Abstract: A write assist circuit is provided. The write assist circuit includes a transistor switch coupled between a bit line voltage node of a cell array and a ground node. An invertor is operative to receive a boost signal responsive to a write enable signal. An output of the invertor is coupled to a gate of the transistor switch. The write assist circuit further includes a capacitor having a first end coupled to the bit line voltage node and a second end coupled to the gate node. The capacitor is operative to drive a bit line voltage of the bit line voltage node to a negative value from the ground voltage in response to the boost signal.

Abstract: A static random access memory (SRAM) periphery circuit includes a first n-type transistor and a second n-type transistor that are disposed in a first well region of first conductivity type, the first well region occupies a first distance in a row direction equal to a bitcell-pitch of an SRAM array. The SRAM periphery circuit includes a first p-type transistor and a second p-type transistor that are disposed in a second well region of second conductivity type. The second well region occupies a second distance in the row direction equal to the bitcell-pitch of the SRAM array. The second well region is disposed adjacent to the first well region in the row direction.

Abstract: A clock circuit includes a latch circuit, a memory state latch circuit, a memory state trigger circuit and a clock trigger circuit. The latch circuit is configured to latch an enable signal, and to generate a latch output signal based on a first clock signal or an output clock signal. The memory state latch circuit is configured to generate the output clock signal responsive to a first control signal. The memory state trigger circuit is coupled to the memory state latch circuit, and configured to adjust the output clock signal responsive to the latch output signal. The clock trigger circuit is coupled to the latch circuit or the memory state trigger circuit by a first node, configured to generate the first clock signal responsive to a second clock signal, and configured to control the latch circuit and the memory state trigger circuit based on the first clock signal.

Abstract: Various embodiments for configurable memory storage systems are disclosed. The configurable memory storages selectively choose an operational voltage signal from among multiple operational voltage signals to dynamically control various operational parameters. For example, the configurable memory storages selectively choose a maximum operational voltage signal from among the multiple operational voltage signals to maximize read/write speed. As another example, the configurable memory storages selectively choose a minimum operational voltage signal from among the multiple operational voltage signals to minimize power consumption.

Abstract: The present disclosure describes embodiments of a memory device with a pre-charge circuit. The memory device can include a memory cell, and the pre-charge circuit can include a first transistor and a second transistor. The first transistor includes a first gate terminal, a first source/drain (S/D) terminal coupled to a reference voltage, and a second S/D terminal coupled to a first terminal of the memory cell. The second transistor includes a second gate terminal, a third S/D terminal coupled to the reference voltage, and a fourth S/D terminal coupled to the second terminal of the memory cell. The first and second transistors are configured to pass the reference voltage in response to the control signal being applied to the first and second gate terminals, respectively.

Abstract: Disclosed herein are related to an integrated circuit to regulate a supply voltage. In one aspect, the integrated circuit includes a metal rail including a first point, at which a first functional circuit is connected, and a second point, at which a second functional circuit is connected. In one aspect, the integrate circuit includes a voltage regulator coupled between the first point of the metal rail and the second point of the metal rail. In one aspect, the voltage regulator senses a voltage at the second point of the metal rail and adjusts a supply voltage at the first point of the metal rail, according to the sensed voltage at the second point of the metal rail.

Abstract: The present disclosure describes various exemplary memory storage devices that can be programmed to write electronic data into one or more memory cells in a write mode of operation and/or to read the electronic data from the one or more memory cells in a read mode of operation. The various exemplary memory storage devices can select various control lines to read the electronic data from the one or more memory cells onto data lines and/or to write the electronic data from these data lines into the one or more memory cells. In some situations, these data lines are charged, also referred to as pre-charged, to a first logical value, such as a logical one, before the various exemplary memory storage devices write the electronic data into the one or more memory cells. During this pre-charging of these data lines, the various exemplary memory storage devices electrically isolate these data lines from specialized circuitry within these exemplary memory storage devices.

Abstract: A power detection circuit is provided. The power detection circuit includes a comparator circuit operative to generate an output signal in response to an input signal. The output signal is configured to change from a first value to a second value in response to the input signal attaining a first threshold value. The output signal is configured to change from the second value to the first value in response to the input signal subsequently attaining a second threshold value. A current limiting circuit is connected to the comparator circuit and operative to limit a leakage current of the comparator circuit.

Abstract: A dual rail memory operable at a first voltage and a second voltage is disclosed. The dual rail memory includes: a memory array operates at the first voltage; a word line driver circuit configured to drive a word line of the memory array to the first voltage; a data path configured to transmit an input data signal or an output data signal, wherein the data path includes a first level shifter for transferring the input data signal from the second voltage to the first voltage; and a control circuit configured to provide control signals to the memory array, the word line driver circuit and the data path, wherein the control circuit includes a second level shifter for transferring an input control signal from the second voltage to the first voltage; wherein the data path and the control circuit are configured to operate at both the first and second voltages.

Abstract: Disclosed herein are related to an integrated circuit to regulate a supply voltage. In one aspect, the integrated circuit includes a metal rail including a first point, at which a first functional circuit is connected, and a second point, at which a second functional circuit is connected. In one aspect, the integrate circuit includes a voltage regulator coupled between the first point of the metal rail and the second point of the metal rail. In one aspect, the voltage regulator senses a voltage at the second point of the metal rail and adjusts a supply voltage at the first point of the metal rail, according to the sensed voltage at the second point of the metal rail.

