Abstract: A system that handles delivery of a service through a client device or a secondary device paired with the client device, includes an interactive service provider and the client device. The interactive service provider inserts at least one of digital watermarks, fingerprints, and trigger identifiers at event opportunities in media content. The client device detects at least one of the inserted digital watermarks, the digital fingerprints, and the inserted trigger identifiers in the media content. The client device further renders overlay graphics on the media content and activates at least one of input devices in vicinity of the client device or the rendered overlay graphics. The client device receives trigger responses over an activated overlay graphic, via the activated input devices. The client device further displays an interactive view on the client device, to enable delivery of services in response to the received trigger responses.

Abstract: Techniques are described for automatically presenting workflow(s) in an application based at least partly on detected signal(s). A radio-frequency signal may be emitted from a transceiver and received by a transceiver of a user device when the transceiver is in proximity to the device. In response, an application including functionality to activate a payment card can launch.

Abstract: Technologies for high-speed data transmission including a network port logic having a communication lane coupled to a physical medium dependent/physical medium attachment (PMD/PMA) sublayer, a physical coding sublayer (PCS), and a media access control (MAC) sublayer. The communication lane receives serial binary data at a line speed such as 25 gigabits per second. The PMD/PMA converts the serial binary data into parallel data, and the PCS decodes that parallel data using a line code also used for a slower line speed such as 10 gigabits per second. The network port logic may include four independent communication lanes, with each communication lane coupled to a dedicated PMD/PMA, PCS, and MAC. The network port logic may also include a multi-lane PCS and multi-lane MAC to receive and transmit data striped over the four communication lanes. Other embodiments are described and claimed.

Abstract: Technologies for high-speed data transmission including a network port logic having a communication lane coupled to a physical medium dependent/physical medium attachment (PMD/PMA) sublayer, a physical coding sublayer (PCS), and a media access control (MAC) sublayer. The communication lane receives serial binary data at a line speed such as 25 gigabits per second. The PMD/PMA converts the serial binary data into parallel data, and the PCS decodes that parallel data using a line code also used for a slower line speed such as 10 gigabits per second. The network port logic may include four independent communication lanes, with each communication lane coupled to a dedicated PMD/PMA, PCS, and MAC. The network port logic may also include a multi-lane PCS and multi-lane MAC to receive and transmit data striped over the four communication lanes. Other embodiments are described and claimed.

Abstract: Technologies for high-speed data transmission including a network port logic having a communication lane coupled to a physical medium dependent/physical medium attachment (PMD/PMA) sublayer, a physical coding sublayer (PCS), and a media access control (MAC) sublayer. The communication lane receives serial binary data at a line speed such as 25 gigabits per second. The PMD/PMA converts the serial binary data into parallel data, and the PCS decodes that parallel data using a line code also used for a slower line speed such as 10 gigabits per second. The network port logic may include four independent communication lanes, with each communication lane coupled to a dedicated PMD/PMA, PCS, and MAC. The network port logic may also include a multi-lane PCS and multi-lane MAC to receive and transmit data striped over the four communication lanes. Other embodiments are described and claimed.

Abstract: Technologies for high-speed data transmission including a network port logic having a communication lane coupled to a physical medium dependent/physical medium attachment (PMD/PMA) sublayer, a physical coding sublayer (PCS), and a media access control (MAC) sublayer. The communication lane receives serial binary data at a line speed such as 25 gigabits per second. The PMD/PMA converts the serial binary data into parallel data, and the PCS decodes that parallel data using a line code also used for a slower line speed such as 10 gigabits per second. The network port logic may include four independent communication lanes, with each communication lane coupled to a dedicated PMD/PMA, PCS, and MAC. The network port logic may also include a multi-lane PCS and multi-lane MAC to receive and transmit data striped over the four communication lanes. Other embodiments are described and claimed.

Abstract: There is disclosed an apparatus for controlling a physical layer interface of a network interface card. The apparatus comprises: 1) a read only memory (ROM) for storing an embedded control program; 2) a random access memory for storing a downloadable software control program; and 3) a microcontroller for controlling the physical layer interface, wherein the microcontroller in a first operating mode executes the embedded control program to thereby control the physical layer interface, and wherein the microcontroller in a second operating mode downloads the downloadable software control program from an external processing system and executes the software control program in place of the embedded control program to thereby control the physical layer interface.

Abstract: There is disclosed an apparatus for controlling a physical layer interface of a network interface card in real time. The apparatus comprises: 1) a first memory for storing a multitasking control program, the multitasking control program comprising a main routine and a plurality of subroutines callable by the main routine; 2) a second memory for storing a plurality of multitasking vectors associated with the multitasking control program; and 3) a microcontroller for executing the multitasking control program, wherein program execution control is transferred from the main routine to a first one of the plurality of subroutines when the first subroutine is called by the main routine and wherein the first subroutine, upon encountering a decision point in the first subroutine that is not yet capable of being decided, updates a first one of the plurality of multitasking vectors associated with the first subroutine with an address of the decision point and transfers program execution control back to the main routine.