Patent application number | Description | Published |
20080212366 | SEMICONDUCTOR MEMORY DEVICE - This disclosure concerns a semiconductor memory device comprising Fin semiconductors extending in a first direction; source layers provided in the Fin semiconductors; drain layers provided in the Fin semiconductors; floating bodies provided in the Fin semiconductors between the source layers and the drain layers, the floating bodies being in an electrically floating state and accumulating or discharging carries so as to store data; first gate electrodes provided in first grooves located between the Fin semiconductors adjacent to each other; second gate electrodes provided in second grooves adjacent to the first grooves and located between the Fin semiconductors adjacent to each other; bit lines connected to the drain layers, and extending in a first direction; word lines connected to the first gate electrodes, and extending in a second direction orthogonal to the first direction; and source lines connected to the source layers, and extending in the second direction. | 09-04-2008 |
20080232181 | SEMICONDUCTOR MEMORY DEVICE - This disclosure concerns a semiconductor memory device comprising: a memory cell array having memory cells arrayed two-dimensionally; word lines connected to the memory cells of rows of the memory cell array; bit lines connected to the memory cells of columns of the memory cell array; sense amplifiers connected to the bit lines, and detecting data stored in the memory cells; a test pad passing a predetermined reference current from a power source, and transmitting a reference voltage based on the reference current; and test circuits connected between the power source and the test pad and intervening between the power source and the bit lines, the test circuits passing test currents according to the reference voltage via the bit lines. | 09-25-2008 |
20080232184 | SEMICONDUCTOR MEMORY DEVICE - This disclosure concerns a memory comprising memory cells including floating bodies, logic data being stored in the memory cells; word lines connected to gates of the memory cells; bit lines connected to the memory cells; and sense amplifiers connected to the bit lines, and applying a first voltage to the bit lines when first logic data is written to the memory cells connected to the bit lines, wherein the sense amplifiers apply a second voltage to the memory cells having stored therein the first logic data during a refresh operation in which at least second logic data stored in the memory cells is recovered, the second logic data is opposite in logic to the first logic data, and the second voltage is lower in absolute value than the first voltage and equal to or higher in absolute value than a potential of sources of the memory cells. | 09-25-2008 |
20080237695 | SEMICONDUCTOR MEMORY DEVICE - This disclosure concerns a memory comprising a charge trapping film; a gate insulating film; a back gate on the charge trapping film; a front gate on the gate insulating film; and a body region provided between a drain and a source, wherein the memory includes a first storage state for storing data depending on the number of majority carriers in the body region and a second storage state for storing data depending on the amount of charges in the charge trapping film, and the memory is shifted from the first storage state to the second storage state by converting the number of majority carriers in the body region into the amount of charges in the charge trapping film or from the second storage state to the first storage state by converting the amount of charges in the charge trapping film into the number of majority carriers in the body region. | 10-02-2008 |
20080239789 | SEMICONDUCTOR MEMORY DEVICE - The disclosure concerns a semiconductor memory device comprising a semiconductor layer; a charge trap film in contact with a first surface of the semiconductor layer; a gate insulating film in contact with a second surface of the semiconductor layer, the second surface being opposite to the first surface; a back gate electrode in contact with the charge trap film; a gate electrode in contact with the gate insulating film; a source and a drain formed in the semiconductor layer; and a body region provided between the drain and the source, the body region being in an electrically floating state, wherein a threshold voltage or a drain current of a memory cell including the source, the drain, and the gate electrode is adjusted by changing number of majority carriers accumulated in the body region and a quantity of charges trapped into the charge trap film. | 10-02-2008 |
20080251830 | SEMICONDUCTOR STORAGE DEVICE AND DRIVING METHOD THEREOF - This disclosure concerns a semiconductor storage device comprising a semiconductor layer provided on the insulation layer provided on the semiconductor substrate; a source layer and a drain layer provided in the semiconductor layer; a body provided between the source layer and the drain layer, the body being in an electrically floating state; an emitter layer contacting with the source layer, the emitter layer having an opposite conductive type to the source layer; a word line including the source layer, the drain layer, and the body, the word line being provided to memory cells arrayed in a first direction in a plurality of tow-dimensionally arranged memory cells; a source line connected to the source layers of the memory cells arrayed in the first direction; and a bit line connected to the drain layers of the memory cells arrayed in a second direction intersecting the first direction. | 10-16-2008 |
20080316848 | SEMICONDUCTOR MEMORY DEVICE AND DRIVING METHOD THEREFOR - This disclosure concerns a semiconductor memory device comprising memory cells including floating bodies and storing therein logic data; bit lines and word lines connected to the memory cells; sense amplifiers connected to the bit lines; a refresh controller instructing a refresh operation for restoring deteriorated storage states of the memory cells; and a refresh interval timer setting a refresh interval between one refresh operation and a next refresh operation to a first interval in a data read mode or a data write mode, and setting the refresh interval to a second interval longer than the first interval in a data retention mode, the data read mode being a mode in which the data stored in the selected memory cell is read to an outside of the device, the data write mode being a mode in which data from the outside is written to the selected memory cell. | 12-25-2008 |
