The subject application is a U.S. national stage of PCT/CN2014/089903 filed on Oct. 30, 2014 and claims priority on Chinese application no. 201410567490.3 filed on Oct. 22, 2014. The contents and subject matter of the PCT and Chinese priority applications are incorporated herein by reference.
The present invention relates to photonic information processing, particularly, a method for measuring and compensating for channel mismatch of an ultra-high speed photonic sampler.
Photonic analog to digital conversion (PADC) techniques have been progressing rapidly in recent years, and have become hotspots in photonic electronics. Since PADC performance depends on properties of the photonic sampler thereof, how to generate a high-speed and stable optical pulse sequence for the photonic sampler has become an important subject in the field of the art. Time-wavelength interleaved technique (Clark T R, Kang J U, Esman R D, Performance of a time-wavelength interleaved photonic sampler for analog-digital conversion [J]. Photonics Technology Letters, IEEE, 1999, 11(9): 1168-1170.), as an effective method for generating an ultra-high repetition rate optical pulse sequence, makes full use of low jitter property of a mode-locked laser and advantages of the high repetition rate and wide band thereof to generate a stable ultra-high speed optical pulse sequence, thus becoming a general method for generating an ultra-high speed photonic sampling clock.
However, for an ultra-high speed photonic sampling clock generated by time-wavelength interleaving, there exist some extent mismatches among different channels in respect of time delay, amplitude and pulse shapes. In actual scenario, variable optical delay lines and a variable attenuator are introduced in each channel for adjustment of mismatch of time delay and amplitude (Zou, Weiwen; Li, Xing, et al., An ultra-high speed photonic digital to analog conversion method and device therefor, China Patent No. 201410065510.7 [P], 2014). For compensation of channel mismatch, real time measurement of the pulse sequence in each channel is needed by means of experiment, and the variable optical delay lines and variable attenuators are adjusted in accordance with the measured amplitude and delay information for realization of matching among the channels. For comparative low repetition rate optical pulse sequences, amplitude and time delay information may be obtained simply by means of time-domain observation via an oscilloscope. However, for ultra-high speed optical pulse sequences, time-domain measurement thereof cannot be implemented due to limitation of sampling rate of the oscilloscope. Therefore, other methods are needed to be sought out for measurement of channel mismatch of an ultra-high speed time-wavelength interleaved optical pulse sequence.
The object of the present invention is to overcome the defect of the current technology by providing a method for measuring multi-channel mismatch of an ultra-high speed photonic sampler and a measurement compensation device thereof, which is realized by measuring the spectrum and frequency of the pulse sequence respectively via an optical spectrum analyzer and an electrical spectrum analyzer and by analyzing the frequency domain information to obtain the mismatches of the various channels, thus being employed for effective compensation method for mismatches.
The technical principle of the present invention is as follows:
For a time-wavelength interleaved pulse sequence having M channels and a period of Ts, the time-domain of the pulse sequence may be expressed as:
wherein ak is the pulse amplitude of the kth channel, τk the time delay thereof, and uk(t) the normalized waveform thereof. The signal obtained by a photodetector with a responsivity of RPD is:
The radio frequency power spectrum as measured by an electrical spectrum analyzer is expressed as:
wherein ƒs=1/Ts, and ũk (ƒ) is the Fourier transformation of uk(t). The latter may be obtained by means of calculation of the measured optical spectrum:
Ek(ƒ) represents the optical spectrum as measured by the optical spectrum analyzer in the kth channel. In the same manner, the amplitude ak in each channel may be obtained by means of calculation of the optical spectrum power:
ak=|∫−∞+∞Ek(ƒ)dƒ|2 k=1,2, . . . ,M (5)
According to expression (3), there exist M peaks Pk, k=1, 2, . . . , M, on the interval [0, ƒs] of the radio frequency spectrum, with an expression:
Expression (6) implicates that Pk is a of ak, ũk(ƒ) and τk, k=1, 2, . . . , M, with an expression:
Pk=Pk[a1,a2, . . . ,aM;ũ1(ƒ),ũ2(ƒ), . . . ,ũM(ƒ);τ1,τ2, . . . ,τM] (7)
The M spectrum peaks Ck, k=1, 2, . . . , M measured by the electrical spectrum analyzer corresponds with Pk with a relation:
10 log10Pk=Ckk=1,2, . . . ,M (8)
For time delay and without loss of generality, τ1=0 may be supposed to be the reference starting point. By rearranging expression (8), M independent equations may be obtained:—
Since ũk (ƒ) and ak may be obtained by calculating the expressions (4) and (5), with the calculated results therefrom, and in accordance with the function relation of expression (7), Pk becomes a function of just one argument of the time delay τk, and expression (9) becomes an equation group solely in respect of the time delay τk:
By means of solving expression (10) via numerical method, all the M time delays τk, k=1, 2, . . . , M can be obtained.
