Abstract: A computer platform is disclosed. The computer platform comprises a central processing unit (CPU) including at least one socket having a plurality of tiles and control circuitry to partition the socket into a plurality of sub-sockets and assign a unique identity to each of the plurality of sub-sockets for security verification, wherein each sub-socket comprises at least one of the plurality of tiles to operate as a cluster of resources.

Abstract: A computer platform is disclosed. The computer platform comprises a central processing unit (CPU) including at least one socket having a plurality of tiles and control circuitry to partition the socket into a plurality of sub-sockets and assign a unique identity to each of the plurality of sub-sockets for security verification, wherein each sub-socket comprises at least one of the plurality of tiles to operate as a cluster of resources.

Abstract: A self-cleaning air conduit for deactivating and decomposing chemical and life based airborne contamination. The conduit contains ultraviolet (UV) sources that irradiate semi UV reflective surfaces within the conduit. Said conduit is positioned in the path of pre and post filters. The internal surfaces of the conduit and components cast be altered by chemical and or mechanical means to maximize surfaces area and adhesion of photocatalytic coatings. Multiple coated panels within the conduit can be configured parallel to the air flow and positioned to enhancer the interaction of UV radiation with airborne contamination and photocatalytic produced free radical. Microprocessor based electronics connected to the conduit, provide power for key internal and ancillary componence necessary to control and monitor air velocity, UV radiation levels and airborne contamination levels.

Abstract: A computer platform is disclosed. The computer platform comprises a central processing unit (CPU) including at least one socket having a plurality of tiles and control circuitry to partition the socket into a plurality of sub-sockets and assign a unique identity to each of the plurality of sub-sockets for security verification, wherein each sub-socket comprises at least one of the plurality of tiles to operate as a cluster of resources.

Abstract: Methods and apparatus for detecting audio anomalies from a reference audio file and a sampled audio filed. In embodiments, a system can perform aligning in time first and second audio files, dividing the first and second audio files into chunks, performing time-based processing of the amplitude adjusted output of the first and second audio files to identify audio anomalies in the second audio file, and performing frequency-based processing of the amplitude adjusted output of the first and second audio files to identify audio anomalies in the second audio file.

Abstract: The frequency of a clock signal is compared to a predetermined range. If the measured frequency is outside the range, a system controller determines if a current operating state of the overall system allows for the internal clock to be adjusted back into compliance. If the controller determines that the current system state allows for the change, then a control signal to the internal clock signal source is changed by the smallest increment available, either to increase or decrease the frequency. If the internal clock signal is out of the desired range, and the system controller does not decide to modify the frequency, the controller may increase the size of the range by decreasing the lower bound and/or increasing the upper bound.

Abstract: The frequency of a clock signal is compared to a predetermined range. If the measured frequency is outside the range, a system controller determines if a current operating state of the overall system allows for the internal clock to be adjusted back into compliance. If the controller determines that the current system state allows for the change, then a control signal to the internal clock signal source is changed by the smallest increment available, either to increase or decrease the frequency. If the internal clock signal is out of the desired range, and the system controller does not decide to modify the frequency, the controller may increase the size of the range by decreasing the lower bound and/or increasing the upper bound.

Abstract: A system for reducing airborne contamination includes a housing defining the structure of the system and configured to fit within a window of a building. The system also includes a variable-speed fan, and a microprocessor in communication with the fan and configured to control the speed of the fan. Within the housing, the system may include an electrical chassis that defines a chamber and supports at least some of the system's electrical components within the housing. A removable cartridge may be selectively coupled with the electrical chassis to form a germicidal radiation chamber within the housing and within an airflow path through the system. The removable cartridge includes UV light source(s) and filter(s) that sterilize the air as it passes through the system and the germicidal radiation chamber.

Abstract: A method for reducing airborne contamination within a home includes installing an air-pressure control system within a window of the home, and drawing air from outside the home through the system inlet and an airflow path through the system. As it passes through the airflow path, a germicidal radiation chamber with a UV light source sterilizes the air. Additionally, filter(s) may clean the drawn air by removing particulates from the air as it passes through the filter. The method may then introduce the sterilized/cleaned air into the home through the system outlet. The sterilized/cleaned air may displace an equal volume of contaminated air within the home.

Abstract: An air-pressure-control system, the system comprising a system inlet, a system outlet, and a variable-speed fan configured to operate at a speed. A motor controller in communication with the fan is configured to control the speed of the fan. A differential-pressure transducer configured to monitor an air pressure at the system inlet and an air pressure at the system outlet. A closed-loop pressure controller in communication with the motor controller and differential-pressure transducer, wherein the pressure controller is configured to vary the speed of the fan based on the pressure differential between the inlet and outlet of the system, thereby controlling a pressure within a space. An ultraviolet kill chamber may be disposed between the inlet and outlet to expose airborne particulate to UV radiation. The system may also have a filter located within an air-flow path between the system inlet and system outlet.

