Abstract: Various embodiments of the present invention provide systems, methods and circuits for power management and/or EMI reduction. As one example, a method for memory system access is disclosed that includes providing a first bank of memory; providing a second bank of memory; receiving a memory access request that includes assertion of a reference memory clock; accessing the first bank of memory using a first sub memory clock asserted relative to the reference memory clock; delaying a phase offset; and accessing the second bank of memory using a second sub memory clock asserted the phase offset after assertion of the first sub memory clock.

Abstract: A structure and method for increasing the operating speed and reducing the overall programming time of a memory array are provided herein. The method and structure reduce the maximum write current consumption, for writing a plurality of data bits to a NVM array, by writing the data bits sharing an activated word line at different times (e.g., activating bit lines associated with an activated word line at different times). The write operation of respective data bits, which individually utilize only a fraction of the overall write window of the bits, are interleaved so that the maximum write current of respective bits are offset in time from the maximum write current of another bit, allowing a larger number of data bits to be written without exceeding system specifications (e.g., maximum current) and reducing overall memory write time.

Abstract: Circuit and method for recovering clock data in highly integrated semiconductor memory apparatus includes a plurality of signal receiving units configured to receive signals through a plurality of input/output pads and transfer the signals according to a receiving reference clock, the signal receiving units being divided into groups, a plurality of phase detection units configured to detect phases of signals output from the groups of the signal receiving units, a plurality of phase detection control units configured to control the phase detection units so that the phase detection units sequentially detect the phases of the signals output from each of the groups of the signal receiving units and a notification unit configured to output signals output from the phase detection units.

Abstract: Apparatus and methods for providing SRAM timing tracking cell circuits are disclosed. In an embodiment, an apparatus comprises an SRAM array comprising static random access memory cells arranged in rows and columns; a plurality of word lines each coupled to memory cells along one of the rows; a clock generation circuit for outputting clock signals; a word line generation circuit for generating a pulse on the plurality of word lines responsive to one of the clock signals and for ending the pulse responsive to one of the clock signals; and a tracking cell for receiving a clock signal and for outputting a word line pulse end signal to the clock generation circuit, following an SRAM tracking time; wherein the tracking cell further comprises SRAM tracking circuits positioned in the SRAM array and coupled in series to provide a signal indicating the SRAM tracking time. Methods for SRAM timing are disclosed.

Abstract: A semiconductor apparatus includes an odd data clock buffer group configured to maintain or shift a phase of a multi-phase source clock signal, and output a first multi-phase clock signal, an even data clock buffer group configured to maintain or shift a phase of the multi-phase source clock signal, and output a second multi-phase clock signal, an odd data output buffer group configured to drive odd data in response to the first multi-phase clock signal and output the driven data to an odd data pad group, and an even data output buffer group configured to drive even data in response to the second multi-phase clock signal and output the driven data to an even data pad group, wherein the phases of clock signals of the first and second multi-phase clock signal are different from each other.

Abstract: A dual-port static random access memory (SRAM) includes a multitude of programmable delay elements disposed along the paths of a number signals used to carry out read, write or read-then-write operations. At least one of the programmable delay elements controls the timing margin between a pair of clock signals that trigger a read/write enable signal. A second programmable delay element coarsely adjusts the delay of a first signal associated with a dummy bitline. A third programmable delay element finely adjusts the delay of a second signal associated with the dummy bitline. A fourth programmable delay element controls the delay of a signal used to reset the read/write enable signal. During a read operation, the voltage level of the second signal is used as an indicator to activate the sense amplifiers. During a write operation, the voltage level of the second signal is used to control the write cycle.

Abstract: A comparator determines the fidelity of a response vector received from a memory under test. The comparator includes a first logic gate configured to output a first value that is the logical OR of a first proper subset of bits of the response vector. A second logic gate is configured to output a second value that is the logical NAND of the proper subset of bits. A first multiplexer is configured to select between the first and second values based on the value of a first bit of a check vector corresponding to the response vector.

Abstract: An apparatus includes a memory circuit and an interface circuit. The interface circuit is coupled to the memory circuit. The interface circuit selects a phase value of clock signal adapted to clock the memory circuit.

