We demonstrate improved performance of parametric amplifier cascaded with Raman amplifier for gain of 54.79 dB. We report amplification of L-band using 100 × 10 Gbps Dense Wavelength Division Multiplexed (DWDM) system with 25 GHz channel spacing. The gain achieved is the highest reported so far with gain flatness of 3.38 dB without using any gain flattening technique. Hybrid modulated parametric pump is used for suppressing four-wave mixing (FWM) around pump region, resulting in improvement of gain flatness by 2.42 dB. The peak to peak variation of gain is achieved less than 1.6 dB. DWDM system with 16-channel, 25 GHz spaced system has been analyzed thoroughly with hybrid modulated parametric pump amplified Raman-FOPA amplifier for gain flatness and improved performance in terms of BER and Q-factor.
1. Introduction
Fiber optical parametric amplifiers (FOPAs) are promising amplifiers for Wavelength Division Multiplexed (WDM) systems [1, 2] due to their capabilities to provide high gain and low-noise, broadband amplification [1, 3]. The first demonstration of optical parametric amplification was reported by Stolen in low-loss optical fibers [4]. With advent of highly nonlinear fibers (HNLFs) [5], FOPAs gained considerable attention in long distance communication systems. Gain as high as 49 dB is demonstrated [6] using FOPAs whilst wavelength tuning flexibility of FOPAs helped in achieving gain over bandwidth above 200 nm [7]. Marhic et al. demonstrated on-off gain of 65 dB over bandwidth of more than 400 nm [8] using high power parametric pumps. Use of Photonic Crystal Fibers (PCFs), with nonlinearity coefficient (γ) > 100, added to wide gain capabilities of FOPAs. Parametric amplification using PCFs has been demonstrated to obtain continuous-wave bandwidth of more than 20 THz [9]. Peak gain of 58 dB over wide gain bandwidth from 999 to 1139 nm [10] has been achieved using PCF based FOPAs. Feasibility of long haul, broadband communication using FOPAs has been demonstrated in multichannel DWDM systems too [11, 12]. An average gain of 22 dB using dual pump FOPA [11] has been reported by Chavez Boggio et al. for 10 × 64 Gbps system. Jazayerifar et al. [12] analytically proved the feasibility of long haul DWDM transmission up to 750 km systems using single pump FOPA.
Another class of fiber amplifiers capable of providing polarization-independent gain across a wide bandwidth is Raman amplifiers (RA). The gain of Raman amplifiers can be tailored to meet bandwidth requirements by choosing optimum number of pump lasers and their wavelengths appropriately. This flexibility makes them useful for entire communication bandwidth. Though Raman amplifiers provide distributed gain but noise due to pump-pump interactions, double Rayleigh backscattering [13] and amplified spontaneous noise (ASE) degrade the signal quality. Additionally, Double Raman Scattering (DRS) and low Raman gain coefficient limit the gain at every stage [14] of Raman amplification.
Recently, Raman-FOPA (RA-FOPA) hybrid amplifiers have attracted considerable attention. The need for wideband, flat gain amplifier in WDM systems has motivated research interests towards RA-FOPA hybrid. The conventional RA-FOPA hybrid amplifiers use Raman assisted parametric amplification wherein forward travelling parametric pump within an HNLF is augmented by a backward travelling Raman pump, usually in the same fiber [15]. This results in gain higher than sum of the individual gain contributions in certain regions of the spectrum [15, 16]. In RA-FOPAs, long HNLF length is required to maximize the Raman gain. But at the same time, long HNLF lengths result in increased four-wave mixing cross talk products [17]. Though gain enhancement is achieved, in conventional RA-FOPAs, most energy from the Raman amplifier is trapped in the parametric pump at the output end of the amplifier. Wang and Wai [18] proposed a hybrid fiber Raman/parametric amplifier (HFRPA) constructed by cascading a FOPA after the RA-FOPA. Peak small signal gain of 70 dB is achieved using 1 km HNLF with 1.5 W and 0.2 W Raman and parametric pump powers, respectively, for 8-channel WDM system. A net gain enhancement of 34 dB has been achieved over conventional RA-FOPA for the same parametric pump powers using the proposed HFRPA. Ummy et al. [19] demonstrated an extended flat gain of 15 dB with gain ripple of 5 dB, using combined Raman and parametric interaction in HNLF. Peiris et al. [20] demonstrated hybrid Raman-Optical Parametric Amplifier (HROPA) in tandem configuration for extended bandwidth, with gain more than 20 dB and extended gain bandwidth of 170 nm. The gain ripple achieved is less than 4 dB. In tandem configuration, transmitted frequencies are divided into two subbands and a common, single pump FOPA is used for amplification of each. Cross talk generated due to idlers is controlled through a multiplexer filter transfer function. In [21], improved performance for WDM system comprising of ten, 100 GHz spaced DFB lasers has been achieved using RA-FOPA with net gain of 20 dB and gain ripple of 1.9 dB. Different optical amplifiers and their hybrids have been investigated over the time, to exploit the available optical communication bands, namely, S, C, and L. Though C/L-bands are dominated by EDFAs and their hybrids [22, 23], Raman amplifiers [24] as well as FOPAs [3, 25] can be tuned across any band. Kaur et al. [26] demonstrated flat gain of 24.3 dB over bandwidth of 220 nm using RA and multisection FOPA cascade. Akasaka et al. [27] demonstrated S-band amplification and wavelength conversion using RA-FOPA. Freitas et al. [28] demonstrated 10 dB gain enhancement in S-band and S/C-band wavelength conversion by simultaneous Raman as well as parametric amplification. We have previously demonstrated gain of more than 14 dB in L-band with ripple of less than 1.4 dB using RA-FOPA cascade with a gain flattening filter [29].
