ABSTRACT
INTRODUCTION: To eradicate uterine cervix cancer, we report LOVE49 activity in Gunma prefecture and considered activities to be focused on in the future.METHODS: Activities included the creation of original goods and "Gunma-chan" costume, broadcast by local FM radio, plans for distribution, and distribution among college students.RESULTS: Original goods were distributed more efficiently to young women than in previous years. These activities led to an increased number of goods distributed, shortening of the time for distribution and reducing the burden on members.CONCLUSION: It is important that women themselves obtain correct knowledge and information to continuously improve the check-up rate. Health education for young people in particular is important.
ABSTRACT
The maneuvering and electrical characterization of nanotubes inside a scanning electron microscope (SEM) has historically been time-consuming and laborious for operators. Before the development of automated nanomanipulation-enabled techniques for the performance of pick-and-place and characterization of nanoobjects, these functions were still incomplete and largely operated manually. In this paper, a dual-probe nanomanipulation system vision-based feedback was demonstrated to automatically perform 3D nanomanipulation tasks, to investigate the electrical characterization of nanotubes. The XY-position of Atomic Force Microscope (AFM) cantilevers and individual carbon nanotubes (CNTs) were precisely recognized via a series of image processing operations. A coarse-to-fine positioning strategy in the Z-direction was applied through the combination of the sharpness-based depth estimation method and the contact-detection method. The use of nanorobotic magnification-regulated speed aided in improving working efficiency and reliability. Additionally, we proposed automated alignment of manipulator axes by visual tracking the movement trajectory of the end effector. The experimental results indicate the system's capability for automated measurement electrical characterization of CNTs. Furthermore, the automated nanomanipulation system has the potential to be extended to other nanomanipulation tasks.
