Abstract: The invention is directed to a layout of nonvolatile memory device. The memory cell has a gate electrode, a first doped electrode, and a second doped electrode. The first doped electrode is coupled to the bit line. The gate electrode is coupled to one separated word line. A shared coupled capacitor structure is coupled between all of memory cells of the adjacent bit lines from the second doped electrode. The capacitor structure has at least two floating-gate MOS capacitors. Each floating-gate MOS capacitor has a floating-gate transistor having a floating gate, a first S/D region and a second S/D region; and a MOS capacitor coupled to the floating gate. The first S/D region is coupled to the second doped electrode of the corresponding one of the transistor memory cells, and the second S/D region is shared with an adjacent one of the floating-gate transistor.

Abstract: A structure of non-volatile memory has a plurality of buried bit lines in a substrate, extending along a first direction. Selection gate structure lines are located between the buried bit lines. A plurality of stack dielectric films on the both sides of the selection gate structure lines serving as a charge storage region, does not extend to the bit lines and a dielectric layer contacting a surface of substrate adjacent to stacked dielectric films. Word lines are over the substrate, wherein stacked dielectric films and a dielectric layer are interposed between WL and substrate on the region excluding the selection gate structure line, extending along a second direction different from the first direction. Since the charge storage layer does not completely cover between the selection gate structure lines and the bit lines, an additional control gate is formed.

Abstract: A compact mask programmable read-only memory (Mask ROM) is described, comprising a plurality of word lines, a plurality of bit lines, and a plurality of MOS-type and diffusion-type memory cells arranged in an array. The memory cells in one column are coupled to one bit line, and the gates of the MOS-type cells in one row are coupled to one word line via contacts, wherein two columns of memory cells share a column of contacts. A MOS-type cell shares its source and drain with two memory cells in the same column, and a diffusion-type cell directly connects with the diffusions of two adjacent memory cells. A constant number of continuous memory cells are grouped as a memory string, wherein the two diffusions of the two terminal memory cells are electrically connected to a bank select transistor and a ground line, respectively.

Abstract: A structure of non-volatile memory contains a substrate. A plurality of bit lines are formed in the substrate along a first direction, wherein each of the bit lines also serve as a source/drain (S/D) region. A first dielectric layer is disposed over the substrate. A plurality of selection gate (SG) lines are formed over the first dielectric layer between the bit lines. A plurality of charge-storage structure layer are formed over the substrate between the bit lines and the SG lines. A second dielectric layer is formed over the SG lines and a third dielectric layer is formed over the bit lines. A plurality of word lines are formed over the substrate along a second direction, which is crossing the first direction for the bit lines. Wherein, when a selected one of the SG lines is applied a voltage, another S/D region is created in the substrate under the selected one of the SG lines.

Abstract: A memory array device has a plurality of gate structure lines, adjacently disposed over a substrate along a direction, wherein at least a portion of the gate structure lines have memory function. A plurality of first doped regions, in the substrate at a side of a first line of the gate structure lines. A plurality of second doped regions, in the substrate at a side of a last line of the gate structure lines. Wherein the first doped regions and the second doped regions respectively for a plurality of pairs of doped region with respect to a plurality of bit lines. In other words, the conventional source/drain regions for each memory cell are saved. Instead, the gate lines are adjacently disposed together.

Abstract: A structure of non-volatile memory contains a substrate. A plurality of bit lines are formed in the substrate along a first direction, wherein each of the bit lines also serve as a source/drain (S/D) region. A first dielectric layer is disposed over the substrate. A plurality of selection gate (SG) lines are formed over the first dielectric layer between the bit lines. A plurality of charge-storage structure layer are formed over the substrate between the bit lines and the SG lines. A second dielectric layer is formed over the SG lines and a third dielectric layer is formed over the bit lines. A plurality of word lines are formed over the substrate along a second direction, which is crossing the first direction for the bit lines. Wherein, when a selected one of the SG lines is applied a voltage, another S/D region is created in the substrate under the selected one of the SG lines.

Abstract: A memory driving circuit has a register for receiving a new-coming data and a delayed clock, and exporting a current-existing data. The delayed clock has a delay to a clock. A pre-detecting circuit receives the current-existing data, the new-coming data, and a pre-enable signal, and exports an output signal. Wherein, the current-existing data is compared with the new-coming data. The output signal indicates a disable state if the two data are the same. Otherwise, the output signal indicates an enable state, wherein the pre-enable signal is also used to enable or disable the pre-detecting circuit. An output driving circuit receives the current-existing data and an enabling signal, and exports a first output signal. A pre-driving circuit receives the output signal of the pre-detecting circuit and an enable control signal, and exports a second output signal. An I/O pad receives the first output signal and the second output signal.

Abstract: A structure of non-volatile memory has a plurality of buried bit lines in a substrate, extending along a first direction. Selection gate structure lines are located between the buried bit lines. A plurality of stack dielectric films on the both sides of the selection gate structure lines serving as a charge storage region, does not extend to the bit lines and a dielectric layer contacting a surface of substrate adjacent to stacked dielectric films. Word lines are over the substrate, wherein stacked dielectric films and a dielectric layer are interposed between WL and substrate on the region excluding the selection gate structure line, extending along a second direction different from the first direction. Since the charge storage layer does not completely cover between the selection gate structure lines and the bit lines, an additional control gate is formed.

