Abstract: A memory component has a signaling interface, data input/output (I/O) circuitry and command/address (CA) circuitry. The signaling interface includes an on-die terminated data I/O and an unterminated CA input. The data I/O circuitry is dedicated to sampling write data bits at the data I/O timed by a strobe signal and to transmitting read data bits timed by a first clock signal, each of the write and read data bits being valid for a bit time at the data I/O. The CA circuitry samples CA signals at the CA input in response to both rising-edge and falling-edge transitions of a second clock signal, the CA signals indicating read and write operations to be performed within the memory component.

Abstract: Described are memory apparatus organized in physical banks and including configurable data control circuit to support multiple data-width configurations. Relatively narrow width configurations load fewer sense amplifiers, resulting in reduced power usage for relatively narrow memory configurations. Also described are memory controllers that convey configuration value to configurable memory apparatus and support point-to-point data buffers for multiple width configurations.

Abstract: A memory component has a signaling interface, data input/output (I/O) circuitry, command/address (CA) circuitry and clock generation circuitry. The signaling interface includes an on-die terminated data I/O and an unterminated CA input. The data I/O circuitry is dedicated to sampling write data bits at the data I/O timed by a strobe signal and to transmitting read data bits timed by a first clock signal, each of the write and read data bits being valid for a bit time at the data I/O. The CA circuitry samples CA signals at the CA input timed by a second clock signal, the CA signals indicating read and write operations to be performed within the memory component. The clock generation circuitry generates the first clock signal with a phase that establishes alignment between a leading edge of the bit time for each read data bit and a respective transition of the second clock signal.

Abstract: A cache-coherence protocol distributes atomic operations among multiple processors (or processor cores) that share a memory space. When an atomic operation that includes an instruction to modify data stored in the shared memory space is directed to a first processor that does not have control over the address(es) associated with the data, the first processor sends a request, including the instruction to modify the data, to a second processor. Then, the second processor, which already has control of the address(es), modifies the data. Moreover, the first processor can immediately proceed to another instruction rather than waiting for the address(es) to become available.

Abstract: An apparatus for controlling a dynamic random access memory (DRAM), the apparatus comprising an interface to transmit, over a first plurality of wires, to the DRAM a first code to indicate that first data is to be written to the DRAM and a column address to indicate a column location of a memory core in the DRAM where the first data is to be written. The interface is further to transmit a second code to indicate whether mask information for the first data will be sent to the DRAM. If the second code indicates that mask information will be sent, a portion of the column address and a portion of the mask information are sent after the second code is sent. The interface is further to transmit to the DRAM, over a second plurality of wires separate from the first plurality of wires, the first data.

Abstract: A micro-threaded memory device. A plurality of storage banks are provided, each including a plurality of rows of storage cells and having an access restriction in that at least a minimum access time interval must transpire between successive accesses to a given row of the storage cells. Transfer control circuitry is provided to transfer a first amount of data between the plurality of storage banks and an external signal path in response to a first memory access request, the first amount of data being less than a product of the external signal path bandwidth and the minimum access time interval.

Abstract: Systems and methods are provided for detecting and correcting address errors in a memory system. In the memory system, a memory device generates an error-detection code based on an address transmitted via an address bus and transmits the error-detection code to a memory controller. The memory controller transmits an error indication to the memory device in response to the error-detection code. The error indication causes the memory device to remove the received address and prevent a memory operation.

Abstract: A memory module having memory components, a termination structure, an address/control signal path, a clock signal path, multiple data signal paths and multiple strobe signal paths. The strobe signal paths and data signal paths are coupled to respective memory components, and the address/control signal path and clock signal path are coupled in common to all the memory components. The address/control signal path extends along the memory components to the termination structure such that control signals propagating toward the termination structure arrive at address/control inputs of respective memory components at progressively later times corresponding to relative positions of the memory components.

Abstract: Apparatus and methods are disclosed for adjusting phase of data signals to compensate for phase-offset variations between devices during normal operation. The phase of data signals are adjusted individually in each transmit data unit and receive data unit across multiple data slices with a common set of phase vector clock signals and a corresponding clock cycle count signal. The transmission of signal information between a first device (such as a memory controller) and a second device (such as a memory component) occurs without errors even when the accumulated delays between the first device and second device change by a half symbol time interval or more during operation of the system. The apparatus reduces the circuitry required, such as phase-lock-loops, for individually adjusting the phase of each transmit data unit and receive data unit across multiple data slices, which in turn results in reduction in complexity and cost of the system.

Abstract: A DRAM controller component generates a timing signal and transmits, to a DRAM, write data that requires a first time interval to propagate from the DRAM controller component to the DRAM and to be sampled by the DRAM on one or more edges of the timing signal, a clock signal that requires a second time interval to propagate from the DRAM controller component to the DRAM, and a write command, associated with the write data, to be sampled by the DRAM on one or more edges of the clock signal. The DRAM controller component includes series-coupled delay elements to generate respective incrementally delayed signals, and a multiplexer to select one of the delayed signals to time the transmission of the write data, such that transmission of the write data is delayed based on a difference between the first time interval and the second time interval.