Abstract: A memory device includes a plurality of memory cells arranged in an array having a plurality of rows and a plurality of columns. A first word line is connected to a first plurality of the memory cells of a first row of the array, and a second word line is connected to a second plurality of the memory cells of the first row of the array. In some examples, the plurality of memory cells are arranged in or on a substrate, and the first word line is formed in a first layer of the substrate and the second word line is formed in a second layer of the substrate.

Abstract: A method of forming an integrated circuit includes placing a first cell layout design of the integrated circuit on a layout design, and manufacturing the integrated circuit based on the layout design. Placing the first cell layout design includes placing a first active region layout pattern adjacent to a first cell boundary, placing a second active region layout pattern adjacent to a second cell boundary, and placing a first set of active region layout patterns between the first and second active region layout patterns, according to a first set of guidelines. The first set of guidelines includes selecting transistors of a first type with a first driving strength and transistors of a second type with a second driving strength. In some embodiments, the first, second and first set of active region layout patterns extend in the first direction, and are on a first layout level.

Abstract: Disclosed herein are related to an integrated circuit to regulate a supply voltage. In one aspect, the integrated circuit includes a metal rail including a first point, at which a first functional circuit is connected, and a second point, at which a second functional circuit is connected. In one aspect, the integrate circuit includes a voltage regulator coupled between the first point of the metal rail and the second point of the metal rail. In one aspect, the voltage regulator senses a voltage at the second point of the metal rail and adjusts a supply voltage at the first point of the metal rail, according to the sensed voltage at the second point of the metal rail.

Abstract: A clock circuit includes a latch circuit, a memory state latch circuit, a memory state trigger circuit and a clock trigger circuit. The latch circuit is configured to latch an enable signal, and to generate a latch output signal based on a first clock signal or an output clock signal. The memory state latch circuit is configured to generate the output clock signal responsive to a first control signal. The memory state trigger circuit is coupled to the memory state latch circuit, and configured to adjust the output clock signal responsive to the latch output signal. The clock trigger circuit is coupled to the latch circuit or the memory state trigger circuit by a first node, configured to generate the first clock signal responsive to a second clock signal, and configured to control the latch circuit and the memory state trigger circuit based on the first clock signal.

Abstract: Various embodiments for configurable memory storage systems are disclosed. The configurable memory storages selectively choose an operational voltage signal from among multiple operational voltage signals to dynamically control various operational parameters. For example, the configurable memory storages selectively choose a maximum operational voltage signal from among the multiple operational voltage signals to maximize read/write speed. As another example, the configurable memory storages selectively choose a minimum operational voltage signal from among the multiple operational voltage signals to minimize power consumption.

Abstract: A memory device includes a plurality of memory cells arranged in an array having a plurality of rows and a plurality of columns. A first word line is connected to a first plurality of the memory cells of a first row of the array, and a second word line is connected to a second plurality of the memory cells of the first row of the array. In some examples, the plurality of memory cells are arranged in or on a substrate, and the first word line is formed in a first layer of the substrate and the second word line is formed in a second layer of the substrate.

Abstract: A memory circuit includes a reference node configured to carry a reference voltage having a reference voltage level, a power supply node configured to carry a power supply voltage having a power supply voltage level, a bit line coupled with a plurality of memory cells, a write circuit configured to charge the bit line by driving a voltage level on the bit line toward the power supply voltage level with a first current, and a switching circuit coupled between the power supply node and the bit line. The switching circuit is configured to receive the voltage level on the bit line, and responsive to a difference between the voltage level received on the bit line and the power supply voltage level being less than or equal to a threshold value, drive the voltage level on the bit line toward the power supply voltage level with a second current.

Abstract: Various embodiments for configurable memory storage systems are disclosed. The configurable memory storages selectively choose an operational voltage signal from among multiple operational voltage signals to dynamically control various operational parameters. For example, the configurable memory storages selectively choose a maximum operational voltage signal from among the multiple operational voltage signals to maximize read/write speed. As another example, the configurable memory storages selectively choose a minimum operational voltage signal from among the multiple operational voltage signals to minimize power consumption.

Abstract: A clock circuit includes a latch circuit, a memory state latch circuit, a memory state trigger circuit and a clock trigger circuit. The latch circuit is configured to latch an enable signal, and to generate a latch output signal based on a first clock signal. The memory state latch circuit is coupled to the latch circuit, and generates an output clock signal responsive to a first control signal. The memory state trigger circuit is coupled to the memory state latch circuit, and adjusts the output clock signal responsive to the latch output signal or a reset signal. The clock trigger circuit is coupled to the latch circuit and the memory state trigger circuit by a first node, configured to generate the first clock signal responsive to a second clock signal, and configured to control the latch circuit and the memory state trigger circuit based on the first clock signal.

Abstract: A static random access memory (SRAM) periphery circuit includes a first n-type transistor and a second n-type transistor that are disposed in a first well region of first conductivity type, the first well region occupies a first distance in a row direction equal to a bitcell-pitch of an SRAM array. The SRAM periphery circuit includes a first p-type transistor and a second p-type transistor that are disposed in a second well region of second conductivity type. The second well region occupies a second distance in the row direction equal to the bitcell-pitch of the SRAM array. The second well region is disposed adjacent to the first well region in the row direction.