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M. Brian Thomas

Bio: M. Brian Thomas is an academic researcher from Ohio State University. The author has contributed to research in topics: Environmental resource management & Ecosystem. The author has an hindex of 2, co-authored 2 publications receiving 79 citations.

Papers
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Journal ArticleDOI
TL;DR: In this paper, a mathematical model of a bowl feeder was developed by using state-space methods to evaluate bowl-feeder parameters, and a computer simulation can predict the velocity of the parts in the bowl and subsequently the part feed rate.

70 citations

Journal ArticleDOI
TL;DR: In this paper , the authors considered that climate warming is among the most serious of anthropogenic stresses to the environment, because it not only has direct effects on biodiversity but also has indirect effects on humans.
Abstract: Climate warming is considered to be among the most serious of anthropogenic stresses to the environment, because it not only has direct effects on biodiversity

33 citations

Journal ArticleDOI
TL;DR: In this paper, the authors present a design in which position control is realized on a single-rod, double-acting cylinder, where two solenoid valves operate conventionally to fill either chamber of the cylinder, while a third valve uses pulsewidth modulation in metering the exhaust flow.

13 citations


Cited by
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Journal ArticleDOI
TL;DR: In this article, a compliant platform based on the von Mises compliance matrix is proposed for a bowl feeder, which is decomposed into a central compliance matrix and an adjoint transformation leading to the decomposition of the legs' parameter effect from the platform assembly influence.
Abstract: The platform based vibratory bowl feeders are essential elements in automatic assembly. Taking the bowl feeder as a typical three-legged rigidly connected compliant platform device, this paper applies von Mises' compliance matrix to each of the leaf-spring legs, establishes screw systems of the legs and develops the Jacobian of the platform using the adjoint transformation. Based on the force equilibrium between the supporting and external wrenches and the twist deflection, a platform compliance matrix is proposed as a congruence transformation of the legs' compliance matrices. The matrix is then decomposed into a central compliance matrix and an adjoint transformation, leading to the decomposition of the legs' parameter effect from the platform assembly influence. The analysis presents the necessary and sufficient condition for the existence of the twist deflection that is equivalent to the characteristics equation of the compliant platform. Further based on the eigencompliances and eigentwist decomposition, the legs' parameter effect and the platform assembly parameter influence are identified. This reveals the compliance characteristics of this type of devices and the parameters' effect on the compliance and presents a suitable parameter range for design of the compliant platform device.

91 citations

Journal ArticleDOI
01 Oct 1999
TL;DR: This is the first paper to systematically compare alternative estimators for solving the pose statistics of coins and dice as they are dropped on a flat surface and to correlate their performance with statistically significant experiments on industrial parts.
Abstract: Many of the most fundamental examples in probability involve the pose statistics of coins and dice as they are dropped on a flat surface. For these parts, the probability assigned to each stable face is justified based on part symmetry, although most gamblers are familiar with the possibility of loaded dice. In industrial part feeding, parts also arrive in random orientations. We consider the following problem: given part geometry and parameters such as center of mass, estimate the probability of encountering each stable pose of the part. We describe three estimators for solving this problem for polyhedral parts with known center of mass. The first estimator uses a quasistatic motion model that is computed in time O(n log n) for a part with n vertices. The second estimator has the same time complexity but takes into account a measure of dynamic stability based on perturbation. The third estimator uses repeated Monte Carlo experiments with a mechanics simulation package. To evaluate these estimators, we used a robot and computer vision system to record the pose statistics based on 3595 physical drop experiments with four different parts. We compare this data to the results from each estimator. We believe this is the first paper to systematically compare alternative estimators and to correlate their performance with statistically significant experiments on industrial parts.

57 citations

Journal ArticleDOI
TL;DR: A class of vibratory bowl filters that can be described by removing polygonal sections from the track are considered, referred to as traps, which will filter out all but one of the different stable orientations of a given part.
Abstract: The vibratory bowl feeder is the oldest and still most common approach to the automated feeding (orienting) of industrial parts. In this paper, the authors consider a class of vibratory bowl filters that can be described by removing polygonal sections from the track; this class of filters is referred to as traps. For an n-sided polygonal part and an m-sided polygonal trap, an O(n2m log n) algorithm is given to decide whether the part in a specific orientation will safely move across the trap or will fall through the trap and thus be filtered out. For an n-sided convex polygonal part and m-sided convex polygonal trap, this bound is improved to O((n+m) log n). Furthermore, the authors show how to design various trap shapes, ranging from simple traps to general polygons, which will filter out all but one of the different stable orientations of a given part. Although the runtimes of the design algorithms are exponential in the number of trap parameters, many industrial part feeders use few-parameter traps (ba...

50 citations

Journal ArticleDOI
TL;DR: A brief overview of pneumatic actuators based on modeling and control strategies that has been proposed by various researchers is presented in this paper, where some background information will be presented in a relation to PNE actuators.
Abstract: Pneumatic actuators are highly nonlinear characteristics and uncertainties make it difficult to achieve high performances. The objective of this paper is to present a brief overview of pneumatic actuators based on modeling and control strategies that has been proposed by various researchers. Before the main discussion, some background information will be presented in a relation to pneumatic actuators. This review concludes with a short summary INTERNATIONAL JOURNAL ON SMART SENSING AND INTELLIGENT SYSTEMS VOL. 4, NO. 4, DECEMBER 2011

44 citations

Proceedings ArticleDOI
10 May 1999
TL;DR: A class of vibratory bowl filters that can be described by removing polygonal sections from the track is considered; this class of filters are referred to as traps and two rectilinear subclasses, balconies and gaps are considered.
Abstract: The vibratory bowl feeder is the oldest and still most common approach to the automated feeding (orienting) of industrial parts. We consider a class of vibratory bowl filters that can be described by removing polygonal sections from the track; we refer to this class of filters as traps. For an n-sided convex polygonal part and m-sided convex polygonal trap, we give an O((n+m)log(n+m)) algorithm to decide if the part will be rejected by the trap, and an O((nm(n+m))/sup 1+/spl epsiv//) algorithm which deals with non-convex parts and traps. We then consider the problem of designing traps for a given part, and consider two rectilinear subclasses, balconies and gaps. We give linear and O(n/sup 2/) algorithms for designing feeders and have tested the results with physical experiments using a commercial inline vibratory feeder.

39 citations