Abstract: An air-pressure-control system, the system comprising a system inlet, a system outlet, and a variable-speed fan configured to operate at a speed. A motor controller in communication with the fan is configured to control the speed of the fan. A differential-pressure transducer configured to monitor an air pressure at the system inlet and an air pressure at the system outlet. A closed-loop pressure controller in communication with the motor controller and differential-pressure transducer, wherein the pressure controller is configured to vary the speed of the fan based on the pressure differential between the inlet and outlet of the system, thereby controlling a pressure within a space. An ultraviolet kill chamber may be disposed between the inlet and outlet to expose airborne particulate to UV radiation. The system may also have a filter located within an air-flow path between the system inlet and system outlet.

Abstract: An air-pressure-control system, the system comprising a system inlet, a system outlet, and a variable-speed fan configured to operate at a speed. A motor controller in communication with the fan is configured to control the speed of the fan. A differential-pressure transducer configured to monitor an air pressure at the system inlet and an air pressure at the system outlet. A closed-loop pressure controller in communication with the motor controller and differential-pressure transducer, wherein the pressure controller is configured to vary the speed of the fan based on the pressure differential between the inlet and outlet of the system, thereby controlling a pressure within a space. An ultraviolet kill chamber may be disposed between the inlet and outlet to expose airborne particulate to UV radiation. The system may also have a filter located within an air-flow path between the system inlet and system outlet.

Abstract: A system, method and computer program product are provided for scanning a mobile wireless device for malware. Initially, a service agent is initiated utilizing a mobile wireless device. Next, information describing the mobile wireless device is transmitted to a back-end server over a wireless network utilizing the service agent of the mobile wireless device. An update is then received from the back-end server over the wireless network utilizing the service agent of the mobile wireless device. Subsequently, an anti-malware scanner installed on the mobile wireless device is updated so that the mobile wireless device may be scanned utilizing the updated anti-malware scanner.

Abstract: A system, method and computer program product are provided for scanning a mobile wireless device for malware. Initially, an update command is received from a user utilizing a graphical user interface of a mobile wireless device. An anti-malware scanner installed on the mobile wireless device is then updated over a wireless network in response to the update command. The mobile wireless device is then scanned utilizing the updated anti-malware scanner. Such anti-malware scanner may be conditionally updated based on the update command so as to regulate usage of the wireless network with the mobile wireless device.

Abstract: An air-pressure-control system, the system comprising a system inlet, a system outlet, and a variable-speed fan configured to operate at a speed. A motor controller in communication with the fan is configured to control the speed of the fan. A differential-pressure transducer configured to monitor an air pressure at the system inlet and an air pressure at the system outlet. A closed-loop pressure controller in communication with the motor controller and differential-pressure transducer, wherein the pressure controller is configured to vary the speed of the fan based on the pressure differential between the inlet and outlet of the system, thereby controlling a pressure within a space. An ultraviolet kill chamber may be disposed between the inlet and outlet to expose airborne particulate to UV radiation. The system may also have a filter located within an air-flow path between the system inlet and system outlet.

Abstract: An air-pressure-control system, the system comprising a system inlet, a system outlet, and a variable-speed fan configured to operate at a speed. A motor controller in communication with the fan is configured to control the speed of the fan. A differential-pressure transducer configured to monitor an air pressure at the system inlet and an air pressure at the system outlet. A closed-loop pressure controller in communication with the motor controller and differential-pressure transducer, wherein the pressure controller is configured to vary the speed of the fan based on the pressure differential between the inlet and outlet of the system, thereby controlling a pressure within a space. An ultraviolet kill chamber may be disposed between the inlet and outlet to expose airborne particulate to UV radiation. The system may also have a filter located within an air-flow path between the system inlet and system outlet.

Abstract: A system, method and computer program product are provided for scanning a mobile wireless device for malware. A scan command is initially received from a user utilizing a mobile wireless device. Further, a component manager of the mobile wireless device is instantiated in response to the scan command. An anti-malware scanner is then executed utilizing the component manager. Further, the mobile wireless device is scanned utilizing the anti-malware scanner.

Abstract: An air-pressure-control system, the system comprising a system inlet, a system outlet, and a variable-speed fan configured to operate at a speed. A motor controller in communication with the fan is configured to control the speed of the fan. A differential-pressure transducer configured to monitor an air pressure at the system inlet and an air pressure at the system outlet. A closed-loop pressure controller in communication with the motor controller and differential-pressure transducer, wherein the pressure controller is configured to vary the speed of the fan based on the pressure differential between the inlet and outlet of the system, thereby controlling a pressure within a space. An ultraviolet kill chamber may be disposed between the inlet and outlet to expose airborne particulate to UV radiation. The system may also have a filter located within an air-flow path between the system inlet and system outlet.

Abstract: A system, method and computer program product are provided for scanning a plurality of mobile wireless devices for malware. A request is received to update an anti-malware scanner installed on a mobile wireless device over a wireless network. Further, an update tailored for the mobile wireless device is prepared using a back-end infrastructure. Such tailored update is then transmitted from the back-end infrastructure to the mobile wireless device over the wireless network.

Abstract: A system for controlling an electricity supply to a load comprises at least one battery for storing energy. The system also comprises a controller for determining when to switch between a first mode wherein electricity is supplied to the load from a mains electricity circuit; and a discharging mode wherein electricity is supplied from the battery to the load via the mains electricity circuit. The determining is based on information associated with the electricity supply.