Abstract: An LDMOS device and method of fabrication are provided. The LDMOS device has a substrate with a source region and a drain region formed in the substrate. An insulating layer is provided on a portion of the substrate between the source and the drain region, such that a planar interface is provided between the insulating layer and a surface of the substrate. An insulating member is then formed on a portion of the insulating layer, and a gate layer is formed over part of the insulating member and the insulating layer. By employing such a structure, it has been found that a flat current path exists which enables the on-resistance to be decreased while maintaining a high breakdown voltage.

Abstract: A memory array includes a charge storage structure and a plurality of conductive materials over the charge storage structure is provided. Each conductive material, serving as a word line, has a substantially arc-sidewall and a substantially straight sidewall.

Abstract: The memory device is described, which includes a substrate, a conductive layer, a charge storage layer, a plurality of first doped regions and a plurality of second doped regions. The substrate has a plurality of trenches formed therein. The conductive layer is disposed on the substrate and fills the trenches. The charge storage layer is disposed between the substrate and the conductive layer. The first doped regions are configured in the substrate adjacent to both sides of an upper portion of each trench, respectively. The first doped regions between the neighbouring trenches are separated from each other. The second doped regions are configured in the substrate under bottoms of the trenches, respectively. The second doped regions and the first doped regions are separated from each other, such that each memory cell includes six physical bits.

Abstract: The memory device is described, which includes a substrate, a conductive layer, a plurality of charge storage layers and a plurality of doped regions. The substrate has a plurality of trenches formed therein. The conductive layer is disposed on the substrate and fills the trenches. The charge storage layers are disposed between the substrate and the conductive layer in the trenches respectively, wherein the charge storage layers are separated from each other. The doped regions are configured in the substrate under bottoms of the trenches, respectively.

Abstract: A semiconductor device is described, which includes a substrate, a gate structure, doped regions and lightly doped regions. The substrate has a stepped upper surface, which includes a first surface, a second surface and a third surface. The second surface is lower than the first surface. The third surface connects the first surface and the second surface. The gate structure is disposed on the first surface. The doped regions are configured in the substrate at both sides of the gate structure and under the second surface. The lightly doped regions are configured in the substrate between the gate structure and the doped regions, respectively. Each lightly doped region includes a first part and a second part connecting with each other. The first part is disposed under the second surface, and the second part is disposed under the third surface.

Abstract: An operation method of a non-volatile memory for reducing the second-bit effect in the non-volatile memory is suitable for an N-level memory cell having a first storage position and a second storage position (wherein N is a positive integer greater than 2). The method includes following steps: determining sets of operation levels for operating the first storage position according to the level of the second storage position; when the level of the second storage position is a lower level, operating the first storage position according to a first set of operation levels; when the level of the second storage position is a higher level, operating the first storage position according to a second set of operation levels. Each of the levels in the second set of operation levels is greater than the corresponding level in the first set of operation levels.

Abstract: A method of reading a dual-bit memory cell includes a controlling terminal, a first terminal, and a second terminal. The dual-bit memory cell has a first bit storage node and a second bit storage node near the first terminal and the second terminal respectively. First, a controlling voltage and a read voltage are applied to the controlling terminal and the first terminal respectively. The second terminal is grounded to measure a first output current value of the first terminal. Then, the controlling voltage and the read voltage are applied to the controlling terminal and the second terminal respectively. The first terminal is grounded to measure a second output current value of the second terminal. Afterward, the bit state of the first bit storage node and the bit state of the second bit storage node is read simultaneously according to the first output current value and the second output current value.

Abstract: The invention is directed to a method for forming a memory array. The method comprises steps of providing a substrate having a charge trapping structure formed thereon. A patterned material layer is formed over the substrate and the patterned material layer having a plurality of trenches expose a portion of the charge trapping structure. Furthermore, a plurality of conductive spacers are formed on the sidewalls of the trenches of the patterned material layer respectively and a portion of the charge trapping structure at the bottom of the trenches is exposed by the conductive spacers. An insulating layer is formed over the substrate to fill up the trenches of the patterned material layer. Moreover, a planarization process is performed to remove a portion of the insulating layer until a top surface of the patterned material layer and a top surface of each of the conductive spacers are exposed.

Abstract: The invention is directed to a method for forming a memory array. The method comprises steps of providing a substrate having a charge trapping structure formed thereon. A patterned material layer is formed over the substrate and the patterned material layer having a plurality of trenches expose a portion of the charge trapping structure. Furthermore, a plurality of conductive spacers are formed on the sidewalls of the trenches of the patterned material layer respectively and a portion of the charge trapping structure at the bottom of the trenches is exposed by the conductive spacers. An insulating layer is formed over the substrate to fill up the trenches of the patterned material layer. Moreover, a planarization process is performed to remove a portion of the insulating layer until a top surface of the patterned material layer and a top surface of each of the conductive spacers are exposed.

Abstract: A semiconductor device includes a first well region of a first conductivity, a second well region of a second conductivity type, a source region of the second conductivity type within the first well region, and a drain region of the second conductivity type at least partially within the second well region. A well contact to the first well region is coupled to the source. A first doped region of the first conductivity type and a second doped region of the second conductivity type are located in the second well region. A first transistor includes the first doped region, the second well region, and the first well region. The first transistor is coupled to a switch device. A second transistor includes the second well region, the first well region, and the source region. The first and the second transistors are configured to provide a current path during an ESD event.

