Open Access
25 June 2022 Review on all-optical logic gates: design techniques and classifications – heading toward high-speed optical integrated circuits
Erandathara Gokulan Anagha, Ramasamy Kandasamy Jeyachitra
Author Affiliations +
Abstract

All-optical logic gates (AO-LGs) are the key elements that play a pivotal role in the development of future all-optical networks and all-optical computing. A complete overview of the seven all-optical logic gates (i.e., AND, OR, NOT, XOR, XNOR, NAND, and NOR) based on their design techniques and applications are covered, including the latest technologies, such as topological photonics and artificial intelligence-based designs techniques. In addition, we have further categorized the AO-LGs as reconfigurable gates, simultaneous gates, reversible gates, modulation-based gates, and data rate-based gates. The techniques to implement these different classes of gates are reviewed and their limitations are discussed. We also discuss in brief the various simulation tools used to design and analyze the AO-LGs. Finally, the most feasible techniques for constructing optical integrated circuits based on the existing fabrication technologies and available resources are explored, and future prospects are outlined.

1.

Introduction

Currently, the increasing demands for higher bandwidths and ultrafast operating speed requirements imposed by the internet-based variety of applications have created the electronic bottle neck problem. These needs have overloaded the available bandwidths and reached the speed limits of electronic-based devices. This calls for a quick shift toward a newer technology that can meet the demands of high speed and abundant bandwidth to keep pace with the user demands. Compared with electrons, light or photons have several advantages. It has much greater speeds, can carry a huge amount of information, and can provide terahertz range of bandwidths. Further, the interactions between photons are not as strong as that of electrons and hence they reduce energy losses in addition to providing immunity from electromagnetic interferences and ground loops. Despite using optical fiber cables for communication systems, the conversions from optical to electrical and vice versa decreases the speed of operation and hence, the full capacity of optical systems cannot be utilized. Thus, all-optical signal processing, all-optical devices, and a complete optical network have been identified as the potential candidate to replace the conventional electronic integrated circuits.

To form a complete optical network, all the operations from signal generation, processing, encoding, modulation, transmission, demodulation, decoding, filtering, and so on have to be performed in a fully optical manner. The various electronic based devices for performing these actions must be switched into a complete optical domain. This calls for all-optical logic gates (AO-LGs), all-optical sequential and combinational circuits, all-optical processors, and so on. For developing such optical circuits, the design of AO-LGs is a prerequisite. There are various design aspects to be considered in the design of such gates. Designing of AO-LGs suitable for optical integrated circuits (OICs) requires features, such as high contrast ratio (CR), low response times, small dimensions, and low power consumption.1 It should be simple and offer compatibility with hybrid optoelectric systems and the future all-optical systems without compromising the speed of operation.

In this paper, a complete review of the existing techniques for implementing AO-LGs are explored and their limitations and possible solutions are discussed. An outline of the proposed review paper is given in Fig. 1. We have categorized the logic gates based on their basic techniques of implementation which includes design of the various categories of AO-LGs as shown in Fig. 2. This is covered in Sec. 2. Based on their operation, two classes of AO-LGs are identified as reconfigurable gates and simultaneous gates. The advantages of these types of gates and their implementations are described in Sec. 3. Further, some designs of AO-LGs are focused on the modulation format and data rates in specific. Such designs are analyzed in Sec. 4. Section 5 presents the design of AO-reversible logic gates and their features. In the next section, the various applications of AO-LGs and their design techniques are outlined. Section 7 provides a brief summary of the working principle of various techniques used for designing AO-LGs. In Sec. 8, the various CAD tools for the simulation of AO-LGs are discussed in short. Section 9 focuses on the current status and challenges faced by photonic integrated circuits and future prospects. This is followed by conclusion in Sec. 10 and the detailed list of references.

Fig. 1

Outline of the proposed review paper.

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Fig. 2

Classification of AO-LGs.

OE_61_6_060902_f002.png

2.

Design Techniques of AO-Logic Gates

The seven AO-LGs namely NOT, AND, OR, NAND, NOR, XOR, and XNOR gates are irreversible gates. These are the most widely used logic gates in the construction of sequential and combination logic circuits for a wide variety of applications.

2.1.

SOA-Based Designs

Among the different techniques of implementations, semiconductor optical amplifier (SOA)-based designs are the earliest ones. The initial designs utilized the cross-phase modulation (XGM) effect alone in SOA structures.2 Here, the input signal was used to saturate the gain and thus modulate a probe signal to achieve the desired output signal. The designs based on XGM alone was simpler, polarization-independent, and provided feasibility of bit rates up to 100 Gbps. However, due to the large gain modulation, the requirements of high pump power for nonlinearity, formation of large chip output, and bulky designs were the shortcomings that lowered their performance. An experimental demonstration of AO-AND gate utilizing cross polarization modulation in SOA was performed with a CR of around 16 dB as shown in Fig. 3(a). This design differed from the previous SOA-based designs in generating an output signal with a wavelength independent of that of the input signals.3 To achieve better results, SOAs were combined with interferometric configurations thereby utilizing cross phase modulation (XPM) effect. SOA with Michelson interferometers were designed as these gates have simpler structure since they offer direct access for the input signal to the SOAs.5 AO-XOR gate operating at 20 Gbps was experimentally verified using SOA-based ultrafast nonlinear interferometer (UNI) switch.6

Fig. 3

(a) Experimental demo of AO-AND gate using SOA.3 (b) Configuration of AO-NOR using single QD-SOA.4

OE_61_6_060902_f003.png

The most widely used configuration for the realization of AO-logic gates is the Mach Zehnder interferometric configuration (MZI) due to its attractive features, such as low energy requirement, low latency, and high stability. AO-OR gate was designed using SOA-MZI at 10 Gbps.7 By utilizing a delayed interferometer (DI) along with SOA-MZI configuration, AO-XOR operation was achieved 80 Gbps.8 It was observed that the quality of XOR operation was improved by the addition of DI. A more practical and matured design using the principle of DI was proposed recently by masking the longer SOA recovery time to realize AND, NOR, XNOR gates at 160 Gbps with high Q factor.9 Another approach toward SOA-based AO-LG design is based on terahertz optical asymmetric demultiplexer (TOAD) by utilizing its low levels switching energy to achieve precise control of signals. An AO-XOR gate for nonreturn to zero (NRZ) signals based on TOAD was experimentally demonstrated.10 SOA with fiber Sagnac interferometer was utilized to experimentally demonstrate AO-XOR operation at 10 Gbps and AO-AND gate at 100 Gbps.11,12 This scheme was able to weaken the influence of carrier recovery time of SOA on the logic gate operation compared with TOAD-based design, however, stability remained a drawback. In addition to XPM and XGM effects, four-wave mixing (FWM) was also utilized in SOA-based design. However, two pump signals are required to ensure polarization-independent operation of such gates and owing to the complexity of pumping schemes, and it can be used only for higher bit rates (>100  Gbps). AO-NOR gate was realized using FWM effect in SOA, with feasibility of possible integration.13

More recent designs utilize carrier reservoir SOA (CR-SOA), quantum dot SOA (QD-SOA), photonic crystal SOA (PC-SOA), and reflective SOA (RSOA)-based approaches. AO-OR gate design using CR-SOA with DI achieved 100 Gbps operation with a Q factor of 9 by overcoming the SOA response limitations.14 AO-NAND and XNOR gates were realized for the first time at 120 Gbps for return to zero (RZ) data using CR-SOA.15 Owing to the relaxed structural conditions and flexibility of photonic crystal devices, PC-SOA-based AO-NOR and AO-XNOR gates provided better performance compared with conventional SOA designs.16 Such designs were found to provide highly improved performance characteristics when high data rates are required with high PRBS lengths compared with conventional SOA-based approaches. RSOA consists of a high-reflectivity covering on one side and antireflectivity coating to another side and possesses advantages such as higher gains for lower bias currents and faster response with reduction in cost and complexity of designs compared with conventional SOA approaches. AO-XOR gate using RSOA achieved 300 Gbps at 0.3 mW power input.17 SOAs having quantum dot active regions or QD-SOAs provide superior performance compared with their conventional counterparts owing to their high thermal stability, low temperature sensitivity along with ultrafast gain recovery times. AO-AND, XOR, and NOT gates were modeled using QD-SOAs to operate up to 250 Gbps. However, it was observed that for better results, higher injection currents and narrow input pulse widths were required.18 By utilizing the advantages of XPM and XGM in cascaded QD-SOA structures, AO-NAND gate with extinction ratio (ER) of 163 dB at 640 Gbps was realized.19

Another approach with a series configuration of QD-SOAs to realize AO-NAND operation was numerically simulated at 1 Tbps with the feasibility of achieving high Q factor even with the effects of amplified spontaneous emission noise.20 A numerical model for simulating AO-XOR and AND gates using two photon absorption (TPA)-induced pumping to reduce pattern effects leading to high Q factor with 320 Gbps operation was proposed.21 Another approach using a single QDSOA with an optical filter was utilized to achieve AO-NOR operation at 160 Gbps as shown in Fig. 3(b). However, an additional clock signal was utilized as a probe, which imposed some challenges, such as synchronization and generation.4 The power consumption in QDSOA-based devices is still a drawback that limits its compatibility for use in integrated circuits.

