Abstract: According to one aspect, an apparatus includes an expansion element, an expandable element, and a frame. The expandable element is configured to have an expanded state and an unexpanded state, wherein the expandable element is arranged to be inserted between a mated pair of printed circuit boards (PCBs) while in the unexpanded state. The expansion element is arranged to cause the expandable element to expand to the expanded state. When the expandable element is in the expanded state, the expandable element causes the pair of PCBs to demate. The frame is arranged to facilitate an insertion of the expandable element between the mated pair of PCBs. In one embodiment, the expandable element is an inflatable element and the expansion element is an inflator element that includes an air supply.

Abstract: In one embodiment, a method includes receiving an indication at a modular electronic system of initiation of online removal for a module removably inserted into a slot of the modular electronic system, increasing a fan speed at the modular electronic system before the module is removed, monitoring an internal temperature at the modular electronic system, and providing an indication that the module is ready for removal upon reaching a specified cooling state at the modular electronic system based on the temperature monitoring. A panel on an adjacent module is opened and extends into the slot upon removal of the module to substantially block airflow bypass from the slot and maintain cooling within the modular electronic system. An apparatus and logic are also disclosed herein.

Abstract: A heat sink mounting configuration is provided that is configured to prevent the heat sink from damaging ball grid arrays (BGA) of an application specific integrated circuit (ASIC) mounted on a printed circuit board (PCB) when the line card is subjected to vibrations and shocks. The heat sink mounting configuration may include a set of screws configured to be at least partially disposed within the apertures of the heat sink to secure the heat sink to the PCB. The mounting configuration includes a resilient member and a spacer disposed around the screws proximate to the apertures. The resilient members are configured to bias the heat sink against the ASIC to maintain the heat sink in contact with the ASIC. The spacers are configured to prevent the heat sink from impacting the ASIC with forces large enough to damage the BGA when the line card is subjected to vibrations and shocks.

Abstract: In one embodiment, a method includes receiving light from a light generating device at a port of a network device, the port comprising a port optical element positioned within a path of the light, receiving a cable assembly comprising a plug at the port, the plug comprising a plug optical element positioned for alignment with the port optical element when the cable assembly is coupled with the port, and processing the light at the port optical element and the plug optical element. The processed light is emitted from a portion of the plug extending from the port when the cable assembly is coupled with the port to provide a visual indication of compatibility between the cable assembly and the port. An apparatus is also disclosed herein.

Abstract: To reduce the rate at which a false alternating current (“AC”) loss alarming signal is generated, but at the same time detect an actual AC loss situation in a timely manner, the disclosed method describes an AC line power loss detection and active verification method. If the AC line input voltage dips momentarily lower than a standard sine wave amplitude, the AC line may not be considered lost as long as it still has energy to drive a load. The method inserts a momentary load across the AC line and compares the AC line voltage before and after the extra load is applied. If the AC power is present, this extra loading will increase the AC loading current momentarily, but will not affect the AC line voltage. However, if the AC power is lost, such loading will lower the AC line voltage, indicating a loss of power.

Abstract: According to one aspect, an apparatus includes a body and a toggle-interlock assembly. The body has an opening defined therein. The toggle-interlock assembly is coupled to the body, and includes a toggle portion and an interlock portion. The toggle-interlock assembly has a first configuration and a second configuration. When the toggle-interlock assembly is in a first configuration, the toggle portion physically blocks at least part of the opening while the interlock portion is stowed. When the toggle-interlock assembly is in a second configuration, the toggle portion does not physically block access to the opening while the interlock portion is in a deployed position that is arranged to prevent the apparatus from being inserted into a chassis.

Abstract: According to one aspect, an apparatus includes a first printed circuit board (PCB), the first PCB including a first interface, and a corrosion sensor assembly. The corrosion sensor assembly including a second interface arranged to be coupled to the first interface, the corrosion sensor assembly further including a signal trace field and a plurality of components, wherein the signal trace field and the plurality of components are arranged to provide an indication of whether the apparatus is in an environment that is corrosive.

