Статистическая модель оценки веса газовых баллонов

Объектом исследования: выборка фактического веса пустого баллона, выборка наполненного газом баллона и выборка веса газа. Цель работы: определить количество баллонов для взвешивания, чтобы определить средний вес газа в баллонах в выборке. В процессе исследования проводилась оценка распределения вероятностей на основе выборочных данных для определения веса газа в баллоне и проверка гипотезы о параметрах нормального распределения. В результате исследования сделан вывод о том, к какому типу распределения подчиняется выборка веса газа в баллонах и определено количество взвешиваний баллонов.The object of research: sample of actual weight of empty gas bottle, sample of filled gas bottle and sample of gas weight. Purpose of research: to quantify gas bottles for weighing in order to determine the average weight of the gas in the gas bottles in the sample. During the research the evaluation of probability distribution, based on the sample data for weighing gas in the gas bottle, was applied; proving of hypothesis concerning parameters of the normal distribution was carried out. As the result of the research comes the conclusion concerning the type of distribution which the sample of gas weight in gas bottles submitted to; the number of weighings of gas bottles was determined

Time resolution of a photomultiplier readout system for space application

The performance of a readout system for the synchrotron radiation detector (SRD) is studied. The detector is proposed as part of the Alpha Magnetic Spectrometer experiment, an experiment to fly on the International Space Station (ISS) beginning of 2005. The SRD is designed to detect the synchrotron radiation from electrons and positrons (TeV energy range) produced in the earth's magnetic field. For the planned array of scintillators and photomultipliers a readout system is chosen, which is compact, space qualified and has a low- power consumption. The low-power chip APV, originally designed for the CMS experiment at LHC (CERN), is foreseen for the readout. To overcome the diffuse background from photons and charged particles the SRD readout must have a time resolution better than 10 ns. The intrinsic time resolution (sigma from Gauss fit) of the APV25-S0 was found to be 0.46 +or- 0.01 and 0.68 +or-0.02 ns for the APVM. whereas the time resolution of the photomultiplier-APV readout system was measured to be 2.73 +or- 0.10 ns for the APV25-S0 and 2.90 +or- 0.21 ns for the APVM. The investigated timing capabilities of the photomultiplier-APV readout system show that the APV chip is suitable for the SRD readout