| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 365189060 | Including signal clamping | 35 |
| 20080279017 | Semiconductor memory device - During a stand-by state in which power supply is cut off, a high-voltage power supply control circuit isolates a global negative voltage line transmitting a negative voltage and a local negative voltage line provided corresponding to each respective sub array block from each other and isolates a global ground line and a local ground line transmitting a ground voltage from each other. These local ground line and local negative voltage line are charged to a high voltage level through a high voltage line before cut-off from the corresponding power supply. A leakage current path from a word line to the negative voltage line or the ground line is cut off, so that the word line in a non-selected state can reliably be maintained at a non-selection voltage. Thus, in a low power consumption stand-by mode, data stored in a memory cell can be held in a stable manner. | 11-13-2008 |
| 20080285356 | Semiconductor memory device employing clamp for preventing latch up - A semiconductor memory device employs a clamp for preventing latch up. For the purpose, the semiconductor memory device includes a precharging/equalizing unit for precharging and equalizing a pair of bit lines, and a control signal generating unit for producing a control signal which controls enable and disable of the precharging/equalizing unit, wherein the control signal generating unit includes a clamping unit to clamp its source voltage to a voltage level lower than that of its bulk bias. | 11-20-2008 |
| 20090003087 | Memory device bit line sensing system and method that compensates for bit line resistance variations - Systems, devices and methods are disclosed, such as a system and method of sensing the voltage on bit lines that, when respective memory cells coupled to the bit lines are being read that compensates for variations in the lengths of the bit lines between the memory cells being read and respective bit line sensing circuits. The system and method may determine the length of the bit lines between the memory cells and the sensing circuits based on a memory address, such as a block address. The system and method then uses the determined length to adjust either a precharge voltage applied to the bit lines or the duration during which the bit lines are discharged by respective memory cells before respective voltages on the bit lines are latched. | 01-01-2009 |
| 20090201747 | MEMORY, BIT-LINE PRE-CHARGE CIRCUIT AND BIT-LINE PRE-CHARGE METHOD - A memory is provided. The memory includes a memory cell, a clamp transistor, an inverter, a bit line, a pre-charge path and a detector and controller circuit. The memory is coupled to the clamp transistor. The clamp transistor has a first end, a second end and a control end. The inverter has an input end electrically connected to the second end of the clamp transistor and an output end electrically connected to the control end of the clamp transistor. The bit line is electrically connected to the second end of the clamp transistor and the input end of the inverter and has a bit-line voltage thereon. The pre-charge path is electrically connected to the first end of the clamp transistor through a node having a sensing voltage thereon. The detector and controller circuit is electrically connected to the first end of the clamp transistor and the pre-charge path for detecting the sensing voltage in order to open the pre-charge path to raise the bit-line voltage when the sensing voltage is at a low level and close the pre-charge path when the sensing voltage is at a high level. | 08-13-2009 |
| 20090213665 | NONVOLATILE SEMICONDUCTOR MEMORY DEVICE - Provided is a nonvolatile semiconductor memory device which reads out a memory cell at high speed. A minute current source ( | 08-27-2009 |
| 20090244989 | BITLINE VOLTAGE DRIVER - A method and structure for passing a bitline voltage regardless of its voltage level via a bitline in a memory device is disclosed. In one embodiment, the method includes detecting the bitline voltage of the bitline, feeding a control signal at an activation voltage level to the bitline pass device to maintain a pass voltage differential of the bitline pass device when the bitline is selected and passing the bitline voltage via the bitline pass device in response to the control signal, where the pass voltage differential is greater than a threshold voltage of the bitline pass device regardless of a level of the bitline voltage. | 10-01-2009 |
| 20100002528 | SEMICONDUCTOR DEVICE - A sense amplifier section comprises two stages of latch-type sense amplifier circuits, i.e., a primary-stage latch-type sense amplifier and a secondary-stage latch-type sense amplifier, wherein stress exerted on the primary-stage latch-type sense amplifier is reduced significantly to ensure high accuracy in amplification. In the above configuration including the secondary-stage latch-type sense amplifier, when an amplified output from the primary-stage latch-type sense amplifier reaches a predetermined voltage level (e.g., 50 mV), a transition to amplifying operation of the secondary-stage latch-type sense amplifier is enabled so that a time duration of operation of the primary-stage latch-type sense amplifier (corresponding to a time duration of stress exertion on the primary-stage latch-type sense amplifier) can be shortened significantly. Further, by providing a clamp circuit in the primary-stage latch-type sense amplifier, it is possible to decrease a stress voltage itself to be applied to the primary-stage latch-type sense amplifier. | 01-07-2010 |