In conclusion, the pulse amplitude and time delay in each channel may be obtained by means of measuring the pulse sequence optical spectrum and the radio frequency, and therewith as a basis to adjust the variable optical delay lines and the variable attenuator, compensation of channel mismatch is realized.
The technical solution of the present invention is as follows:
A method for measuring multi-channel mismatch of an ultra-high speed photonic sampler, comprising the following steps:
Step 1. Splitting a to-be tested multi-channel optical pulse signal sequence into 2 paths by means of an optical fiber coupler, with one path thereof being input into a spectrometer, the other path passing through a photodetector and being inputted into an electrical spectrum analyzer, with a measurement result of an input signal respectively of the spectrometer and of the electrical spectrum analyzer being outputted to a data analyzing and processing module;
Step 2. Calculating an amplitude ak, k=1, 2, . . . , M, of each channel, wherein M being a number of all the channels, with a formula as follows:
ak=|∫−∞+∞Ek(ƒ)dƒ|2 (11)
wherein Ek(ƒ) is an optical spectrum as measured by the spectrometer for the kth channel;
Calculating ũk (ƒ), wherein uk(t) being a Fourier transformation, uk(t) being a normalized waveform of the kth channel, with a formula as follows:
Step 3. Calculating a time delay τk with a formula as follows:
wherein Ck, k=1, 2, . . . , M are M spectrum peaks measured by the electrical spectrum analyzer, Pk are M peaks of a radio frequency spectrum on an interval [0, ƒs]:
wherein M is a number of the total channels, Ts is a sampling period, ƒs=1/Ts, and RPD is a responsivity of the photodetector.
A measurement compensation device for multi-channel mismatch of the ultra-high speed photonic sampler, comprising the 1×2 optical fiber coupler, the spectrometer, the photodetector, the electrical spectrum analyzer, the data analyzing and processing module, and a driving and feedback module.
An input port of the 1×2 optical fiber coupler is connected with an output port of a generating module of the to-be tested ultra-high speed time-wavelength interleaved optical pulse sequence and having variable optical delay lines and variable attenuators; the 1×2 optical fiber coupler splits the to-be tested ultra-high speed time-wavelength interleaved optical pulse sequence into 2 paths, with one path being connected with an input port of the spectrometer, the other path being successively connected with the photodetector and the electrical spectrum analyzer; an output port of the spectrometer and the electrical spectrum analyzer respectively is connected with an input port of the data analyzing and processing module; an output port of the data analyzing and processing module is connected with an input port of the driving and feedback module; an output port of the driving and feedback module is connected with the variable optical delay lines and the variable attenuators.
The generating module of the to-be tested ultra-high speed time-wavelength interleaved optical pulse sequence may adopt an active mode-locked fiber laser or a passive mode-locked fiber laser as laser source. Subsequently, wavelength division and de-multiplexing technique is adopted for multi-channel and multi-wavelength splitting, and time and amplitude adjustment is realized based on time delay and optical amplitude.
