A method of operating a memory controller is disclosed. The method includes transmitting data signals to a memory device over each one of at least two parallel data links. A timing signal is sent to the memory device on a first dedicated link. The timing signal has a fixed phase relationship with the data signals. A data strobe signal is driven to the memory device on a second dedicated link. Phase information is received from the memory device. The phase information being generated internal to the memory device and based on a comparison between the timing signal and a version of the data strobe signal internally distributed within the memory device. A phase of the data strobe signal is adjusted relative to the timing signal based on the received phase information.

Techniques are described herein for a training procedure that identifies a frame boundary and generates a frame clock to identify the beginning and the end of a frame. After the frame training procedure is complete, a memory device may be configured to execute a frame synchronization procedure to identify the beginning of a frame based on the frame clock without the use of headers or other information within the frame during an active session of the memory device. During an activation time period after a power-up event, the memory device may initiate the frame training procedure. Once the frames are synchronized, the memory device may be configured to use that frame clock during an entire active session (e.g., until a power-down event) to identify the beginning of a frame as part of a frame synchronization procedure.

An apparatus is described. The apparatus includes a memory controller having an interface to communicate with a memory. The memory controller comprising logic circuitry to specify one of multiple possible write values to the memory during a write operation with multiple bits of a command that is sent on a command address bus that emanates from the interface. The memory to write any one of the possible write values into its storage cells while the memory interface is in a power saving state wherein the specified one write value is not articulated by the memory controller on a data bus of the interface as part of the write operation.

Methods, systems, and devices for dynamically configuring transmission lines of a bus between two electronic devices (e.g., a controller and memory device) are described. A first device may determine a quantity of bits (e.g., data bits, control bits) to be communicated with a second device over a data bus. The first device may partition the data bus into a first set of transmission lines (e.g., based on the quantity of data bits) and a second set of transmission lines (e.g., based on the quantity of control bits). The first device may communicate the quantity of data bits over the first set of transmission lines and communicate the quantity of control bits over the second set of transmission lines. In some cases, the first device may repartition the data bus based on different quantities of data bits and control bits to be communicated with the second device at a different time.

In certain embodiments, a memory module includes a printed circuit board (PCB) having an interface that couples it to a host system for provision of power, data, address and control signals. First, second, and third buck converters receive a pre-regulated input voltage and produce first, second and third regulated voltages. A converter circuit reduces the pre-regulated input voltage to provide a fourth regulated voltage. Synchronous dynamic random access memory (SDRAM) devices are coupled to one or more regulated voltages of the first, second, third and fourth regulated voltages, and a voltage monitor circuit monitors an input voltage and produces a signal in response to the input voltage having a voltage amplitude that is greater than a threshold voltage.

A method for controlling data transmission mode of an SD memory card device, which at least operates under an SD mode, includes: sending a first power signal from an electronic device to the SD memory card device via pin VDD1 to control and make the SD memory card device enter an initial state; and, sending a second power signal via one of a pin VDD2 and a pin VDD3 to the SD memory card device, to control and make the SD memory card device enter an Linkup state of a PCIe mode wherein a voltage level of the second power signal is lower than a voltage level of the first power signal.

Techniques are described herein for a training procedure that identifies a frame boundary and generates a frame clock to identify the beginning and the end of a frame. After the frame training procedure is complete, a memory device may be configured to execute a frame synchronization procedure to identify the beginning of a frame based on the frame clock without the use of headers or other information within the frame during an active session of the memory device. During an activation time period after a power-up event, the memory device may initiate the frame training procedure. Once the frames are synchronized, the memory device may be configured to use that frame clock during an entire active session (e.g., until a power-down event) to identify the beginning of a frame as part of a frame synchronization procedure.

An apparatus is described. The apparatus includes a memory controller having an interface to communicate with a memory. The memory controller comprising logic circuitry to specify one of multiple possible write values to the memory during a write operation with multiple bits of a command that is sent on a command address bus that emanates from the interface. The memory to write any one of the possible write values into its storage cells while the memory interface is in a power saving state wherein the specified one write value is not articulated by the memory controller on a data bus of the interface as part of the write operation.

A collector included in a data collection apparatus performs data collection to collect data from a PLC. A controller included in the data collection apparatus determines whether the collector is valid depending on whether the collector at a time when an instruction to start the data collection is provided matches the collector at a preset time, and causes the collector to start the data collection in response to the collector being valid.

The present technology includes a data strobe dock output circuit. The data strobe clock output circuit includes a first output circuit configured to generate a rising clock and a falling clock in response to a clock and a first enable signal and output a first data strobe clock in response to the rising clock, the falling clock, and mode signals, and a second output circuit configured to generate a rising inverted clock and a falling inverted clock by inverting the rising clock and the falling clock generated by the first output circuit, and output a second data strobe clock in response to the rising inverted clock, the falling inverted clock, a second enable signal, and the mode signals.