Abstract: A movement management device specifies, when a data center includes separated areas of a first area in which a server rack is installed and a second area in which a worker works, a worker who enters the second area. The movement management device specifies a target server rack to be operated by the specified worker from among a plurality of server racks installed in the first area. The movement management device moves the specified target server rack from the first area to the second area that the worker enters.
Abstract: A control server controls an operator who provides an operational service on an operating system based on export control regulations. The control server stores therein operator information related to the operator and control information including a determination date that is a date when provision of the operational service is determined to comply with the export control regulations. The control server selects an operator who does not fall under the export control regulations, out of the operators, as an operator who provides the operational service, based on the control information and an effective date that is a date when the latest export control regulations become effective.
Abstract: The invention offers a calculation method and program capable of performing line-by-line calculations using a Voigt function at speeds of 50-100 times what is conventional. The Voigt function is divided into a first range around the peak and a skirt portion not contained in the first range. The first range is replaced by a cubic function, and the skirt portion is taken as the Voigt function to perform calculations in predetermined ranges of equal intervals. Furthermore, the peak area of the first range is replaced by a cubic function, and the skirt portion is taken as a function representing the difference between the Voigt function and the cubic function to perform calculations in second predetermined intervals smaller than the aforementioned first predetermined intervals. This is repeated until the desired level of precision is reached. Additionally, interpolation is performed by dividing these predetermined intervals into four or five parts.
Abstract: The object of the present invention can be achieved by the data verification supporting server for supporting verification of data which is inputted to each item of a survey form for surveying an effect of implementing a product, including a survey form managing part managing the survey form sent from an implementer terminal of an implementer, with a revised number of the survey form; a re-survey information managing part informing the implementer of a re-survey inquiry based on a re-survey inquiry request for requesting a re-survey, which is received from a verifier terminal of a verifier verifying the survey form, the re-survey inquiry request indicating the implementer who sent the survey form; and a survey form maintaining part maintaining the survey form and the version information managed by the survey form managing part when notification of a verification completion of the survey form is received from the verifier terminal.
Abstract: The present invention relates to a distribution aiding system, a distribution aiding server, a distribution aiding method, and a distribution aiding program capable of selling articles without individual trading conditions being known to a maker, other users or other dealers, and is so configurated that a user retrieves or selects a necessary article, the user registers order information according to the selected article, and a dealer in charge of the user registers order-acceptance condition information to be added to the order information, and notifies the user of the order-acceptance condition information.
Type:
Grant
Filed:
May 10, 2001
Date of Patent:
February 16, 2010
Assignees:
Wako Pure Chemical Industries, Ltd., Fujitsu FIP Corporation
Abstract: The invention offers a calculation method and program capable of performing line-by-line calculations using a Voigt function at speeds of 50-100 times what is conventional. The Voigt function is divided into a first range around the peak and a skirt portion not contained in the first range. The first range is replaced by a cubic function, and the skirt portion is taken as the Voigt function to perform calculations in predetermined ranges of equal intervals. Furthermore, the peak area of the first range is replaced by a cubic function, and the skirt portion is taken as a function representing the difference between the Voigt function and the cubic function to perform calculations in second predetermined intervals smaller than the aforementioned first predetermined intervals. This is repeated until the desired level of precision is reached. Additionally, interpolation is performed by dividing these predetermined intervals into four or five parts.