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Review

Research Progress on Router Devices for the OAM Optical Communication

by
Binbin Wang
1,2,†,
Xizheng Zhang
3,†,
Jinlong Tian
1,
Badreddine Merabet
1,
Zhixiang Li
1,
Syed Afaq Ali Shah
1,*,
Yi Lei
1,
Bingyi Liu
1,
Kai Guo
1 and
Zhongyi Guo
1,*
1
School of Computer and Information, Hefei University of Technology, Hefei 230009, China
2
School of Mechanical Engineering, Hefei University of Technology, Hefei 230009, China
3
School of Materials Science and Engineering, Hefei University of Technology, Hefei 230009, China
*
Authors to whom correspondence should be addressed.
These authors contributed equally to this work.
Sensors 2024, 24(3), 944; https://doi.org/10.3390/s24030944
Submission received: 27 December 2023 / Revised: 19 January 2024 / Accepted: 26 January 2024 / Published: 1 February 2024
(This article belongs to the Special Issue Novel Technology in Optical Communications)
Browse Figures
Versions Notes

Abstract

:
Vortex beams carrying orbital angular momentum (OAM) provide a new degree of freedom for light waves in addition to the traditional degrees of freedom, such as intensity, phase, frequency, time, and polarization. Due to the theoretically unlimited orthogonal states, the physical dimension of OAM is capable of addressing the problem of low information capacity. With the advancement of the OAM optical communication technology, OAM router devices (OAM-RDs) have played a key role in significantly improving the flexibility and practicability of communication systems. In this review, major breakthroughs in the OAM-RDs are summarized, and the latest technological standing is examined. Additionally, a detailed account of the recent works published on techniques related to the OAM-RDs has been categorized into five areas: channel multicasting, channel switching, channel filtering, channel hopping, and channel adding/extracting. Meanwhile, the principles, research methods, advantages, and disadvantages are discussed and summarized in depth while analyzing the future development trends and prospects of the OAM-RDs.

1. Introduction

In recent years, with the continuous development of the modern information industry and the rapid growth of large traffic consumable businesses, such as the Internet of Things, cloud computing, e-commerce, and online gaming, there has been an increasing demand for high-speed and large-capacity communication among people. This trend is expected to pose a significant challenge to existing communication technologies [1,2,3,4,5]. In the field of free-space optical communication, multi-dimensional multiplexing technologies, such as wavelength-division multiplexing (WDM), polarization-division multiplexing (PDM), and time-division multiplexing (TDM), are commonly employed to enhance system capacity, along with advanced signal modulation techniques, such as quadrature amplitude modulation (QAM), pulse position modulation (PPM), and multi-phase shift keying [6,7,8,9,10]. However, in recent years, the development of these resource dimensions has nearly reached its limits. Network bandwidth has gradually become a bottleneck, and capacity crisis remains a significant challenge for optical communication. Therefore, expanding the communication system’s capacity has become an urgent problem to be addressed in the field of communication [11]. At present, a novel research concept involves utilizing spatial dimensions for multiplexing. Among these dimensions, orbital angular momentum (OAM) stands out as a distinct degree of freedom from polarization, amplitude, phase, frequency, and time due to its exceptional advantages in terms of transmission speed, capacity, and stability. As such, OAM has become the primary focus of current research [12,13,14,15,16,17].
In 1992, Allen et al. [18] experimentally verified that a beam with a helical phase wavefront carries the OAM. The most common type of OAM beam in optical communication systems, the Laguerre–Gaussian (LG) beam’s field distribution, can be mathematically expressed as follows [19]:
u L G ( l , p ) r , φ , z = 2 p ! π p + l ! 1 w z r 2 w z l L p l 2 r 2 w 2 z × exp r 2 w 2 z i k r 2 z 2 R z × exp i 2 p + l + 1 tan 1 z z R exp i l φ
where l is referred to as the topological charge or OAM mode value, indicating the number of wavefront rotations within one wavelength propagation distance; p is the radial indices; λ is the wavelength; k = 2 π / λ is the wavenumber; w ( z ) = w 0 1 + ( z / z R ) 2 represents the Gaussian beam radius, in which w 0 is the beam waist and Z R = π w 0 2 λ is the Rayleigh range; L p l ( ) represents the generalized Laguerre polynomial; and ( 2 p + l + 1 ) tan 1 ( z / z R ) is the Gouy phase. Due to the existence of a phase singularity in the center of the beam, the distribution of the vortex annular field intensity is 0. This type of beam is commonly referred to as an OAM beam or vortex beam [19,20,21,22,23]. The helical phase structure characteristics of a vortex beam are determined by the phase factor exp(ilφ), [24,25,26]. φ represents azimuths, with each photon in a vortex beam carrying an OAM of (where ћ is Planck’s constant divided by 2π) [27,28,29]. Theoretically, any value of l can be selected, and OAM beams carrying different topological charges are mutually orthogonal [30,31,32]. These exceptional qualities of OAM have guaranteed promising results in addressing the problem of low information capacity in optical communications. With the advancement of OAM optical communication technology, OAM router devices (OAM-RDs) have played a key role in significantly improving the flexibility and practicability of communication systems. Therefore, the multiplexing of OAM beams with different topological charges without interference is possible, which provides a potential solution to the capacity crisis in optical communication. Currently, the OAM beam exhibits a vast range of potential applications in the fields of optics [33,34,35,36,37,38,39,40], electromagnetism [41,42,43,44,45,46,47,48,49,50], acoustics [51,52,53,54,55,56,57,58,59,60], and mechanics [61,62,63], thus garnishing significant attention from researchers.
In the field of optical communication, the applications of OAM beams mainly include two areas: OAM-shift keying (OAM-SK) [64,65,66,67,68,69,70,71] and OAM-division multiplexing (OAM-DM) [72,73,74,75,76,77,78,79]. OAM-SK is a mapping technique that assigns digital signals to differentiate OAM beams based on the unique value of each OAM mode (with each mode representing a data bit). Meanwhile, OAM-DM utilizes the carrier of an OAM beam to modulate signals and achieve channel multiplexing via the orthogonality between various beams, resulting in exponential increases in the channel capacity [80,81,82]. For a mature OAM optical communication system, the manipulation and transformation of different channels play a crucial role in enhancing the flexibility and practicality of the system [83,84,85]. Currently, the research focus in OAM optical communication lies in the development of routing technology that enables end-to-end signal transmission path transformations [86,87,88,89,90,91]. Therefore, extensive research and development have been conducted on the OAM router devices (OAM-RDs) with significant performance enhancements [92,93,94].
This review focuses on the field of OAM-RDs and provides a detailed account of recent advancements in OAM router schemes, which are centered around OAM-RDs that enable channel multicasting, channel switching, channel filtering, channel hopping, and channel adding/extracting functionalities, as illustrated in Table 1. Finally, this study also summarizes the research process of OAM-RDs while examining their potential for future development.

2. OAM Channel Multicasting

In OAM-based optical communication networks, the transmission efficiency of OAM communication links can be greatly expanded by the selective manipulation of different data channels. One such OAM router device (OAM-RD) realizes OAM multicasting by dispersing a single channel into multiple channels and then transmitting data information from a single channel to multiple channels. These channels are orthogonal to each other and can serve different users in multi-user communication so as to better adapt to the multi-user environment. At present, multicast technology is widely used in traditional optical communication and OAM optical communication [95,96,97,98,99,100,101,102]. For an OAM optical communication system, the OAM-RD, which can realize the OAM multicasting, plays an important role [103]. In 2012, Yan et al. proposed a method of spatial mode multicasting in OAM mode spatial division multiplexing [104]. As depicted in Figure 1a, a quadrature-phase-shift-keyed (QPSK) optical signal is transmitted from a single-mode fiber to a fiber collimator. During the OAM mode multicasting stage, when an OAM beam with input topological charge l encounters an angular-amplitude aperture with n-order rotational symmetry, it can be assigned to a multi-OAM beam with equally spaced OAM topological charges [105]. For coherent detection, one of the multicast channels is demultiplexed and then coupled to a single-mode fiber. First, the Gaussian beam emitted from the collimator is transformed into an OAM beam using a spatial light modulator (SLM) loaded with a helical phase distribution to generate a single OAM channel. And then, the input single OAM channel is converted into a superposition of multiple OAM channels using a specially designed slicing phase pattern on SLM-2. SLM-3 is utilized for demultiplexing one of the multicasting channels. After demultiplexing, the beam passes through a pinhole and then couples into a single-mode fiber for coherent detection. Subsequently, this research group demonstrated through experiments that their proposed method can produce up to eight multicast modes with uniform power and less than −20 dB crosstalk, and the power loss induced by the multicasting is only 0.3 dB, as shown in Table 2. The significant advantage of this scheme is that it can generate the required OAM modes while maintaining a low power loss. However, multiple optical devices are needed in the experimental process, and the device integration is relatively low.
In real-world applications, beam power requirements may vary for different users. To address this issue and to improve the overall transmission efficiency, in 2015, Li et al. [106] proposed a multicast scheme with adjustable power by employing a specially designed complex phase pattern to enable the generation of composite beams with multiple OAM modes superimposed with adjustable success rates. In 2022, Almaiman et al. [107] presented a novel approach to creating tunable optical tapped-delay-lines (OTDLs) based on the OAM modal domain. This method leverages OAM mode multicasting to generate the necessary taps, thereby enabling flexible and efficient tunability. Figure 1b illustrates the fundamental concept behind the tunable OTDL, which relies on mode-dependent delays to perform the functions of correlation and equalization on a QPSK data signal. Specifically, the input optical beam carrying a QPSK data signal s(t) in the fundamental Gaussian mode is fed into the OTDL system. The input signal in the tunable OTDL system can consist of either pattern symbols [A, B, C, D] or a QPSK signal constellation that is distorted by chromatic dispersion. The OTDL adopts a multi-step approach: first, the system creates the input signal taps by multicasting into different OAM modes (l1, l2, , lN), where N ∈ [1, 2, …, ∞). Second, each of the replicas in the OAM domain is an assigned amplitude and phase coefficient corresponding to a specific tap (h1, h2, …, hN). Finally, the taps are differentially delayed using a mode-dependent delay subsystem (0, T, …, (N − 1) T), allowing for precise temporal control of the signal, and the taps are combined to provide the output k = 1 N h k × s t k 1 T in the fundamental mode. Subsequent experiments were conducted to validate the equalization function of the proposed system using a 20 Gbaud QPSK signal as input and subjecting it to 336–1008 ps/nm of chromatic dispersion. The results demonstrate that the system can significantly improve the signal quality, reducing the error vector amplitude (EVM) from 25.4% to 12.9% in the presence of 336 ps/nm chromatic dispersion, as depicted in Table 2.
In order to further increase the channel utilization rate, in 2022, Shang et al. [108] proposed a multiplexed vortex state array consisting of multiple multiplexed vortex beams, which allows for flexible manipulation of both the spatial position and the corresponding OAM spectrum as desired (Figure 1c1). Then, employing an array as a data-carrier, the research group demonstrated a one-to-many multicasting link through multi-state OAM shift keying, where four various states were utilized to encode a four-bit symbol, achieving high-dimensional encoding; the experimental setup is shown in Figure 1c2. The Gaussian beam generated by a distributed feedback laser diode is converted into a horizontal linear polarization state by a half-wave plate (HWP) and a polarization beam splitter (PBS), and then the multicast OAM is encoded by a specially constructed phase-only liquid-crystal SLM. SLM1 is employed to carry out multicast OAM encoding. By switching holograms loaded on SLM1 continuously, a coded time-varying multiplexed vortex state array sequence is generated, which records the input signals. The array contains three diffraction orders. Regarding every diffraction order as a channel, there are three channels to send information, which are labeled as channel 1 to channel 3. After propagating 1.5 m in free space, the three encoded multiplexed vortex beams are received and decoded by three identical receivers consisting of an SLR camera, a lens, and an infrared CCD camera. In a subsequent demonstration, the research group generated different grayscale images from one transmitter to each of the three receivers. The results showed that the images received by each receiver were basically consistent with the transmitted signals, and the total bit error rate(BER) of the three channels was only 4.16 × 10−4, indicating successful multicasting of various signals, as presented in Table 2.
Although the aforementioned methods achieved promising results, the overall complexity of the spatial frequency distribution increases considerably with an increase in the number of multiplexing channels. This adversely affects the hologram generation for multiplexed vortex beams, resulting in an increase in the OAM spectrum error. Therefore, a tradeoff is made between the bit error rate (BER) and the number of multiplexed channels. To address the above problem, in 2023, Meng et al. [109] reported a unique concept of OAM neural communication employing a network model based on a U-net neural network (Figure 2a) to transform the complex amplitude transmission functions into phase-only holograms (Figure 2b) [109]. The phase-only hologram predicted by their proposed network model generated a high-precision OAM spectrum for OAM multicasting with OAM-SK using only a few training datasets. At the transmitter, the information is sent to multiple users simultaneously when a beam of light passes through the hologram. Based on OAM-SK, the data at each user are encoded, and four different OAM states are selected to represent a 4-bit symbol, as can be seen in Figure 2a. Gray is used for a 0 weight OAM state, whereas OAM state 1 is represented by white. Decoding is performed at the receiver using a well-designed multiplexed OAM phase plate. A gray-scale algorithm measures the relative power of the four regions and translates it into the corresponding data. By switching holograms in the time sequence, real-time OAM optical communication can be achieved because, once trained, the network model can realize the noniterative calculation of all input signals. The hardware refresh time indicates the switching interval. To experimentally demonstrate the proposed concept, Meng and coworkers established 1-to-40 multicasting with 16-ary shift keying in OAM communication and achieved the encoding and decoding of 40 images with 16 gray values with a BER of 0 following a 3 m free space transmission.
Using the design of various OAM-RDs and related technologies, starting from the one-to-many multicast link in an ideal environment to the multicast link under diverse practical conditions, the OAM channel’s multicast technology has gradually matured. This is highly significant for reducing data congestion and enhancing efficiency and performance through multi-user data multicast. In addition, with the continuous development of hardware technology, the number of OAM multicasting channels has greatly increased, which is advantageous for its application in the network [110,111,112]. Thus, the OAM multicasting routers have become one of the important devices in today’s complex optical communication networks and have broad development prospects. Table 2 summarizes the representative works reported to date for the channel multicasting routers in OAM-based optical communication.

