Abstract: Disclosed are systems and methods for generating graphical displays of analyte data and/or health information. In some implementations, the graphical displays are generating based on a self-referential dataset that are modifiable based on identified portions of the data. The modified graphical displays can indicate features in the analyte data of a host.

Abstract: Disclosed are systems and methods for generating graphical displays of analyte data and/or health information. In some implementations, the graphical displays are generating based on a self-referential dataset that are modifiable based on identified portions of the data. The modified graphical displays can indicate features in the analyte data of a host.

Abstract: A new and distinct cultivar of Hosta named ‘Wu Hoo’, characterized by its very large sized mounding clump, blue-green leaves with medium green margins. In combination these traits set ‘Wu Hoo’ apart from all other existing varieties of Hosta known to the inventor.

Abstract: A Wireless Traffic Congestion and Hazardous Condition Detection and Warning System. The system utilizes electronic nodes placed alongside a highway to detect traffic congestion and other hazardous conditions, visually notify drivers of a detected hazardous condition, and wirelessly communicate the hazardous condition to neighboring nodes in order to notify drivers well in advance of the hazard. A detected hazardous condition can also be transmitted through the existing cellular network to enable remote monitoring of traffic flow and remote notification of detected hazardous conditions.

Abstract: A Static Sleep Convention Logic (SSCL) circuit. The circuit improves upon Multi-Threshold NULL Convention Logic (MTNCL), disclosed in U.S. Pat. No. 7,977,972, by utilizing the SECRII architecture along with the Bit-Wise MTNCL technique, to produce a new SSCL gate without an nsleep input, which yields a smaller and faster circuit that utilizes less energy per operation than the patented SMTNCL gate design, while only very slightly increasing leakage power during sleep mode.

Abstract: A multi-threshold null convention logic circuit. The circuit includes a first circuit, a first high-threshold transistor coupled to Vcc, and an inverter receiving power from the first high-threshold transistor, driven by the first circuit, and including an output.

Abstract: A Static Sleep Convention Logic (SSCL) circuit. The circuit improves upon Multi-Threshold NULL Convention Logic (MTNCL), disclosed in U.S. Pat. No. 7,977,972, by utilizing the SECRII architecture along with the Bit-Wise MTNCL technique, to produce a new SSCL gate without an nsleep input, which yields a smaller and faster circuit that utilizes less energy per operation than the patented SMTNCL gate design, while only very slightly increasing leakage power during sleep mode.

Abstract: A multi-threshold null convention logic circuit. The circuit includes a first circuit, a first high-threshold transistor coupled to Vcc, and an inverter receiving power from the first high-threshold transistor, driven by the first circuit, and including an output.

Abstract: A Multi-Threshold CMOS NULL Convention Logic asynchronous circuit (MTNCL). The MTNCL circuit provides delay-insensitive logic operation with significant leakage power and active energy reduction. The MTNCL circuit is also capable of functioning properly under extreme supply voltage scaling down to the sub-threshold region for further power reduction. Four MTNCL architectures and four MTNCL threshold gate designs offer an asynchronous logic design methodology for glitch-free, ultra-low power, and faster circuits without area overhead.

Abstract: A Multi-Threshold CMOS NULL Convention Logic asynchronous circuit (MTNCL). The MTNCL circuit provides delay-insensitive logic operation with significant leakage power and active energy reduction. The MTNCL circuit is also capable of functioning properly under extreme supply voltage scaling down to the sub-threshold region for further power reduction. Four MTNCL architectures and four MTNCL threshold gate designs offer an asynchronous logic design methodology for glitch-free, ultra-low power, and faster circuits without area overhead.

Abstract: A Multi-Threshold CMOS NULL Convention Logic asynchronous circuit (MTNCL). The MTNCL circuit provides delay-insensitive logic operation with significant leakage power and active energy reduction. The MTNCL circuit is also capable of functioning properly under extreme supply voltage scaling down to the sub-threshold region for further power reduction. Four MTNCL architectures and four MTNCL threshold gate designs offer an asynchronous logic design methodology for glitch-free, ultra-low power, and faster circuits without area overhead.

Abstract: A Multi-Threshold CMOS NULL Convention Logic asynchronous circuit (MTNCL). The MTNCL circuit provides delay-insensitive logic operation with significant leakage power and active energy reduction. The MTNCL circuit is also capable of functioning properly under extreme supply voltage scaling down to the sub-threshold region for further power reduction. Four MTNCL architectures and four MTNCL threshold gate designs offer an asynchronous logic design methodology for glitch-free, ultra-low power, and faster circuits without area overhead.

Abstract: A selective call device (130) having a receiver (204) that receives a selective call signal with an address (312), a formatting message (406), and a related message (408). A processor (214) correlates a recovered address with a predetermined address in the selective call device (130) and determines selection of the selective call device (130). A decoder (212) decodes the formatting message (406) and the related message (408) contained in the selective call signal in response to the processor (214) determining selection of the selective call device. An information display (228) presents at least a portion of the related message (408) in accordance with a format determined at least in part by the formatting message (406).

Abstract: A selective call device (130) has a receiver (204) for receiving a selective call signal including an address (312). An address correlator (214) coupled to a decoder (212) determines that the selective call signal is directed thereto and determines whether the selective call signal includes an update command (400, 500). The update command includes a major version number (406, 506), topic numbers associated with sub-message(s) stored in the selective call device, update data associated with each topic number for updating the sub-messages, and minor version numbers (427, 527) associated with each topic number. The major version number is incremented when a sub-message template is changed. Minor version numbers are incremented after each update. The selective call device updates a sub-message with update data only if the update command includes a current major version number and an incremented minor version number.

Abstract: A selective call device (130) has a receiver (204) for receiving a selective call signal including an address (312) and a topic sub-address (504) indicative of a subscribed information, a processor (212, 214) for correlating the address (312) in the selective call signal to determine when the selective call signal is directed thereto, a decoder (212), in response to the processor (212, 214) determining that the selective call signal is directed thereto, for decoding the topic sub-address (504) to determine when the selective call signal includes the subscribed information, and a battery saver, coupled to the receiver (204), for initiating battery saving when the address (312) does not correlate with a predetermined address of the selective call device (130) and for initiating battery saving when the topic sub-address (504) is absent from the selective call signal.

Abstract: A new and distinct cultivar of Hosta named ‘Wu Hoo’, characterized by its very large sized mounding clump, blue-green leaves with medium green margins. In combination these traits set ‘Wu Hoo’ apart from all other existing varieties of Hosta known to the inventor.