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Sensor-based Characterization and Control of Additive Biomanufacturing ProcessesSingh, Manjot 10 June 2021 (has links)
According to data provided by the U.S. Department of Health and Human Services, the waiting list of organ transplantation as of April 2021 is approximately 107,550 out of which 90,908 patients are waiting for a kidney and 11,871 are waiting for a liver. In 2020, only 39,000 transplants were performed. A promising potential solution to this organ shortage crisis is rapid development of drugs for end-stage kidney and liver failure and the fabrication of organs using additive biomanufacturing (Bio-AM) processes. While progress toward industrial-scale production of 3D-bioprinted tissue models and organs remains hindered by various biological and tissue engineering challenges, such as vascularization and innervation, quality Bio-AM is impeded by lack of integrated process monitoring and control strategies. This dissertation aims to address the compelling need to incorporate sensing and control with Bio-AM processes, which are currently open-loop processes and improve the scalability and reliability of additively biomanufactured products.
The specific aim is to develop a closed loop-controlled additive biomanufacturing process capable of fabricating 3D-bioprinted biological constructs (mini-tissues) of controlled mechanical properties. The proposed methodology is based on the use of embedded sensors and real-time material property sensing for feedback control of the bioprinted constructs mechanical property. There are three objectives of this dissertation:
(1) experimenting and modeling the processes to understand the causal effect of process-material interactions on Bio-AM defects,
(2) use of sensors to detect defects during printing,
(3) prevention of the propagation of defects through closed-loop process control.
This will help us understand the fundamentals of the bio-physical process interactions that govern the quality of printed biological tissue through empirical investigation of the sensor-based data This will also provide us with a real-time monitoring, closed-loop quality control strategy to prevent the propagation of quality defects by executing corrective actions during the whole duration of the printing process. / Doctor of Philosophy / As of April 2021, there are 107,550 patients on the national transplant list out of which approximately 39,000 patients received a transplant. Simultaneously, drug development remains an expensive and time-consuming endeavor. These burden on the public and healthcare system are expected to further increase compounded by the rapidly aging population in the United States with 80 million people expected to be older than 65 years old by 2040. Additive biomanufacturing processes, commonly referred to as 3D bioprinting processes, are automated biofabrication processes that offer great potential toward manufacturing future therapeutics and models for drug discovery. Despite all the benefits and the versatility that 3D printing provides, it does not come without its own shortcomings. Additive biomanufacturing is traditionally an open-loop process, meaning the process parameters are not adjusted during the biofabrication process making it challenging to detect and correct defects during processing and achieve high reproducibility and product quality.
While the dimensional characteristics and material properties are important quality signatures of a cell-based products, there are additional signatures associated with the cell quality. Some of these quality attributes include cell viability, cell proliferation, metabolic activity, morphology, and gene expression profile. Given the clinical importance and invasive nature of bio-products such as scaffolds for tissue regeneration and stem cell therapy, rigorous approaches for characterization, monitoring, and control of quality are critical to future additive bio-manufacturing paradigms. In particular, the elastic modulus of the extracellular matrix has been found to have an influence on the cell morphology, proliferation, and differentiation process. Hence, it is an excellent parameter to monitor as a measure of tissue quality. However, the traditional techniques used to characterize tissue elastic modulus are low-throughput, offline techniques and face challenges with tissue integration. Thus, there is a need for integrated sensors that can measure the modulus of tissues during 3D bioprinting.
This dissertation aims to address some of these issues by developing a multi-material 3D printing and pick-and-place approach to develop smart tissue cultureware and designing a tissue integrated closed-loop feedback sensor system for polymerization of hydrogels.
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Dynamic Mission Planning for Unmanned Aerial VehiclesRennu, Samantha R. January 2020 (has links)
No description available.