3. OAM Channel Switching

For the OAM optical communication system, it might be useful to extend the employment of an OAM-based communications link in a multi-user environment, in which different OAM data channels could be selectively manipulated. One of the OAM-RDs that can realize channel switching plays an important role [113,114,115,116,117,118,119]. In 2013, Yue et al. [120] experimentally demonstrated OAM-based reconfigurable optical switching functions when multiple OAM modes were used by switching n input modes with arbitrary OAM charges to n OAM modes with a desired number of charges. The concept of OAM-based reconfigurable optical networking functions can be described in parts “Charge shift”, “Charge exchange”, and “Charge selective manipulation”. “Charge shift” can realize the m-l shift of all OAM modes by using an SLM with topological charge m-l and a mirror. “Charge exchange” can reverse the order of OAM modes by using only one SLM, thus realizing the information exchange between the two OAM modes. “Charge selective manipulation” combines the functions of “Charge shift” and “Charge exchange” to easily manipulate the number of OAM modes using two SLMs without affecting the OAM of other modes. By effectively concatenating these three functions, it is possible to reposition any input of N OAM modes to any desired output state. Then, the team experimentally verified the feasibility of this OAM-based reconfigurable optical networking function system. In multi-pair OAM mode switching, the average conversion efficiency is −3.6 dB. At a BER of 2 × 10−3 (enhanced FEC (EFEC) threshold), the average OSNR penalties for the channels before and after exchanges are 1.5 dB and 2.4 dB, respectively. This research content has a very important influence on the OAM optical communication industry, and provides a new idea for the subsequent research in the design of router parts, as shown in Table 3
Low-cost channel switching can also be realized by directing two composite vortex beams with different data and OAM mode values of l1 and l2 on a reflective SLM loaded with an OAM mode value of lR = −(l1 + l2). This converts the OAM mode values to −l2 and −l1 [121]. Taking the research further, Ahmed et al. [122] investigated a reconfigurable OAM channel switch with a 2 × 2 layout in 2013. The group experimentally demonstrated that multiplexed OAM beams can be selectively re-sent to different outputs by using multiple SLMs to first split the separated beams in space, followed by rerouting the separated beams. A schematic of the 2 × 2 OAM switcher that can either pass or redirect each input OAM beam can be seen in Figure 3a. Initially, the multiplexed input beam is converted into a Gaussian-like beam. At this time, the mode values of other OAM beams also change accordingly. After that, the OAM beam and the Gaussian beam are separated in space by employing a specially designed beam control phase mode, and the coaxial recombination of the Gaussian beam and OAM beam on another path is realized. Finally, the composite beam’s mode up-conversion is accomplished using the programmable SLM. In order to complete the mode up-conversion of the composite beam and the switching of the dual OAM channels, the center and peripheral phases of the composite beam correspond to distinct OAM modes. This allows the Gaussian beam to be restored to an appropriate OAM beam. The research group applied two multiplexed beams with OAM modes of l = +4, −4, and l = +2, −6, respectively, to input ports A and B. After system switching, the two multiplexed beams could complete the arbitrary switching of the OAM mode, and the signal-to-noise ratio was less than 2.5 dB, as presented in Table 3.
In addition to channel switching between the different OAM modes, the researchers then focused on spatial location switching. In 2016, Liu et al. [123] proposed a reconfigurable OAM mode-switching and spatial-switching scheme. By using multiple SLMs, this scheme realized the arbitrary control of the output position of the beam space while regulating the mode value of the input OAM beam. Thus, the tasks of OAM mode switching, space switching, joint OAM mode, and space switching can be completed in synch with each other. The experimental settings are shown in Figure 3b. Four channels transmit four different OAM beams generated by SLM1–SLM4 to specific locations in the spatial domain, which are then collected by three unpolarized beam splitters, BS1–BS3. BS1 collects the beams from SLM1 and SLM2 and splits them horizontally, whereas BS2 collects the beams from SLM3 and SLM4 and splits them horizontally. SLM5 emulates a 4 × 4 switching node. The four input ports of the switching node are linked to the four OAM channels after BS3, and the four output ports are projected onto a camera for monitoring. Thus, 4 × 4 OAM mode switching, space switching, and joint OAM mode and space switching are realized. This scheme further expands the utilization range of the optical networks and improves the flexibility of network control, as illustrated in Table 3. However, the use of multiple SLMs in the process increases the difficulty of loading phase designs on different SLMs and increases the system complexity and device cost to a certain extent. This has certain constraints on the high-speed optical communication link system, which requires high real-time and economic performance.
Very recently, Wu et al. [118] proposed a unique concept of multi-channel (OAM) mode switching based on an in-fiber mode selective interferometer (MSI) formed in a four-mode fiber. The MSI is made up of two strongly modulated long-period fiber gratings (LPFGs), which realize the mode switching between the selected mode pair (OAM0 and OAM2). By applying torsion to the MSI, the propagation constant of the two resonant modes will change, resulting in the control of the phase difference between both modes to switch at multiple channels. The experimental setup and the schematic diagram of the multi-channel MSI can be seen in Figure 3c and Figure 3d, respectively.
The majority of the reports discussed above use SLM to realize the function of OAM routing. Although the OAM beam generated by SLM has advantages in terms of conversion efficiency and energy consumption reduction, the switching speed is limited by the material properties of the device itself. In 2017, Lei et al. [124] proposed an OAM-RD that used digital micromirrors instead of SLMs. They applied the device to an optical communication link system based on the data interconnection of OAM selection, as shown in Figure 4a. The optical router uses a binary grating driven by a digital micromirror to break the correspondence between the traditional OAM mode and diffraction order and can not only realize the mutual switching of input OAM modes but also ensure the function of multicast. In general, the scheme achieves the routing function of OAM channel switching well and also utilizes the advantage of a digital micromirror to greatly improve the switching speed, as shown in Table 3. In 2018, an OAM wavelength switch exploiting four OAM modes and four wavelengths was demonstrated by exploiting an integrated OAM multiplexer with four concentric waveguides, which allows for four input ports [125]. In 2021, Chen et al. [126] proposed an optical separation device composed of an SLM and a double-area mirror. They used On–Off Keying (OOK) to modulate four channels to form two inputs, channel A and channel B, each channel with two multiplexed OAM beams. An SLM was utilized to modify the OAM-multiplexed beams in each channel, with one of the beams being transformed into a Gaussian beam. The Gaussian beam was separated by a double-area mirror, thus enabling the switching of the beams carrying different data in the two channels. Figure 4b1 shows the principal architecture of a 2 × 2 OAM switcher. The double-area mirror is composed of two different mirrors. One was placed in the central region to reflect the Gaussian beam and the other in the outer region to reflect the OAM beam. Therefore, the separation of the Gaussian beam and OAM beam can be realized only by adjusting the angle between the inner and outer regions of the double-area mirror. As shown in Figure 4b2, two multiplexed beams with OAM modes of l1, l3s and l2, l3 were applied to input ports A and B, respectively. One beam at each input port was replaced with a Gaussian beam, and the other beam, still carrying the OAM state, passed through the double-area mirror for beam separation. The Gaussian beams extracted from channel A and channel B were introduced into the OAM beams of the other channels, creating mutual coupling. The reconstituted beam was coaxially transmitted and added at the corresponding phase to convert the multiplexed beams of channel A and channel B into the initial topological charge state, thus enabling the data interchange carried by the beam. The proposed method has the advantages of a simple structure, low cost, easy integration, and large angle separation, and can be applied to various OAM reconstruction scenarios, as depicted in Table 3. This facilitates a large-scale flexible OAM network construction.
Although the reported works above achieved promising results, a significant breakthrough in OAM switching was reported by Scaffardi et al. in 2023, reporting a 10 OAM × 16 wavelengths two-layer switch for 19.2 Tb/s data traffic using an integrated mode multiplexer [127]. They employed a 16-channel wavelength division multiplexing (WDM) grid, which enabled the switch to receive 160 optical Gaussian data inputs and route each input signal to a distinct output port, all of which take advantage of 10 OAMs. The foundation of this optical switch is built on an integrated OAM multiplexer and a tiny OAM demultiplexer. When verified experimentally, a 19.2 Tb/s total enabled throughput is made possible by each port’s 30 GHz bandwidth. The switching time is observed to be less than 1 μs. Since the OAM demux is passive, the OAM switch power consumption is 1.35 mW/Gb/s, which may be entirely attributed to the thermal tuning of the OAM emitters. This is advantageous compared to single-layer switches that cascade elementary blocks, such as 2 × 2, in order to achieve enormous port counts that increase in proportion to the square of the number of ports. The switch is compatible with standard telecom devices because it accepts input and output signals with Gaussian phase profiles that pass through optical fibers and waveguides.
At present, most OAM routers that can realize channel-switching functions switch the data information transmitted by different channels by controlling the change in the OAM beam mode value. In the past, the OAM switcher could switch data between two OAM beams, but with the continuous development of OAM multiplexing technology, the OAM switcher can now switch data between multiple composite beams [125,126,127]. With the development of OAM-RD, the flexible control of the OAM mode carried by multiplexed beams and the practicability of OAM communication links have been greatly improved, which lays a foundation for the research of OAM-RD. Table 3 summarizes the works reported to date for the channel-switching routers in OAM-based optical communication.

