Abstract
In recent years, the optical accelerometer based on the optical trapping force effect has gradually attracted the attention of researchers for its high sensitivity and high measurement accuracy. However, due to its large size and the complexity of optical path adjustment, the optical force accelerometers reported are only suitable for the laboratory environment up to now. In this paper, a miniature optical force dual-axis accelerometer based on the miniature optical system and a particles cavity which is prepared by Micro-Electro-Mechanical Systems (MEMS) technology is proposed. The overall system of the miniature optical levitation including the miniature optical system and MEMS particles cavity is a cylindrical structure with a diameter of about 10 mm and a height of 33 mm (Φ 10 mm × 33 mm). Moreover, the size of this accelerometer is 200 mm × 100 mm × 100 mm. Due to the selected light source being a laser diode light source with elliptical distribution, it is sensitive to the external acceleration in both the long axis and the short axis. This accelerometer achieves a measurement range of ±0.17 g–±0.26 g and measurement resolution of 0.49 mg and 1.88 mg. The result shows that the short-term zero-bias stability of the two orthogonal axes of the optical force accelerometer is 4.4 mg and 9.2 mg, respectively. The main conclusion that can be drawn is that this optical force accelerometer could provide an effective solution for measuring acceleration with an optical force effect for compact engineering devices.
Highlights
By using an optical system composed of one laser diode, a pair of micro-lenses, and a particles chamber fabricated by Micro-Electro-Mechanical System (MEMS) technology, the packaging volume of the accelerometer is reduced to 200 mm × 100 mm × 100 mm
The measurement of acceleration was successfully realized by using this miniature optical force accelerometer
We calibrated and evaluated the response of the accelerometer to external acceleration by analyzing the offset signals exported by silicon particles with a diameter of 10 μm at different rotation angles
Summary
According to different measuring principles and structure forms, the traditional accelerometers can be divided into electrostatic accelerometers, Micro-Electro-Mechanical System (MEMS). Accelerometers, and flexible pendulous accelerometers [1,2]. Based on their performance indicators, different kinds of accelerometers have been widely used in civilian and military fields, including unmanned driving, weapon guidance, and other fields. To improve the accuracy of navigation and positioning, high-precision accelerometers have attracted more and more attention and research. The accelerometer based on an optical-levitated particle has a high mechanical resolution, high measurement accuracy, and it can isolate the external thermal environment noise [3,4,5]. It is widely considered to be a new type of accelerometer with high precision potential
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