Patent application number | Description | Published |
20090091998 | POWER SAVING METHOD AND CIRCUIT THEREOF FOR A SEMICONDUCTOR MEMORY - A power saving method for a semiconductor memory is provided. The power saving method for a semiconductor memory including the steps of receiving a plurality of address codes, each of which has a first part code and a second part code; and activating a first boost process when the first part code of a currently received address code is different from the first part code of a last received address code, otherwise a second boost process is activated. | 04-09-2009 |
20100182834 | TWISTED DATA LINES TO AVOID OVER-ERASE CELL RESULT COUPLING TO NORMAL CELL RESULT - Over-erasure induced noise on a data line in a nonvolatile memory that couples into an adjacent data line is mitigated by using twisted data lines and differential sensing amplifiers. Noise coupled into data lines is compensated by similar noise coupled into reference data lines and cancelled in the differential sensing amplifiers. | 07-22-2010 |
20100202213 | Current-Mode Sense Amplifying Method - A sense amplifying method, applied in a memory having a memory cell and a reference cell, includes: charging the memory cell and the reference cell to have a cell current and a reference current, respectively; duplicating the cell current and the reference current to respectively generate a mirrored cell current via a first current path and a mirrored reference current via a second current path and equalizing a first voltage drop generated as the mirrored cell current flows by the first current path and a second voltage drop generated as the mirrored reference current flows by the second current path; and removing the equalization of the first voltage drop and the second voltage drop and adjusting first voltage drop and the second voltage drop according to a first current flowing by the first current path and a second current flowing by the second current path. | 08-12-2010 |
20100301918 | Level Shifter and Level Shifting Method Thereof - A level shifter includes a first level-switching device and a second level-switching device. The first level-switching device includes a first switch device, a second switch device, a first control switch and a third switch device. The first switch device is for receiving the input voltage and outputting a first voltage. The second switch device is coupled to the first switch device for outputting a first operational voltage as the output voltage according to the first voltage. The first control switch is coupled to the first switch device for receiving the first voltage. The third switch device is coupled between the first control switch and the first operational voltage and controlled by the output voltage. The second level-switching device is coupled to the first level-switching device for receiving the input voltage and accordingly outputting a second operational voltage as the output voltage. | 12-02-2010 |
20110032771 | Memory and Reading Method Thereof - A reading method applied for a memory, which includes a cell row including a first memory cell coupled to a first bit line and a second memory cell coupled to a second bit line is provided. The reading method comprises the following steps. Firstly, the first bit line coupled to a first terminal of the first memory cell is selected for reading the first memory cell in a time period. Next, the second terminal of the first memory cell is discharged via the second bit line coupled to the second memory cell in the time period. | 02-10-2011 |
20110161718 | Command Decoding Method and Circuit of the Same - A decoding circuit for decoding a command is provided. The received command is transmitted during at least two clock periods of a clock signal, and the received command is divided to a former encoded data and a latter encoded data. The decoding circuit includes a pre-trigger signal generating unit, a comparing unit, and a starting signal generating unit. The pre-trigger signal generating unit receives the former encoded data and generates a pre-trigger signal when the former encoded data of the received command matches the corresponding former encoded data of a predetermined command. The comparing unit generates a match signal when the latter encoded data of the received command is the same with the latter encoded data of the predetermined command. The starting signal generating unit outputs a starting signal according to the pre-trigger signal and the match signal. The starting signal starts a corresponding operation of the predetermined command. | 06-30-2011 |
20130246836 | COMMAND DECODING METHOD AND CIRCUIT OF THE SAME - A decoding circuit includes a pre-trigger signal generating unit, a comparing unit, and a starting signal generating unit. The pre-trigger signal generating unit receives the former encoded data and generates a pre-trigger signal when the former encoded data of the received command matches the corresponding former encoded data of a predetermined command. The comparing unit generates a match signal when the latter encoded data of the received command is the same with the latter encoded data of the predetermined command. The starting signal generating unit outputs a starting signal according to the pre-trigger signal and the match signal. The starting signal starts a corresponding operation of the predetermined command. | 09-19-2013 |
20130285737 | Charge Pump System - In one aspect, a first charge pump has serially arranged charge pump stages. Inter-stage nodes between adjacent stages are pumped by a second charge pump. In another aspect, timing of the charge pump stages is controlled by at a command clock signal. The command clock signal and command data are communicated between a integrated circuit with the charge pump and an external circuit. | 10-31-2013 |
Patent application number | Description | Published |
