An interface circuit provides communication between a memory card and a host device which use a half duplex communication protocol. The interface circuit switches communication direction between the host device and memory card by analyzing interface protocol. The interface circuit includes a sending packet analyzing module which receives a first signal packet from the host device and obtains working status of the host device and memory card by analyzing the first signal packet, a bus direction control module coupled to the sending packet analyzing module which generates a first control signal according to a first parameter in the first signal packet which includes conducting direction information indicating the host device between the memory card, and a direction switching module coupled to the bus direction control module which controls the conducting direction of the pathway between the host device and memory card according to the first control signal.

Apparatuses, methods, systems, and program products are disclosed for dynamic baseboard management controller memory use. A method includes determining, by use of a processor, presence of main memory of a computing device, in response to determining that the main memory is not present in the computing device, preparing at least a portion of a memory device of a baseboard management controller for use by the processor, and making the at least a portion of the memory device of the BMC available to the processor.

An apparatus is provided that compensates for misalignment on a synchronous data bus. The apparatus includes a replica radial distribution element, a bit lag control element, and a synchronous lag receiver. The replica radial distribution element is configured to receive a first signal, and is configured to generate a second signal, where the replica radial distribution element comprises replicated propagation path lengths, loads, and buffering of a radial distribution network for a strobe. The bit lag control element is configured to measure a propagation time beginning with assertion of the first signal and ending with assertion of the second signal, and is configured to generate a value on a lag bus that indicates the propagation time. The bit lag control element has delay lock control and a gray encoder. The delay lock control is configured to select one of a plurality of successively delayed versions of the first signal that coincides with the assertion of the second signal, where the delay lock control selects the one of a plurality of successively delayed versions of the first signal by incrementing and decrementing bus states of select inputs on a first mux, and where the plurality of successively delayed versions of the first signal comprises inputs to the first mux, and where the plurality of successively delayed versions comprises outputs of a first plurality of series-coupled matched inverter pairs. The gray encoder is configured to gray encode the propagation time to generate the value on the lag bus. The synchronous lag receiver is configured to receive one of a plurality of radially distributed strobes and a data bit, and is configured to delay registering of the data bit by the propagation time. The synchronous lag receiver includes a second plurality of series-coupled matched inverter pairs, a second mux, and a bit receiver. The second plurality of series-coupled matched inverter pairs is configured to generate successively delayed versions of the data bit. The second mux is coupled to the second plurality of series-coupled matched inverter pairs, is configured to receive the value on the lag bus, and is configured to select one of the successively delayed versions of the data bit that corresponds to the value. The bit receiver is configured to receive the one of the successively delayed versions of the data bit and one of a plurality of radially distributed strobe signals, and is configured to register the state of the one of the successively delayed versions of the data bit upon assertion of the one of a plurality of radially distributed strobe signals.

A method is provided that compensates for misalignment on a synchronous data bus. The method includes: replicating propagation path lengths, loads, and buffering of a radial distribution network for a strobe; receiving a first signal, and generating a second signal by employing the replicated propagation path lengths, loads, and buffering; when an update signal is asserted, when an update signal is asserted, measuring a propagation time beginning with assertion of the first signal and ending with assertion of the second signal by selecting one of a plurality of successively delayed versions of the first signal that coincides with the assertion of the second signal, wherein said selecting comprises incrementing and decrementing bus states of select inputs on a mux, wherein the plurality of successively delayed versions of the first signal comprises inputs to the mux; gray encoding a value on a lag bus that indicates the propagation time; and receiving one of a plurality of radially distributed strobes and a data bit, and delaying registering of the data bit by the propagation time. The receiving includes generating successively delayed versions of the data bit; receiving the value on the lag bus, and selecting one of the successively delayed versions of the data bit that corresponds to the value; and registering the state of the one of the successively delayed versions of the data bit upon assertion of one of a plurality of radially distributed strobe signals.

Physical layer logic is provided that is to receive data on one or more data lanes of a physical link, receive a valid signal on another of the lanes of the physical link identifying that valid data is to follow assertion of the valid signal on the one or more data lanes, and receive a stream signal on another of the lanes of the physical link identifying a type of the data on the one or more data lanes.

An interface device and a signal transceiving method thereof are provided. The interface device includes a master circuit and a slave circuit. The slave circuit includes a second receiver, a clock generator, a sampler, and a comparator. The first receiver and second receiver respectively receive input data and a clock signal from the master circuit. The clock generator delays the clock signal according to a delay value to generate a delayed clock signal, and generates a plurality of sampling signals according to the delayed clock signal. The sampler samples the input data according to the sampling signals to generate a plurality of sampling results. The comparator compares the sampling results to generate a comparison result. The clock generator adjusts the delay value according to the comparison result.

Dynamic bus inversion (DBI) for programmable levels of a ratio of ones and zeros. A transmitting device identifies a number and/or ratio of ones and zeros in a noninverted version of a signal to be transmitted (noninverted signal) and a number and/or ratio of ones and zeros in an inverted version of the signal (inverted signal). The transmitting device can calculate whether a difference of ones and zeros in the noninverted signal or a difference of ones and zeros in the inverted signal provides a calculated average ratio of ones to zeros closer to a target ratio. The transmitting device sends the signal that achieves provides the calculated average ratio closer to the target ratio.

A synchronous transmission device includes a first communication port, a first bus instance and a second bus instance. The first communication port is connected to the first endpoint and the second endpoint. The first bus instance executes a first data transmission with the first endpoint according to a first node of a first schedule list. The first node corresponds to the first endpoint, and the first bus instance corresponds to the first communication port. When the first data transmission is executed, the first bus instance is further configured to determine whether the second bus instance is idle. When the second bus instance is idle, the first bus instance controls the second bus instance to execute a second data transmission with the second endpoint according to a second node of the first schedule list. The second node of the first schedule list corresponds to the second endpoint.

A portable lighting device that provides different user interfaces that may be selected by the user. Each user interface may provide one or more operational modes, such as on mode, power save mode, strobe mode or momentary mode. After a user interface is selected, the user may select on of the operational modes. The portable lighting device may be a flashlight.

An apparatus is provided that compensates for misalignment on a synchronous data bus. The apparatus includes a replica radial distribution element, a bit lag control element, and a synchronous lag receiver. The replica radial distribution element is configured to receive a lag pulse signal, and is configured to generate a replicated strobe signal, where the replica radial distribution network comprises replicated propagation path lengths, loads, and buffering of a radial distribution network for a strobe. The bit lag control element is configured to measure the time between assertion of the lag pulse signal and assertion of the replicated strobe signal when an update signal is asserted, and is configured to generate a first value on a lag bus that indicates the time. The bit lag control element has delay lock control that is configured to select one of a plurality of successively delayed versions of the lag pulse signal that coincides with the assertion the replicated strobe signal, and is configured to generate a second value on a lag select bus that indicates the propagation time, where the delay lock control selects the one of a plurality of successively delayed versions of the lag pulse signal by incrementing and decrementing bus states of select inputs on a mux, and where the plurality of successively delayed versions comprises inputs to the mux. The synchronous lag receiver is coupled to the bit lag control element, and is configured to receive a first one of a plurality of radially distributed strobes and a data bit, and is configured to delay registering of the data bit by the time.