Abstract: A luminescent element renewal system including an enclosure having a closed condition defining an inside space in which one or more light emitting elements have a location to proximally align with a corresponding one or more photoluminescent elements of a device received within said enclosure with the one or more light emitting elements operable in the closed condition of the enclosure to emit an amount of light to induce luminescence in the photoluminescent elements of the device.

Abstract: A luminescent element renewal system including an enclosure having a closed condition defining an inside space in which one or more light emitting elements have a location to proximally align with a corresponding one or more photoluminescent elements of a device received within said enclosure with the one or more light emitting elements operable in the closed condition of the enclosure to emit an amount of light to induce luminescence in the photoluminescent elements of the device.

Abstract: Adaptive voltage scalers (AVSs), systems, and related methods are disclosed. The AVSs are configured to adaptively adjust voltage levels powering a functional circuit(s) based on target operating frequencies and delay variation conditions to avoid or reduce voltage margin. In one embodiment, the AVS includes an AVS database. The AVS database can be configured to store voltage levels for various operating frequencies of a functional circuit(s) to avoid or reduce voltage margin. The AVS database allows rapid voltage level decisions. The voltage levels stored in the AVS database may be initial, minimum, learned, populated, explored, backed out, temperature-based, and/or age-based voltage levels according to disclosed embodiments to further avoid or reduce voltage margin. An AVS module may be a software-based module that consults the AVS database to make voltage level decisions. Providing the AVS module as a software-based module may allow flexibility in configuring the AVS module and/or the AVS database.

Abstract: Adaptive voltage scalers (AVSs), systems, and related methods are disclosed. The AVSs are configured to adaptively adjust voltage levels powering a functional circuit(s) based on target operating frequencies and delay variation conditions to avoid or reduce voltage margin. In one embodiment, the AVS includes an AVS database. The AVS database can be configured to store voltage levels for various operating frequencies of a functional circuit(s) to avoid or reduce voltage margin. The AVS database allows rapid voltage level decisions. The voltage levels stored in the AVS database may be initial, minimum, learned, populated, explored, backed out, temperature-based, and/or age-based voltage levels according to disclosed embodiments to further avoid or reduce voltage margin. An AVS module may be a software-based module that consults the AVS database to make voltage level decisions. Providing the AVS module as a software-based module may allow flexibility in configuring the AVS module and/or the AVS database.

Abstract: Adaptive voltage scalers (AVSs), systems, and related methods are disclosed. The AVSs are configured to adaptively adjust voltage levels powering a functional circuit(s) based on target operating frequencies and delay variation conditions to avoid or reduce voltage margin. In one embodiment, the AVS includes an AVS database. The AVS database can be configured to store voltage levels for various operating frequencies of a functional circuit(s) to avoid or reduce voltage margin. The AVS database allows rapid voltage level decisions. The voltage levels stored in the AVS database may be initial, minimum, learned, populated, explored, backed out, temperature-based, and/or age-based voltage levels according to disclosed embodiments to further avoid or reduce voltage margin. An AVS module may be a software-based module that consults the AVS database to make voltage level decisions. Providing the AVS module as a software-based module may allow flexibility in configuring the AVS module and/or the AVS database.

Abstract: The AVSs are configured to adaptively adjust voltage levels powering a functional circuit(s) based on target operating frequencies and delay variation conditions to avoid or reduce voltage margin. In one embodiment, the AVS includes an AVS database. The AVS database can be configured to store voltage levels for various operating frequencies of a functional circuit(s) to avoid or reduce voltage margin. The AVS database allows rapid voltage level decisions. The voltage levels stored in the AVS database may be initial, minimum, learned, populated, explored, backed out, temperature-based, and/or age-based voltage levels according to disclosed embodiments to further avoid or reduce voltage margin. An AVS module may be a software-based module that consults the AVS database to make voltage level decisions. Providing the AVS module as a software-based module may allow flexibility in configuring the AVS module and/or the AVS database.

Abstract: Adaptive voltage scalers (AVSs), systems, and related methods are disclosed. The AVSs are configured to adaptively adjust voltage levels powering a functional circuit(s) based on target operating frequencies and delay variation conditions to avoid or reduce voltage margin. In one embodiment, the AVS includes a database. The database can be configured to store voltage levels for various operating frequencies of a functional circuit(s) to avoid or reduce voltage margin. The database allows rapid voltage level decisions. In one embodiment, a voltage offset is added to a voltage level retrieved from the database corresponding to a target operating frequency of the functional circuit(s). In another embodiment, a voltage level is retrieved from the database corresponding to a target operating frequency for and a temperature level of the functional circuit(s). The AVS may partially or fully controllable by a software-based module that consults the database to make voltage level decisions.

Abstract: Adaptive voltage scalers (AVSs), systems, and related methods are disclosed. The AVSs are configured to adaptively adjust voltage levels powering a functional circuit(s) based on target operating frequencies and delay variation conditions to avoid or reduce voltage margin. In one embodiment, the AVS includes a database. The database can be configured to store voltage levels for various operating frequencies of a functional circuit(s) to avoid or reduce voltage margin. The database allows rapid voltage level decisions. In one embodiment, a voltage offset is added to a voltage level retrieved from the database corresponding to a target operating frequency of the functional circuit(s). In another embodiment, a voltage level is retrieved from the database corresponding to a target operating frequency for and a temperature level of the functional circuit(s). The AVS may partially or fully controllable by a software-based module that consults the database to make voltage level decisions.

Abstract: A portable support apparatus for supporting game or other objects above the ground between spaced vertical columns comprises a support bracket attached by non-elastic straps to each column and a cross bar extending between the brackets. Each bracket includes a vertical back plate that rests flat against the vertical column and a vertical support plate that extends outwardly from a front side of the support plate. A recess in an upper edge of the support plate serves as a cross bar rest. The back plate can include studs to reduce slipping. The cross bar rest can have a rectangular U-shape or a V-shape for a rectangular, round or angled cross bar. The bracket can be mounted at a skewed angle on the column so the cross bar fits snugly in the recess.

Abstract: A processor provides two-level interrupt servicing. In one embodiment, the processor comprises a storage device and an interrupt handler. The storage device is configured to store an interrupt identifier corresponding to an interrupt request. The interrupt handler is configured to recognize the interrupt request, initiate a common interrupt service routine responsive to recognizing the interrupt request and subsequently initiate an interrupt service routine corresponding to the stored interrupt identifier.