This application provides a memory training method, a memory controller, a processor, and an electronic device. The memory controller keeps transmission delays of N DQs unchanged, adjusts a transmission delay of a DQS, and determines a maximum DQS transmission delay and/or a minimum DQS transmission delay of the DQS when all data carried in the N DQs is correctly transmitted. The memory controller adjusts the transmission delay of the DQS to a target DQS transmission delay between the maximum DQS transmission delay and the minimum DQS transmission delay. The method helps quickly align relative timing positions between the DQS and the N DQs. Therefore, memory training may be repeatedly performed in a working process of the processor, so that the N DQs keep enough timing margins.

A memory system includes memory chips connected to each other. Each of the memory chips includes a memory array, a read/write data strobe pin, a look-up table storage device, a chip number identification circuit, and a control logic circuit. The memory array stores data. The read/write data strobe pin is connected to read/write data strobe pins of other memory chips. The look-up table storage device stores a plurality of trimming shift values related to a number of chip connections in advance. The chip number identification circuit identifies a current number of chip connections according to a state information, and finds a selected trimming shift value from the look-up table storage device. The control logic circuit transmits a data signal in response to a clock signal, and adjusts a setup hold time between the clock signal and the data signal according to the selected trimming shift value.

A memory controller instantiated on a semiconductor IC device comprises a timing circuit to transfer a timing signal, the timing circuit being configured to receive a first test signal and to effect a delay in the timing signal in response to the first test signal, the first test signal including a first timing event. The memory controller further comprises an interface circuit configured to transfer the data signal in response to the timing signal, the interface circuit being further configured to receive a second test signal and to effect a delay in the data signal in response to the second test signal, the second test signal including a second timing event that is related to the first timing event according to a test criterion.

A circuit includes a dynamic core data register (DCDR) cell that includes a data register, a shift register and an output circuit to route the output state of the data register or the shift register to an output of the DCDR in response to an output control input. A clock gate having a gate control input controls clocking of the shift register in response to a first scan enable signal. An output control gate controls the output control input of the output circuit and controls which outputs from the data register or the shift register are transferred to the output of the output circuit in response to a second scan enable signal. The first scan enable signal and the second scan enable signal to enable a state transition of the shift register at the output of the DCDR.

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.

Disclosed herein is an apparatus that includes a first semiconductor chip, first and second TSVs penetrating the first semiconductor chip, a first path including the first TSV, a second path including the second TSV, a first charge circuit configured to charge the first path, a second charge circuit configured to charge the second path, a first discharge circuit configured to discharge the first path, a second discharge circuit configured to discharge the second path, and a comparator circuit configured to compare a potential of the first path with a potential of the second path.

Memory devices and systems with adjustable through-silicon via (TSV) delay, and associated methods, are disclosed herein. In one embodiment, an apparatus includes a plurality of memory dies and a TSV configured to transmit signals to or receive signals from the plurality of memory dies. The apparatus further includes circuitry coupled to the TSV and configured to introduce propagation delay onto signals transmitted to or received from the TSV. In some embodiments, the apparatus includes additional circuitry configured to activate, deactivate, adjust at least a portion of the circuitry, or any combination thereof, to alter the propagation delay. In this manner, the apparatus can align internal timings of memory dies of the plurality of memory dies.

A memory device in which reliability of a clock signal is improved is provided. The memory device comprises a data module including a clock signal generator configured to receive an internal clock signal from a buffer, and to generate a first internal clock signal, a second internal clock signal, a third internal clock signal, and a fourth internal clock signal having different phases, on the basis of the internal clock signal, and a first data signal generator configured to generate a first data signal on the basis of first data and the first internal clock signal, generate a second data signal on the basis of second data and the second internal clock signal, generate a third data signal on the basis of third data and the third internal clock signal, and generate a fourth data signal on the basis of fourth data and the fourth internal clock signal.

A processing device in a memory system determines a first error rate corresponding to a first set of write-to-read delay times at a first end of a range of write-to-read delay times for a memory device and a second error rate corresponding to a second set of write-to-read delay times at a second end of the range of write-to-read delay times, and determines whether a ratio of the first error rate to the second error rate satisfies a threshold criterion. Responsive to the ratio of the first error rate to the second error rate not satisfying the threshold criterion, the processing device adjusts a read voltage level associated with the range of write-to-read delay times

A memory device includes at least one first register, a memory circuit, an analyzing circuit, and a control circuit. The memory circuit includes a plurality of bit cells. The analyzing circuit is configured to perform an analyzing process on the bit cells to generate an analyzing result. If the analyzing result indicates that a first bit cell of the bit cells fails, the control circuit establishes a repair process by controlling data to be written into the at least one first register and controlling the data to be read out from the at least one first register.