Abstract: A cell that can be used as a dynamic memory cell for storing data or a field programmable gate array (FPGA) cell for programming is disclosed. The cell includes a capacitor having a first terminal connected to a column bitline and a second terminal connected to a switch control node. A select transistor has a gate connected to the read bitline, a source connected to the switch control node, and a drain connected to a row wordline. The switch control node stores data as a voltage indicative of a one or a zero.

Abstract: A reprogrammable non-volatile memory array and constituent memory cells is disclosed. The semiconductor memory cells each have a data storage element constructed around an ultra-thin dielectric, such as a gate oxide. The gate oxide is used to store information by stressing the ultra-thin dielectric into breakdown (soft or hard breakdown) to set the leakage current level of the memory cell. The memory cell is read by sensing the current drawn by the cell. A suitable ultra-thin dielectric is high quality gate oxide of about 50 ? thickness or less, as commonly available from presently available advanced CMOS logic processes. The memory cells are first programmed by stressing the gate oxide until soft breakdown occurs. The memory cells are then subsequently reprogrammed by increasing the breakdown of the gate oxide.

Abstract: A programmable memory cell comprised of a transistor located at the crosspoint of a column bitline and a row wordline is disclosed. The transistor has its gate formed from the column bitline and its source connected to the row wordline. The memory cell is programmed by applying a voltage potential between the column bitline and the row wordline to produce a programmed n+ region in the substrate underlying the gate of the transistor. Further, a gate dielectric of the transistor has a higher breakdown voltage near the source connected to the row wordline than its drain.

Abstract: A programmable memory cell comprised of a transistor located at the crosspoint of a column bitline and a row wordline is disclosed. The transistor has its gate formed from the column bitline and its source connected to the row wordline. The memory cell is programmed by applying a voltage potential between the column bitline and the row wordline to produce a programmed n+ region in the substrate underlying the gate of the transistor. Further, the row wordline is formed from a buried N+ layer allowing for higher density integration.

Abstract: A programmable memory cell comprised of a transistor located at the crosspoint of a column bitline and a row wordline is disclosed. The transistor has its gate formed from the column bitline and its source connected to the row wordline. The memory cell is programmed by applying a voltage potential between the column bitline and the row wordline to produce a programmed n+region in the substrate underlying the gate of the transistor.

Abstract: A semiconductor memory cell having a data storage element constructed around an ultra-thin dielectric, such as a gate oxide, is used to store information by stressing the ultra-thin dielectric into breakdown (soft or hard breakdown) to set the leakage current level of the memory cell. The memory cell is read by sensing the current drawn by the cell. A suitable ultra-thin dielectric is high quality gate oxide of about 50 Å thickness or less, as commonly available from presently available advanced CMOS logic processes.

Abstract: A method of programming a memory cell is disclosed. The memory cell comprises a select transistor and a data storage element. The method comprises allowing current to flow through the data storage element until a predetermined current or voltage is detected. If the current or voltage exceeds a threshold, then the programming is deemed complete.

Abstract: A programmable memory cell comprised of a transistor located at the crosspoint of a column bitline and a row wordline is disclosed. The transistor has its gate formed from the column bitline and its source connected to the row wordline. The memory cell is programmed by applying a voltage potential between the column bitline and the row wordline to produce a programmed p+ region to form a p-n diode in the substrate underlying the gate of the transistor. Further, the wordline is formed from a buried diffusion N+ layer while the column bitline is formed from a counterdoped polysilicon layer.

Abstract: A method of testing the programmability of a memory cell is disclosed. The memory cell comprises a select transistor and a data storage element. The method comprises applying a test voltage across the data storage element. The select transistor is turned on. Finally, a current flow through the data storage element when the test voltage is applied is measured. A test positive signal is indicated if the current flow is greater than a reference.

Abstract: A semiconductor memory cell having a data storage element constructed around an ultra-thin dielectric, such as a gate oxide, is used to store information by stressing the ultra-thin dielectric into breakdown (soft or hard breakdown) to set the leakage current level of the memory cell. The memory cell is read by sensing the current drawn by the cell. A suitable ultra-thin dielectric is high quality gate oxide of about 50 Å thickness or less, as commonly available from presently available advanced CMOS logic processes.

Abstract: A method of testing a memory cell is disclosed. The memory cell has a data storage element constructed around an ultra-thin dielectric, such as a gate oxide, which is used to store information by stressing the ultra-thin dielectric into breakdown (soft or hard breakdown) to set the leakage current level of the memory cell. In order to ensure that the gate oxide underlying the data storage elements are of sufficient quality for programming, the memory cells of a memory array may be tested by applying a voltage across the gate oxide of the data storage element and measuring the current flow. Resultant current flow outside of a predetermined range indicates a defective memory cell.

