A circuit includes an operational amplifier including an inverting input terminal capacitively coupled to each of an OTP cell array and an NVM cell array and first and second output terminals, an ADC coupled to the first and second output terminals, thereby configured to receive a differential output voltage from the operational amplifier, and a comparator coupled to the ADC and configured to output a data bit responsive to a digital output signal received from the ADC. The circuit is configured to cause the operational amplifier to generate the differential output voltage based on each of a current received from an OTP cell of the OTP cell array and a voltage received from an NVM cell of the NVM cell array.

A mask read only memory device is provided. Single-transistor memory cells are arranged in rows and columns. Each word line is associated with a corresponding row. Each bit line is associated with a corresponding column. Each first reference line selectively provides a first potential in a first phase and a second potential in a second phase. Each second reference line selectively provides the second potential in the first read phase and the first potential in the second phase. Each memory cell has a gate coupled to a word line, a drain coupled to a bit line and a source terminal either floating, grounded or coupled to one among a first reference line and a second reference line. One of first to fourth logic values is read during the memory cell.

A circuit includes an array of OTP cells, an array of NVM cells, an amplifier coupled to each of the array of OTP cells and the array of NVM cells, and a control circuit configured to generate one or more control signals. Responsive to the one or more control signals, the amplifier is configured to generate an output voltage based on a current received from the array of OTP cells in a first configuration, and generate the output voltage based on a voltage received from the array of NVM cells in a second configuration.

An operation method of a multi-bits read only memory includes a step of applying a gate voltage to a conductive gate, a first voltage to a first electrode, and a second voltage to a second electrode. The multi-bits read only memory of the present invention includes a substrate and a transistor structure with the conductive gate mounted between the first electrode and the second electrode. A multiplicity of M nanowire channels is mounted between the first electrode and the second electrode, and M is a positive integer greater than one. The present invention breaks multiple states of the multi-bits read only memory. The multiple states are programmable and include an i.sup.th state, and 1 <i <M . The aforementioned states allow storage of multiple bits on the read only memory, instead of just storing a single bit on the read only memory.

Provided is a read-only memory (ROM) device. The ROM device comprises a substrate that has a plurality of vertical transport field effect transistors (VFETs). The ROM device further comprises an un-activated semiconductor layer provided on each VFET. The un-activated semiconductor layer includes implanted dopants that have not been substantially activated.

A multi-bit, asynchronous e-fuse macro, the macro comprising: the following inputs: an input output enable, a power on reset, a write address, an input write enable, a ground clamp enable, and a write clock; a plurality of e-fuse bits; a supply voltage configured to allow programming at least one of the e-fuse bits; at least one fuse output; and self-timing and control circuitry configured to perform signaling, wherein each of the inputs is in electrical communication with said e-fuse macro.

A non-volatile memory includes a cell array, a current supply circuit, a path selecting circuit and a judging circuit. The cell array includes plural multi-level memory cells in an m×n array. The cell array is connected with m word lines and n lines. The current supply circuit provides one of plural reference currents according to a current control value. The path selecting circuit is connected with the current supply circuit and the n bit lines. The judging circuit is connected with the path selecting circuit, and generates n output data. A first path selector of the path selecting circuit is connected with a path selecting circuit and a first bit line. A first judging device of the judging circuit is connected with the first path selector and generates a first output data.

A neuromorphic device may include: pre-synaptic neurons; row lines extending in a first direction from the pre-synaptic neurons, respectively; post-synaptic neurons; column lines extending in a second direction from the post-synaptic neurons, respectively, the second direction crossing the first direction; and synapses arranged in intersection regions between the row lines and the column lines. The synapses may include resistor interconnections having various fixed resistance values. The synapses may be programmed with at least one pattern based on the various fixed resistance values.

The present invention discloses a multi-bit-per-cell three-dimensional read-only memory (3D-OTP.sub.MB). It comprises a plurality of OTP cells stacked above a semiconductor substrate. Each OTP cell comprises an antifuse layer, which is irreversibly switched from a high-resistance state to a low-resistance state during programming. By adjusting the programming current, the programmed antifuses have different resistances.

A one-time programmable (OTP) memory device includes an OTP memory cell array comprising a plurality of dummy cells and a plurality of main cell groups of main cells and an access circuit configured to write data to at least two of the cells simultaneously. The arrangement of the dummy cells and the main cell groups may allow for the reliable writing of multi-bit data to the memory array. Each of the main cell groups may include a plurality of main cells which are connected to word lines, respectively, and to bit lines, respectively. Each of the main cells may be writable and each of the dummy cells may be unwritable. Each of the main cells may include a contact layer, and the dummy cells might not include the contact layer. A supply voltage may be applied to the OTP memory cell array through the contact layer.