Provided are a memory device detecting a defect and an operating method thereof. The memory device includes a memory cell area including a memory cell array that stores data, and a peripheral circuit area including a control logic configured to control operations of the memory cell array, wherein the peripheral circuit area further includes a defect detection circuit, the defect detection circuit being configured to generate a count result value by selecting a first input signal from a plurality of input signals and counting at least one time interval of the first input signal based on a clock signal, and to detect a defect of the first input signal by comparing an expected value with the count result value, and the at least one time interval is a length of time in which logic low or logic high is maintained.

An apparatus with a memory array having a plurality of memory cells. The apparatus also including a memory built-in self-test circuit to test the memory array. The memory built-in self-test circuit includes one or more processing devices to write a data pattern to one or more memory cells to be tested in the memory array, pause for a time period corresponding to a predetermined pause time setting, and read the written data pattern from the one or more memory cells after the time period has elapsed. The predetermined pause time setting is automatically adjusted based on memory device conditions, which can include the temperature of the apparatus.

Methods of optimizing the placement of memories in a memory device including a substrate and an electrical component, and associated devices and systems, are disclosed herein. A representative method includes first testing the memories to determine at least one parameter for each of the memories indicating an ability of the memory to process signals from the electrical component. The method can further include labeling each memory with a label based on the parameter, the labels including at least a first label and a second label. The first label can indicate that the memories with the first label are better able to process signals from the electrical component than the memories with the second label. The method can further include electrically coupling the memories to the substrate such that the memories with the second label are positioned closer to the electrical component than the memories with the first label.

A resistor-capacitor (RC) sensor circuit includes an integration capacitor configured to integrate a representative copy of a current that drives an electronic circuit line. The integration capacitor is configured to integrate over a first time period to generate a first representative voltage and over a second time period to generate a second representative voltage. The RC sensor circuit includes a sampling circuit coupled to the integration capacitor and configured to sample the first representative voltage and the second representative voltage. A ratio of the first sampled voltage and the second sampled voltage is indicative of an RC time constant of the electronic circuit line.

Methods and apparatuses for improve data clock to reduce power consumption are presented. The apparatus includes a memory configured to receive a data clock from a host via a link and to synchronize the data clock with the host. The memory includes a clock tree buffer configured to toggle based on the data clock to capture write data or to output read data and a command decoder configured to detect a data clock suspend command while the data clock is synchronized between the host and the memory. The clock tree buffer is configured to disable toggling based on the data clock in response to the command decoder detecting the data clock suspend command. the host includes a memory controller configured to provide a data clock suspend command to the memory via the link while the data clock is synchronized between the host and the memory.

A signal processing circuit includes a delay locked loop (DLL) circuit, a data output path circuit, and a first phase detector circuit. The DLL circuit is arranged to receive a memory clock signal, and generate a DLL output signal according to the memory clock signal and a DLL feedback signal. The data output path circuit is coupled to the DLL circuit, and is arranged to generate a DQS signal according to the DLL output signal. The first phase detector circuit is coupled to the data output path circuit, and is arranged to receive the memory clock signal and the DQS signal, and detect a phase difference between the memory clock signal and the DQS signal to generate a first phase detection result.

An apparatus includes a nonvolatile semiconductor memory device storing identification information and first setting information on an output signal, a memory holding identification information of nonvolatile semiconductor memory devices, the identification information including the identification information of the nonvolatile semiconductor memory device, and setting information on an output signal associated with the identification information of the nonvolatile semiconductor memory devices, the setting information including at least second setting information on the output signal, and a processor acquiring the identification information of the nonvolatile semiconductor memory.

According to one embodiment, a memory system includes a memory interface circuit. The memory interface circuit has delay circuits, a detection circuit, and a control circuit. One of the delay circuits applies a delay to a data signal. Another delay circuit generates, fora strobe signal, a first delay strobe signal, a second delay strobe signal, and a third delay strobe signal, each with different delay amounts. The detection circuit detects a drift in the timing of the first delay strobe signal with respect to the delayed data signal by using the delay data signal, the first delay strobe signal, the second delay strobe signal, and the third delay strobe signal. The control circuit adjusts the first delay amount, the second delay amount, and the third delay amount in a direction to compensate the drift.

A memory device, and an operating method of the memory device and a host device are provided. The method of operating a memory device includes receiving a command for requesting an Eye Open Monitor (EOM) operation performance from a host device, receiving pattern data including data and non-data from the host device, performing the EOM operation which performs an error count to correspond to the data, and does not perform the error count on the non-data, and transmitting an EOM response signal including the error count result to the host device.

A memory system includes: a plurality of memory dies, and a controller selects a second read request, including at least a portion of a plurality of first read requests, so that the memory dies interleave and output data corresponding to the first read requests, and performs a correlation operation for the selected second read request, when the second read request is selected, the controller determines whether the correlation operation is performed or not before a time at which the second read request is selected, determines whether the correlation operation is successful or not, determines a pending credit in response to an operation state of the memory dies at the time at which the second read request is selected, and determines whether to perform the correlation operation or not for the second read request that is selected at the time at which the second read request is selected based on the pending credit.