• Journal of Internet Computing and Services
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• v.16 no.2
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• pp.109-115
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• 2015

The new medical device technologies for bio-signal information and medical information which developed in various forms have been increasing. Information gathering techniques and the increasing of the bio-signal information device are being used as the main information of the medical service in everyday life. Hence, there is increasing in utilization of the various bio-signals, but it has a problem that does not account for security reasons. Furthermore, the medical image information and bio-signal of the patient in medical field is generated by the individual device, that make the situation cannot be managed and integrated. In order to solve that problem, in this paper we integrated the QR code signal associated with the medial image information including the finding of the doctor and the bio-signal information. bio-signal. System implementation environment for medical imaging devices and bio-signal acquisition was configured through bio-signal measurement, smart device and PC. For the ROI extraction of bio-signal and the receiving of image information that transfer from the medical equipment or bio-signal measurement, .NET Framework was used to operate the QR server module on Window Server 2008 operating system. The main function of the QR server module is to parse the DICOM file generated from the medical imaging device and extract the identified ROI information to store and manage in the database. Additionally, EMR, patient health information such as OCS, extracted ROI information needed for basic information and emergency situation is managed by QR code. QR code and ROI management and the bio-signal information file also store and manage depending on the size of receiving the bio-singnal information case with a PID (patient identification) to be used by the bio-signal device. If the receiving of information is not less than the maximum size to be converted into a QR code, the QR code and the URL information can access the bio-signal information through the server. Likewise, .Net Framework is installed to provide the information in the form of the QR code, so the client can check and find the relevant information through PC and android-based smart device. Finally, the existing medical imaging information, bio-signal information and the health information of the patient are integrated over the result of executing the application service in order to provide a medical information service which is suitable in medical field.

• Journal of the Korea Institute of Information Security & Cryptology
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• v.29 no.5
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• pp.949-960
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• 2019

Due to miniaturization of electronic devices and development of IoT(Internet of Things), embedded system have been used in various field. Meanwhile, there is a potential vulnerability by the insufficient of system's security. In this paper, we implement secure boot using TPM to protect the integrity of embedded system environment. The Suggestion considers the required availability in the embedded system and detects the system's tampering at secure boot process via TPM. In addition, we have reinforced the confidentiality through AES encryption of the kernel at secure boot.

• Journal of the Korea Society of Computer and Information
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• v.27 no.7
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• pp.57-64
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• 2022

In this paper, the definition and overview of digital health care that has emerged recently, core technology, and We would like to propose a plan to establish a next-generation information protection system that can protect digital healthcare devices and data from cyber attacks. Various vulnerabilities exist for digital healthcare devices and data, and cyber attacks are possible for those vulnerabilities. Through an attack on digital health care devices and information and communication networks, it can directly adversely affect human life and health, Since digital healthcare data contains sensitive and personal information, it is essential to safely protect it from cyber attacks. In the case of this proposal, for continuous safe management of data and cyber attacks on equipment and communication networks for digital health devices, It is expected to be able to respond more effectively and continuously through the establishment of the next-generation information protection system.

• Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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• 2015.05a
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• pp.876-879
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• 2015

Inernet of Things(IoT) is a network to be interconnected with things anytime, anywhere. This means interaction with each other, collecting, sharing, and analysing the data. IoT also offers a new paradigm shift in industry. In particular, the combining with the fields of health care services has been noted. The convergence of IoT technology and health care is expected to be the innovation paradigm in the healthcare industry that includes all of the changes to bring the mobile health and wearable health care devices. This study analyzes IoT, health care status, and the use cases of the IoT in the medical field, finally analyses security on the Internet of Things, the most important issues of security challenges while still in medical services.

• Information and Communications Magazine
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• v.29 no.10
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• pp.66-73
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• 2012

