• 의료법학
• /
• 제21권3호
• /
• pp.145-178
• /
• 2020

뇌신경과학 기술의 발전으로 인하여 자신의 뇌신경적 상태와 데이터에 관한 자율적 선택과 개입의 가능성이 늘어남에 따라, 본인의 의사에 반하여 혹은 본인에게 불리하게 이용될 위험성도 커지게 될 수 있으므로, 이러한 부당한 간섭이나 방해로부터 개인의 자유와 권리를 보호해야 한다는 주장들이 계속해서 제기되고 있다. 대표적인 예로 2020년 10월 칠레 의회에 제출된 '뇌신경권 및 정신적 완전성의 보호 등에 관한 법안'은 뇌신경 데이터를 뇌로부터 직·간접적으로 수집된 모든 데이터로 정의하고, 정신적 프라이버시와 완전성을 개인의 뇌신경권(Neuroderechos)으로 보호할 것을 명시하였다. 뇌신경과학은 점점 개인의 신체와 일상에 가까이 스며드는 기술로 진화하여 더욱 일상화, 개인화되는 동시에 모듈의 형태로도 변모할 잠재력을 충분히 지니고 있고 빅데이터와 인공지능 기술의 발전은 이러한 변화를 더욱 가속화·고도화하는 요인이 된다. 이는 곧 다양한 종류의 기기로 뇌신경적 상태를 디지털 데이터화하고 분석하여 활용할 수 있게 된다는 것을 의미한다. 그리고 이로 인해 개인의 의도, 선호, 성격, 기억, 감정 상태 등을 확인하고 추론해낼 수 있는 데이터를 더 많이 생성할 수 있는 환경으로 변화하고 있다는 점은 개인의 자유와 권리에 관한 논의의 필요성을 더욱 부각시키고 있다. 그런데 뇌신경 데이터는 개인정보 보호 법제하에서 민감정보로 볼 것인지 여부가 불분명한 영역이 있다. 또 구체적인 활용 영역 예컨대, 법정, 교육, 고용 등에서 어떻게 뇌신경 데이터 주체를 보호할 것인지에 대한 법적 고찰이 요청된다. 이 논문에서는 기존의 인지적 자유, 정신적 프라이버시, 뇌신경 프라이버시, 정신적 완전성 등 다양한 개념으로 제시되고 있는 논의를 포괄적인 인격권의 성격을 갖는 '뇌신경권'이라는 개념으로 포섭하고자 한다.

• 한국항공우주학회지
• /
• 제38권3호
• /
• pp.228-235
• /
• 2010

본 논문에서는 틸트로터 항공기의 회전익 모드에 대한 자율비행 유도제어 알고리즘을 적응제어기법을 이용하여 설계하는 것이다. 이를 위해 우선 출력기반 근사적 궤환선형화 기법을 통하여 알고리즘의 내부루프를 구성하고 그로부터 발생하는 모델오차를 단일 은닉층-신경망을 적용하여 상쇄하였다. 그리고 리아푸노프 안정성 이론에 따른 적응제어 갱신법칙은 선형 관측기를 기반으로 설계하였다. 나아가 외부루프는 경로점 유도법칙으로부터 생성되는 궤적을 추종하도록 하였으며 특히 엄밀한 자동착륙 궤적추종 성능 향상을 위하여 방향각 및 비행경로각 시선유도법칙을 설계하였다. 틸트로터 비선형 모델 시뮬레이션 결과는 콜렉티브 입력에서 보이는 순간적인 작동기 포화현상 이외에는 만족할 만한 안정성과 추종성능을 보여 주고 있다.

• 지능정보연구
• /
• 제9권3호
• /
• pp.81-97
• /
• 2003

본 논문에서는 인간시각시스템의 특성에 기반하여 웨이블릿 변환을 적용하여 멀티미디어 데이터의 소유권 보호를 위하여 시각적으로 눈에 띄지 않는 강인한 워터마킹 기법을 제안하고 있다. 이를 위하여 우선 웨이블릿 변환을 사용하여 level 3에서 원 영상을 분해한 후, 최저파수 대역에 해당하는 LL$_3$대역을 제외한 모든 부 대역에 신경회로망을 사용하여 웨이블릿 분해 계수들을 분류한 다음, 최대값을 갖는 클러스터에 대해서 임계치를 적용한다. 그리고 사용된 워터마크는 워터마크의 시각적 확인을 위하여 가우시안 랜덤 벡터 대신에 이진 로고 형태의 워터마크를 사용하였다. 또한, 본 논문에서는 다중 워터마크의 삽입 및 검출을 테스트하였다. 이를 위하여, 웨이블릿 변환을 이용하여 level 3에서 원 영상을 분해한 후, 최 저주파수 대역에 해당하는 LL$_3$ 대역을 제외한 모든 부대역에 대하여 워터마크를 삽입하였다. 실험에서 우리는 여러 가지 공격에서도 삽입한 워터마크가 강인함을 알 수 있었다.

