Stochastic or near-stochastic physical characteristics of resistive switching devices are utilized for generating data distinct to those resistive switching devices. The distinct data can be utilized for applications related to electronic identification. As one example, data generated from physical characteristics of resistive switching devices on a semiconductor chip can be utilized to form a distinct identifier sequence for that semiconductor chip, utilized for verification applications for communications with the semiconductor chip or utilized for generating cryptographic keys or the like for cryptographic applications.

Disclosed herein are related to a memory device including a set of memory cells and a memory controller. In one aspect, each of the set of memory cells includes a select transistor and a storage element connected in series between a corresponding bit line and a corresponding source line. In one aspect, the memory controller is configured to apply a first write voltage to a bit line coupled to a selected memory cell, apply a second write voltage to a word line coupled to a gate electrode of a select transistor of the selected memory cell during a first time period, and apply a third write voltage to a source line coupled to the selected memory cell. The second write voltage may be between the first write voltage and the third write voltage.

A method of manufacturing an anti-fuse device includes forming an anti-fuse structure on a substrate, forming a first transistor at a first position away from the anti-fuse device in a first direction, and forming a second transistor at a second position away from the anti-fuse device in a second direction opposite the first direction. Forming the anti-fuse structure includes forming first and second S/D structures in an active area, the first transistor includes the first S/D structure, and the second transistor includes the second S/D structure. The method includes constructing a first electrical connection between gate structures of the first and second transistors and a second electrical connection between a third S/D structure of the first transistor and a fourth S/D structure of the second transistor.

A method of manufacturing an anti-fuse device includes forming an anti-fuse structure on a substrate, forming a first transistor at a first position away from the anti-fuse device in a first direction, and forming a second transistor at a second position away from the anti-fuse device in a second direction opposite the first direction. Forming the anti-fuse structure includes forming first and second S/D structures in an active area, the first transistor includes the first S/D structure, and the second transistor includes the second S/D structure. The method includes constructing a first electrical connection between gate structures of the first and second transistors and a second electrical connection between a third S/D structure of the first transistor and a fourth S/D structure of the second transistor.

The disclosure provides an anti-fuse device including an anti-fuse unit and a sensing circuit. The anti-fuse unit includes a first anti-fuse and a second anti-fuse serially connected between a first terminal of the anti-fuse unit and a second terminal of the anti-fuse unit. The sensing circuit is coupled to the first terminal and the second terminal of the anti-fuse unit for sensing a blown state of the anti-fuse unit.

The disclosure provides an anti-fuse device including an anti-fuse unit and a sensing circuit. The anti-fuse unit includes a first anti-fuse and a second anti-fuse serially connected between a first terminal of the anti-fuse unit and a second terminal of the anti-fuse unit. The sensing circuit is coupled to the first terminal and the second terminal of the anti-fuse unit for sensing a blown state of the anti-fuse unit.

Various embodiments of the present disclosure relate to a non-volatile memory device including a sense amplifier and an operation method thereof. The non-volatile memory device may include: a memory cell array comprising a plurality of memory cells; and the sense amplifier configured to read data of the plurality of memory cells and output the read data. The sense amplifier may include: a first stage sense amplifier configured to sense a voltage difference between a reference voltage and a voltage of a bit line connected to at least one memory cell among the plurality of memory cells, and perform a primary amplification of the sensed voltage difference; and a second stage sense amplifier configured to perform a secondary amplification of a first result of the primary amplification and output a second result of the secondary amplification.

Various embodiments of the present disclosure relate to a non-volatile memory device including a sense amplifier and an operation method thereof. The non-volatile memory device may include: a memory cell array comprising a plurality of memory cells; and the sense amplifier configured to read data of the plurality of memory cells and output the read data. The sense amplifier may include: a first stage sense amplifier configured to sense a voltage difference between a reference voltage and a voltage of a bit line connected to at least one memory cell among the plurality of memory cells, and perform a primary amplification of the sensed voltage difference; and a second stage sense amplifier configured to perform a secondary amplification of a first result of the primary amplification and output a second result of the secondary amplification.

In an anti-fuse memory reading circuit with controllable reading time, a reading time control circuit generates a control signal corresponding to reading time. Based on a clock signal, a programmable reading pulse generation circuit generates a reading pulse with a pulse width corresponding to the control signal. Based on the reading pulse and the control signal, the reading amplification circuit selects a pull-up current source corresponding to the reading time, pulls up a voltage on a bit line (BL) of an anti-fuse memory cell, reads data stored in the anti-fuse memory cell starting from a rising edge of the reading pulse, and latches the read data at a falling edge of the reading pulse. The anti-fuse memory reading circuit can generate a reading pulse with a corresponding pulse width and a pull-up current source with a corresponding size based on the required reading time.

In an anti-fuse memory reading circuit with controllable reading time, a reading time control circuit generates a control signal corresponding to reading time. Based on a clock signal, a programmable reading pulse generation circuit generates a reading pulse with a pulse width corresponding to the control signal. Based on the reading pulse and the control signal, the reading amplification circuit selects a pull-up current source corresponding to the reading time, pulls up a voltage on a bit line (BL) of an anti-fuse memory cell, reads data stored in the anti-fuse memory cell starting from a rising edge of the reading pulse, and latches the read data at a falling edge of the reading pulse. The anti-fuse memory reading circuit can generate a reading pulse with a corresponding pulse width and a pull-up current source with a corresponding size based on the required reading time.