A semiconductor device includes an internal clock generation circuit configured to generate an internal clock; a plurality of unit circuits configured to have a first unit circuit and a second unit circuit operating while being synchronized with an internal clock; a plurality of transfer circuits including a first transfer circuit configured to provide a first transfer path having a first delay time, and a second transfer circuit configured to provide a second transfer path having a second delay time different from the first delay time; and a delay compensation circuit configured to compare a first clock input to the first unit circuit through the first transfer path with a second clock input to the second unit circuit through the second transfer path, and to adjust the second delay time so that the adjusted second delay time matches the first delay time.

A semiconductor system including: an operation period adjusting circuit configured to generate operation information for adjusting an operation period, when an input count of an active command during a test mode period is equal to or more than a preset count; and a command generation circuit configured to adjust the input count of the active command applied to a semiconductor device during a preset period, by adjusting the operation period on the basis of the operation information.

According to one embodiment, a semiconductor storage device includes strings each with a first select transistor, memory cell transistors, and a second select transistor connected in series. Word lines are provided, each connected to memory cell transistors in a same position across the strings. A bit line is connected in common to a first end of each of the strings. A source line is connected in common to a second end of each of the strings. A control circuit is configured to perform an erase operation on strings. The control circuit adjusts, for each of the strings, either an application time of a first voltage applied to a gate of the first select transistor of the respective string in the erase operation or a voltage level of the first voltage applied to the gate of the first select transistor of the respective string in the erase operation.

A semiconductor memory device includes a quadrature error correction circuit, a clock generation circuit and a data input/output (I/O) buffer. The quadrature error correction circuit performs a locking operation to generate a first corrected clock signal and a second corrected clock signal by adjusting a skew and a duty error of a first through fourth clock signals generated based on a data clock signal and performs a relocking operation to lock the second corrected clock signal to the first corrected clock signal in response to a relock signal. The clock generation circuit generates an output clock signal and a strobe signal based on the first corrected clock signal and the second corrected clock signal. The data I/O buffer generates a data signal by sampling data from a memory cell array based on the output clock signal and transmits the data signal and the strobe signal to a memory controller.

A semiconductor device includes: a first transfer path outputting a first preliminary signal; a second transfer path outputting a second preliminary signal; a third transfer path outputting a third preliminary signal; a first calibration circuit generating a first calibration code corresponding to a difference in delay values between the first transfer path and a selected transfer path having a largest delay value among the first to third transfer paths; a second calibration circuit generating a second calibration code corresponding to a difference in delay values between the second transfer path and the selected transfer path; a third calibration circuit generating a third calibration code corresponding to a difference in delay values between the third transfer path and the selected transfer path; a first delay control circuit generating a first signal; a second delay control circuit generating a second signal; and a third delay control circuit generating a third signal.

A memory system includes a memory medium and a memory controller configured to control the memory medium. The memory controller includes a training core and a training block. The training core is configured to detect a delay time of a clock signal to generate a delay selection signal during a training operation for the memory medium. The training block is configured to generate a delayed clock signal which is delayed by a time period set according to the delay selection signal outputted from the training core.

A method of operating a memory device comprises generating a target voltage using a pump circuit of the memory device, the target voltage to be applied to a word line or pillar of a memory cell of the memory device; providing an indication of current generated by the pump circuit after the pump circuit output reaches the target voltage; and determining when the current generated by the pump circuit is greater than a specified threshold current and generating a fault indication according to the determination.

Examples herein relate to devices that include a strobe tree circuit for capturing data using a memory-sourced strobe. In an example, a device includes a data capture path including first and second flip-flops, and a strobe tree including a comparator and first and second multiplexers. The comparator is configured to output complementary signals on first and second output nodes. First and second selection input nodes of the first multiplexer are connected to the first and second output nodes of the comparator, respectively. First and second selection input nodes of the second multiplexer are connected to the second and first output nodes of the comparator, respectively. The read strobe tree is configured to provide first and second signals output from the first and second multiplexers to first and second nodes, respectively. Clock input nodes of the first and second flip-flops are connected to the first and second nodes, respectively.

A first power-supply voltage is applied to I/O cells, an I/O cell connected to a clock terminal is initially set to a threshold of a second voltage signaling, an I/O cell connected to a command terminal and I/O cells connected to data terminals are initially set as an input, and when a clock control unit detects receipt of one clock pulse and a signal voltage control unit detects a host using the second voltage signaling, a signal voltage control unit drives the I/O cell of a first data terminal high level after a second power-supply voltage is applied to I/O cells and the threshold of a second voltage signaling is set to I/O cells of the clock, command and data terminals.

A memory temperature controlling method and a memory temperature controlling system are provided. The method includes: performing, by a testing equipment, test modes on a memory storage device, and obtaining a first internal temperature of a memory control circuit unit, a second internal temperature of each memory package and a surface temperature of each memory package to establish a linear relationship expression of the first internal temperature, the second internal temperature and the surface temperature; using, by the memory storage device, the linear relationship expression to calculate a predicted surface temperature of a rewritable non-volatile memory based on a first current internal temperature of the memory control circuit unit and a second current internal temperature of each memory package; adjusting, by the memory storage device, an operating frequency for accessing the rewritable non-volatile memory based on the predicted surface temperature.