Abstract
The Pockels effect in periodically poled lithium niobate made it possible to switch optical signals between two orthogonal optical linear polarizations of the vertical and horizontal polarization states. Based on this effect, we demonstrated polarization-based binary optical logic gates: AND, and OR gates. By combining these basic gates with other polarization-based optical logic gates such as XOR gate accomplished in our previous researches, half-adder and half-subtracter of digital signals with a high extinction ratio of about 10dB have been demonstrated in our experiment, which made it possible to run more complex logical calculus.
© 2015 Optical Society of America
1. Introduction
The Moore's law tells us that the calculative ability of computers doubled every 18 months in the past. However, it is believed that in the near future the traditional electrical computer will meet the bottleneck, because of its physical mechanism. In order to overcome the bottleneck of current information systems, ultrafast high-speed, large-capacity, all-optical networks are really necessary [1, 2]. Therefore, all-optical logic gates become more and more important as crucial functions for all-optical signal processing. In the past decades, optical logic using different schemes, including dual semiconductor optical amplifier (SOA) [3], Mach-Zehnder interferometer(MZI) [4, 5], semiconductor laser amplifier (SLA) loop mirror [6], ultrafast nonlinear interferometer (UNI) [7], four-wave mixing (FWM) in SOA [8], photonic solitons [9], cross phase modulation(XPM) in nonlinear devices [10], micro/nano plasmonic structures [11–13] and a triangular triple-core photonic crystal fiber [14]have been demonstrated one by one. In addition, all-optical logic gates based on different schemes in periodically poled lithium niobate (PPLN) [15, 16] have also been presented recently owing to its attractive property.
Most of optical logic gates demonstrated before are encoded based on the intensity of optical waves. However, the intensity is always depleted rapidly along with the computation. It is known that the polarization information of light can be maintained as long as the intensity is above zero. What is more, with the depletion, the polarization information can be distinguished more easily from the opposite information than the intensity information. As a result, to avoid this high intensity depletion and accomplish some more complex signal processing, optical polarization-based binary logic gates have been proposed and demonstrated [17]. In this scheme, two orthogonal states of polarization were used to represent logic one and logic zero.
In our previous work, the capability to change polarization state of optical wave with high precision and rate in PPLN has been researched and verified [18]. By utilizing the linear polarization-state generator in PPLN, polarization-based optical logic controlled-NOT, XOR, and XNOR gates have been demonstrated in our previous work [16]. In this letter, we study the polarization-based optical logic controlled-NOT, AND and OR gates, which are accomplished by employing polarization beam splitter (PBS) and optimizing the external electric field on 5 mol% MgO-doped periodically poled lithium niobate (MgO:PPLN). Additionally, we generate digital signals by using a polarization rotator, and a series of output digital signals have been demonstrated in our experiment. Finally, based on these basic logic gates, digital optical half-adder and half-subtracter are also designed and demonstrated.
2. Pockels effect
The electro-optic (EO) effect in PPLN has already been theoretically and experimentally studied [16, 18]. With a transverse external electric field applied on PPLN, the optical axis of positive domains can be rotate by angles of + θ, while the negative domains by angles of –θ with respect to the plane of polarization of the input light:
Ey is the field intensity, γ51 is the electro-optic coefficient, no and ne represent the refractive indices of the ordinary and extraordinary waves, respectively. The difference of phase velocities between the ordinary wave (OW) and the extraordinary wave (EW) makes each domain of PPLN serving as a half-wave plate at a certain wavelength. After passing through the stack of half-wave plates, the optical plane of polarization will rotate continually and finally create a total rotation angle of 2Nθ, where N is the number of periods of PPLN. As a result, polarization of light can be totally rotated by 90° in the presence of the proper external applied electric field after propagating through PPLN. In our experiment, we used one polarizer to generate a linear polarization state of the input light, and another polarizer as an analyzer to check the output polarization state.
