, for example in a duplex cable.

Other encodings can also be used a characteristic light wave parameter for the optical to be reflected Control signal KS in addition to the frequency or polarization already mentioned for clear monitoring the optical connec tion can be used. It is important that the feedback control signal RKS has a measurable property that differs from properties of common reflections clearly distinguishes from the optical connection and continues is separable.

Instead of the element KE, a Data encoding instead of a change a property of a light wave parameter of the returned control signal RKS can be realized as well as a corresponding decoding for decoding or for detection of the returned control signal RKS in the receiving unit EE. The returned control signal should RKS can be modulated.

In 3 is a variant of the feedback device RV according to 1 and 2 shown. Instead of the reflector R, the second outcoupler KO2 is followed by a waveguide, which forms a loop SC with an end coupler EK connected upstream of the second coupling unit KO2. The element KE is arranged at one point of the waveguide. In contrast to the bidirectional beam path with the reflector R according to 1 and 2 a property of the optical control signal is changed once. As an element KE z. B. an electro-acoustic element can be used. The end coupler EK has coupling and decoupling properties that are adapted to the optical characteristics of the signals RK and RKS.

Claims (23)

Method for monitoring an optical connection (LWL), in which: - an optical control signal (KS) is fed into the optical connection (LWL) at the start of the optical connection (LWL) to be monitored, - in the end of the optical connection to be monitored (LWL) the optical control signal (KS) is coupled out of the optical connection (LWL) and fed into a feedback device, - in which the optical control signal (KS) is in turn fed back into the optical connection (LWL), - in which the returned optical control signal (RKS) is coupled out and detected from the optical connection (LWL) at the beginning of the optical connection (LWL) to be monitored, characterized in that - the feedback device generates the returned optical control signal (RKS) from the optical control signal (KS) derives in such a way that in the returned optical control signal (RKS) at least one property is changed in which the returned optical control signal (RKS) at the beginning of the optical connection differs from the original optical control signal (KS) and - that the detection of the returned optical control signal (RKS) takes place in relation to this different property. A method according to claim 1, characterized in that as optical control signal (KS) a data signal transmitted on the optical link (LWL) (DS) is used. A method according to claim 1 or 2, characterized in that the change in property by means of a variation of a light wave parameter of the optical control signal (KS). A method according to claim 3, characterized in that the Variation of a light wave parameter by means of a frequency change and / or a polarization rotation of the optical control signal (KS) in the feedback device he follows. A method according to claim 4, characterized in that with a frequency change the returned optical Control signal (RKS) after the one at the beginning of the optical connection (LWL) provided coupling spectrally filtered and detected will or that with a polarization rotation directions of polarization between the returned optical control signal (RKS) and the optical control signal (KS) at least after the At the beginning of the optical connection (LWL) provided decoupling if possible are provided orthogonally and the returned optical control signal (RKS) according to its Polarization direction is separated and detected. Method according to one of the preceding claims 1 to 3, characterized in that upon variation of another light wave parameter as the frequency or the state of polarization the returned optical Control signal (RKS) corresponding to the light wave parameter Signal isolation after the beginning of the optical connection (LWL) provided decoupling experiences. Method according to one of the preceding claims, characterized characterized that to determine the returned optical control signal (RKS) a light output measurement is carried out. Method according to one of the preceding claims, characterized characterized that for the optical control signal (KS) visible light is used, in which the presence of the coupled out optical control signal (RKS) after filtering or after polarization separation by Eye control can be determined. Method according to one of the preceding claims, characterized characterized that monitoring is purely passive. Monitoring device an optical connection (LWL) with one from a transmitter unit (SE) generated control signal (KS), where the optical connection (LWL) a first coupling unit (KO1) and has a second coupling unit (KO2) at its section end, in the case of the second coupling unit (KO2), a feedback device (RV) to return the Control signal (KS) downstream in the optical connection (LWL) at the beginning of the section of the optical connection (LWL) the returned optical Control signal (RKS) of a receiving unit (EE) is emitted, thereby in that the feedback device (RV) an element (KE) for change at least one property of the from the optical control signal (KS) returned optical Control signal (RKS) and that in the receiving unit (EE) a property dependent Isolation module (IM) for the detection of the returned optical control signal (RKS) is arranged. Apparatus according to claim 10, characterized in that the feedback device (RV) has a reflector (R), the element (KE) and the second Coupling unit (KO2) is interposed or that the Feedback device (RV) has an optical waveguide connected to the element (KE), the a loop (SC) with one of the second coupling units (KO2) upstream end coupler (EK) forms. Device according to claim 10 or 11, characterized in that that the change the property by means of a change a light wave parameter of the original optical control signal (KS) is feasible. Device according to one of claims 10 to 12, characterized in that that the element (KE) is a device for changing the frequency or a polarization rotator is. Device according to claim 13, characterized in that as Device for change the frequency a frequency doubler or as a polarization rotator a Faraday rotator with 45 degrees polarization rotation is provided is. Device according to one of claims 10 to 14, characterized in that that when the frequency is adjusted, the isolation module (IM) is spectral Filter (F) or the insulation module (IM) for polarization rotation a polarization beam splitter (PST) or a polarization filter is. Device according to one of claims 10 to 15, characterized in that for the returned optical Control signal (RKS) and / or for the optical control signal (KS) the isolation module (IM) opto-electrical Converter (OEW) or devices for visualizing the signals are connected downstream. Device according to one of claims 10 to 16, characterized in that that the reflector (R) by a polished and / or coated End portion of a waveguide is realized. Device according to one of claims 10 to 17, characterized in that that with visible light at least for the returned optical control signal (RKS) the insulation module (IM) an optical fiber with polished End section is connected as a light indicator. Device according to one of claims 10 to 18, characterized in that that as coupling units (KO1, KO2) wavelength-selective coupling and decoupling elements are provided. Device according to one of claims 10 to 19, characterized in that that the optical connection (LWL) has one or more optical fibers, the ends of which are connected to the coupler units (KO1, KO2). Device according to one of claims 10 to 20, characterized in that that the optical connection (FO) as a bidirectional transmission link for data signals is trained. Device according to one of claims 10 to 21, characterized in that that the transmitter unit (SE) has a modulator for modulating the optical control signal (KS) has. Device according to one of claims 10 to 22, characterized in that that the element (KE) is designed as a modulation adjuster, the receiving unit (EE) being a module for modulation adjustment corresponding detection of the optical feedback control signal (RKS) having.