4. OAM Channel Filtering

According to different applications, users have different requirements for channels where different OAM beams are located. When users have requirements for specific channels in multiplexed OAM communication links, it becomes increasingly urgent to study the filtering technology that filters out useless channels and only extracts specific channels according to the requirements [128,129,130,131,132,133]. Using the optical geometric transformation, Huang et al. [134] presented an OAM-RD in 2014 that could implement OAM filtering as can be seen in Figure 5a. The filtering operation works as follows: first, the light from the laser source is collimated and incident on SLM1, which has been pre-loaded with phase holograms designed to produce multiple superimposed OAM modes. The resulting OAM beam is sent into an OAM filter consisting of an SLM to control the light plate and a mode converter made up of two reflective elements used to convert phases. Based on the principle of optical geometric transformation, after the multiplexed OAM beam passes through the mode converter, the original annular distribution of light intensity is converted into a series of strip light spots whose distribution corresponds to the OAM mode value one by one. The light spot is then brought into focus on the focal plane using a convex lens. At various positions, the light spot can be selectively controlled using the SLM. The spot of OAM beam filtering required by the target is blocked and reflected at the same time. Finally, based on the principle of optical geometric inversion, the reflected light spots are recovered from the light spots to the normal annular OAM beam, and the beam splitter is used to separate them. Thus, the filtering operation of the required OAM beam components in the composite OAM beam is completed. The group experimentally demonstrated that the blocking mode and propagation mode output power suppression ratios are greater than 14.5 dB. However, when the mode value interval of the input composite OAM beams is 1, the light spots will overlap following geometric transformation, which results in considerable difficulty in subsequent filtering. This is because of the inherent limitations of optical geometry transformation.
In order to further optimize the OAM multicast filter element and change the fixed relationship between diffraction order and OAM mode in the traditional computational hologram, in 2016, Gao et al. [135] proposed a new routing scheme based on OAM-labeled. First, several Gaussian beams are incident at specific incidence angles to reach the Dammann optical vortex grating (DOVX), so as to ensure multiple coaxial OAM beams of different OAM beams are generated at the outgoing end. The receiver incident the OAM beam into a specially designed computer-generated holograph (CGH). By taking the relative root-mean-square error as the evaluation factor of the hologram, the pure phase transmittance function is optimized using the iterative method, and the phase distribution of the CGH is dynamically controlled. Multiple OAM beams are reconverted into Gaussian-like beams by using a CGH, which can then be routed to different output ports. These OAM-labeled beams can be manipulated through direct connection, switching, multicast, and filtering functionalities. These routing functions can be realized by reconstructing CGH. The team verified the OAM filtering in the subsequent experiments, and the experimental results are highly consistent with the theoretical results, and the blocked output port power is suppressed by more than 23 dB by the filter, as shown in Table 4.
In order to realize the high-fidelity output of OAM mode, in 2019, Li et al. [136] combined the advantages of the interferometer and proposed another novel OAM filter using the interferometer. In this scheme, multi-beam interference filtering is realized by controlling the relative phase difference in the different OAM beams. The principle is shown in Figure 5b. First, the polarized beam splitter (PBS) is used to divide the input n OAM multiplexed beams into n equal parts, and then the relative phase difference in the different OAM beams is controlled by the Dow prism. Additionally, a half-wave plate (HWP) is utilized to counteract the half-wave loss due to the reflection at each branch interface. Moreover, a series of phase compensators are placed to adjust for the phase discrepancies arising from the different optical path branches. Since the relationship between OAM mode and phase difference satisfies θ = 2πl, only a specific OAM mode value can achieve 100% passing, while other OAM modes will be suppressed, so as to realize the OAM filtering function as presented in Table 4. This filtering reduces the overlapping effect of adjacent OAM modes and improves the filtering effect. It can be used in the fields of single photon recognition and optical switching.
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Figure 5. Principle or experimental setup of OAM-RDs based on OAM channel filtering: (a) the tunable mode-blocking filter [134]. (b) Schematic diagram of OAM filter based on multiple-beam interference [136]. (c) Schematic diagram of the transmission loss in the righthanded CLPG [137].
Figure 5. Principle or experimental setup of OAM-RDs based on OAM channel filtering: (a) the tunable mode-blocking filter [134]. (b) Schematic diagram of OAM filter based on multiple-beam interference [136]. (c) Schematic diagram of the transmission loss in the righthanded CLPG [137].
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In 2022, Rao et al. [137] proposed and experimentally demonstrated a chiral long-period fiber grating (CLPG)-based scheme for filtering spin-entangled OAM of photons by utilizing the inherent spiral characteristics of a CLPG. The authors demonstrated both theoretically and experimentally that co-handed OAM, characterized by the same chirality as the helical phase wavefront of a CLPG, couples with higher-order cladding modes and experiences a loss. Conversely, cross-handed OAM with the opposite chirality propagates freely through the CLPG. To input |L, 1〉 and |R, −1〉, for example, on the right side of CLPG, a transmission loss is observed, as shown in Figure 5c. Since the spatial light coupling at the input end to the fiber will inevitably excite the fundamental mode (HE11), there will be not only the input vector vortex beam (VVB) but also the HE11 mode in the grating. In addition, the excited HE11 mode will be coupled with the cladding HE21 mode, and the loss will occur near the resonant wavelength. The HE11 modes excited by input |L, 1〉 and |R, −1〉 are the same. Excluding the loss from HE11 coupling, there will be no extra loss as the input VVB |L, 1〉 will freely pass, while the input VVB |R, −1〉 will couple to the cladding mode and suffer loss. Therefore, VVB |R, −1〉 will suffer more loss than VVB |L, 1〉 and their difference is the loss caused by chirality selected VVB |R, −1〉 coupling. Thus, the filtering function is realized. In contrast to an OAM filter based on twisted photonic crystal fiber, the CLPG-based scheme has the advantages of narrow bandwidth and wavelength selectivity. In contrast to the OAM filters based on spatial optical devices, the CLPG-based scheme has the advantages of small size and good compatibility with the existing fiber-based OAM applications, which is promising for all-fiber OAM multiplexing communications, as illustrated in Table 4.
The OAM filter routers can filter out unnecessary OAM beams via the selective filtering of multiplexed OAM beams, which meets the requirement of channel filtering of specific nodes in optical networks [138,139,140]. Initially, the OAM filter components only filtered OAM beams with large mode spacing. However, it is now possible to carry out high-fidelity filtering for any OAM beam, which has a broad application prospect in future optical communication networks. Table 4 summarizes the works reported to date for the channel filtering OAM-based optical communication routers.

5. OAM Channel Hopping

There are various types of OAM-RD, and in addition to the numerous categories mentioned above, a device capable of channel hopping has gradually come into view [141,142,143,144]. This device can be used in a reconfigurable multiple-access network to output different OAM modes at different time windows. Willner and coworkers proposed the channel-hopping OAM-RD in 2015 [145]. Its working is similar to frequency hopping in conventional transmissions and can be realized by controlling the hop mode controller to output the desired OAM mode for a specific time from a particular output port (Figure 6a). In this scheme, the use of a digital micromirror instead of an SLM effectively improves the speed of channel hopping and can be used to arbitrarily route data streams based on the spatial pattern occupied by the channel in a multi-access optical network. Willner and group succeeded in performing reconfigurable hopping of a QPSK data channel at a rate of 100 Gbit/s (with a switching protection time of 2 ns), with a signal carrying four OAM modes keeping the power loss below 5.3 dB.
In order to achieve efficient channel hopping performance of OAM communication in 2018, Liang et al. [146] combined the mode hopping (MH) scheme with the traditional frequency modulation scheme and proposed a mode frequency hopping (MFH) scheme. The system model is shown in Figure 6b (the transmitter on the left and the receiver on the right). The MFH system is based on the MH system by adding two frequency synthesizers (as shown in the red dotted line in Figure 6b). The OAM transmitter and OAM receiver can utilize a uniform circular array (UCA) antenna configuration. In the case of the OAM transmitter, the N array elements are fed with the same input signal, with each successive element receiving a progressively delayed signal so that the phase of the wavefront is incremented by an integer multiple l of 2π after a complete turn. The input data symbol experiences U OAM mode or frequency hops. At the transmitter, a mode/frequency synthesizer, controlled by a pseudorandom noise sequence generator (PNG), selects an OAM mode or a frequency band range. To de-hop the OAM mode at the receiver, PNGs identical to those used in the transmitter are employed. The received signal is processed through an integrator and low-pass filter to recover the transmitted signal. The research group then compared the BERs of the scheme it developed with traditional wideband frequency modulation schemes. The numerical results show that the communication BER of the MFH scheme developed by the research group is much lower than that of the traditional wireless frequency modulation scheme, which can improve the anti-interference performance of wireless communication systems effectively, as illustrated in Table 5.
In 2022, Liang et al. introduced an index-modulation embedded mode-hopping (IM-MH) scheme [147]. This innovative scheme enables the simultaneous activation of multiple OAM modes for hopping, while also facilitating the transmission of additional index information and signal data. An analysis of the average bit error rates (ABERs) for the proposed IM-MH scheme under two scenarios—perfect channel state information (CSI) and imperfect CSI—was performed. Additionally, they propose the index-modulation embedded double-serial MH (IM-DSMH) scheme, which incorporates a random activation of one OAM mode as the second serial hop in transmitting the hopping signals within the IM-MH scheme. This further reduces the average bit error rates (ABER) in wireless communications. The input signal information is divided into signal and index components. By utilizing secure keys to determine the index information, index selector A selectively activates I out of N OAM modes, enabling the realization of OAM multiplexing at each hop. The inactive state is assigned to the remaining (N–I) OAM modes. During the operation of the Double-Serial Mode-Hopping (DSMH), index selector B selectively activates one OAM mode as the second serial hop based on the index information. The activation pattern of OAM modes follows a consistent sequence for both transmitters and receivers while appearing random to potential attackers. Extensive numerical analysis demonstrates the effectiveness of their proposed schemes in achieving low Average Bit Error Rates (ABER) and significantly increasing Spectral Efficiency (SE) within a narrowband. Specifically, the ABERs of the proposed IM-MH and IM-DSMH schemes are approximately 25% and 10% of the traditional schemes, respectively.
At present, most OAM-RD which can realize the channel switching function realizes the strong anti-interference ability of wireless communication by mode hopping or frequency hopping [148,149]. However, only one OAM mode/band is excited to load and transmit line information per hop, resulting in low-capacity problems caused by low OAM mode or spectral interest rate. This problem is at odds with the increasing data rate requirements of wireless communications. Therefore, how to improve the OAM-RD which can realize channel hopping is a priority in future research direction. Table 5 summarizes the works reported to date for the channel hopping routers OAM-based optical communication.

6. OAM Channel Adding/Extracting

Selective channel adding or extracting is also an important part of optical communication links [150,151]. In 2013, Huang et al. [152] reported an OAM mode division multiplexer that efficiently added or extracted a single OAM beam. Figure 7a gives the working mechanism of the proposed experimental setup. The desired OAM beam is transformed into a Gaussian beam while the mode values of other OAM beams remain unchanged. Afterward, using an SLM loaded with two different region grating phases, a composite beam is separated. To filter out the center Gaussian beam of the coaxial composite beam, the inner grating changes the diffraction direction of the Gaussian beam, while the outer grating does not change the diffraction direction of the OAM beam, enabling the OAM beam to reflect along its normal path and thus extract the target OAM beam channel. For a 100 Gbit/s QPSK data channel, this scheme incurs a power loss of less than 2 dB, and the BER of the channel is only 2.0 × 10−3, as can be seen in Table 6. Although this OAM-RD can flexibly manipulate a single OAM channel, controlling the extraction or addition of multiple OAM channels is still a challenge due to the power loss caused by crosstalk between channels.
Table 6. Summary of channel adding/extracting routers used for the OAM-based optical communications.
Table 6. Summary of channel adding/extracting routers used for the OAM-based optical communications.
YearMethodsEquipmentStrengths/
Weaknesses		Transmission
Result		Ref.
2013Reconfigurable multiplexersSLMOperate channels flexibly/Only one channel at a timeThe power loss of this scheme is less than 2 dB and the channel error rate is only 2.0 × 10−3.[152]
2019Geometric transformationSLMRealize the addition and extraction/Required multiple SLMsThe energy purity of the measured OAM is about 95%.[153]
2019OAM analyzerInterferometer, Dove prismsSeparate the odd and even OAM beams/-The crosstalk values are below −10 dB and can sort the odd and even OAM beams [154]
2021OAM add-drop multiplexerdiffractive deep neural
network		Diffraction efficiency and mode purity are very high/
-		Signal-to-noise ratio penalties of ~1 dB at a BER of 3.8 × 10−3[155]
To add or extract multiple OAM channels, in 2019, Feng et al. [153] developed a geometric transformation-based OAM mode division multiplexer that successfully realized the extraction and addition of multiple OAM channels. First, a series of narrow light spots corresponding to the OAM mode values are obtained by using two SLMs loaded with special phases and a Fourier lens to transform the incoming OAM multiplexed beam based on the principle of optical geometric transformation. Then, the target OAM beam to be extracted is transmitted by setting the reflection phase on the SLM, while the other OAM beams remain reflected. Finally, the reflected light path passes through the previous optical components to complete the optical geometric inverse transformation and restore the original OAM beam, thereby achieving the extraction of multiple OAM beams in the composite beam. When it is necessary to add multiple OAM beams, the desired OAM beams to be added are first transformed into narrow light spots at the focal plane position through optical geometric transformation. Then, the SLM is adjusted to transmit the target OAM beam to be added while reflecting other OAM beams. After the reverse transmission along the same optical path, the added beam and the original beam are restored into a new OAM multiplexed beam at the output end through a beam splitter and optical geometric inverse transformation, thus completing the OAM beam adding operation. This scheme can not only realize the adding and extracting of OAM beams simultaneously but also further duplicate the other OAM modes in the composite OAM beam without affecting them, reducing the spot size to maintain the high energy purity of the OAM beam, as depicted in Table 6.
In 2019, Feng et al. [154] introduced a high-density OAM analyzer comprising two OAM mode converters and a modified Mach–Zehnder interferometer (MZI). This MZI, which includes a pair of Dove prisms in addition to the standardized MZI configuration, effectively avoids the inherent overlap of adjacent OAM modes within the mode converter. In this scheme, the multiplexing OAM beam is incident into the modified MZI, which can sort and separate the even and odd OAM modes into different ports, respectively. The schematic of the modified MZI is shown in Figure 7b: when the input beam is incident to the beam splitter of BS1, the beam is divided into two beams. In the upper path, the reflected beam is first reflected by M1 and then passes through DP2, after which it is split into two beams by BS2. One beam reaches port A of BS2 while the other is reflected towards port B. Conversely, in the lower path, the transmitted beam first passes through DP1 and is then reflected by M2 before being split by BS2. One of the resulting beams is directed towards port A of the BS2, while the other reaches port B. The proposed method ensures that the topological charge interval between adjacent OAM beams is at least equal to 2 at both output ports of the MZI. As a result, the distance between the converted light spots corresponding to these OAM modes will be greater than the width of each individual spot, effectively avoiding any overlapping and enabling high-density OAM mode analysis with enhanced discrimination resolution, as presented in Table 6. This feature addresses a key challenge in the OAM mode analysis, where previously the ability to analyze high-density OAM modes was effectively constrained.
Generally, phase gratings are employed in the construction of the OAM add–drop multiplexer (OADM). However, the rigid construction and beam-splitting properties of phase gratings restrict their diffraction efficiency, adaptability, and usefulness. In recent years, deep neural networks have emerged as a promising technique for information processing in the OAM mode. These networks have the capacity to theoretically approximate functional relationships in any input–output domain. In 2021, Xiong et al. [155] introduced an OAM add–drop multiplexer (OADM) utilizing an optical diffractive deep neural network (ODNN). By leveraging the powerful data-fitting capability of deep neural networks and the intricate light-field manipulation abilities of multilayer diffraction screens, a five-layer ODNN was constructed. This ODNN enables precise control over the spatial positioning of vortex beams, facilitating the selective coupling and separation of OAM modes. The specific structure of the OAM add-drop multiplexer (OADM) using the optical diffractive deep neural network (ODNN) is depicted in Figure 7c. The input plane of the diffraction neural network is divided into several ports: (1) in port: this port receives the multiplexed OAM channels; (2) drop port: it extracts the selected OAM channel from the multiplexed channels; (3) add port: this port uploads an OAM channel carrying a new data stream; (4) through port: it outputs the re-multiplexed OAM channels. By leveraging the add and drop functions, the OADM can selectively upload and download OAM channels without affecting other transmitted OAM channels. In simulations, both the diffraction efficiency and mode purity exceeded 95%. Four OAM channels carrying 16-quadrature amplitude modulation signals were successfully downloaded and uploaded with only 1 dB loss in optical signal-to-noise ratio at a BER of 3.8 × 10−3. This innovative approach overcomes the limitations of conventional OADMs, which have single functionalities and poor flexibility. It provides new possibilities for OAM multiplexing and all-optical interconnection.
In general, the research on the OAM-RD that can implement channel addition/extraction is still in its infancy, and more in-depth related research is needed. These studies have developed from the extraction and addition of a single OAM beam to the extraction and addition of multiple OAM beams, which will improve the expansion ability of OAM channels step by step, and build the foundation for realizing multi-channel networks, in which intermediate-node users can access their selected channels without interfering with other channels. Table 6 summarizes the works reported to date for the channel adding/extracting routers OAM-based optical communication.