In order to switch these two orthogonal linear polarization states of input signals, we set the polarizer along the Y direction and the analyzer along the Z direction, and then the OW can be switched to the EW after applying the external filed. While the polarizer is set along the Z direction and the analyzer along the Y direction, the EW can be switched to the OW contrarily.
To evaluate this switch, we measured the transmission T, which denotes the depletion of input optical signal after EO modulation. The quantities T∥ and T⊥ corresponding to the horizontal and vertical polarization state of input signal are defined as, and , respectively. Iin,// and Iin,⊥ are the intensities of horizontal and vertical polarization state of input optical signal. Iout,// and Iout,⊥ are the intensities of horizontal and vertical polarization state of output optical signal respectively.
In our experiment, The horizontal state could be switched to vertical one at the applied electric field of 3.15 kV/cm where the transmission T// reaches maximum, while the vertical state could be completely switch to the horizontal state, where the applied electric field is about 3.37 kV/cm.
We set a polarizer to generate a state of polarization and the analyzer to check the transmission of the output at the end of the MgO:PPLN crystal. Using this kind of experimental setup, the overall transmission for this optical rotation was measured, and the results are shown in Table 1. Here we used PBS as polarizer and analyzer.
3. Polarization-based optical AND and OR gates
In our work, the experimental schematics of optical logic XOR, XNOR, AND and OR gates are shown in Figs. 1 (a) and 1(b). The corresponding poling grating period of MgO:PPLN was 19.9 µm. At a given experimental temperature of 23.5 °C, the device performed the switch between two orthogonal states of polarization at 1552.9 nm.
Considering the results obtained in Table 1 and the definitions of different logic gates shown in Table 2, XOR, XNOR, AND and OR logic gates can be achieved respectively. By defining the optical signal with vertical and horizontal polarization state as logic 0 and logic 1 and considering the applied electric field of 0 and 3.26 kV/cm as logic 1 and logic 0 respectively, we can obtain all the basic logic gates shown in Table 3, corresponding to the results in Table 1. It is convenient to switch the logic function between AND (XNOR) gates and OR (XOR) gates by changing the definitions of optical signals in Table 2.
4. Optical digital half-adder and half-subtracter
To achieve the polarization-based optical half-adder and half-subtracter, firstly we need to have the basic logic gates of XOR and AND which have been showned in Fig. 1(a), 1(b) and Table 2 above. Figure 2 shows our experimental setup for achieving the half-adder and half-subtracter.
A continuous wave(CW) with a wavelength of 1552.9 nm was launched from a tunable laser, and amplified to tens of mw through an EDFA. Consequently the CW was modulated as signal 1 by employing an optical rotation modulator (Photline: PS-LN-10) driven by a signal generator with 40 MHZ. The signal 1 passed through a collimator and launched into the PPLN samples with different linear polarizations. An electric field Ey along to Y direction provided by a voltage source was defined as the signal 2. By combining output 2 and 3 in Fig. 2, we constructed an AND logic gate which was shown in Fig. 2(b). Similarly a XOR logic gate could be obtained from output 1, which has been shown in Fig. 2(a). Through combining the above XOR and AND gates, a half-adder could be achieved as shown in Fig. 2. If we want to demonstrate a half-substracter, we just need to detect the output 3 as the BORROW and combine the XOR gate from the output 1. Table 4 shows us the truth tables of SUM, DIFF, CARRY and BORROW for half-adder and half-subtracter.
In our experiment, signal 1 is a bunch of digital optical signals which is polarization modulated, while signal 2 is an alterable external electric field. Then we have a series of digital optical output signals as shown in Fig. 3, where we get a high extinction ratio of about 10dB. For signal 1, we define signal with the horizontal and vertical polarizations as logic 0 and 1 respectively, and for signal 2, we have the logic 0 and 1 when the external electric field are 0 and E.
