Abstract: A one time programmable memory cell having a gate, a gate dielectric layer, a source region, a drain region, a capacitor dielectric layer and a conductive plug is provided herein. The gate dielectric layer is disposed on a substrate. The gate is disposed on the gate dielectric layer. The source region and the drain region are disposed in the substrate at the sides of the gate, respectively. The capacitor dielectric layer is disposed on the source region. The capacitor dielectric layer is a resistive protection oxide layer or a self-aligned salicide block layer. The conductive plug is disposed on the capacitor dielectric layer. The conductive plug is served as a first electrode of a capacitor and the source region is served as a second electrode of the capacitor. The one time programmable memory (OTP) cell is programmed by making the capacitor dielectric layer breakdown.

Abstract: A non-volatile memory unit cell includes a first transistor pair and first and second control gates. The first transistor pair includes first and second transistors that are connected in series and of the same type. The first and second transistors have a first floating polysilicon gate and a second floating polysilicon gate, respectively. The first control gate is coupled to the first floating polysilicon gate through a tunneling junction and the second control gate is coupled to the second floating polysilicon gate through another tunneling junction.

Abstract: An anti-fuse memory with coupling channel is provided. The anti-fuse memory includes a substrate of a first conductive type, a doped region of a second conductive type, a coupling gate, a gate dielectric layer, an anti-fuse gate, and an anti-fuse layer. The substrate has an isolation structure. The doped region is disposed in the substrate. A channel region is defined between the doped region and the isolation structure. The coupling gate is disposed on the substrate between the doped region and the isolation structure. The coupling gate is adjacent to the doped region. The gate dielectric layer is disposed between the coupling gate and the substrate. The anti-fuse gate is disposed on the substrate between the coupling gate and the isolation structure. The anti-fuse gate and the coupling gate have a space therebetween. The anti-fuse layer is disposed between the anti-fuse gate and the substrate.

Abstract: A non-volatile semiconductor memory cell with dual functions includes a substrate, a first gate, a second gate, a third gate, a charge storage layer, a first diffusion region, a second diffusion region, and a third diffusion region. The second gate and the third gate are used for receiving a first voltage corresponding to a one-time programming function of the dual function and a second voltage corresponding to a multi-time programming function of the dual function. The first diffusion region is used for receiving a third voltage corresponding to the one-time programming function and a fourth voltage corresponding to the multi-time programming function. The second diffusion region is used for receiving a fifth voltage corresponding to the multi-time programming function.

Abstract: A one-time-programmable memory device comprises a one-time-programmable memory cell array, a voltage pumping circuit, and a programming verification circuit. The one-time-programmable memory cell array comprises a plurality of memory cells. Each memory cell is arranged at an intersection of a bit line and a word line. The voltage pumping circuit comprises a plurality of local voltage boost circuits. Each local voltage boost circuit is shared by a corresponding memory cell of the plurality of memory cells. The programming verification circuit is coupled to the one-time-programmable memory cell array for verifying that conduction current of programmed memory cells of the plurality of memory cells is greater than a predetermined current level after programming. Each local boost circuit isolates leakage current of a corresponding programmed memory cell, and prevents programming voltage failure due to current overloading at a corresponding voltage pumping circuit.

Abstract: The present invention provides a non-volatile memory cell structure. A first isolation structure is disposed on a substrate and a semiconductor layer is disposed on the first isolation structure to form a silicon on insulator device. A first doping region is made of a portion of the semiconductor layer. A gate is disposed on the first doping region. A gate oxide layer is sandwiched between the first doping region and the gate. A second doping region is disposed within the semiconductor layer and outside the first doping region. A second doping region is in direct contact with the first doping region. A second isolation structure is disposed on the first isolation structure. Further, the second isolation structure surrounds the first doping region and the second doping region. The second isolation structure is also in direct contact with the first doping region and the second doping region.

