The invention is directed to a high-linearity photonic link, and in particular to a photonic link having an improved even-order distortion response.
High-linearity photodiodes are actively researched in the field of microwave photonics, with applications in the academic, industrial and military sectors. A recent survey collects reported state-of-the-art results from the component level (V. J. Urick, J. F. Diehl, M. N. Draa, J. D. McKinney, and K. J. Williams, “Wideband analog photonic links: some performance limits and considerations for multi-octave limitations,” Proc. SPIE 8259, 1-14 (2012) (“Urick et al. 1”). The concentration of high-linearity photodiode work is largely in terms of single-octave third-order-limited intermodulation distortion as quantified by a third-order output intercept point (OIP3). One of the inherent advantages of photonic solutions is the wide bandwidth available in the optical domain, making analog optical links attractive for multi-octave applications. However, even-order distortion generated by photodiodes can be inhibiting in such implementations as described in Urick et al. Previous works, e.g. Urick et al. 1 and V. J. Urick, A. S. Hastings, J. D. McKinney, P. S. Devgan, K. J. Williams, C. Sunderman, J. F. Diehl, and K. Colladay, “Photodiode linearity requirements for radio-frequency photonics and demonstration of increased performance using photodiode arrays,” in 2008 IEEE International Meeting on Microwave Photonics Digest, pp. 86-89 (“Urick et al. 2”), have described the photodiode requirements in high-linearity photonic links for single- and multi-octave applications in terms of OIP3 and second-order output intercept point (OIP2), respectively. Oftentimes the present photodiode technology falls short of the system requirements, particularly in multi-octave applications. Architectural techniques have been devised to mitigate the component limitations. For example, photodiode arrays have been shown to achieve better linearity than the individual photodiodes are capable of alone. Two- and four-photodiode arrays have been demonstrated (see, respectively, A. Joshi, “Highly linear dual photodiodes for Ku-Band applications,” in 2009 IEEE Avionics Fiber Optics and Photonics Conference Digest, pp. 9-10, and Y. Fu, H. Pan, and J. C. Campbell, “Photodiodes with monolithically integrated Wilkinson power combiner,” IEEE J. Quantum Electron. 46, 541-545 (2010); and S. Itakura, K. Sakai, T. Nagatsuka, E. Ishimura, M. Nakaji, H. Otsuka, K. Mori, and Y. Hirano, “High-current backside-illuminated photodiode array module for optical analog links,” J. Lightwave Technol. 28, 965-971 (2010) and Y. Fu, H. Pan, Z. Li, and J. Campbell, “High linearity photodiode array with monolithically integrated Wilkinson power combiner,” in 2010 IEEE International Meeting on Microwave Photonics Digest, pp. 111-113). This simple but quite effective technique is based on dividing the input signal between numerous non-linear devices and then linearly combining their outputs. The “array gain” scales with the number of elements for both even- and odd-order distortion, assuming that each element exhibits the same nonlinearity. Balanced photodiode arrays have been demonstrated that improve the OIP3 by the array gain but suppress photodiode-generated even-order distortion through the balanced detection process (Urick et al. 2, and A. S. Hastings, V. J. Urick, C. Sunderman, J. F. Diehl, J. D. McKinney, D. A. Tulchinsky, P. S. Devgan, and K. J. Williams, “Suppression of even-order photodiode nonlinearities in multioctave photonic links,” J. Lightwave Technol. 26, 2557-2562 (2008). This technique is attractive for multi-octave applications but requires two phase-matched fibers for the transmission span when implemented with a Mach-Zehnder modulator (MZM).
According to the invention, a system for suppressing even-order distortion in a photonic link includes a laser for providing laser light to a first input of a Mach-Zehnder modulator (MZM), where the MZM has a second input for receiving an RF input signal, a third input for applying a DC bias voltage to the MZM, and an optical signal output. A dc-voltage-biased photodiode has an input, coupled to the MZM optical signal output, and a modulated RF signal output. The MZM DC bias voltage is set at a value to generate an even-order distortion amplitude substantially equal to an even-order distortion amplitude from the photodiode and 180 degrees out of phase so as to substantially cancel the photodiode even-order distortion.
The invention provides the cancellation of photodiode even-order distortion via predisortion linearization with a MZM biased slightly away from quadrature, employing a single fiber run and a single photodiode. The invention provides an improvement in carrier-to-intermodulation ratio (CIR) upwards of 40 dB.
