A computer memory system includes an electro-optical chip, an electrical fanout chip electrically connected to an electrical interface of the electro-optical chip, and at least one dual in-line memory module (DIMM) slot electrically connected to the electrical fanout chip. A photonic interface of the electro-optical chip is optically connected to an optical link. The electro-optical chip includes at least one optical macro that converts outgoing electrical data signals into outgoing optical data signals for transmission through the optical link. The optical macro also converts incoming optical data signals from the optical link into incoming electrical data signals and transmits the incoming electrical data signals to the electrical fanout chip. The electrical fanout chip directs bi-directional electrical data communication between the electro-optical chip and a dynamic random access memory (DRAM) DIMM corresponding to the at least one DIMM slot.

A supply voltage sensitivity of an output current of a bias current generator circuit is reduced. The bias current generator includes a plurality of transistors and a plurality of resistors coupled to the plurality of transistors. The supply voltage sensitivity of the output current of the bias current generator circuit is reduced by applying a second bias current generated by the bias current generator circuit to a first bias current generated by the bias current generator circuit.

A memory circuit includes a pre-charging circuit and a control circuit. The pre-charging circuit includes a first pre-charging unit, a second pre-charging unit, a first power supply terminal, a second power supply terminal, a first control terminal, a second control terminal and a data terminal; the first pre-charging unit is connected with the first power supply terminal, the first control terminal and the data terminal; the second pre-charging unit is connected with the second power supply terminal, the second control terminal and the data terminal. The control circuit is configured to in response to a memory being in a row active state and not performing a reading-writing operation, control, through the second pre-charging unit, the data terminal and the second power supply terminal to be disconnected, and control, through the first pre-charging unit, the data terminal and the first power supply terminal to be disconnected.

A memory circuit includes a pre-charging circuit and a control circuit. The pre-charging circuit includes a first pre-charging unit, a second pre-charging unit, a first power supply terminal, a second power supply terminal, a first control terminal, a second control terminal and a data terminal; the first pre-charging unit is connected with the first power supply terminal, the first control terminal and the data terminal; the second pre-charging unit is connected with the second power supply terminal, the second control terminal and the data terminal. The control circuit is configured to in response to a memory being in a row active state and not performing a reading-writing operation, control, through the second pre-charging unit, the data terminal and the second power supply terminal to be disconnected, and control, through the first pre-charging unit, the data terminal and the first power supply terminal to be disconnected.

The present disclosure describes embodiments of a memory system with a memory cell power supply. The memory system can include a circuit with a first voltage supply, a second voltage supply, pull-up devices, pull-down devices, and pass devices. The first voltage supply is configured to provide a first voltage. The first voltage supply is configured to apply the first voltage to gate terminals of the pass devices. The second voltage supply is electrically coupled to S/D terminals of the pull-up devices and is configured to transition from the first voltage to the second voltage for a read operation.

A variety of applications can include apparatus or methods that provide a well ring for resistive ground power domain segregation. The well ring can be implemented as a n-well in a p-type substrate. Resistive separation between ground domains can be generated by biasing a n-well ring to an external supply voltage. This approach can provide a procedure, from a process standpoint, that provides relatively high flexibility to design for chip floor planning and simulation, while providing sufficient noise rejection between independent ground power domains when correctly sized. Significant noise rejection between ground power domains can be attained.

When a host-slave system including a host device and a slave device transitions to a power-down mode, the host device drives a CMD line in order of a high level, a low level, and a high level, and stops supplying a clock signal after a predetermined time elapses. During a power-down mode period, the slave device stops supplying a power to a back-end module. When the host device resumes the supply of the clock signal, the host-slave system returns from the power-down mode.

A voltage detecting circuit for a non-volatile memory is provided. When a standby signal is not asserted, a power supply unit of the non-volatile memory provides an array voltage to a first node. The voltage detecting circuit includes an initial voltage generator, a capacitor, a latch and a combinational logic circuit. The initial voltage generator receives an inverted standby signal and an enable signal. An output terminal of the initial voltage generator is connected with a second node. The capacitor is coupled between the first node and the second node. An input terminal of the latch is connected with the second node. An output terminal of the latch is connected with a third node. An input terminal of the combinational logic circuit is connected with the third node. An output terminal of the combinational logic circuit generates the enable signal.

Systems and methods described herein may enable memory maintenance operations to be performed on a memory device in compliance with a time interval having a duration based on a temperature of the memory device. A system may include a memory device and a memory controller communicatively coupled to the memory device. The memory controller may receive a temperature measurement indicative of a present temperature of the memory device and determine a memory management interval based on the temperature measurement. The memory controller may perform a memory management operation based on the memory management interval. Sometimes, the memory controller powers on the memory device to perform the memory management operation on the memory device.

Systems and methods described herein may enable memory maintenance operations to be performed on a memory device in compliance with a time interval having a duration based on a temperature of the memory device. A system may include a memory device and a memory controller communicatively coupled to the memory device. The memory controller may receive a temperature measurement indicative of a present temperature of the memory device and determine a memory management interval based on the temperature measurement. The memory controller may perform a memory management operation based on the memory management interval. Sometimes, the memory controller powers on the memory device to perform the memory management operation on the memory device.