Microprobe microsystem platform inserted during early metamorphosis to actuate insect flight muscle

2007 IEEE 20th International Conference on Micro Electro Mechanical Systems (MEMS) Pub Date : 2007-01-01 DOI:10.1109/MEMSYS.2007.4432976

A. Bozkurt, A. Paul, S. Pulla, A. Ramkumar, B. Blossey, J. Ewer, R. Gilmour, A. Lal

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引用次数: 31

Abstract

Following from early work demonstrating that early pupal- stage inserts are accepted by insects [9], a microprobe based microsystem platform was designed with respect to the position of the muscle bundles, and was inserted into the thorax at 4 days of the pupal stage. The platform is roughly 8times7times1.5 mm3 in size with probe thickness of 200 mum and weighs 500 mg, which the moth is able to successfully carry in the adult stage. In addition to the microsystem, an anchor to easily manipulate the adults was successfully formed in the insect by placing a glass-capillary through the pupae. The pupae emerged successfully, and the microsystem was used to characterize the potential for flight control. As part of the work to determine the microplatform design, we determined the strength-interval profiles of the pulses needed for direct muscle actuation. Two sets of flight muscles, which are symmetrically present on either side of the thorax, were differentially electrically actuated, which potentially influences the individual wing beat frequency and amplitude resulting in controlled turning behavior during flight.

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微探针微系统平台插入在早期变态，以驱动昆虫飞行肌肉

根据早期的研究表明昆虫可以接受早期的蛹期插入物[9]，我们根据肌束的位置设计了一个基于微探针的微系统平台，并在蛹期第4天将其插入胸腔。该平台的大小约为8 × 7 × 1.5毫米，探针厚度为200毫米，重量为500毫克，蛾子能够在成虫阶段成功携带。除了微系统外，通过在蛹中放置玻璃毛细管，成功地在昆虫体内形成了一个易于操纵成虫的锚。蛹成功出现，微系统被用来表征飞行控制的潜力。作为确定微平台设计工作的一部分，我们确定了直接肌肉驱动所需脉冲的强度间隔分布。两组飞行肌肉对称地分布在胸部两侧，是不同的电动驱动，这可能会影响单个翅膀拍打的频率和幅度，从而在飞行过程中控制转弯行为。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2007 IEEE 20th International Conference on Micro Electro Mechanical Systems (MEMS)

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