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        검색결과 3

        1.
        2017.09 KCI 등재 구독 인증기관 무료, 개인회원 유료
        Process capability is well known in quality control literatures. Process capability refers to the uniformity of the process. Obviously, the variability in the process is a measure of the uniformity of output. It is customary to take the 6-sigma spread in the distribution of the product quality characteristic as a measure of process capability. However there is no reference of process capability when maximum material condition is applied to datum and position tolerance in GD&T (Geometric Dimensioning and Tolerancing). If there is no material condition in datum and position tolerance, process capability can be calculated as usual. If there is a material condition in a feature control frame, bonus tolerance is permissible. Bonus tolerance is an additional tolerance for a geometric control. Whenever a geometric tolerance is applied to a feature of size, and it contains an maximum material condition (or least material condition) modifier in the tolerance portion of the feature control frame, a bonus tolerance is permissible. When the maximum material condition modifier is used in the tolerance portion of the feature control frame, it means that the stated tolerance applies when the feature of size is at its maximum material condition. When actual mating size of the feature of size departs from maximum material condition (towards least material condition), an increase in the stated tolerance-equal to the amount of the departure-is permitted. This increase, or extra tolerance, is called the bonus tolerance. Another type of bonus tolerance is datum shift. Datum shift is similar to bonus tolerance. Like bonus tolerance, datum shift is an additional tolerance that is available under certain conditions. Therefore we try to propose how to calculate process capability index of position tolerance when maximum material condition is applied to datum and position tolerance.
        4,000원
        2.
        1996.01 KCI 등재 구독 인증기관 무료, 개인회원 유료
        본 연구는 Bessel 측지계에서 WGS-84 측지계로 좌표변환할 경우 발생할 수 있는 우리나라 지형정보의 변동을 고찰한 것이다. 고찰 대상은 우리나라 지형형태와 독도와 일본의 오끼제도 사이의 거리로 하였다. Bessel 측지계에서 WGS-84 측지계로 좌표변환한 결과는 다음과 같다. 1). Mercator 도법에서, 임의로 선정한 정사각형의 우리나라 주변 지형은 고위도에서 축소되면서 부채꼴 모양으로 변형되는 결과를 나타내었다. 2). UTM 도법에서, 우리나라 남동부근 연안의 52S 지역중에서 임의로 선정한 정사각형 지형은 가로가 2m 축소되고, 세로는 1m 축소되었다. 3). Mercator 도법을 이용한 한국의 독도와 일본의 오끼제도 사이의 거리를 비교한 결과 오끼제도가 독도쪽으로 약 25.3m 근접하게 되는 결과를 나타내었다.
        4,900원
        3.
        1995.07 KCI 등재 구독 인증기관 무료, 개인회원 유료
        There are numerous mapping, charting, geodetic systems and electronic digital products defined in various local geodetic datum. It becomes a straight forward requirement to simplify the complexity by referencing all the products to a common reference globally. WGS-84 is well known as a state-of-the-art global reference system based on the use of data, techniques and technology available within American Defence Mapping Agency(DMA). Its parameters can be translated into more accurate maps, charts and geodetic positioning compared to others previously. Since Global Positioning System(GPS/NAVSTAR), which is asssociated with World Geodetic System(WGS-84)in reference frame, has been widely used, the unified geodetic system has been required for GPS users in many fields.
        4,600원