7. Conclusions

This paper mainly reviews and summarizes the research achievements of OAM-RDs for OAM-based optical communication. According to different router functions, the router components can be divided into five categories, including OAM channel multicasting, switching, filtering, hopping, and adding/extracting. This review briefly introduced the working principle and development history of different OAM-RDs.
With further development of the OAM-based optical communication technology, OAM-RDs play important roles in improving the flexibility and practicability of optical communication systems. OAM multicasting devices can copy the data information of a single channel to multiple channels for better adaptation to the multi-user environment. OAM switching devices can switch the OAM mode value of the input beam to realize effective data switching between different OAM channels. OAM filtering devices can realize the extraction of specific channel information from the multiplexed OAM channels. OAM hopping devices, by changing the OAM modes or frequencies, can achieve channel switching to improve the anti-jamming ability of OAM-based optical communication. Meanwhile, OAM adding/extracting devices, employing the selective addition or extraction of the OAM communication channel, can access the selected channel without interfering with other channels for the intermediate-node users. So far, OAM-RDs are developing towards miniaturization and integration, which coincides with the requirements of devices in today’s optical communication. With in-depth research, the developments on the OAM-RDs have achieved a series of important breakthrough results, which play important roles in the OAM-based optical communication system.
OAM channel multicasting holds great potential to meet the increasing bandwidth demands in future optical communication networks as it allows a single optical signal to send data through a shared optical network to multiple receivers. However, significant efforts are still needed to send data to ultra-multi-users simultaneously without compromising the bit error rate (BER) of data transmission. Similarly, realizing low-cost channel switching with ultra-fast switching time is a challenge yet to be overcome. The use of multiple SLMs in the switching process increases the difficulty of loading phase design on different SLMs and increases the system complexity and device cost, putting constraints on the high-speed optical communication link system which requires high real-time and economic performance. OAM channel filtering router devices with small sizes and good compatibility with the existing fiber-based OAM applications are one of the future research directions. To achieve efficient channel hopping, the performance of combinational OAM communication schemes should be researched and studied to combine the benefits of both simultaneously. For efficient, reliable, and easily integrable OAM add–drop multiplexer (OADM), deep neural networks must be explored as the traditional rigid construction and beam splitting properties of phase gratings restrict their diffraction efficiency, adaptability, and usefulness.
In summary, as a new optical communication technology, OAM-RDs for OAM-based optical communication have been widely explored by researchers, but there are still some challenges to overcome, which are attracting further research. In addition, OAM has developed in the field of optical communication, and it is also a broad application prospect in the field of acoustic communication and traditional RF communication. However, the OAM-RD research in the field of acoustic communication and traditional RF communication is still in its infancy. It is believed that with the continuous studies conducted by worldwide researchers, in the near future, there will be more functions and more optimized and flexible OAM-RDs in various fields to gradually promote the continuous development of wireless communication based on the OAM.

Author Contributions

Writing Original Draft, B.W. and X.Z.; review and editing, J.T., B.M., Z.L. and S.A.A.S.; review and supervision Z.G., K.G., B.L. and Y.L. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the National Natural Science Foundation of China under Grant 61775050.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

We acknowledge the financial support extended by Hefei University of Technology, China.

Conflicts of Interest

The authors declare no conflicts of interest.

