An Experimental Optical Three-axis Tactile Sensor for Micro-Robots

Ohka, Masahiro, Mitsuya, Yasunaga, Higashioka, Isamu, Kabeshita, Hisanori

07 1900

No description available.

Tactile sensor

Optical measurement

Three-axis

MEMS

Micro-robot

Sensing Characteristics of an Optical Three-axis Tactile Sensor Mounted on a Multi-fingered robotic Hand

Ohka, Masahiro, Kobayashi, Hiroaki, Mitsuya, Yasunaga

02 August 2005

No description available.

Tactile sensor

Three-axis

hemispherical

Multi-fingered hand

Optical measurement

A Nonlinear Magnetic Controller for Three-Axis Stability of Nanosatellites

Makovec, Kristin Lynne

28 July 2001

The problem of magnetic control for three-axis stability of a spacecraft is examined. Two controllers, a proportional-derivative controller and a constant coefficient linear quadratic regulator, are applied to the system of equations describing the motion of the spacecraft. The stability of each is checked for different spacecraft configurations through simulations, and the results for gravity-gradient stable and non gravity-gradient stable spacecraft are compared. An optimization technique is implemented in an attempt to obtain the best performance from the controller. For every spacecraft configuration, a set of gains can be chosen for implementation in the controller that stabilizes the linear and nonlinear equations of motion for the spacecraft. / Master of Science

Spacecraft Attitude Dynamics

Magnetic Control

Three-Axis Stability

Sensing characteristics of an optical three-axis tactile sensor　under combined loading

Ohka, Masahiro, Mitsuya, Yasunaga, Matsunaga, Yasuaki, Takeuchi, Shuichi

03 1900

No description available.

Tactile sensor

Optical measurement

Three-axis cell

Combined loading

Surface condition

Optimization of Three-Axis Vertical Milling of Sculptured Surfaces

Salas Bolanos, Gerardo

January 2010

A tool path generation method for sculptured surfaces defined by triangular meshes is presented in this thesis along with an algorithm that helps determine the best type of cutter geometry to machine a specific surface. Existing tool path planning methods for sculptured surfaces defined by triangular meshes require extensive computer processing power and result in long processing times mainly since surface topology for triangular meshes is not provided. The method presented in this thesis avoids this problem by offsetting each triangular facet individually. The combination of all the individual offsets make up a cutter location surface. A single triangle offsetting results in many more triangles; many of these are redundant, increasing the time required for data handling in subsequent steps. To avoid the large number of triangles, the proposed method creates a bounding space to which the offset surface is limited. The original surface mesh describes the bounding surface of a solid, thus it is continuous with no gaps. Therefore, the resulting bounding spaces are also continuous and without gaps. Applying the boundary space limits the size of the offset surface resulting in a reduction in the number of triangular surfaces generated. The offset surface generation may result in unwanted intersecting triangles. The tool path planning strategy addresses this issue by applying hidden-surface removal algorithms. The cutter locations from the offset surface are obtained using the depth buffer. The simulation and machining results show that the tool paths generated by this process are correct. Furthermore, the time required to generate tool paths is less than the time required by other methods. The second part of this thesis presents a method for selecting an optimal cutter type. Extensive research has been carried out to determine the best cutter size for a given machining operation. However, cutter type selection has not been studied in-depth. This work presents a method for selecting the best cutter type based on the amount of material removed. By comparing the amount of material removed by two cutters at a given cutter location the best cutter can be selected. The results show that the optimal cutter is highly dependent on the surface geometry. For most complex surfaces it was found that a combination of cutters provides the best results.

CNC machining

offset surface

tool selection

three axis

generalized cutter

Mechanical Engineering

Object exploration and manipulation using a robotic finger equipped with an optical three-axis tactile sensor

Yussof, Hanafiah Bin, Morisawa, Nobuyuki, Suzuki, Hirofumi, Kobayashi, Hiroaki, Takata, Jumpei, Ohka, Masahiro

09 1900

No description available.

Robotic finger

Object manipulation

Contour measurement

Surface measurement

Three-axis

Tactile sensor

Optimization of Three-Axis Vertical Milling of Sculptured Surfaces

Salas Bolanos, Gerardo

January 2010

A tool path generation method for sculptured surfaces defined by triangular meshes is presented in this thesis along with an algorithm that helps determine the best type of cutter geometry to machine a specific surface. Existing tool path planning methods for sculptured surfaces defined by triangular meshes require extensive computer processing power and result in long processing times mainly since surface topology for triangular meshes is not provided. The method presented in this thesis avoids this problem by offsetting each triangular facet individually. The combination of all the individual offsets make up a cutter location surface. A single triangle offsetting results in many more triangles; many of these are redundant, increasing the time required for data handling in subsequent steps. To avoid the large number of triangles, the proposed method creates a bounding space to which the offset surface is limited. The original surface mesh describes the bounding surface of a solid, thus it is continuous with no gaps. Therefore, the resulting bounding spaces are also continuous and without gaps. Applying the boundary space limits the size of the offset surface resulting in a reduction in the number of triangular surfaces generated. The offset surface generation may result in unwanted intersecting triangles. The tool path planning strategy addresses this issue by applying hidden-surface removal algorithms. The cutter locations from the offset surface are obtained using the depth buffer. The simulation and machining results show that the tool paths generated by this process are correct. Furthermore, the time required to generate tool paths is less than the time required by other methods. The second part of this thesis presents a method for selecting an optimal cutter type. Extensive research has been carried out to determine the best cutter size for a given machining operation. However, cutter type selection has not been studied in-depth. This work presents a method for selecting the best cutter type based on the amount of material removed. By comparing the amount of material removed by two cutters at a given cutter location the best cutter can be selected. The results show that the optimal cutter is highly dependent on the surface geometry. For most complex surfaces it was found that a combination of cutters provides the best results.

CNC machining

offset surface

tool selection

three axis

generalized cutter

Mechanical Engineering

光学式マイクロ三軸触覚センサの試作

大岡, 昌博, OHKA, Masahiro, 東岡, 制, HIGASHIOKA, Isamu, 壁下, 寿登, KABESHITA, Hisanori, 三矢, 保永, MITSUYA, Yasunaga

10 1900

No description available.

Mechatronics and Robotics

Sensor

Optical Measurement

Tactile

Three-Axis

Optical Waveguide

Micro Machine

Micro-scope

Typed Robot

Three-axis magnetometer calibration with norm preservation

Lichlyter, Seth

09 August 2022

This thesis proposes a set of methods for the purpose of improving the calibration of three-axis magnetometers. Specifically, these methods aim to improve the accuracy of the bias estimation methods currently in use. The first proposed method utilizes a constrained optimization problem based on norm preserving. The second proposed method finds the same bias estimate as the first method, but in a computationally more efficient manner. The last proposed method tackles the case where the value of the local geomagnetic field is only imprecisely known. Computer simulations demonstrate the viability of the proposed methods.

three axis

magnetometer

calibration

norm preservation

bias estimation

Novel type of neutron polarization analysis using the multianalyser at PUMA implementation, characterization and first experiments

Schwesig, Steffen

16 August 2019

No description available.

540

Three axis spectrometer

Neutron scattering

Neutron polarisation analysis

Instrumentation development

Magnons in copper oxide

Chemie  (PPN62138352X)