Design and Fabrication of Ultralight High-Voltage Power Circuits for Flapping-Wing Robotic Insects
Authors: not saved
Abstract:
Flapping-wing robotic insects are small, highly maneuverable flying robots inspired by biologicalinsects and useful for a wide range of tasks, including exploration, environmental monitoring, searchand rescue, and surveillance. Recently, robotic insects driven by piezoelectric actuators have achievedthe important goal of taking off with external power; however, fully autonomous operation requiresan ultralight power supply capable of generating high-voltage drive signals from low-voltage energysources. This paper describes high-voltage switching circuit topologies and control methods suitablefor driving piezoelectric actuators in flapping-wing robotic insects and discusses the physicalimplementation of these topologies, including the fabrication of custom magnetic components bylaser micromachining and other weight minimization echniques. The performance of lasermicromachined magnetics and custom-wound commercial magnetics is compared through theexperimental realization of a tapped inductor boost converter capable of stepping up a 3.7V Li-polycell input to 200V. The potential of laser micromachined magnetics is further shown byimplementing a similar converter weighing 20mg (not including control functionality) and capable ofup to 70mW output at 200V and up to 100mW at 100V.
similar resources
design and fabrication of ultralight high-voltage power circuits for flapping-wing robotic insects
flapping-wing robotic insects are small, highly maneuverable flying robots inspired by biologicalinsects and useful for a wide range of tasks, including exploration, environmental monitoring, searchand rescue, and surveillance. recently, robotic insects driven by piezoelectric actuators have achievedthe important goal of taking off with external power; however, fully autonomous operation requir...
full textFlapping wing aerodynamics: from insects to vertebrates.
More than a million insects and approximately 11,000 vertebrates utilize flapping wings to fly. However, flapping flight has only been studied in a few of these species, so many challenges remain in understanding this form of locomotion. Five key aerodynamic mechanisms have been identified for insect flight. Among these is the leading edge vortex, which is a convergent solution to avoid stall f...
full textDesign and Fabrication of a Portable 1-DOF Robotic Device for Indentation Tests
There are many tactile devices for indentation examinations to measure mechanical properties of tissue. The purpose of this paper is to develop a portable indentation robotic device to show its usability for measuring the mechanical properties of a healthy abdominal tissue. These measurements will help to develop suitable mathematical models representing abdominal tissue. A 1-DOF portable robot...
full textDesign and Fabrication of Advanced Hybrid Circuits for High Energy
Current design and fabrication techniques of hybrid devices are explained for the Drift Chamber and the Liquid Ar-pon Calorimeter for the Stanford Linear Collider Large Detector (SLD) at SLAC. Methods of developing layouts, raging from hand-cut templates to advanced designs utilizing CAD tools with special hybrid design software were applied. Physical and electrical design rules for good yield ...
full textPassive torque regulation in an underactuated flapping wing robotic insect
Recent developments in millimeter-scale fabrication processes have led to rapid progress towards creating airborne flapping wing robots based on Dipteran (two winged) insects. Previous work to regulate forces and torques generated by flapping wings has focused on controlling wing trajectory. An alternative approach uses underactuated mechanisms with tuned dynamics to passively regulate these fo...
full textPassive Aerodynamic Drag Balancing in a Flapping-Wing Robotic Insect
Flapping-wing robotic platforms based on Dipteran insects have demonstrated lift to weight ratios greater than 1, but research into regulating the aerodynamic forces produced by their wings has largely focused on active wing trajectory control. In an alternate approach, a flapping-wing drivetrain design that passively balances aerodynamic drag torques is presented. A discussion of the dynamic p...
full textMy Resources
Journal title
volume 1 issue 3
pages 46- 57
publication date 2012-12-01
By following a journal you will be notified via email when a new issue of this journal is published.
Hosted on Doprax cloud platform doprax.com
copyright © 2015-2023