References

  1. Botta, A.; De Donato, W.; Persico, V.; Pescape, A. Integration of cloud computing and internet of things: A survey. Future Gener. Comput. Syst. 2016, 56, 684. [Google Scholar] [CrossRef]
  2. Díaz, M.; Martín, C.; Rubio, B. State-of-the-art, challenges, and open issues in the integration of Internet of things and cloud computing. J. Netw. Comput. Appl. 2016, 67, 99. [Google Scholar] [CrossRef]
  3. Ijaz, M.; Li, G.; Lin, L.; Cheikhrouhou, O.; Hamam, H.; Noor, A. Integration and applications of fog computing and cloud computing based on the internet of things for provision of healthcare services at home. Electronics 2021, 10, 1077. [Google Scholar] [CrossRef]
  4. Dhingra, S.; Madda, R.B.; Patan, R.; Jiao, P.; Barri, K.; Alavi, A.H. Internet of things-based fog and cloud computing technology for smart traffic monitoring. Internet Things 2021, 14, 100175. [Google Scholar] [CrossRef]
  5. Paricherla, M.; Babu, S.; Phasinam, K.; Pallathadka, H.; Zamani, A.S.; Narayan, V.; Shukla, S.K.; Mohammed, H.S. Towards Development of Machine Learning Framework for Enhancing Security in Internet of Things. Secur. Commun. Netw. 2022, 2022, 4477507. [Google Scholar] [CrossRef]
  6. Winzer, P. Modulation and multiplexing in optical communications. In Proceedings of the Conference on Lasers & Electro-Optics, Baltimore, MD, USA, 2–4 June 2009. [Google Scholar]
  7. Zhou, X.; Yu, J. Multi-level, multi-dimensional coding for high-speed and high-spectral-efficiency optical transmission. J. Light. Technol. 2009, 27, 3641. [Google Scholar] [CrossRef]
  8. Richter, T.; Palushani, E.; Schmidt-Langhorst, C.; Ludwig, R.; Molle, L.; Nolle, M.; Schubert, C. Transmission of single-channel 16-QAM data signals at terabaud symbol rates. J. Light. Technol. 2012, 30, 504. [Google Scholar] [CrossRef]
  9. Gnauck, A.; Winzer, P.; Chandrasekhar, S.; Liu, X.; Zhu, B.; Peckham, D.W. Spectrally efficient long-haul WDM transmission using 224-Gb/s polarization-multiplexed 16-QAM. J. Light. Technol. 2011, 29, 373. [Google Scholar] [CrossRef]
  10. Zhou, X.; Yu, J.; Huang, M.; Shao, Y.; Wang, T.; Nelson, L.; Magill, P.; Birk, M.; Borel, P.I.; Peckham, D.w.; et al. 64-Tb/s, 8 b/s/Hz, PDM-36QAM transmission over 320 km using both pre- and post-transmission digital signal processing. J. Light. Technol. 2011, 29, 571. [Google Scholar] [CrossRef]
  11. Winzer, P. Making spatial multiplexing a reality. Nat. Photonics 2014, 8, 345. [Google Scholar] [CrossRef]
  12. Guo, Z.; Gong, C.; Liu, H.; Li, J.; Wang, Z.; Yang, Y.; Gong, Y. Research advances of orbital angular momentum based optical communication technology. Opto-Electron. Eng. 2020, 47, 190593. (In Chinese) [Google Scholar]
  13. Guo, Z.; Pan, Z.; Gong, C.; Wang, Z.; Guo, K.; Zhou, H. Research on router devices of OAM optical communication. J. Commun. 2020, 41, 185. (In Chinese) [Google Scholar]
  14. Li, L.; Liu, B.; Li, Z.; Guo, K.; Guo, Z. Acoustic vortex filter based on tunable metasurfaces. Appl. Phys. Lett. 2024, 124, 011702. [Google Scholar] [CrossRef]
  15. Guo, Z.; Wang, Y.; Zheng, Q. Research progress of vortex electromagnetic wave antenna technology. J. Radars 2019, 8, 631. (In Chinese) [Google Scholar]
  16. Wang, Z.; Dedo, M.I.; Guo, K.; Zhou, K.; Shen, F.; Sun, Y.; Liu, S.; Guo, Z. Efficient Recognition of the Propagated Orbital Angular Momentum Modes in Turbulences With the Convolutional Neural Network. IEEE Photonics J. 2019, 11, 1. [Google Scholar] [CrossRef]
  17. Guo, Z.; Wang, Y.; Wang, Y. Research advances in vortex radar imaging technology. J. Radars 2021, 10, 665. [Google Scholar]
  18. Allen, L.; Beijersbergen, M.; Spreeuwr, J.; Woerdman, J.P. Orbital angular momentum of light and transformation of Laguerre Gaussian laser modes. Phys. Rev. A 1992, 45, 8185. [Google Scholar] [CrossRef]
  19. Doster, T.; Watnik, A.T. Laguerre–gauss and bessel–gauss beams propagation through turbulence: Analysis of channel efficiency. Appl. Opt. 2016, 55, 10239–10246. [Google Scholar] [CrossRef] [PubMed]
  20. Jin, X.; Pang, F.; Zhang, Y.; Huang, S.; Li, Y.; Wen, J.; Chen, Z.; Wang, M.; Wang, T. Generation of the first-order OAM modes in single-ring fibers by offset splicing technology. IEEE Photon. Technol. Lett. 2016, 28, 1581. [Google Scholar] [CrossRef]
  21. Chen, M.; Mazilu, M.; Arita, Y.; Wright, M.E.; Dholakia, K. Optical trapping with a perfect vortex beam. In Proceedings of the Optical Trapping and Optical Micromanipulation XI, San Diego, CA, USA, 17–21 August 2014; Volume 9164, pp. 69–73. Available online: https://spie.org/Publications/Proceedings/Volume/9164#_=_ (accessed on 15 October 2023).
  22. Lian, Y.; Qi, X.; Wang, Y.; Bai, Z.; Wang, Y.; Lu, Z. OAM beam generation in space and its applications: A review. Opt. Lasers Eng. 2022, 151, 106923. [Google Scholar] [CrossRef]
  23. Xiang, Z.; Shen, Z.; Shen, Y. Quasi-perfect vortices generated by Pancharatnam-Berry phase metasurfaces for optical spanners and OAM communication. Sci. Rep. 2022, 12, 1053. [Google Scholar] [CrossRef]
  24. Yin, Z.; Zheng, Q.; Wang, K.; Guo, K.; Shen, F.; Zhou, H.; Sun, Y.; Zhou, Q.; Gao, J.; Luo, L.; et al. Tunable dual-band terahertz metalens based on stacked graphene metasurfaces. Opt. Commun. 2018, 429, 41. [Google Scholar] [CrossRef]
  25. Yin, Z.; Zheng, Q.; Guo, K.; Guo, Z. Tunable beam steering, focusing and generating of orbital angular momentum vortex beams using high-order patch array. Appl. Sci. 2019, 9, 2949. [Google Scholar] [CrossRef]
  26. Wang, L.; Chen, H.; Guo, K.; Shen, F.; Guo, Z. An inner-and outer-fed dual-arm archimedean spiral antenna for generating multiple orbital angular momentum modes. Electronics 2019, 8, 251. [Google Scholar] [CrossRef]
  27. Wu, S.; Zhang, Y.; Cui, X.; Zhang, J.; Xu, P.; Ji, X. Generation of dual-polarization orbital angular momentum vortex beams with reflection-type metasurface. Opt. Commun. 2024, 553, 130107. [Google Scholar] [CrossRef]
  28. Memon, S.; Li, X.; Memon, K.A.; Huang, Y.; Uqaili, J.A.; Ishfaq, M. The development trends and research fronts in orbital angular momentum technology: A bibliometric analysis. China Commun. 2023, 20, 289. [Google Scholar] [CrossRef]
  29. Guo, K.; Zheng, Q.; Yin, Z.; Guo, Z. Generation of mode-reconfigurable and frequency-adjustable OAM beams using dynamic reflective metasurface. IEEE Access 2020, 8, 7552. [Google Scholar] [CrossRef]
  30. Wang, Y.; Wang, Y.; Guo, K.; Guo, Z. Detecting targets’ longitudinal and angular accelerations based on vortex electromagnetic waves. Measurement 2022, 187, 110278. [Google Scholar] [CrossRef]
  31. Wang, Y.; Wang, Y.; Guo, Z. OAM radar based fast super-resolution imaging. Measurement 2022, 189, 110600. [Google Scholar] [CrossRef]
  32. Guo, K.; Lei, S.; Lei, Y.; Zhou, H.; Guo, Z. Research on detecting targets’ accelerations based on vortex electromagnetic wave in non-line-of-sight scenario. IEEE Sens. J. 2023, 23, 4078–4084. [Google Scholar] [CrossRef]
  33. Wang, Z.; Guo, Z. Adaptive Demodulation Technique for Efficiently Detecting Orbital Angular Momentum (OAM) Modes Based on the Improved Convolutional Neural Network. IEEE Access 2019, 7, 163633. [Google Scholar] [CrossRef]
  34. Ruffato, G. OAM-inspired new optics: The angular metalens. Light Sci. Appl. 2021, 10, 96. [Google Scholar] [CrossRef]
  35. Zhou, H.; Pan, Z.; Dedo, M.; Guo, Z. High-efficiency and high-precision identification of transmitting orbital angular momentum modes in atmospheric turbulence based on an improved convolutional neural network. J. Opt. 2021, 23, 065701. [Google Scholar] [CrossRef]
  36. Gong, C.; Pan, Z.; Dedo, M.; Sun, J.; Wang, L.; Guo, Z. Improving the demultiplexing performances of the multiple Bessel Gaussian beams (mBGBs). Results Phys. 2021, 30, 104829. [Google Scholar] [CrossRef]
  37. Dedo, M.; Wang, Z.; Guo, K.; Guo, Z. OAM mode recognition based on joint scheme of combining the Gerchberg–Saxton (GS) algorithm and convolutional neural network (CNN). Opt. Commun. 2020, 456, 124696. [Google Scholar] [CrossRef]
  38. Lou, Y.; Lv, Y.; Wang, J.; Liu, S.; Jing, J. Orbital Angular Momentum Multiplexed Deterministic All-Optical Quantum Erasure-Correcting Code. Phys. Rev. Lett. 2024, 132, 040601. [Google Scholar] [CrossRef]
  39. Dedo, M.; Wang, Z.; Guo, K.; Sun, Y.; Shen, F.; Zhou, H.; Gao, J.; Sun, R.; Ding, Z.; Gou, Z. Retrieving performances of vortex beams with GS algorithm after transmitting in different types of turbulences. Appl. Sci. 2019, 9, 2269. [Google Scholar] [CrossRef]
  40. Guo, Z.; Wang, Z.; Dedo, M.; Guo, K. The orbital angular momentum encoding system with radial indices of Laguerre–Gaussian beam. IEEE Photon. J. 2018, 10, 1. [Google Scholar] [CrossRef]
  41. Lei, Y.; Yang, Y.; Wang, Y.; Guo, K.; Gong, Y.; Guo, Z. Throughput performance of wireless multiple-input multiple-output systems using OAM antennas. IEEE Wirel. Commun. Lett. 2020, 10, 261. [Google Scholar] [CrossRef]
  42. Yang, Y.; Gong, Y.; Guo, K.; Sehn, F.; Sun, J.; Guo, Z. Broad-Band Multiple OAMs’ Generation with Eight-arm Archimedean Spiral Antenna (ASA). IEEE Access 2020, 8, 53232. [Google Scholar] [CrossRef]
  43. Yang, Y.; Liu, G.; Shen, F.; Sun, J.; Guo, K.; Guo, Z.; Zhou, K.; Jiang, H.; Wu, Z.; Zeng, B.; et al. Generating and Detecting Broad-Band Underwater Multiple OAMs Based on Water-immersed Antenna Array. IEEE Access 2020, 8, 149586. [Google Scholar] [CrossRef]
  44. Shen, F.; Mu, J.; Guo, K.; Wang, S.; Guo, Z. Generation of continuously variable-mode vortex electromagnetic waves with three-dimensional helical antenna. IEEE Antennas Wirel. Propag. Lett. 2019, 18, 1091. [Google Scholar] [CrossRef]
  45. Shen, F.; Yin, C.; Guo, K.; Wang, S.; Gong, Y.; Guo, Z. Low-Cost Dual-Band Multi-Polarization Aperture-Shared Antenna with Single-Layer Substrate. IEEE Antennas Wirel. Propag. Lett. 2019, 18, 1337. [Google Scholar] [CrossRef]
  46. Shen, F.; Mu, J.; Guo, K.; Guo, Z. Generating circularly polarized vortex electromagnetic waves by the conical conformal patch antenna. IEEE Trans. Antennas Propag. 2019, 67, 5763. [Google Scholar] [CrossRef]
  47. Yang, Y.; Guo, K.; Shen, F.; Gong, Y.; Guo, Z. Generating Multiple OAM Based on a Nested Dual-Arm Spiral Antenna. IEEE Access 2019, 7, 138541. [Google Scholar] [CrossRef]
  48. Yang, Y.; Wang, Z.; Wang, S.; Zhou, Q.; Shen, F.; Jiang, H.; Wu, Z.; Zeng, B.; Guo, Z.; Gong, Y. Designing Water-Immersed Rectangular Horn Antenna for Generating Underwater OAM Wave. Electronics 2019, 8, 1224. [Google Scholar] [CrossRef]
  49. Hui, X.; Zheng, S.; Chen, Y.; Hu, Y.; Jin, X.; Chi, H.; Zhang, X. Multiplexed Millimeter Wave Communication with Dual Orbital Angular Momentum (OAM) Mode Antennas. Sci. Rep. 2015, 5, 10148. [Google Scholar] [CrossRef]
  50. Yan, Y.; Xie, G.; Lavery, M.; Huang, H.; Ahmed, N.; Bao, C.; Ren, Y.; Cao, Y.; Li, L.; Zhao, Z.; et al. High-capacity millimetre-wave communications with orbital angular momentum multiplexing. Nat. Commun. 2014, 5, 4876. [Google Scholar] [CrossRef]
  51. Zhou, H.; Li, J.; Guo, K.; Guo, Z. Generation of acoustic vortex beams with designed Fermat’s spiral diffraction grating (FSDG). J. Acoust. Soc. Am. 2019, 146, 4237. [Google Scholar] [CrossRef]
  52. Guo, Z.; Liu, H.; Zhou, H.; Wang, S.; Shen, F.; Gong, Y.; Gao, J.; Liu, S.; Guo, K. High-order acoustic vortex field generation based on the metasurface. Phys. Rev. E. 2019, 100, 053315. [Google Scholar] [CrossRef]
  53. Gong, C.; Li, J.; Guo, K.; Zhou, H.; Guo, Z. Measuring the orbital angular momentum of acoustic vortices based on the Fraunhofer’s diffraction. Chin. Phys. B 2020, 29, 104301. [Google Scholar] [CrossRef]
