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Determining cosmological parameters from the brightest SDSS quasarsJanzen, Daryl 25 January 2008 (has links)
According to current cosmological theory, the rate of expansion of the universe depends on the average energy densities of matter, radiation, and a possible vacuum energy described by a cosmological constant, Λ, in the Einstein equation.<p>Observations of galaxies and radiation, along with an assumption that we hold no special place in the universe, imply an isotropic and homogeneous energy distribution, for which the universal rate of expansion for most of the history of the universe may be constructed to depend only on present values of the dimensionless matter and vacuum energy density parameters, Ω<sub>M</sub> and Ω<sub>Λ</sub>, respectively, and the present rate of expansion of the universe, H<sub>0</sub>. Over the past decade, much progress has been made in determining the values of the three density parameters using a variety of independent methods. In particular, observations of type Ia supernovae in the late 1990s provided the first evidence that Λ ≠ 0 and that universal expansion is accelerating.<p>This study has determined values for Ω<sub>M</sub> and Ω<sub>Λ</sub> using the brightest quasars in the Sloan Digital Sky Survey Data Release 5, which are located at a range of distances - equivalently, a range of lookback times - that have not been accessible through any other observations. After fitting the apparent magnitudes of the brightest quasars at various redshifts to the distance modulus equation with a luminosity evolution term, values for the density parameters were determined to be Ω<sub>M</sub> = 0.07 and Ω<sub>Λ</sub> = 1.13.
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Measurement of Balanced Devices Using Vector Network AnalyzersTsai, Di-Chi 12 July 2002 (has links)
This thesis presented a complete measurement method for accurate characterization of balanced devices using two-port vector network analyzer. Combining renormalization and mixed-mode transformation techniques, this method is good for coaxial components. At first, the feasibility of the method was confirmed with the help of ADS simulation. Then a real example of Marchand balun fabricated on FR4 substrate was measured with calibrated mixed-mode S-parameters that have been further verified by full-wave simulations. The measurement system developed based on this method does not require any additional hardware to the vector network analyzer. This system can be also applied to the measurement of on-wafer components with the help of some microwave switches.
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Refinement in Vision-Based Localization of a Remotely Operated Vehicle for Parameter IdentificationChou, Chun-hung 11 September 2007 (has links)
none
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Parameterization of Pulses from a Particle Detector Using a FlashADCHuang, Yunyi January 2014 (has links)
With the deep exploration of particle physics, particle accelerators, detection methods, data recording and processing, and application of computing technology are continuously developing. It has not only brought progress in particle physics, but also promoted the development of the Science and Technology. The main focus of this thesis is data recording and processing. It provides a calibration method for pulses processed by ADCs. It uses some existing filters to achieve the accurate parameters of pulses and existing concept to do the comparison among filters. The FPGA implementation scheme is also discussed in the paper.
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Gravity drainage : microscopic studies and free fall in fractured reservoirsSajjadian, Valiahmad January 1999 (has links)
No description available.
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Parametrické 3D modely / Parametric 3D ModelsOndrejó, Michal January 2020 (has links)
The aim of this work is to propose possibilities of interconnection of objects in parametric model. Individual options are implemented in the parametric three-dimensional modeling system. This system allows the creation of models using various geometric operations, change parameters at any time, animate the created model, and save the parametric model in a human-readable format. The proposed solution was implemented and evaluated on simple example.
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Estimating Wind Profile Parameters Over a Maturing CropKalanda, Brian Douglas 04 1900 (has links)
Abstract Not Provided. / Thesis / Bachelor of Science (BSc)
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A NOVEL METHODOLOGY FOR MODELING PERFORMANCE PARAMETERS OF ANALOG CIRCUITSBALASUBRAMANIAN, SHYAM SUNDAR January 2004 (has links)
No description available.
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Formulation, in vitro release and transdermal diffusion of atropine by implementation of the delivery gap principle / Jani van der WesthuizenVan der Westhuizen, Jani January 2014 (has links)
The transdermal delivery route has become a popular alternative to more conventional routes, such as oral administration, but has not yet reached its full potential (Prausnitz & Langer, 2008:1261). Although the transdermal route proves to have several advantages over the conventional route, the greatest challenge is to overcome the effective barrier of the skin (Jepps et al., 2012:153). The permeation of the active pharmaceutical ingredient (API) through the skin is a complex, multi-step process and therefore predicting the permeability of the API is difficult (Jepps et al., 2012:153; Williams, 2003:30). Various approaches have been developed to overcome the skin barrier and it is recognised that the nature of the vehicle in which the API is applied plays a significant role in promoting transdermal delivery (Foldvari, 2000:417). It is important to consider the fate of the formulation ingredients and the API after application and how this changes the composition of the formulation on the skin when developing a vehicle for transdermal delivery (Lane et al., 2012:496; Otto et al., 2009:2).
