Abstract: Systems and methods for forensic resolution of ransomware attacks are provided. The systems and methods define a platform and functionality for addressing ransom based attacks. According to one aspect, the platform and functionality provides a suite of programs and services that enable verification of “ransomed” files to ensure that they can in fact be recovered. If an attack has compromised the integrity of the underlying data so that it cannot be recovered, paying the ransom is an exercise in futility. Additional aspects provide for rapid collection of data that is targeted and specific and that further enables efficient forensic analysis. Many conventional approaches in this space fail to capture requisite detail and/or fail to provide a methodology for handling the volumes of data required to efficiently and effectively track or resolve such attacks. Further aspects provide actionable intelligence that drives result oriented goals for ransomed data and/or compromised systems.

Abstract: Systems and methods for forensic resolution of ransomware attacks are provided. The systems and methods define a platform and functionality for addressing ransom based attacks. According to one aspect, the platform and functionality provides a suite of programs and services that enable verification of “ransomed” files to ensure that they can in fact be recovered. If an attack has compromised the integrity of the underlying data so that it cannot be recovered, paying the ransom is an exercise in futility. Additional aspects provide for rapid collection of data that is targeted and specific and that further enables efficient forensic analysis. Many conventional approaches in this space fail to capture requisite detail and/or fail to provide a methodology for handling the volumes of data required to efficiently and effectively track or resolve such attacks. Further aspects provide actionable intelligence that drives result oriented goals for ransomed data and/or compromised systems.

Abstract: Systems and methods for forensic resolution of ransomware attacks are provided. The systems and methods define a platform and functionality for addressing ransom based attacks. According to one aspect, the platform and functionality provides a suite of programs and services that enable verification of “ransomed” files to ensure that they can in fact be recovered. If an attack has compromised the integrity of the underlying data so that it cannot be recovered, paying the ransom is an exercise in futility. Additional aspects provide for rapid collection of data that is targeted and specific and that further enables efficient forensic analysis. Many conventional approaches in this space fail to capture requisite detail and/or fail to provide a methodology for handling the volumes of data required to efficiently and effectively track or resolve such attacks. Further aspects provide actionable intelligence that drives result oriented goals for ransomed data and/or compromised systems.

Abstract: A sealing device, in particular a sealing head, for sealing a container has at least one sealing unit for a force and/or energy transmission, generating a sealing, to the container, and has at least one test unit (16a), integrated at least partly in the sealing unit, for monitoring a sealing quality of the container sealed by the sealing unit. The test unit includes at least one temperature sensor for detecting a sealing temperature. The temperature sensor is arranged in a sensor material recess of a base body of a heating unit of the sealing unit, and/or the temperature sensor is arranged in a sensor material recess of a sealing tool of the sealing unit. The sensor material recess of the sealing tool is arranged in a proximity of the heating unit.

Abstract: A controller for displaying a puncture site of an intra-atrial septum for heart repairs includes a memory and a processor (710). The processor (710) executes instructions (784) to perform a process based on image data of a heart that includes a mitral valve and an intra-atrial septum. The process includes defining a mitral valve annulus plane along a mitral valve annulus of the mitral valve and a normal vector perpendicular to the mitral valve annulus plane. The process also includes defining an offset plane that intersects with the intra-atrial septum and that is parallel to the mitral valve annulus plane. A safe zone for the puncture site is identified and displayed on the intra-atrial septum. The safe zone is between a lower boundary plane (456) and an upper boundary plane (455) that are each parallel to the offset plane by specified distances.

Abstract: The invention provides a system for determining a real-time valve function of a subject. The system comprises a processing unit adapted to: obtain a numerical model of a cardiac system, the numerical model being a 0D numerical model or a 1D numerical model, wherein the numerical model is adapted to receive physiological data as an input and output a simulated function of the cardiac system in real-time, wherein the simulated function of the cardiac system comprises a simulated function of a valve within the cardiac system. The processor is further adapted to obtain a continuous stream of physiological data from the subject; provide the continuous stream of physiological data as an input to the numerical model of the cardiac system, thereby generating a simulated real-time function of the cardiac system of the subject; and determine a real-time valve function of the subject based on the simulated real-time function of the cardiac system of the subject.

Abstract: A controller for displaying a puncture site of an intra-atrial septum for heart repairs includes a memory and a processor (710). The processor (710) executes instructions (784) to perform a process based on image data of a heart that includes a mitral valve and an intra-atrial septum. The process includes defining a mitral valve annulus plane along a mitral valve annulus of the mitral valve and a normal vector perpendicular to the mitral valve annulus plane. The process also includes defining an offset plane that intersects with the intra-atrial septum and that is parallel to the mitral valve annulus plane. A safe zone for the puncture site is identified and displayed on the intra-atrial septum. The safe zone is between a lower boundary plane (456) and an upper boundary plane (455) that are each parallel to the offset plane by specified distances.

Abstract: A gripper device comprises a gripper with a gripper arm rotatable around a rotation axis such that the gripper is movable between an open end position and a closed end position, and a hoisting device connected to the gripper and comprising a first cable and a second cable which are each connected with their one outer end to the gripper and are each connected with their other outer end to respectively a first and second hoisting means for raising and lowering the gripper with the cables, wherein each hoisting means is, driven by a separate drive, wherein a controller transmits the same control signal to both drives for the purpose of raising or lowering the gripper, and each drive comprises a motor with internal slippage or a slippage coupling so that synchronous running of the hoisting means is automatically realized.

Abstract: A gripper device comprises a gripper with a gripper arm rotatable around a rotation axis such that the gripper is movable between an open end position and a closed end position, and a hoisting device connected to the gripper and comprising a first cable and a second cable which are each connected with their one outer end to the gripper and are each connected with their other outer end to respectively a first and second hoisting means for raising and lowering the gripper with the cables, wherein each hoisting means is, driven by a separate drive, wherein a controller transmits the same control signal to both drives for the purpose of raising or lowering the gripper, and each drive comprises a motor with internal slippage or a slippage coupling so that synchronous running of the hoisting means is automatically realized.