Abstract: A structure of non-volatile memory contains a substrate. A plurality of bit lines are formed in the substrate along a first direction, wherein each of the bit lines also serve as a source/drain (S/D) region. A first dielectric layer is disposed over the substrate. A plurality of selection gate (SG) lines are formed over the first dielectric layer between the bit lines. A plurality of charge-storage structure layer are formed over the substrate between the bit lines and the SG lines. A second dielectric layer is formed over the SG lines and a third dielectric layer is formed over the bit lines. A plurality of word lines are formed over the substrate along a second direction, which is crossing the first direction for the bit lines. Wherein, when a selected one of the SG lines is applied a voltage, another S/D region is created in the substrate under the selected one of the SG lines.

Abstract: A non-volatile memory array structure, comprising a plurality of first transistors, serving for memory function, being arranged to have a plurality of columns and a plurality of first rows. The first transistors in each column are coupled in series, and adjacent two of the columns are grouped into a memory group using a common bit line. The gate electrodes of the first transistors in the same first row are coupled with a first sequence word line. A plurality of second transistors are also included. Each of the second transistors is coupled between two columns of the memory group and is adjacent to each of the first rows. The second transistors form a plurality of second rows, wherein gate electrodes of the second transistors in the same second row are coupled to a second sequence word line.

Abstract: The invention is directed to a nonvolatile memory device. Each memory cell is formed to have the depletion mode operation by doped opposite conductive-type dopants to the substrate at the surface region under the gate electrode, so that the depletion memory cell is formed. The charge-storing structure layer is, for example, an O/N/O structure layer, wherein the nitride layer is used to store the charge. The erasing operation speed can be improved.

Abstract: The present invention relates to a fabrication method for a mask read only memory structure. By forming double spacers, the code implantation can be performed in a self-aligned way into the channel regions of predetermined memory cells. By avoiding erroneous implantation to the non-channel regions and thus the laterally diffusion of the un-wanted impurities to the channel regions of non-coded memory cells, the threshold voltage of the non-coded memory cells can be unaffected and the error rate of reading can be greatly reduced.

Abstract: The present invention relates to a multi-level read only memory cell that can store two bits and the fabrication method thereof. The multi-level ROM cell has the storage capacity of two bits and the resultant NAND type ROM memory array can provide four logic states of two bits, thus increasing the data storage capacity.

Abstract: A memory array device has a plurality of gate structure lines, adjacently disposed over a substrate along a direction, wherein at least a portion of the gate structure lines have memory function. A plurality of first doped regions, in the substrate at a side of a first line of the gate structure lines. A plurality of second doped regions, in the substrate at a side of a last line of the gate structure lines. Wherein the first doped regions and the second doped regions respectively for a plurality of pairs of doped region with respect to a plurality of bit lines. In other words, the conventional source/drain regions for each memory cell are saved. Instead, the gate lines are adjacently disposed together.

Abstract: The invention is directed to a layout of nonvolatile memory device. The memory cell has a gate electrode, a first doped electrode, and a second doped electrode. The first doped electrode is coupled to the bit line. The gate electrode is coupled to one separated word line. A shared coupled capacitor structure is coupled between all of memory cells of the adjacent bit lines from the second doped electrode. The capacitor structure has at least two floating-gate MOS capacitors. Each floating-gate MOS capacitor has a floating-gate transistor having a floating gate, a first S/D region and a second S/D region; and a MOS capacitor coupled to the floating gate. The first S/D region is coupled to the second doped electrode of the corresponding one of the transistor memory cells, and the second S/D region is shared with an adjacent one of the floating-gate transistor.

Abstract: A contactless Mask ROM is described, comprising a plurality of MOS-type memory cells. The memory cells include a plurality of first memory cells and a plurality of second memory cells. The first memory cells have a first channel conductivity so that they are depletion-mode MOS transistors, and the second memory cells have a second channel conductivity so that they are enhanced-mode MOS transistors. In the contactless Mask ROM, a memory cell shares two diffusions with two adjacent memory cells that are aligned with the memory cell along a first direction.

Abstract: A non-volatile memory array structure, comprising a plurality of first transistors, serving for memory function, being arranged to have a plurality of columns and a plurality of first rows. The first transistors in each column are coupled in series, and adjacent two of the columns are grouped into a memory group using a common bit line. The gate electrodes of the first transistors in the same first row are coupled with a first sequence word line. A plurality of second transistors are also included. Each of the second transistors is coupled between two columns of the memory group and is adjacent to each of the first rows. The second transistors form a plurality of second rows, wherein gate electrodes of the second transistors in the same second row are coupled to a second sequence word line.

Abstract: A contactless mask programmable read-only memory (Mask ROM) is described, comprising a plurality of word lines extending in row direction and a plurality of diffusions arranged in rows and columns in a substrate. In the Mask ROM, two rows of diffusions are separated by a word line. Two adjacent diffusions in the same column, the word line between the two diffusions, and the substrate between the two diffusions together constitute a memory cell. The memory cells include a plurality of first memory cells and a plurality of second memory cells. The channel length, the gate oxide width or the channel dopant concentration of the first memory cells is different from that of the second memory cells, such that the threshold voltage of the first memory cells is substantially different from that of the second memory cells.

Abstract: A compact mask programmable read-only memory (Mask ROM) is described, comprising a plurality of word lines, a plurality of bit lines, and a plurality of MOS-type and diffusion-type memory cells arranged in an array. The memory cells in one column are coupled to one bit line, and the gates of the MOS-type cells in one row are coupled to one word line via contacts, wherein two columns of memory cells share a column of contacts. A MOS-type cell shares its source and drain with two memory cells in the same column, and a diffusion-type cell directly connects with the diffusions of two adjacent memory cells. A constant number of continuous memory cells are grouped as a memory string, wherein the two diffusions of the two terminal memory cells are electrically connected to a bank select transistor and a ground line, respectively.