| 20100020621 | MEMORY DEVICE BIT LINE SENSING SYSTEM AND METHOD THAT COMPENSATES FOR BIT LINE RESISTANCE VARIATIONS - Systems, devices and methods are disclosed, such as a system and method of sensing the voltage on bit lines that, when respective memory cells coupled to the bit lines are being read that compensates for variations in the lengths of the bit lines between the memory cells being read and respective bit line sensing circuits. The system and method may determine the length of the bit lines between the memory cells and the sensing circuits based on a memory address, such as a block address. The system and method then uses the determined length to adjust either a precharge voltage applied to the bit lines or the duration during which the bit lines are discharged by respective memory cells before respective voltages on the bit lines are latched. | 01-28-2010 |
| 20100177574 | SYSTEM AND METHOD FOR MITIGATING REVERSE BIAS LEAKAGE - The present disclosure includes devices, methods, and systems for programming memory, such as resistance variable memory. One embodiment can include an array of resistance variable memory cells, wherein the resistance variable memory cells are coupled to one or more data lines, a row decoder connected to a first side of the array, a column decoder connected to a second side of the array, wherein the second side is adjacent to the first side, a gap located adjacent to the row decoder and the column decoder, and clamp circuitry configured to control a reverse bias voltage associated with one or more unselected memory cells during a programming operation, wherein the clamp circuitry is located in the gap and is selectively coupled to the one or more data lines. | 07-15-2010 |
| 20100284229 | BITLINE VOLTAGE DRIVER - A method and structure for passing a bitline voltage regardless of its voltage level via a bitline in a memory device is disclosed. In one embodiment, the method includes detecting the bitline voltage of the bitline, feeding a control signal at an activation voltage level to the bitline pass device to maintain a pass voltage differential of the bitline pass device when the bitline is selected and passing the bitline voltage via the bitline pass device in response to the control signal, where the pass voltage differential is greater than a threshold voltage of the bitline pass device regardless of a level of the bitline voltage. | 11-11-2010 |
| 20110032775 | MEMORY DEVICES AND METHOD FOR DRIVING A SIGNAL LINE TO A KNOWN SIGNAL LEVEL - A system and method for erasing a block of data in a plurality of memory cells includes clamping one of a digit line and an I/O line in a sensing circuit of a memory device to a fixed logic level. The memory cells of the block of memory cells are selected and refreshed to the fixed logic level. A sense amplifier includes a clamping circuit adapted to connect one of a digit line and an I/O line to a fixed logic level in response to an erase signal during a refresh of the selected block of memory cells. | 02-10-2011 |
| 20110103158 | LOW VOLTAGE SENSING SCHEME HAVING REDUCED ACTIVE POWER DOWN STANDBY CURRENT - A low voltage sensing scheme reduces active power down standby leakage current in a memory device. A clamping device or diode is used between a Psense amplifier control line (e.g. ACT) and Vcc and/or between an Nsense amplifier control line (e.g. RNL*) and Vss (ground potential). The clamping diode is not enabled during normal memory operations, but is turned on during active power down mode to reduce leakage current through ACT and/or RNL* nodes. The clamping device connected to the ACT node may reduce the voltage on the ACT line during power down mode, whereas the clamping device connected to the RNL* node may increase the voltage on the RNL* line during power down mode to reduce sense amplifier leakage current through these nodes. Because of the rules governing abstracts, this abstract should not be used to construe the claims. | 05-05-2011 |
| 20110158006 | SEMICONDUCTOR MEMORY DEVICE - A semiconductor memory device comprising: a memory cell array having a plurality of memory cells that are arranged in a shape of a matrix along a plurality of bit lines arranged in parallel and a plurality of word lines intersecting orthogonally to the bit lines, and that have their data read out to the bit lines; a sense amplifier which detects a voltage or a current of the bit line, and which decides the read data from each of the memory cells; a clamping transistor which is connected between the sense amplifier and the bit lines, and which determines a voltage in a charging mode of the bit lines by a clamp voltage applied to a gate thereof; and a clamp voltage generation circuit which generates the clamp voltage so as to become larger as a distance from the sense amplifier to a selected one of the memory cells is longer. | 06-30-2011 |
| 20110199837 | High Voltage Word Line Driver - A word line driver circuit coupled to a memory circuit word line includes pull-up, pull-up clamp, pull-down and pull-down clamp transistors, each having a source, a drain and a gate. For the pull-up transistor, the source is coupled to a first power supply, and the gate to a pull-up control signal. For the pull-up clamp transistor, the source is coupled to the drain of the pull-up transistor, the drain to the word line, and the gate to a pull-up clamp gate signal. For the pull-down transistor, the source is coupled to a second power supply, and the gate to a pull-down control signal. For the pull-down clamp transistor, the source is coupled to the drain of the pull-down transistor, the drain to the word line, and the gate to a pull-down clamp gate signal. The word line is coupled to one or more DRAM cells. Source to drain voltage magnitudes of the pull-up and pull-down transistors are less than a voltage between the first and second power supplies. | 08-18-2011 |