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Sensor óptico de alta tensão com chaveamento de quadratura e realimentado por controle de fase /Pereira, Fernando da Cruz. January 2018 (has links)
Orientador: Cláudio Kitano / Resumo: Os transformadores de potencial baseados em tecnologia óptica têm sido desenvolvidos com a finalidade de melhorar o desempenho na proteção e medição nos sistemas elétricos de potência. Estes transformadores de potencial podem ser projetados em torno dos moduladores eletro-ópticos de amplitude que, por sua vez, são baseados no efeito Pockels em cristal como o Niobato de Lítio. A expressão geral da transmissão (razão entre o retardo de fase e a tensão aplicada) de um modulador eletro-óptico de intensidades é idêntica à expressão do sinal de saída de um interferômetro de dois feixes. Através de processamento eletrônico de dois sinais interferométricos de saída, com fase relativa de 90o entre si, consegue-se demodular o sinal, independentemente das derivas ambientais. Esses interferômetros, chamados de interferômetros de quadratura, são amplamente utilizados em laboratórios de metrologia. Assim, em 2014, um método de detecção interferométrica de fase óptica foi desenvolvido no Laboratório de Optoeletrônica (LOE) da FEIS-UNESP, constituindo uma versão melhorada da técnica de phase-unwrapping. Este método é imune ao fenômeno de desvanecimento, consegue medir o tempo de atraso entre o estímulo e a resposta, tem ampla faixa dinâmica, reconstrói a forma de onda do sinal de modulação sem a necessidade de aplicação de filtros à saída interferométrica, possuindo, ainda, a capacidade de demodular sinais com formas de ondas não periódicas. Beneficiando-se dessas informações, promoveu-se a ... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: Optical technology-based potential transformers have been developed to improve performance in protection and measurement in electrical power systems. These potential transformers can be designed around amplitude electro-optical modulators which, in turn, are based on the crystal Pockels effect such as Lithium Niobate. The general expression of the transmission (ratio between phase delay and applied voltage) of an electro-optical modulator of intensities is identical to the expression of the output signal of a two-beam interferometer. By electronic processing of two interferometric output signals, with relative phase of 90o between each other, the signal can be demodulated, irrespective of the environmental drift. These interferometers, called quadrature interferometers, are widely used in metrology laboratories. Thus, in 2014, an optical phase interferometric detection method was developed at the FEIS-UNESP’s Optoelectronic Laboratory (LOE), constituting an improved version of the phase-unwrapping technique. This method is immune to the phenomenon of fading, can measure the delay time between the stimulus and the response, has a wide dynamic range, reconstructs the waveform of the modulation signal without the need of applying filters to the interferometric output, also possessing the ability to demodulate signals with non-periodic waveforms. Taking advantage of this information, the adaptation of the method to a high voltage optical sensor in a quadrature configuration was p... (Complete abstract click electronic access below) / Doutor
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Sensor óptico de alta tensão com chaveamento de quadratura e realimentado por controle de fase / High-voltage optical sensor with quadrature switching and phase-controlled feedbackPereira, Fernando da Cruz 09 March 2018 (has links)
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Previous issue date: 2018-03-09 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Os transformadores de potencial baseados em tecnologia óptica têm sido desenvolvidos com a finalidade de melhorar o desempenho na proteção e medição nos sistemas elétricos de potência. Estes transformadores de potencial podem ser projetados em torno dos moduladores eletro-ópticos de amplitude que, por sua vez, são baseados no efeito Pockels em cristal como o Niobato de Lítio. A expressão geral da transmissão (razão entre o retardo de fase e a tensão aplicada) de um modulador eletro-óptico de intensidades é idêntica à expressão do sinal de saída de um interferômetro de dois feixes. Através de processamento eletrônico de dois sinais interferométricos de saída, com fase relativa de 90o entre si, consegue-se demodular o sinal, independentemente das derivas ambientais. Esses interferômetros, chamados de interferômetros de quadratura, são amplamente utilizados em laboratórios de metrologia. Assim, em 2014, um método de detecção interferométrica de fase óptica foi desenvolvido no Laboratório de Optoeletrônica (LOE) da FEIS-UNESP, constituindo uma versão melhorada da técnica de phase-unwrapping. Este método é imune ao fenômeno de desvanecimento, consegue medir o tempo de atraso entre o estímulo e a resposta, tem ampla faixa dinâmica, reconstrói a forma de onda do sinal de modulação sem a necessidade de aplicação de filtros à saída interferométrica, possuindo, ainda, a capacidade de demodular sinais com formas de ondas não periódicas. Beneficiando-se dessas informações, promoveu-se a adaptação do método a um sensor óptico de altas tensões em configuração de quadratura de sinais. Desta forma, a presente pesquisa aborda o estudo e o desenvolvimento de um sensor óptico de alta tensão com chaveamento de quadratura, baseado em célula Pockels, dando continuidade às pesquisas em desenvolvimento no LOE, de um sistema de sensoriamento eletro-óptico de alta tensão. O sensor de alta tensão com chaveamento de quadratura e realimentado por controle de fase, foi implementado e submetido a testes com aplicação de tensões entre 200 V e 8,4 kV (de pico) em 60 Hz, apresentado excelente linearidade na faixa de interesse e boa precisão na medição do conteúdo harmônico dos sinais. Tais resultados evidenciam o potencial do sistema para