A possible alternative is to utilize the slow light phenomenon of photonic crystal waveguides to bring down the power consumption of QD-SOAs in addition to enhancing the gain and phase changes. Such designs enable precise confinement and efficient transmission of light signals and lead to compact and feasible realizations. AO-NOR gate based on PC-QDSOA with a low power consumption of 4 mW was realized with the low ER of 7 dB limited by the slow phase recovery of PC-QDSOAs.22 Figure 4 shows the active region of the proposed PC-QDSOA. A similar realization achieved AO-OR and AND operations at 160 Gbps with Q factors.23

Fig. 4

Active region of PC-QDSOA.22

OE_61_6_060902_f004.png

2.2.

Nonlinear Fiber-Based Design

Few of the earlier designs of AO-LGs besides SOA were based on the nonlinearity of the optical fiber itself. Highly nonlinear fiber (HNLF) has the ability to process ultrafast signals by utilizing the Kerr effect in silica, and the requirements of high input powers for nonlinearity and bulky dimensions (longer interaction lengths) limited their use in integrated circuits. AO-XOR gates were implemented using nonlinear polarization rotation in HNLF at 20 Gbps.24 An experimental demonstration of AO-XOR, NOT, and AND gates using nonlinear polarization rotation in HNLF was performed at 10 Gbps.25,26 Among the earlier designs, some implementations were based fully on optical fiber componenets and nonlinearity, such as nonlinear directional couplers as shown in Fig. 5, asymmetric couplers, and so on. Various AO-LG operations were numercially analyzed using a symmetric three-core nonlinear directional coupler (TNLDC) and an asymmetric two-core coupler (DNLDC) and their performances were compared by introducing a new figure of merit.27 AO-AND, XOR, and OR gates were analyzed based on three different asymmetric DNLDC with varying self pahse modulation (SPM) profiles wherein the optimization of nonlinearity profile lead to better results.28 By utilizing soliton propagation in TNLDC, AO-XOR, OR, NAND, NOR, XOR, and XNOR gates were analyzed numerically.29

Fig. 5

A nonlinear directional coupler of length Lc.27

OE_61_6_060902_f005.png

2.3.

Interferometer-Based Design

There are several designs of AO-LGs based on interferometric structures, such as MZI, Sagnac interferometers, and UNI. The basic principle behind such structures is the interaction between different waves leading to constructive or destructive interfernce depending on phase, amplitude, and frequency (wavelength) of the waves. Nonlinear effects commonly utilized with such structures for the design of AO-LGs include XPM, two-photon absorption, etc. Nonlinear optical loop mirror (NOLM) or the nonlinear Sagnac interferometer was used in the early designs of AO-LGs. Owing to its inherent stability and fast response times due to fiber nonlinearity, such designs provided feasibility for all-optical signal processing. However, NOLM requirements of high optical powers and longer fiber lengths restricted their flexibility and widespread use. AO-XOR operation was experimentally demonstrated at 10 Gbps using a fiber Sagnac interferoemeter assisted by SOA.11 Another such work realized AO-LGs using low birefringent NOLMs at 100 Gbps for the application of all-optical packet drop function.30 Electro-optic effect-based cascaded MZI structures were used to achieve XOR, XNOR, AND functionalities.31 Various logic functions were realized using local nonlinear MZI acting as a phase shifter employing angular deflection of spatial solitons.32 Few of the recent works utilized photoic crystal-based nonlinear MZI wherein the nonlinear arm of MZI is replaced with slotted photonic crystal waveguide. By utilizing a control signal and XPM phenomenon, an AO-NOT with low input power requirement and response time of 3 ps was succesfully implemented.33 Another approach used MZI with dual-core nonlinear photonic crystal fiber (PCF) to achieve AND and OR gates having high CR.34 Some of the experimental works on AO-LGs were based on semiconductor laser diodes with the target of lowering response times and cost effective approaches. AO-NOT and NOR gates were experimentally demonstrated at 10 Gbps by utilizing the gain modulation technique in Fabry–Perot laser diodes (FP-LDs). This technique provided the added advantage of supporting multicasting operation of AO-LGs with low power operation and high ER.35 Similar realization of AO-NOT and NOR gates at 10 Gbps with FP-LDs allowing two different wavelengths was achieved with the possibility of attaining up to 40 Gbps speed by replacing with quantum-well FP-LDs.36 A much simpler design without using any external probe signals was achieved based on a single mode FP-LD working on self-locked dominant mode to achieve NAND, XNOR, AND, and XOR operations at 10 Gbps.37 Recently, a hybrid cavity semiconductor laser consisting of a FP cavity and a square microcavity was used to experimentally demonstrate NOT, NOR, and NAND functions at 20 Gbps with high ER values.38

2.4.

PPLN-Based Design

Periodically poled lithium niobate (PPLN) waveguides were utilized to realize all-optical logic functions with ultrafast response, complete transparency, negligible spontaneous emission noise, independency of data format, and bit rate and low intrinsic frequency chirp. However, size limitations along with temperature and polarization dependencies limit their use in integrated circuits. Based on sum-frequency generation in a single PPLN waveguide, AO-OR and XOR gates were realized at 40 Gbps.39 An experimental demonstration of AO-AND gate based on cascaded sum and difference frequency generation in PPLN waveguide was performed at 20 Gbps.40 Electro-optic effect in PPLN was utilized to achieve AO-controlled NOT, XNOR, and XOR gates based on polarization control with experimental demonstration.41 By utilizing the mechanical movement of mirrors, the path followed by light signals can be controlled in a suitable manner to achieve all-optical logic operations.

2.5.

MEMS and Nematic Liquid Crystal-Based Design

Three variable AO-XOR and XNOR gates were implemented with mechanical movable mirrors with feasibility of chip-level implementation using MEMS (micro electromechanical systems)-based systems.42 A liquid crystal light valve with a photonic crystal slab was utilized to achieve all-optical control of spatial solitons for the realization of reconfigurable AO-LGs. AO-NOR and XNOR functions were achieved in such a manner using external beams for flexible operations.43 Despite possessing longer response times, the generation of solitons in nematic liquid crystals to perform all-optical logic operations has advantages such as transparent spectrum and nonresonant nonlinearity which may be explored further.

2.6.

MMI-Based Design

Multimode interference (MMI)-based devices work on the principle of self-imaging to achieve the desired logic operation wherein the guided modes of the MMI region are excited to interfere constructively. AO-XOR, NAND, OR, XNOR, and NOT gates were realized using an MMI waveguide structure with compact dimensions with simultaneous operations.44 A 3-dB MMI coupler was used to implement a two-input AO-XOR gate as a base structure for the design of three- and four-input XOR gates and addressed the possible fabrication issues for practical implementations.45 AO-AND, OR, NOR, and XOR gates were realized based on MMI effect using 2×2 MMI couplers.46

2.7.