20080316849 | MEMORY DRIVING METHOD AND SEMICONDUCTOR STORAGE DEVICE - This disclosure concerns a method of driving a memory including memory cells, bit lines, and word lines, each memory cell having a source, a drain, and a floating body, the method comprising performing a refresh operation for recovering deterioration of first logical data of the memory cells and deterioration of second logical data of the memory cells, wherein in the refresh operation, the number of the carriers injected into the floating body is larger than the number of the carriers discharged from the floating body when a potential at the floating body is larger than a critical value, and the number of the carriers injected into the floating body is smaller than the number of the carriers discharged from the floating body when the potential at the floating body is smaller than the critical value. | 12-25-2008 |
20090086559 | SEMICONDUCTOR MEMORY DEVICE AND DRIVING METHOD THEREOF - This disclosure concerns a memory including a memory cell including a drain, a source and a floating body, wherein when a refresh operation is executed, a first current is carried from the drain or the source to the body and a second current is carried from the body to the second gate electrode by applying a first voltage and a second voltage to the first gate electrode and the second gate electrode, the first voltage and the second voltage being opposite in polarity to each other, and a state of the memory cell is covered to an stationary state in which an amount of the electric charges based on the first current flowing in one cycle of the refresh operation is almost equal to an amount of the electric charges based on the second current flowing in one cycle of the refresh operation. | 04-02-2009 |
20090168576 | SEMICONDUCTOR MEMORY DEVICE - A memory includes: first sense amplifiers arranged in a first interval of an arrangement of memory cell arrays, each being connected to first bit lines corresponding to two memory cell arrays provided at both sides of the first sense amplifier; second sense amplifiers arranged in a second interval of the arrangement of the memory cell arrays, each being connected to second bit lines corresponding to two memory cell arrays at both sides of the second sense amplifier; edge arrays provided beside both ends of an arrangement of the memory cell arrays, the edge arrays generating only the reference data; and edge sense amplifiers provided between the arrangement of the memory cell arrays and the edge arrays, wherein the edge sense amplifier detects data from the memory cell array at one end of the memory cell arrays based on the reference data from one of the edge arrays. | 07-02-2009 |
20100019304 | SEMICONDUCTOR MEMORY DEVICE AND MANUFACTURING METHOD THEREOF - A semiconductor memory device includes bodies electrically floating; sources; drains; gate electrodes, each of which is adjacent to one side surface of the one of the bodies via a gate dielectric film; plates, each of which is adjacent to the other side surface of the one of the bodies via a plate dielectric film; first bit lines on the drains, the first bit lines including a semiconductor with a same conductivity type as that of the drains; and emitters on the semiconductor of the first bit lines, the emitters including a semiconductor with an opposite conductivity type to that of the semiconductor of the first bit lines, wherein the emitters are stacked above the bodies and the drains. | 01-28-2010 |
20100165770 | SEMICONDUCTOR MEMORY DEVICE - A memory includes memory cells, wherein during a first write operation in which first logical data is written in all memory cells connected to a first word line, a source line driver and a word line driver, the source line driver shifts a voltage of a selected source line corresponding to the first word line in a direction away from the voltage of the first word line and the word line driver shifts a voltage of a second word line in a same direction as a transition direction of voltage of a selected source line, and during a second write operation in which second logical data is written in a selected cell connected to the first word line, the source line driver and the word line driver shift voltages of the selected source line and the second word line in a direction approaching the voltage of the first word line. | 07-01-2010 |
20100177573 | SEMICONDUCTOR MEMORY DEVICE AND SEMICONDUCTOR MEMORY DEVICE DRIVING METHOD - A memory includes a latch circuit latching data from a first and a second bit lines to a first and a second sense nodes; a first data line reading-out the data from the first sense node to an outside; a second data line reading-out the data from the second sense node to the outside; a first write transistor connected between the first bit line and the first or second data line without via the first and second sense node; and a second write transistor connected between the second bit line and the first or second data line without via the first and second sense node, wherein in a write operation, the first write transistor transmits the data from the first or second data line to the first bit line, or the second write transistor transmits the data from the first or second data line to the second bit line. | 07-15-2010 |
20100182853 | Semiconductor Memory Device Having a Floating Storage Bulk Region Capable of Holding/Emitting Excessive Majority Carriers - A semiconductor memory device includes: a semiconductor layer formed on an insulating layer; a plurality of transistors formed on the semiconductor layer and arranged in a matrix form, each of the transistors having a gate electrode, a source region and a drain region, the electrodes in one direction constituting word lines; source contact plugs connected to the source regions of the transistors; drain contact plugs connected to the drain regions of the transistors; source wirings each of which commonly connects the source contact plugs, the source wirings being parallel to the word lines; and bit lines formed so as to cross the word lines and connected to the drain regions of the transistors via the drain contact plugs. Each of the transistors has a first data state having a first threshold voltage and a second data state having a second threshold voltage. | 07-22-2010 |
20100238740 | SEMICONDUCTOR MEMORY DEVICE AND DRIVING METHOD OF THE SAME - A memory includes a first and a second bit lines (BL); a first and a second sense nodes (SN); a first transfer gate between the 1 | 09-23-2010 |