Abstract: An access control system removes the human element from static protection by detecting a level of static energy when the user attempts to authenticate to the access control system, and when the user's detected level of static energy exceeds a defined threshold, access is denied until the user discharges the static energy. A static energy detection mechanism in a badge reader includes two conductive plates that form a first capacitor, and the space between an electrically conductive badge and one of the conductive plates on the badge reader forms a second capacitor. Using these two capacitors, the level of static energy on the user can be measured by the sum of the voltage across these two capacitors as the user presents the badge to the badge reader. The access control system assures the user is properly grounded before allowing access to an area, equipment, etc.

Abstract: A system and method for managing device communication anonymously in wireless networks. A controller in a device manages communication for the device. The device has a static device tag. The controller establishes a first key for the device. The controller establishes the first key in response to a first triggering event of the device. The first key is based on a first status of the device. The controller generates a first identifier of the device. The controller generates the first identifier by using a hashing technique. The controller uses the hashing technique on a combination of the first key and the static device tag. The first identifier is for identifying the device on a first wireless network. The controller provides a second status of the device. The controller provides the second status to the first wireless network. The controller couples the second status with the first identifier.

Abstract: A bus communicates bits in parallel between a transmitter and receiver. A selected set of bits has its bits scrambled. Scrambling the bits includes assigning two or more bits of the selected set of bits to atypical lanes of the bus. By scrambling the bits, the order in which the bits of the selected set of bits are ready by a processer are obscured. The set of bits is transmitted to the receiver with one or more delays. The delays are on one or more of the lanes of the bus. The delays indicate the order of the bits. The receiver is configured to use the delays to identify the order of the bits and unscramble the set of bits.

Abstract: An apparatus for providing security for an integrated circuit (IC) chip is disclosed. The apparatus may include the IC chip, attached to a surface of a printed circuit board (PCB). The PCB may include a first, electrically insulative, conformal coating layer attached to the PCB surface and to exposed IC chip surfaces. The PCB may also include a Wheatstone bridge circuit to indicate changes to a second, X-ray opaque, optically opaque and electrically resistive, conformal coating layer. The circuit may include four resistors, formed from second conformal coating layer regions, four sets of electrically conductive pads on the PCB, each set electrically connected to a resistor of the four resistors. The circuit may also include a voltage source, connected to two conductive pads and a monitoring device, connected to another two conductive pads and configured to detect a change of resistance of the Wheatstone bridge.

Abstract: Aspects of the present disclosure are directed towards a method of electronic verification of motion data. This includes collecting a first set of motion data that corresponds to a first set of motion characteristics generated from physically moving a hardware element of a computer ending upon inserting the hardware element of the computer into a computer chassis. This can further include determining an approved set of motion data and comparing the first set of motion data to the approved set of motion data. This can further include determining a difference between the first set of motion data and the approved set of motion data. This can further include determining that the difference does not satisfy a threshold. This can further include executing a reaction sequence in the computer, in response to determining that the difference does not satisfy the threshold.

Abstract: Systems and methods to safeguard data and hardware may include a memory configured to store a first image and sensitive data, and an optical sensor configured to capture a second image. A sensor signal comprising the captured second image may be generated. A controller having access to the memory may be configured to receive the sensor signal. The controller may be further configured to compare the stored first image to the captured second image, and based on the comparison, to determine whether the sensitive data is accessed.

Abstract: In an example, a polymeric material is disclosed. The polymeric material includes a polymer substrate and a plurality of graphene traces arranged to form a tamper detection circuit on the polymer substrate.

Abstract: In an example, a process includes forming a patterned layer on a polymer substrate. The process also includes depositing a graphene-containing material on the patterned layer to form a plurality of graphene traces of a tamper detection circuit.

Abstract: A removable, permanent or reconfigurable debug probing device for use in debug probing of a printed circuit assembly, the printed circuit assembly having at least one through via, the debug probing device comprising at least one leader thread configured to be threaded through the at least one through via. Using the probing device comprises inserting a selected one of the at least one leader threads through a selected one of the at least one through via to thereby probe a surface of the printed circuit assembly; and responsive to detecting a defect in the selected through via, using a flexible circuit connected to the selected leader thread to repair the detected defect.

Abstract: Aspects of the present disclosure are directed towards environmental based location monitoring. Environmental based location monitoring can include collecting, a first set of image data that corresponds to a first set of environmental characteristics existing within a bounded area encompassing a hardware element of the computer and determining an environmental difference based on a difference between a first location corresponding to a geographic position of the hardware element relative to the first set of environmental characteristics and a second location corresponding to an approved geographic position of the hardware element. Environmental based location monitoring can include determining that the environmental difference does not satisfy a threshold and executing a reaction sequence in the computer, in response to determining that the environmental difference does not satisfy the threshold.