In this paper, we present successful analysis of a Raman-FOPA cascade hybrid amplifier for achieving flat gain in L-band, DWDM system without any gain flattening/compensating technique. The RA-FOPA cascade has been chosen over RA assisted FOPA to fully exploit the flexibilities to tune Raman and FOPA pumps such that gain is provided in separate regions of bandwidth. To achieve flat gain, we propose using FWM suppression at parametric pumps instead of applying external modulators at each transmitter. Use of MZM-PM hybrid modulator for parametric pump to achieve FWM suppression has been proposed.
2. Experimental Setup
Experimental setup consists of 100 DWDM channels spaced 25 GHz apart covering L-band frequencies from 187 THz to 189.475 THz as shown in Figure 1.
Experimental setup for Raman-FOPA with hybrid modulator for FWM suppression. PLA: pump laser array, PM: phase modulator, MZM: Mach Zender modulator, CW: continuous-wave laser, and PG: pulse generator.
The proposed system uses Raman-FOPA cascade as inline amplifier after traversing 50 km Single Mode Fiber (SMF). The dispersion of SMF is compensated by 10 km fiber used for Raman amplification with its dispersion (D) = −90 ps/km/nm. Raman amplified signal is then launched into short length HNLF of 0.2 km for parametric amplification. The CW parametric pump used is hybrid modulated using MZM-PM modulated RZ signal.
Single HNLF fiber section of length “L” results in gain G given by(1)G=1+γPgsinhgL2,where g=γP2-K/22 for single pump FOPA, where K=Δβ+2γP and(2)Δβ=2∑m=1∞β2 m2 m!Ω2 m-ωp2 m,Ω=ωs-ωp.From theory of Raman scattering in optical fibers, Raman interactions are expressed by [30] (3)δ=-3ω18ncAeffχ3″Ω,where n is the refractive index of the core, Ω is the frequency deviation from pump frequency, and χ3″Ω is the imaginary part of the third-order susceptibility resulting in set of equations expressed as(4a)∂A3∂z=2qA3+qA4∗e-iKz,(4b)∂A4∗∂z=-2qA4∗-qA3eiKzfor signal and idler, respectively.
Here, q=iγ+δP0 affects the four-wave mixing interaction of signal waves causing significant gain variation due to phase modulation originating from pump interactions [31]. Gao et al. [32] analyzed the phase mismatch conditions for parametric gain and derived the dependence of parametric gain on the real part of the complex Raman susceptibility. Use of tunable NRZ signals is suggested for reduced susceptibility of gain saturation in Raman-FOPA hybrid [33]. The real part of Raman susceptibility strongly affects peak parametric gain in case of single pump FOPA [34] in dispersion shifted fibers. In case of broadband amplification, Raman gain can cause significant spectral distortions [35] in RA-FOPA hybrid. In our analysis, we assume gain variations due to Raman susceptibility relatively small in comparison to nonlinear parametric gain as HNLF with high “γ.”
To optimize use of pumps in RA-FOPA cascade, it has been considered that, for bandwidths of order of 200 nm, the FOPA gain significantly overlaps with the pump-induced Raman gain which peaks at about 110 nm from the pump on the longer wavelength region of spectrum [36]. To keep this to a minimum, we choose Raman pumps from 1485 nm to 1513 nm with varying pump powers (200–350 mW) such that gain is more at lower frequency end from 187 THz to 188.725 THz. Figure 2 shows the power and wavelength of Raman pumps. Pump wavelengths have been carefully optimized to achieve flat gain. For band of frequencies higher than 188.725 THz, parametric amplification is used with pump tuned at 1583.56 nm. So the pump difference of at least 70 nm is maintained between Raman pumps and parametric pump to keep pump-pump FWM cross talk to a minimum. Moreover, peak gain regions of both Raman and FOPA fall at different band of frequencies in the output spectrum. Raman pump is tuned to provide gain in lower frequency region while parametric amplification provides the maximum gain at higher end of frequencies.