A calculation demonstrating cancellation of photodiode even-order distortion with MZM-generated distortion is conducted assuming the architecture of the invention 100 shown in
Link with Ideal Photodiode
The response for an IMDD link employing a MZM is well-known (see B. H. Kolner and D. W. Dolfi, “Intermodulation distortion and compression in an integrated electrooptic modulator,” Appl. Opt. 26, 3676-3680 (1987)). Here, the terms relevant to the cancellation technique are highlighted. We assume an ideal push-pull MZM with the following transfer function:
where E1 and E2 are the fields corresponding to the two MZM outputs, φ is the phase shift induced by the applied voltage, and Ein is the field at the MZM input. The frequency-dependent MZM half-wave voltage is Vπ(Ω). The input field is written as Ein=κ√{square root over (2Po)}eiωt, where Po is the average optical power at angular frequency ω and κ is a constant such that Po=E*E/(2κ2). The input to the MZM comprises a DC bias voltage Vdc and a two-tone RF signal of the form V1 sin(Ω1t)+V2 sin(Ω2t), where Ω are the angular frequencies. With these input voltages the phase shift φ(t)=φdc+φ1 sin(Ω1t)+φ2 sin(Ω2t) results, where φdc=πVdc/Vπ and φ1,2=πV1,2/Vπ. Assuming an ideal photodiode with responsivity , the total photocurrent due to E1 can be calculated and separated into three components:
where Idc,q is the photocurrent at quadrature and J is a Bessel function of the first kind. The quadrature condition is given by φdc=(2k+1)π/2 where k is an integer. Equation (2a) is the average (DC) current, Eq. (2b) are the odd-order RF terms, and Eq. (2c) are the even-order RF terms. Thus, the total photocurrent for this output is I1(t)=Idc,mzm+Iodd,mzm+Ieven,mzm. The photocurrent associated with E2 is I2(t)=2Idc,q−I1(t). The treatment here will assume a small-signal two-tone test with equal amplitude tones, thus φ1=φ2=φ<<1. A small-signal approximation allows for the Bessel functions to be written as Jn(φ)≈φn/(2nn!). These conditions can be applied to Eq. (2) to yield the fundamental photocurrents
Ifund,mzm=φIdc,q sin(φdc)[ sin(Ω1t)+ sin(Ω2t)] (3)
Assuming all of the current is delivered to a load with resistance R, the average output power for both the fundamentals is Pfund,mzm=φ2Idc,q2 sin2(φdc)R/2. The work here concentrates on even-order distortion. The largest small-signal distortion in Eq. (2) is second-order intermodulation distortion (IMD2) at frequencies |f1±f2| given by the first two double summations in Eq. (2c) with n=p=0. The small-signal photocurrent for these two terms is
The average power associated with Eq. (4) is Pimd2,mzm=φ4Idc,q2 cos2(φdc)R/8. Finally, the OIP2 due to MZM-generated IMD2 is
As given by Eq. (5) and detailed previously in Urick et al. 1, small deviations from quadrature bias can significantly degrade the OIP2. In fact, the tolerance on MZM bias can be quite stringent to maintain third-order-limited performance in multi-octave links.
Photodiode Distortion
Numerous models have been developed to describe photodiode distortions in microwave photonics applications (see K. J. Williams and R. D. Esman, “Design considerations for high-current photodetectors,” J. Lightwave Technol. 17, 1443-1454 (1999), and Y. Fu, H. Pan, Z. Li, A. Beling, and J. C. Campbell, “Characterizing and modeling nonlinear intermodulation distortions in modified uni-traveling carrier photodiodes,” IEEE J. Quantum Electron. 47, 1312-1319 (2011)). Here, we assume that the fundamentals from the MZM drive the photodiode, which can be described by a Taylor series expansion. We apply the following definition for a Taylor series expansion
Ipd=a0+a1(Iin−Idc)+a2(Iin−Idc)2+a3(Iin−Idc)3+ . . . (6)
where Ipd is the output current of the photodiode with an injection current of Iin and an average current Idc. The Taylor coefficients are defined as usual
Now, if we assume that Iin=Ifund,mzm as given by Eq. (3), that is, the ideal IMDD link provides the injection current to a nonlinear photodiode described by Eq. (6), then
where I=φIdc,q sin(φdc) and the expansion has been carried out to terms of second order. The currents for the IMD2 terms in Eq. (8) are
Iimd2,pd=±a2φ2Idc,q2 sin2(φdc)cos [(Ω2∓Ω1)t] (9)
The OIP2 for the photodiode can be determined by the expression OIP2pd=Pfund,pd2/Pimd2,pd, where Pfund,pd=a12I2R/2 and Pimd2,pd=a22I4R/2 are the average powers for the fundamental and IMD2, respectively. Thus,
Combined Response
Our proposition is that the MZM biased can be adjusted to generate even-order distortion matching the amplitude of that arising from the photodiode. The forms of Eqs. (4) and (9) predict that two sources of distortion can be out of phase as well. The treatments of MZM- and photodiode-generated distortion above can be combined to derive the cancellation condition. The peak current at both IMD2 terms is obtained by addition of Eqs. (4) and (9):
where the “+” and “−” signs correspond to the terms at (Ω2−Ω1) and (Ω2+Ω1), respectively. Setting Eq. (11) to zero yields the cancellation condition as
The analysis above also predicts that second-harmonic distortion will cancel as well; expanding the Taylor series to higher order shows that all even-order distortion is suppressed with this technique. The parameters in Eq. (12) are readily determined. The bias phase and photocurrent at quadrature are easily measured. The small-signal gain of the link will allow for the magnitude of a1 to be calculated. With this information, a measurement of the photodiode OIP2 will give the magnitude for a2 by way of Eq. (10). Cancellation of the IMD2 is then predicted by Eq. (12) to be cyclic as a function of φdc.
The experimental investigation involves two apparatuses, a single-MZM link 100 (
The structure shown in
The same photodiode was used in a link such as shown in
A two-tone test was applied to the link with frequencies f1=0.9 GHz and f2=1.1 GHz, the results of which are shown in
To confirm the cancellation condition, equations were plotted with measured data as a function of φdc. As shown in
To demonstrate the utility at high frequencies and under conditions where the photodiode is uncompressed, a second device was measured. A u2t Photonics (Model: u2t S/N 46167) commercial device was measured as above biased at 3V with Idc,q=2.5 mA, at center frequency 35.5 GHz with 500 MHz separation. Shown in
A phase- or polarization-modulation link can be employed to cancel photodiode even-order distortion in much the same way as the IMDD link. A similar theoretical treatment can be applied to the phase- or polarization-modulation architecture. The phase-modulation link 300 is shown in
The polarization-modulation link architecture 400 is shown in
Obviously many modifications and variations of the present invention are possible in the light of the above teachings. It is therefore to be understood that the scope of the invention should be determined by referring to the following appended claims.
This application claims the benefit of U.S. Provisional Application 61/787,392 filed on Mar. 15, 2013 and incorporated herein by reference.
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