A memory device includes a first on-die termination circuit, a second on-die termination circuit, a voltage generator, and a code generator. The first on-die termination circuit may correspond to a data input buffer. The second on-die termination circuit may correspond to a command/address buffer. The voltage generator may generate a reference voltage. The code generator may generate a resistance calibration code of a selected one of the on-die termination circuits in response to the reference voltage. The reference calibration code may calibrate a resistance value of the selected on-die termination circuit.

A memory device includes a first on-die termination circuit, a second on-die termination circuit, a voltage generator, and a code generator. The first on-die termination circuit may correspond to a data input buffer. The second on-die termination circuit may correspond to a command/address buffer. The voltage generator may generate a reference voltage. The code generator may generate a resistance calibration code of a selected one of the on-die termination circuits in response to the reference voltage. The reference calibration code may calibrate a resistance value of the selected on-die termination circuit.

A memory control circuit unit, a memory storage device and a signal receiving method. In one exemplary embodiment, a memory interface circuit of the memory control circuit unit receives a first signal from a volatile memory and adjusts a voltage value of the first signal to a voltage range in response to an internal impedance of the memory interface circuit, where a central value of the voltage range is not equal to a default voltage value, and the default voltage value is one half a sum of a voltage value of a supply voltage of the memory interface circuit and a voltage value of a reference ground voltage. In addition, the memory interface circuit further generates an input signal according to a voltage correspondence between the first signal and an internal reference voltage.

A memory control circuit unit, a memory storage device and a signal receiving method. In one exemplary embodiment, a memory interface circuit of the memory control circuit unit receives a first signal from a volatile memory and adjusts a voltage value of the first signal to a voltage range in response to an internal impedance of the memory interface circuit, where a central value of the voltage range is not equal to a default voltage value, and the default voltage value is one half a sum of a voltage value of a supply voltage of the memory interface circuit and a voltage value of a reference ground voltage. In addition, the memory interface circuit further generates an input signal according to a voltage correspondence between the first signal and an internal reference voltage.

A non-volatile semiconductor memory device and a driving method for word lines thereof are provided. A flash memory of the invention includes a memory cell array including blocks and a block selection element selecting the block of the memory cell array based on row address information and including a block selection transistor, a level shifter, a boost circuit and a voltage supplying element. The block selection transistor is connected to each word line of the block. The level shifter supplies a voltage to a node connected to a gate of the block selection transistor. The boost circuit boosts a potential of the node. The voltage supplying element supplies an operation voltage to one of the terminals of the block selection transistor. The node, after performing first boosting by the operating voltage supplied by the supplying element, performs second boosting by the second circuit.

A non-volatile semiconductor memory device and a driving method for word lines thereof are provided. A flash memory of the invention includes a memory cell array including blocks and a block selection element selecting the block of the memory cell array based on row address information and including a block selection transistor, a level shifter, a boost circuit and a voltage supplying element. The block selection transistor is connected to each word line of the block. The level shifter supplies a voltage to a node connected to a gate of the block selection transistor. The boost circuit boosts a potential of the node. The voltage supplying element supplies an operation voltage to one of the terminals of the block selection transistor. The node, after performing first boosting by the operating voltage supplied by the supplying element, performs second boosting by the second circuit.

Methods, systems, and devices for operating a ferroelectric memory cell or cells are described. A memory array may be operated in a half density mode, in which a subset of the memory cells is designated as reference memory cells. Each reference memory cell may be paired to an active memory cell and may act as a reference signal when sensing the active memory cell. Each pair of active and reference memory cells may be connected to a single access line. Sense components (e.g., sense amplifiers) associated with reference memory cells may be deactivated in half density mode. The entire memory array may be operated in half density mode, or a portion of the array may operate in half density mode and the remainder of the array may operate in full density mode.

Embodiments herein describe a memory system that includes a DRAM module with a plurality of individual DRAM chips. In one embodiment, the DRAM chips are per DRAM addressable (PDA) so that each DRAM chip can use a respective reference voltage (VREF) value to decode received data signals (e.g., DQ or CA signals). During runtime, the VREF value can drift away from its optimal value set when the memory system is initialized. To address possible drift in VREF value, the present embodiments perform VREF calibration dynamically. To do so, the memory system monitors a predefined criteria to determine when to perform VREF calibration. To calibrate VREF value, the memory system may write transmit data and then read out the test data to determine the width of a signal eye using different VREF values. The memory system selects the VREF value that results in the widest signal eye.

Embodiments herein describe a memory system that includes a DRAM module with a plurality of individual DRAM chips. In one embodiment, the DRAM chips are per DRAM addressable (PDA) so that each DRAM chip can use a respective reference voltage (VREF) value to decode received data signals (e.g., DQ or CA signals). During runtime, the VREF value can drift away from its optimal value set when the memory system is initialized. To address possible drift in VREF value, the present embodiments perform VREF calibration dynamically. To do so, the memory system monitors a predefined criteria to determine when to perform VREF calibration. To calibrate VREF value, the memory system may write transmit data and then read out the test data to determine the width of a signal eye using different VREF values. The memory system selects the VREF value that results in the widest signal eye.

A memory circuit includes a bank of non-volatile memory (NVM) devices, a plurality of high-voltage (HV) drivers, a global HV power switch configured to generate a HV power signal, and a plurality of HV power switches coupled to the global HV switch. A first HV power switch of the plurality of HV power switches is coupled to each HV driver of the plurality of HV drivers, the first HV power switch of the plurality of HV power switches is configured to output a power signal responsive to the HV power signal, and each HV driver of the plurality of HV drivers is configured to output a HV activation signal to a corresponding column of the bank of NVM devices responsive to the power signal.