Abstract: A memory interface allows access to SDRAM by receiving a column address for a data read or write of a burst of data units. Each data unit in the burst has an expected bit size. The interface generates n (n>1) column memory addresses from the received column address. The interface accesses the synchronous dynamic memory to read or write n bursts of data at the n column memory addresses. Preferably, the SDRAM is clocked at n times the rate of the interconnected memory accessing device, and the memory units. The data units in the n bursts preferably have one nth the expected bit size. In this way, SDRAM may be accessed with high memory bandwidth, without requiring an increase in the size of data units in the SDRAM, and the associated data bus. Conveniently, the interface may be operable in two separate modes or configurations. In one mode, SDRAM may be accessed through the interface in a conventional manner. In the second mode, SDRAM is accessed in multiple bursts for each received burst access.

Abstract: The column address circuit of a semiconductor memory device according to an aspect of the present disclosure includes a column address generation circuit configured to generate an internal dummy clock in response to a data output enable signal, generate an internal clock in response to a read enable signal, generate first count addresses in response to the internal dummy clock, and generate normal count addresses in response to the internal clock after the generation of the first count addresses, where the read enable signal is activated later than the data output enable signal, and a column address output circuit configured to store the first count addresses and the normal addresses and to generate column addresses by synchronizing the first count addresses and the normal addresses with output clocks, respectively.

Abstract: Memory circuit and a tracking circuit thereof. The tracking circuit includes a dummy bit line (DBL). The tracking circuit further includes a first circuit to discharge the dummy bit line in response to a first signal and a wordline activation signal. The wordline activation signal causes activation of a memory cell. The tracking circuit also includes a second circuit which is responsive to discharge of the dummy bit line to enable access to the memory cell.

Abstract: An apparatus for data strobe and timing variation detection of an SDRAM interface includes a differential-signal to single-end signal converter, a first phase delay circuit, a data latch circuit. The differential-signal to single-end signal converter receives a differential data strobe signal from the SDRAM interface and converts the signal into a single-end data strobe signal. The first phase delay circuit is connected to the differential-signal to single-end signal converter to delay the phase of the single-end data strobe signal for producing a delayed data strobe signal. The data latch circuit is connected to the phase delay circuit to latch synchronous data from the SDRAM interface according to the delayed single-end data strobe signal.

Abstract: Such a device is disclosed that includes a control circuit outputting a first clock signal having a first clock cycle in response to a first command signal and outputting a second clock signal having a second clock cycle in response to a second command signal, a first circuit controlled based on the first clock signal, and a second circuit controlled based on the second clock signal.

Abstract: Data serializers, output buffers, memory devices and methods for serializing are provided, including a data serializer that may convert digits of parallel data to a stream of corresponding digits of serial data digits. One such data serializer may include a logic system receiving the parallel data digits and clock signals having phases that are equally phased apart from each other. Such a data serializer may use the clock signals to generate data sample signals having a value corresponding to the value of a respective one of the parallel data digits and a timing corresponding to a respective one of the clock signals. The data sample signals may be applied to a switching circuit that includes a plurality of switches, such as respective transistors, coupled to each other in parallel between an output node and a first voltage.

Abstract: A clock generator includes a first input end and a second input end. The first input end is capable of receiving a first clock signal including a first state transition and a second state transition defining a first pulse width. The second input end is capable of receiving a second clock signal having a third state transition. A time period ranges from the first state transition to the third state transition. The clock generator can compare the first pulse width and the time period. The clock generator can output a third clock signal having a second pulse width ranging from a fourth state transition to a fifth state transition. The fifth state transition of the third clock signal is capable of being triggered by the second state transition of the first clock signal or the third state transition of the second clock signal depending on the comparison of the first pulse width and the time period.

Abstract: A memory controller for a smart card including a non-volatile memory can include an internal circuit that is configured to perform cryptographic key processing responsive to a first clock and a non-volatile memory interface circuit for transferring/receiving a signal to/from the internal circuit in synchronization with the first clock and transferring/receiving the signal to/from an external device in synchronization with a second clock that is asynchronous relative to the first clock.