Plasmonic Waveguide-Based Design

Plasmonics and photonics are two widely researched areas with regard to the design of AO-LGs due to their fascinating features that enable flexible, compact, and ultrafast realizations. Plasmonic slot waveguides exhibit strong plasmonic enhancement enabling strong confinement of light into a subwavelength range region and possess ultralong range propagation over several micrometres. To overcome the limitations in performance, due to dust particles in the air slots, a possible solution of replacing air slots with dielectric has been utilized in several designs. AO-XNOR, XOR, NOT, and OR gates were realized using plasmonic slot waveguides based on linear interference with an ER of 24 dB.47 Graphene-based plasmonic MZI structure was used to achieve 6 AO-LG functions with distinctive features, such as high flexibility, compactness, and large scalable bandwidth spectrum.48 Hybrid metal on insulator metal plasmonic waveguide was utilized to realize AO-O, XOR, and NOT gates miniaturized dimensions and high ER of 26 dB based on interference effect.49 A similar attempt was made recently with further reduced dimensions of using metal insulator metal (MIM) plasmonic waveguides and improved the CR value by 27.8 dB.50 A simpler design for AO-AND gate was attempted using a Y-shaped MIM plasmonic waveguide with improved flexibility and operating speed.51 The diffraction limit is a factor that brings down the photonics-based design approach when attempting compact designs with device dimensions comparable to operating wavelength. In such a scenario, plasmonics-based waveguides are better candidates, which helps in realizing ultracompact devices to overcome the diffraction limit and confine and control light in a precise manner.

2.8.

Photonic Crystal-Based Design

Photonic crystals have recently emerged as the best platform for the design of all-optical logic devices with compact dimensions, high speed, simpler designs, flexibility, and compatibility with hybrid opto-electronic as well all-OICs. By utilizing their unique photonic bandgap property for efficient and precise control of light signals, several all-optical devices such as filters, multiplexers and demultiplexers, encoders and decoders, splitters, switches, logic gates etc. have been implemented.52 In general, there are three approaches to design AO-LGs using photonic crystals. The first approach is based on linear effects which utilizes constructive and destructive interference effects and have much lower power consumption but require precise phase control, sometimes requiring external phase shifters. The disadvantage of this approach is that it is affected by phase sensitivity, operational bandwidth limitations, and low tolerance to input power fluctuations and therefore achieving high ER values is difficult. AO-AND, XOR, NOT gates using a Y-shaped photonic crystal waveguide based on interference effect with compact dimensions and reduced power consumption.53 Another design realized AO-OR, NOT, AND gates based on wave optics theory with low response time of 0.128 ps.54 The universal AO-NOR gate was recently designed using square lattice photonic crystals to bring down the delay time to 0.06 ps and enable easy fabrication and integration with OICs.55 A power efficient design for AO-NOT gate using a nanoresonator in a hexagonal lattice of photonic crystals achieved a maximum data rate of 2.145 Tbps and verified the feasibility of operation in OICs as shown in Fig. 6(a).1 The second approach is based on nonlinear effects which usually require longer interactions lengths and higher power consumptions to realize designs with high CRs with comparatively longer response times. Most of the available works utilize the optical Kerr effect wherein the refractive index of the pump signal is varied upon the application of high input intensity. Photonic crystal ring resonators working on Kerr effect were utilized to design AO- AND/OR/NOT gates with lower threshold input power at 1550 nm.57 AO-AND gate with a response time of 0.4 ps with an input switching power of 10 W was proposed on GaAs substrate.58 AO-NAND and NOR gates were realized with a unique bypass waveguide to reduce the heating effect in the integrated circuit with good CR values and low power consumption.59 A GaAs-based photonic crystal ring resonator was utilized to achieve AO-AND operation using nonlinear Kerr effect with a response time of 1.8 ps.60

Fig. 6

(a) Checking the feasibility of photonic crystal AO-NOT gate in OICs.1 (b) MMI-based photonic crystal LG design.56

OE_61_6_060902_f006.png

The third approach is based on self-collimation effect in photonic crystals with the advantage of intensity-independent operation. The interference between self-collimated beams were used to design AO-NOT, OR, AND, and XOR gates with low power consumption at the telecommunication wavelength of 1550 nm.61 A 3-dB splitter based on line defects was utilized to realize AO-XOR and OR operations with a CR of 17 dB with simple design.62 Various logic functions were achieved using a single structure based on silicon photonic crystals with compact dimensions and a CR value of 6 dB.63 The limitations of using self-collimation effect is that dispersion control in photonic crystals is more difficult and it requires precise phase control with larger footprints. MMI effect has been utilized in photonic crystal waveguides due to their low loss, low polarization dependence, and wider bandwidths to realize AO-LGs with simple geometry. AO-XOR, NAND, XNOR, and OR gates were realized using MMI photonic crystal waveguide with ultra-compact dimensions of 6.9  μm×6.7  μm and high CRs.64 Various logic functions were realized on a BPSK modulated input signal using MMI waveguides in two-dimensional (2D) photonic crystals with a wide operating bandwidth of C band56 as shown in Fig. 6(b). Si rods in a square lattice of photonic crystals are utilized to realize MMI-based AO-XNOR/XOR, OR/NAND gates with high CR of 40.41 and 37.40 dB with low response times of 0.131 ps and small footprint.65 So far, most of the designs based on 2D photonic crystals utilized rods in air or any other substrate due to its simpler geometry and easy implementation. When considering the practical implementation and fabrication factors, photonic crystal slab-based designs come into the picture. Such designs provide confinement of light in vertical direction using total internal reflection and permit manipulation of light in the plane of slab. AO-NAND, AND, NOR, and OR gates were implemented on Ag-polymer photonic crystal slabs based on the nonlinear effects of the high Q-cavities.66 On chip realization of AO-XOR, AND gates operating at different frequencies on silicon photonic crystal slabs were achieved without any nonlinear optical effects.67 The seven major AO-LGs were realized using a 50:50 topologically protected beam splitter based on Si photonic crystal slabs with interference effect.68

2.9.

Photonics and Plasmonics Based Design

Recently, several architectures utilizing the advantages of both plasmonics and photonics have come up to design AO-LGs. Hybrid plasmonic-photonic nanocavities possess the features of original cavities along with plasmonic features of metallic elements, which boosts the light matter interactions and offer better performance. One such design based on silicon insulator photonic crystal cavity equipped with a metallic nanoantenna was used to realize AO-NOT and AND logic functions.69 AO-LGs were realized using triangular lattice of photonic crystals with copper-based plasmonic material as background material.70

2.10.

Topological Photonics-Based Design

One of the recent technologies in use for the implementation of AO-LGs is based on topological photonics. The conventional photonic-based waveguides are not able to transport light over sharp turns (90 deg) without using a large radius of curvature. Also, the transmission cannot be achieved in an effcient way when defects are also included in such waveguide design. The nonnegligible backscattering in photonic crystal waveguides is a concern that requires some significant concern. In this case, a potential solution is the application of topologically protected edge states (TPES) in the anomalous Floquet photonic topological insulator structures, which enable easy fabrication. The advantage of this technology includes the ability to use visible light and extended spectrum upto near-IR for silicon photonics, efficient manipulation of optical signals, and robustness against disorder makes them potential candidates for AO-device design. AO-OR, AND, and XOR gates were implemented based on TPES in the visible light range for the first time along with the consideration of possible fabrication techniques.71 A linear interference approach was utilized to implement the seven AO-LGs using 2D photonic crystals with edge states possessing advantages of immunity from disturbance and fault tolerance.72 An experimental implementation of AO-OR/XOR gate based on coherent interactions between 1D photonic topological interfaces in coupled waveguide arrays was achieved with unique topological properties, such as efficient confinement, fast switching, and robustness.73 A recent approach realized the various AO-LGs with high operational speeds utilizing metamaterials-based three-dimensional (3D) photonics technology by making suitable variations in diameter of air holes, lattice constant, and effective refractive index of the structure.74 AO-OR, AND, and XOR gates were fabricated using 3D printing as simple, low-cost solutions to perform AO-logic operations at THz frequency ranges with possibility of reconfiguration to achieve various other logic functions.75

2.11.

