![]() ![]() In this study, we focused on comparing the newly released exome probe set Agilent SureSelect Human All Exon v8 and the previous probe set v7. It is important for facilities providing genetic services to keep track of changes in the technology of exome capture in order to maximize throughput while reducing cost per sample. The measurements and models presented in this paper constitute the foundation for the development of a sensor for determining the degree of curing an onion has undergone.Exome sequencing is becoming a routine in health care, because it increases the chance of pinpointing the genetic cause of an individual patient's condition and thus making an accurate diagnosis. Preliminary results showed use of a density-independent function was more effective in prediction of moisture content then using dielectric properties alone. ![]() In order to validate the models, a standard error of performance (SEP) was calculated from a set of observations that were not used in the calibration. Models were evaluated for calibration effectiveness in predicting moisture content using coefficient of determination (R²) and standard error of calibration (SEC). Linear regression models were developed using the dielectric constant, dielectric loss factor, and a density-independent function. Dielectric properties were obtained using an open-ended coaxial-line probe connected to a network analyzer. In this study, dielectric properties of Vidalia onions were analyzed for moisture dependence at 13.36 GHz and 23☌ for moisture content between 6% and 92%. Microwave Sensing provides a means to nondestructively determine the amount of moisture in materials by sensing the dielectric properties of the material. In addition, they own better mechanical and stability properties than the widely used agar or gelatin. This versatility offers the chance to create heterogeneous models of particular regions of the body, and thus improve the test realism. These gels can be tailored to control the amount of liquid they embed so that they can imitate different body tissues in a wide bandwidth (2-26.5 GHz), which includes most of the current mobile communication and medical bands. In this paper, PHEA gels are suggested for achieving those properties due to their synthetic nature, which gives them the possibility to be swollen reversibly in more types of mixtures, in addition to water. ![]() Gels are suitable materials because of their high water content, which is required to mimic the dielectric properties of most tissues. These are especially key in body area networks, where the body itself acts as the propagation medium since transmission is highly influenced by its diverse dielectric properties. Tissue phantoms are widely used for assessing the interaction between the electromagnetic waves and the human body. It is believed that previous studies would lead to a promising solution of characterizing materials with high sensitivity, particularly in determining a high Q-factor resonator sensor. This technique enables its use for several industrial applications such as agriculture and quality control. This paper reviews the common characteristics of planar transmission line and discusses numerous studies about several designs of the microstrip resonator to improve the sensor performance in terms of the sensitivity and accuracy. Thus, this technique is cost effective, easy to manufacture and due to its compact size, it has the potential to produce sensitivity and a high Q-factor for various materials. However, these planar transmission lines are often large and expensive to build, further restricting their use in many important applications. Conventionally, cavity waveguide perturbation, free-space transmission, open-ended coaxial probe, and planar transmission line technique have been used for characterizing materials. Microwave sensor is used in various industrial applications and requires highly accurate measurements for material properties. ![]()
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