20080232164 | METHOD FOR PROGRAMMING A MULTILEVEL MEMORY - A method for programming a MLC memory is provided. The MLC memory has a number of bits, and each bit has a number of programmed states. Each programmed state has a first PV level. The method comprises programming the bits of the memory having a Vt level lower than the first PV level of the targeted programmed state such that at least one bit of them has a Vt level larger than a second PV level corresponding to a targeted programmed state, wherein the second PV level of the targeted programmed state is larger than the corresponding first PV level; and programming only the bits of the memory with a Vt level lower than the first PV level of the targeted programmed state such that each of them has a Vt level larger than the first PV level of the targeted programmed state. | 09-25-2008 |
20080291722 | Charge trapping memory and accessing method thereof - An accessing method for a charge trapping memory including memory cells and tracking cells for storing expected data. The method includes the following steps. In a specific time first, the expected data is written into the tracking cells and the memory cells are not being programmed, read or erased. Next, the data stored in the tracking cells is sensed as read data according to a present reference current. Then, the present reference current is adjusted to an adjusted reference current according to a difference between the read data and the expected data so that the data stored in tracking cells is sensed as corresponding with the expected data according to the adjusted reference current. Thereafter, the memory cells are read according to the adjusted reference current. | 11-27-2008 |
20080310223 | Method for programming a multilevel memory - A method for programming a MLC memory is provided. The MLC memory has a number of bits, and each bit has a number of programmed states. Each programmed state has a first PV level. The method comprises (a) programming the bits of the memory having a Vt level lower than the PV level of a targeted programmed state into programmed bits by using a Vd bias BL; (b) ending this method if each bit of the memory has a Vt level not lower than the PV level of the targeted programmed state, otherwise, continuing the step (c); and (c) setting BL=BL+K | 12-18-2008 |
20090058508 | Word line boost circuit and method - A word line boost circuit includes a first pump circuit, a first transistor, a voltage detection circuit and a second pump circuit. The first pump circuit provides a gate boosted signal according to an address transfer detection (ATD) signal. The first transistor has a control terminal for receiving the gate boosted signal and a second terminal coupled to a target word line. The voltage detection circuit is for detecting a voltage level of the gate boosted signal and accordingly outputting a detection signal. The second pump circuit is for outputting a boost signal to a first terminal of the first transistor according to a voltage level of the detection signal. The boost signal boosts the target word line via the turned-on first transistor. | 03-05-2009 |
20090116293 | Memory and method for charging a word line thereof - A memory and method for charging a word line thereof are disclosed. The memory includes a first word line driver, a first word line and a first switch. The first word line driver is connected to a first operational voltage for receiving a first control signal. The first word line comprises a start terminal connected to an output terminal of the first word line driver. The first switch is connected to a second operational voltage and an end terminal of the first word line. The second operational voltage is not smaller than the first operational voltage. When the first word line driver is controlled by the first control signal to start charging up the first word line, the first switch is simultaneously turned on to provide another charging path for the first word line until the first word line is charged to the first operational voltage. | 05-07-2009 |
20090303792 | METHOD FOR PROGRAMMING A MULTILEVEL MEMORY - A method for programming a MLC memory is provided. The MLC memory has a number of bits, and each bit has a number of programmed states. Each programmed state has a first PV level. The method comprises (a) programming the bits of the memory having a Vt level lower than the PV level of a targeted programmed state into programmed bits by using a Vd bias BL; (b) ending this method if each bit of the memory has a Vt level not lower than the PV level of the targeted programmed state, otherwise, continuing the step (c); and (c) setting BL=BL+K | 12-10-2009 |
20120063228 | DATA SENSING ARRANGEMENT USING FIRST AND SECOND BIT LINES - Over-erasure induced noise on a data line in a nonvolatile memory that couples into an adjacent data line is mitigated by using twisted data lines and differential sensing amplifiers. Noise coupled into data lines is compensated by similar noise coupled into reference data lines and cancelled in the differential sensing amplifiers. | 03-15-2012 |
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 |
20130286764 | CIRCUIT AND METHOD FOR ADDRESS TRANSITION DETECTION - A new address transition detection (ATD) circuit for use on an address bus having a plurality of address signal lines comprises a first circuit for each address signal line and a second circuit. The first circuit has a first input, a second input and an output. The first input is coupled to an address signal line. The second input is coupled to an ATD signal. The first circuit saves the current level of the first input in response to an ATD pulse on the ATD signal and generates a change signal at its output by comparing the current level and the saved level of the first input. The second circuit has an input and an output. The second circuit receives on its input the change signal from the first circuit. In response, the second circuit generates the ATD pulse on the ATD signal at its output. | 10-31-2013 |