Artificial Neural Networks-Based Design

Another upcoming area of recent interest in the design of AO-LGs is based on artificial neural networks (ANNs). Most of the designs available in the literature so far depend on precise phase control of the incoming optical signals including their phase difference, polarization, and intensity. This makes the design of compact devices difficult due to bulky components or larger footprint requirements imposed by the phase control mechanisms.

Also, in practical scenarios, inaccuracy in phase control leads to instability and brings down the CR values which is the primary performance metric with regard to AO-LGs. To overcome these challenges, a universal strategy based on diffractive neural networks was proposed to realize the seven logic operations within a compact system using plane waves. After training, the diffractive neural network based on Huygen’s metasurface could directionally scatter of focus light to designated areas to represent the two different logic states, 0 and 1. The proposed work possesses advantages such as universality of the design, powerful, and flexible operations and miniaturization. An experimental demonstration of the above concept performed at microwave frequencies to attain AO-NOT, OR, AND operations, and theoretical framework for their realization at terahertz frequencies was proposed.76

Most of the modeling techniques for AO-LGs utilize numerical simulations based on finite element method (FEM), finite difference time domain (FDTD), plane wave expansion (PWE), beam propagation method (BPM), and so on. The computational complexity and computation time of such simulators are still an open challenge that needs some addressing. Recently, ANN-based approaches have attempted to reduce the complexity, cost, and processing time and also improve the accuracy of output prediction. To simulate the performance and analyze the behavior of an AO-3 input XOR gate, two different approaches based on ANN were proposed. Two learning methods, multilayer perceptron and radial basis function, have been utilized to predict the output logic state of the proposed gate with improved accuracy and reduced processing times. This work opened up the possibility of exploring various machine learning-based algorithms to model AO-logic devices with high accuracy and bring down the computational time utilized by existing commercial softwares from several hours/minutes to the range of milliseconds.77 Two optical neural networks composed of passive optical elements were utilized to achieve AO-XOR operation with low power consumption.78 A summary of the various techniques to design AO-LGs is shown in Table 1.

Table 1

Summary of techniques for the design of AO-LGs.

Sl. no.AO-LG design techniquePaperMax data rateMax CR (dB)Remarks
1SOA based1 to 23,791 Tbps19.21Increased power consumption, bulky dimensions, and increased latency
2HNLF based24 to 2620 Gbps25Increased power consumption, bulky dimensions
3NLDC based27 to 2970.3Bulky dimensions, lack of flexibility in design
4Interferometric structure based11, 3031.32.33.34100 Gbps17Bulky dimensions, phase control requirements, increased power consumption
5Semiconductor laser based35 to 3820 Gbps20Bulky dimensions, high input power requirements
6PPLN based3940.41160 GbpsSize limitations, temperature and polarization dependencies
7Mechanical movable mirror based42Bulky dimensions, lack of integration capability and flexibility
8Nematic liquid crystals43Size limitations, external phase control, longer delay time
9MMI device based44 to 4626Size limitations, excess loss, fabrication issues
10Plasmonic waveguide based47 to 513.33 Tbps27.8Propagation loss, flexibility
11Photonic crystal based1, 52 to 682.145 Tbps40.41Diffraction limit leading to size issues, power consumption for nonlinear effect-based designs
12Plasmonics + photonics69, 70Able to overcome the diffraction limit and design ultracompact devices with precise control of light
13Topological photonics based71 to 73>20Signal loss at sharp bends in PhC waveguides can be overcome
143D photonics technology based74, 75Complexity, compatibility
15Artificial intelligence based75, 76, 78Universal designs, miniaturization, flexible and powerful operation, complexity and computation time need to be addressed

3.

Reconfigurable and Simultaneous AO-LGs

In reconfigurable logic gates, more than one logic function can be realized without altering the device structure. The various logic functions can be realized by suitable techniques such as tuning the wavelength or using phase control. The advantage of reconfigurable AO-LGs is that they improve flexibility and robustness in addition to reducing the number of devices for integration in OICs. AO-NOR, AND, and OR gates were experimentally demonstrated at 100 Gbps using a single SOA along with an optical filter wherein reconfigurability was achieved by deployment of CW light and tuning of the optical bandpass filter at SOA output.80 The experimental setup for the same is shown in Fig. 7. Various AO-LGs were experimentally demonstrated for differential phase shift keying (DPSK) modulated signals at 20 Gbps utilizing SOA and delay interferometers. The variation of input wavelengths or phase control provided the required reconfigurability.81 A Si photonic crystal-based compact structure operated as AO-XOR/NOT gate based on a fixed bias signal. The proposed device worked purely on linear optics regime and achieved high CR values with operating speed up to 3.15 Tbps.82 A similar work based on photonic crystals achieved reconfigurable AO-XOR/OR gates by varying the phase of the input signals and achieved very low response time of 120 fs.83 A reconfigurable structure to realize up to 25 logic functions by adjusting the bias voltage of the modulators, peak-to-peak voltages of the driving signals, and the rotation angle between the polarizations was simulated at 10 Gbps and experimentally verified to achieve the six basic logic functions at 1 Gbps.84

Fig. 7

Experimental setup for reconfigurable AO-LGs using single SOA at 100 Gbps.80

OE_61_6_060902_f007.png

The unique photonic and optoelectronic properties and high confinement in graphene was utilized to design reconfigurable logic gates based on coherent perfect absorption principle in the THz region. AO-AND, OR, and XOR operations were achieved in a simple compact structure wherein switching between functions was achieved by varying the relative phase difference between the signals.85 A QD-SOA and optical filter were utilized to achieve multiple logic operations on a single structure at 160 Gbps. The detuning of the filter was used to switch between NOT, OR, AND, and NOR operations with high quality output.86 Two parallel HNLFs and a phase shifter were utilized to implement AO-NOT, XOR, and AND operations at 120 Gbps based on XPM effect as shown in Fig. 8. Here, the reconfigurability was achieved by slightly modifying the input signals and phase variation to obtain high quality output.87 Ultrafast reconfigurable logic operations were numerically simulated based on a nonlinear metallodielectric grating with enhanced nonlinearity, high speed, and scalability in design with addition to compatibility with existing CMOS-based structures. Although the design provided sub-picosecond switching speeds with improved cascadability, the high switching power was still a limiting factor which required further improvement.88 One of the earlier attempts involved an experimental demonstration of four different logic operations using an optical parametrical amplifier based on highly nonlinear dispersion shifted fibers working on FWM effect. AO-AND, NOT, XOR, and OR operations were achieved at 10 Gbps with possibility of operation up to 80 Gbps wherein reconfigurability was obtained by altering the input power, center frequencies, and/or polarization states on incoming signals.89 By making use of the advantages of BPSK modulated signals such as nonlinearity tolerance and improved OSNR, photonic crystal MMI waveguides as shown in Fig. 9 attained AO-XOR, XNOR, OR, and NAND operations with high CR value. Different combinations of BPSK signals were used to realize the various logic operations without changing any structural parameters.64 Reconfigurable and polarization independent AO-LGs were implemented on silicon on insulator photonic crystal structure with a complete bandgap in the 1550-nm optical window having a 2D honeycomb lattice structure as shown in Fig. 10. The reconfigurability was achieved by varying the phase angle of the reference signal within the three-port waveguide shaped structure.90 An optical programmable Boolean logic unit has been designed using 2×2 polarization-independent optoelectronic cross bar switch. The above design is one of the first attempts at more complex reconfigurable structures capable of performing parallel switching operations with minimum data loss.91 A summary of the design techniques for realizing reconfigurable AO-LGs is shown in Table 2.

Fig. 8

Realization of reconfigurable AO-LGs using parallel HNLFs.87

OE_61_6_060902_f008.png

Fig. 9

Photonic crystal MMI-based structure for realizing attained AO-XOR, XNOR, OR, and NAND operations.64

OE_61_6_060902_f009.png

Fig. 10

Three-port honeycomb photonic crystal structure for reconfigurable AO-LG design.90

OE_61_6_060902_f010.png

Table 2

Summary of reconfigurable AO-LGs.

