Technologies for coordinating access to packets include a network device. The network device is to establish a ring in a memory of the network device. The ring includes a plurality of slots. The network device is also to allocate cores to each of an input stage, an output stage, and a worker stage. The worker stage is to process data in a data packet with an associated worker function. The network device is also to add, with the input stage, an entry to a slot in the ring representative of a data packet received with a network interface controller of the network device, access, with the worker stage, the entry in the ring to process at least a portion of the data packet, and provide, with the output stage, the processed data packet to the network interface controller for transmission.

A distributed digital projection system is disclosed which includes a plurality of smart projectors coupled to a head end server computer via a network. Each smart projector has a first network interface coupled to the network. Each smart projector is configured to receive commands and digital content, to process the received commands, and to convert the received digital content into a projection light signal for output. Each smart projector may include a second network interface to allow a daisy-chain network configuration. The head end server computer is configured to issue commands and to forward digital content to each of the at least one smart projectors, the commands specifying at least a time for display of the digital content. The digital content is stored on either network attached storage device coupled to the network or on a storage device directly coupled to or integrated with the head end server computer.

A memory device includes a memory array having a plurality of memory cells. Each memory cell of the plurality of memory cells is connected to a word line to apply a first signal to select the memory cell to read data from or write the data to the memory cell and a bit line to read the data from the memory cell or provide the data to write to the memory cell upon selecting the memory cell by the word line. A first bit line portion of the bit line connected to a first memory cell of the plurality of memory cells abuts a second bit line portion of the bit line connected to a second memory cell of the plurality of memory cells. The first memory cell is adjacent to the second memory cell.

A memory device includes a memory array having a plurality of memory cells. Each of the plurality of memory cells includes a first word line to apply a first signal to select the each of the plurality of memory cells to read data from or write the data to the each of the plurality of memory cells, a second word line to apply a second signal to select the each of the plurality of memory cells to read the data from or write the data to the each of the plurality of memory cells, and a bit line to read the data from the each of the plurality of memory cells or provide the data to write to the each of the plurality of memory cells upon selecting the each of the plurality of memory cells by at least one of the first word line or the second word line.

A system and method of extending a recording time of a recording event within a receiving device is set forth. The receiving device includes a memory and a controller. The controller generates a recording event request for content having a start time and a first end time and begins to store content in a memory of the first receiving unit starting at the start time. The controller reviews a program associated characteristic of the content when the end time is reached and when the program associated characteristic corresponds to the content, changes the first end time to second end time later than the first end time.

A multimedia device includes input ports dedicated to receiving a real-time media signal and a processor system dedicated to capturing the real-time media signal. The processor system defines an embedded environment. The input ports and the processor system are integrated into the multimedia capture device. The input ports include an audio input port and at least one of a visual-capture input port or a digital-image input port.

A memory module includes a first memory device, a second memory device, and a processing buffer circuit that is connected to the first memory device and the second memory device (independently of each other) and a host. A processing buffer circuit is provided, which includes a processing circuit and a buffer. The processing circuit processes at least one of data received from the host, data stored in the first memory device, or data stored in the second memory device based on a processing command received from the host. The buffer is configured to store data processed by the processing circuit. The processing buffer circuit is configured to communicate with the host in compliance with a DDR SDRAM standard.

In some embodiments, infrastructure data and service data is received for a computing infrastructure. The infrastructure data indicates resources in the computing infrastructure, and the service data indicates services to be orchestrated across the computing infrastructure. An infrastructure capacity model is generated, which indicates a capacity of the computing infrastructure over a particular time window. Service-to-resource placement options are also identified, which indicate possible placements of the services across the resources over the particular time window. Resource inventory data is obtained, which indicates an inventory of resources that are available to add to the computing infrastructure during the particular time window. An infrastructure capacity plan is then generated, which indicates resource capacity allocation options over the time slots of the particular time window. Resource capacities for the services are then allocated in the computing infrastructure.

An imaging device and an electronic apparatus including an imaging device are provided. The imaging device includes a substrate and plurality of pixel regions, wherein each pixel region includes: a first photoelectric conversion portion that performs photoelectric conversion according to a first wavelength of incident light; a first reading portion that reads charges converted by the first photoelectric conversion portion; a first storage unit that is formed between adjacent pixels and stores the charges read by the first reading portion; a second photoelectric conversion portion that performs photoelectric conversion according to a second wavelength different from the first wavelength; a second reading portion that reads charges converted by the second photoelectric conversion portion; and a second storage unit that is formed between adjacent pixels and stores the charges read by the second reading portion.

In some embodiments, infrastructure data and service data is received for a computing infrastructure. The infrastructure data indicates resources in the computing infrastructure, and the service data indicates services to be orchestrated across the computing infrastructure. An infrastructure capacity model is generated, which indicates a capacity of the computing infrastructure over a particular time window. Service-to-resource placement options are also identified, which indicate possible placements of the services across the resources over the particular time window. Resource inventory data is obtained, which indicates an inventory of resources that are available to add to the computing infrastructure during the particular time window. An infrastructure capacity plan is then generated, which indicates resource capacity allocation options over the time slots of the particular time window. Resource capacities for the services are then allocated in the computing infrastructure.