Wiechers (2012) proposed the Skin Delivery Gap (SDG) as an indicator for the permeability of an API. An API with a SDG < 1 will readily permeate the skin, whilst an SDG > 1 indicates a more complex delivery system is required. The partitioning of the API between the skin and the formulation is influenced by the formulation and by altering the formulation properties it is possible to manipulate the transdermal delivery of the API. The relative polarity index (RPI), based on the octanol-water partition coefficient (log P) of the stratum corneum, formulation and the API, was initially developed by Wiechers as a tool for developing formulations with an optimal polarity, to ensure the transdermal delivery of at least 50% of the API (Lane et al., 2012:498; Wiechers, 2008:94; Wiechers et al., 2004:174). The use of log P as an indicator of polarity was considered impractical by Hansen (2013) and acknowledged by both Wiechers and Abbott, who consequently developed the Formulating for Efficacy™ (FFE™) software which uses Hansen solubility parameters (HSP) instead of log P to indicate polarity (Hansen, 2013). The FFE™ calculates HSP distances, known as gaps, between the skin, API and the formulation to indicate the solubility of the different components in each other. A smaller HSP gap indicates a high solubility. The FFE™ enables the formulator to develop a formulation with a good balance between the active-formulation gap (AFG) and the skin-formulation gap (SFG) to ensure sufficient diffusion of the API into the skin.
The FFE™ software was used to develop formulations containing 1.5% atropine as a model drug. Formulations of different polarity (optimised towards the stratum corneum, more hydrophilic and more lipophilic) were developed to determine the effect of the polarity of the formulation and the relevant HSP gaps on the transdermal delivery of the API. The same
formulations were utilised for atropine sulphate to determine the effect the salt form has on the transdermal delivery of the API compared to the base compound.
The log P and octanol-buffer partition coefficient (log D) of both atropine and atropine sulphate were determined. Log D is a more reliable indicator of distribution compared to log P, since, it considers the degree of ionisation of the API (Ashford, 2007:294). The log P and log D of atropine (0.22 and -1.26) and atropine sulphate (-1.32 and -1.23) both predicted poor skin penetration (Brown et al., 2005:177). The aqueous solubility of atropine (0.9 mg/ml) also predicted limited transdermal delivery, while the solubility of atropine in phosphate buffer solution (PBS pH 7.4) (5.8 mg/ml) indicated favourable permeation (Naik et al., 2000:321). The high degree of ionisation of the API (99.68 %), at pH 7.4, predicts only a small amount will penetrate the skin (Barry, 2007:576).
The membrane release study confirmed the API was released from the different formulations and subsequently skin diffusion studies were conducted, followed by tape stripping after 12 h, to determine which formulation resulted in the highest transdermal delivery of the API. The atropine hydrophilic formulation released the highest percentage of API after 6 h (13.930%). This was explained by the low affinity the lipophilic atropine has towards the hydrophilic formulation (Otto et al., 2009:9). The highest percentage transdermal delivery (0.065%) was observed with the lipophilic formulation containing atropine. The higher SFG compared to the AFG of the lipophilic formulation initially predicted poor transdermal delivery, but when considering the HSP profile and molar volume of the different ingredients, it was observed the dimethyl isosorbide (DMI) penetrated and provided a desirable environment for the API in the skin. The residual formulation (containing less DMI and more polyethylene glycol 400 (PEG 8) and liquid paraffin) was less desirable for the API and was therefore forced out of the formulation (Abbott, 2012:219). Both these factors contributed to the high transdermal delivery of atropine from the lipophilic formulation. The atropine sulphate hydrophilic formulation had the highest percentage in the stratum corneum-epidermis (0.29 μg/ml) and the hydrophilic formulation of both atropine and atropine sulphate had the highest concentration in the epidermis-dermis (both 0.55 μg/ml). The hydrophilic formulations had the lowest driving force provided by the AFG and the only driving force for the API to leave the formulation was the concentration gradient. These formulations had the lowest transdermal delivery which indicates the API had not fully traversed through the skin after 12 h.
According to Wiechers, a minimised SFG would indicate the formulation is optimised towards the stratum corneum and should essentially deliver the highest percentage of API through the skin. The results obtained are contrary to this belief and it is concluded that the total HSP profile and the molar volume of the formulation and the API should be considered when developing a formulation with optimal transdermal delivery rather than just the SFG. / MSc (Pharmaceutics), North-West University, Potchefstroom Campus, 2015
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Formulation, in vitro release and transdermal diffusion of atropine by implementation of the delivery gap principle / Jani van der WesthuizenVan der Westhuizen, Jani January 2014 (has links)
The transdermal delivery route has become a popular alternative to more conventional routes, such as oral administration, but has not yet reached its full potential (Prausnitz & Langer, 2008:1261). Although the transdermal route proves to have several advantages over the conventional route, the greatest challenge is to overcome the effective barrier of the skin (Jepps et al., 2012:153). The permeation of the active pharmaceutical ingredient (API) through the skin is a complex, multi-step process and therefore predicting the permeability of the API is difficult (Jepps et al., 2012:153; Williams, 2003:30). Various approaches have been developed to overcome the skin barrier and it is recognised that the nature of the vehicle in which the API is applied plays a significant role in promoting transdermal delivery (Foldvari, 2000:417). It is important to consider the fate of the formulation ingredients and the API after application and how this changes the composition of the formulation on the skin when developing a vehicle for transdermal delivery (Lane et al., 2012:496; Otto et al., 2009:2).