Abstract: A semiconductor device includes a first well region of a first conductivity, a second well region of a second conductivity type, a source region of the second conductivity type within the first well region, and a drain region of the second conductivity type at least partially within the second well region. A well contact to the first well region is coupled to the source. A third doped region of the first conductivity type and a fourth doped region of the second conductivity type are located in the second well region. A first transistor includes the third doped region, the second well region, and the first well region. The first transistor is coupled to a switch device. A second transistor includes the second well region, the first well region, and the source region. The first and the second transistors are configured to provide a current path during an ESD event.

Abstract: An operation method of a non-volatile memory is provided. The operation method is that a reading operation is performed to a selected nitride-based memory cell, a first positive voltage is applied to a word line adjacent to one side of the selected memory cell and a second positive voltage is applied to another word line adjacent to the other side of the selected memory cell. The operation method of this present invention not only can reduce a coupling interference issue but also can obtain a wider operation window.

Abstract: An ESD protection circuit including a substrate of a first conductivity type, an annular well region of a second conductivity type, two first regions of the first conductivity type and at least one transistor of the second conductivity type is provided. The annular well region is disposed in the substrate. The first regions are disposed in the substrate and surrounded by the annular well region. The at least one transistor is disposed on the substrate between the first regions and including a source, a gate, and a drain. The annular well region and the drain are coupled to a first voltage source. The source and one of the first regions are coupled to a second voltage source, and the other of the first regions is coupled to a substrate triggering circuit.

Abstract: In an ESD protection structure and method utilizing substrate triggering for a high-voltage tolerant pad on a substrate, an ESD protection device has a source connected to the pad and a gate and a drain both connected to a ground, and a substrate-triggering control circuit is used to keep the substrate at a low voltage during a normal operation, and pumping the substrate to a high voltage during an ESD event for the ESD protection device to be triggered much easier. The substrate-triggering control circuit is implemented with an active device, thereby reducing the chip size for the circuit and the loading effect on the pad.

Abstract: A memory architecture for an integrated circuit comprises a first memory array configured to store data for one pattern of data usage and a second memory array configured to store data for another pattern of data usage. The first and second memory arrays comprise charge storage based nonvolatile memory cells having substantially the same structure in both arrays. A first operation algorithm adapted for example for data flash applications is used for programming, erasing and reading data in the first memory array. A second operation algorithm adapted for example for code flash applications is used for programming, erasing and reading data in the second memory array, wherein the second operation algorithm is different than the first operation algorithm. Thus, one die with memory for both code flash and data flash applications can be easily manufactured using a simple process, at low cost and high yield.

Abstract: An LDMOS device and method of fabrication are provided. The LDMOS device has a substrate with a source region and a drain region formed in the substrate. An insulating layer is provided on a portion of the substrate between the source and the drain region, such that a planar interface is provided between the insulating layer and a surface of the substrate. An insulating member is then formed on a portion of the insulating layer, and a gate layer is formed over part of the insulating member and the insulating layer. By employing such a structure, it has been found that a flat current path exists which enables the on-resistance to be decreased while maintaining a high breakdown voltage.

Abstract: A method for measuring intrinsic capacitance of a MOS device is provided. The MOS device includes a first terminal, a second terminal, a third terminal and a fourth terminal. First, provide a first input signal to the second terminal and ground the third terminal and fourth terminal. Then, charge the first terminal and measure a first current required for charging the first terminal. Afterward, provide a second input signal to the second terminal, ground the third terminal and the fourth terminal, and measure a second current required for charging the first terminal, wherein the first input signal and the second input signal have the same low level, but different high levels. Finally, determine intrinsic capacitance between the first terminal and the second terminal according to the first current, the second current and a high level difference between the first input signal and the second input signal.

Abstract: Charge trapping memory cells are protected from over-erasing in response to an erase command. For example, in response to an erase command, one bias arrangement is applied to program charge trapping memory cells, and another bias arrangement is applied to erase the charge trapping memory cells, such that the charge trapping memory cells have a higher net electron charge, in the erased state than i.n the programmed state. In another example, an integrated circuit with an array of charge trapping memory cells has logic which responds to an erase command by applying similar bias arrangements to the charge trapping memory cells. In a further example, such an integrated circuit is manufactured.

Abstract: An LDMOS device and method of fabrication are provided. The LDMOS device has a substrate with a source region and a drain region formed in the substrate. An insulating layer is provided on a portion of the substrate between the source and the drain region, such that a planar interface is provided between the insulating layer and a surface of the substrate. An insulating member is then formed on a portion of the insulating layer, and a gate layer is formed over part of the insulating member and the insulating layer. By employing such a structure, it has been found that a flat current path exists which enables the on-resistance to be decreased whilst maintaining a high breakdown voltage.

Abstract: An operation method of a non-volatile memory is provided. The operation method is that a reading operation is performed to a selected nitride-based memory cell, a first positive voltage is applied to a word line adjacent to one side of the selected memory cell and a second positive voltage is applied to another word line adjacent to the other side of the selected memory cell. The operation method of this present invention not only can reduce a coupling interference issue but also can obtain a wider operation window.