Abstract: A memory controller is disclosed. In one particular exemplary embodiment, the memory controller may comprise a first transmitter to output first and second write commands synchronously with respect to a clock signal, a second transmitter to output first data using a first timing offset such that the first data arrives at a first memory device in accordance with a predetermined timing relationship with respect to a first transition of the clock signal, and a third transmitter to output second data suing a second timing offset such that the second data arrives at a second memory device in accordance with a predetermined timing relationship with respect to a second transition of the clock signal.

Abstract: A memory module having reduced access granularity. The memory module includes a substrate having signal lines thereon that form a control path and first and second data paths, and further includes first and second memory devices coupled in common to the control path and coupled respectively to the first and second data paths. The first and second memory devices include control circuitry to receive respective first and second memory access commands via the control path and to effect concurrent data transfer on the first and second data paths in response to the first and second memory access commands.

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: A memory controller has an interface to convey, over a first set of interconnect resources: a first command that specifies activation of a row of memory cells, a second command that specifies a write operation directed to the row of memory cells, a bit that specifies whether precharging will occur in connection with the write operation, a code that specifies whether data mask information will be issued in connection with the write operation, and if the code specifies that data mask information will be issued, data mask information that specifies whether to selectively write portions of write data associated with the write operation. The memory controller interface further conveys, over a second set of interconnect resources, separate from the first set of interconnect resource, the write data.

Abstract: This disclosure provides a method for adjusting system timing in a reconfigurable memory system. In a Dynamic Point-to-Point (“DPP”) system, for example, manufacturer-supplied system timing parameters such as access latency and maximum clock speed typically reflect a worst-case configuration scenario. By in-situ detecting actual configuration (e.g., whether expansion boards have been inserted), and correspondingly configuring the system to operate in a mode geared to the specific configuration, worst-case or near worst-case scenarios may be ruled out and system timing parameters may be redefined for faster-than-conventionally-rated performance; this is especially the case in a DPP system where signal pathways typically become more direct as additional modules are added. Contrary to convention wisdom therefore, which might dictate that component expansion should slow down timing, clock speed can actually be increased in such a system, if supported by the configuration, for better performance.

Abstract: A method of operation within a memory device is disclosed. The method comprises receiving address information and corresponding enable information in association with a memory access request. The address information includes a row address that specifies a row of storage cells within a storage array of the memory device, and the enable information includes first and second enable values that correspond respectively to first and second storage locations within the row of storage cells. The method involves selectively transferring data between the first and second storage locations and sense amplifier circuitry according to states of the first and second enable values. This includes transferring data between the first storage location and the sense amplifier circuitry if the first enable value is in an enable state and transferring data between the second storage location and the sense amplifier circuitry if the second enable value is in the enable state.

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: The memory module includes front and back faces. Multiple devices are disposed on each of the faces. A first control line serially connects a first group of devices on both the front and back faces so that the first group of devices commonly contribute multiple bits to a data bus. A second control line serially connects a second group of devices on both the front and back faces so that the second group of devices commonly contribute multiple bits to a data bus.

Abstract: A memory system includes a memory module which further includes a set of memory devices. The set of memory devices includes a first subset of memory devices and a second subset of memory devices. An address bus is disposed on the memory module, wherein the address bus includes a first segment coupled to the first subset and a second segment coupled to the second subset. An address signal traverses the set of memory devices in sequence. The memory system also includes a memory controller which is coupled to the memory module. The memory controller includes a first circuit to output a first control signal that controls the first subset, such that the first control signal and the address signal arrive at a memory device in the first subset at substantially the same time.

Abstract: A method and system that provides for execution of a first calibration sequence, such as upon initialization of a system, to establish an operation value, which utilizes an algorithm intended to be exhaustive, and executing a second calibration sequence from time to time, to measure drift in the parameter, and to update the operation value in response to the measured drift. The second calibration sequence utilizes less resources of the communication channel than does the first calibration sequence. In one embodiment, the first calibration sequence for measurement and convergence on the operation value utilizes long calibration patterns, such as codes that are greater than 30 bytes, or pseudorandom bit sequences having lengths of 2N?1 bits, where N is equal to or greater than 7, while the second calibration sequence utilizes short calibration patterns, such as fixed codes less than 16 bytes, and for example as short as 2 bytes long.