전 세계적으로 노령인구가 급격히 증가하면서 만성질환자도 급증하고 있는 추세이다. 또한, 고도화된 현대사회와 과도한 업무, 서양화된 식습관, 그리고 운동부족은 젊은 층에서의 성인병 및 만성질환 증가를 부추기고 있다. 만성질환의 증가는 의료비 증가로 이어지고 결국은 국가재정 부담으로 돌아가게 된다. 만성질환자의 대부분은 지속적인 생체정보 측정과 이를 통한 관리가 필수적인데 매번 병원을 방문해 관리하는 것은 현실적으로나 비용적인 측면으로나 무리가 있는 것이 사실이다. 이러한 문제를 해결하고 언제 어디서나 시간과 공간에 구애받지 않고 생체정보를 원격에서 측정하고 관리 받을 수 있도록 하는 것이 U-헬스케어 서비스이다. U-헬스케어 서비스는 전통적인 의료 서비스에 정보통신 기술을 접목한 형태로 고령인구 및 만성질환자의 지속적인 관리를 위해 현재 주목 받고 있는 기술이다. U-헬스케어 서비스의 가장 중요하면서도 기본적인 요소는 원격지 사용자의 생체정보를 측정하고 수집할 수 있는 원격 생체정보 모니터링 기술이다. 이를 위해서는 다양한 종류의 생체정보 측정기기가 필요한데 장비나 시스템 간 통신 인터페이스의 상호 호환성이 매우 중요하다. 본 논문에서는 원격 생체정보 모니터링을 위한 표준 기술인 IEEE 11073 PHD를 소개하고 현재 IEEE 11073 PHD 표준에서 명시하고 있지 않은 보안 문제점과 필요 기술들을 분석하고자 한다. 또한, IEEE 11073 PHD에서 IEEE 11073-20601 표준 프로토콜을 이용한 사용자 인증 구조를 제안한다.

• Proceedings of the Korea Information Processing Society Conference
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• 2012.04a
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• pp.738-741
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• 2012

한국정보통신기술협회(TTA)에서 표준 제안한 WBAN(Wireless Body Area Network)은 인체 내부 통신(in-body or implant)과, 인체 외부 통신(on-body)통신으로 구분하고 있다. 생체측정 정보 중 체온, 호흡, 맥박, 운동량, 심박의 부분적인 데이터 수집을 바탕으로 환자의 생체정보 데이터를 수합 후 데이터 프레임구조로 변환하여 스마트모바일 애플리케이션 환경에서 사용자가 모바일기기 화면에 정보를 표시 할 수 있다. 이렇게 표시된 정보들은 환자의 상태를 실시간으로 자신의 스마트모바일을 이용하여 확인할 수 있으며, 이러한 정보를 보호하고 의료기관에 전송하기 위한 방법으로 국제표준암호알고리즘인 HIGHT 알고리즘을 적용하여 생체정보 데이터의 부분 암호화 적용을 설계 하였다. 이를 통해 의료기관의 인증서버에 대한 부하 감소 및 환자의 생체정보의 보안 강화를 제시한다.

• Information and Communications Magazine
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• v.31 no.8
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• pp.45-53
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• 2014

센싱 (Sensing), 엑츄에이팅 (Actuating), 제어 (Control) 및 네트워킹 (Networking) 기술의 급격한 발달로 기계, 전자장비, 사회 기반시설, 에너지 공급 및 소비시설, 의료기기, 자동차 등과 같은 물리 세계를 구성하는 다양한 개체들간의 긴밀한 융합이 가능하게 되었다. 다양한 센서를 통하여 물리 개체들로부터 필요한 정보를 수집, 분석하고 가공된 정보를 다양한 컨트롤러, 엑츄에어터 등과 공유함으로써 기존의 개별 전자기기를 위한 센싱 엑츄에이팅 기반 임베디드 시스템과는 근본적으로 차별화되는 복잡한 시스템 위의 시스템 (Systems of Systems) 기술이 제안되어 개발되고 있다. 이렇게 사이버 세계 정보처리 기능과 물리 세계가 서로 긴밀하게 응답하고, 협력하는 인지형 컨트롤 시스템을 사이버물리시스템 (Cyber-Physical Systems, CPS)이라 부른다. 사이버 물리시스템은 대부분의 정보처리, 제어 컴퓨팅 분야에 적용되어 효율성, 안전성, 보안성 향상에 획기적인 기여를 할 것으로 기대된다. 특히, 지능화된 사이버 정보수집 및 최적 제어 기술을 기반으로 도시의 지능형 교통 제어, 건물그룹의 에너지 소비분석과 최적제어, 스마트 스페이스 서비스 등 다양한 분야에 적용되어 스마트 시티 (Smart City)라는 새로운 지능형 통합 시스템을 구현하고 현실화 하는데 핵심 기능을 담당할 것으로 기대된다. 본고에서는 사이버물리시스템의 전반적인 소개와 함께, 스마트 시티를 현실화하는데 사용될 핵심 기술 분야를 소개하고, 스마트 시티 시스템에서 사이버물리시스템이 어떤 역할을 하는지에 대해, 핵심기술들이 적용되는 도시 내 대상 공간의 규모별로 구분하여 기술한다.