Abstract: A method and system provides for execution of calibration cycles from time to time during normal operation of the communication channel. A calibration cycle includes de-coupling the normal data source from the transmitter and supplying a calibration pattern in its place. The calibration pattern is received from the communication link using the receiver on the second component. A calibrated value of a parameter of the communication channel is determined in response to the received calibration pattern. The steps involved in calibration cycles can be reordered to account for utilization patterns of the communication channel. For bidirectional links, calibration cycles are executed which include the step of storing received calibration patterns on the second component, and retransmitting such calibration patterns back to the first component for use in adjusting parameters of the channel at first component.

Abstract: An integrated circuit device includes a transmitter circuit including an output driver. The integrated circuit device includes a first register to store a value representative of a drive strength setting associated with the transmitter circuit such that the output driver outputs data in accordance with the drive strength setting. The integrated circuit device also includes a second register to store a value representative of an equalization setting associated with the transmitter circuit such that the output driver outputs data in accordance with the equalization setting. The integrated circuit device further includes a third register to store a value representative of a slew rate setting associated with the transmitter circuit such that the output driver outputs data in accordance with the slew rate setting.

Abstract: A method for storing data in a memory chip that includes a memory core having dynamic random access memory cells, is performed by a memory controller chip. The method includes sending a write command to a first interface of the memory chip, wherein the write command specifies a write operation. After sending the write command, the memory controller chip waits for a first time period corresponding to a time period during which the write command is stored by the memory chip, and sends data associated with the write operation to a second interface of the memory chip, wherein the sending of the data occurs after a second time period transpires, the second time period following the first time period, such that sending the write command and sending the data are separated by a first predetermined delay time that includes both the first time period and the second time period.

Abstract: A cache-coherence protocol distributes atomic operations among multiple processors (or processor cores) that share a memory space. When an atomic operation that includes an instruction to modify data stored in the shared memory space is directed to a first processor that does not have control over the address(es) associated with the data, the first processor sends a request, including the instruction to modify the data, to a second processor. Then, the second processor, which already has control of the address(es), modifies the data. Moreover, the first processor can immediately proceed to another instruction rather than waiting for the address(es) to become available.

Abstract: A memory component having a first and second interface. The first interface is provided to sample address information in response to a first clock signal. The first interface includes inputs to sample at least two bits of the address information in succession during a clock cycle of the first clock signal. The second interface is provided to sample data in response to a second clock signal, having a frequency that is at least twice the frequency of the first clock signal. The second interface includes inputs to sample at least two bits of data in succession during a clock cycle of the second clock signal.

Abstract: A chip includes a receiver circuit that uses a reference voltage to receive a data signal such that a logic level of the received data signal is determined using the reference voltage, and a register to store a value that represents an adjustment to the reference voltage.

Abstract: A method and system provides for execution of calibration cycles from time to time during normal operation of the communication channel. A calibration cycle includes de-coupling the normal data source from the transmitter and supplying a calibration pattern in its place. The calibration pattern is received from the communication link using the receiver on the second component. A calibrated value of a parameter of the communication channel is determined in response to the received calibration pattern. The steps involved in calibration cycles can be reordered to account for utilization patterns of the communication channel. For bidirectional links, calibration cycles are executed which include the step of storing received calibration patterns on the second component, and retransmitting such calibration patterns back to the first component for use in adjusting parameters of the channel at first component.

Abstract: Described are memory apparatus organized in memory subsections and including configurable routing to support multiple data-width configurations. Relatively narrow width configurations load fewer sense amplifiers, resulting in reduced power usage for relatively narrow memory configurations. Also described are memory controllers that convey width selection information to configurable memory apparatus and support point-to-point data interfaces for multiple width configurations.

Abstract: A memory component having a first and second interface. The first interface is provided to sample address information in response to a first clock signal. The first interface includes inputs to sample at least two bits of the address information in succession during a clock cycle of the first clock signal. The second interface is provided to sample data in response to a second clock signal, having a frequency that is at least twice the frequency of the first clock signal. The second interface includes inputs to sample at least two bits of data in succession during a clock cycle of the second clock signal.

Abstract: A module having first and second memory devices and a termination component. A first signal line is coupled to the first memory device to provide first data thereto, the first data to be stored in a memory array of the first memory device during a write operation. A second signal line is coupled to the second memory device to provide thereto, the second data to be stored in a memory array of the second memory device during the write operation. A control signal path is coupled to the first memory device, the second memory device and the termination component such that a write command propagating on the control signal path propagates past the first memory device and the second memory device before reaching the first termination component, wherein the write command specifies the write operation.