  54. Guo, Z.; Liu, H.; Li, J.; Zhou, H.; Guo, K.; Jun, G. Research progress of applications of acoustic-vortex information. Acta Phys. Sin. 2020, 69, 244301. (In Chinese) [Google Scholar] [CrossRef]
  55. Zhou, H.; Li, J.; Gong, C.; Guo, K.; Guo, Z. Measuring the orbital angular momentum of acoustic vortices by apertures. J. Acoust. Soc. Am. 2020, 148, 167–173. [Google Scholar] [CrossRef] [PubMed]
  56. Li, Z.; Lei, Y.; Guo, K.; Guo, Z. Generating reconfigurable acoustic orbital angular momentum with double-layer acoustic metasurface. J. Appl. Phys. 2023, 133, 074901. [Google Scholar] [CrossRef]
  57. Pu, S.; Guo, G.; Guo, X.; Zhou, C.; Li, Y.; Ma, Q.; Tu, J.; Zhang, D. Auto-focusing acoustic-vortex tweezers for obstacle-circumventing manipulation. J. Appl. Phys. 2021, 130, 234903. [Google Scholar] [CrossRef]
  58. Shi, C.; Dubois, M.; Wang, Y.; Zhang, X. High-speed acoustic communication by multiplexing orbital angular momentum. Proc. Natl. Acad. Sci. USA 2017, 114, 7250. [Google Scholar] [CrossRef] [PubMed]
  59. Fu, Y.; Shen, C.; Zhu, X.; Li, J.; Liu, Y.; Cummer, S.; Xu, Z. Sound vortex diffraction via topological charge in phase gradient metagratings. Sci. Adv. 2020, 6, 9876. [Google Scholar] [CrossRef]
  60. Zhang, B.W.; Hong, Z.Y.; Drinkwater, B.W. Transfer of Orbital Angular Momentum to Freely Levitated High-Density Objects in Airborne Acoustic Vortices. Phys. Rev. Appl. 2022, 18, 024029. [Google Scholar] [CrossRef]
  61. Ran, L.; Guo, Z.; Qu, S. Rotation of optically trapped microscopic particles by vortex femtosecond laser. Chin. Phys. B 2012, 21, 104206. [Google Scholar] [CrossRef]
  62. Li, Y.; Guo, Z.; Qu, S. Living cell manipulation in microfluidic device by femtosecond optical tweezers. Opt. Lasers Eng. 2014, 55, 150. [Google Scholar] [CrossRef]
  63. Karuna, S.M.; Bosanta, R.B. Optical force calculation in the ray-optics regime for beams with arbitrary complex amplitude profiles. Opt. Lett. 2022, 47, 4151. [Google Scholar]
  64. Cui, X.-z.; Yin, X.-l.; Chang, H.; Guo, Y.-l.; Zheng, Z.-j.; Sun, Z.-w.; Liu, G.-y.; Wang, Y.-j. Analysis of an adaptive orbital angular momentum shift keying decoder based on machine learning under oceanic turbulence channels. Opt. Commun. 2018, 429, 138. [Google Scholar] [CrossRef]
  65. Krenn, M.; Fickler, R.; Fink, M.; Handsteiner, J.; Malik, M.; Scheidl, T.; Ursin, R.; Zeilinger, A. Communication with spatially modulated light through turbulent air across vienna. New J. Phys. 2014, 16, 113028. [Google Scholar] [CrossRef]
  66. Du, J.; Wang, J. High-dimensional structured light coding/decoding for free-space optical communications free of obstructions. Opt. Lett. 2015, 40, 4827. [Google Scholar] [CrossRef]
  67. Li, X.; Li, Y.; Zeng, X.N.; Han, Y. Perfect optical vortex array for optical communication based on orbital angular momentum shift keying. J. Opt. 2018, 20, 125604. [Google Scholar] [CrossRef]
  68. Tian, Q.; Li, Z.; Hu, K.; Zhu, L.; Pan, X.; Zhang, Q.; Wang, Y.; Tian, F.; Yin, X.; Xin, X. Turbo-coded 16-ary OAM shift keying FSO communication system combining the CNN-based adaptive demodulator. Opt. Express 2018, 26, 27849. [Google Scholar] [CrossRef] [PubMed]
  69. Kai, C.; Huang, P.; Shen, F.; Zhou, H.; Guo, Z. Orbital angular momentum shift keying based optical communication system. IEEE Photon J. 2017, 9, 1–10. [Google Scholar] [CrossRef]
  70. Fu, S.; Zhai, Y.; Zhou, H.; Zhang, J.; Wang, T.; Liu, X.; Gao, C. Experimental demonstration of free-space multi-state orbital angular momentum shift keying. Opt. Express 2019, 27, 33111. [Google Scholar] [CrossRef] [PubMed]
  71. Zhu, J.; Fan, M.; Pu, Y.; Li, H.; Wang, S. 1024-ary composite OAM shift keying for free-space optical communication system decoded by a two-step neural network. Opt. Lett. 2023, 48, 2692. [Google Scholar] [CrossRef] [PubMed]
  72. Huang, H.; Xie, G.; Yan, Y.; Ahmed, N.; Ren, Y.; Yue, Y.; Rogawski, D.; Willner, M.J.; Erkmen, B.I.; Birnbaum, K.M.; et al. 100 Tbit/s free-space data link enabled by three-dimensional multiplexing of orbital angular momentum, polarization, and wavelength. Opt. Lett. 2014, 39, 197. [Google Scholar] [CrossRef]
  73. Li, S.; Wang, J. A compact trench-assisted multi-orbital-angular- momentum multi-ring fiber for ultrahigh-density space-division multiplexing (19 rings × 22 modes). Sci. Rep. 2014, 4, 3853. [Google Scholar] [CrossRef]
  74. Wang, J.; Liu, J.; Lyu, X.; Zhu, L.; Wang, D.; Li, S.; Wang, A.; Zhao, Y.; Long, Y.; Du, J.; et al. Ultra-high 435-bit/s/Hz spectral efficiency using N-dimentional multiplexing and modulation link with pol-muxed 52 orbital angular momentum (OAM) modes carrying Nyquist 32-QAM signals. In Proceedings of the European Conference on Optical Communication, Valencia, Spain, 27 September–1 October 2015; IEEE Press: Piscataway, NJ, USA, 2015. [Google Scholar]
  75. Zahidy, M.; Liu, Y.; Cozzolino, D.; Ding, Y.; Morioka, T.; Oxenløwe, L.K.; Bacco, D. Photonic integrated chip enabling orbital angular momentum multiplexing for quantum communication. Nanophotonics 2022, 11, 821. [Google Scholar] [CrossRef]
  76. Gatto, A.; Tacca, M.; Martelli, P.; Boffi, P.; Martinelli, M. Free-space orbital angular momentum division multiplexing with Bessel beams. J. Opt. 2011, 13, 064018. [Google Scholar] [CrossRef]
  77. Lei, T.; Zhang, M.; Li, Y.; Jia, P.; Liu, G.N.; Xu, X.; Li, Z.; Min, C.; Lin, J.; Yu, C.; et al. Massive individual orbital angular momentum channels for multiplexing enabled by Dammann gratings. Light Sci. Appl. 2015, 4, e257. [Google Scholar] [CrossRef]
  78. Liu, J.; Wang, H.; Chen, S.; Zheng, S.; Zhu, L.; Wang, A.; Zhou, N.; Li, S.; Shen, L.; Du, C.; et al. Demonstration of orbital angular momentum (OAM) fiber amplifier in data-carrying OAM-division multiplexing and wavelength-division multiplexing (WDM) system. In Proceedings of the 2017 Optical Fiber Communications Conference and Exhibition (OFC), San Diego, CA, USA, 19–23 March 2017. [Google Scholar]
  79. Jian, Y.; Chow, C. Design and analysis of a compact micro-ring resonator signal emitter to reduce the uniformity-induced phase distortion and crosstalk in orbital angular momentum (OAM) division multiplexing. Opt. Express 2023, 31, 810. [Google Scholar] [CrossRef]
  80. Lei, Y.; Li, L.; Zhou, H.; Guo, K.; Guo, Z. Transmission characteristics of vortex frozen waves in different obstacle channels. Opt. Express 2023, 31, 4701. [Google Scholar] [CrossRef]
  81. Li, Z.; Li, X.; Jia, H.; Pan, Z.; Gong, C.; Zhou, H.; Guo, Z. High-efficiency anti-interference OAM-FSO communication system based on Phase compression and improved CNN. Opt. Commun. 2023, 537, 129120. [Google Scholar] [CrossRef]
  82. Bin, W.; Michael, T.; Zhe, Z.; Esashi, Y.; Jenkins, N.W.; Murnane, M.M.; Kapteyn, H.C.; Liao, C. T.Coherent Fourier scatterometry using orbital angular momentum beams for defect detection. Opt. Express 2021, 29, 3342. [Google Scholar]
  83. Long, Z.; Mingliang, D.; Bing, L.; Guo, X.; Wang, A. Turbulence-resistant high-capacity free-space optical communications using OAM mode group multiplexing. Opt. Express 2023, 31, 14454. [Google Scholar]
  84. Li, J.; Yang, Q.; Dai, X.; Lim, C.; Nirmalathas, A. Investigation on repetition-coding and space-time-block-coding for indoor optical wireless communications employing beam shaping based on orbital angular momentum modes. Opt. Express 2022, 30, 20278. [Google Scholar] [CrossRef] [PubMed]
  85. Fang, X.; Ren, H.; Gu, M. Orbital angular momentum holography for high-security encryption. Nat. Photonics 2020, 14, 102. [Google Scholar] [CrossRef]
  86. Tomkos, I.; Azodolmolky, S.; Sole-Pareta, J.; Careglio, D.; Palkopoulou, E. A tutorial on the flexible optical networking paradigm: State of the art, trends, and research challenges. Proc. IEEE Inst. Electr. Electron. Eng. 2014, 102, 1317. [Google Scholar] [CrossRef]
  87. Mamadou, D.; Shen, F.; Dedo, M.; Zhou, Q.; Guo, K.; Guo, Z. High-efficiency sorting and measurement of orbital angular momentum modes based on the March-Zehnder interferometer and complex phase gratings. Meas. Sci. Technol. 2019, 30, 075201. [Google Scholar] [CrossRef]
  88. Zhang, Y.; Chen, Y.; Zhong, Z.; Xu, P.; Chen, H.; Yu, S. Orbital angular momentum (OAM) modes routing in a ring fiber based directional coupler. Opt. Commun. 2015, 350, 160. [Google Scholar] [CrossRef]
  89. Lavery, M.; Dudley, A.; Forbes, A.; Courtial, J.; Padgett, M.J. Robust interferometer for the routing of light beams carrying orbital angular momentum. New J. Phys. 2011, 13, 093014. [Google Scholar] [CrossRef]
  90. Garcia-Escartin, J.; Chamorro-Posada, P. Quantum computer networks with the orbital angular momentum of light. Phys. Rev. A 2012, 86, 032334. [Google Scholar] [CrossRef]
  91. Merabet, B.; Liu, B.; Li, Z.; Tian, J.; Guo, K.; Shah, S.A.S.; Guo, Z. Vision transformers motivating superior OAM mode recognition in optical communications. Opt. Express 2023, 31, 38958. [Google Scholar] [CrossRef] [PubMed]
  92. Willner, A. OAM light for communications. Opt. Photonics News 2021, 32, 34. [Google Scholar] [CrossRef]
  93. Dai, K.; Gao, C.; Zhong, L.; Na, Q.; Wang, Q. Measuring OAM states of light beams with gradually-changing-period gratings. Opt. Lett. 2015, 40, 562. [Google Scholar] [CrossRef]
  94. Ruffato, G.; Rossi, R.; Massari, M.; Mafakheri, E.; Capaldo, P.; Romanato, F. Design, fabrication and characterization of computer generated holograms for anti-counterfeiting applications using OAM beams as light decoders. Sci. Rep. 2017, 7, 18011. [Google Scholar] [CrossRef]
  95. Garcia-Molina, H.; Spauster, A.M. Ordered and reliable multicast communication. ACM Trans. Comput. Syst. 1991, 9, 242. [Google Scholar] [CrossRef]
  96. Moyer, M.; Rao, J. A survey of security issues in multicast communications. IEEE Netw. 1999, 13, 12. [Google Scholar] [CrossRef]
  97. Kim, J.; Joung, J.; Lee, J.W. Resource allocation for multiple device-to-device cluster multicast communications underlay cellular networks. IEEE Commun. Lett. 2018, 22, 412. [Google Scholar] [CrossRef]
  98. Xiong, J.; Ma, D.; Zhao, H.; Gu, F. Secure multicast communications in cognitive satellite-terrestrial networks. IEEE Commun. Lett. 2019, 23, 632. [Google Scholar] [CrossRef]
  99. Wang, Z.; Hu, J.; Liu, G.; Ma, Z. Optimal power allocations for relay-assisted NOMA-based 5G V2X broadcast/multicast communications. In Proceedings of the IEEE/CIC International Conference on Communications, Beijing, China, 16–18 August 2018; IEEE Press: Piscataway, NJ, USA, 2018. [Google Scholar]
  100. Yang, W.; Chen, Y.; Huang, Z.; Zhang, H.; Gu, H.; Yu, C. A Survey of Multicast Communication in Optical Network-on-Chip (ONoC). In Proceedings of the Parallel Architectures, Algorithms and Programming: 10th International Symposium, PAAP 2019, Guangzhou, China, 12–14 December 2019; Springer: Singapore, 2020. [Google Scholar]
  101. Du, J.; Wang, J. Design of on-chip N-fold orbital angular momentum multicasting using V-shaped antenna array. Sci. Rep. 2015, 5, 1. [Google Scholar] [CrossRef]
  102. Cai, A.; Li, Y.; Chen, J.; Shen, J. Coordinating Multiple Light-Trails in Multicast Elastic Optical Networks With Adaptive Modulation. IEEE Photonics J. 2023, 15, 1. [Google Scholar] [CrossRef]
  103. Wang, J.; Liu, J.; Li, S.; Zhao, Y.; Du, J.; Zhu, L. Orbital angular momentum and beyond in free-space optical communications. Nanophotonics 2021, 11, 645. [Google Scholar] [CrossRef]
