A method of operating a memory circuit includes turning on a first programming device and turning on a first selection device thereby causing a first current to flow through a first fuse element. The first fuse element is coupled between the first selection device and the first programming device. The method further includes turning off a second programming device and turning off a second selection device, and blocking the first current from flowing through a second fuse element that is coupled between the second selection device and the first programming device.

A Read Only Memory (ROM) cell array includes: a first transistor coupled to a first word line; a second transistor coupled to a second word line; and a third transistor disposed between the first transistor and the second transistor, the third transistor having a first gate terminal permanently coupled to a power rail.

A semiconductor device includes first nanostructures vertically separated from one another, a first gate structure wrapping around each of the first nanostructures, and second nanostructures vertically separated from one another. The semiconductor device also includes a second gate structure wrapping around the second nanostructures, a first drain/source structure coupled to a first end of the first nanostructures, a second drain/source structure coupled to both of a second end of the first nanostructures and a first end of the second nanostructures, and a third drain/source structure coupled to a second end of the second nanostructures. The first drain/source structure has a first doping type, the second and third drain/source structures have a second doping type, and the first doping type is opposite to the second doping type.

Some embodiments include apparatuses having non-volatile memory cells, each of the non-volatile memory cells to store more than one bit of information; data lines, at most one of the data lines electrically coupled to each of the non-volatile memory cells; a circuit including transistors coupled to the data lines, the transistors including gates coupled to each other; and an encoder including input nodes and output nodes, the input nodes to receive input information from the data lines through the transistors, and the output nodes to provide output information having a value based on a value of the input information.

A device includes a first switch, a first irreversibly programmable memory point, and a second irreversibly programmable memory point coupled in parallel with the first irreversibly programmable memory point. The first switch and the parallel combination of the first and second irreversibly programmable memory points are coupled in series between a first node and a second node.

A memory circuit array includes a first read device and a first program device. The first read device is coupled to a first bit line. The first read device includes a first transistor coupled to a first word line, and a second transistor coupled to the first word line. The first program device is coupled to the first read device. The first program device includes a third transistor coupled to a second word line, and a fourth transistor coupled to the second word line.

According to an embodiment, there is provided a semiconductor memory device comprising: a global bit line; a local bit line to which a plurality of cell transistors are connected; a switch connected to the local bit line; signal lines connected to the plurality of cell transistors; and a control circuit, wherein the control circuit selects a cell transistor to be selected by setting a potential of the signal line of the cell transistor to be selected to a first potential, changes a potential of the global bit line, changes a potential of the local bit line, and turns on the switch to connect the local bit line to the global bit line after changing the potential of the global bit line and the potential of the local bit line.

A semiconductor device includes first nanostructures vertically separated from one another, a first gate structure wrapping around each of the first nanostructures, and second nanostructures vertically separated from one another. The semiconductor device also includes a second gate structure wrapping around the second nanostructures, a first drain/source structure coupled to a first end of the first nanostructures, a second drain/source structure coupled to both of a second end of the first nanostructures and a first end of the second nanostructures, and a third drain/source structure coupled to a second end of the second nanostructures. The first drain/source structure has a first doping type, the second and third drain/source structures have a second doping type, and the first doping type is opposite to the second doping type.

A high-reliability one-time programmable memory adopting series high voltage partition, which relates to integrated circuit technology and comprises a first MOS tube, a second MOS tube and an anti-fuse element, wherein a gate end of the first MOS tube is connected to a second connecting line (WS), a first connecting end of the first MOS tube is connected to a gate end of the second MOS tube and a voltage limiting device, and a second connecting end of the first MOS tube is connected to a third connecting line (BL); a first connecting end of the second MOS tube is connected to a fourth connecting line (BR), a second connecting end of the second MOS tube is connected to the third connecting line (BL), and a gate end of the second MOS tube is connected to the voltage limiting device and the second connecting end of the first MOS tube.

In an example, a memory array may include a memory cell around at least a portion of a semiconductor. The memory cell may include a gate, a first dielectric stack to store a charge between a first portion of the gate and the semiconductor, and a second dielectric stack to store a charge between a second portion of the gate and the semiconductor, the second dielectric stack separate from the first dielectric stack.