Evaluation of material properties and friction data in metalforming

Yeh, Chih-chiang

January 1989

No description available.

Engineering, Mechanical

Material Properties

Friction Data

Metalforming

A device-independent graphical user interface for theoretical studies of surface temperatures generated by friction

Janajreh, Isam Mustafa

23 December 2009

Computer graphics is an important tool for engineering visualization and computer aided design systems. The use of this tool to create graphical user interfaces (GUIs) for engineering applications is growing dramatically owing to the almost real-time response to creative thinking which allows engineers to quickly visualize many potential solutions to a problem. This thesis describes the creation of a GUI for a software system which is capable of predicting the surface temperatures generated at the contact between two sliding bodies. This GUI uses the ISO standard PHIGS for 3D graphics support. The use of PHIGS and the standard programming language C renders this system device-independent and hence, portable. Although PHIGS supports the creation of graphics-based engineering applications, many basic functions required for a GUI (e.g. functions for menus, templates, etc.) need to be created from scratch. During the creation of the GUI described in this thesis, special attention was paid to functions which could be created as re-usable, high-level functions. These functions can be made available to other programmers who wish to create similar GUIs for other engineering applications. The design and creation of these high-level functions and the use of these high-level functions in the creation of the GUI for the surface temperature prediction software are described in this thesis. / Master of Science

LD5655.V855 1992.J362

Friction -- Data processing

User interfaces (Computer systems)

Exploring gravity

Berry, Christopher P. L.

January 2014

Gravitation is the dominant influence in most astrophysical interactions. Weak-field interactions have been extensively studied, but the strong-field regime remains largely unexplored. Gravitational waves (GWs) are an excellent means of accessing strong-field regions. We investigate what we can learn about both astrophysics and gravitation from strong-field tests and, in particular, GWs; we focus upon extreme-mass-ratio (EMR) systems where a small body orbits a much more massive one. EMR bursts, a particular class of GW signals, could be used to determine the properties of massive black holes (MBHs). They could be detectable with a space-borne interferometer from many nearby galaxies, as well as the Galactic centre. Bursts could provide insightful constraints on the MBHs' parameters. These could elucidate the formation history of the MBHs and, by association, their host galaxies. The Galactic centre is the most promising source. Its event rate is determined by the stellar distribution surrounding the MBH; the rate is not high, but we still expect to gain useful astronomical information from bursts. Strong-field tests may reveal deviations from general relativity (GR). We calculate modifications that could be observed assuming metric f(R)-gravity as an effective alternative theory. Gravitational radiation is modified, as are planetary precession rates. Both give a means of testing GR. However, existing laboratory measurements already place tighter constraints on f(R)-gravity, unless there exists a screening effect, such as the chameleon mechanism, which suppresses modifications on small scales. To make precision measurements of astrophysical systems or place exacting bounds on deviations from GR, we must have accurate GW templates. Transient resonances are currently not included in the prescription for generating EMR inspiral waveforms. Their effects can be estimated from asymptotic expansions of the evolving orbital parameters. The quantitative impact on parameter estimation has yet to be calculated, but it appears that it shall be necessary to incorporate resonances when creating inspiral waveforms.

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