Abstract: Circuit and method for recovering clock data in highly integrated semiconductor memory apparatus includes a plurality of signal receiving units configured to receive signals through a plurality of input/output pads and transfer the signals according to a receiving reference clock, the signal receiving units being divided into groups, a plurality of phase detection units configured to detect phases of signals output from the groups of the signal receiving units, a plurality of phase detection control units configured to control the phase detection units so that the phase detection units sequentially detect the phases of the signals output from each of the groups of the signal receiving units and a notification unit configured to output signals output from the phase detection units.

Abstract: A semiconductor memory device for controlling an operation of a delay-locked loop (DLL) circuit includes a DLL circuit that receives an external clock signal and that performs a locking operation on the external clock signal and an internal clock signal, thereby obtaining a locked state. A control unit controls the DLL circuit to constantly maintain the locked state during an updating period of an auto-refresh period of an auto-refresh operation for refreshing memory banks.

Abstract: A clock signal having a clock pulse width duration is received. A delay time is received. A first relationship and a second relationship between the clock pulse width duration and the delay time are determined. A new clock is generated that has a first new clock pulse width duration determined by the first relationship and the delay time and a second new clock pulse width duration determined by the second relationship and the clock pulse width duration. Switching between the first new clock pulse width duration and the second new clock pulse width duration is automatic based on the first relationship and the second relationship.

Abstract: A method for operating a memory device with pseudo double clock signals comprises the steps of: generating an even clock signal and an odd clock signal, wherein the clock rates of both the even clock signal and the odd clock signal are half that of the input clock signal, and the even clock signal is the inverse signal of the odd clock signal; if the logic level of the even clock signal is 1 when receiving a trigger of a control signal, applying the even clock signal to a memory device; and if the logic level of the odd clock signal is 1 when receiving another trigger of the control signal, applying the odd clock signal to the memory device.

Abstract: Circuitry for determining timing characteristics, for example, access time, setup time, hold time, recovery time and removal time, of as-manufactured digital circuit elements, such as latches, flip-flops and memory cells. Each element under test is embodied in variable-loop-path ring oscillator circuitry that includes multiple ring-oscillator loop paths, each of which differs from the other(s) in terms of inclusion and exclusion of ones of a data input and a data output of the element under test. Each loop path is caused to oscillate at each of a plurality of frequencies, and data regarding the oscillation frequencies is used to determine one or more timing characteristics of the element under test. The variable-loop-path ring oscillator circuitry can be incorporated into a variety of test systems, including automated testing equipment, and built-in self test structures and can be used in performing model-to-hardware correlation of library cells that include testable as-manufactured digital circuit elements.

Abstract: A semiconductor memory storage device is disclosed, the memory comprises: a plurality of storage cells for storing data; at least two access control lines each for controlling access to a respective at least one of the plurality of storage cells; at least two access control circuits each for controlling a voltage level supplied to a corresponding one of the at least two access control lines in response to an access request, the at least two access control circuits each comprising a capacitor and switching circuitry; routing circuitry for routing the access request and a boost signal to a selected one of the at least two access control circuits in dependence upon an address associated with the access request; wherein the at least two access control circuits are each responsive to: receipt of the access request from the routing circuitry to connect the selected access control line to a supply voltage; and receipt of the boost signal from the routing circuitry to disconnect the supply voltage from the access con

Abstract: A storage apparatus includes: a plurality of storage sections each of which corresponds to each of a plurality of addresses; a read pointer register that outputs a read pointer indicating an address of a storage section from which data is read; a write pointer register that outputs a write pointer indicating an address of a storage section to which data is written; a control circuit that receives first clock signals of a first frequency and second clock signals of a second frequency that is different from the first frequency, determines selection signals indicating either the first clock signals or the second clock signals on the basis of the read pointer or the write pointer for each of the plurality of storage sections, and outputs the selection signals; and selection circuits selects signals indicated by the selection signals, and outputs the selected signals.

Abstract: A semiconductor memory apparatus includes a clock input unit configured to receive a system clock and a data clock, a data clock phase regulation unit configured to regulate a frequency of the data clock, and delay the data clock by a delay varied in accordance with a training information signal, and a clock phase comparison unit configured to compare a phase of an output clock of the data clock phase regulation unit with a phase of the system clock, and generate the training information signal according to a result of the comparison.