And as shown in Fig. 3, we can achieve the experimental results of column (a) and (b) when the external electric fields (signal 2) are on and off, in which we demonstrated SUM/DIFF(Output 1) and CARRY(combining Output 2 and Output 3) by using the similar logic definitions as signal 1. Consequently the half-adder has been realized by combining SUM and CARRY. While we can achieve the half-subtracter by employing DIFF and BORROW, in which we have to change the definition of BORROW (Output 3) which is contrary to the definition of signal 1.
Moreover, based on the experimental demonstration in this paper, a potential on-chip quantum computer will be expected by employing different structures with waveguides as shown in Fig. 4 when combining its nonlinearity and electro-optic effects. Thus recently it is necessary to develop an integrated on-chip system in lithium niobate, which attracts more research interesting in fabricating on-chip devices due to its distinguished nonlinear optical [19–21], electro-optical [16, 18] and mechanical properties [22].
5. Conclusion
By employing Pockels effect in MgO:PPLN, we experimentally demonstrate polarization-based binary optical logic gates using AND and OR gates and the XOR gate completed in our previous work. When choosing the proper electric field, these logic gates can present excellent performance, in which the optical signals are encoded in polarizations, and might not suffer from the possible intensity attenuations for cascading operations. In our future work, the electric field of high intense optical waves will take place of the electric field provided by the applied electrical signal directly. Then a real all-optical logic calculation will be expected. Moreover, by changing these functional structures in PPLN, more complex computing such as full-adder and full-subtracter can also be achieved, which will offer a new solution for the on-chip all-optical signal processing in lithium niobate.
Acknowledgments
The research was supported by the National Natural Science Foundation of China under Grand No.11174204, 61125503, 61235009, the Foundation for Development of Science and Technology of Shanghai under Grant No.13JC1408300.
References and links
1. D. Cotter, R. J. Manning, K. J. Blow, A. D. Ellis, A. E. Kelly, D. Nesset, I. D. Phillips, A. J. Poustie, and D. C. Rogers, “Nonlinear optics for high-speed digital information processing,” Science 286(5444), 1523–1528 (1999). [CrossRef] [PubMed]
2. M. Saruwatari, “All-optical signal processing for terabit/second optical transmission,” IEEE J. Sel. Top. Quantum Electron. 6(6), 1363–1374 (2000). [CrossRef]
3. L. Lei, J. Dong, Y. Yu, S. Tan, and X. Zhang, “All-optical canonical logic units-based programmable logic array (CLUs-PLA) using semiconductor optical amplifiers,” J. Lightwave Technol. 30(22), 3532–3539 (2012). [CrossRef]
4. J. H. Kim, Y. M. Jhon, Y. T. Byun, S. Lee, D. H. Woo, and S. H. Kim, “All-optical XOR gate using semiconductor optical amplifiers without additional input beam,” IEEE Photon. Technol. Lett. 14(10), 1436–1438 (2002). [CrossRef]
5. J.-Y. Kim, J.-M. Kang, T.-Y. Kim, and S.-K. Han, “All-optical multiple logic gates with XOR, NOR, OR, and NAND functions using parallel SOA-MZI structures: theory and experiment,” J. Lightwave Technol. 24(9), 3392–3399 (2006). [CrossRef]
6. T. Houbavlis, K. Zoiros, A. Hatziefremidis, H. Avramopoulos, L. Occhi, G. Guekos, S. Hansmann, H. Burkhard, and R. Dall’Ara, “10 Gbit/s all-optical Boolean XOR with SOA fibre Sagnac gate,” Electron. Lett. 35(19), 1650–1652 (1999). [CrossRef]