Spectral allocation of Raman pumps.
The proposed schematic is governed by(5)Gtotal=GRaman∗GFOPA,where GRaman and GFOPA are the gain of parametric sections. Raman gain in dB is 10·log10expgR·P·Leff/Aeff-αL.
The parameters used for Raman fiber serving as DCF and HNLF used for parametric amplifier are listed in Table 1.
Values of parameters used for HNLF parametric amplifier and DCF in Raman amplifier.
Parameter
Value
DCF length
10 km
Dispersion (DCF)
−90 ps/km/nm
DCF attenuation
0.5 dB/km
Effective area
30 µm2
HNLF length
0.2 km
HNLF effective area
11 µm2
Dispersion (HNLF )
2 ps/km/nm
Nonlinear coefficient (γ)
11.45
HNLF attenuation
0.8 dB/km
3. Results and Discussions
In this work, we propose achieving flat gain for Terabits capacity system implemented as 100 × 10 channels with 25 GHz spaced RZ signals. RA-FOPA cascade is used as inline amplifier and dispersion compensation has been combined in Raman amplifying fiber medium itself. Use of single pump parametric amplifiers for broadband amplification has been reported previously [12, 19, 26]. But with increased number of channels in DWDM systems, high pump powers of the order of 200 mW are required to overcome the cross talk due to parametric amplification [12]. High pump power coupled with narrow channel spacing poses serious challenge to achievement of flat gain over the entire band. Due to relatively high pump power, the frequencies in immediate vicinity of pump frequency tend to have much higher gain than frequencies at the extremes of the band. This gives high ripple in the amplifier gain. To make the gain flat, we propose modulating the parametric pump using MZM-PM hybrid modulation. The resultant modulated pump pulse is pulse spread across band of frequencies with its center at the pump frequency.
Use of hybrid modulated parametric pump to suppress FWM results in flat gain when compared to similar system employing unmodulated CW parametric pump. Results of the implemented system using MZM-PM hybrid modulated pump indicate a nearly flat gain as shown in Figure 3. The fiber serving as medium for Raman amplification has been used for dispersion compensation [14]. Results show a peak gain of 57.24 dB for CW parametric pump, whereas using MZM-PM hybrid modulated parametric pump peak gain of 54.79 dB is achieved. Though peak gain reduces using hybrid modulated pump but gain flatness improves, when hybrid modulated parametric pump is used, gain ripple is reduced to 3.38 dB from 5.8 dB in case of unmodulated CW parametric pumped system. Also, higher average gain of 53.6 dB is achieved for hybrid modulated parametric pump against average gain of 53.27 dB with CW parametric pump (excluding the peak gain at extreme right shown by dotted curve in Figure 3).
Gain comparison for 100-channel RA-FOPA at 10 Gbps with hybrid modulated parametric pump (solid curve) versus unmodulated CW parametric pump.
Figure 4 shows gain comparison using proposed RA-FOPA amplifier for L-band with unmodulated CW parametric pump versus hybrid modulated parametric pump at 40 Gbps. When hybrid modulation is applied to parametric pump, the maximum gain is 26.88 dB while minimum gain is 19.23 dB giving ripple of 7.65 dB while in the absence of any modulation parametric pump results in maximum gain of 28.12 dB while minimum gain is 18.22 dB resulting in ripple of 9.91 dB. So we achieve flatness improvement of 2.26 dB. With increase in data rate, net gain has decreased and the gain ripple has increased. But use of hybrid modulated parametric pump definitely gives better performance over conventional parametric pumped FOPA even at high data rates.
Gain comparison for RA-FOPA at 40 Gbps with hybrid modulated parametric pump (solid) and no modulation CW pump (dotted).
To analyze FWM suppression in proposed system, we simulate a 16-channel system at 25 GHz channel spacing extending from 187.1 THz to 187.475. The parametric pump with 10 mW power is fixed at frequency of 187.323 THz while Raman pump is located at 1501.6 nm.