Abstract: Embodiments of the present invention describe a memory device comprising a delay line and a feedback circuit coupled to the delay line. The feedback circuit has the capability to adjust a delay interval, which is then locked on the delay line. The feedback circuit is switched off after the delay interval is locked to reduce power consumption. The feedback circuit periodically switches on to adjust and lock the delay interval.

Abstract: A data capturing device is provided. The data capturing device includes a data capturing device controller and data capturing components. The data capturing device is arranged to send a burst read command. Each of the data capturing components includes a DLL component, a data sampling component, a comparison component, and a valid clock calculation component. The DLL component is arranged to provide clock signals. The data sampling component is arranged to receive a serial data signal that includes a read preamble, where the read preamble includes a training pattern, and to sample the serial data signal with each of the clock signals. The comparison component is arranged to compare each of the sampled data signals with an expected training pattern. The valid clock calculation component is arranged to, based on the comparisons, select one of the clock signals as the valid clock signal for locking the DLL component to.

Abstract: A semiconductor memory device includes: a strobe signal reception unit configured to receive a strobe signal and generate a tracking clock signal; a clock reception unit configured to receive a clock signal and generate an internal clock signal; a plurality of data reception units configured to receive parallel data in accordance with the internal clock signal and generate internal data; and a phase control unit configured to control the phase of the internal clock signal to track the tracking clock signal and to compensate for a variation in the phase of the internal clock signal while the data is received.

Abstract: A semiconductor memory apparatus includes a clock control unit configured to receive a first clock when an enable signal is activated and generate a second clock which has a cycle closer in length to a target clock cycle than the first clock; a DLL input clock generation unit configured to output one of the first clock and the second clock as a DLL input clock according to a DLL select signal; and an address/command input clock generation unit configured to output one of the first clock and the second clock as an AC input clock according to the enable signal.

Abstract: A method for generating a variable pulse width signal on an integrated circuit (IC) chip, includes receiving a first clock signal on the IC chip and receiving a second clock signal on the IC chip having a variable delay relative to the first clock signal. A signal having a rising edge triggered by a rising edge of the first clock signal and a falling edge triggered by a rising edge of the second clock signal is output. The output signal is provided to circuitry on the chip, such as a magnetoresistive junction (MTJ) cell of a spin torque transfer magnetic random access memory (STT-MRAM).

Abstract: A semiconductor device includes a clock input block to receive a system clock and a data clock, a clock frequency dividing block to generate a plurality of multi-phase data frequency division clocks each of which has the phase difference of a predetermined size by dividing a frequency of the data clock and to determine whether or not phases of the plurality of multi-phase data frequency division clocks are reversed in response to a frequency division control signal, and a first phase detecting block to detect a phase of the system clock based on a phase of a first selected clock that is predetermined among the plurality of multi-phase data frequency division clocks and to determine a logic level of the frequency division control signal in response to the detected result.

Abstract: A semiconductor device for applying an auto clock alignment training mode to reduce the time required for a clock alignment training operation. The semiconductor device adjusts the entry time of the auto clock alignment training mode to prevent the clock alignment training operation from malfunctioning. The semiconductor device includes a clock division block configured to divide a data clock to generate a data division clock, a phase multiplex block configured to generate a plurality of multiple data division clocks in response to the data division clock, a logic level control block configured to set a period, in which a division control signal is changeable, depending on the data division clock, and a first phase detection block configured to detect a phase of a system clock on the basis of the multiple data division clocks in the period, and to generate the division control signal corresponding to a detection result.

Abstract: Memories, multi-phase clock signal generators, and methods for generating multi-phase duty cycle corrected clock signals are disclosed. For example, one such clock signal generator includes a delay-locked loop having a first multi-tap adjustable delay line configured to delay a reference signal to provide a plurality of clock signals having different phases relative to the reference clock signal. A periodic signal generated by the delay-locked loop is provided to a second multi-tap adjustable delay line as an input clock signal. Clock signals from taps of the second multi-tap adjustable delay line are provided as the multi-phase duty cycle corrected clock signals.