| 20110205813 | POWER-OFF APPARATUS, SYSTEMS, AND METHODS - Apparatus, methods, and systems are disclosed, including those that are to prevent a bias voltage from rising to a higher level than a storage node voltage as the bias voltage transitions to a ground level. For example a first voltage generator may be utilized to generate a bias voltage to bias a transistor in a memory cell in a memory array. A second voltage generator may be utilized to generate an plate voltage. The memory cell may include a transistor on a substrate and a capacitor. The capacitor connects from a drain of the transistor to the plate voltage. The storage node voltage is located at the drain of the transistor. A power controller may provide an off signal to the first and second voltage generators. The bias voltage may then transition to ground from a voltage less than zero volts. The rate of the bias voltage rise to ground is such that the bias voltage is maintained at less than or equal to the storage node voltage during the transition time period. | 08-25-2011 |
| 20110235439 | STATIC MEMORY CELL HAVING INDEPENDENT DATA HOLDING VOLTAGE - A static memory cell, composed of cross-coupled MOS transistors having a relatively high threshold voltage, is equipped with MOS transistors for controlling the power supply line voltage of the memory cell. To permit the voltage difference between two data storage nodes in the inactivated memory cell to exceed the voltage difference between the two nodes when write data is applied from a data line pair DL and /DL to the two nodes in the activated memory cell, the power supply line voltage control transistors are turned on to apply a high voltage VCH to the power supply lines after the word line voltage is turned off. The data holding voltage in the memory cell can be activated to a high voltage independent of the data line voltage, and the data holding voltage can be dynamically set so that read and write operations can be performed at high speed with low power consumption. | 09-29-2011 |
| 20120008427 | Semiconductor Memory Device To Reduce Off-Current In Standby Mode - A semiconductor memory device capable of reducing off-current in a standby mode is provided. The semiconductor memory device includes an enable signal generating unit configured to receive a plurality of address decoding signals and generate a first enable signal to select a first cell block and a second enable signal to select a second cell block, and an internal voltage generating unit for generating an internal voltage by controlling a supply of a first voltage in accordance with the first or second enable signals. | 01-12-2012 |
| 20120026804 | SEMICONDUCTOR MEMORY DEVICE - A semiconductor memory device comprises a plurality of memory layers arranged in multilayer, each memory layer including a cell array, the cell array containing a plurality of first parallel lines, a plurality of second parallel lines arranged crossing the first lines, and a plurality of memory cells connected at intersections of the first lines and the second lines; a pulse generator operative to generate pulses required for data access to the memory cell; and a control means operative to control the pulse generator such that the pulse output from the pulse generator has energy in accordance with the memory layer to which the access target memory cell belongs. | 02-02-2012 |
| 20120140574 | NON-VOLATILE MEMORY DEVICE AND SENSING METHOD THEREOF - A non-volatile memory device is disclosed, which performs a sensing operation using a current. The non-volatile memory device includes a cell array including one or more unit cells, configured to read or write data, a current-voltage converter configured to convert a sensing current corresponding to data stored in the unit cell into a sensing voltage, and perform a precharge operation of the sensing voltage upon receiving the sensing current in response to a current driving signal at an activation time point of a word line of the cell array, and a sense-amp configured to compare the sensing voltage with a predetermined reference voltage, and amplify the compared result. | 06-07-2012 |
| 20120163101 | MEMORY INTERFACE CIRCUIT, MEMORY INTERFACE METHOD, AND ELECTRONIC DEVICE - A memory interface circuit includes a gating circuit that starts detection of a logic level of a data strobe signal in accordance with a data read command. A clamp circuit clamps the data strobe signal to a first logic level after the data read command is issued. A detection circuit detects a logic level of the data strobe signal, which is driven by the memory, in accordance with the data read command. | 06-28-2012 |
| 20120195135 | SEMICONDUCTOR MEMORY DEVICE - According to one embodiment, a semiconductor memory device includes a plurality of memory cells each of which is arranged at the intersection position between a pair of complementary bit lines and a word line, and stores data between a first power supply voltage applied to a first node and a voltage applied to a virtual ground node, and a control circuit which changes the amount of current of the pair of bit lines in accordance with the amplitude of the pair of bit lines for each column in a memory macro, that is formed by arranging the plurality of memory cells in a matrix, in the data read operation of each of the plurality of memory cells. | 08-02-2012 |