Abstract: According to one aspect, an apparatus includes an expansion element, an expandable element, and a frame. The expandable element is configured to have an expanded state and an unexpanded state, wherein the expandable element is arranged to be inserted between a mated pair of printed circuit boards (PCBs) while in the unexpanded state. The expansion element is arranged to cause the expandable element to expand to the expanded state. When the expandable element is in the expanded state, the expandable element causes the pair of PCBs to demate. The frame is arranged to facilitate an insertion of the expandable element between the mated pair of PCBs. In one embodiment, the expandable element is an inflatable element and the expansion element is an inflator element that includes an air supply.

Abstract: In one embodiment, a piezoelectric device is positioned adjacent to a debris fence. A resonant frequency detection circuit connects with the piezoelectric device. The resonant frequency of the piezoelectric device is responsive to debris adjacent to the debris fence.

Abstract: In one embodiment, a piezoelectric device is positioned adjacent to a debris fence. A resonant frequency detection circuit connects with the piezoelectric device. The resonant frequency of the piezoelectric device is responsive to debris adjacent to the debris fence.

Abstract: In one embodiment, a piezoelectric device is positioned adjacent to a debris fence. A resonant frequency detection circuit connects with the piezoelectric device. The resonant frequency of the piezoelectric device is responsive to debris adjacent to the debris fence.

Abstract: A heat sink mounting configuration is provided that is configured to prevent the heat sink from damaging ball grid arrays (BGA) of an application specific integrated circuit (ASIC) mounted on a printed circuit board (PCB) when the line card is subjected to vibrations and shocks. The heat sink mounting configuration may include a set of screws configured to be at least partially disposed within the apertures of the heat sink to secure the heat sink to the PCB. The mounting configuration includes a resilient member and a spacer disposed around the screws proximate to the apertures. The resilient members are configured to bias the heat sink against the ASIC to maintain the heat sink in contact with the ASIC. The spacers are configured to prevent the heat sink from impacting the ASIC with forces large enough to damage the BGA when the line card is subjected to vibrations and shocks.

Abstract: According to one aspect, a method includes determining when a change has occurred with respect to a first piece of data that is stored in a database, and causing the first piece of data to be displayed on a display screen, the display screen being in communication with the database. The method also includes causing a visual indication to be displayed on the display screen, the visual indication being arranged to be superimposed with respect to the first piece of data on the display screen, the visual indication being configured to visually indicate at least one selected from a group including qualitative information and quantitative information associated with the change, wherein the visual indication is arranged to be activated to cause details associated with the change to be displayed on the display screen.

Abstract: A system of maintaining consumable physical components of networking equipment includes a physical network operations controller, having a controller and an interconnected memory device, which is configured to communicate with at least one notification device and consumable physical components for networking equipment.

Abstract: A computing device housing is described. The housing includes a front shell and a back shell coupled to a mid-frame. An infrared port may be an integral portion of the housing or the mid-frame.

Abstract: In one embodiment, a piezoelectric device is positioned adjacent to a debris fence. A resonant frequency detection circuit connects with the piezoelectric device. The resonant frequency of the piezoelectric device is responsive to debris adjacent to the debris fence.

Abstract: In one embodiment, a method includes obtaining, on a database system, a change definition request, the change definition request being obtained from a subscriber. The method also includes determining whether the change definition request defines a parametric change, the parametric change being associated with a parameter stored in the database system, and populating a criteria set associated with the parameter when it is determined that the change definition request is associated with the parametric change. Finally, the method includes determining when the parametric change occurs, and providing a first notification to the subscriber when it is determined that the parametric change has occurred.

Abstract: A computing device housing is described. The housing includes a front shell and a back shell coupled to a mid-frame. An infrared port may be an integral portion of the housing or the mid-frame.

Abstract: In one embodiment, a method includes obtaining collaboration data from at least one data source, and mapping the collaboration data into a visual representation in a collaboration space. The visual representation is arranged to be manipulated to cause details associated with the collaboration to be displayed in the collaboration space. Finally, the method includes enabling manipulations of the visual representation.

Abstract: A handheld computer having a housing with a midframe construction is described. The housing includes a front shell and a back shell coupled to a midframe. The handheld computer also includes two accessory slots for a stylus or other devices on the left and right sides of the housing. The handheld computer also includes an infrared port which is an integral portion of the housing.