Sl. no.Logic functionPaperImplementationNo. of reconfigurable logic functions achievedMax CR (dB)Max data rateFootprint (μm2)
1AO-NOR, OR, AND80Experimental3100 Gbps
2AO-AND, NOR, XOR, XNOR81Experimental420 Gbps
3AO-NOT, XOR82Simulation243.43.15 Tbps85.02
4AO-XOR, OR83Simulation2150
56 basic LG functions + 19 advanced LG functions84Experimental + simulation25>610 Gbps
6AO-AND, OR, XOR85Simulation314676
7AO-AND, NOR, NOT, OR86Simulation411.34160 Gbps
8AO-NOT, AND, XOR87Simulation3120 Gbps
9AO-XOR, AND88Simulation28
10AO-XOR, OR, NOT, AND89Experimental415.3680 Gbps
11AO-XOR, XNOR, NAND, OR64Simulation428.646.23
12AO-AND, OR, NOT, NAND, NOR, XNOR90Simulation6103.33 Tbps

Simultaneous AO-LGs achieve more than one logic operation within the same structure at the same time, i.e., when two or more logic functions are achieved simultaneously on different ports of a single device. The advantage of such gates compared with conventional ones is that they can achieve more than one logic function for the same set of input in the same device thereby saving space and lowering power requirements for an OIC. There have been designs for simultaneous AO-LG implementation in the recent times. AO-AND/OR operations were achieved simultaneously using incomplete coupling concept in nonlinear directional coupler with the aim of reducing power consumption and enabling cascaded operation.92 A square lattice photonic crystal structure with two input and two output ports generated AO-OR and XOR output at each of the output ports at the same time. The proposed devices achieved control of light signals using line and point defects and operated with high data rate of 2.5 Tbps.93 Another attempt to realize simultaneous AO-XOR/OR gates utilized a single quantum dot bimodal cavity working in the low-photon-number regime utilizing destructive interference effect.94 Photonic crystal ring resonators utilizing the nonlinear Kerr effect was used to attain concurrent implementation of AO-XOR/AND gates at 746 Gbps with reduced power consumption at the telecommunication wavelength of 1550 nm.95 The schematic for the same is shown in Fig. 11.

Fig. 11

Concurrent implementation of AO-XOR/AND using photonic crystal ring resonators.94

OE_61_6_060902_f011.png

Concurrent implementation of AO-XNOR/XOR was experimentally demonstrated at 100 Gbps using cascaded microring resonator-based electro-optic logic circuit using plasma dispersion effect. The proposed set up had limitations in improving the operating speed and lowering the dimensions which required further addressing.96 Simultaneous AO-AND/OR logic function is attained with multiwavelength operation in the C band using a photonic crystal platform at ultrahigh bit rates.97 An earlier attempt to achieve simultaneous implementation of AO-XOR, NOR, OR, and AND operations was experimentally demonstrated using two parallel SOA-MZI structures at 10 Gbps by suitable varying the gain and phase differences to attain maximum ER.98 A nonlinear photonic crystal ring resonator-based structure was used to achieve simultaneous AO-XOR/XNOR operation at 1550 nm. However, the design possessed a higher footprint and longer response time, which required further improvement.99 Simultaneous operation of AO-XOR and AND gates was achieved using one-dimensional periodic nonlinear material model with CR of 14.13 dB.100 A 3×3 optical interconnecting switch based on QDSOA-MZI achieved three AO-logic operations simultaneously with high speed and CR of 8.20 dB.101 Simultaneous AO-XOR/XNOR functions were realized using 2D MEMS-based diagonal switching with possible extension for higher bit operation.102 A summary of the design techniques for realizing simultaneous AO-LGs is shown in Table 3.

Table 3

Summary of simultaneous AO-LGs.

Sl. no.Logic functionPaperImplementationNo. of simultaneous logic functions achievedMax CR (dB)Max data rateFootprint (μm2)
1AO-OR, AND92Simulation2500 Gbps
2AO-XOR, OR93Simulation26.762.5 Tbps
3AO-OR, XOR94Simulation2
4AO-AND, XOR95Simulation212.78746 Gbps320
5AO-XOR, XNOR96Experimental2100 Mbps
6AO-AND, OR97Simulation217.956.76 Tbps249.48
7AO-XOR, NOR, OR, NAND98Experimental + simulation41010 Gbps
8AO-XOR, XNOR99Simulation21200
9AO-XOR,AND100Simulation214.13

4.

Reversible AO-LGs

The literature considered so far involved only irreversible optical logic gates wherein the input bits are lost after generation of output bits. However, the conventional irreversible logic gates are not suitable for large-scale integrated circuits due to heat dissipation owing to bit loss at the output. Considering high-speed integrated circuits, a large amount of bit loss leads to a higher heat dissipation, which could lead to a serious issue. In such a scenario, the best option is to shift toward reversible logic gates. Reversible AO-LGs possess a direct mapping between input and output and there is no chance of bit loss, which lowers the heat dissipation in the circuit. The number of input ports and output ports remains the same leading to unique retrieval of input information from the output information. The use of reversible AO-LGs for the building optical processor leads to power efficient designs and improves the ability of data recovery. The main difference between reversible and irreversible logic gates is that reversible gates do not lose information, whereas irreversible gates tend to lose information after computation. Some of the widely used basic reversible gates in the electronic domain are Toffoli gate, Fredkin gate, and Feynman gate.

One of the initial attempts to demonstrate all-optical Fredkin gate utilized an SOA-based nonlinear loop mirror with a switching energy of 100 fJ.103 Based on the nonlinear rotation of the state of polarization of probe beam and frequency conversion properties of nonlinear SOAs, frequency encoded AO-Fredkin and Toffoli gates were realized. The advantage of using frequency encoding to bring down the bit error problems along with high-bit-rate operation were achieved.104 The attractive features of lithium niobate-based MZI structures, such as integration potential, thermal stability, compactness, low response time, and reconfigurability, were applied to realize AO-Fredkin and Feynman gates based on electro optic effect.105 A different approach to design AO-Toffoli and Fredkin gates utilized the frequency conversion properties of SOA.106 An attempt to construct a modified Fredkin gate using SOA-MZI structure with the ability to perform 15 Boolean logic functions was proposed. However, the proposed work was a preliminary model that needed further improvements to bring down the BER value and increase the speed of operation.107 A plasmonics-based design approach was used to implement reversible NOT, swap, wire, and Feynman gates at 1550 nm. The above design used nanoring dielectric metal dielectric plasmonic waveguides based on interference effect.108 AO-Fredkin gate was realized using photonic crystal based three types of nonlinear ring resonators with doped glass as nonlinear material.109 AO-Feynman gate was theoretically analyzed and experimentally demonstrated using silicon microring resonators for 10 kbps.110 A 16-wavelength hybrid AlGaInAs/InP microdisk laser array on silicon-on-insulator (SOI) was analyzed using FEM to improve the thermal characteristics for efficient operation.111 A new design for reversible optical double Feynman gate using XPM in MZI was proposed for use in MZI-based quantum circuits.112 An all-optical reversible programmable processor capable of performing 16 different operations was designed using liquid crystal-phase spatial light modulators, a polarization beam splitter, a half-wave plate, and plane mirrors.113 SOA-assisted Sagnac interferometer-based design for the equalizer SWAP gate with improved performance in terms of reduced optical cost, low crosstalk, and high CR.114 A simple design for all-optical Fredkin gate using mechanically controllable mirrors with feasibility for chip level implementation using MEMS was proposed.115 All-optical Feynman, Toffoli, Peres, and Feynman double gates were realized using optically controlled bacteriorhodopsin protein-coated microresonators with low power consumption and high Q factor.116

The design of reversible AO-LGs is an upcoming area requiring wider research owing to its versatile areas of applications. It is the primary component required to design sequential and combination circuits for optical processors for applications, such as optical computing, optical signal processing, multivalues logic operations, and so on. The key advantages of such gates are low power consumption, high data recovery capabilities, least power dissipation, less hardware complexity, and high speed of operation. Hence, there is a growing need to design highly compact, flexible, and robust structures with high CR and low response times to achieve reversible logic operations. A summary of the design techniques for realizing all-optical reversible logic gates is shown in Fig. 12 and the details are tabulated in Table 4.

