Abstract: The present disclosure provides an electronic wearable device. The electronic wearable device includes a first module having a first contact and a second module having a second contact. The first contact is configured to keep electrical connection with the second contact in moving with respect to each other during a wearing period.

Abstract: A method for obtaining the binding kinetic rate constants using fiber optic particle plasmon resonance (FOPPR) sensor, suitable for a test solution with two or more concentrations, which employs the following major steps: providing one FOPPR sensor instrument system, obtaining optical time-resolved signal intensities starting at the initial time to the steady state of the two or more regions, substituting the measured signal intensity values into the formula which is derived by using the pseudo-first order rate equation model. In addition, this method measures the temporal signal intensity evolution under static conditions as the samples are quickly loaded. As a result, unlike the conventional device where the sample is continuously infused, the method is able to measure the association and dissociation rate constants of which the upper bounds are not limited by the sample flow rate.

Abstract: The present invention relates to a method for splitting circles, and the method is mainly applied to a wafer of semiconductors. A plurality of splitting blades are disposed above the wafer, and conditions and steps are set for switching the plurality of splitting blades based on a safe distance value set at an outer edge of a wafer or a safe distance value set at an inner edge of a metal ring. Accordingly, the plurality of splitting blades are prevented from cutting an outer frame during splitting and failing to complete actions of splitting wafers. The method has an advantage of efficiency of enhancing a production capacity yield rate.

Abstract: The present invention relates to a laser beam splitting and angle adjusting device. The device comprises a design of a multibeam module disposed between a plurality of laser units and a refractor to allow light beams emitted out from the plurality of laser units being modulated by the multibeam module so as to perform scan photolithography on photomask patterns. Different cutting purposes can be achieved through adjusting an arrangement of light beams in order to accomplish effects including deepening depths of cutting, and adjusting or controlling a size of groove widths of groove cutting, and so on.

Abstract: The present invention relates to a laser cutting method and apparatus thereof. The method comprises the following steps of fixing a substrate to be cut on a base, processing a first alignment procedure via an image sensor, forming a first cutting channel on a first surface of the substrate by cutting the first surface via laser beams, flipping over the substrate to be cut and fixing the substrate on the base, processing a second alignment procedure via the image sensor, and forming a second cutting channel on a second surface of the substrate by cutting the second surface via laser beams. The method can achieve improvement to laser cutting quality and effectiveness of enhancing production.

Abstract: The present invention relates to an improved laser structure comprising a laser generation module and an optical component. The laser generation module outputs laser beams to the optical component. A composite substrate to be cut comprises at least two board layers of different materials, and an upper surface of each of the at least two board layers is a cutting starting point of the each of the at least two board layers. The optical component is used to transform the laser beams to laser beams having at least two focal depths so as to be respectively focused on the upper surface of the each of the at least two board layers mentioned above, and to achieve effect of enhancing cutting efficiency of the composite substrate.

Abstract: A method for obtaining the binding kinetic rate constants using fiber optic particle plasmon resonance (FOPPR) sensor, suitable for a test solution with two or more concentrations, which employs the following major steps: providing one FOPPR sensor instrument system, obtaining optical time-resolved signal intensities starting at the initial time to the steady state of the two or more regions, substituting the measured signal intensity values into the formula which is derived by using the pseudo-first order rate equation model. In addition, this method measures the temporal signal intensity evolution under static conditions as the samples are quickly loaded. As a result, unlike the conventional device where the sample is continuously infused, the method is able to measure the association and dissociation rate constants of which the upper bounds are not limited by the sample flow rate.

Abstract: A method for estimating binding kinetic rate constants by using a fiber optic particle plasmon resonance (FOPPR) sensor mainly employs the steps of: providing a FOPPR sensor instrument system, obtaining optical signal intensities at an initial time and steady state signal intensities of first and second regions in an intensity versus time graph separately, substituting the measured signal intensity values into a formula derived by using a pseudo-first order rate equation model. According to this method, no fluorophore labeling is required. In addition, this method measures a temporal signal intensity evolution under static conditions as the samples are quickly loaded. As a result, unlike the conventional device where the sample is continuously infused, the method is able to measure binding and decomposition rate constants whose upper limit is not limited by a sample flow rate.

Abstract: An IPSec tunnel is established by assigning parameters TS and SPI being translated into TFT (PF I, PF II). A first index is assigned. A GTP tunnel is established based on TFT (PF I, PF II) and the first index. GGSN generates a table based on TFT (PF I, PF II) and the first index, for UE in WLAN network to access 3G services. UE assigns a second index when roaming into the 3G network. A tunnel between SGSN and UE is established based on TFT (PF I, PF II) and the second index. Another tunnel between the SGSN and the GGSN is established based on TFT (PF I, PF II) and the second index. GGSN searches for the table with the first index based on SPI in the TFT (PF II), for reusing the table for not interrupting 3G services provided to the UE in the 3G network.

Abstract: A disk drive includes a gear transmission system disposed within a casing. The gear transmission system includes first and second gears, a driven plate having a first serrated portion meshed with the first gear, a second serrated portion facing a third gear, and first and second guiding slots. A lifting frame has two couplers slidably engaging with the slots in the driven plate. Rotation of the third gear alternately in opposite directions results in movement of the driven plate in right and left sides of the casing, which, in turn, results in lifting of the frame to an upper reading position, in which, a resilient pushing arm of the lifting frame abuts against the driven plate to provide resilience between the second serrated portion and the third gear.

Abstract: An IPSec tunnel is established by assigning parameters TS and SPI being translated into TFT (PF I, PF II). A first index is assigned. A GTP tunnel is established based on TFT (PF I, PF II) and the first index. GGSN generates a table based on TFT (PF I, PF II) and the first index, for UE in WLAN network to access 3G services. UE assigns a second index when roaming into the 3G network. A tunnel between SGSN and UE is established based on TFT (PF I, PF II) and the second index. Another tunnel between the SGSN and the GGSN is established based on TFT (PF I, PF II) and the second index. GGSN searches for the table with the first index based on SPI in the TFT (PF II), for reusing the table for not interrupting 3G services provided to the UE in the 3G network.

Abstract: A disk drive includes a gear transmission system disposed within a casing. The gear transmission system includes first and second gears, a driven plate having a first serrated portion meshed with the first gear, a second serrated portion facing a third gear, and first and second guiding slots. A lifting frame has two couplers slidably engaging with the slots in the driven plate. Rotation of the third gear alternately in opposite directions results in movement of the driven plate in right and left sides of the casing, which, in turn, results in lifting of the frame to an upper reading position, in which, a resilient pushing arm of the lifting frame abuts against the driven plate to provide resilience between the second serrated portion and the third gear.