Abstract: Two (or more) different, but complementary, families of integrated circuits having the same layout are developed simultaneously where the different families are achieved by changing one or more design parameters of transistors used to implement the integrated circuits. For example, a low-power (but low-speed) family of one or more ICs (e.g., for handheld applications) can be achieved by designing at least some transistors with relatively high threshold-voltage (Vt) levels, while a different, but complementary, high-speed (but high-power) family of one or more ICs (e.g., for server applications) can be achieved by designing corresponding transistors with relatively low Vt levels. In this way, the two families can share in common all but a very few masks used to fabricate the ICs of the different families.

Abstract: An EEPROM cell is described that is programmed and erased by electron tunneling across an entire portion of separate transistor channels. The EEPROM cell has three transistors formed in a semiconductor substrate. The three transistors are a tunneling transistor (PMOS), a sense transistor (NMOS) and a read transistor (NMOS). Electron tunneling occurs to program the EEPROM cell through a sense tunnel oxide layer having a thickness to allow the electron tunneling across an entire portion of a sense channel upon incurrence of a sufficient voltage potential between a floating gate and the tunnel channel. Electron tunneling also occurs to erase the EEPROM cell through a tunnel oxide layer having a thickness to allow electron tunneling across an entire portion of a tunneling channel upon incurrence of a sufficient voltage potential between the floating gate and the tunneling channel.

Abstract: A non-volatile memory cell, comprising a semiconductor substrate having a first conductivity type. A control region is formed of said first conductivity type in the substrate and a control region oxide formed over the control region. The cell includes a program element having a first active region of a second conductivity type formed in said substrate, a doped or implanted region adjacent to said first active region, and a gate oxide overlying at least the channel region. An active region oxide covers a portion of the first active region. A floating gate is formed over said semiconductor substrate on said active region oxide and said control region oxide.

Abstract: An EEPROM cell is described that is programmed and erased by electron tunneling across an entire portion of separate transistor channels. The EEPROM cell has three transistors formed in a semiconductor substrate. The three transistors are a tunneling transistor (PMOS), a sense transistor (NMOS) and a read transistor (NMOS). Electron tunneling occurs to program the EEPROM cell through a sense tunnel oxide layer having a thickness to allow the electron tunneling across an entire portion of a sense channel upon incurrence of a sufficient voltage potential between a floating gate and the tunnel channel. Electron tunneling also occurs to erase the EEPROM cell through a tunnel oxide layer having a thickness to allow electron tunneling across an entire portion of a tunneling channel upon incurrence of a sufficient voltage potential between the floating gate and the tunneling channel.

Abstract: An EEPROM cell is described that is programmed and erased by electron tunneling at separate regions, an edge of a tunneling drain and a sense transistor channel. The EEPROM cell has three transistors formed in a semiconductor substrate. The three transistors are a tunneling transistor (NMOS), a sense transistor (NMOS) and a read transistor (NMOS). Electron tunneling occurs to program the EEPROM cell through a sense tunnel oxide layer by electron tunneling across an entire portion of a sense channel upon incurrence of a sufficient voltage potential between a floating gate and the sense channel. Electron tunneling also occurs to erase the EEPROM cell through a tunnel oxide layer be electron tunneling at an edge of a tunneling drain upon incurrence of a sufficient voltage potential between the floating gate and the tunneling drain.

Abstract: A two transistor EEPROM cell is described that is erased by electron tunneling across an entire portion of a tunneling channel and programmed by electron tunneling at an edge of a tunneling drain.

Abstract: A non-volatile memory cell structure which includes a floating gate, a reverse breakdown element and a read transistor. The reverse breakdown element is at least partially formed in a first region of a first conductivity type in a semiconductor substrate, and underlies a portion of the floating gate; and the read transistor is at least partially formed in the first region and connected to the reverse breakdown element. In a further embodiment a control gate is capacitively coupled to the floating gate and is formed in a second region of the substrate, outside the well region.

Abstract: A method of creating a reverse breakdown condition in an array of memory cells arranged in columns and rows in the array, and an array structure are provided. The method comprises the steps of applying a first voltage on a first column connection coupling a first column of said cells, and a second voltage on a second column connection coupling a second column of said cells; and applying a third voltage on a first row connection coupling a first row of said cells, and applying said second voltage on a second row connection coupling a second row of said cells. In this aspect, the difference between the first voltage and the third voltage creates said reverse breakdown condition in at least one cell occupying said first column and first row. In a further aspect, each cell includes a floating gate and the method of the invention includes the step of programming one of said cells by coupling a control voltage to each floating gate.