• 융합보안논문지
• /
• 제7권1호
• /
• pp.29-34
• /
• 2007

본 논문에서는 디지털 콘텐츠의 저작권을 보호하기 위하여 공모공격에 강인한 BIBD 기반의 불법공모방지코드를 설계하였다. 또한 핑거프린트 정보는 디지털 콘텐츠의 전송 중 외부 공격 및 잡음 등에 의해 손실이 발생할 수 있는데 이러한 점을 개선하기 위하여 홉필드 신경회로망을 이용하여 손실이 발생한 코드를 정정할 수 있는 핑거프린트 알고리즘을 제안하였다. 제안된 알고리즘은 크게 선형 공모 공격에 강인성을 가지는 BIBD 기반의 불법공모방지코드 설계와 외부공격에 의해 발생한 에러비트를 정정하기 위한 피드백형 연상메모리방식의 홉필드 신경회로망으로 구성되어있다. 실험 결과 BIBD 기반의 불법공모방지코드는 평균화 선형 공모공격에 대해 100% 공모코드 검출이 이루어졌으며 에러비트 정정을 위해 설계한 (n, k) 코드를 사용한 홉필드 신경회로망은 2비트 이내의 에러비트를 정정할 수 있음을 확인하였다. 결과적으로 제안된 알고리즘은 평균화 공모공격 및 공모코드에 에러비트가 발생되었을 때 공모자를 정확히 검출할 수 있음을 확인하였다.

• Journal of Radiation Protection and Research
• /
• 제46권4호
• /
• pp.204-212
• /
• 2021

Background: Identification of radioisotopes for plastic scintillation detectors is challenging because their spectra have poor energy resolutions and lack photo peaks. To overcome this weakness, many researchers have conducted radioisotope identification studies using machine learning algorithms; however, the effect of data normalization on radioisotope identification has not been addressed yet. Furthermore, studies on machine learning-based radioisotope identifiers for plastic scintillation detectors are limited. Materials and Methods: In this study, machine learning-based radioisotope identifiers were implemented, and their performances according to data normalization methods were compared. Eight classes of radioisotopes consisting of combinations of ²²Na, ⁶⁰Co, and ¹³⁷Cs, and the background, were defined. The training set was generated by the random sampling technique based on probabilistic density functions acquired by experiments and simulations, and test set was acquired by experiments. Support vector machine (SVM), artificial neural network (ANN), and convolutional neural network (CNN) were implemented as radioisotope identifiers with six data normalization methods, and trained using the generated training set. Results and Discussion: The implemented identifiers were evaluated by test sets acquired by experiments with and without gain shifts to confirm the robustness of the identifiers against the gain shift effect. Among the three machine learning-based radioisotope identifiers, prediction accuracy followed the order SVM > ANN > CNN, while the training time followed the order SVM > ANN > CNN. Conclusion: The prediction accuracy for the combined test sets was highest with the SVM. The CNN exhibited a minimum variation in prediction accuracy for each class, even though it had the lowest prediction accuracy for the combined test sets among three identifiers. The SVM exhibited the highest prediction accuracy for the combined test sets, and its training time was the shortest among three identifiers.

• Journal of Radiation Protection and Research
• /
• 제48권4호
• /
• pp.175-183
• /
• 2023

Background: Recently, biological adsorbents have been developed for removing radionuclides from radioactive liquid waste due to their high selectivity, eco-friendliness, and renewability. However, since they can be damaged by radiation in radioactive waste, a method for estimating the bio-adsorbent performance as a time should consider the radiation damages in terms of their renewability. This paper aims to develop a simulation method that applies a deep learning technique to rapidly and accurately estimate the adsorption performance of bio-adsorbents when inserted into liquid radioactive waste. Materials and Methods: A model that describes various interactions between a bio-adsorbent and liquid has been constructed using numerical methods to estimate the adsorption capacity of the bio-adsorbent. To generate datasets for machine learning, Monte Carlo N-Particle (MCNP) simulations were conducted while considering radioactive concentrations in the adsorbent column. Results and Discussion: Compared with the result of the conventional method, the proposed method indicates that the accuracy is in good agreement, within 0.99% and 0.06% for the R² score and mean absolute percentage error, respectively. Furthermore, the estimation speed is improved by over 30 times. Conclusion: Note that an artificial neural network can rapidly and accurately estimate the survival rate of a bio-adsorbent from radiation ionization compared with the MCNP simulation and can determine if the bio-adsorbents are reusable.