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: A memory component includes a memory core, a control transport block to receive a write command from external control lines, and a write control buffer to store the write command for a first time period after the write command is received at the transport block. A data buffer receives data from external data lines, the data to be stored in the memory core in response to the write command, wherein receipt of the data occurs based on a second time period that follows the first time period, such that receipt of the write command and the data are separated by a delay time that includes both the first time period and the second time period. A write mask buffer receives write masking information from an external write mask line. Receipt of the write command and the write masking information are separated by the delay time.

Abstract: A signaling system is disclosed. The signaling system includes a first integrated circuit (IC) chip to receive a data signal and a strobe signal. The first IC includes circuitry to sample the data signal at times indicated by the strobe signal to generate phase error information and circuitry to output the phase error information from the first IC device. The system further includes a signaling link and a second IC chip coupled to the first IC chip via the signaling link to output the data signal and the strobe signal to the first IC chip. The second IC chip includes delay circuitry to generate the strobe signal by delaying an aperiodic timing signal for a first time interval and timing control circuitry to receive the phase error information from the first IC chip and adjust the first time interval in accordance with the phase error information.

Abstract: A memory device having a memory core is described. The memory device includes a clock receiver circuit, a first interface to receive a read command, a data interface, and a second interface to receive power mode information. The data interface is separate from the first interface. The second interface is separate from the first interface and the data interface. The memory device has a plurality of power modes, including a first mode in which the clock receiver circuit, first interface, and data interface are turned off; a second mode in which the clock receiver is turned on and the first interface and data interface are turned off; and a third mode in which the clock receiver and first interface are turned on. In the third mode, the data interface is turned on when the first interface receives the command, to output data in response to the command.

Abstract: Methods of operation of a memory device and system are provided in embodiments. Initialization operations are conducted at a first frequency of operation during an initialization sequence. Memory access operations are then performed at a second frequency of operation. The second frequency of operation is higher than the first frequency of operation. Also, the memory access operations include a read operation and a write operation. In an embodiment, information that represents the first frequency of operation and the second frequency of operation is read from a serial presence detect device.

Abstract: An integrated circuit device includes a delay circuit, sampling circuit and delay control circuit that cooperate to carry out adaptive timing calibration. The delay circuit generates a timing signal by delaying an aperiodic input signal for a first interval. The sampling circuit samples a data signal in response to the timing signal to generate a sequence of data samples, and also samples the data signal in response to a phase-shifted version of the timing signal to generate a sequence of edge samples. The delay control circuit adjusts the first interval based, at least in part, on a phase error indicated by the sequence of data samples and the sequence of edge samples.

Abstract: A plurality of control signals are asserted within an asynchronous integrated circuit memory device in response to each transition of a memory access initiation signal to effect pipelined memory access operations.

Abstract: Described is a memory system in which the memory core organization changes with device width. The number of physical memory banks accessed reduces with device width, resulting in reduced power usage for relatively narrow memory configurations. Increasing the number of logic memory banks for narrow memory widths reduces the likelihood of bank conflicts, and consequently improves speed performance.

Abstract: A memory controller has an interface to convey, over a first set of interconnect resources: a first command that specifies activation of a row of memory cells, a second command that specifies a write operation directed to the row of memory cells, a bit that specifies whether precharging will occur in connection with the write operation, a code that specifies whether data mask information will be issued in connection with the write operation, and if the code specifies that data mask information will be issued, data mask information that specifies whether to selectively write portions of write data associated with the write operation. The memory controller interface further conveys, over a second set of interconnect resources, separate from the first set of interconnect resource, the write data.

Abstract: The memory module includes front and back faces. Multiple devices are disposed on each of the faces. A first control line serially connects a first group of devices on both the front and back faces so that the first group of devices commonly contribute multiple bits to a data bus. A second control line serially connects a second group of devices on both the front and back faces so that the second group of devices commonly contribute multiple bits to a data bus.