摘要
随着云计算和数据中心的高速发展,片上集成光互连和光处理凭借在集成度、速度、带宽及功耗等方面的独特优势,成为突破传统电子瓶颈的关键技术。同时,光子具有频率、偏振、时间、复振幅及空间结构等多个物理维度,可发展为多维混合复用技术,进一步提升光互连和光处理的带宽。结合光场多个物理维度资源,分别对片上集成多维光互连和光处理的关键技术进行了回顾,并对其未来发展趋势进行总结和展望。
Significance In the past half century,integrated circuits(ICs)supported by complementary metal-oxide semiconductor(CMOS)technology have developed rapidly,which promotes the continuous progress of modern information technology.As the feature size of transistors continues to decrease,the semiconductor-manufacturing process is gradually approaching its limit,resulting in slow or even stagnant improvement of integration.Meanwhile,the system performance is seriously restricted,mainly due to the electronic bottleneck.In addition,with the increase in the number of microprocessors and computing speed,power consumption and heat dissipation due to parasitic effects are becoming the main limiting factors.To break through the bottleneck of conventional IC technology in the post-Moore era,optical interconnects are considered to gradually replace conventional electrical interconnects.Compared with electrical signals,using light as the carrier for signal transmission has its unique advantages,such as large bandwidth,low loss,strong anti-electromagnetic interference capability,and high-speed parallel transmission without crosstalk.Therefore,optical interconnects will undoubtedly become the enabling technology for high-speed data transfer.Concurrently,at the network nodes,conventional optical-electrical-optical signal processing is still limited by the electronic bottleneck.Processing signals in the optical domain offer an effective strategy to increase speed.Consequently,on-chip optical interconnects and processing are paramount to the development of modern high-speed and large-capacity communication networks.The photonic integrated circuit(PIC)is paramount to realize on-chip optical interconnects and processing,which achieves rapid development in recent years.Silicon and III-V are both promising materials for the PIC platform.The main advantage of InP and other III-V materials is that they are direct bandgap materials,which can be used to fabricate semiconductor lasers,amplifiers,modulators,detectors,and other active devices.However,the cost is relatively high and size is relatively large,which limit their large-scale commercialization.By contrast,silicon materials have distinct advantages of large reserves in nature,low cost,almost transparent in the nearinfrared and even mid-infrared bands,low loss,and large refractive index contrast of silicon on insulator(SOI),making them suitable for large-scale and high-density integration.Importantly,silicon materials are fully compatible with the existing mature CMOS process,which is essential for developing silicon-based PICs.Since silicon material is an indirect bandgap material,it is impossible to produce high-efficiency light sources.Monolithic integration of all active and passive devices on a single material platform is still challenging.The hybrid integration technology provides a possible solution,which enables the integration of discrete active devices,such as lasers and amplifiers,onto silicon-based passive devices through co-packaging,epitaxial bonding,and monolithic growth to realize low-cost and high-performance hybrid PICs.Although on-chip optical interconnects and processing are the development trends of high-speed communication networks,the sustainable increase of communication capacity is still crucial in the big data era with increasing capacity demand.Notably,photons have multiple physical dimensions,such as frequency/wavelength,polarization,time,complex amplitude,and spatial structure,which can be developed into multiple multiplexing and advanced modulation technologies,making it possible to realize ultra-high-capacity optical communications and interconnects.Wavelength-division multiplexing(WDM),time-division multiplexing(OTDM),polarizationdivision multiplexing(PDM),space-division multiplexing,and advanced modulation formats have rapidly developed in the past few decades,significantly increasing the transmission capacity of optical communication systems.Therefore,on-chip optical interconnects and processing should also exploit multiple physical dimensions of photons.Particularly,multiple multiplexing technologies and advanced modulation formats can be combined to effectively increase the number of signal channels and aggregate capacity of on-chip optical interconnects and processing systems.Progress Here,we give a comprehensive review of on-chip integrated multidimensional optical interconnects and processing(Fig.1).The main characteristics of on-chip integrated multidimensional optical interconnects and processing are high integration,small footprint,high reliability,high speed,and low loss.The main contents of optical interconnects include on-chip data transmission of multidimensional optical signals(Fig.2),on-chip multidimensional multiplexing interconnects of optical signals(Fig.3),key integrated devices for optical interconnects(Fig.4),heterogeneous waveguide coupling for optical interconnects(Figs.5--7),and PICs/optical modules for optical interconnects(Fig.8).The main contents of optical processing include on-chip wavelength conversion(Fig.9),on-chip optical frequency comb(Fig.10),on-chip mode processing(Fig.11),on-chip polarization processing(Fig.12),on-chip optical logic and computing(Figs.13--16),on-chip reconfigurable optical processing(Fig.17),and on-chip intelligent optical processing(Fig.18).Conclusions and Prospects With the rapid development of cloud computing and data centers,on-chip integrated optical interconnects and processing have become the key technologies to break through the conventional electronic bottleneck with their unique advantages in integration,speed,bandwidth,power consumption,and multiple physical dimensions.In this article,we review the key technologies and recent progress of on-chip integrated multidimensional optical interconnects and processing.Looking to the future,one would expect the development trend toward multiple materials(III-V,silicon,silicon nitride,silica,polymer,lithium niobate,and 2Dmaterial),integrations(hybrid integration,monolithic integration,and integration of photonics and electronics),physical dimensions(frequency/wavelength,polarization,time,complex amplitude,and spatial structure),frequency bands(O+E+S+C+L+U,visible,mid-infrared,microwave,and terahertz),mediums(chip,fiber,free space,and underwater),functions(multifunction,reconfigurable,programmable,and intelligent),and applications(communications,sensing,measurement,imaging,computing,and quantum)(Fig.19).One typical example would be ultrahigh capacity silicon-based on-chip multidimensional multiplexing and processing system,which consists of an integrated transmitter,integrated receiver,silicon-based multidimensional multiplexing and processing chip incorporating hybrid wavelength/polarization/mode(de)multiplexer,optical switch array,reconfigurable optical add-drop multiplexer array,variable optical attenuator array,and optical power monitor array(Fig.20).
作者
王健
曹晓平
张新亮
Wang Jian;Cao Xiaoping;Zhang Xinliang(Wuhan National Laboratory for Optoelectronics,Huazhong University of Science and Technology,Wuhan,Hubei 430074,China)
出处
《中国激光》
EI
CAS
CSCD
北大核心
2021年第12期193-222,共30页
Chinese Journal of Lasers
基金
国家重点研发计划(2019YFB2203604)。
关键词
光电子学
光子集成
物理维度
多维复用
光互连
光处理
optoelectronics
photonic integration
physical dimension
multi-dimensional multiplexing
optical interconnect
optical processing