• Computers and Concrete
• /
• 제19권5호
• /
• pp.457-465
• /
• 2017

The Taiwanese liquid crystal display (LCD) industry has traditionally produced a huge amount of waste glass that is placed in landfills. Waste glass recycling can reduce the material costs of concrete and promote sustainable environmental protection activities. Concrete is always utilized as structural material; thus, the concrete compressive strength with a variety of mixtures must be studied using predictive models to achieve more precise results. To create an efficient waste LCD glass concrete (WLGC) design proportion, the related studies utilized a multivariable regression analysis to develop a compressive strength waste LCD glass concrete equation. The mix design proportion for waste LCD glass and the compressive strength relationship is complex and nonlinear. This results in a prediction weakness for the multivariable regression model during the initial growing phase of the compressive strength of waste LCD glass concrete. Thus, the R ratio for the predictive multivariable regression model is 0.96. Neural networks (NN) have a superior ability to handle nonlinear relationships between multiple variables by incorporating supervised learning. This study developed a multivariable prediction model for the determination of waste LCD glass concrete compressive strength by analyzing a series of laboratory test results and utilizing a neural network algorithm that was obtained in a related prior study. The current study also trained the prediction model for the compressive strength of waste LCD glass by calculating the effects of several types of factor combinations, such as the different number of input variables and the relevant filter for input variables. These types of factor combinations have been adjusted to enhance the predictive ability based on the training mechanism of the NN and the characteristics of waste LCD glass concrete. The selection priority of the input variable strategy is that evaluating relevance is better than adding dimensions for the NN prediction of the compressive strength of WLGC. The prediction ability of the model is examined using test results from the same data pool. The R ratio was determined to be approximately 0.996. Using the appropriate input variables from neural networks, the model validation results indicated that the model prediction attains greater accuracy than the multivariable regression model during the initial growing phase of compressive strength. Therefore, the neural-based predictive model for compressive strength promotes the application of waste LCD glass concrete.

• Geomechanics and Engineering
• /
• 제14권1호
• /
• pp.91-98
• /
• 2018

Length of a vehicle is an important variation to generate different variants of an automotive platform. This parameter is usually adjusted by embedding dimensional flexibility into different components of the Body in White (BIW) including the floor pan. Due to future uncertainties, it is not necessarily possible to define certain values of wheelbase for the future products of a platform. This work is performed to add flexibility into the design process of a length-variable floor pan. By means of this analysis, the cost and time consuming process of optimization is not necessary to be performed for designing the different variants of a product family. Stiffness and mass of the floor pan are two important functional requirements of this component which directly affect the occupant comfort, dynamic characteristics, fuel economy and environmental protection of the vehicle. A combination of Genetic algorithm, GMDH-type of artificial neural networks and TOPSIS methods is used to optimally design the floor pan associated with arbitrary length of the variant in the defined system range. The correlation between the optimal results shows that for a constant mass of the floor pan, the first natural frequency decreases by increasing the length of this component.

• 한국공간구조학회논문집
• /
• 제23권3호
• /
• pp.87-94
• /
• 2023

Chloride is one of the most common threats to reinforced concrete (RC) durability. Alkaline environment of concrete makes a passive layer on the surface of reinforcement bars that prevents the bar from corrosion. However, when the chloride concentration amount at the reinforcement bar reaches a certain level, deterioration of the passive protection layer occurs, causing corrosion and ultimately reducing the structure's safety and durability. Therefore, understanding the chloride diffusion and its prediction are important to evaluate the safety and durability of RC structure. In this study, the chloride diffusion coefficient is predicted by machine learning techniques. Various machine learning techniques such as multiple linear regression, decision tree, random forest, support vector machine, artificial neural networks, extreme gradient boosting annd k-nearest neighbor were used and accuracy of there models were compared. In order to evaluate the accuracy, root mean square error (RMSE), mean square error (MSE), mean absolute error (MAE) and coefficient of determination (R2) were used as prediction performance indices. The k-fold cross-validation procedure was used to estimate the performance of machine learning models when making predictions on data not used during training. Grid search was applied to hyperparameter optimization. It has been shown from numerical simulation that ensemble learning methods such as random forest and extreme gradient boosting successfully predicted the chloride diffusion coefficient and artificial neural networks also provided accurate result.

• Nuclear Engineering and Technology
• /
• 제55권9호
• /
• pp.3150-3163
• /
• 2023

To improve the performance of blanket: maximizing the tritium breeding rate (TBR) for tritium self-sufficiency, and minimizing the Dose of backplate for radiation protection, most previous studies are based on manual corrections to adjust the blanket structure to achieve optimization design, but it is difficult to find an optimal structure and tends to be trapped by local optimizations as it involves multiphysics field design, which is also inefficient and time-consuming process. The artificial intelligence (AI) maybe is a potential method for the optimization design of the blanket. So, this paper aims to develop an intelligent optimization method based on an improved multi-objective NSGA-III algorithm and an adaptive BP neural network to solve these problems mentioned above. This method has been applied on optimizing the radial arrangement of a conceptual design of CFETR HCSB blanket. Finally, a series of optimal radial arrangements are obtained under the constraints that the temperature of each component of the blanket does not exceed the limit and the radial length remains unchanged, the efficiency of the blanket optimization design is significantly improved. This study will provide a clue and inspiration for the application of artificial intelligence technology in the optimization design of blanket.