Abstract: Embodiments are disclosed for a method. The method includes generating a correction datastore indicating shifts in magnitude representing corresponding characters that uniquely identify hardware comprising a computer processing chip. The method further includes generating security masks based on a correction file. Additionally, the method includes using a correction process for the computer processing chip. The generated security masks include corresponding overlays representing the shifts in magnitude with respect to corresponding product masks for the computer processing chip. The method also includes generating the computer processing chip using the security masks and the product masks.

Abstract: Described is a semiconductor processing system including a measurement tool configured to measure warpage characteristics in a semiconductor wafer. The semiconductor processing system further includes a pixelated surface configured to retain the semiconductor wafer, where the pixelated surface approximates the warpage characteristics to conform to the semiconductor wafer. The semiconductor processing system further includes a semiconductor processing tool configured to perform processing on the semiconductor wafer while it is retained on the pixelated surface.

Abstract: Embodiments are disclosed for a method. The method includes generating a correction datastore indicating shifts in magnitude representing corresponding characters that uniquely identify hardware comprising a computer processing chip. The method further includes generating security masks based on a correction file. Additionally, the method includes using a correction process for the computer processing chip. The generated security masks include corresponding overlays representing the shifts in magnitude with respect to corresponding product masks for the computer processing chip. The method also includes generating the computer processing chip using the security masks and the product masks.

Abstract: In an approach, a processor receives device identification information corresponding to at least one device local to a location of a transaction. A processor receives notification of an infected user. A processor determines that the infected user is associated with the transaction. A processor identifies a second user from the device identification information. A processor sends a notification to the second user.

Abstract: Systems and methods for operating a DMA unit with address alignment are disclosed. These may include configuring a bandwidth control setting for a read job that includes a data transfer size corresponding to a first number of bytes. A second number of bytes to reach a read address alignment is determined. In a first data transfer, a third number of bytes substantially equal to the first number of bytes plus the second number of bytes are transferred. In subsequent data transfers of the read job, the first number of bytes are transferred to the data buffer. After the third number of bytes are transferred to the data buffer, a fourth number of bytes from the data buffer are transferred to a destination.

Abstract: Systems and methods for operating a DMA unit with address alignment are disclosed. These may include configuring a bandwidth control setting for a read job that includes a data transfer size corresponding to a first number of bytes. A second number of bytes to reach a read address alignment is determined. In a first data transfer, a third number of bytes substantially equal to the first number of bytes plus the second number of bytes are transferred. In subsequent data transfers of the read job, the first number of bytes are transferred to the data buffer. After the third number of bytes are transferred to the data buffer, a fourth number of bytes from the data buffer are transferred to a destination.

Abstract: Method, systems and arrangements are provided for creating a high-resolution magnetic resonance image (“MRI”) or obtaining other information of a target, such as a cardiac region of a patient. Radio-frequency (“RF”) pulses can be transmitted toward the target by, e.g., an RF transmitter of an MRI apparatus. In response, multiple echoes corresponding to the plurality of pulses may be received from the target. Data from each of the echoes can be assigned to a single line of k-space, and stored in memory of the apparatus. An image of the target, acceleration data and/or velocity data associated with a target can be generated as a function of the data. In one exemplary embodiment, the data from different echoes may be assigned to the same k-space line, and to different cardiac phases. In one further embodiment, parallel processing may be used to improve the resolution of the image acquired during a single breath-hold duration.