Abstract: A lithium battery cell includes an upper cover module, a first battery electrode group, a second battery electrode group, and a plurality of first electrode connection straps. The first electrode connection straps are stacked together and have the same width and length. A first end of the first electrode connection straps is welded to a first tab, a second end of the first electrode connection straps is welded to a second tab, and a middle part of the first electrode connection straps is welded to a first electrode terminal. An even number of first bending parts are formed between the middle part and the first end, and an even number of second bending parts are formed between the middle part and the second end, and the first bending parts and the second bending parts are symmetrical to each other. Furthermore, a lithium battery cell manufacturing method is also disclosed therein.

Abstract: A method and system for establishing a model for sensing ions in a solution, and a method and system for sensing ions in a solution apply an ion-sensitive field effect transistor in a machine learning model for ion detection in training solutions. The method for establishing a model includes adjusting environmental parameters, where the environmental parameters are selected from any one of multiple target temperatures or from any one of multiple external electric fields; establishing at least one virtual sensor based on the biasing relationship of the multi-gate ion sensitive field effect transistor; obtaining, by the at least one virtual sensor, multiple training features of the training solution based on the environmental parameters and bias parameters; and loading, by a computer, the environmental parameters and the training features into a machine learning model to establish an ion detection model, which is used to sense the types and concentrations of ions.

Abstract: Methods and pad structures to test via accuracy are provided. A method according to the present disclosure includes forming a first pad and a second pad on a device component, wherein the second pad includes a via landing area and a clearance opening, providing a core substrate that includes a cavity, placing the device component in the cavity, forming a build-up film over the device component and the core substrate, forming a first contact via extending through the build-up film to contact the landing area and a second contact via extending through build-up film and the clearance opening, and performing a continuity test to determine whether the second contact via is in contact with the second pad.

Abstract: A lithium battery cell includes an upper cover module, a first battery electrode group, a second battery electrode group, and a plurality of first electrode connection straps. The first electrode connection straps are stacked together. A first end of the first electrode connection straps is welded to a first tab, a second end of the first electrode connection straps is welded to a second tab, and a middle part of the first electrode connection straps is welded to a first electrode terminal. An even number of first bending parts are formed between the middle part and the first end, and an even number of second bending parts are formed between the middle part and the second end, and the first bending parts and the second bending parts are symmetrical to each other. A lithium battery cell manufacturing method is also disclosed therein.

Abstract: A lithium battery cell includes an upper cover module, a first battery electrode group, a second battery electrode group, and a plurality of first electrode connection straps. The first electrode connection straps are stacked together and have the same width and length. A first end of the first electrode connection straps is welded to a first tab, a second end of the first electrode connection straps is welded to a second tab, and a middle part of the first electrode connection straps is welded to a first electrode terminal. An even number of first bending parts are formed between the middle part and the first end, and an even number of second bending parts are formed between the middle part and the second end, and the first bending parts and the second bending parts are symmetrical to each other. Furthermore, a lithium battery cell manufacturing method is also disclosed therein.

Abstract: A method of locating locking holes of an intramedullary nail includes taking an X-ray image of an intramedullary nail having two locking holes; connecting centroids of the locking hole contours and an X-ray source to define locking hole vectors and axial directions of the locking holes; calculating a first included angle and normal vector perpendicular to vectors connecting the X-ray source and the locking hole contour centroids; defining a cross product of the locking hole vector and the normal vector as a vector connecting centers of the locking holes, and calculating second and third included angles with the vector connecting the locking hole centers and the vectors connecting the X-ray source to the locking hole contour centroids; and locating the locking holes according to the first, second and third included angles, vectors connecting the X-ray source to the locking hole contour centroids, and a distance between the locking holes.

Abstract: Methods for treating central nervous system (CNS) disorders or attenuating pain with a lithium benzoate compound.

Abstract: Methods for treating central nervous system (CNS) disorders or attenuating pain with a lithium benzoate compound.

Abstract: A method of locating locking holes of an intramedullary nail includes taking an X-ray image of an intramedullary nail having two locking holes; connecting centroids of the locking hole contours and an X-ray source to define locking hole vectors and axial directions of the locking holes; calculating a first included angle and normal vector perpendicular to vectors connecting the X-ray source and the locking hole contour centroids; defining a cross product of the locking hole vector and the normal vector as a vector connecting centers of the locking holes, and calculating second and third included angles with the vector connecting the locking hole centers and the vectors connecting the X-ray source to the locking hole contour centroids; and locating the locking holes according to the first, second and third included angles, vectors connecting the X-ray source to the locking hole contour centroids, and a distance between the locking holes.