Research on the phase-frequency relationship of the field effect amplifier front-end of shipborne USB system

Normally, most researches on phase calibration of shipborne USB system focus on the means of phase calibration. This article starts with the research on the channel of the system. The composition of the channel is introduced, and the characteristics of the channel is analyzed. Taking the channel of the field effect amplifier front-end as the research object, a mathematical fitting algorithm is used to derive the functional relationship between the phase of the field effect amplifier front-end and the working frequency. The actual calibration data is used for simulation analysis to obtain the fitting order of the function. Combining the phase-frequency relationship of the field effect amplifier front-end and the microwave self-checking phase correction of the field effect amplifier back-end, a new phase calibration method is proposed.

Calibration of Siberian Radioheliograph antenna gains using redundancy

The paper describes application of standard gain calibration using redundancy for a 48-antenna prototype of Siberian Radioheliograph. Traditionally, for calibration, the visibilities were measured only between adjacent antennas since they have the highest signal-to-noise ratio and are sufficient for phase calibration. We have shown that this limited set of visibilities did not allow using the antenna array redundancy potential and obtaining images with a high dynamic range on a permanent basis. Images without amplitude calibration contain many artifacts and require special care when analyzed. The inclusion of visibility measurement between antennas with a double step made it possible to significantly increase the accuracy of solving the system of equations for amplitudes. Images constructed using both phase and amplitude calibrations do not have visible artifacts and are more reliable.

Calibration of Siberian Radioheliograph antenna gains using redundancy

The paper describes application of standard gain calibration using redundancy for a 48-antenna prototype of Siberian Radioheliograph. Traditionally, for calibration, the visibilities were measured only between adjacent antennas since they have the highest signal-to-noise ratio and are sufficient for phase calibration. We have shown that this limited set of visibilities did not allow using the antenna array redundancy potential and obtaining images with a high dynamic range on a permanent basis. Images without amplitude calibration contain many artifacts and require special care when analyzed. The inclusion of visibility measurement between antennas with a double step made it possible to significantly increase the accuracy of solving the system of equations for amplitudes. Images constructed using both phase and amplitude calibrations do not have visible artifacts and are more reliable.

Calibrating a Discrete-Event Simulation for Quantification of Sex-Specific Colorectal Neoplasia Development

Background: Medical evidence collected from new observational studies can sometimes significantly alter our understanding of disease incidence and progression. This requires efficient and accurate calibration of disease models to help quantify the differences between observed cohorts. However, in model calibration, it is common to encounter overfitting with many model parameters but few observational outcomes. Additionally, the difficulty in evaluating fitting performance is significant due to a large degree of outcome variation and expensive computations for even a single simulation run. Methods: We developed a two-phase calibration procedure to address the above challenges. As a proof-of-the-concept study, we verified the procedure with a discrete-event-simulation-based study on sex-specific colorectal neoplasia development. For the study, we estimated eight disease model parameters that govern colorectal adenoma incidence risk and growth rates at three distinct states: non-advanced, advanced adenoma, and adenoma becoming cancerous. For the calibration, we defined the likelihood measure by a relative weighted sum-of-squares difference between the three actual prevalence values reported in a recent publication and those predicted by a discrete-event colorectal cancer simulation. In phase I of the calibration procedure, we performed a series of low-dimensional sampling-based grid searches to identify reasonably good candidate parameter designs. In phase II, we performed a local search-based approach to further improve the model fit.Results: Overall, our two-phase procedure showed better goodness of fit than a straightforward implementation of the Nelder-Mead algorithm, yielding a 10-fold reduction in calibration error (0.0025 vs. 0.0251 for an all-white mixed-family-history male cohort on the likelihood measure defined above). Further, the two-phase procedure was more effective in calibrating a validated simulation model for a female cohort than a male cohort. Finally, in phase II, performing local search on each of the parameters sequentially is more effective than searching the entire parameter space simultaneously. Conclusions: The proposed two-phase calibration procedure is effective for estimating computationally expensive stochastic dynamic disease models. In addition, initial parameter search range truncation and sensitivity analysis on various parameters can be computationally cost-effective.

Independent PRF Generation and Control for Frequency Phase Calibration on Mono-pulse Radar at a Remote Location

This paper presents a method of independent pulse repetition frequency(PRF) generation and control for frequency phase calibration on mono-pulse radar at a remote location. In order to generate an independent PRF signal of 320[Hz], pulse width modulation(PWM) of 16-bit timer/counter was applied. For a precision control of PRF signal, 16-bit timer/counter interrupt was changed for each period. Therefore, average frequency of PRF could be controlled by 0.0001[Hz]. To calibrate a frequency phase of mono-pulse radar at a remote location, the proposed PRF generator with a precision control of frequency was used regardless of receiving PRF signal from a radar. For the verification of the proposed PRF generator, theoretical analysis and experimental results are included.