Wiechers (2012) proposed the Skin Delivery Gap (SDG) as an indicator for the permeability of an API. An API with a SDG < 1 will readily permeate the skin, whilst an SDG > 1 indicates a more complex delivery system is required. The partitioning of the API between the skin and the formulation is influenced by the formulation and by altering the formulation properties it is possible to manipulate the transdermal delivery of the API. The relative polarity index (RPI), based on the octanol-water partition coefficient (log P) of the stratum corneum, formulation and the API, was initially developed by Wiechers as a tool for developing formulations with an optimal polarity, to ensure the transdermal delivery of at least 50% of the API (Lane et al., 2012:498; Wiechers, 2008:94; Wiechers et al., 2004:174). The use of log P as an indicator of polarity was considered impractical by Hansen (2013) and acknowledged by both Wiechers and Abbott, who consequently developed the Formulating for Efficacy™ (FFE™) software which uses Hansen solubility parameters (HSP) instead of log P to indicate polarity (Hansen, 2013). The FFE™ calculates HSP distances, known as gaps, between the skin, API and the formulation to indicate the solubility of the different components in each other. A smaller HSP gap indicates a high solubility. The FFE™ enables the formulator to develop a formulation with a good balance between the active-formulation gap (AFG) and the skin-formulation gap (SFG) to ensure sufficient diffusion of the API into the skin.
The FFE™ software was used to develop formulations containing 1.5% atropine as a model drug. Formulations of different polarity (optimised towards the stratum corneum, more hydrophilic and more lipophilic) were developed to determine the effect of the polarity of the formulation and the relevant HSP gaps on the transdermal delivery of the API. The same
formulations were utilised for atropine sulphate to determine the effect the salt form has on the transdermal delivery of the API compared to the base compound.
The log P and octanol-buffer partition coefficient (log D) of both atropine and atropine sulphate were determined. Log D is a more reliable indicator of distribution compared to log P, since, it considers the degree of ionisation of the API (Ashford, 2007:294). The log P and log D of atropine (0.22 and -1.26) and atropine sulphate (-1.32 and -1.23) both predicted poor skin penetration (Brown et al., 2005:177). The aqueous solubility of atropine (0.9 mg/ml) also predicted limited transdermal delivery, while the solubility of atropine in phosphate buffer solution (PBS pH 7.4) (5.8 mg/ml) indicated favourable permeation (Naik et al., 2000:321). The high degree of ionisation of the API (99.68 %), at pH 7.4, predicts only a small amount will penetrate the skin (Barry, 2007:576).
The membrane release study confirmed the API was released from the different formulations and subsequently skin diffusion studies were conducted, followed by tape stripping after 12 h, to determine which formulation resulted in the highest transdermal delivery of the API. The atropine hydrophilic formulation released the highest percentage of API after 6 h (13.930%). This was explained by the low affinity the lipophilic atropine has towards the hydrophilic formulation (Otto et al., 2009:9). The highest percentage transdermal delivery (0.065%) was observed with the lipophilic formulation containing atropine. The higher SFG compared to the AFG of the lipophilic formulation initially predicted poor transdermal delivery, but when considering the HSP profile and molar volume of the different ingredients, it was observed the dimethyl isosorbide (DMI) penetrated and provided a desirable environment for the API in the skin. The residual formulation (containing less DMI and more polyethylene glycol 400 (PEG 8) and liquid paraffin) was less desirable for the API and was therefore forced out of the formulation (Abbott, 2012:219). Both these factors contributed to the high transdermal delivery of atropine from the lipophilic formulation. The atropine sulphate hydrophilic formulation had the highest percentage in the stratum corneum-epidermis (0.29 μg/ml) and the hydrophilic formulation of both atropine and atropine sulphate had the highest concentration in the epidermis-dermis (both 0.55 μg/ml). The hydrophilic formulations had the lowest driving force provided by the AFG and the only driving force for the API to leave the formulation was the concentration gradient. These formulations had the lowest transdermal delivery which indicates the API had not fully traversed through the skin after 12 h.
According to Wiechers, a minimised SFG would indicate the formulation is optimised towards the stratum corneum and should essentially deliver the highest percentage of API through the skin. The results obtained are contrary to this belief and it is concluded that the total HSP profile and the molar volume of the formulation and the API should be considered when developing a formulation with optimal transdermal delivery rather than just the SFG. / MSc (Pharmaceutics), North-West University, Potchefstroom Campus, 2015
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