| 20120230126 | MEMORY VOLTAGE REGULATOR WITH LEAKAGE CURRENT VOLTAGE CONTROL - A voltage regulator for a memory that regulates a voltage provided to the memory cells based on a measured leakage current from a second set of memory cells. In one embodiment, based on the measured leakage current, the voltage to the cells is raised or lowered to control the amount of leakage current from the cells. | 09-13-2012 |
| 20120269009 | MEMORY ARRAY WITH TWO-PHASE BIT LINE PRECHARGE - An integrated circuit includes an array of memory cells with a plurality of columns and rows. A plurality of data lines is coupled to the columns in the array and a plurality of word lines is coupled to the rows in the array. Clamp transistors are coupled to respective data lines in the plurality of data lines, and adapted to prevent voltage on the respective bit lines from overshooting a target level during a precharge interval. A bias circuit is coupled to the clamp transistors on the plurality of bit lines, and arranged to apply the bias voltage in at least two phases within a precharge interval, and to prevent overshoot of the target level on the bit line. | 10-25-2012 |
| 20120287730 | NON-VOLATILE MEMORY DEVICE AND SENSING METHOD THEREOF - A non-volatile memory device and a sensing method thereof are disclosed, which can sense multi-level data using resistance variation. The non-volatile memory device includes a cell array and a sensing unit. The cell array includes a plurality of unit cells where data is read out or written. The sensing unit compares a sensing voltage corresponding to data stored in the unit cell with a reference voltage, amplifies/outputs the compared result, measures a difference in discharge time where the sensing voltage is discharged in response to a resistance value of the unit cell during an activation period of a sensing enable signal after a bit line is precharged, and senses the data in response to the measured result. | 11-15-2012 |
| 20120320687 | LOW VOLTAGE SENSING SCHEME HAVING REDUCED ACTIVE POWER DOWN STANDBY CURRENT - A low voltage sensing scheme reduces active power down standby leakage current in a memory device. A clamping device or diode is used between a Psense amplifier control line (e.g. ACT) and Vcc and/or between an Nsense amplifier control line (e.g. RNL*) and Vss (ground potential). The clamping diode is not enabled during normal memory operations, but is turned on during active power down mode to reduce leakage current through ACT and/or RNL* nodes. The clamping device connected to the ACT node may reduce the voltage on the ACT line during power down mode, whereas the clamping device connected to the RNL* node may increase the voltage on the RNL* line during power down mode to reduce sense amplifier leakage current through these nodes. Because of the rules governing abstracts, this abstract should not be used to construe the claims. | 12-20-2012 |
| 20130016573 | MEMORY DEVICE WITH TRIMMABLE POWER GATING CAPABILITIESAANM Goel; AnkurAACI KarnalAACO INAAGP Goel; Ankur Karnal INAANM Konudula; Venkateswara ReddyAACI BanagaloreAACO INAAGP Konudula; Venkateswara Reddy Banagalore INAANM Gowda; Sathisha NanjundeAACI HassanAACO INAAGP Gowda; Sathisha Nanjunde Hassan IN - A memory device includes at least one memory cell including a storage element electrically connected with a source potential line. A drive strength of the storage element is controlled as a function of a voltage level on the source potential line. The memory device further includes a clamp circuit electrically connected between the source potential line and a voltage source. The clamp circuit is operative to regulate the voltage level on the source potential line relative to the voltage source. A control circuit of the memory device is connected with the source potential line. The control circuit is operative to adjust the voltage level on the source potential line as a function of an operational mode of the memory device. A coarseness by which the voltage level on the source potential line is adjusted is selectively controlled as a function of at least a first control signal. | 01-17-2013 |
| 20130128676 | MEMORY DEVICE WITH AREA EFFICIENT POWER GATING CIRCUITRY - A memory device comprises a memory block, a power gating transistor, and control circuitry. The memory block includes at least one memory cell comprising a storage element electrically connected to a source potential line, a drive strength of the storage element being a function of a voltage level on the source potential line. The power gating transistor, in turn, is connected between the source potential line and a voltage source. The control circuitry is operative to configure the power gating transistor to electrically connect the source potential line to the voltage source while the memory block is in a first mode, and to clamp the source potential line at a voltage different from that of the voltage source when the memory block is in a second mode. | 05-23-2013 |