It can be well observed from gain results in Figure 5 that when we use hybrid modulated parametric pump the peak gain is decreased and low gain regions slightly raised which helps reduce the gain extremes. Due to use of relatively high power pump, the FWM effect results in sharp gain at channel frequencies close to pump at 187.32 THz while gain diminishes towards the high and low extremes of the bandwidth. But when we modulate the parametric pump using MZM-PM, resulting pulse is not as sharp but is a pulse spread over range of frequencies around the pump frequency with power in side bands diminishing slowly. Additionally, due to the phase modulation, the peak power is further decreased as phase difference increases, resulting in lower FWM efficiency. This lowering of peak power in vicinity of parametric pump results in lesser gain ripple between highest and lowest gain achieved across the entire bandwidth.
Gain of 16-channel system with and without hybrid modulator.
The quality of received signal can be well observed from eye diagrams in Figures 6(a) and 6(b). Figure 6(a) shows eye opening when hybrid modulated parametric pump is used. The minimum eye opening is 1.3 × 10−4 while as seen in Figure 6(b) for system with CW parametric pump eye opening is 1.1 × 10−4.
(a) BER pattern and eye diagram for hybrid modulated parametric pump based system. (b) BER pattern and eye diagram for unmodulated CW parametric pump.
BER analysis in Figure 7 shows a significant improvement with use of hybrid modulator for parametric pump. Figure 7 shows improvement in BER to order of 10−19 from 10−12 at −2 dBm of transmitter input power, which is minimum BER achieved in both cases, respectively.
BER of hybrid modulated system versus unmodulated parametric pump.
Results of the Q-factor variation in Figure 8 confirm improved performance using the proposed hybrid. Use of hybrid modulator improves quality factor from 7.2 to nearly 9 at total input power of −2 dBm.
Q-factor of hybrid modulated system versus unmodulated parametric pump.
Another significant parameter in determining performance of an optical communication system is dispersion. For the proposed system, dispersion in the transmitted signals has been analyzed briefly. The dispersion analysis result in Figure 9 shows that increase in dispersion of the transmitted signals when employing hybrid modulated parametric pump is much less than the system which uses unmodulated CW parametric pump.
Dispersion variation of hybrid modulated parametric pump versus unmodulated parametric pump.
The solid curve in Figure 9 shows lesser dispersion increase with use of proposed hybrid modulator.
So, results confirm improved performance of DWDM system with RA-FOPA cascade hybrid amplifier when using hybrid modulated parametric pump.
4. Conclusion
We have proposed a novel idea to modulated parametric pump using MZM-PM hybrid modulation to achieve flat gain for RA-FOPA cascaded amplifier. The gain achieved has been the highest reported so far using RA-FOPA hybrid used as inline amplifier for 100-channel L-band DWDM system. Never before for RA-FOPA hybrid dispersion compensation is reportedly combined with Raman amplifier fiber medium making it more economical and compact. Achieved gain of 54.79 dB, with gain ripple of 3.38 dB, is the best reported result. No gain flattening or compensating technique has been employed. Previous best gain in L-band for 100-channel, 25 GHz spaced DWDM system at 10 Gbps has been reported as >24 dB using Er-Yb codoped waveguide amplifier (EYDWA) and a semiconductor optical amplifier (SOA) hybrid [36] as booster amplifier.
Our work is motivated from hybrid modulation techniques used to suppress FWM cross talk. Recently, FWM suppression techniques for WDM systems have been proposed [37, 38]. But as a general approach, hybrid modulators have only been applied to transmitters for FWM suppression [37]. This significantly adds to size and cost of system. So, we propose using hybrid modulator for CW parametric pump to suppress FWM generated idlers and hence achieving improved gain flatness in RA-FOPA hybrid. This has never been done previously. Results achieved are the best reported to date for L-band DWDM amplification.
Future scope of proposed RA-FOPA can be viewed multidimensionally. FWM has been the most detrimental effect for narrow spaced DWDM systems [34]. We have exploited FWM for amplification in DWDM systems in combination with partial suppression to facilitate flat gain. Our proposed system can be explored to achieve significant results with polarization based FWM suppression techniques for further gain enhancement. Additionally, novel techniques for parametric pump modulation in other existing hybrid parametric amplifier configurations [39] may help improvise the gain in WDM systems.
Another characteristic of FOPA is dependence of gain on fiber properties. Advent of novel fiber [40] design with reduced sensitivity of fiber dispersion to diameter fluctuations would help achieve more dependable results for broadband amplification using parametric amplifiers.
In conclusion, thorough investigation has been done in direction to establish use of RA-FOPA hybrid amplifiers across all bands of communication [3, 26–29], namely, S, C, and L with good gain and wide gain bandwidth. Exploring the possibilities of using proposed RA-FOPA in combination with existing/novel techniques for gain enhancement may help identify a true broadband amplifier capable of providing flat gain across entire communication band for evolving WDM systems.
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
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