DE8909905U1 - Backscatter meter - Google Patents

Description

ANT Communications Engineering 6mb'Ä: · ·* .*.".', .'··."·' .* BK 83/104

Description

Backscatter meter

The complaint concerns a backscattering device according to the generic term of claim 1.

Backscattering technology is an important measuring method in optical communications technology. It is used for fault location, for determining splice and point loss and for determining fiber optic and cable system loss.

The structure of a backscatter measuring device is known, for example, from EP 122 953 A1 . The backscatter measuring device has a pulsed light source and a coupler for coupling the light into an optical waveguide. A photoreceiver is used as a receiver for the backscattered light, means for signal processing, an intermediate storage device and an evaluation unit are provided. The evaluation unit is connected to output devices. A control unit is provided for control.

Another backscatter measuring device is known from "Backscatter dispersion measuring device for glass fiber production" by R. Bondiek and WE Freyhardt in ntz volume 36 (1983) issue 7, pp. 438-441. From this article it is known that lasers with high transmission power are used as the light source, which also requires high drive currents.

ANT Nachrichtentechnik ÄmbH. . : ·.··.' . '.-*: : BK 89/104

Communications engineering (JrnbH. . : &idigr;."." . "·\ ·'..·

In order to measure the return loss of optical components, such as a connector, using backscattering technology, the pulse height of the connector's reflection pulse must be evaluated using the backscattering diagram. The reflected energy is significantly greater (factor 100 or more) than the backscattered energy and is superimposed on it.

To measure the return loss, it is necessary to generate a reference signal with a defined signal. This can be done, for example, by immersing the end of the optical fiber to be measured in a fluid and thus generating a standard reflection pulse. When doing this, care must be taken to ensure that the free optical fiber end is cut exactly perpendicular to the core axis, and the reflected power of the standard reflection element must be known exactly.

The aim of the innovation is to provide a backscattering measuring device with which the return loss of optical fiber components can be measured.

The problem is solved by the features of claim 1. Advantageous further developments are specified in the subclaims.

A backscatter measuring device that complies with the new standards has an internal reference line to which the object to be measured can be connected. The reference line serves as a feed line for each measurement. The power scattered back by the reference line is known and can be assigned to the measured backscatter signal. The length of the reference line must be selected so that the

ANT Communications Engineering (JmbH· . &iacgr;.',',,'··'' : BK 89/10

The backscatter signal generated by the reference line can be clearly evaluated.

Since when measuring the return loss it is also important to ensure that the reflection pulse and the backscatter signal are in the linear display range of the backscatter measuring device, it is sensible to provide a control of the transmission power. This can be done either by optical attenuators or by controlling the optical output power of the light source.

The measures listed above have significantly expanded the application area of a backscatter measuring device. External aids such as optical attenuators or standard reflection elements are not necessary when measuring return loss. The new backscatter measuring device represents a user-friendly solution.

An example of the innovation is described using the figure. The figure shows a block diagram of a backscatter measuring device according to the innovation and the setup for a measuring process.

The figure shows a measurement object M with a mechanical splice Sp. The measurement object M is connected to a backscatter measuring device G at a coupling part A. A reference line R is located within the backscatter measuring device G at the coupling part A. The reference line R is connected to the laser L via a beam splitter ST for coupling light and to the photodiode P for coupling light out. A laser control LA is connected to the laser L. A controller S accessible from outside the backscatter measuring device G

ANT Communications Engineering &phgr;&igr;&psgr;&EEgr;; . : :.'■·'. .'· . '; BK 89/104

to regulate the control current of the laser control LA and thus to regulate the optical output power of the laser L. The backscattered and/or reflected light received by the photodiode P is evaluated in an evaluation unit AW and displayed on a monitor Mo, for example as a backscatter diagram.

In the present case, reflection pulses are generated both at the interface between coupling part A and measurement object M and at the mechanical splice Sp.

The device's own reference line is significantly longer than necessary for the direct connection of its endpoints.

Claims (3)

ANT Communications engineering feiafcH .::."··.'..'■ · ·' BK 89/104 Protection claims 1. Backscatter measuring device for measuring return loss, which has an optical waveguide between the light source and the coupling part (A) for a measurement object (M), characterized in that the optical waveguide serves as an internal reference line (R) in the backscatter measuring device (G), to which a measurement object (M) can be connected and which is at least long enough that its backscatter attenuation can be clearly determined from the backscatter diagram or that, if the backscatter attenuation is known, its backscatter signal is clearly shown in the backscatter diagram. 2. Backscatter measuring device according to claim 1, characterized in that the device-internal reference line (R) serves as a lead length for a connectable measuring object (M). 3. Backscattering device according to one of claims 1 or 2, characterized in that at least one laser (L) is provided as the light source and that an internal device controller (S) accessible from the outside is provided, which serves to regulate the optical output power of the light source.