Optics: measuring and testing – By light interference – Using fiber or waveguide interferometer
Reexamination Certificate
2000-01-21
2002-07-09
Turner, Samuel A. (Department: 2877)
Optics: measuring and testing
By light interference
Using fiber or waveguide interferometer
C356S480000, C250S227140
Reexamination Certificate
active
06417926
ABSTRACT:
The present invention relates to an apparatus for the measurement of the wavelength of optical waves and, in particular, to the measurement of wavelengths of short optical pulses and to high accuracy measurements of optical wavelengths.
BACKGROUND OF THE INVENTION
There is a requirement in the field of optical communications for the use of short pulses of light, for high-bit-rate transmission and for optically pure sources of light for wavelength division, multiplexing and soliton pulse transmission. In communication diagnostics it is desirable to determine the wavelength of a single optical pulse, in that the wavelength may differ from pulse to pulse. As the number of multiplexed channels increase down a single fibre, it is also important to obtain the wavelength measurement with increasing accuracy.
In optical sensing applications, there is an increasing need for high-power, short-pulsed optical sources with high wavelength stability between pulses. The accurate wavelength measurement of these sources is essential.
There is a present limitation to the accurate wavelength measurement of short pulses in that conventional apparatus, such as the monochromator, require the scanning of a dispersive element over a time shorter than the duration of the pulse. This is not feasible when the pulse is short. Another conventional technique operates with the detection of light scattered from a dispersive element by an array of detectors. Again, this is not usable with short pulses as the interference path length is limited by the pulse width. Both these techniques can be used with some success to measure the average wavelength of a number of pulses but are unable to accurately quantify the wavelength of each individual pulse.
SUMMARY OF THE INVENTION
This invention uses backscatter in optical fibres to transform the short pulse into a longer one, which is open to wavelength analysis by conventional. techniques. The backscatter process also provides a mechanism for the highly-accurate measurement of the wavelength using the technique described in the present invention.
According to the present invention there is provided apparatus for measuring the wavelength of a pulsed or continuous source of light, which apparatus comprises at least one scatter medium, such as an optical fibre which is able to provide a continuous backscatter signal, a wavelength measurement device which is adapted to operate with a dispersive element or with an interference element and a conversion means for converting an optical signal into an electrical signal, which conversion means comprises a detector or an array of detectors.
The invention also provides a method for measuring the wavelength of a pulsed or continuous source of light which method comprises passing the light down a backscatter medium such as an optical fibre, detecting the backscattered light from the backscatter medium and measuring the wavelength of the backscattered light.
The optical fibre may be single mode, or multimode and may have tailored doping levels, or many different doping layers, to enhance the backscattering. The optical fibre may be physically modulated to reduce the effect of any power variation in the backscatter signal due to coherent interference. The optical fibre may also exhibit birefringence and include polarisation selective components.
In use, light from a test source, the wavelength of which is to be measured, is transmitted down an optical fibre and backscattered light is transmitted back down the fibre. The duration of the light emitted from the test source may be short, but the duration of the backscattered light will be relatively long. The backscattered light will be predominantly of the same wavelength as the transmitted light. This may be measured directly to determine the wavelength of the test source. The backscattered light also contains a Brillouin component which has a frequency shift from the source wavelength that is inversely proportional to the source wavelength. Measurement of this Brillouin shift can yield the source wavelength to high accuracy.
Higher accuracy still can be obtained by comparing the test wavelength with the known wavelength of a reference signal using an interferometer. The difference in the interference orders of the two signals can be determined with a coarser wavelength measurement, such with the measurement of the Brillouin shift, and the higher accuracy can be obtained from the interferometer reading. The interferometer can be calibrated by modulating a reference source at a known frequency.
When light propagates through an optical fibre, a small amount is backscattered. The propagating light generates backscattered light for the duration of twice its transit through the optical fibre. This has the effect that a short pulse will generate a continuous backscattered signal whose duration is twice the time taken for the incident pulse to travel through the fibre, a time which may be significantly larger than the input pulse duration. Thus, as described in the present invention, a short pulse with previously inaccurately determinable wavelength is transformed into a long, backscattered signal which may be accurately spectrally analysed.
The backscattered signal predominantly comprises three components. The elastically scattered Rayleigh signal which has the same wavelength as the input signal, and the significantly weaker inelastically scattered Brillouin Stokes and anti-Stokes signals which have a characteristic wavelength difference from the Rayleigh signal.
The wavelength of the input light pulse may be measured directly from the wavelength of the Rayleigh signal using conventional techniques, such as those stated earlier. The wavelength can be measured to greater accuracy, however, from the analysis of the Brillouin signal. The frequency separation of the Brillouin signal from the Rayleigh signal is inversely proportional to the input light wavelength. Hence, by measuring the frequency shift of the backscattered Brillouin signal, the wavelength of the source signal can be determined. Furthermore, it is possible to determine the Brillouin shift very accurately with the use of interference spectrometers, such as the Fabry-Perot interferometer, and, hence, to measure the source wavelength accurately. In this case, the Brillouin backscatter signal is calibrated by comparing the Brillouin shift generated by a source of known wavelength with the fibre held at a known temperature. Even higher accuracy may be obtained by measuring the relative frequency of the Rayleigh signal with respect to a reference source with a known wavelength.
The reference source may be a single mode or multimode coherent source with known wavelength and it may be a gas laser or a solid-state laser.
Here the Rayleigh signal and the reference signal are scanned simultaneously with an interferometer, for example with a Fabry-Perot interferometer, to measure the apparent frequency separation with a very high accuracy. The overall frequency separation between the two signals would be that apparently measured by the calibrated interferometer scan plus an integer number of free spectral ranges, (The free spectral range is the frequency over which an interference pattern repeats itself, for example, two optical sources whose frequencies differ by an integer number of free spectral ranges would be superimposed.) In this system a coarse wavelength measurement would determine the number of free-spectral-ranges separating the two sources while the interferometer reading provides an accurate determination of the test source wavelength. As described in the present invention, a particularly useful configuration would use the Brillouin shift measurement to provide the coarse wavelength measurement.
The reference source, and/or test source, and/or backscattered signal may be amplified and/or attenuated to match the powers of the measured backscattered signal and the measured reference signal for efficient detection, and optical isolators may be used to prevent instability of the laser sources.
The reference optical fibre may be a
Farhadiroushan Mahmoud
Parker Tom Richard
Baker & Botts L.L.P.
Sensornet Limited
Turner Samuel A.
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