Your search keyword '"Jessica Onaka"' showing total 4 results

1. Varifocal optical lens using ultrasonic vibration and thixotropic gel

Author

Mami Matsukawa, Daiko Sakata, Takahiro Iwase, Daisuke Koyama, and Jessica Onaka

Subjects

Thixotropy, Materials science, Acoustics and Ultrasonics, business.industry, Deformation (meteorology), Piezoelectricity, law.invention, Lens (optics), Optics, Arts and Humanities (miscellaneous), law, Transmittance, Shear stress, Focal length, sense organs, Acoustic radiation force, business

Abstract

A variable focus optical lens using a thixotropic gel and ultrasonic vibration is discussed. The surface profile of the gel could be deformed via acoustic radiation force generated by ultrasound. A thixotropic gel in which the viscosity was changed by shear stress was employed as a transparent lens material. The thixotropic gel allowed the lens to maintain shape deformation in the absence of continuous ultrasound excitation. The lens had a simple structure with no mechanical moving parts and included an annular piezoelectric transducer, a glass disk, and the thixotropic gel film. The axisymmetric concentric flexural vibration mode was generated on the lens at 71 kHz, which resulted in static surface deformation of the gel via the acoustic radiation force. The preservation rate was investigated after switching off the ultrasonic excitation. There was a trade-off between the preservation rate of the lens deformation and the response time for focusing. The focal length could be controlled via the input voltage to the lens, and a variable-focus convex lens could be realized; the change in the focal length with 4.0 Vpp was 0.54 mm. The optical transmittance of the lens was measured and the transmittance ranged 70%–80% in the visible spectral region.

Published

2021

2. Evaluation of the Optical Characteristics of the Liquid Crystal Lens Using a Shack-Hartmann Wavefront Sensor

Author

Mami Matsukawa, Jessica Onaka, Takahiro Iwase, and Daisuke Koyama

Subjects

Materials science, business.industry, Physics::Optics, Wavefront sensor, Piezoelectricity, law.invention, Lens (optics), Standing wave, Optics, Liquid crystal, law, Electric field, Ultrasonic sensor, business, Shack–Hartmann wavefront sensor

Abstract

Although ultrasonically controlled liquid crystal lens may play in important role in future optical systems, many optical properties in the liquid crystal layer are still unclear. Moreover, most of the previously conducted studies control the liquid crystal molecular orientation by an applied electric field using transparent electrodes. In this study, using multichannel piezoelectric transducer, standing wave and traveling wave actuation mechanism were applied to the liquid crystal lens and further reported about its optical characteristics using a Shack-Hartmann wavefront sensor. The surface data obtained from the sensor was analyzed and the optical aberrations measured. Traveling wave actuation showed small optical aberrations when compared to the standing wave.

Published

2021

3. Ultrasound liquid crystal lens with a variable focus in the radial direction for image stabilization

Author

Jessica Onaka, Takahiro Iwase, Akira Emoto, Mami Matsukawa, and Daisuke Koyama

Subjects

Focal point, Materials science, business.industry, Piezoelectricity, Atomic and Molecular Physics, and Optics, law.invention, Lens (optics), Image stabilization, Optics, law, Liquid crystal, Ultrasonic sensor, Electrical and Electronic Engineering, Adaptive optics, business, Focus (optics), Engineering (miscellaneous)

Abstract

New technologies for adaptive optics are becoming increasingly important for miniature devices such as cell-phone cameras. In particular, motion-free autofocusing and optical image stabilization require sophisticated approaches for alternative lens architectures, materials, and processing to replace multiple solid elements. We discuss a new method, to the best of our knowledge, that provides image stabilization via an annular piezoelectric ceramic that uses ultrasound to drive a liquid crystal layer sandwiched between two circular glass substrates. The piezoelectric ceramic is divided into four quadrants that are independently driven with sinusoidal voltages at the resonant frequency of the lens. The technique is based on ultrasound vibrations with a suitable driving scheme. The lens configuration was modeled via finite-element analysis. Various combinations of the four-channel ultrasound transducer can be used to define the focal point of the liquid crystal lens. Clear optical images could be obtained with the lens. By using two-dimensional fast Fourier transforms, the focal point position was defined and shifted in the radial direction.

Published

2021

4. Ultrasound liquid crystal lens with enlarged aperture using traveling waves

Author

Marina Fukui, Daisuke Koyama, Mami Matsukawa, Takahiro Iwase, and Jessica Onaka

Subjects

Materials science, Aperture, business.industry, Astrophysics::Instrumentation and Methods for Astrophysics, Physics::Optics, 02 engineering and technology, Wavefront sensor, 021001 nanoscience & nanotechnology, 01 natural sciences, Piezoelectricity, Atomic and Molecular Physics, and Optics, Finite element method, law.invention, Physics::Fluid Dynamics, 010309 optics, Lens (optics), Optics, Liquid crystal, law, 0103 physical sciences, Focal length, 0210 nano-technology, business, Refractive index

Abstract

A new type of ultrasonically controlled concave liquid crystal lens based on traveling waves (TWs) with a divided electrode structure and an appropriate driving scheme is proposed in this Letter. The lens uses an annular piezoelectric ceramic divided into four parts for four-phase driving and consists of a liquid crystal layer in a sandwich structure between two circular glass substrates. The lens configuration was simulated by finite element analysis using the Ansys software. Here we discuss the use of TWs to expand the lens aperture and clarify the lens’ optical characteristics using a Shack–Hartmann wavefront sensor. The effective lens aperture using TWs was 4.4 mm, and the focal length was 3.8 m.

Published

2021