  104. Yan, Y.; Yue, Y.; Huang, H.; Ren, Y.; Ahmed, N.; Willner, A.; Dolinar, S. Spatial-mode multicasting of a single 100-Gbit/s orbital angular momentum (OAM) mode onto multiple OAM modes. In Proceedings of the European Conference and Exhibition on Optical Communication, Amsterdam, The Netherlands, 16–20 September 2012; Optica Publishing Group: Washington, DC, USA, 2012. [Google Scholar]
  105. Yan, Y.; Yue, Y.; Huang, H.; Ren, Y.; Ahmed, N.; Tur, M.; Dolinar, S.; Willner, A. Multicasting in a spatial division multiplexing system based on optical orbital angular momentum. Opt. Lett. 2013, 38, 3930. [Google Scholar] [CrossRef] [PubMed]
  106. Li, S.; Wang, J. Adaptive power-controllable orbital angular momentum (OAM) multicasting. Sci. Rep. 2015, 5, 9677. [Google Scholar] [CrossRef] [PubMed]
  107. Almaiman, A.; Song, H.; Minoofar, A.; Song, H.; Zhang, R.; Su, X.; Zou, Z.; Pang, K.; Liu, C.; Liao, P.; et al. Demonstration of QPSK data correlation and equalization using a tunable optical tapped delay line based on orbital angular momentum mode delays. Opt. Commun. 2022, 503, 127438. [Google Scholar] [CrossRef]
  108. Shang, Z.; Fu, S.; Hai, L.; Zhang, Z.; Li, L.; Gao, C. Multiplexed vortex state array toward high-dimensional data multicasting. Opt. Express 2022, 30, 34053. [Google Scholar] [CrossRef] [PubMed]
  109. Meng, W.; Li, B.; Luan, H.; Gu, M.; Fang, X. Orbital Angular Momentum Neural Communications for 1-to-40 Multicasting with 16-Ary Shift Keying. ACS Photonics 2023, 10, 2799. [Google Scholar] [CrossRef]
  110. Li, S.; Wang, J. Compensation of a distorted N-fold orbital angular momentum multicasting link using adaptive optics. Opt. Lett. 2016, 41, 1482–1485. [Google Scholar] [CrossRef] [PubMed]
  111. Li, Q.; Wu, C.; Zhang, Z.; Zhao, S.; Zhong, B.; Li, S.; Li, H.; Jin, L. High-purity multi-mode vortex beam generation with full complex-amplitude-controllable metasurface. IEEE Trans. Antennas Propag. 2022, 71, 774–782. [Google Scholar] [CrossRef]
  112. Almaiman, A.; Song, H.; Minoofar, A.; Song, H.; Zhang, R.; Su, X.; Zou, K.; Pang, K.; Liu, C.; Liao, P.; et al. Experimental Demonstration of a Data Correlation and Data Equalization using a Tunable Optical Tapped-Delay-Line Using the Spatial Domain and Modal-Dependent Delays. In Proceedings of the CLEO: Science and Innovations 2020, Washington, DC, USA, 10–15 May 2020. ISBN 978-1-943580-76-7; From the session Emerging Platforms in Integrated Photonics (STu3O). [Google Scholar]
  113. Xue, X.; Calabretta, N. Nanosecond optical switching and control system for data center networks. Nat. Commun. 2022, 13, 2257. [Google Scholar] [CrossRef] [PubMed]
  114. Sasikala, V.; Chitra, K. All optical switching and associated technologies: A review. J. Opt. 2018, 47, 307. [Google Scholar] [CrossRef]
  115. Song, X.; Ma, J.; Bai, Y.; Yao, Y.; Zheng, Z.; Gao, X.; Huang, S. Optical-controlled fast switching of radio frequency orbital angular momentum beams with different mode and radiation direction. J. Light. Technol. 2021, 40, 640. [Google Scholar] [CrossRef]
  116. Meng, W.; Hua, Y.; Cheng, K.; Li, B.; Liu, T.; Chen, Q.; Luan, H.; Gu, M.; Fang, X. 100 Hertz frame-rate switching three-dimensional orbital angular momentum multiplexing holography via cross convolution. Opto-Electron. Sci. 2022, 1, 220004-10. [Google Scholar] [CrossRef]
  117. Liu, Z.; Gao, S.; Lai, Z.; Li, Y.; Ao, Z.; Li, J.; Tu, J.; Wu, Y.; Liu, W.; Li, Z. Broadband, Low-Crosstalk, and Massive-Channels OAM Modes De/Multiplexing Based on Optical Diffraction Neural Network. Laser Photonics Rev. 2023, 17, 2200536. [Google Scholar] [CrossRef]
  118. Wu, G.; Wu, X.; Gao, S.; Tu, J.; Zhou, J.; Sui, Q.; Liu, W.; Li, Z. Multi-channel higher-order OAM generation and switching based on a mode selective interferometer. Opt. Express 2022, 30, 25093. [Google Scholar] [CrossRef] [PubMed]
  119. Lemon, M.; Robertson, E.; Free, J.; Dai, K.; Miller, J.K.; Vanderschaaf, L.; Cox, M.; Watkins, R.J.; Johnson, E.G. Sensing and coupling of optical channels in dynamic atmospheric turbulence using OAM beamlets for improved power and data transmission. Opt. Express 2022, 30, 47598. [Google Scholar] [CrossRef]
  120. Yue, Y.; Ahmed, N.; Huang, H.; Yan, Y.; Ren, Y.; Rogawski, D.; Willner, A.E. Reconfigurable orbital-angular-momentum-based switching among multiple 100-Gbit/s data channels. In Proceedings of the Optical Fiber Communication Conference, Anaheim, Calif, 17–21 March 2013; Optica Publishing Group: Washington, DC, USA, 2013. [Google Scholar]
  121. Wang, J.; Yang, J.Y.; Fazal, I.M.; Ahmed, N.; Yan, Y.; Huang, H.; Ren, Y.; Yue, Y.; Dolinar, S.; Tur, M.; et al. Terabit free-space data transmission employing orbital angular momentum multiplexing. Nat. Photonics 2012, 6, 488. [Google Scholar] [CrossRef]
  122. Ahmed, N.; Huang, H.; Ren, Y.; Yan, Y.; Xie, G.; Willner, A.E. Reconfigurable 2 × 2 orbital angular momentum based optical switching of 50-Gbaud QPSK 884 channels. Opt. Express 2014, 22, 756. [Google Scholar] [CrossRef] [PubMed]
  123. Liu, J.; Wang, J. Demonstration of reconfigurable joint orbital angular momentum mode and space switching. Sci. Rep. 2016, 6, 60. [Google Scholar] [CrossRef] [PubMed]
  124. Lei, T.; Gao, S.; Li, Z.; Yuan, Y.; Li, Y.; Zhang, M.; Liu, G.N.; Xu, X.; Tian, J.; Yuan, X. Fast-switchable OAM-based high capacity density optical router. IEEE Photon. J. 2017, 9, 1. [Google Scholar] [CrossRef]
  125. Zhang, N.; Scaffardi, M.; Malik, N.M.; Toccafondo, V.; Klitis, C.; Lavery, M.P.J.; Meloni, G.; Fresi, F.; Lazzeri, E.; Marini, D.; et al. 4 OAM × 4 WDM Optical Switching Based on an Innovative Integrated Tunable OAM Multiplexer. In Proceedings of the 2018 Optical Fiber Communications Conference and Exposition (OFC), San Diego, CA, USA, 11–15 March 2018; pp. 1–3. [Google Scholar]
  126. Chen, S.; Ke, X. Demonstration of Orbital-Angular-Momentum-Based Optical Switching Using Dual-Area Mirrors. Opt. Photonics J. 2021, 11, 351. [Google Scholar] [CrossRef]
  127. Scaffardi, M.; Malik, M.N.; Zhang, N.; Rydlichowski, P.; Toccafondo, V.; Klitis, C.; Lavery, M.P.J.; Zhu, J.; Cai, X.; Yu, S.; et al. 10 OAM × 16 Wavelengths Two-Layer Switch Based on an Integrated Mode Multiplexer for 19.2 Tb/s Data Traffic. J. Light. Technol. 2021, 39, 3217. [Google Scholar] [CrossRef]
  128. Srinivasu, S.; Wanare, H. Graded-azimuthal-index fiber as a control element for radial-index and orbital-angular-momentum modes of Laguerre-Gaussian beams. Phys. Rev. A 2023, 107, 013517. [Google Scholar] [CrossRef]
  129. Nadi, M.; Sedighy, S.; Cheldavi, A. Multimode OAM Beam Generation through 1-Bit Programmable Metasurface Antenna for High throughput Data Communications. 2023. Available online: https://www.researchsquare.com/article/rs-3022677/v1 (accessed on 15 October 2023).
  130. Chen, Y.; Zheng, S.; Xiong, X.; Zhu, S.; Xiong, X.; Zhu, Z.; Pan, B.; Ren, C.; Hui, X.; Jin, X.; et al. Experimental Demonstration of OAM Spatial Field Digital Modulation Communication System. IEEE Commun. Lett. 2022, 26, 2470. [Google Scholar] [CrossRef]
  131. Reddy, A.N.K.; Anand, V.; Podlipnov, V.V.; Khonina, S.N.; Juodkazis, S. Simultaneous Detection of Modal Composition and Wavelength of OAM Fields Using a Hexagonal Vortex Filter. In Proceedings of the 2022 Photonics & Electromagnetics Research Symposium (PIERS), Hangzhou, China, 25–27 April 2022; pp. 981–984. [Google Scholar]
  132. Zhang, J.; Wu, X.; Lau, A.P.T.; Li, Z.; Lu, C. Dynamic analysis of PAM-4 IM/DD OAM-based MGDM transmission enabled by mode-group filter approach. Opt. Lett. 2023, 48, 3259. [Google Scholar] [CrossRef]
  133. Zou, K.; Pang, K.; Song, H.; Fan, J.; Zhao, Z.; Song, H.; Zhang, R.; Zhou, H.; Minoofar, A.; Liu, C.; et al. High-capacity free-space optical communications using wavelength-and mode-division-multiplexing in the mid-infrared region. Nat. Commun. 2022, 13, 7662. [Google Scholar] [CrossRef] [PubMed]
  134. Huang, H.; Ren, Y.; Xie, G.; Yan, Y.; Yue, Y.; Ahmed, N.; Lavery, M.P.J.; Padgett, M.J.; Dolinar, S.; Tur, M.; et al. Tunable orbital angular momentum mode filter based on optical geometric transformation. Opt. Lett. 2014, 39, 1689. [Google Scholar] [CrossRef]
  135. Gao, S.; Lei, T.; Li, Y.; Yuan, Y.; Xie, Z.; Li, Z.; Yuan, X. OAM-labeled free-space optical flow routing. Opt. Express 2016, 24, 21642. [Google Scholar] [CrossRef] [PubMed]
  136. Li, W.; Zhao, S. Orbital angular momentum filter based on multiple-beam interference. Opt. Commun. 2019, 430, 98. [Google Scholar] [CrossRef]
  137. Rao, X.; Yang, L.; Su, J.; Ban, Q.; Deng, X.; Wang, W. Spin-entangled orbital angular momentum filter of photons based on a chiral long-period fiber grating. Opt. Lett. 2022, 47, 5758. [Google Scholar] [CrossRef]
  138. Wu, G.; Gao, S.; Tu, J.; Shen, L.; Feng, Y.; Sui, Q.; Liu, W.; Li, Z. Mode manipulation in a ring–core fiber for OAM monitoring and conversion. Nanophotonics 2022, 11, 4889. [Google Scholar] [CrossRef]
  139. Shukla, A.; Gupta, S. Joint WDM and OAM Mode Group Multiplexed Transmission Over Conventional Multimode Fiber. IEEE Photon. J. 2023. Available online: https://ieeexplore.ieee.org/abstract/document/10114950 (accessed on 15 October 2023).
  140. Li, Z.; Chai, J.; Lu, Y.; Zhang, J.; Jiang, Z.F.; Liu, W. Mode decomposition of a few-mode fiber with OAM eigenmodes. In Proceedings of the 2nd International Conference on Laser, Optics and Optoelectronic Technology, Qingdao, China, 20–22 May 2022. [Google Scholar]
  141. Liang, L.; Cheng, W.; Zhang, H.; Li, Z.; Li, Y. Orbital-angular-momentum based mode-hopping: A novel anti-jamming technique. In Proceedings of the 2017 IEEE/CIC International Conference on Communications, Qingdao, China, 22–24 October 2017; IEEE Press: Piscataway, NJ, USA, 2017. [Google Scholar]
  142. Zhao, Y.; Ge, Y.; Yang, Z.; Ju, G.; Ma, L.; Lu, Y.; Guan, Y.L. OAM-based Reconfigurable Doppler Shifts Enable PAPR Reduction for Multi-carrier Doppler Diversity. In Proceedings of the 2022 Asia-Pacific Microwave Conference (APMC), Yokohama, Japan, 29 November–2 December 2022; pp. 485–487. [Google Scholar]
  143. Zhu, L.; Yao, H.; Wang, J.; Zhang, Q.; Hanzo, L. Channel modeling for orbital angular momentum based underwater wireless optical systems. IEEE Trans. Veh. Technol. 2022, 71, 5880–5895. [Google Scholar] [CrossRef]
  144. Zeng, Q.; Zhong, J.; Liu, X. Sparse Code Multiple Access Communication Networks Based on Multi-Level Quality-of-Service Frequency-hopping for Heterogeneous Multi-tier Multi-cell. J. Electron. Inf. Techn. 2022, 44, 2977–2985. [Google Scholar]
  145. Willner, A.; Ren, Y.; Xie, G.; Zhao, Z.; Cao, Y.; Li, L.; Ahmed, N.; Wang, Z.; Yan, Y.; Liao, P.; et al. Experimental demonstration of 20 Gbit/s data encoding and 2 ns channel hopping using orbital angular momentum modes. Opt. Lett. 2015, 40, 5810. [Google Scholar] [CrossRef] [PubMed]
  146. Liang, L.; Cheng, W.; Zhang, W.; Zhang, H. Mode hopping for anti-jamming in radio vortex wireless communications. IEEE Trans. Veh. Technol. 2018, 67, 7018–7032. [Google Scholar] [CrossRef]
  147. Liang, L.; Cheng, W.; Zhang, W.; Zhang, H. Index-modulation embedded mode hopping for antijamming. IEEE Syst. J. 2022, 16, 3905. [Google Scholar] [CrossRef]
  148. Zhu, L.; Yao, H.; Chang, H.; Tian, Q.; Zhang, Q.; Xin, X.; Yu, F.R. Adaptive Optics for Orbital Angular Momentum-Based Internet of Underwater Things Applications. IEEE Internet Things J. 2022, 9, 24281. [Google Scholar] [CrossRef]
  149. Liu, S.; Chen, P.; Ge, S.; Zhu, L.; Zhang, Y.H.; Lu, Y.Q. 3D Engineering of Orbital Angular Momentum Beams via Liquid-Crystal Geometric Phase. Laser Photonics Rev. 2022, 16, 2200118. [Google Scholar] [CrossRef]