Fig. 12

Design techniques of AO-reversible LGs.

OE_61_6_060902_f012.png

Table 4

Summary of reversible AO-LGs.

Sl. no.Reversible AO-LGTechniquePaperImplementation
1AO-Fredkin gateSOA-based nonlinear loop mirror103Experimental
2AO-Fredkin, Toffoli gateSOA-based ADM104Numerical analysis
3AO-Feynman, Fredkin gateLithium niobate-based MZI105Simulation
4AO-Fredkin, Toffoli gateSOA as PSW106Simulation
5AO-modified Fredkin gateSOA-MZI switch107Simulation
6AO-Feynman gatePlasmonic waveguides108Simulation
7AO-Fredkin gatePhotonic crystal nonlinear cavities109Simulation
8AO-Feynman gateSilicon microring resonators110Experimental

5.

AO-LGs Based on Modulation Format and Data Rate

Another classification of AO-LGs is based on the modulation format of the input signals. A majority of the implementations makes use of on-off keying (OOK), as it can be directly interfaced with electrical logic without any encoding or decoding by merely switching the optical signal on and off. An investigation on AO-XOR operation between OOK and BPSK modulated signals was performed based on nonlinear effect in HNLF. The attempt was aimed to perform XOR operation on signals having different modulation formats without unnecessary conversion of signals to the same modulation format.117 An experimental demonstration of dual channel AO-AND operation for OOK signals was achieved based on FWM using a fabricated multimode silicon waveguide.118 FWM in a single SOA was utilized to obtain simultaneous implementation of AO-AND and OR operations for three different modulation formats at 40 Gbps.

A numerical analysis and experimental demonstration were performed for the typical NRZ-OOK format along with RZ-OOK (RZ) and CSRZ-OOK (carrier suppresses return to zero) formats with high ER values.119 Another experimental demonstration for XOR operation was achieved using FWM effect in silicon nanowire for QPSK modulated signals with the capability of high-speed operation limited by the carrier recovery time.120 A similar attempt using degenerate FWM in HNLF was utilized to obtain XOR operation for NRZ-DPSK signals at 40 Gbps with multicasting capability.121 One of the earlier attempts to achieve AO-AND/OR operations for pulse position modulation (PPM) soliton pulses used a symmetric NLDC for TDM systems.122 Another such design utilized integrated SOA-MZI to demonstrate AO-NAND operation at 10 Gbps which showed potential for further improved by utilizing differential scheme.123 A summary of modulation format-based AO-LGs is tabulated in Table 5.

Table 5

Summary of modulation format based AO-LGs.

Sl. no.Logic functionTechniquePaperImplementationModulation format used
1AO-XORXPM in HNLF117Numerical analysisOOK, BPSK
2AO-ANDFWM in multimode silicon waveguide118ExperimentalOOK
3AO-OR, ANDFWM in SOA119ExperimentalNRZ/RZ/CSRZ-OOK
4AO-XORFWM in silicon nanowire120ExperimentalQPSK
5AO-XORFWM in HNLF121ExperimentalNRZ-DPSK
6AO-AND, ORSPM in symmetric NLDC122Numerical analysisPPM

High data rate is one of the significant advantages offered by AO-LGs. An AO-AND gate operating at 10 Gbps was implemented and experimentally demonstrated using cascaded SOAs based on XGM effect.124 One of the first realizations of AO-XOR gate using NOLMs attained up to 10 Gbps speed.125 Further experimental attempts based on UNI-6 and SOA-based MZI configurations126 achieved up to 20-Gbps data rate. To improve the data rate of AO-LGs based on SOA-MZI due to limitations imposed by carrier life time, a differential scheme was explored with potential capability of >100  Gbps operation.127 A TOAD-based demultiplexer achieved 50 Gbps switching by exploiting the nonlinear effects in semiconductors with less than 1 pJ of energy as compared to earlier designs of AO-LGs.128 A theoretical approach to accelerate the recovery time in SOA to achieve high data rates up to 2.5 Tbps with Q factor of 4.9 was utilized to design QD-SOA-based XOR gates.129 An experimental demonstration of AO-AND gate using silicon microring resonator was performed at 10 Gbps attaining clear eye diagrams and low bit error rates.130 A reconfigurable logic gate based on XPM in an HNLF was realized at 160 Gbps.131 The major cause of low bit rate in XGM-based designs is the high chirping and lower ER values. These were overcome using high power pump signal with low power probe signal to realize various logic operations using XGM in SOA at a high bit rate of 340 Gbps.132 A new scheme to realize AO-AND gate at 640 Gbps using a bulk SOA with turbo switch to boost the data rate using an improved version of differential scheme was numerically analyzed.133 By utilizing the merits of both quantum dots and TPA effects, a shorter carrier recovery time and higher bit rates of 2 Tbps were attained for realizing AO-NOR and XNOR functions in QDSOAs.134 A PCF-based NOLM was utilized to achieve AO-XNOR, XOR operations at 1 Tbps with lower dimensions and high ER values.135 Another attempt at improving the data rate of QD-SOA-based AO-XOR gate without using MZI structure achieved 2 Tbps speed. The above work utilized nonMZI layout without any filter thereby lowering complexity and precise phase matching and tuning of filter.136 A method to increase the data rate of a photonic crystal-based AND gate by changing diameter of hole increased the bit rate from 0.976 to 1.52  Tbit/s.137 A summary of data rate-based AO-LGs is tabulated in Table 6.

Table 6

Summary of data rate-based AO-LGs.

Sl. no.Logic functionTechniquePaperImplementationData rate achieved
1AO-ANDXGM in SOA124Experimental10 Gbps
2AO-XORNonlinear effect in nonlinear loop mirror125Experimental10 Gbps
3AO-XORSOA-based UNI switch6Experimental20 Gbps
4AO-XORXGM in SOA-MZI126Experimental20 Gbps
5AO-XORXGM in QDSOA129Simulation2.5 Tbps
6AO-ANDSilicon microring resonator nonlinear effect130Experimental10 Gbps
7AO-XOR, OR, NAND, NOR, NOTXPM in HNLF131Numerical analysis160 Gbps
8AO-NOT, XOR, XNOR, NORXGM in SOA132Simulation340 Gbps
9AO-ANDXGM in SOA-MZI133Numerical analysis640 Gbps
10AO-NOR, XNORTwo photon absorption in QDSOA134Numerical analysis2 Tbps
11AO-XOR, XNORPhotonic crystal fiber NOLM135Numerical analysis1 Tbps
12AO-XORXGM in QDSOA without filter136Numerical analysis2 Tbps
13AO-ANDLinear effect in photonic crystal waveguides137Simulation1.52 Tbps

6.

AO-Combinational and Sequential Logic Circuits

AO-LGs form the building blocks for the construction of various AO-combinational and sequential logic circuits for a wide variety of applications. Several AO-circuits such as code converters, parity checker and generator circuits, half adder, full adder, flip-flops (FFs), and so on are derived from basic AO-LGs as shown in Fig. 13. A brief review of such circuits and their methods of implementation is presented below.

Fig. 13

Applications of AO-LGs.

OE_61_6_060902_f013.png

6.1.