Abstract: Aspects of the present disclosure are directed towards a method of electronic verification of motion data. This includes collecting a first set of motion data that corresponds to a first set of motion characteristics generated from physically moving a hardware element of a computer ending upon inserting the hardware element of the computer into a computer chassis. This can further include determining an approved set of motion data and comparing the first set of motion data to the approved set of motion data. This can further include determining a difference between the first set of motion data and the approved set of motion data. This can further include determining that the difference does not satisfy a threshold. This can further include executing a reaction sequence in the computer, in response to determining that the difference does not satisfy the threshold.

Abstract: Aspects of the present disclosure are directed towards a method of electronic verification of motion data. This includes collecting a first set of motion data that corresponds to a first set of motion characteristics generated from physically moving a hardware element of a computer ending upon inserting the hardware element of the computer into a computer chassis. This can further include determining an approved set of motion data and comparing the first set of motion data to the approved set of motion data. This can further include determining a difference between the first set of motion data and the approved set of motion data. This can further include determining that the difference does not satisfy a threshold. This can further include executing a reaction sequence in the computer, in response to determining that the difference does not satisfy the threshold.

Abstract: Disclosed aspects relate to an elastomeric electrical connector structure. A first physical hardware plane has a first group of electrical contacts to establish a first portion of a set of electrical connections. A second physical hardware plane has a second group of electrical contacts to establish a second portion of the set of electrical connections. The elastomeric electrical connector structure is to join the first and second portions of the set of electrical connections. The elastomeric electrical connector structure includes a first state having a first distance between the first and second physical hardware planes, and a second state having a second distance between the first and second physical hardware planes. The first distance exceeds the second distance.

Abstract: In an example, a method includes obtaining an expected biological sample value at a computing device. The expected biological sample value indicates an expected concentration of a material biologically processed by a courier. The computing device determines whether the measured biological sample value is associated with the courier based on a comparison of the expected biological sample value to the measured biological sample value. The method also includes determining a particular set of operations to be performed at the computing device based on a result of the comparison.

Abstract: In an example, an apparatus includes a biological analysis component and a control component. The biological analysis component is configured to obtain an expected biological sample value. The expected biological sample value indicates an expected concentration of a material biologically processed by a courier. The biological analysis component is further configured to determine whether a measured biological sample value is associated with the courier based on a comparison of the expected biological sample value to the measured biological sample value. The control component is configured to perform a first set of operations based on the result of the comparison indicating that the measured biological sample value is associated with the courier. The control component is configured to perform a second set of operations based on the result of the comparison indicating that the measured biological sample value is outside an acceptable range of the biological sample value.

Abstract: A stub of a via formed in a printed circuit board is backdrilled to a predetermined depth. A capacitance probe is positioned within the via. Then the capacitance probe is used to obtain a test capacitance measurement. The test capacitance measurement is compared to a predetermined baseline capacitance measurement. Residual conductive plating material in the backdrilled stub causes the test capacitance measurement to exceed the predetermined baseline capacitance measurement. An indication is made that the predetermined baseline capacitance measurement has been exceeded.

Abstract: A stub of a via formed in a printed circuit board is backdrilled to a predetermined depth. A capacitance probe is positioned within the via. Then the capacitance probe is used to obtain a test capacitance measurement. The test capacitance measurement is compared to a predetermined baseline capacitance measurement. Residual conductive plating material in the backdrilled stub causes the test capacitance measurement to exceed the predetermined baseline capacitance measurement. An indication is made that the predetermined baseline capacitance measurement has been exceeded.

Abstract: Aspects of the present disclosure are directed towards environmental based location monitoring. Environmental based location monitoring can include collecting, a first set of image data that corresponds to a first set of environmental characteristics existing within a bounded area encompassing a hardware element of the computer and determining an environmental difference based on a difference between a first location corresponding to a geographic position of the hardware element relative to the first set of environmental characteristics and a second location corresponding to an approved geographic position of the hardware element. Environmental based location monitoring can include determining that the environmental difference does not satisfy a threshold and executing a reaction sequence in the computer, in response to determining that the environmental difference does not satisfy the threshold.

Abstract: Systems and methods to safeguard data and hardware may include a memory configured to store a first image and sensitive data, and an optical sensor configured to capture a second image. A sensor signal comprising the captured second image may be generated. A controller having access to the memory may be configured to receive the sensor signal. The controller may be further configured to compare the stored first image to the captured second image, and based on the comparison, to determine whether the sensitive data is accessed.

Abstract: An access control system removes the human element from static protection by detecting a level of static energy when the user attempts to authenticate to the access control system, and when the user's detected level of static energy exceeds a defined threshold, access is denied until the user discharges the static energy. A static energy detection mechanism in a badge reader includes two conductive plates that form a first capacitor, and the space between an electrically conductive badge and one of the conductive plates on the badge reader forms a second capacitor. Using these two capacitors, the level of static energy on the user can be measured by the sum of the voltage across these two capacitors as the user presents the badge to the badge reader. The access control system assures the user is properly grounded before allowing access to an area, equipment, etc.