A semiconductor device may include: a first receiver configured to receive a chip select signal from a receiving node to which a termination resistor is coupled and configured to generate a first internal chip select signal; a command pulse generation circuit configured to generate a command pulse for entering into a self-refresh operation based on an internal command address and the first internal chip select signal; and an operation control circuit configured to, when the semiconductor device enters the self-refresh operation based on the command pulse, generate a resistor value change signal that adjusts the value of the termination resistor.

A method and memory device of controlling a plurality of low power states are provided. The method includes: entering a low power mode state, in which memory cell rows of the memory device are refreshed and power consumption is lower than in a self-refresh mode state, in response to a low power state entry command; and exiting the low power mode state based on a low power mode exit latency time that is set in a mode register of the memory device or at least one of an alarm signal and a low power mode exit command.

A system and method for use in dynamic random-access memory (DRAM) comprising entering into a self-refresh mode of operation, exiting the self-refresh mode of operation in response to commands from a self-refresh state machine memory operation (MOP) array, and updating a device state of the DRAM for a target power management state in response to commands from the MOP array.

In one form, a memory controller includes a controller and a memory operation array. The controller has an input for receiving a power state change request signal and an output for providing memory operations. The memory operation array comprises a plurality of entries, each entry comprising a plurality of encoded fields. The controller is responsive to an activation of the power state change request signal to access the memory operation array to fetch at least one entry, and to issue at least one memory operation indicated by the entry. In another form, a system comprises a memory system and a processor coupled to the memory system. The processor is adapted to access the memory module using such a memory controller.

A power control circuit includes a power control signal generation circuit configured to generate a voltage control signal according to a deep sleep command for operating a semiconductor apparatus in a deep sleep mode; a voltage divider circuit having a division ratio that is changed according to the voltage control signal, and configured to generate a divided voltage by dividing an internal voltage at the changed division ratio; a comparator configured to generate a detection signal by comparing a reference voltage to the divided voltage; an oscillator configured to generate an oscillation signal according to the detection signal; and a pump configured to generate the internal voltage according to the oscillation signal.

A memory system including a plurality of dynamic random access memory (DRAM) devices and a DRAM controller is provided. The plurality of DRAM devices includes one or more DRAM groups. Each of the one or more DRAM groups includes at least two DRAM devices. The DRAM controller outputs a clock enable signal, and controls a selection signal used to select a target DRAM device that operates in a normal mode in response to the clock enable signal. At least one target DRAM device is selected from the one or more DRAM groups. One or more stand-by DRAM devices other than the at least one target DRAM device operates in a self-refresh mode.

An image processing apparatus having a plurality of functional units that respectively execute predetermined functions, a method of controlling the apparatus, the apparatus manages a memory with a plurality of areas, and allocates the plurality of areas of the memory to the plurality of functional units respectively. Then, when, in a power saving state, at least one of the plurality of functional units is caused to transition into a power saving state, the apparatus stops a refreshing of the area of the memory allocated to the functional unit that is caused to transition into the power saving state.

Systems, methods, and computer programs are disclosed for method for reducing memory subsystem power. In an exemplary method, a system resource manager provides memory performance requirements for a plurality of memory clients to a double data rate (DDR) subsystem. The DDR subsystem and the system resource manager reside on a system on chip (SoC) electrically coupled to a dynamic random access memory (DRAM). A cache hit rate is determined of each of the plurality of memory clients associated with a system cache residing on the DDR subsystem. The DDR subsystem controls a DDR clock frequency based on the memory performance requirements received from the system resource manager and the cache hit rates of the plurality of memory clients.

Various implementations described herein are directed to an integrated circuit. The integrated circuit may include a memory cell configured to operate in multiple retention states including a static retention state and a dynamic retention state. The integrated circuit may include a controller configured to selectively apply different voltage levels to the memory cell based on the retention state of the memory cell.

Disclosed herein is an apparatus that includes a first semiconductor chip including a memory cell array having a volatile memory cell and an access control circuit configured to perform a refresh operation on the volatile memory cell, and a second semiconductor chip including a power generator configured to supply a first power supply voltage to the first semiconductor chip. The access control circuit is configured to activate a first enable signal during the refresh operation. The second semiconductor chip is configured to change a capability of the power generator based on the first enable signal.