  150. Zhang, L.; Zhu, Y.; Chen, Y.; Xie, W. Parameter Extraction of Accelerated Motion Targets Based on Vortex Electromagnetic Wave Radar. IEEE Geosci. Remote Sens. Lett. 2023. Available online: https://ieeexplore.ieee.org/abstract/document/10128984 (accessed on 15 October 2023).
  151. Yang, L.; Huang, S.; Zhu, G. Jointly Detecting Atmospheric Turbulence and Recognizing OAM Modes Via a Residual Network. Wirel. Pers. Commun. 2023, 131, 187–196. [Google Scholar] [CrossRef]
  152. Huang, H.; Yue, Y.; Yan, Y.; Ahmed, N.; Ren, Y.; Tur, M.; Willner, A.E. Liquid-crystal-on-silicon-based optical add/drop multiplexer for orbital-angular-momentum-multiplexed optical links. Opt. Lett. 2013, 38, 5142. [Google Scholar] [CrossRef]
  153. Feng, Z. Research on High-Efficiency Measurement of OAM Beam Based on Geometric Optical Transformation and Its Application Technology; Hefei University of Technology: Hefei, China, 2019. [Google Scholar]
  154. Feng, Z.; Wang, X.; Dedo, M.I.; Guo, K.; Shen, F.; Kai, C.; Guo, Z. High-density Orbital Angular Momentum mode analyzer based on the mode converters combining with the modified Mach–Zehnder interferometer. Opt. Commun. 2019, 435, 441. [Google Scholar] [CrossRef]
  155. Xiong, W.; Huang, Z.; Wang, P.; Wang, X.; He, Y.; Wang, C.; Liu, J.; Ye, H.; Fan, D.; Chen, S. Optical diffractive deep neural network-based orbital angular momentum mode add–drop multiplexer. Opt. Express 2021, 29, 36936–36952. [Google Scholar] [CrossRef]
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Figure 1. Principle or experimental setup of OAM-RDs based on OAM channel multicasting (I); (a) experimental setup for OAM-mode multicasting [104], Col: Collimator; (b) the concept of tunable OTDL system using the modal-dependent delays [107]; (c1,c2) the multiplexed vortex state array [108]: (c1) depicts the concept of generating a multiplexed vortex state array using a phase-only hologram, and (c2) shows the experimental setup, BS, and beam splitter; L1~L4, lenses; CCD1&CCD2, infrared CCD camera; AS, aperture stop.
Figure 1. Principle or experimental setup of OAM-RDs based on OAM channel multicasting (I); (a) experimental setup for OAM-mode multicasting [104], Col: Collimator; (b) the concept of tunable OTDL system using the modal-dependent delays [107]; (c1,c2) the multiplexed vortex state array [108]: (c1) depicts the concept of generating a multiplexed vortex state array using a phase-only hologram, and (c2) shows the experimental setup, BS, and beam splitter; L1~L4, lenses; CCD1&CCD2, infrared CCD camera; AS, aperture stop.
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Figure 2. Working principle and experimental setup of OAM-RDs based on OAM channel multicasting (II) [109]: (a) principle of OAM neural communication, and (b) experimental setup.
Figure 2. Working principle and experimental setup of OAM-RDs based on OAM channel multicasting (II) [109]: (a) principle of OAM neural communication, and (b) experimental setup.
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Figure 3. Principle or experimental setup of OAM-RDs based on OAM channel switching(I) (a) Functional block diagram of the 2 × 2 OAM-based switch [122]; (b) experimental setup of reconfigurable 4 × 4 OAM mode switching, space switching, and joint OAM mode and space switching [123]; (c) the schematic diagram of multi-channel MSI [118]; (d) experimental setup for the mode generation, dynamic switching, and detection between OAM modes. OC, 50:50 optical coupler; PC, polarization controller; H, holder; R, rotator; Obj, objective; ATT, attenuator; BS, beam splitter; Col, collimator; SLM, spatial light modulator; CCD, charge-coupled device [118].
Figure 3. Principle or experimental setup of OAM-RDs based on OAM channel switching(I) (a) Functional block diagram of the 2 × 2 OAM-based switch [122]; (b) experimental setup of reconfigurable 4 × 4 OAM mode switching, space switching, and joint OAM mode and space switching [123]; (c) the schematic diagram of multi-channel MSI [118]; (d) experimental setup for the mode generation, dynamic switching, and detection between OAM modes. OC, 50:50 optical coupler; PC, polarization controller; H, holder; R, rotator; Obj, objective; ATT, attenuator; BS, beam splitter; Col, collimator; SLM, spatial light modulator; CCD, charge-coupled device [118].
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Figure 4. Principle or experimental setup of OAM-RDs based on OAM channel switching(II): (a) schematic of OAM-RD for intra-datacenter optical interconnects [124]; (b1,b2) the reconfigurable optical switching based on OAM [126]; (b1) dual-area mirror and principle of separating multiplexed beams; and (b2) principle of OAM-based optical switching.
Figure 4. Principle or experimental setup of OAM-RDs based on OAM channel switching(II): (a) schematic of OAM-RD for intra-datacenter optical interconnects [124]; (b1,b2) the reconfigurable optical switching based on OAM [126]; (b1) dual-area mirror and principle of separating multiplexed beams; and (b2) principle of OAM-based optical switching.
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Figure 6. Principle or experimental setup of OAM-RDs based on OAM channel hopping: (a) spatial domain channel hopping principle based on OAM mode [145]; (b) the schematic diagram MFH system model [146].
Figure 6. Principle or experimental setup of OAM-RDs based on OAM channel hopping: (a) spatial domain channel hopping principle based on OAM mode [145]; (b) the schematic diagram MFH system model [146].
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Figure 7. Principle or experimental setup of OAM-RD for OAM channel adding/extracting: (a) concept of OAM channel add/drop multiplexing [152]; (b) the schematic of the modified MZI [154], BS: beam splitter, M: mirror, and DP: Dove prism; (c) concept of OADM for OAM add-drop multiplexing [155].
Figure 7. Principle or experimental setup of OAM-RD for OAM channel adding/extracting: (a) concept of OAM channel add/drop multiplexing [152]; (b) the schematic of the modified MZI [154], BS: beam splitter, M: mirror, and DP: Dove prism; (c) concept of OADM for OAM add-drop multiplexing [155].
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Table 1. Schematic diagram of OAM router function and previous works related to OAM-RD.
Table 1. Schematic diagram of OAM router function and previous works related to OAM-RD.
OAM-RDSchematic DiagramFunctionReference
MulticastingSensors 24 00944 i001Extended communication link[95,96,97,98,99,100,101,102,103,104,105,106,107,108,109,110,111,112]
SwitchingSensors 24 00944 i002Exchanging data[113,114,115,116,117,118,119,120,121,122,123,124,125,126,127]
FilteringSensors 24 00944 i003Extracting specific channel[128,129,130,131,132,133,134,135,136,137,138,139,140]
HoppingSensors 24 00944 i004Anti-interference[141,142,143,144,145,146,147,148,149]
Adding/
Extracting		Sensors 24 00944 i005Improved the scalability of channels[150,151,152,153,154,155]
Table 2. Summary of channel multicasting routers used for the OAM-based optical communications.
Table 2. Summary of channel multicasting routers used for the OAM-based optical communications.
YearMethodInputOutputEquipmentStrengths/
Weaknesses		Transmission
Result		Ref.
2013Sliced phase patternsSingle OAMMultiple same-mode-spacing OAMs SLMLow loss efficiency/
Low integration		Channel crosstalk < −20 dB[105]
2015Adaptive correctionGaussian beamMultiple collinear superposition OAMSLMOutput power adjustable/
Limited mode selection		Maximum power deviation is ~0.3 dB[106]
2022Optical tapped-delay-linesGaussian beamMultiple adjustable OAMSLMReduced error vector magnitude (EVM) Error-vector magnitude is ~12.9%[107]
2022Multiplexed vortex state arrayMultiplex OAMMultiple multiplexed OAMSLMHigh channel utilization/-The mean square error is 1.06 × 10−3[108]
202316-ary shift keyingMultiplex OAMMultiple multiplexed OAMSLM-/Ultra-high precision, 1-to-40
multicasting		The mean square error is 0.02, BER of 0[109]
Table 3. Summary of channel-switching routers used for the OAM-based optical communications.
Table 3. Summary of channel-switching routers used for the OAM-based optical communications.
YearMethodsEquipmentStrengths/
Weaknesses		Transmission
Result		Ref.
2013Reconfigurable optical networking functionsSLMMulti-pair data channel exchange/Cumbersome structureThe average conversion efficiency is −3.6 dB[120]
2013Mode overlaySLMSimple structure/
Only switch the single OAM 		When the BER is 1 × 10−9, the power loss is less than 2.4 dB[121]
2013Reconfigurable 2 × 2 switchSLM-Signal-to-noise ratio less than 2.5 dB[122]
2016Space switchingSLMAdjustable output position/
Complex system and high device cost		-[123]
2017Optical vortex gratingDigital micromirrorFast switching speed/-The router has a fast-switching time of 6.9 μs [124]
2021Optical separationReflector and SLMSimple structure and low cost/
-		-[126]
Table 4. Summary of channel filtering routers used for the OAM-based optical communications.
Table 4. Summary of channel filtering routers used for the OAM-based optical communications.
YearMethodsEquipmentStrengths/
Weaknesses		Transmission
Result		Ref.
2014Optical geometric transformationSLMMode adjustable/
Difficult to filter out OAM with small mode intervals		The output power rejection ratio of blocking mode and propagation mode exceeds 14.5 dB.[134]
2016Labeling overlapped optical flowsDammann optical vortex gratingDiversified function/-The power of the blocked output port is suppressed by more than 23 dB by the filter[135]
2019Controlling the phase differenceInterferometerReduce the overlapping effect of adjacent OAM models/-Specific OAM schema values can achieve 100% passing theoretically[136]
2022Chiral long-period fiber gratingSLM, gratingWithout exerting extra loss for other OAM/--[137]
Table 5. Summary of channel hopping routers used for the OAM-based optical communications (PNG, pseudorandom noise sequence generator; BPF, band pass filter; LPF, low pass filter; UCA, uniform circular array).
Table 5. Summary of channel hopping routers used for the OAM-based optical communications (PNG, pseudorandom noise sequence generator; BPF, band pass filter; LPF, low pass filter; UCA, uniform circular array).
YearMethodsEquipmentHopping TypeStrengths/
Weaknesses		Transmission
Result		Ref.
2015Mode hopping controllerDigital micromirrorOAM modeFast Channel hopping/Additional lossesThe measured power penalties are below 5.3 dB.[145]
2018Orthogonality of OAM modesPNG, BPF, LPF, integratorOAM mode, frequencyLow BER/
Low integration		The BER is much lower than the traditional method[146]
2022IM-MH schemeSignal modulator, index selector, UCA mode hoppingLow ABERs and
Increase the SE/
-		The ABER is around 25% of the traditional scheme[147]
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Wang, B.; Zhang, X.; Tian, J.; Merabet, B.; Li, Z.; Shah, S.A.A.; Lei, Y.; Liu, B.; Guo, K.; Guo, Z. Research Progress on Router Devices for the OAM Optical Communication. Sensors 2024, 24, 944. https://doi.org/10.3390/s24030944

AMA Style

Wang B, Zhang X, Tian J, Merabet B, Li Z, Shah SAA, Lei Y, Liu B, Guo K, Guo Z. Research Progress on Router Devices for the OAM Optical Communication. Sensors. 2024; 24(3):944. https://doi.org/10.3390/s24030944

Chicago/Turabian Style

Wang, Binbin, Xizheng Zhang, Jinlong Tian, Badreddine Merabet, Zhixiang Li, Syed Afaq Ali Shah, Yi Lei, Bingyi Liu, Kai Guo, and Zhongyi Guo. 2024. "Research Progress on Router Devices for the OAM Optical Communication" Sensors 24, no. 3: 944. https://doi.org/10.3390/s24030944

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