Abstract: The present invention provides a versatile flower container includes a base, a top cover, a carrying container placing on the top of top cover and a sensing device placing in the base, the carrying container has a concave space can be used to accommodate the sponge, floral and water, the sensing device includes an electronic control panel, two humidity detection rod, a number of lamps and speakers, the two humidity detection rods are through the top cover and inserting into the sponge in the concave space, thereby they can detect the humidity values of the sponge, the lamps and the speaker can be activated to produce light and sound and then generate warning effect when the humidity values are not enough in the carrying container.

Abstract: An only-one-polysilicon layer non-volatile memory unit cell includes a first P-type transistor, a second P-type transistor, a N-type transistor pair, a first and second coupling capacitors is provided. The N-type transistor pair has a third transistor and a fourth transistor that are connected. The third transistor and the fourth transistor have a first floating polysilicon gate and a second floating polysilicon gate to serve as charge storage mediums, respectively. One end of the second coupling capacitor is connected to the gate of the second transistor and is coupled to the second floating polysilicon gate, the other end of the second coupling capacitor receives a second control voltage. One end of the second coupling capacitor is connected to the gate of the second transistor and is coupled to the second floating polysilicon gate, the other end of the second coupling capacitor receives a second control voltage.

Abstract: A non-volatile memory structure is disclosed. LDD regions may be optionally formed through an ion implantation using a mask for protection of a gate channel region of an active area. Two gates are apart from each other and disposed on an isolation structure on two sides of a middle region of the active area, respectively. The two gates may be each entirely disposed on the isolation structure or partially to overlap a side portion of the middle region of the active area. A charge-trapping layer and a dielectric layer are formed between the two gates and on the active area to serve for a storage node function. They may be further formed onto all sidewalls of the two gates to serve as spacers. Source/drain regions are formed through ion implantation using a mask for protection of the gates and the charge-trapping layer.

Abstract: A non-volatile semiconductor memory cell with dual functions includes a substrate, a first gate, a second gate, a third gate, a charge storage layer, a first diffusion region, a second diffusion region, and a third diffusion region. The second gate and the third gate are used for receiving a first voltage corresponding to a one-time programming function of the dual function and a second voltage corresponding to a multi-time programming function of the dual function. The first diffusion region is used for receiving a third voltage corresponding to the one-time programming function and a fourth voltage corresponding to the multi-time programming function. The second diffusion region is used for receiving a fifth voltage corresponding to the multi-time programming function.

Abstract: A single-polysilicon layer non-volatile memory having a floating gate transistor, a program gate and a control gate is provided. The floating gate transistor has a floating gate and a tunneling dielectric layer. The floating gate is disposed on a substrate. The tunneling dielectric layer is disposed between the floating gate and the substrate. The program gate, the control gate and the erase gate are respectively disposed in the substrate under the floating gate separated by the tunneling dielectric layer. Therefore, during a program operation and an erase operation, charges are injected in and expelled out through different regions of the tunneling dielectric layer, so as to increase reliability of the non-volatile memory.

Abstract: An operating method for a memory unit is provided, wherein the memory unit includes a well region, a select gate, a first gate, a second gate, an oxide nitride spacer, a first diffusion region, and a second diffusion region. The operating method for the memory unit comprises the following steps. During a programming operation, a breakdown voltage is coupled to the second diffusion region through a first channel region formed under the select gate. A programming voltage is sequentially or simultaneously applied to the first gate and the second gate to rupture a first oxide layer and a second oxide layer, wherein the first oxide layer is disposed between the first gate and the well region, and the second oxide layer is disposed between the second gate and the well region.

Abstract: A one time programmable memory cell having a gate, a gate dielectric layer, a source region, a drain region, a capacitor dielectric layer and a conductive plug is provided herein. The gate dielectric layer is disposed on a substrate. The gate is disposed on the gate dielectric layer. The source region and the drain region are disposed in the substrate at the sides of the gate, respectively. The capacitor dielectric layer is disposed on the source region. The capacitor dielectric layer is a resistive protection oxide layer or a self-aligned silicide block layer. The conductive plug is disposed on the capacitor dielectric layer. The conductive plug is served as a first electrode of a capacitor and the source region is served as a second electrode of the capacitor. The one time programmable memory (OTP) cell is programmed by making the capacitor dielectric layer breakdown.

