Optics has been behind various enabling technologies to cope with the ever-increasing bandwidth demands at internet backbone level. Dense-wavelength-division-multiplexing (DWDM) allows concurrent transmissions of many channels of wide bandwidth data through a single fiber. The success of erbium-doped fiber amplifiers (EDFA) pushes the data regeneration distance longer and longer. The emerging massively parallel optical switches are revolutionizing all-optical communication networks. We are witnessing an era of renaissance of optics due to the communication infrastructure upgrade frenzy. High speed optics, once so prohibitively expensive that only long-haul communications was feasible, is being applied to ever-shorter distances, penetrating from metro-area to access and intra-computer interconnect networks. Bulk free-space optics is being miniaturized and integrated to serve critical missions to keep the pace of bandwidth booms. At the same time, the pace of developing wider bandwidth and more cost-effective solutions to sustain the explosive growth of bandwidth presents huge challenges and opportunities for optical scientists and engineers.

We are choosing this forum to present a special section dedicated to Active and Passive Components for Optical Networks with one main objective: to update on some of the latest research and development results in these areas which are critically important to wide bandwidth optical networking applications. Innovative and affordable component concepts are the emphasis of the special section.

The organization of the presentation adopts the cluster format, grouping papers in similar areas together. The presentation sequence is as follows. An invited paper from Eldada kicks off the special section with an overview of recent advances in telecom and datacom optical component developments. The first cluster behind the overview devotes to transmitters, modulators and receivers. Here we showcase some of the latest research works. The first paper in the cluster, from Michalzik et al.;, discusses the applications of short-wavelength vertical-cavity-surface-emitting lasers. The emphasis of this work is in optical interconnect and local access networks where communications distances are short. The next paper, by Liu et al.;, deals mainly with the wide-bandwidth multiple quantum-well based modulators and photo-detectors. The last paper of the cluster, by Wang et al.;, shows research results in photo-detectors, too. However, its focus is on Si-based resonant-cavity-enhanced photo-detectors. The next cluster of the special section is devoted to optical network amplifiers with two papers presenting latest results. The first one, by Liu et al.;, is in the area of L-band EDFA’s, and the second one, by Zhang et al.;, discusses about a new generation of narrow-band amplifier, called amplets aimed to applications of sub-system level optical power and dispersion management. The next cluster contains five papers in areas of filters and switches for DWDM-based network applications. First, Zhao et al.; demonstrates a grating-based wavelength demultiplexer which can potentially address cost concerns of the DWDM components. Then, Popelek and Li show a multiple-purpose optical filter architecture that can be used for WDM-based add/drop and wavelength routing applications. Following that paper, Sun et al.; discuss their innovative approach of using a polymeric electro-optic switch array suitable to planar light-wave integration to perform wide-band optical array switching. The next paper, by Ren et al.;, investigates experimentally dispersion compensation performance based on manipulating transmission properties of a fiber Bragg grating. Last but not least, Jeong and Lee show their theoretical analysis of a new type of fiber grating: liquid-crystal fiber grating for its suitability of fabricating long-period fiber gratings for dynamic gain flattening. The last cluster of the special section contains two papers dealing with radio-frequency (RF) oriented network applications. The first of the two, by Li et al.;, demonstrates a RF mixer based on a photo-detector fabricated using a metal-semiconductor-metal structure. Such RF mixer is a critical component to optical RF networks using sub-carrier modulations. The second paper, by Shi et al.; (also the last paper of the entire special section), discusses another mission—critical components in RF communications, a true-time-delay device. The paper presents a survey of current as well as promising technologies to implement the desired time-delay functions.

Active and passive components will continue to play important roles of building future optical networks of all levels. We hope this special section will serve to stimulate research and development interests in related areas going forward.