The scientific community has been dealing with big data for a long time. Due to advancement in sensing, networking, and storage technology, other domains such as business, health, and social media followed. Data are considered the gold of the 21st century and are being collected, stored, and analyzed at a rapid pace. The amount of data being collected creates a compelling case for investing in hardware and software research to support generating even more data from new sensors and with better quality. It also creates a compelling case for investing in research and development of new hardware and software for data analytics. This special section of Optical Engineering explores the optical and hybrid imaging and processing technology that will enable capturing and analyzing large amounts of data or help stream the data for further exploration and analysis.

The paper “Design for source-and-detector configuration of a ring-scanning-based near-infrared optical imaging system” by J.-M. Yu, M.-C. Pan, and M.-C. Pan describes the design scheme of the source-and-detector arrangement of a ring scanning–based near-infrared optical system. The new design helps reduce the time required for data acquisition by dividing circular scanning into several zones, each of which includes $n$ sources and $l$ detectors; i.e., $m$ zones and $n$ sources along with $l$ detectors per zone. The influences of the source-and-detector arrangement on the resulting images are evaluated and a formula to estimate the scanning time is provided. Reducing data acquisition time for images is important for real time and streaming data analysis. Several domains can benefit from such advancements.

The paper titled “Full-range in-plane rotation measurement for image recognition with hybrid digital-optical correlator” by T. Zheng et al. is an excellent example of the kind of research and development needed in order to speed up the analysis of images. Several applications can benefit from the ability to compute the correlation of images at a high speed. The algorithm will help compare images in the absence of coordinate matching or geo-registration since it uses the two-step rotation with finer resolution in the second step. Health, astronomy, remote sensing, and other domains will find this algorithm very useful. Also, enhancing the speed of image correlation will introduce new challenges to consequent steps in the image-analysis pipeline since the data will be produced faster.

The paper “Three random phase encryption technology in the Fresnel diffraction system based on computer-generated hologram” by S. Xi et al. proposes a new method for image encryption using a Fourier computer-generated hologram (CGH) in the encryption system of multiple Fresnel diffraction transforms with phase masks. The first two papers demonstrated technologies for speeding up image acquisition and correlation computing (image analysis); however, images have to be transferred over the network for analysis purposes. There are several domains that require high security for image transmission over the network. The proposed algorithms are very useful, and in some cases necessary, to guarantee the security or privacy of transferred images.

The paper titled “Acceleration of split-field finite difference time-domain method for anisotropic media by means of graphics processing unit computing” by J. Francés et al. discusses the implementation of split-field finite difference time domain applied to light-wave propagation through periodic media with an arbitrary anisotropy method in graphics processing units (GPUs). The authors also elaborate on the performance of the CPU and GPU implementation in several different applications such as in binary phase grating in dielectric medium and gratings in liquid crystal medium.

The last paper in the special section titled “Shoreline extraction from light detection and ranging digital elevation model data and aerial images” by A.Yousef, K. Iftekharuddin, and M. Karim discusses the implementation of two innovative algorithms for extracting shorelines from images depending on the available data sources. The first algorithm uses multistep morphological techniques to detect and eliminate outliers from waves; in addition, it uses Hough transform to identify and eliminate objects such as docks, bridges, and fishing piers. The second algorithm uses training data and support vector machines classifier to segment the data into water and land. The performance is compared to other techniques to show the effectiveness of the new approach.

Although the set of papers in this special section is relatively small, the diversity of the topics discussed and the techniques used to speed up data acquisition and analysis is still apparent. This is an attempt to encourage the optics community to engage in the emerging data-intensive applications field and explore how optical engineering can contribute to the state of the art to extract the knowledge buried in these data. Hardware-accelerated algorithms such as the ones discussed in the first two papers are important for speeding up data analysis. The rest of the papers contributed algorithms that are useful for the data mining community in general. We hope this issue will spur new activities and collaboration in this emerging field.