Abstract: Systems and techniques are provided for wireless communications. For example, a process can include transmitting, to a network entity, first channel map information of a wireless communication device, wherein the first channel map information includes one or more channels associated with the wireless communication device. A process can include receiving, from the network entity, an identifier of a particular subframe of a plurality of subframes and a subframe channel map of the particular subframe, wherein the wireless communication device is allocated to the particular subframe based on a comparison of the one or more channels included in the first channel map information and one or more channels included in the subframe channel map of the particular subframe. A process can include transmitting, to the network entity, a periodic advertisement (PA) response using a channel included in the subframe channel map of the particular subframe.

Abstract: Disclosed are techniques relating to an improved air quality device that can provide personalized comfort and improved air quality elements to occupants of a common space. The improved air quality device can comprise a plurality of individually adjustable directional outlets. The state of these individually adjustable directional outlets can be updated to individually satisfy comfort levels of various occupants at different locations within the common space, which can be determined based on inputs from a control device (e.g., thermostat), a sensor (e.g., occupancy sensor), and so forth. The improved air quality device can further comprise an ultraviolet light device that can reduce pathogens in the common space. The state of the ultraviolet light device (e.g., on/off, duration of on/off, a position/location, and so on) can be a function of the state of the state of the outlets.

Abstract: Described herein are heating, ventilation, air conditioning, and refrigeration (HVACR) systems and methods directed to indoor air quality. HVACR systems and methods are based on dynamic people modeling to simulate and/or to monitor airflow impact on pathogen spread in an indoor space. HVACR systems and methods model an indoor space with pathogen killing technology to deploy the pathogen killing technology. HVACR systems and methods are directed to control administration of a pathogen killing technology to an indoor space based on factors that impact airflow including from dynamic analytics, a known input, and/or detection.

Abstract: Disclosed are techniques relating to an improved air quality device that can provide personalized comfort and improved air quality elements to occupants of a common space. The improved air quality device can comprise a plurality of individually adjustable directional outlets. The state of these individually adjustable directional outlets can be updated to individually satisfy comfort levels of various occupants at different locations within the common space, which can be determined based on inputs from a control device (e.g., thermostat), a sensor (e.g., occupancy sensor), and so forth. The improved air quality device can further comprise an ultraviolet light device that can reduce pathogens in the common space. The state of the ultraviolet light device (e.g., on/off, duration of on/off, a position/location, and so on) can be a function of the state of the state of the outlets.

Abstract: Described herein are heating, ventilation, air conditioning, and refrigeration (HVACR) systems and methods directed to indoor air quality. HVACR systems and methods are based on dynamic people modeling to simulate and/or to monitor airflow impact on pathogen spread in an indoor space. HVACR systems and methods model an indoor space with pathogen killing technology to deploy the pathogen killing technology. HVACR systems and methods are directed to control administration of a pathogen killing technology to an indoor space based on factors that impact airflow including from dynamic analytics, a known input, and/or detection.

Abstract: Described herein are heating, ventilation, air conditioning, and refrigeration (HVACR) systems and methods directed to indoor air quality. HVACR systems and methods are based on dynamic people modeling to simulate and/or to monitor airflow impact on pathogen spread in an indoor space. HVACR systems and methods model an indoor space with pathogen killing technology to deploy the pathogen killing technology. HVACR systems and methods are directed to control administration of a pathogen killing technology to an indoor space based on factors that impact airflow including from dynamic analytics, a known input, and/or detection.

Abstract: An electronic design automation (EDA) tool that analyzes a circuit design to identify sequential elements (flip-flops) that do not need to be reset, for example, because they do not need to be initialized in order to be in a known state, and converts the identified sequential elements to non-resettable circuits, which saves power and area.

Abstract: A method for balancing both edges of a signal of an integrated circuit (IC) design includes defining a virtual cell to have the same geometry as that of a port of the IC design. First and second input pins of the virtual cell are defined for detecting rising and falling edges. The first and second input pin geometries are defined to be the same as that of the corresponding pins of the port. The virtual cell is overlapped with the port so the first and second input pins are connected to the corresponding port network. The first and second input pins are configured as sinks for clock and buffer tree synthesis. An EDA tool identifies the first and second input pins as additional parallel sinks on the port network and balances the rising and falling edges of the signal at the port.