Abstract: A semiconductor device includes a system clock input unit configured to receive a system clock for synchronizing input times of an address signal and a command signal from a memory controller, a data clock input unit configured to receive first and second data clocks for synchronizing an input/output time of a data signal from the memory controller, wherein a phase of the second data clock is shifted according to a training information signal, and the second data clock having the shifted phase is inputted to the data clock input unit, and a phase detection unit configured to detect a logic level of the second data clock based on an edge of the first data clock, and generate the training information signal to transmit the generated signal to the memory controller according to the detected logic level.

Abstract: A semiconductor device includes a system clock input unit configured to receive a system clock for synchronizing input times of an address signal and a command signal from a memory controller, a data clock input unit configured to receive first and second data clocks for synchronizing an input/output time of a data signal from the memory controller, wherein a phase of the second data clock is shifted according to a training information signal, and the second data clock having the shifted phase is inputted to the data clock input unit, and a phase detection unit configured to detect a logic level of the second data clock based on an edge of the first data clock, and generate the training information signal to transmit the generated signal to the memory controller according to the detected logic level.

Abstract: A high voltage generation circuit includes a clock logic unit configured to generate a switch clock signal and a pump clock signal, that has a varying frequency, in response to an input signal, a high voltage unit configured to generate a high voltage in response to the pump clock signal, a high voltage switch configured to output a selection signal in response to the switch clock signal, and a switching element configured to transfer the high voltage, generated by the high voltage unit, to an output node in response to the selection signal.

Abstract: To provide a counter circuit capable of accurately counting a high-frequency signal in which hazard or the like is easily generated. There are provided: a frequency dividing circuit that generates first and second frequency dividing clocks, which differ in phase to each other, based on a clock signal; a first counter that counts the first frequency dividing clock; a second counter that synchronizes with the second frequency dividing clock to fetch a count value of the first counter; and a selection circuit that exclusively selects count values of the first and second counters. According to the present invention, a relation of the count values between the first and second counters is kept always constant, and thus, even when hazard occurs, the count values are only made to jump and the count values do not fluctuate.

Abstract: Examples of command latency systems and methods are described. In some examples, phase information associated with a received command signal is stored, a received command signal is propagated through a reduced clock flip-flop pipeline and the delayed command signal is combined with the stored phase information. The reduced clock flip-flop pipeline may use a clock having a lower frequency than that used to issue the command signal. Accordingly, fewer flip-flops may be required.

Abstract: A nonvolatile memory apparatus includes a memory device having a configuration information storage block for storing a first configuration data group and a second configuration data group having fewer bits than the first configuration data group and a configuration information processing circuit configured to determine a majority of the first configuration data group outputted from the memory device, during a first period of a power-up operation, and determine a majority of the second configuration data group outputted from the memory device, during a second period after the first period.

Abstract: A semiconductor memory device includes output enable signal generation means configured to be reset in response to an output enable reset signal, count a DLL clock signal and an external clock signal, and generate an output enable signal in correspondence to a read command and an operating frequency; and activation signal generation means configured to generate an activation signal for inactivating the output enable signal generation means during a write operation interval.

Abstract: An asynchronously pipelined SDRAM has separate pipeline stages that are controlled by asynchronous signals. Rather than using a clock signal to synchronize data at each stage, an asynchronous signal is used to latch data at every stage. The asynchronous control signals are generated within the chip and are optimized to the different latency stages. Longer latency stages require larger delays elements, while shorter latency states require shorter delay elements. The data is synchronized to the clock at the end of the read data path before being read out of the chip. Because the data has been latched at each pipeline stage, it suffers from less skew than would be seen in a conventional wave pipeline architecture. Furthermore, since the stages are independent of the system clock, the read data path can be run at any CAS latency as long as the re-synchronizing output is built to support it.

Abstract: Memories, clock synchronization circuits, clock synchronization controller circuits, and methods for setting a voltage controlled delay of a clock synchronization circuit and tracking and recording the control voltage are disclosed. For example, a clock synchronization controller provides an initial control voltage to the voltage controlled delay during initialization of the synchronization circuit until a phase dependent control voltage stabilizes. The stable phase dependent control voltage is substituted for the initial control voltage. Following stabilization of the phase dependent control voltage, a phase detector of the clock synchronization circuit is activated. A recovery control voltage is provided by the clock synchronization controller to the voltage controlled delay during recovery of the clock synchronization from a power-saving mode until the phase dependent control voltage stabilizes.

