Abstract: A current-limited latch circuit is used within a nonvolatile memory integrated circuit for decoding, programming, erase, and other operations. In one implementation, there are a number of latches connected together in parallel between two power supply lines. A current mirroring scheme limits current supplied to the latch. This reduces a difference of the two supplies, positive voltage, ground, or negative voltages, during data changes. The circuit provides smaller device sizes and fast speeds when data changes in the latch, while also providing lower power consumption. The technique provides greater benefits as the voltage difference between the two power supplies is greater.

Abstract: A current-limited latch circuit is used within a nonvolatile memory integrated circuit for decoding, programming, erase, and other operations. In one implementation, there are a number of latches connected together in parallel between two power supply lines. A current mirroring scheme limits current supplied to the latch. This reduces a difference of the two supplies, positive voltage, ground, or negative voltages, during data changes. The circuit provides smaller device sizes and fast speeds when data changes in the latch, while also providing lower power consumption. The technique provides greater benefits as the voltage difference between the two power supplies is greater.

Abstract: A magnetic random access memory having reference magnetic resistance is provided. The memory includes at least one magnetic memory cell having an antiferromagnet layer, a pinned layer formed thereon, a tunnel barrier layer formed thereon, and a free layer formed thereon. The pinned layer and free layer are arranged orthogonally to form a reference magnetic resistance state. Through the provided MRAM structure, the access accuracy is greatly increased and the access speed is accelerated.

Abstract: A magnetic random access memory having reference magnetic resistance is provided. The memory includes at least one magnetic memory cell having an antiferromagnet layer, a pinned layer formed thereon, a tunnel barrier layer formed thereon, and a free layer formed thereon. The pinned layer and free layer are arranged orthogonally to form a reference magnetic resistance state. Through the provided MRAM structure, the access accuracy is greatly increased and the access speed is accelerated.

Abstract: The present invention relates to a hybrid MRAM architecture, and more particularly to a hybrid MRAM architecture capable of being used with an MCU and an MPU. This hybrid MRAM architecture is adapted to a controlling device for accessing a bit of information, comprising a plurality of first MRAM arrays (1T1MTJ architecture), a plurality of second MRAM arrays (XPC architecture), an address line, an access decoder, a sensing and writing circuit, and at least one I/O bus. The access decoder accesses to the bit of information from either the first or the second MRAM arrays selected in accordance with an address signal from the controlling device. The sensing and writing circuit amplifies the bit of information and transmits it to the controlling device via the at least one I/O bus. Accordingly, the access of the bit of information is completed.

Abstract: A current-limited latch circuit is used within a nonvolatile memory integrated circuit for decoding, programming, erase, and other operations. In one implementation, there are a number of latches connected together in parallel between two power supply lines. A current mirroring scheme limits current supplied to the latch. This reduces a difference of the two supplies, positive voltage, ground, or negative voltages, during data changes. The circuit provides smaller device sizes and fast speeds when data changes in the latch, while also providing lower power consumption. The technique provides greater benefits as the voltage difference between the two power supplies is greater.

Abstract: A current-limited latch circuit is used within a nonvolatile memory integrated circuit for decoding, programming, erase, and other operations. In one implementation, there are a number of latches connected together in parallel between two power supply lines. A current mirroring scheme limits current supplied to the latch. This reduces a difference of the two supplies, positive voltage, ground, or negative voltages, during data changes. The circuit provides smaller device sizes and fast speeds when data changes in the latch, while also providing lower power consumption. The technique provides greater benefits as the voltage difference between the two power supplies is greater.

Abstract: A two-transistor flash EPROM cell includes a first floating gate transistor for programming the cell and a second merged transistor for reading the cell. The first transistor, a floating gate transistor, has a drain coupled to the write bit line, a gate coupled to the word line, and a source coupled to the source line. The merged transistor effectively consists of a floating gate transistor in series with a NMOS enhancement transistor. The series NMOS transistor has a voltage threshold of about 1 to 2 volts, thus preventing cell activation caused by overerasure (negative voltage threshold) of the floating gate transistor.