AO-Combinational Circuits

A design of AO-Galois field adder based on a photonic crystal-based AO-XOR gate working on interference effect was proposed. The 4-bit adder was realized using 4 AO-XOR gates.138 A design for 8 to 3 binary optical encoder utilized 4 AO-OR gates and a buffer gate to achieve efficient operation based on linear effects.139 A structure for 4-to-2 AO-encoder based on a buffer and AO-OR gate utilized linear interference effect in 2D photonic crystals and achieved low response time.140 Another such attempt was based on nonlinear effect in photonic crystal ring resonators and utilized AO-NOR gate.141 An experimental demonstration of an AO-divider circuit based on AO-XOR gate for forward error detection was realized using SOA-MZI structures.142 AO-half adder circuit based on AO-XOR/AND gates was proposed based on PhCRR with high CR and low footprint with operating wavelength of 1530 nm.143 A similar attempt at realizing AO-half adder utilized AlGaAs is used as a nonlinear material and achieved maximum CR of 12.9 dB at 0.322 Tbps.144 A photonic crystal semiconductor optical amplifier-Mach–Zehnder interferometer-based design of AO-half adder achieved high CR and data rate up to 500 Gbps.145 AO-half adder and full adder circuits were realized using SOA-MZI utilizing nonlinear effects feasible for operation up to 60 Gbps.146 A single SOA-based structure was used to realize half-subtracter, half-adder, comparator, and decoder with 10 Gbps operation based on FWM and XPM effects.147 Frequency-encoded AO-XOR gate along with half adder and full adder circuits were implemented using a TOAD-based switch with acceptable CR value.148 An AO-multifunctional logic circuit based on SOA-based polarization rotation switches enabled half adder, half subtractor, and comparator operations with high Q factor and 100 Gbps operating speed.149 A plasmonic-based design approach of AO-half adder used SPP logic gates based on interference phenomena achieved small footprint and high CR.150 Another plasmonic approach for realizing AO-full adder used MIM waveguides at 1550 nm with reduced losses and a transmission coefficient of 0.62.151 A design of AO-comparator was proposed based on QD-SOA-based AO-AND, NO, XOR gates and achieved ER>10  dB and Q factor of 9 with high speed operation.152 A structure for two’s complement generator based on XOR gates was implemented based on RSOA with high Q factor and CR.153

A further step toward the use of the above circuits is constructing an AO-arithmetic and logic unit (ALU). One approach utilized seven MRR structures and beam splitter to achieve efficient operation without any optical crossings in the design shown in Fig. 14.154 There have been several attempts utilizing to realize AO-ALU using SOA155 and TOAD;156 however, they possessed disadvantages such bulky dimensions and lack of integration capability for photonic integrated circuits (PICs).

Fig. 14

Design of AO-ALU using MRRs.154

OE_61_6_060902_f014.png

Another application of AO-LGs is in the design of AO-code converters. Many types of binary codes, such as binary-coded decimal (BCD) codes, gray codes, and American Standard Code for Information Interchange, are used in digital systems. A code converter improves the efficiency of the overall signal-processing unit. A method to implement all-optical frequency-encoded gray code conversions using SOA-based polarization switches was proposed with operating speed up to 600 Gbps.157 A 4-bit high-speed code converter utilizing two-photon absorption effect within microring resonators was designed at 1551 nm.158 XGM in RSOA was used to realize an optical gray code converter with high Q factor at 1555 nm.159 AO-binary-to-gray and gray-to-binary code converters were realized using linear interference effect in 2D photonic crystals to achieve good CR and low response time at 1550 nm.160 AO-code converter based on SOA-MZI was used to perform binary-to-gray, BCD-to-gray, and octal-to-binary conversions at 500 Gbps.161

AO-parity checker and generator circuits are realized using AO-XOR/NOT gates for error correction and detection applications in computing and communication systems. A 3-bit AO-parity checker and generator was implemented using 4 MRRs to achieve a high CR of 15.56 dB.162 Another attempt used AO-XOR gates based on linear interference of surface plasmon polaritons propagating in the plasmonic waveguides.163 A 3-bit integrated AO-parity generator and checker circuit were realized using SOA-MZI-based optical tree architecture at 10 Gbps.164

6.2.

AO-Sequential Circuits

AO-sequential circuits such as FFs, shift registers, and counters are realized using AO-LGs utilizing different techniques as detailed below. An AO-D FF was realized using MRRs with fast response time and small footprint.165 Polarization rotation-based MRRs were utilized to realize AO-D, T FFs with cascaded layout possible for further extension.166 A clocked D FF based on single GaAs-AlGaAs MRR achieved CR value of 16.53 dB.167 AO-SR FF was realized using nonlinear Kerr effect in photonic crystal cavities with a device size of 361  μm2 and maximum response time of 3.1 ps.168 Optical MRR-based switch was utilized to achieve easy and cascadable structures for AO-JK, SR, and T FFs.169

A design of AO-D FF and 2-bit down counter was proposed based on nonlinear effect in optical MRR to achieve satisfactory performance metrics.170 An AO-counter based on RS FF and AND gate was presented using cascaded stages of SOA fiber laser utilizing FWM effect.171 Two-photon absorption effect in silicon MRR was used to achieve the design of CMOS compatible AO-RS FF and 2-bit counter at 45 Gbps.172 An attempt to realize AO-two bit asynchronous up counter was proposed based on 2D PCRR-based RS FFs.173 A 4-bit AO-synchronous up counter was designed using electro-optic effect in lithium niobate-based MZI.174 An attempt to realize AO-Johnson counter was proposed utilizing XGM in SOA-based D FFs.175

AO-shift register have wide applications in optical packet buffers, serial-to-parallel converters, and synchronizers for all optical signal processing. A possible integrable structure for AO-shift register was proposed utilizing fiber loop-based AO-AND gate and optical buffer with multi-Gbps operation.176 Silicon MRRs were used to realize AO-universal shift register using two optical multiplexers and two optical D FFs.177

7.

Techniques/Principles for the Design of AO-LGs

The different methods of realizing various classifications of AO-LGs and their applications are covered in Secs. 23456. Here, a summary of the various working principles involved in these designs are presented briefly.

  • (a) XPM: It arises when two or more different optical signals travel through a nonlinear medium. Due to the dependence of the refractive index on the intensity of light, refractive index nonlinearity converts the optical intensity fluctuations in one particular wavelength signal to phase variations in the copropagating signal. The nonlinear refractive index changes experienced by an optical beam depend not only on the intensity of that beam but also on the intensity of other copropagating beams.

  • (b) Cross gain modulation: A gain saturation process takes place within the SOA when both a probe signal and strong pump signal are applied to the SOA due to the high pump signal power. The gain of the probe is also modulated when the pump signal power is modulated with data. Thus, the data get transferred from the pump to probe as the probe signal output power is modulated.

  • (c) FWM: It is an intermodulation phenomenon in nonlinear optics wherein two beams of light at different operating wavelengths produce two new wavelengths or three wavelengths produce one new wavelength. It is a phase-sensitive process and is widely used in wavelength converters.178

  • (d) Linear interference effect: It occurs when two beams undergo interference in a linear medium. Constructive interference occurs when two beams interfere by a phase difference of 2kπ (i.e., k=0,1,2) and destructive interference arises when two light signals have a phase difference of (2k+1) π (i.e., k=0,1,2).179

  • (e) Nonlinear Kerr effect: It is a nonlinear optical phenomenon that arises when light propagates in crystals and glasses. It is the change in refractive index caused by electric fields, the change being proportional to the square of electric field.180

  • (f) Plasmonic effect: It is the interaction between free electrons in metal nanoparticles and incident polarized light. Since light couples with the electrons, polarized light can be used to control the distribution of the electrons and the confinement of light occurs in a small dimension between metal and dielectric interface.181

8.

CAD Tools for Simulation of AO-LGs

Various CAD-based simulation tools are utilized to investigate the light propagation and analyze the various performance metrics of AO-LGs. For most of the design techniques, experimental analysis becomes too expensive or lacks feasibility due to complexity or nonavailability of equipment/materials. Based on existing works, the commonly utilized simulation platforms for the study of AO-LGs are described briefly.

