Toward Practical Optical Phased Arrays through Grating Antenna Engineering

Shuai, Youqiang; Zhou, Zhiping; Su, Hui

doi:10.3390/photonics10050520

Photonics

2023

DOI: 10.3390/photonics10050520

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Toward Practical Optical Phased Arrays through Grating Antenna Engineering

Youqiang Shuai

Zhiping Zhou

Hui Su

Abstract: In recent years, using silicon-based waveguide grating antennas in optical phased array has become a research focus. To date, this technique has not been widely implemented in practical applications. In this paper, the basic principle of a waveguide grating antenna is described, and the researches on effective length, uniform emission and the directionality of diffraction are summarized. Through analysis, it is found that there is a trend to prepare grating antennas by using a SiN/Si hybrid integrated platform… Show more

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Cited by 6 publications

References 41 publications

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Wide-angle non-uniform optical phased array using compact and efficient antenna design

Elsheikh,

Swillam

2024

Sci Rep

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In the need for a more compact and efficient optical phased array with a wide steering beam for LIDAR applications, a wide steering array with high resolution is desirable. However, in the published work, a trade-off is often made for one over another. Apodized grating antennas have shown good efficiency with a compact size and wide beam profile, which improve optical phased array beam steering capability and are also compatible with the CMOS silicon photonics process. A promising studies shows enhancement in steering range with good resolution utilizing a non-uniform optical phased array. In this work, we present two highly efficient optical antennas with 94% and 93.5% upward power at the center frequency for the first and second antenna respectively, exceeding state-of-the-artwork to the best of our knowledge, and wide full-width half maximum of 8.88° x 78.05° and 7.53° x 69.85° in elevation and azimuthal planes, respectively. Both antennas provide a broad bandwidth across the 1400–1700 nm wavelength range with more than 80% efficiency in the S, C, and L bands. To overcome the limited scan ranges and small aperture size, a two-dimensional non-uniform array of 10 × 10 elements is utilized to increase the beam steering capability. A genetic algorithm is used to optimize the position of array elements, resulting in an aliasing-free array with a wide steering range of 160° with beam width 0.5° and consistent −11 dB maximum side lobe level across the steering range.

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Wide-angle non-uniform optical phased array using compact and efficient antenna design

Elsheikh,

Swillam

2024

Sci Rep

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Compact and Efficient Transverse Spliced Waveguide Grating Antenna for Integrated Optical Phased Array

Maurya,

Chack,

Vickey

2024

IEEE Trans. Nanotechnology

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Silicon-based optical phased array with a reconfigurable aperture for “gaze” scanning of LiDAR

Hu,

He,

Chen

et al. 2024

Photon. Res.

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Light detection and ranging (LiDAR) serves as one of the key components in the fields of autonomous driving, surveying mapping, and environment detection. Conventionally, dense points clouds are pursued by LiDAR systems to provide high-definition 3D images. However, the LiDAR is typically used to produce abundant yet redundant data for scanning the homogeneous background of scenes, resulting in power waste and excessive processing time. Hence, it is highly desirable for a LiDAR system to “gaze” at the target of interest by dense scanning and rough sparse scans on the uninteresting areas. Here, we propose a LiDAR structure based on an optical phased array (OPA) with reconfigurable apertures to achieve such a gaze scanning function. By virtue of the cascaded optical switch integrated on the OPA chip, a 64-, 128-, 192-, or 256-channel antenna can be selected discretionarily to construct an aperture with variable size. The corresponding divergence angles for the far-field beam are 0.32°, 0.15°, 0.10°, and 0.08°, respectively. The reconfigurable-aperture OPA enables the LiDAR system to perform rough scans via the large beam spots prior to fine scans of the target by using the tiny beam spots. In this way, the OPA-based LiDAR can perform the “gaze” function and achieve full-range scanning efficiently. The scanning time and power consumption can be reduced by 1/4 while precise details of the target are maintained. Finally, we embed the OPA into a frequency-modulated continuous-wave (FMCW) system to demonstrate the “gaze” function in beam scanning. Experiment results show that the number of precise scanning points can be reduced by 2/3 yet can obtain the reasonable outline of the target. The reconfigurable-aperture OPA (RA-OPA) can be a promising candidate for the applications of rapid recognition, like car navigation and robot vision.

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Toward Practical Optical Phased Arrays through Grating Antenna Engineering

Cited by 6 publications

References 41 publications

Wide-angle non-uniform optical phased array using compact and efficient antenna design

Wide-angle non-uniform optical phased array using compact and efficient antenna design

Compact and Efficient Transverse Spliced Waveguide Grating Antenna for Integrated Optical Phased Array

Silicon-based optical phased array with a reconfigurable aperture for “gaze” scanning of LiDAR

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