7. C. Bintjas, M. Kalyvas, G. Theophilopoulos, T. Stathopoulos, H. Avramopoulos, L. Occhi, L. Schares, G. Guekos, S. Hansmann, and R. Dall’Ara, “20 Gb/s all-optical XOR with UNI gate,” IEEE Photon. Technol. Lett. 12(7), 834–836 (2000). [CrossRef]
8. L. Lei, J. Dong, B. Zou, Z. Wu, W. Dong, and X. Zhang, “Expanded all-optical programmable logic array based on multi-input/output canonical logic units,” Opt. Express 22(8), 9959–9970 (2014). [CrossRef] [PubMed]
9. M. Xu, Y. Li, T. Zhang, J. Luo, J. Ji, and S. Yang, “The analysis of all-optical logic gates based with tunable femtosecond soliton self-frequency shift,” Opt. Express 22(7), 8349–8366 (2014). [CrossRef] [PubMed]
10. Z. Li, Y. Liu, S. Zhang, H. Ju, H. De Waardt, G. Khoe, H. Dorren, and D. Lenstra, “All-optical logic gates using semiconductor optical amplifier assisted by optical filter,” Electron. Lett. 41(25), 1397–1399 (2005). [CrossRef]
11. C. Lu, X. Hu, S. Yue, Y. Fu, H. Yang, and Q. Gong, “Ferroelectric hybrid plasmonic waveguide for all-optical logic gate applications,” Plasmonics 8(2), 749–754 (2013). [CrossRef]
12. Y. Bian and Q. Gong, “Compact all-optical interferometric logic gates based on one-dimensional metal–insulator–metal structures,” Opt. Commun. 313, 27–35 (2014). [CrossRef]
13. H. Wei, Z. Wang, X. Tian, M. Käll, and H. Xu, “Cascaded logic gates in nanophotonic plasmon networks,” Nat. Commun. 2, 387 (2011). [CrossRef] [PubMed]
14. A. Coelho, M. Costa, A. Ferreira, M. Da Silva, M. Lyra, and A. Sombra, “Realization of all-optical logic gates in a triangular triple-core photonic crystal fiber,” Lightwave Technology, Journalism 31, 731–739 (2013).
15. J. Wang, J. Sun, Q. Sun, D. Wang, X. Zhang, D. Huang, and M. M. Fejer, “PPLN-based flexible optical logic AND gate,” IEEE Photon. Technol. Lett. 20(3), 211–213 (2008). [CrossRef]
16. Y. Zhang, Y. Chen, and X. Chen, “Polarization-based all-optical logic controlled-NOT, XOR, and XNOR gates employing electro-optic effect in periodically poled lithium niobate,” Appl. Phys. Lett. 99(16), 161117 (2011). [CrossRef]
17. Y. A. Zaghloul and A. R. Zaghloul, “Complete all-optical processing polarization-based binary logic gates and optical processors,” Opt. Express 14(21), 9879–9895 (2006). [CrossRef] [PubMed]
18. K. Liu, J. Shi, and X. Chen, “Linear polarization-state generator with high precision in periodically poled lithium niobate,” Appl. Phys. Lett. 94(10), 101106 (2009). [CrossRef]
19. J. Zhang, Y. Chen, F. Lu, and X. Chen, “Flexible wavelength conversion via cascaded second order nonlinearity using broadband SHG in MgO-doped PPLN,” Opt. Express 16(10), 6957–6962 (2008). [CrossRef] [PubMed]
20. J. U. Fürst, D. V. Strekalov, D. Elser, M. Lassen, U. L. Andersen, C. Marquardt, and G. Leuchs, “Naturally phase-matched second-harmonic generation in a whispering-gallery-mode resonator,” Phys. Rev. Lett. 104(15), 153901 (2010). [CrossRef] [PubMed]
21. J. Lin, Y. Xu, Z. Fang, J. Song, N. Wang, L. Qiao, W. Fang, and Y. Cheng, “Second harmonic generation in a high-Q lithium niobate microresonator fabricated by femtosecond laser micromachining,” arXiv preprint arXiv:1405.6473 (2014).
22. Q. Rolland, S. Dupont, J. Gazalet, and J.-C. Kastelik, “Acousto-optic couplings in two-dimensional Lithium Niobate phoXonic crystal,” in IOP Conference Series: Materials Science and Engineering, (IOP Publishing, 2014), 012006. [CrossRef]