• The Optical Journal
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• s.141
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• pp.21-23
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• 2012

신종플루의 전 세계적 유행과 함께 적외선 광학계는 일반인에게 익숙한 기술이 되었다. 스웨덴에서 최초로 개발된 적외선 카메라는 현재 군수용뿐만 아니라 보안, 의료, 차량, 재난구조 등 다양한 분야에 적용되고 있다. 이런 민간분야 시장 성장에는 핵심부품인 적외선 렌즈와 IR Detecter의 가격 인하가 가장 큰 역할을 하고 있다. 특히 차량용 적외선 카메라의 채용은 관련시장을 폭발적으로 성장시킬 가능성을 인정받고 있으며 이런 흐름은 다시 관련 분야의 가격 인하요인으로 강력히 작용하고 있다. 아래표의 적외선 광학계의 수요 산업군 메가 트렌드(<적외선 수요 산업군> 표)는 자동차, 플랜트, 보안, 소방방재, 방위산업 등 다양한 분야의 적외선 광학관련 수요를 포함하고 있어 향후 주요 산업군으로 부각될 것으로 예상된다. 특히 저가양산이 가능해 다양하게 주목받고 있는 성형방식 적외선 광학렌즈 관련 주요 해외 선진업체의 기술수준은 적외선 원천소재를 제외하고는 국내에도 이미 세계수준의 기술을 보유하고 있으며, IR Detector 관련 기술 역시 냉각식 및 비냉각식 분야에서 세계최고 수준의 원천기술을 보유 중이어서 국내 업체의 양산화 기술이 완성되면 관련 세계 시장 선점이 가능하며 향후 5년이 이를 결정짓는 중요한 시점이 될 것이다.

• Journal of Digital Convergence
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• v.18 no.4
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• pp.325-340
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• 2020

Today's rapidly developing health technology is accumulating vast amounts of data through medical devices based on the Internet of Things in addition to data generated in hospitals. The collected data is a raw material that can create a variety of values, but our society lacks legal and institutional mechanisms to support medical Big Data. Therefore, in this study, we looked at four major factors that hinder the use of medical Big Data to find ways to enhance use of the Big Data based healthcare industry, and also derived implications for expanding domestic medical Big Data by identifying foreign policies and technological trends. As a result of the study, it was concluded that it is necessary to improve the regulatory system that satisfies the security and usability of healthcare Big Data as well as establish Big Data governance. For this, it is proposed to refer to the Big Data De-identification Guidelines adopted by the United States and the United Kingdom to reorganize the regulatory system. In the future, it is expected that it will be necessary to have a study that has measures of the conclusions and implications of this study and to supplement the institutional needs to play a positive role in the use of medical Big Data.

• Journal of Internet Computing and Services
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• v.16 no.1
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• pp.47-55
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• 2015

Recently, the environment of a hospital information system is a trend to combine various SMART technologies. Accordingly, various smart devices, such as a smart phone, Tablet PC is utilized in the medical information system. Also, these environments consist of various applications executing on heterogeneous sensors, devices, systems and networks. In these hospital information system environment, applying a security service by traditional access control method cause a problems. Most of the existing security system uses the access control list structure. It is only permitted access defined by an access control matrix such as client name, service object method name. The major problem with the static approach cannot quickly adapt to changed situations. Hence, we needs to new security mechanisms which provides more flexible and can be easily adapted to various environments with very different security requirements. In addition, for addressing the changing of service medical treatment of the patient, the researching is needed. In this paper, we suggest a dynamic approach to medical information systems in smart mobile environments. We focus on how to access medical information systems according to dynamic access control methods based on the existence of the hospital's information system environments. The physical environments consist of a mobile x-ray imaging devices, dedicated mobile/general smart devices, PACS, EMR server and authorization server. The software environment was developed based on the .Net Framework for synchronization and monitoring services based on mobile X-ray imaging equipment Windows7 OS. And dedicated a smart device application, we implemented a dynamic access services through JSP and Java SDK is based on the Android OS. PACS and mobile X-ray image devices in hospital, medical information between the dedicated smart devices are based on the DICOM medical image standard information. In addition, EMR information is based on H7. In order to providing dynamic access control service, we classify the context of the patients according to conditions of bio-information such as oxygen saturation, heart rate, BP and body temperature etc. It shows event trace diagrams which divided into two parts like general situation, emergency situation. And, we designed the dynamic approach of the medical care information by authentication method. The authentication Information are contained ID/PWD, the roles, position and working hours, emergency certification codes for emergency patients. General situations of dynamic access control method may have access to medical information by the value of the authentication information. In the case of an emergency, was to have access to medical information by an emergency code, without the authentication information. And, we constructed the medical information integration database scheme that is consist medical information, patient, medical staff and medical image information according to medical information standards.y Finally, we show the usefulness of the dynamic access application service based on the smart devices for execution results of the proposed system according to patient contexts such as general and emergency situation. Especially, the proposed systems are providing effective medical information services with smart devices in emergency situation by dynamic access control methods. As results, we expect the proposed systems to be useful for u-hospital information systems and services.