Abstract: An operation guarantee system includes a decoder circuit, a comparison circuit, a CPU circuit, a frequency adjustment circuit and a DQ adjustment circuit. The comparison circuit compares a test data signal input from the decoder circuit with an expected value data signal input from the exterior, and detects the presence or absence of an output error in the decoder circuit. The CPU circuit controls the frequency adjustment circuit and the DQ adjustment circuit to vary a frequency of a clock signal input to an external memory and a delay amount of the data signal. In addition, the CPU circuit acquires a result of detection of the comparison circuit under various conditions. Then, the CPU circuit determines an appropriate frequency of the clock signal input to the external memory based on a relationship between the various conditions and the presence or absence of the output error.

Abstract: A three-dimensional (3D) semiconductor device may include a stack of chips, including a master chip and one or more slave chips. I/O connections of slave chips need not be connected to channels on a motherboard, and only electrode pads of a master chip may be connected to the channels. Only the master chip may provide a load to the channels. A through-substrate via (TSV) boundary may be set on a data input path, a data output path, an address/command path, and/or a clock path of a semiconductor device in which the same type of semiconductor chips are stacked.

Abstract: A semiconductor memory device can output data according to a predetermined data output timing, in spite of a high frequency of system clock, even when a delay locked loop is disabled. The semiconductor memory device includes a delay locked loop configured to perform a delay locking operation on an internal clock to output delay locked clock, and a data output control unit configured to determine a data output timing, according to whether the delay locked loop is enabled or disabled, in response to a read command.

Abstract: A semiconductor device includes a system clock input unit configured to receive a system clock for synchronizing input times of an address signal and a command signal from a memory controller, a data clock input unit configured to receive first and second data clocks for synchronizing an input/output time of a data signal from the memory controller, wherein a phase of the second data clock is shifted according to a training information signal, and the second data clock having the shifted phase is inputted to the data clock input unit, and a phase detection unit configured to detect a logic level of the second data clock based on an edge of the first data clock, and generate the training information signal to transmit the generated signal to the memory controller according to the detected logic level.

Abstract: A semiconductor memory device includes: plural bit lines connected with plural memory cells, respectively; plural transfer lines allocated in common to the plural bit lines; sense amplifiers (SA1) and (SA2) connected to these transfer lines, respectively; and a control circuit making the sense amplifier (SA2) perform a converting operation during an amplifying operation performed by the sense amplifier (SA1). Because the plural sense amplifiers are allocated to the same bit lines, and these are operated in parallel in this way, data can be read at a high speed.

Abstract: A latency circuit for use in a semiconductor memory device includes a latency control clock generator generating an m-divided division signal from an external clock and at least one latency control clock from the m-divided division signal, wherein m is a natural number greater than or equal to 2. The latency circuit also includes a latency signal generator generating a latency signal in response to the at least one latency control clock, a latency control signal and an internal read command signal, wherein the latency control signal is generated from a column address strobe (CAS) latency and the internal read command signal is generated in response to a received read command.

Abstract: Examples described include memory units coupled to a controller using a daisy chain wiring configuration. A filter located between a first memory unit and the controller attenuates a particular frequency, which may improve ringback in a signal received at the memory units. In some examples, a quarter-wavelength stub is used to implement the filter. In some examples, signal components at 800 MHz may be attenuated by a stub, which may improve ringback.

Abstract: A signal capture system and method is used to capture a data signal using a data strobe signal having a preamble of strobe signal transitions. The system includes a data latch circuit receiving the data signal. The data latch circuit is clocked by transitions of the data strobe signal to capture respective bits of data corresponding to the data signal. A decoder receives a memory command signal and generates a data start signal after a delay period from receiving the memory command signal if the command signal corresponds to a read or a write command. The receipt of read or write command signals is used by a control circuit to identify the start of valid read or write data signals. The control circuit then outputs the captured data signals responsive to the data start signal, thereby ignoring the transitions in the preamble of the data strobe signal.

Abstract: A clock control circuit includes a first clock buffer configured to toggle a first clock signal when a self-refresh exit command signal is inputted during a self-refresh operation; and a second clock buffer configured to toggle a second clock signal when the self-refresh operation is finished, the second clock being provided to internal circuits.