operar na análise da qualidade de energia elétrica em sistemas da classe de 13,8 kV. / Optical technology-based potential transformers have been developed to improve performance in protection and measurement in electrical power systems. These potential transformers can be designed around amplitude electro-optical modulators which, in turn, are based on the crystal Pockels effect such as Lithium Niobate. The general expression of the transmission (ratio between phase delay and applied voltage) of an electro-optical modulator of intensities is identical to the expression of the output signal of a two-beam interferometer. By electronic processing of two interferometric output signals, with relative phase of 90o between each other, the signal can be demodulated, irrespective of the environmental drift. These interferometers, called quadrature interferometers, are widely used in metrology laboratories. Thus, in 2014, an optical phase interferometric detection method was developed at the FEIS-UNESP’s Optoelectronic Laboratory (LOE), constituting an improved version of the phase-unwrapping technique. This method is immune to the phenomenon of fading, can measure the delay time between the stimulus and the response, has a wide dynamic range, reconstructs the waveform of the modulation signal without the need of applying filters to the interferometric output, also possessing the ability to demodulate signals with non-periodic waveforms. Taking advantage of this information, the adaptation of the method to a high voltage optical sensor in a quadrature configuration was promoted. In this way, the present research deals with the study and development of a high voltage optical sensor with quadrature switching, based on Pockels cell, giving continuity to researches in the LOE of a high voltage electro-optical sensing system. The high voltage sensor with quadrature switching and phase controlled feedback was implemented and submitted to tests with voltage between 200 V and 8.4 kV (peak) at 60 Hz, with excellent linearity in the range of interest and good accuracy in measuring the harmonic content of the signals. These results show the potential of the system to operate in the analysis of electric power quality in systems of the class of 13.8 kV.
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Active Vibration Control Synthesis Using Viscoelastic Damping PhenomenaVadiraja, G K 07 1900 (has links) (PDF)
In this thesis, a new method is followed to design an active control system which imparts viscoelastic phenomenological damping in an elastic structure. Properties of a hypothetical viscoelastic system are used to design an active feedback controller for an undamped structural system with distributed sensor, actuator and controller. The variational structure is projected on a solution space of a closed-loop system involving a weakly damped structure with distributed sensor and actuator with controller. These controller components assign the phenomenology based on internal strain rate damping parameter of a viscoelastic system to the undamped elastic structure.
An elastic cantilever beam with proportional-derivative controller and displacement feedback is considered in all the design formulations. In the first part of the research, a closed-loop control system is designed using two time domain modern control system design methods, pole placement and optimal pole placement, which use viscoelastic damping parameter. Equation of motion of a viscoelastic system is employed to synthesize the desired closed-loop poles. Desired poles are then assigned to an elastic beam with an active controller. Time domain finite element formulation is used without considering actuator-sensor dynamics and the effect of transducer locations. Characteristics of closed-loop system gains are found as a function of desired damping parameter and realization of damping have been analyzed with closed loop system pole positions.
The next part consists of a novel frequency domain active control system design to impart desired viscoelastic characteristics, which uses spectral method and the exact dynamic stiffness matrix of the system. In the first case, a sub-optimal local control system for a cantilever beam, with collocated actuator and sensor is designed. In the second case, a closed-loop local controller for an elastic system with non-collocated transducers is designed. Next, a global controller for non-collocated arrangement of sensor-actuator is designed by considering all the degrees-of freedom in the system, which leads to solving an eigenvalue problem. The reason for the failure of the collocated arrangement in global control is also explained. In this novel control system design method transducer dynamics and locations are considered in the formulation.
In frequency domain design, the frequency responses of the system show satisfactory performance of the closed-loop elastic system. The closed-loop system is able to reproduce the desired viscoelastic characteristics as targeted in the design. Optimal and sub-optimal system gains are found as functions of transducer locations, transducer properties, excitation frequency and internal strain rate damping parameter of a hypothetical viscoelastic system. Performance of the closed loop system is established by comparing the specific damping capacity of the hypothetical viscoelastic system with that of the closed-loop elastic system. The novel frequency domain method is simple, accurate, efficient and can be extended to complex structures to achieve desired damping. The method can be a better way of designing structures with variable stiffness which has research potential in designing morphing airplanes/spacecrafts. The ultimate goal of this research is that, if this design method is applied to practical applications such as aircraft wings, where vibration is undesirable, one would be able to achieve strength and desired damping characters simultaneously.
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