Archaeological and ethnographic painted wood artifacts from the North American Southwest : the case study of a matrix approach for the conservation of cultural materials

Odegaard, nancy Nell, n/a

January 1996

This study examines and demonstrates the value of a matrix approach in the discipline of conservation and the concerns specific to the conservation of archaeological and ethnographic objects. The chapters identify the relevance of the matrix to current conservation practices through a history of artifact conservation and a discussion of the factors that compromise the conservators' role in the study and preservation of material culture. The discussion evaluates the nature of systematic research collections, the impact of legal issues, and the ethics of including cultural context as important aspects in the development of the matrix approach. The matrix approach provides the conservator with a number of variables or categories of information that may assist in the determination of an appropriate conservation process. In this study, the matrix approach was tested on a number of artifact objects. To provide a common link, all of the objects were characterized by paint on some form of cellulose (wood or a wood-like substrate). The object cases were from both ethnographic and archaeological contexts, and the work involved both laboratory procedures and consideration of non-laboratory (i.e. legal, cultural, ethical) aspects. The specific objects included (1) a probable tiponi of archaeological (Anasazi culture) context, (2) a group of coiled baskets of archaeological (Mogollon culture) context, (3) a kachina doll of ethnographic (Hopi culture) context, (4) a group of prayer sticks of archaeological (Puebloan and Tohono O'Odham) context, and (5) a fiddle of ethnographic (Apache culture) context. By recognizing the unique and diverse aspects of anthropology collections, the conservator who uses a matrix approach is better equipped to work with archaeologists on sites, with curators and exhibit designers in museums, and with claimants (or the descendants of an object's maker) in carrying out the multiple activities frequently involved in the conservation of objects as they exist in an ever broadening and more political context.

matrix approach

archaeological objects

ethnographic objects

conservation

artifacts

North American Southwest

cultural materials

Parametric studies of circular expansion chambers using four-pole matrix approach while considering higher order mode effects

Maddali, Ramakanth

20 April 2011

No description available.

Acoustics

circular expansion chambers

higher order modes

four-pole matrix approach

mufflers

parametric study on mufflers

A dual perspective towards building resilience in manufacturing organizations

Fazio, Steven A

10 December 2021

Modern manufacturing organizations exist in the most complex and competitive environment the world has ever known. This environment consists of demanding customers, enabling, but resource intensive Industry 4.0 technology, dynamic regulations, geopolitical perturbations, and innovative, ever-expanding global competition. Successful manufacturing organizations must excel in this environment while facing emergent disruptions generated as biproducts of complex man-made and natural systems. The research presented in this thesis provides a novel two-sided approach to the creation of resilience in the modern manufacturing organization. First, the systems engineering method is demonstrated as the qualitative framework for building literature-derived organizational resilience factors into organizational structures under a life cycle perspective. A quantitative analysis of industry expert survey data through graph theory and matrix approach is presented second to prioritize resilience factors for strategic practical implementation.

organizational resilience

manufacturing

systems engineering

graph theory and matrix approach

multi criteria decision making

management

resilience

Industrial Engineering

Systems Engineering

Testing of Ground Subsurface using Spectral and Multichannel Analysis of Surface Waves

Naskar, Tarun

January 2017

Two surface wave testing methods, namely, (i) the spectral analysis of surface waves (SASW), and (ii) the multi-channel analysis of surface waves (MASW), form non-destructive and non-intrusive techniques for predicting the shear wave velocity profile of different layers of ground and pavement. These field testing tools are based on the dispersive characteristics of Rayleigh waves, that is, different frequency components of the surface wave travel at different velocities in layered media. The SASW and MASW testing procedure basically comprises of three different components: (i) field measurements by employing geophones/accelerometers, (ii) generating dispersion plots, and (iii) predicting the shear wave velocity profile based on an inversion analysis. For generating the field dispersion plot, the complexities involved while doing the phase unwrapping calculations for the SASW technique, while performing the spectral calculations on the basis of two receivers’ data, makes it difficult to automate since it requires frequent manual judgment. In the present thesis, a new method, based on the sliding Fourier transform, has been introduced. The proposed method has been noted to be quite accurate, computationally economical and it generally overcomes the difficulties associated with the unwrapping of the phase difference between the two sensors’ data. In this approach, the unwrapping of the phase can be carried out without any manual intervention. As a result, an automation of the entire computational process to generate the dispersion plot becomes feasible. The method has been thoroughly validated by including a number of examples on the basis of surface wave field tests as well as synthetic test data. While obtaining the dispersion image by using the MASW method, three different transformation techniques, namely, (i) the Park’s wavefield transform, (ii) the frequency (f) -wavenumber ( ) transform and (iii) the time intercept ( -phase slowness (p) transform have been utilized for generating the multimodal dispersion plots. The performance of these three different methods has been assessed by using synthetic as well as field data records obtained from a ground site by means of 48 geophones. Two-dimensional as well as three-dimensional dispersion plots were generated. The Park’s wavefield transformation method has been found to be especially advantageous since it neither requires a very high sampling rate nor an inclusion of the zero padding of the data in a wavenumber (distance) domain. In the case of an irregular dispersive media, a proper analysis of the higher modes existing in the dispersion plots becomes essential for predicting the shear wave velocity profile of ground on the basis of surface wave tests. In such cases, the establishment of the predominant mode becomes quite significant. In the current investigation for Rayleigh wave propagation, the predominant mode has been computed by maximizing the normalized vertical displacements along the free surface. Eigenvectors computed from the thin layer approach (TLM) approach are analyzed to predict the corresponding predominant mode. It is noted that the establishment of the predominant mode becomes quite important where only two to six sensors are employed and the governing (predominant) modal dispersion curve is usually observed rather than several multiple modes which can otherwise be identified by using around 24 to 48 multiple sensors. By using the TLM, it is, however, not possible to account for the exact contribution of the elastic half space in the dynamic stiffness matrix (DSM) approach. A method is suggested to incorporate the exact contribution of the elastic half space in the TLM. The numerical formulation is finally framed as a quadratic eigenvalue problem which can be easily solved by using the subroutine polyeig in MATLAB. The dispersion plots were generated for several chosen different ground profiles. The numerical results were found to match quite well with the data available from literature. In order to address all the three different aspects of SASW and MASW techniques, a series of field tests were performed on five different ground sites. The ground vibrations were induced by means of (i) a 65 kg mass dropped freely from a height of 5 m, and (ii) by using a 20 pound sledge hammer. It was found that by using a 65 kg mass dropped from a height of 5 m, for stiffer sites, ground exploration becomes feasible even up to a depth of 50-80 m whereas for the softer sites the exploration depth is reduced to about 30 m. By using a 20 lb sledge hammer, the exploration depth is restricted to only 8-10 m due to its low impact energy. Overall, it is expected that the work reported in the thesis will furnish useful guidelines for (i) performing the SASW and MASW field tests, (ii) generating dispersion plots/images, and (iii) predicting the shear wave velocity profile of the site based on an inversion analysis.

Surface Wave Testing Method

Wave Propagation Spectral Calculations

Isotropic Elastic Half Space

Surface Waves

Surface Wave Tests

Rayleigh Wave Propagation

Dynamic Stiffness Matrix Approach

MASW Transformation Techniques

Multimodal Dispersion Plots

Civil Engineering