{"title":"在单轴侧向磁场上使用不对称框架的双轴电磁扫描仪","authors":"Yuki Okamoto;Rihachiro Nakashima;Ryo Oda;Thanh-Vinh Nguyen;Yusuke Takei;Masaaki Ichiki;Hironao Okada","doi":"10.1109/JMEMS.2024.3402211","DOIUrl":null,"url":null,"abstract":"Conventional electromagnetic microelectromechanical system scanners require a biaxial (two-axis) external magnetic field to obtain a biaxial torque, which increases the number of bulky external permanent magnets and the packaging size caused by 45°-orientated placement of permanent magnets. Thus, this study developed a two-axis resonant electromagnetic scanner with an asymmetric gimbal frame that generates two-axis torque via a one-axis lateral external magnetic field. As external permanent magnets can be placed parallel to the device die, the proposed method reduced the packaging size. Two driving forces were generated by two independent electromagnetic actuators placed on both sides of the asymmetric gimbal frame, which converted the unidirectional forces into two-axis torque. As the two driving actuators were independent of the connecting beams, gimbal frame, and mirror and were connected to the thick outer Si handle frame, the temperature increase of torsion beams and the asymmetric gimbal frame, which affects the resonant performance, were reduced. Additionally, as the current paths were not multiturn coil shapes, the paths can be formed with a via-less single metal layer. Also, the drive circuit can be simplified since drive signals for two-axis rotation can be applied to individual actuators. We demonstrated biaxial scanning using the proposed structure with a 4-mm mirror. The optical scanning angle was 4.84° for the 1.308 kHz X-axis scan and 16.1° for the 2.568 kHz Y-axis scan when a current of 300 mA was applied independently to the X- and Y-axes driving actuators. We obtained the large displacement at the resonant frequency using the asymmetric gimbal frame under a lateral magnetic field.[2024-0050]","PeriodicalId":16621,"journal":{"name":"Journal of Microelectromechanical Systems","volume":"33 4","pages":"495-502"},"PeriodicalIF":2.5000,"publicationDate":"2024-03-29","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=10541112","citationCount":"0","resultStr":"{\"title\":\"Two-Axis Electromagnetic Scanner Using an Asymmetric Frame on a One-Axis Lateral Magnetic Field\",\"authors\":\"Yuki Okamoto;Rihachiro Nakashima;Ryo Oda;Thanh-Vinh Nguyen;Yusuke Takei;Masaaki Ichiki;Hironao Okada\",\"doi\":\"10.1109/JMEMS.2024.3402211\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Conventional electromagnetic microelectromechanical system scanners require a biaxial (two-axis) external magnetic field to obtain a biaxial torque, which increases the number of bulky external permanent magnets and the packaging size caused by 45°-orientated placement of permanent magnets. Thus, this study developed a two-axis resonant electromagnetic scanner with an asymmetric gimbal frame that generates two-axis torque via a one-axis lateral external magnetic field. As external permanent magnets can be placed parallel to the device die, the proposed method reduced the packaging size. Two driving forces were generated by two independent electromagnetic actuators placed on both sides of the asymmetric gimbal frame, which converted the unidirectional forces into two-axis torque. As the two driving actuators were independent of the connecting beams, gimbal frame, and mirror and were connected to the thick outer Si handle frame, the temperature increase of torsion beams and the asymmetric gimbal frame, which affects the resonant performance, were reduced. Additionally, as the current paths were not multiturn coil shapes, the paths can be formed with a via-less single metal layer. Also, the drive circuit can be simplified since drive signals for two-axis rotation can be applied to individual actuators. We demonstrated biaxial scanning using the proposed structure with a 4-mm mirror. The optical scanning angle was 4.84° for the 1.308 kHz X-axis scan and 16.1° for the 2.568 kHz Y-axis scan when a current of 300 mA was applied independently to the X- and Y-axes driving actuators. 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引用次数: 0
摘要
传统的电磁微机电系统扫描仪需要双轴(两轴)外磁场来获得双轴扭矩,这就增加了笨重的外部永久磁铁的数量,并且永久磁铁的 45° 朝向放置会导致包装尺寸增大。因此,本研究开发了一种带有非对称万向架的双轴谐振电磁扫描仪,通过一轴横向外磁场产生双轴扭矩。由于外部永久磁铁可以平行于设备芯片放置,因此所提出的方法减小了封装尺寸。不对称万向架两侧的两个独立电磁致动器产生两个驱动力,将单向力转换为双轴扭矩。由于两个驱动致动器独立于连接梁、万向架和反射镜,并与厚外层硅手柄框架相连,因此降低了影响谐振性能的扭转梁和非对称万向架的温度升高。此外,由于电流通路不是多圈线圈形状,因此可以用无通孔的单金属层形成通路。此外,由于双轴旋转的驱动信号可以应用于单个致动器,因此驱动电路也可以简化。我们演示了使用 4 毫米镜面的拟议结构进行双轴扫描。当对 X 轴和 Y 轴驱动致动器分别施加 300 mA 电流时,1.308 kHz X 轴扫描的光学扫描角度为 4.84°,2.568 kHz Y 轴扫描的光学扫描角度为 16.1°。我们利用横向磁场下的非对称万向节框架获得了共振频率下的大位移[2024-0050]。
Two-Axis Electromagnetic Scanner Using an Asymmetric Frame on a One-Axis Lateral Magnetic Field
Conventional electromagnetic microelectromechanical system scanners require a biaxial (two-axis) external magnetic field to obtain a biaxial torque, which increases the number of bulky external permanent magnets and the packaging size caused by 45°-orientated placement of permanent magnets. Thus, this study developed a two-axis resonant electromagnetic scanner with an asymmetric gimbal frame that generates two-axis torque via a one-axis lateral external magnetic field. As external permanent magnets can be placed parallel to the device die, the proposed method reduced the packaging size. Two driving forces were generated by two independent electromagnetic actuators placed on both sides of the asymmetric gimbal frame, which converted the unidirectional forces into two-axis torque. As the two driving actuators were independent of the connecting beams, gimbal frame, and mirror and were connected to the thick outer Si handle frame, the temperature increase of torsion beams and the asymmetric gimbal frame, which affects the resonant performance, were reduced. Additionally, as the current paths were not multiturn coil shapes, the paths can be formed with a via-less single metal layer. Also, the drive circuit can be simplified since drive signals for two-axis rotation can be applied to individual actuators. We demonstrated biaxial scanning using the proposed structure with a 4-mm mirror. The optical scanning angle was 4.84° for the 1.308 kHz X-axis scan and 16.1° for the 2.568 kHz Y-axis scan when a current of 300 mA was applied independently to the X- and Y-axes driving actuators. We obtained the large displacement at the resonant frequency using the asymmetric gimbal frame under a lateral magnetic field.[2024-0050]
期刊介绍:
The topics of interest include, but are not limited to: devices ranging in size from microns to millimeters, IC-compatible fabrication techniques, other fabrication techniques, measurement of micro phenomena, theoretical results, new materials and designs, micro actuators, micro robots, micro batteries, bearings, wear, reliability, electrical interconnections, micro telemanipulation, and standards appropriate to MEMS. Application examples and application oriented devices in fluidics, optics, bio-medical engineering, etc., are also of central interest.