Abstract: A software, system and methodology for protecting against malware Point-of-Sale attacks that utilize, for example, memory scraping techniques. The application protects Point-of-sale hardware and its software against memory scraping malware attacks, and the loss of critical user credit card and confidential information often swiped at a terminal or stored in point of sale application databases. An embodiment of a method for blocking memory scraping attacks includes the following steps. Upon detecting a credit card swipe submission event from local hardware or comport event specific memory table events are flagged as unreadable, and immediately after allowing the data to be properly submitted, the system memory tables are cleared of data and specific memory processes are flagged as readable again. The method prevents memory scraping or point of sale malware from capturing swiped credit card data or input data, thereby protecting the user from theft of credit card data or other credentials.

Abstract: An apparatus, system, and method is disclosed for protecting against key logger malware. The protection includes protection form grabbing keylogger malware. In response to detecting a form submission event from a browser associated with a user entering data into a form, confidential data is cleared to prevent it being captured by malware. Additional protection of data inputs, entered at a driver level, may be provided as an additional level of protection against hook based malware operating at a virtual keyboard level or operating system level. Data inputs received at a physical driver level may be protected as they pass through a virtual keyboard level and an operating system level. The projection against malware may be provided as a preventive measure that does not require detection of the key logger malware itself.

Abstract: An apparatus, system, and method is disclosed for protecting against key logger malware. The protection includes protection form grabbing keylogger malware. In response to detecting a form submission event from a browser associated with a user entering data into a form, confidential data is cleared to prevent it being captured by malware. Additional protection of data inputs, entered at a driver level, may be provided as an additional level of protection against hook based malware operating at a virtual keyboard level or operating system level. Data inputs received at a physical driver level may be protected as they pass through a virtual keyboard level and an operating system level. The projection against malware may be provided as a preventive measure that does not require detection of the key logger malware itself.

Abstract: The present disclosure involves a method of communicating with an implantable medical device. A programmer is provided. The programmer has a plurality of diversity antennas. The diversity antennas are configured to send wireless signals to the implantable medical device. A subset of the diversity antennas is selected. A communications link is established between the programmer and the implantable medical device through the selected subset of the diversity antennas. A link quality of the communications link is measured. A different subset of the diversity antennas is selected to communicate with the implantable medical device if the link quality falls below a predetermined threshold.

Abstract: Energy usage can be monitored within at least one building having a plurality of energy consuming components. A database can be generated that contains values for a set of data points corresponding to data received from the plurality of energy consuming components. A change in a configuration can be detected for the plurality of energy consuming components based upon a change in values received from plurality of energy consuming components relative to the database. Based upon the change, an additional data point can be added to the set of data points in the database. Based upon the values for the set of data points, a probability can be determined that a rule for the additional data point is valid. A message can then be generated that includes the determined probability.

Abstract: The present disclosure involves a method of communicating with an implantable medical device. A programmer is provided. The programmer has a plurality of diversity antennas. The diversity antennas are configured to send wireless signals to the implantable medical device. A subset of the diversity antennas is selected. A communications link is established between the programmer and the implantable medical device through the selected subset of the diversity antennas. A link quality of the communications link is measured. A different subset of the diversity antennas is selected to communicate with the implantable medical device if the link quality falls below a predetermined threshold.

Abstract: The present disclosure involves a programmer configured to program an implanted medical device. The programmer includes a circuit board and first and second wireless communication devices located on the circuit board. The first wireless communication device is configured to operate in a first frequency band. The second wireless communication device is configured to operate in a second frequency band different from the first frequency band. The first and second wireless communication devices are each configured to communicate wirelessly with the implanted medical device. The programmer includes a first group of antennas coupled to the first wireless communication device. The antennas in the first group have first different positions on the circuit board. The programmer includes a second group of antennas coupled to the second wireless communication device. The antennas in the second group have second different positions on the circuit board.

Abstract: The invention relates to a satellite antenna assembly and a mounting assembly to allow the satellite antenna assembly to be mounted to a support means which may be located on the vertical support surface of a wall of a building. The mounting assembly allows initial engagement of first and second portions of the mounting assembly so as to allow the weight of the satellite antenna assembly to be carried by the mounting assembly and thereby allow the operator greater freedom in performing further actions to achieve a second engagement condition of the first and second portions together and thereby secure the satellite antenna assembly in the fixed location.

Abstract: A seat assembly having a seat back and a fold assist mechanism. The fold assist mechanism may have a drive plate and a spring. The spring may bias the seat back from a first position toward the second position when the spring engages a drive plate flange.

Abstract: A waveguide for transmission of data signals therealong. Data signals are typically received from and/or transmitted to a remote location and subsequently passed to or emitted from the apparatus which allows the data to be processed. The waveguide includes a channel which has a cross-sectional shape, the angular orientation of which is changed at least one point along the length of the same so as to provide a waveguide which is less sensitive to interferences. The waveguide, in one embodiment, can also include recessed portions and/or ridges along the length of the channel which ensures that the waveguide can be formed in a more reliable and controlled manner.

Abstract: A seat assembly having a seat back and a fold assist mechanism. The fold assist mechanism may have a drive plate and a spring. The spring may bias the seat back from a first position toward the second position when the spring engages a drive plate flange.

