Transfer Functions of the Slip-Controlled Induction Machine

The use of a feedback loop to regulate the slip frequency of an inverter-driven induction machine is viewed as replacing the normal independent control of stator frequency with independent control of slip frequency. For steady-state conditions the two modes of operation are shown to produce characteristics analogous to shunt and series dc machines. A method employing closed-form transfer functions, a reduced set of nondimensional parameters, and a general root locus diagram is used to present the dynamic characteristics of controlled slip frequency operation and to compare performance with conventional operation. The parameter range in the general diagram is sufficient to incorporate nearly all standard induction machines over a wide size and frequency range. The results demonstrate that the ratio K? of the rotor transient time constant to the static electromechanical time constant is a critical parameter in the comparison of the two modes. Since this parameter tends to increase with machine size, the relative advantages of slip frequency control are shown to be machine-size dependent. Inclusion of a speed-control loop regulating machine voltage is also Considered and shown to be described by the same general root loci. The performance of this closed-loop system is also shown to be very dependent on K? and hence on machine size.     

Sensing methodology for in vivo stability evaluation of total hip and knee arthroplasty

This paper describes an implantable, remotely interrogated system for the in vivo measurement of both micromotion and migration in applications such as total hip arthroplasty (THA) and total knee arthroplasty (TKA). These metrics are the primary indicators of post-operative implant stability and their easy availability represents an important advance in the ability of clinicians to assess the long-term stability of the implants and also to plan and optimise patients’ rehabilitation protocols. The system is based on a modified form of differential variable reluctance transducer (DVRT) whose null-point is set automatically by means of a self-calibration algorithm. The self-calibration process not only allows the measuring bridge to work at maximum accuracy (i.e. for micromotion measurements) but also automatically records gross changes in position (migration). Simulations and preliminary measurements show that the calibration algorithm works correctly in spite of component tolerances and initial set up errors, and that the device can measure micromotion with an amplitude as low as 1 μm with a gross displacement (migration) in the range 0 to ±4 mm.     

Gravity is an important but secondary determinant of regional pulmonary blood flow in upright primates

Original studies leading to the gravitational model of pulmonary blood flow and contemporary studies showing gravity-independent perfusion differ in the recent use of laboratory animals instead of humans. We explored the distribution of pulmonary blood flow in baboons because their anatomy, serial distribution of vascular resistances, and hemodynamic responses to hypoxia are similar to those of humans. Four baboons were anesthetized with ketamine, intubated, and mechanically ventilated. Different colors of fluorescent microspheres were given intravenously while the animals were in the supine, prone, upright (repeated), and head-down (repeated) postures. The animals were killed, and their lungs were excised, dried, and diced into approximately 2-cm3 pieces with the spatial coordinates recorded for each piece. Regional blood flow was determined for each posture from the fluorescent signals of each piece. Perfusion heterogeneity was greatest in the upright posture and least when prone. Using multiple-stepwise regression, we estimate that 7, 5, and 25% of perfusion heterogeneity is due to gravity in the supine, prone, and upright postures, respectively. Although important, gravity is not the predominant determinant of pulmonary perfusion heterogeneity in upright primates. Because of anatomic similarities, the same may be true for humans.     

Team cognition in group interventions: The relation between coleaders' shared mental models and group climate.

The relation between the convergence in group coleaders' mental models of their groups and group members' perceptions of group climate was examined. Coleaders of 8 intergroup dialogue groups provided paired-comparison ratings of the similarity of their group members, and group members provided group climate ratings, following each of 7 sessions. The paired-comparison ratings were analyzed using pathfinder network analysis (Schvaneveldt, 1990) to examine the structure of each coleader's mental model of her or his group, and to compare these mental models within coleader pairs to determine degree of similarity in coleaders' mental models for each coleader pair for each week (i.e., how similarly coleaders of a group view their group). Growth curve analyses of the degree of similarity and group climate data showed an increase in similarity of coleaders' mental models within groups across sessions, and that similarity in coleader mental models was related to increases in the engaged and decreases in the avoiding aspects of the group climate. (PsycINFO Database Record (c) 2010 APA, all rights reserved)