Abstract: A one-time-programmable memory device comprises a one-time-programmable memory cell array, a voltage pumping circuit, and a programming verification circuit. The one-time-programmable memory cell array comprises a plurality of memory cells. Each memory cell is arranged at an intersection of a bit line and a word line. The voltage pumping circuit comprises a plurality of local voltage boost circuits. Each local voltage boost circuit is shared by a corresponding memory cell of the plurality of memory cells. The programming verification circuit is coupled to the one-time-programmable memory cell array for verifying that conduction current of programmed memory cells of the plurality of memory cells is greater than a predetermined current level after programming. Each local boost circuit isolates leakage current of a corresponding programmed memory cell, and prevents programming voltage failure due to current overloading at a corresponding voltage pumping circuit.

Abstract: A method of forming a charge-storing layer in a non-volatile memory cell in a logic process includes forming a select gate over an active region of a substrate, forming long polysilicon gates partially overlapping the active region of the substrate, and filling the charge-storing layer between the long polysilicon gates.

Abstract: A single-polysilicon layer non-volatile memory having a floating gate transistor, a program gate and a control gate is provided. The floating gate transistor has a floating gate and a tunneling dielectric layer. The floating gate is disposed on a substrate. The tunneling dielectric layer is disposed between the floating gate and the substrate. The program gate, the control gate and the erase gate are respectively disposed in the substrate under the floating gate separated by the tunneling dielectric layer. Therefore, during a program operation and an erase operation, charges are injected in and expelled out through different regions of the tunneling dielectric layer, so as to increase reliability of the non-volatile memory.

Abstract: A non-volatile memory unit cell includes a first transistor pair and first and second control gates. The first transistor pair includes first and second transistors that are connected in series and of the same type. The first and second transistors have a first floating polysilicon gate and a second floating polysilicon gate, respectively. The first control gate is coupled to the first floating polysilicon gate through a tunneling junction and the second control gate is coupled to the second floating polysilicon gate through another tunneling junction.

Abstract: A method for analyzing mucosa structure with optical coherence tomography (OCT) is provided, and includes: (a) scanning a mucosa sample with optical coherence tomography; (b) choosing a lateral range from a two- or three-dimensional OCT image and analyzing all the A-scan intensity profiles in the lateral range; (c) calculating three indicators in each A-scan intensity profile, including the standard deviation for a certain depth range below the sample surface, the exponential decay constant of the spatial-frequency spectrum and the epithelium thickness under the condition that the basement membrane is identifiable; and (d) using the three indicators of each A-scan intensity profile within the lateral range to analyze the mucosa structure.

Abstract: A non-volatile memory disposed in a SOI substrate is provided. The non-volatile memory includes a memory cell and a first conductive type doped region. The memory cell includes a gate, a charge storage structure, a bottom dielectric layer, a second conductive type drain region, and a second conductive type source region. The gate is disposed on the SOI substrate. The charge storage structure is disposed between the gate and the SOI substrate. The bottom dielectric layer is disposed between the charge storage layer and the SOI substrate. The second conductive type drain region and the second conductive type source region are disposed in a first conductive type silicon body layer next to the two sides of the gate. The first conductive type doped region is disposed in the first conductive type silicon body layer and electrically connected to the first conductive type silicon body layer beneath the gate.

Abstract: A non-volatile memory disposed in a SOI substrate is provided. The non-volatile memory includes a memory cell and a first conductive type doped region. The memory cell includes a gate, a charge storage structure, a bottom dielectric layer, a second conductive type drain region, and a second conductive type source region. The gate is disposed on the SOI substrate. The charge storage structure is disposed between the gate and the SOI substrate. The bottom dielectric layer is disposed between the charge storage layer and the SOI substrate. The second conductive type drain region and the second conductive type source region are disposed in a first conductive type silicon body layer next to the two sides of the gate. The first conductive type doped region is disposed in the first conductive type silicon body layer and electrically connected to the first conductive type silicon body layer beneath the gate.