Formulation, development, and characterization of magnetic pastes and epoxies for thick film inductors /

Kashani, Mohammad Mansour Riahi,

January 1992

Thesis (Ph. D.)--Virginia Polytechnic Institute and State University, 1992. / Vita. Abstract. Includes bibliographical references (leaves 230-242). Also available via the Internet.

Thick films. Thick-film circuits.

Coupled noise study of thick film circuits

Quilici, James Edwin, 1961-

January 1988

Methods of noise coupling in high speed thick film circuits has been investigated. Parasitic coupling parameters have been experimentally determined for a variety of single and multilayer thick film layouts. In addition, the severity of the problem has been studied by measuring coupled noise induced on carefully constructed test cards. Curves are presented as an aid for predicting noise levels as a function of conductor spacing and signal edge speed. The measurements are discussed quantitatively and guidelines for the design of high speed thick film circuits are summarized.

Thick-film circuits.

Crosstalk.

Hybrid integrated circuits.

A modular miniaturised chemical analysis system :

Sirait, Hiskia.

Unknown Date

Thesis (PhDElectronicEngineering)--University of South Australia, 2003.

Electronic measurements.

Thick-film circuits.

Thick films

The Role of residual stresses in ceramic substrate materials for hybrid thick film applications /

Schulz, Noel Nunnally,

January 1990

Thesis (M.S.)--Virginia Polytechnic Institute and State University, 1990. / Vita. Abstract. Includes bibliographical references (leaves 77-81). Also available via the Internet.

A plastic-based thick-film li-ion microbattery for autonomous microsensors /

Lin, Qian,

January 2006

Thesis (Ph. D.)--Brigham Young University Dept. of Chemical Engineering, 2006. / Includes bibliographical references (p. 155-165).

Characterization and modeling of magnetic materials and structures

Al-Mazroo, Abdulhameed Yousef

January 1988

This dissertation presents methods for wideband characterization and modeling of magnetic materials and structures over a wide frequency range (dc to a few GHz). A method for modeling the thick film inductor structures at high frequencies is presented in this dissertation. The thick film inductor under test is printed and located in shunt connection at the end of a reference transmission line. Time Domain Reflectometry (TDR) technique is used to measure the response waveform from the inductor under test. The response from a short circuit at the location of the inductor is acquired as the reference waveform. The two acquired waveforms are then transformed into the frequency domain using the Fast Fourier Transform algorithm (FFT). The reflection coefficient is then computed as the ratio between the Fourier Transforms of the response and reference waveforms. From the information contained, the complex impedance of the structure under study can be calculated. This information is used for modeling that structure by fitting the data to the network model using the computer network analysis program. Experimental and simulated response waveforms are compared and brought to a close match by changing the model components values. A cavity-like sample holder filled with ferrite material ls proposed in this dissertation to measure the complex permeability of the magnetic material filling this cavity. The cavity walls are deposited on a coaxially shaped sample using thick film techniques. The reflection coefficient from the cavity under study is measured by adapting the cavity to the end of a transmission line. The full field analysis of this proposed configuration is used to determine a relationship between the complex permeability of the ferrite material and the measured reflection coefficient. The method of moments ls used to achieve this task. Computer simulation experiments are performed to test the sensitivity of the technique and to predict the performance over the desired frequency range. Actual experimentation as well as verifications of these measurements are conducted to verify the merit of the proposed technique. / Ph. D. / incomplete_metadata

LD5655.V856 1988.A4465

Magnetic materials

Thick-film circuits

Formulation, development, and characterization of magnetic pastes and epoxies for thick film inductors

Kashani, Mohammad Mansour Riahi

04 October 2006

Inductors and transformers constitute two important magnetic components In RF and power hybrids electronic circuitry. Thick film inductors have been subject of extensive research in recent years because they significantly reduce the weight and size, and increase the frequency of operation of electronic circuits. The research work in this dissertation is aimed at the formulation of thick film ferrite pastes and ferrite epoxies and the design, construction, and evaluation of thick film spiral inductors. Wideband characterization (DC - 2GHz) of ferrite pastes, ferrite epoxies, and ferrite substrates is performed using two techniques. These techniques are based on current image and transmission line (coaxial cavity) concepts for low (DC-IOOMHz) and high (50MHz-2GHz) frequency regions, respectively. They are used to evaluate the permeability spectra of formulated and commercially available thick film magnetic materials in respective frequency ranges. A method to numerically calculate the inductance of thick film circular spiral inductors based on modeling the spiral as concentric circles is presented. A novel method for fine as well as coarse tuning of thick film inductors is also introduced. The tunable inductors are constructed using formulated ferrite epoxies and magnetic cores. The method of analysis of variance is used to investigate the variation significance of tunable inductors. Finally, chemical and mechanical properties of developed magnetic materials are discussed. The studied properties include, glass transition temperature, degradation temperature, thermal coefficient of expansion, adhesion, particle-size distribution and particle densification , grain size, and compositional constituents of the magnetic materials. / Ph. D.

LD5655.V856 1992.K374

Thick films

Thick-film circuits

The Role of residual stresses in ceramic substrate materials for hybrid thick film applications

Schulz, Noel Nunnally

09 May 2009

This work presents introductory research to provide the relationship between electrical measurements and residual stresses caused by hybrid processing. X-ray diffraction is used to measure residual stresses in the ceramic substrate as well as metallization of wideband coplanar thick film probes. The probes are also tested for electrical performance using Time Domain Reflectometry (TDR) technique. This thesis presents results that indicate that significant tensile residual stresses were generated on the back of the substrate, particularly during the laser scribing phase of the finished device. Significant tensile stresses were also observed in the Silver-Palladium (Ag-Pd) metallization. TDR measurements indicated significant response variations which were attributed to these induced stresses. Attempts were also made to reduce these stresses by an annealing process in order to improve the TDR response uniformity. / Master of Science

LD5655.V855 1990.S384

Hybrid integrated circuits -- Defects

Thick-film circuits -- Defects