Abstract: A signal processing circuit, complying with DisplayPort standard and operated in a display device which is as a DisplayPort sink device, includes a main physical circuit, which is configured to receive a first signal from one of a plurality of DisplayPort connectors of the display device connected to a first DisplayPort source device and a plurality of auxiliary physical circuits. Only a first auxiliary physical circuit of the plurality of auxiliary physical circuits is enabled to receive a second signal from the DisplayPort connector connected to the first DisplayPort source device.

Abstract: A data processing method and apparatus are provided. The data processing apparatus includes a converter module and a control module. The converter module receives a clock signal through a pin, and decides a bit value of the first data according to a length of a corresponding period of the clock signal. The control module determines whether to perform a bit writing operation for writing the bit value into a memory according to the clock signal and the first data.

Abstract: A data processing method and apparatus are provided. The data processing apparatus includes a converter module and a control module. The converter module receives a clock signal through a pin, and decides a bit value of the first data according to a length of a corresponding period of the clock signal. The control module determines whether to perform a bit writing operation for writing the bit value into a memory according to the clock signal and the first data.

Abstract: An image adjustment method is disclosed. The steps of the method include: receiving an image data having a plurality of original pixels, the number of the original pixels is equal to Num1, and 2N?1?Num1?2N?1, wherein N and Num1 are natural numbers; adding a plurality of expanding pixels to the image data, such that a sum of the original pixels and the expanding pixels is equal to 2N?1; calculating a plurality of cumulative pixel numbers corresponding to a plurality of gray levels, wherein each of the cumulative pixel numbers is not larger than the number of the original pixels and the expanding pixels corresponding to each of the gray levels; and tuning the gray levels of the original pixels according to the corresponding relationship between the gray levels and the cumulative pixel numbers.

Abstract: The present direct cardiac compression (DCC) design, termed Cardiac Resynchronization Compression Sac System (CRCSS), combines the mechanical and electrical characteristics associated with DCC and cardiac resynchronization therapy (CRT), respectively. The CRCSS comprises a shell, at least one opening on the shell, at least one inflatable balloon, and a pumping system. The shell is custom manufactured to substantially conform to the contour of a portion of a heart, the contour being obtained by an imaging system. The opening on the shell is designed for passing pericardial fluid so as not to impede the myocardial contraction. The inflatable balloon attaches to at least one predetermined location of the inner surface of the shell. Furthermore, the shell naturally positions in the pericardium space without resorting to any artificial force to prevent it from dislodging from the heart. When the inflatable balloon inflates at least one ventricular free wall of the heart is compressed.

Abstract: A manifold for accessing blood from a human blood vessel is disclosed which comprises a first and a second pathway intersecting with each other at an angle, the first pathway being configured to be completed embedded in the human blood vessel with the second pathway leading toward outside of the human blood vessel wherein the manifold is substantially retained by the human blood vessel alone.

Abstract: A ventricular assist device is disclosed which comprises a sac for wrapping around a portion of a heart, the sac having one or more inflatable chambers for compressing the heart when the chambers being inflated and a blood outlet made to an aorta, the blood outlet being the sole opening in the human blood path in the vicinity of heart, wherein during a systolic phase the inflatable chambers inflate while blood flows out of the aorta through the blood outlet, and during a diastolic phase the inflatable chambers deflate while blood flows into the aorta through the blood outlet.

Abstract: An image adjustment method is disclosed. The steps of the method include: receiving an image data having a plurality of original pixels, the number of the original pixels is equal to Num1, and 2N?1?Num1?2N?1, wherein N and Num1 are natural numbers; adding a plurality of expanding pixels to the image data, such that a sum of the original pixels and the expanding pixels is equal to 2N?1; calculating a plurality of cumulative pixel numbers corresponding to a plurality of gray levels, wherein each of the cumulative pixel numbers is not larger than the number of the original pixels and the expanding pixels corresponding to each of the gray levels; and tuning the gray levels of the original pixels according to the corresponding relationship between the gray levels and the cumulative pixel numbers.

Abstract: A ventricular assist device is disclosed which comprises a sac for wrapping around a portion of a heart, the sac having one or more inflatable chambers for compressing the heart when the chambers being inflated and a blood outlet made to an aorta, the blood outlet being the sole opening in the human blood path in the vicinity of heart, wherein during a systolic phase the inflatable chambers inflate while blood flows out of the aorta through the blood outlet, and during a diastolic phase the inflatable chambers deflate while blood flows into the aorta through the blood outlet.

Abstract: The present direct cardiac compression (DCC) design, termed Cardiac Resynchronization Compression Sac System (CRCSS), combines together the mechanical and electrical characteristics associated with DCC and cardiac resynchronization therapy (CRT), respectively. The CRCSS comprises a shell, at least one opening on the shell, and at least one inflatable balloon, and a pumping system. The shell is custom manufactured to substantially conform to the contour of a portion of a heart, the contour of the heart being obtained by an imaging system. The opening on the shell is designed for passing pericardial fluid so as not to impede the myocardial contraction. The inflatable balloon attaches to at least one predetermined location of the inner surface of the shell. Furthermore, the shell naturally positions in the pericardium space without resorting to any artificial force to prevent it from dislodging from the heart, and when the inflatable balloon inflates at least one ventricular free wall of the heart is compressed.

Abstract: A manifold for accessing blood from a human blood vessel is disclosed which comprises a first and a second pathway intersecting with each other at an angle, the first pathway being configured to be completed embedded in the human blood vessel with the second pathway leading toward outside of the human blood vessel wherein the manifold is substantially retained by the human blood vessel alone.

Abstract: A ventricular assist device is disclosed which comprises a sac for wrapping around a portion of a heart, the sac having one or more inflatable chambers for compressing the heart when the chambers being inflated and a blood outlet made to an aorta, the blood outlet being the sole opening in the human blood path in the vicinity of heart, wherein during a systolic phase the inflatable chambers inflate while blood flows out of the aorta through the blood outlet, and during a diastolic phase the inflatable chambers deflate while blood flows into the aorta through the blood outlet.

Abstract: A method of fabricating barium titanate powders uses titanium tetrachloride and barium hydroxide as reactants in a reaction solution. The pH value of the reaction solution is adjusted to strongly alkaline range by adding potassium hydroxide. Nitrogen is charged into a reaction tank at normal pressure, and the reaction solution is heated at 80–102°. The solution is intensively stirred at constant temperature, and then subjected to a hydro-thermal reflux. Then, the solution is treated through an ion exchange resin and dried to obtain a cubic BaTiO3 powders.

Abstract: A method of fabricating barium titanate powders uses titanium tetrachloride and barrium hydroxide as reactants in a reaction solution. The pH value of the reaction solution is adjusted to strongly alkaline range by adding potassium hydroxide. Nitrogen is charged into a reaction tank at normal pressure, and the reaction solution is heated at 80-102° C. The solution is intensively stirred at constant temperature, and then subjected to a hydro-thermal reflux. Then, the solution is treated through an ion exchange resin and dried to obtain a cubic BaTiO3 powders.