Abstract: Systems and methods for detecting malicious or potentially malicious script data are provided. Script data is extracted from a data stream at the network level and emulated in a controlled environment. Based upon a comparison of features extracted from emulation of the script to a set of heuristics, malicious script data can be identified for further analysis or processing.

Abstract: Systems, apparatuses, and methods are described for managing data collection and security in a network. An computing device may instruct sensors on one or more networks to collect and report data of certain data types based on modes that indicate instructions for sending and/or storing data of one or more data types. If the reported data is determined to indicate a security event, the computing device may determine additional data and/or data types useful in monitoring the security event, identify sensors based on a proximity of the sensors to the security event, and update the sensor modes based on new data collected.

Abstract: Technologies are provided for identification of cyberattack campaigns. Cyberattack campaigns are represented by temporal graphs based on detection events representing suspicious activities in a computer network. Temporal relationships and property relationships among the detection events dictate the node and edge structure of a temporal graph representing a cyberattack campaign. By tracking how those relationships change over time, changes to the node and edge structure of the temporal graph can be determined. Those changes reveal the dynamics of the cyberattack campaign by identifying time-dependent changes in the connections across multiple network entities that are involved in the cyberattack campaign. Accordingly, the temporal graph may represent the entire evolution of a cyberattack campaign since its inception in a computer network.

Abstract: Systems and methods for detecting malicious or potenitally malicious script data are provided. Script data is extracted from a data stream at the network level and emulated in a controlled environment. Based upon a comparison of features extracted from emulation of the script to a set of heuristics, malicious script data can be identified for further analysis or processing.

Abstract: Improved systems and methods for automated machine-learning, zero-day malware detection. Embodiments include a system and method for detecting malware using multi-stage file-typing and, optionally pre-processing, with fall-through options.

Abstract: Improved systems and methods for automated machine-learning, zero-day malware detection. Embodiments include a system and method for detecting malware using multi-stage file-typing and, optionally pre-processing, with fall-through options.

Abstract: Improved systems and methods for automated machine-learning, zero-day malware detection. Embodiments include a system and method for detecting malware using multi-stage file-typing and, optionally pre-processing, with fall-through options.

Abstract: Systems and methods for detecting malicious or potenitally malicious script data are provided. Script data is extracted from a data stream at the network level and emulated in a controlled environment. Based upon a comparison of features extracted from emulation of the script to a set of heuristics, malicious script data can be identified for further analysis or processing.

Abstract: Improved systems and methods for automated machine-learning, zero-day malware detection. Embodiments include a system and method for detecting malware using multi-stage file-typing and, optionally pre-processing, with fall-through options.

Abstract: A method of making carbon thin films comprises depositing a catalyst on a substrate, depositing a hydrocarbon in contact with the catalyst and pyrolyzing the hydrocarbon. A method of controlling a carbon thin film density comprises etching a cavity into a substrate, depositing a hydrocarbon into the cavity, and pyrolyzing the hydrocarbon while in the cavity to form a carbon thin film. Controlling a carbon thin film density is achieved by changing the volume of the cavity. Methods of making carbon containing patterned structures are also provided. Carbon thin films and carbon containing patterned structures can be used in NEMS, MEMS, liquid chromatography, and sensor devices.

Abstract: A method (and resulting structure) for fabricating a sensing device. The method includes providing a substrate comprising a surface region and forming an insulating material overlying the surface region. The method also includes forming a film of carbon based material overlying the insulating material and treating to the film of carbon based material to pyrolyzed the carbon based material to cause formation of a film of substantially carbon based material having a resistivity ranging within a predetermined range. The method also provides at least a portion of the pyrolyzed carbon based material in a sensor application and uses the portion of the pyrolyzed carbon based material in the sensing application. In a specific embodiment, the sensing application is selected from chemical, humidity, piezoelectric, radiation, mechanical strain or temperature.

Abstract: A packaging system for microfluidics including a microfluidic modular packaging system comprising: a packaging jig comprising a body, at least two module ports for placing microfluidic modules, at least one external fluidic port, and at least one internal fluidic port; at least two die platforms adapted to fit into the module ports and move the microfluidic modules; at least one fluidic control die; at least one circuit board, and at least one cover. HPLC applications are particularly important for proteomics research and commercialization.

Abstract: A method (and resulting structure) for fabricating a sensing device. The method includes providing a substrate comprising a surface region and forming an insulating material overlying the surface region. The method also includes forming a film of carbon based material overlying the insulating material and treating to the film of carbon based material to pyrolyzed the carbon based material to cause formation of a film of substantially carbon based material having a resistivity ranging within a predetermined range. The method also provides at least a portion of the pyrolyzed carbon based material in a sensor application and uses the portion of the pyrolyzed carbon based material in the sensing application. In a specific embodiment, the sensing application is selected from chemical, humidity, piezoelectric, radiation, mechanical strain or temperature.

Abstract: A method of making carbon thin films comprises depositing a catalyst on a substrate, depositing a hydrocarbon in contact with the catalyst and pyrolyzing the hydrocarbon. A method of controlling a carbon thin film density comprises etching a cavity into a substrate, depositing a hydrocarbon into the cavity, and pyrolyzing the hydrocarbon while in the cavity to form a carbon thin film. Controlling a carbon thin film density is achieved by changing the volume of the cavity. Methods of making carbon containing patterned structures are also provided. Carbon thin films and carbon containing patterned structures can be used in NEMS, MEMS, liquid chromatography, and sensor devices.