A memory device includes a word line driver. The word line driver is coupled through word lines to an array of bit cells. The word line driver includes a first driving circuit, a second driving circuit and a modulating circuit. The first driving circuit and the second driving circuit are configured to select a word line. The modulating circuit is coupled through the selected word line to the first driving circuit and the second driving circuit, and is configured to modulate at least one signal transmitted through the selected word line. The first driving circuit and the second driving circuit are further configured to charge the selected word line to generate a first voltage signal and a second voltage signal at two positions of the selected word line. The first voltage signal is substantially the same as the second voltage signal. A method is also disclosed herein.

Various implementations described herein are related to a device with a wordline driver that provides a wordline signal to a wordline based on a row selection signal and a row clock signal. The device may have row selector logic that provides the row selection signal to the wordline driver based on first input signals in a periphery voltage domain. The device may also have level shifter circuitry that provides the row clock signal to the wordline driver in a core voltage domain based on second input signals in the periphery voltage domain.

A clock mode configuration circuit for a memory device is described. A memory system includes any number of memory devices serially connected to each other, where each memory device receives a clock signal. The clock signal can be provided either in parallel to all the memory devices or serially from memory device to memory device through a common clock input. The clock mode configuration circuit in each memory device is set to a parallel mode for receiving the parallel clock signal, and to a serial mode for receiving a source synchronous clock signal from a prior memory device. Depending on the set operating mode, the data input circuits will be configured for the corresponding data signal format, and the corresponding clock input circuits will be either enabled or disabled. The parallel mode and the serial mode is set by sensing a voltage level of a reference voltage provided to each memory device.

The present disclosure provides embodiments for methods and memory devices. One embodiment of a memory device includes a first volatile memory cell having a first volatile access transistor with a current electrode coupled with a first volatile bit line; a first non-volatile memory cell having a first non-volatile access transistor with a current electrode coupled with a first non-volatile bit line; and a transfer circuit coupled between the first volatile bit line and the first non-volatile bit line. The transfer circuit is configured to: couple data latched from the first volatile bit line with the first non-volatile bit line during a store operation, and couple the first volatile bit line with the first non-volatile bit line during a restore operation.

Apparatuses, memories, and methods for decoding memory addresses for selecting access lines in a memory are disclosed. An example apparatus includes an address decoder circuit coupled to first and second select lines, a polarity line, and an access line. The first select line is configured to provide a first voltage, the second select line is configured to provide a second voltage, and the polarity line is configured to provide a polarity signal. The address decoder circuit is configured to receive address information and further configured to couple the access line to the first select line responsive to the address information having a combination of logic levels and the polarity signal having a first logic level and further configured to couple the access line to the second select line responsive to the address information having the combination of logic levels and the polarity signal having a second logic level.

A memory circuit comprises an array of data storage elements; access circuitry to access a data bit, stored by a data storage element enabled for access, by an access signal for that data storage element; and control circuitry to enable groups of data storage elements for access, the groups having a group size, the group size being one or more, the access signals for data storage elements in a group being combined to provide a combined access signal common to that group of data storage elements; the control circuitry being configured to selectively operate in at least a first mode and a second mode, the group size in the first mode being different to the group size in the second mode.

A semiconductor storage device has a non-volatile memory, a memory controller to carry out write processing to the non-volatile memory using a write pulse, and a write pulse controller to select one of a first write mode for writing to the non-volatile memory and a second write mode for writing to the non-volatile memory with higher electric power consumption than the first write mode at higher speed than the first write mode and, when the first write mode is selected, set a pulse width of the write pulse such that the pulse width is shorter than one cycle of a clock signal used to control access to the non-volatile memory,

A voltage switching apparatus includes a plurality of high voltage switching circuits operable in response to a single control signal, and suitable for pumping a voltage level of a switching signal to a target level based on the voltage level of the switching signal and a common control unit suitable for generating the single control signal.

A semiconductor device, semiconductor system, and system may be provided. The semiconductor system may include one semiconductor device of a first semiconductor device and a second semiconductor device suitable for transmitting and receiving addresses and encrypted data. The one semiconductor device may include an address output circuit configured to output the addresses. The one semiconductor device may include an encryption circuit configured to output the encrypted data based on normal data and the addresses. The one semiconductor device may include a decryption circuit configured to output the normal data based on the addresses and the encrypted data.

A semiconductor device, semiconductor system, and system may be provided. The semiconductor system may include one semiconductor device of a first semiconductor device and a second semiconductor device suitable for transmitting and receiving addresses and encrypted data. The one semiconductor device may include an address output circuit configured to output the addresses. The one semiconductor device may include an encryption circuit configured to output the encrypted data based on normal data and the addresses. The one semiconductor device may include a decryption circuit configured to output the normal data based on the addresses and the encrypted data.