• 대한수학회지
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• 제36권1호
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• pp.229-241
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• 1999

The fractal space is often associated with natural phenomena with many length scales and the functions defined on this space are usually not differentiable. First we define a $\sigma$-multifractal from $\sigma$-iterated function systems with probability. We introduce the measure derivative through the invariant measure of the $\sigma$-multifractal. We show that the non-differentiable function on the $\sigma$-multifractal can be differentiable with respect to this measure derivative. We apply this result to some examples of ordinary differential equations and diffusion processes on $\sigma$-multifractal spaces.

• 대한기계학회논문집
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• 제19권9호
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• pp.2342-2352
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• 1995

Deposition of flame-synthesized silica particles onto a target is utilized in optical fiber preform fabrication processes. The particles are convected and deposited onto the target. Falkner-Skan wedge flow was chosen as the particle laden flow. Typically the particles are polydisperse in size and follow a lognormal size distribution. Brownian diffusion, thermophoresis, and coagulation of the particles were considered and effects of these phenomena on particle deposition were studied. A moment model was developed in order to predict the particle number density and the particle size distribution simultaneously. Particle deposition with various wedge configurations was examined for conditions selected for a typical VAD process. When coagulation was considered, mean particle size and its standard deviation increased and particle number density decreased, compared to the case without coagulation. These results proved the fact that coagulation effect expands particle size distribution. The results were discussed with characteristics of thermal and diffusion boundary layers. As the boundary layers grow in thickness, overall temperature and concentration gradients decrease, resulting in decrease of deposition rate and increase of particle residence time in the flow and thus coagulation effect.

• 한국입자에어로졸학회지
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• 제9권3호
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• pp.163-171
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• 2013

Soot particles emitted from combustion processes are often coated by non-absorbing organic materials, which enhance the global warming effect of soot particles. It is of importance to study the condensation characteristics of soot particles experimentally and theoretically to reduce the uncertainty of the climate impact of soot particles. In this study, the condensational growth of soot particles in a tubular coater was modeled by a one-dimensional (1D) plug flow model and a two-dimensional (2D) laminar flow model. The effects of 2D heat and mass transports on the predicted particle growth were investigated. The temperature and coating material vapor concentration distributions in radial direction, which the 1D model could not accounted for, affected substantially the particle growth in the coater. Under the simulated conditions, the differences between the temperatures and vapor concentrations near the wall and at the tube center were large. The neglect of these variations by the 1D model resulted in a large error in modeling the mass transfer and aerosol dynamics occurring in the coater. The 1D model predicted the average temperature and vapor concentration quite accurately but overestimated the average diameter of the growing particles considerably. At the outermost grid, at which condensation begins earliest due to the lowest temperature and saturation vapor concentration, condensing vapor was exhausted rapidly because of the competition between condensations on the wall and on the particle surface, decreasing the growth rate. At the center of the tube, on the other hand, the growth rate was low due to high temperature and saturation vapor concentration. The effects of Brownian diffusion and thermophoresis were not high enough to transport the coating material vapor quickly from the tube center to the wall. The 1D model based on perfect radial mixing could not take into account this phenomenon, resulting in a much higher growth rate than what the 2D model predicted. The result of this study indicates that contrary to a previous report for a thermodenuder, 2D heat and mass transports must be taken into account to model accurately the condensational particle growth in a coater.

• 재무관리연구
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• 제20권2호
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• pp.95-126
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• 2003

주가가 정규분포보다 꼬리가 두꺼운 확률변수인 점, 주가의 변동이 군집화를 이루고 있는 현상, 주가가 장기기억과정에 의하여 생성되고 있다는 점이 실증분석을 통하여 밝혀지고 있다. 주가를 형성시키는 이 세 요소가 하나의 모형내에 통합되지 못하고 있는 실정인데. 이 세 요소가 통합되는 확률과정이 다중프랙탈과정이다. 다중프랙탈과정은 표준브라운 운동과정과 랜덤시간 변형과정의 결합을 통하여 얻게되는 확률과정이다. 이 과정은 Ito형의 확률과정에 포함되지 않는 연속과정인 것이다. 본 논문에서는 주가시계열의 Pareto-Levy 분포성, 분포의 두꺼운 꼬리성질, 시계열상관이 쌍곡선율로 완만하고 무척 더디게 감소하여 장기에 걸쳐서 평균에 회귀하는 장기기억성, 군집화 현상, 거래시간의 통합성을 포괄하는 다중프랙탈과정의 성질을 살펴보고 이 과정이 주가를 생성시키는 과정인지 아닌지를 검정하는데 그 목적을 둔다. 다중프랙탈과정은 표준브라운 운동과 시간변형과정의 통합을 통하여 형성된 확률과정이다. 시간변형과정은 주가의 군집화 현상을 포착하는 과정이다. 표준브라운 운동은 이 운동과 시간 변형과정의 통합화 속에서 분수브라운운동의 성질이 용해되어 장기기억과정을 포착해준다. 다중프랙탈성은 관찰치들의 시간척축이 변함에 따라 발생하는 확률과정의 적률에 가해진 일련의 제약조건이라 할 수 있다. 이 모형은 마팅게일 성질을 만족하는 모형으로 변형시킬 수도 있으며 자기회귀 조건부 이분산 모형을 대체할 수 있는 모형이다. 이 모형에서는 자기상관을 가지고 있지 않은 수익률에도 적용가능하며, 따라서 시장효율성을 점검하는데에도 이용할 수 있다. 이 모형은 축척일치성이라는 성질이 존재하므로 데이터의 총량화가 무리 없이 이루어질 수 있다. 다중프랙탈은 국소축척구성성질을 가지고 있으며, 시간의 흐름에 따라 변할 수 있는 국소축척구성요소를 내포하고 있다. 자본자산의 다중프랙탈 과정을 한국종합주가지수에 적용하였는 바, 이 과정이 한국종합주가 지수의 행동 잘 설명하고 있다. 따라서 한국종합주가지수는 분포의 꼬리의 두꺼움, 자산가격의 군집화현상, 특이한 값, 장기기억을 내포하고 있다.