| 20130182512 | MEMORY CIRCUITS HAVING A PLURALITY OF KEEPERS - A circuit including a memory circuit, the memory circuit includes a first plurality of memory arrays and a first plurality of keepers, each keeper of the first plurality of keepers is electrically coupled with a corresponding one of the first plurality of memory arrays. The memory circuit further includes a first current limiter electrically coupled with and shared by the first plurality of keepers. | 07-18-2013 |
| 20130223161 | VDIFF MAX LIMITER IN SRAMS FOR IMPROVED YIELD AND POWER - An integrated circuit structure comprises a static random access memory (SRAM) structure and a logic circuit. A power supply is operatively connected to the SRAM structure, and provides a first voltage to the SRAM structure. A voltage limiter is operatively connected to the power supply. The voltage limiter comprises a switching device operatively connected to the power supply. The switching device receives the first voltage and a second voltage supplied to structures external to the SRAM structure. A resistive element is operatively connected to the switching device. The switching device connects the resistive element to the power supply. The resistive element is selected to enable an output from the switching device to the logic circuit when a difference between the first voltage and the second voltage is greater than a voltage threshold value of the switching device. | 08-29-2013 |
| 20130286754 | Wordline Coupling Reduction Technique - A semiconductor memory includes a memory array having memory cells coupled to wordlines and bitlines. Each wordline has a left end and an opposing right end. A first wordline in every two adjacent wordlines has its left end connected to a left row driver and its right end connected to a right clamp circuit, and a second wordline in every two adjacent wordlines has its right end connected to a right row driver and its left end connected to a left clamp circuit, such that when the right clamp circuits are activated, the right clamp circuits clamp the corresponding wordline ends to a predetermined potential, and when the left clamp circuits are activated, the left clamp circuits clamp the corresponding wordline ends to the predetermined potential. | 10-31-2013 |
| 20140078836 | USING A REFERENCE BIT LINE IN A MEMORY - Methods, memories and systems may include charging a sense node to a logic high voltage level, and supplying charge to a bit line and to a reference bit line for a precharge period that is based, at least in part, on a time for a voltage of the reference bit line to reach a reference voltage. A memory cell that is coupled to the bit line may be selected after the precharge period, and a clamp voltage may be set based, at least in part, on the voltage of the reference bit line. If a voltage level of the bit line is less than the clamp voltage level during a sense period, charge may be drained from the sense node, and a state of the memory cell may be determined based, at least in part, on a voltage level of the sense node near an end of the sense period. | 03-20-2014 |
| 20140153343 | LOW VOLTAGE SENSING SCHEME HAVING REDUCED ACTIVE POWER DOWN STANDBY CURRENT - A low voltage sensing scheme reduces active power down standby leakage current in a memory device. A clamping device or diode is used between a Psense amplifier control line (e.g. ACT) and Vcc and/or between an Nsense amplifier control line (e.g. RNL*) and Vss (ground potential). The clamping diode is not enabled during normal memory operations, but is turned on during active power down mode to reduce leakage current through ACT and/or RNL* nodes. The clamping device connected to the ACT node may reduce the voltage on the ACT line during power down mode, whereas the clamping device connected to the RNL* node may increase the voltage on the RNL* line during power down mode to reduce sense amplifier leakage current through these nodes. Because of the rules governing abstracts, this abstract should not be used to construe the claims. | 06-05-2014 |
| 20140355360 | HIGH SPEED AND LOW OFFSET SENSE AMPLIFIER - A sense amplifier includes a sensing circuit and an equalizing circuit. The sensing circuit is configured to supply one or more output signals according to one or more input signals. The equalizing circuit is configured to bring the sensing circuit to a metastable state from which the sensing circuit switches to an inverting state in response to a potential of the one or more input signals. Each transistor in the sensing circuit may switch to logic 0 or logic 1 faster and die-to-die PVT variations may be compensated, thereby providing high speed and low offset read operation. | 12-04-2014 |
| 20150029797 | MEMORY MACRO WITH A VOLTAGE KEEPER - A memory macro comprises a data line, a first interface circuit comprising a first node coupled to the data line, and a voltage keeper configured to control a voltage level at the first node, and a second interface circuit comprising a second node coupled with the data line, wherein the voltage keeper is configured to control a voltage level at the second node via the data line. | 01-29-2015 |
| 20150098279 | SENSING AMPLIFIER AND SENSING METHOD THEREOF - A sensing amplifier comprising a clamp circuit is provided. The clamp circuit is coupled between a first node and a second node. The clamp circuit comprises a first P-type transistor having a first terminal, a second terminal and a control terminal receiving a first bias signal, the first terminal and the second terminal of the first P-type transistor are coupled to the first node and the second node, respectively, and a sensing current from the memory cell flows into the second node via the first node during a sensing time period. | 04-09-2015 |