Abstract: The present disclosure involves a programmer configured to program an implanted medical device. The programmer includes a circuit board and first and second wireless communication devices located on the circuit board. The first wireless communication device is configured to operate in a first frequency band. The second wireless communication device is configured to operate in a second frequency band different from the first frequency band. The first and second wireless communication devices are each configured to communicate wirelessly with the implanted medical device. The programmer includes a first group of antennas coupled to the first wireless communication device. The antennas in the first group have first different positions on the circuit board. The programmer includes a second group of antennas coupled to the second wireless communication device. The antennas in the second group have second different positions on the circuit board.

Abstract: Techniques for data center analysis are provided. In one aspect, a method for modeling thermal distributions in a data center includes the following steps. Vertical temperature distribution data is obtained for a plurality of locations throughout the data center and is plotted as an s-curve, wherein the vertical temperature distribution data reflects physical conditions at each of the locations which is reflected in a shape of the s-curve. Each of the s-curves is represented with a set of parameters that characterize the shape of the s-curve, wherein the s-curve representations make up a knowledge base model of predefined s-curve types from which thermal distributions and associated physical conditions at the plurality of locations throughout the data center can be analyzed. The set of parameters that characterize the shape of the s-curve are associated with the physical conditions at the plurality of locations throughout the data center using a machine-learning model.

Abstract: Techniques for data center analysis are provided. In one aspect, a method for modeling thermal distributions in a data center is provided. The method includes the following steps. Vertical temperature distribution data is obtained for a plurality of locations throughout the data center. The vertical temperature distribution data for each of the locations is plotted as an s-curve, wherein the vertical temperature distribution data reflects physical conditions at each of the locations which is reflected in a shape of the s-curve. Each of the s-curves is represented with a set of parameters that characterize the shape of the s-curve, wherein the s-curve representations make up a knowledge base model of predefined s-curve types from which thermal distributions and associated physical conditions at the plurality of locations throughout the data center can be analyzed.

Abstract: A waveguide for transmission of data signals therealong. Data signals are typically received from and/or transmitted to a remote location and subsequently passed to or emitted from the apparatus which allows the data to be processed. The waveguide includes a channel which has a cross-sectional shape, the angular orientation of which is changed at least one point along the length of the same so as to provide a waveguide which is less sensitive to interferences. The waveguide, in one embodiment, can also include recessed portions and/or ridges along the length of the channel which ensures that the waveguide can be formed in a more reliable and controlled manner.

Abstract: Techniques for data center analysis are provided. In one aspect, a method for modeling thermal distributions in a data center is provided. The method includes the following steps. Vertical temperature distribution data is obtained for a plurality of locations throughout the data center. The vertical temperature distribution data for each of the locations is plotted as an s-curve, wherein the vertical temperature distribution data reflects physical conditions at each of the locations which is reflected in a shape of the s-curve. Each of the s-curves is represented with a set of parameters that characterize the shape of the s-curve, wherein the s-curve representations make up a knowledge base model of predefined s-curve types from which thermal distributions and associated physical conditions at the plurality of locations throughout the data center can be analyzed.

Abstract: Provided is a micropower impulse radar (MIR) pneumothorax detector. The detector includes a processor and a handheld MIR scanner. The handheld MIR scanner includes a device housing, an antenna located within the device housing, circuitry that generates MIR signals, and circuitry that processes received echoes of the MIR signals and provides the processed received echoes to the processor. The processor automatically determines whether a pneumothorax is present based on the processed received echoes of the MIR signals.

Abstract: A head mounted medical device for obtaining and processing EEG, EKG, and EOG/EMG signals from a wearer. The device utilizes electrodes organized into multiple electrode assemblies for ease of use and replacement, with the electrode assemblies being removably connected to the headband. The device includes processing and conditioning circuitry in the headband, the processing and conditioning including amplification, filtering, A/D conversion, and multiplexing of the analog signals generated by the electrodes, reducing noise influences and improving the handling and mobility of the device. The device connects to an external receiving device that then monitors and/or records the resulting serial, digital, and multiplexed data signal. The external device might also provide power and/or commands to the medical device.

Abstract: An automatic test system controlled by a general purpose digital central processor is disclosed. The central processor accepts test programs in a high level compiler language such as Atlas. The Atlas program is compacted into a simplified language which is utilized to communicate with test devices via a standard IEEE 488 data bus. Each of the test devices includes a programmable interface digital processor which performs any translation that may be necessary in order to permit specific test instruments coupled to the central processor via the interface processor to perform the tests specified by the high level test programs. A switching matrix also communicates with the digital processor to connect the appropriate test device to the unit under test.

Abstract: A test system utilizing a plurality of programmable test instruments each capable of executing portions of a test program with the test program being written in a compiler language such as ATLAS, for example, is disclosed. Programs specifying the tests to be performed are written in a compiler language such as ATLAS and transferred to a central control processor utilizing standard peripheral equipment. The central control processor communicates with a plurality of test instruments utilizing a series of data busses. In executing the test program, the control processor first segments the program into a series of individual tests to be performed. The test instruments are interrogated to determine which of the test instruments is currently capable of executing a specific sequence of the test program. Once an instrument has been identified which can execute the program segment, the control process transfers that segment to the instrument capable of executing the test.