The spectrometer is employed for measuring the optical spectrum of the to-be tested ultra-high speed time-wavelength interleaved optical pulse sequence for the various channels.
The photodetector is employed for converting of the ultra-high speed time-wavelength interleaved optical pulse sequence to a radio frequency signal, the radio frequency power spectrum thereof being measured by means of the electrical spectrum analyzer.
The data analyzing and processing module is employed for analyzing and processing of the measured data by the spectrometer and the electrical spectrum analyzer, and comprises but is not limited to an analog signal processing circuit, digital, a digital signal processor, and computer software.
The driving and feedback module is employed for adjustment of the optical signal amplitude and time delay in accordance with the mismatch information, and comprises but is not limited to a mechanical structure and an electronic circuit.
In comparison with the prior art, the present invention is advantageous in that:
1. By means of frequency-domain measurement and numerical analysis of the ultra-high speed time-wavelength interleaved optical pulse sequence, bottleneck of sampling inadequacy is overcome in the time-domain measurement, and channel mismatch information is obtained from measurement results of the frequency-domain measurement.
2. The present invention is simple and easy to manipulate, as the mismatch information obtained may act as a basis for compensation and correction of channel mismatch, and the result thereof is more accurate than that of the time-domain direct observation.
In combination with the figures provided hereunder, the present invention provides an embodiment hereunder, which is implemented based on the technical solution of the present invention and is provided with detailed means and procedure, but which is not meant to limit the scope of protection of the present invention.
An embodiment of the present invention is shown in
wherein Ek(ƒ), k=1, 2, 3, 4 being an optical spectrum as measured by the spectrometer for the kth channel.
The data analyzing and processing module 5, in accordance with the expression (9) and the peaks Ck, k=1, 2, 3, 4 of the radio frequency power spectrum data 4-3, obtains the following equations:
By substituting the expression (15) into the expression (16) for numerical solution, the amplitude ak and the time delay error τk, k=1, 2, 3, 4, are obtained; that is, time delay and amplitude mismatch information 10 of each channel is obtained. The data analyzing and processing module 5 inputs the obtained time delay and amplitude mismatch information 10 into the driving and feedback module 11, and the driving and feedback module 11 outputs a corresponding adjustment signal in accordance with the comparative value of the time delay and amplitude of each channel to drive the adjustment of the variable time delay line 1-3 and the variable attenuator 1-4, by increasing a relatively small time delay and amplitude value, while decreasing a relatively big time delay and amplitude value, to arrive at balance of time delay and amplitude among all the channels, thus achieving compensation of channel mismatch.
In the above process, optical spectrum and radio frequency spectrum of the time-wavelength interleaved optical pulse sequence of 40 GHz are measured for the 4 channels, channel mismatch information among the channels is obtained by means of numerical analysis, and the effectiveness of the method is validated by comparing the experiment result with that of the simulation based on mismatch information. Furthermore, on the basis of the mismatch information, mismatch may be compensated and corrected by means of further adjusting the variable optical delay line 1-3 and the variable attenuator 1-4. The present invention is based on frequency-domain measurement of the pulse, overcomes bottleneck of inadequate sampling in time-domain measurement, may acquire channel mismatch information from the frequency-domain measurement, and has characteristics of simplicity and ease of manipulation. The present invention is widely applicable in measurement, compensation and correction of channel mismatch in a generating system of an ultra-high speed time-wavelength interleaved pulse sequence.
Number | Date | Country | Kind |
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2014 1 0567490 | Oct 2014 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2014/089903 | 10/30/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2016/061838 | 4/28/2016 | WO | A |
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5909659 | Fujita | Jun 1999 | A |
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Number | Date | Country |
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101701852 | May 2010 | CN |
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Entry |
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Clark, T. R., et al., “Performance of a time-wavelength interleaved photonic sampler for analog-digital conversion” J. Photonics Technology Letters, IEEE, 1999, 11(9): 1168-1170. |
Number | Date | Country | |
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20180024009 A1 | Jan 2018 | US |