Abstract: A programmable memory cell comprised of a transistor located at the crosspoint of a column bitline and a row wordline is disclosed. The transistor has its gate formed from the column bitline and its source connected to the row wordline. The memory cell is programmed by applying a voltage potential between the column bitline and the row wordline to produce a programmed n+ region in the substrate underlying the gate of the transistor.

Abstract: A programmable memory cell comprised of a transistor located at the crosspoint of a column bitline and a row wordline is disclosed. The transistor has its gate formed from the column bitline and its source connected to the row wordline. The memory cell is programmed by applying a voltage potential between the column bitline and the row wordline to produce a programmed n+ region in the substrate underlying the gate of the transistor. Further, a gate dielectric of the transistor has a higher breakdown voltage near the source connected to the row wordline than its drain.

Abstract: A smart card having improved non-volatile memory and a processor. The memory includes of a plurality of memory cells. The semiconductor memory cells each have a data storage element constructed around an ultra-thin dielectric, such as gate oxide. The gate oxide is used to store information by stressing the ultra-thin dielectric into breakdown (soft or hard breakdown) to set the leakage current level of the memory cell. The memory cell is read be sensing the current drawn by the cell. A suitable ultra-thin dielectric is high quality gate oxide of about 50 angstroms thickness or less, as commonly available from presently available advance CMOS logic process.

Abstract: A programmable memory cell comprised of a transistor located at the crosspoint of a column bitline and a row wordline is disclosed. The transistor has its gate formed from the column bitline and its source connected to the row wordline. The memory cell is programmed by applying a voltage potential between the column bitline and the row wordline to produce a programmed n+ region in the substrate underlying the gate of the transistor. Further, the row wordline is formed from a buried N+ layer allowing for higher density integration.

Abstract: A semiconductor memory cell having a data storage element constructed around an ultra-thin dielectric, such as a gate oxide, is used to store information by stressing the ultra-thin dielectric into breakdown (soft or hard breakdown) to set the leakage current level of the memory cell. The memory cell is read by sensing the current drawn by the cell. A suitable ultra-thin dielectric is high quality gate oxide of about 50 Å thickness or less, as commonly available from presently available advanced CMOS logic processes.

Abstract: A reprogrammable non-volatile memory array and constituent memory cells is disclosed. The semiconductor memory cells each have a data storage element constructed around an ultra-thin dielectric, such as a gate oxide. The gate oxide is used to store information by stressing the ultra-thin dielectric into breakdown (soft or hard breakdown) to set the leakage current level of the memory cell. The memory cell is read by sensing the current drawn by the cell. A suitable ultra-thin dielectric is high quality gate oxide of about 50 Å thickness or less, as commonly available from presently available advanced CMOS logic processes. The memory cells are first programmed by stressing the gate oxide until soft breakdown occurs. The memory cells are then subsequently reprogrammed by increasing the breakdown of the gate oxide.

Abstract: A smart card having improved non-volatile memory is disclosed. The smart card may include a processor and memory. The memory is comprised of a plurality of memory cells. The semiconductor memory cells each have a data storage element constructed around an ultra-thin dielectric, such as a gate oxide. The gate oxide is used to store information by stressing the ultra-thin dielectric into breakdown (soft or hard breakdown) to set the leakage current level of the memory cell. The memory cell is read by sensing the current drawn by the cell. A suitable ultra-thin dielectric is high quality gate oxide of about 50 angstrom thickness or less, as commonly available from presently available advanced CMOS logic processes.

Abstract: A semiconductor memory cell having a data storage element constructed around an ultra-thin dielectric, such as a gate oxide, is used to store information by stressing the ultra-thin dielectric into breakdown (soft or hard breakdown) to set the leakage current level of the memory cell. The memory cell is read by sensing the current drawn by the cell. A suitable ultra-thin dielectric is high quality gate oxide of about 50 Å thickness or less, as commonly available from presently available advanced CMOS logic processes.

Abstract: A programming circuit includes a wordline decoder, an adjustable voltage generator, and a column transistor. The programming circuit is useful in programming a memory cell comprised of a select transistor and a data storage element. The data storage element is programmed by a programming current. The amount of the programming current can be modulated by the column transistor, the select transistor, or the adjustable voltage generator.