The RSoft CAD environment enables the design of various passive and active optical components and circuits to study in detail its various material properties and analyze light propagation within them using various modules, such as BandSOLVE, FullWAVE, and BeamPROP. The BandSOLVE module performs band gap calculations for 1D, 2D, and 3D photonic crystal devices using the PWE method. FullWAVE module utilizes FDTD method to perform a detailed analysis of the light propagation within the variety of photonic devices using high speed simulations. The BeamPROP tool is based on BPM to simulate and analyze the behavior of complex and integrated waveguide devices for a variety of applications, such as sensing, WDM, etc.182 Another widely used simulation platform by researchers and engineers is COMSOL Multiphysics software for the modeling and analysis of devices in all areas of engineering with accurate results. There are a number of add-on modules corresponding to different fields of engineering, such as electromagnetics, structural mechanics, heat transfer, chemical engineering, and so on. The wave optics module under the section of electromagnetics modules has been widely used for the design of various optical components, such as waveguide couplers, plasmonic devices, optical fibers, photonic crystals, and so on. Several designs of AO-LGs based on photonic crystals, nonlinear effects, and plasmonic effects have been simulated using the above software with detailed analysis and accurate results.183

Optiwave Systems Inc. provides several products for photonic component level as well as system level design, simulation, optimization, and analysis for several research applications. The Optiwave Opti-FDTD software works on FDTD method to simulate various optical phenomena such as reflection, scattering, diffraction, polarization, and nonlinear effects in passive and nonlinear fiber optic components. It supports the testing and study of various components for applications such as CMOS sensor design, plasmonic designs, nanoparticle simulation, all-optical devices such as logic gates, couplers using photonic crystals, plasmonic waveguides, and so on.184 The Optiwave Optisystem software enables system level analysis for realizing various integrated optical circuits for applications such as optical networks (WDM, OTDM, SONET/SDH rings, OCDMA etc.), free space optics, all-optical signal processing, radio over fiber (RoF), and so on. It utilizes numerical analysis or semianalytical techniques for systems limited by intersymbol interference and noise. Most of the SOA-based design of AO-LGs utilizing nonlinear effects have utilized the above software for simulation and analyzed various performance metrics with a system-level perspective.185 For the analysis is of more complex waveguide devices, the Optiwave OptiBPM software based on BPM has been utilized. It has been used for several applications such as design of nonsymmetrical waveguide structures, couplers, splitters, sensor structures, rib or ridge waveguide design, and so on. Several designs of AO-LGs based on MZI have combined MATLAB with OptiBPM software to study the wave propagation within such structures.186

Another widely used simulation software for FDTD simulations is MIT electromagnetic equation propagation (MEEP), which is an open-source software developed at the Massachusetts Institute of Technology (MIT). It has been utilized to design photonic crystal-based all-optical devices, such as multiplexers, logic gates, splitters, and so on. Another similar open-source software for computing photonic band structures or dispersion relations of periodic dielectric structures is the MIT photonic bands (MPB).187 Another highly efficient simulation tool for 2D/3D Maxwell’s solver is Lumerical FDTD for the analysis and design of nanophotonic devices. It enables accurate modeling of photonic components for a broad range of applications, such as surface plasmonics, photonic crystals, solar cells, metamaterials, and so on. A summary of the various CAD tools used for the design of AO-LGs is shown in Table 7.

Table 7

Summary of the various CAD tools for simulation of AO-LGs.

Simulation toolModeling technique/methodPaper
RSoft CAD FullWAVEFDTD1, 54, 57, 60, 64, 65
RSoft CAD BandSOLVEPWE1, 54, 57, 59, 60
RSoft CAD BeamPROPBPM44 to 46
COMSOL MultiphysicsPhysics-based modeling, equation-based modeling68, 71, 72
Optiwave Opti-FDTDFDTD83
Optiwave OptisystemNumerical analysis or semianalytical techniques4, 5, 13, 17
Optiwave Opti-BPMBPM31
MEEPFDTD56, 66
MPBPWE56
Lumerical FDTDFDTD69

9.

Toward Photonic Integrated Circuits

In the current scenario, the existing communication systems are still operating on digital electronics and hybrid optoelectronic systems. However, due to the electronic bottle neck problem caused by the O/E/O conversions, there is a lack of complete utilization of optical transmission capacity of optical fibers in the existing fiber optic communication systems. Majority of the existing devices still require some O/E/O conversion for their operation and hence most of them are electro-optic devices and cannot be called all-optical devices. The idea of all-optical signal processing system/device requires all the operations to be performed completely in the optical domain without any conversions into electrical signals.

A truly optical system will consist of PICs similar to electronic integrated circuits wherein a large number of optical devices are integrated on a single chip.188 A lot of research is being done on PICs in recent years to realize all-optical systems/devices.189 With the evolution of PIC technology, many platforms have been developed such as SOI, SiN, InP, silica, and so on for specific requirements. PICs have attracted other applications beyond telecom/datacom, such as biomedical, Lidars, sensing, quantum processing, Lidars, 5G backhaul, among others.190,191 Recently, silicon photonic integrated circuits have emerged as highly suitable candidates for all-optical systems owing to their ease of fabrication, ability for high density integration, and compatibility with the existing CMOS-based systems.192 The two main platforms based on silicon for PICs are thin and thick SOI.

The selection of a suitable platform for PICs that can be used universally without compatibility issues is one of the existing challenges in the design of all-optical systems. Another challenge is the enabling of efficient coupling of light signals from the optical fiber backbone to the PICs. To overcome this issue, highly efficient and compatible coupling structures with compact dimensions and cost-effective fabrication need to be developed.193,194 The design automation challenges associated with the integrated photonics device design also need further development. Some of the challenges that need to be addressed when moving from electronics to photonic design include the curvilinear layout, since photonic structures require smooth curves and bends for routing light to enable confinement; photonic circuit analysis capable of understanding the unique characteristics of photonic components; and new process design kits (PDKs) with additional features along with improved verification methodologies and tools.195 Hence, to meet the unique challenges of PIC design, dedicated photonic simulation and layout capabilities are needed.

10.

Conclusion

AO-LGs are the crucial elements that play a pivotal role in various applications, such as all-optical computing, telecommunication, optical signal processing, and so on. Hence, the various design aspects of AO-LGs such as principle of operation, multiwavelength operation, power consumption, and miniaturization are of utmost interest to researchers and scientists working in various domains. The demand for high speed and miniaturization requires a fully optical integrated network with all-optical components, such as logic gates, encoders, decoders, and so on. The current requirement calls for all optical logic gates with high CR, low response times, reduced power consumption, small footprint, reversible operation, and flexible, robust designs with compatibility with hybrid electro-optic as well as fully OICs. The various classes of AO-LGs available in the literature are carefully reviewed and the research gaps are identified and concluded. Photonics and plasmonics are the current technologies driving the design of all-optical logic devices. Several other upcoming technologies such as topological photonics and AI-based designs have provided improved performances; however, their computation times, complexity, and practical implementation aspects need further studies.

Acknowledgments

This research did not receive any specific grants from funding agencies in the public, commercial, or not-for-profit sectors. The authors declare that they have no conflict of interest.

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Biography

Erandathara Gokulan Anagha received her master’s of engineering degree in communication systems from Vellore Institute of Technology, Vellore, Tamil Nadu, India, in 2018. She is currently working toward her PhD at the Department of Electronics and Communication Engineering, National Institute of Technology, Tiruchirappalli, India. Her research interests include all-optical devices, photonics, and optical communication.

Ramasamy Kandasamy Jeyachitra received her master’s of engineering degree in microwaves and optical engineering from Alagappa Chettiar College of Engineering and Technology, Karaikudi, Tamil Nadu, India, and her PhD in information and communication engineering from Anna University, Chennai. In 2007, she joined the National Institute of Technology (NIT), Trichy, India, where she is now an associate professor in the Department of Electronics and Communication Engineering. She has several years of research experience in the areas of advanced communication systems. Her research interests include information and communication systems, microwave/millimeter-wave photonics, optical wireless communication, RoF, optical communication, artificial intelligence in optical communication, optical logic gates, and PCFs. She is a life member of the Institution of Engineers (IE), Indian Institution of Electronics and Telecommunication Engineers (IETE), and Indian Society for Technical Education (ISTE). She has reviewed books and acted as a reviewer for several refereed international journals, such as IEEE MTT, IEEE Access, IEEE Communication Letters, and Springer Telecommunications. She also serves on the technical program committee for IEEE international conferences.

© 2022 Society of Photo-Optical Instrumentation Engineers (SPIE)
Erandathara Gokulan Anagha and Ramasamy Kandasamy Jeyachitra "Review on all-optical logic gates: design techniques and classifications – heading toward high-speed optical integrated circuits," Optical Engineering 61(6), 060902 (25 June 2022). https://doi.org/10.1117/1.OE.61.6.060902
Received: 25 February 2022; Accepted: 24 May 2022; Published: 25 June 2022
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KEYWORDS
Photonic crystals

Logic devices

Logic

Computer aided design

Waveguides

Chromium

Photonics

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