A latch circuit includes a latch module, a set control module, a reset control module and a clock module, wherein the latch module is employed for latching data input by a data module, the set control module is employed for controlling the latch module to output a high-level signal, the reset control module is employed for controlling the latch module to output a low-level signal, and the clock module is employed for providing a readout clock signal to the latch module.

Provided is an anti-fuse memory circuit. The anti-fuse memory circuit includes a memory array, a bit line (BL), and a word line (WL); an anti-fuse memory cell (FsBIn) electrically connected to the bit line (BL) through a first switch transistor (1Add); a second switch transistor (2Add) configured to connect the bit line (BL) to a transmission wire (100); a third switch transistor (3Add) configured to discharge the transmission wire (100); a reading module (102) including a first input end (+) connected to the transmission wire (100), a second input end (−) for receiving a reference voltage (VTRIP), and a sampling input end (C) for receiving a sampling signal (CLK); and a compensation module (101), connected to the third switch transistor (3Add) and configured to slow down a drop speed of a voltage at the transmission wire (100).

A layout structure of an anti-fuse array at least includes an array circuit area and a functional circuit area. The array circuit area is electrically connected with the functional circuit area. The functional circuit area is located on at least one side of the array circuit area, and at least one side of the array circuit area is located on an edge of the layout structure. The array circuit area includes an anti-fuse array composed of anti-fuse cells, and the array circuit area is configured to provide the anti-fuse cells under different column addresses to the functional circuit area. The functional circuit area is configured to fuse the anti-fuse cells under the different column addresses.

An anti-fuse circuit includes the following: a first transistor, and at least one parasitic transistor and at least one parasitic triode that are connected to the first transistor. The at least one parasitic transistor and the at least one parasitic triode are connected to a first node.

A memory device includes a plurality of magnetoresistive random-access memory (MRAM) cells including a first one-time programmable (OTP) MRAM cell. A first OTP select transistor is connected to the first OTP MRAM cell. The first OTP select transistor configured to selectively apply a breakdown current to the first OTP MRAM cell to write the first OTP MRAM cell to a breakdown state.

A memory device includes a plurality of magnetoresistive random-access memory (MRAM) cells including a first one-time programmable (OTP) MRAM cell. A first OTP select transistor is connected to the first OTP MRAM cell. The first OTP select transistor configured to selectively apply a breakdown current to the first OTP MRAM cell to write the first OTP MRAM cell to a breakdown state.

Methods, systems, and devices for signal sampling with offset calibration are described. For example, sampling circuitry may include an input pair of transistors where input signals may be provided to gate nodes of the transistors, and an output signal may be generated based on a comparison of voltages of drain nodes of the transistors. In some examples, source nodes of the transistors may be coupled with each other, such as via a resistance, and each source node may be configured to be coupled with a ground node. In some examples, a conductive path between the source nodes may be coupled with one or more switching components configurable for further coupling of the source nodes with the ground node. In some examples, enabling such switching components may add an electrical characteristic (e.g., capacitance) to the conductive path between the source nodes, which may be configurable to mitigate sampling circuitry imbalances.

Methods, systems, and devices for signal sampling with offset calibration are described. For example, sampling circuitry may include an input pair of transistors where input signals may be provided to gate nodes of the transistors, and an output signal may be generated based on a comparison of voltages of drain nodes of the transistors. In some examples, source nodes of the transistors may be coupled with each other, such as via a resistance, and each source node may be configured to be coupled with a ground node. In some examples, a conductive path between the source nodes may be coupled with one or more switching components configurable for further coupling of the source nodes with the ground node. In some examples, enabling such switching components may add an electrical characteristic (e.g., capacitance) to the conductive path between the source nodes, which may be configurable to mitigate sampling circuitry imbalances.

A one-time programmable nonvolatile memory cell includes a substrate providing a first conductivity type well and a second conductivity type well, a first MOS transistor having a floating gate and a gate oxide, and an auxiliary gate and a gate oxide formed by extending one end of the floating gate and the gate oxide of the first MOS transistor from an edge of the first active region, along a second direction perpendicular to the first direction, passing through the isolation region until to cover a part or an entire of the second active region. The first and the second active regions are separated by an isolation region, and the first and second active regions and the isolation region are arranged parallel to each other along a first direction. The memory cell has an improved structure and optimized performance and a reduced size.

An anti-fuse memory circuit includes: a memory array including multiple anti-fuse memory cells; bit lines, each connected to the anti-fuse memory cells arranged in extension direction of the bit line, each anti-fuse memory cell being electrically connected to respective one of bit lines through first switch transistor; word lines, each connected to first switch transistors arranged in extension direction of word line; a second switch transistor connects one of the bit lines to transmission wire; a reading circuit, having first input terminal connected to the transmission wire, second input terminal for receiving reference voltage, and sampling input terminal for receiving sampling signal; and a signal generation circuit for generating sampling signal according to precharge voltage and precharge signal, where precharge signal is used for instructing to precharge transmission wire to precharge voltage, and delay duration between sampling signal and precharge signal is positively correlated with voltage amplitude of precharge voltage.