Patent application number | Description | Published |
20090302914 | Pad input signal processing circuit - A pad input signal processing circuit includes a control unit for setting a level of a pad output terminal to which a first control signal is input in response to a power up signal, and a signal output unit for outputting a command signal in response to a signal of the pad output terminal and a second control signal. | 12-10-2009 |
20100085815 | Command Generation circuit and semiconductor memory device - There is provided a command generation circuit. The command generation circuit includes a first driving unit driving an output node in response to an internal MRS command and a RAS idle signal; a second driving unit driving the output node in response to an off-signal; and a latch unit latching a signal at the output node in response to a power-up signal and generating an SRR command. | 04-08-2010 |
20100085816 | Flag signal generation circuit and semiconductor memory device - There is provided a flag signal generation circuit. The flag signal generation circuit includes a status register read (SRR) signal generating unit receiving an idle signal and an SRR command to generate an SRR signal; a pulse signal generating unit receiving an SRR signal to generate a pulse signal; and a flag signal generating unit receiving the pulse signal and a read signal for SRR to generate a flag signal. | 04-08-2010 |
20100327839 | DRIVING CONTROLLER AND INTERNAL VOLTAGE GENERATION CIRCUIT - A driving controller for use in stabilizing transient voltages from power supplies is presented. The driving controller includes a first pulse generator, a second pulse generator, and a control signal generator. The first pulse generator is configured to generate a power-up pulse signal including a pulse activating at a time of terminating a power-up period. The second pulse generator is configured to generate a detection pulse signal including a pulse that is being active from a time when an internal voltage reaches a predetermined level. The control signal generator is configured to generate an operation control signal, which controls a driving controller activating the internal voltage, in response to the power-up pulse signal and the detection pulse signal. | 12-30-2010 |
20110241761 | FUSE CIRCUIT WITH ENSURED FUSE CUT STATUS - A fuse circuit includes a fuse information signal generation unit and an output driving unit. The fuse information signal generation unit is configured to precharge a fuse information signal in response to a precharge signal and drive the fuse information signal in response to a selection signal capable of cutting a fuse. The output driving unit configured to equally maintain potentials at both terminals of the fuse in response to a control signal. | 10-06-2011 |
20110241762 | FUSE CIRCUIT - A fuse circuit includes a fuse, a control pulse generation unit, and an equipotential element. The fuse is coupled between a power supply voltage terminal and a first node. The control pulse generation unit is configured to generate a control pulse including a pulse generated in a period in which a power-up period is ended. The equipotential element is configured to make the first node have the same potential as a power supply voltage in response to the control pulse. | 10-06-2011 |
20120008420 | Command Generation Circuit And Semiconductor Memory Device - There is provided a command generation circuit. The command generation circuit includes a first driving unit driving an output node in response to an internal MRS command and a RAS idle signal; a second driving unit driving the output node in response to an off-signal; and a latch unit latching a signal at the output node in response to a power-up signal and generating an SRR command. | 01-12-2012 |
20120170396 | SEMICONDUCTOR MEMORY DEVICE - A semiconductor memory device includes a temperature sensor configured to generate a low-temperature signal which is enabled at below first set temperature and a high-temperature signal which is enabled at above second set temperature; a start signal generator configured to receive a refresh command and generate a start signal according to the low-temperature signal; and an address counter configured to count refresh addresses in response to the start signal. | 07-05-2012 |
20130033944 | INTERNAL VOLTAGE GENERATION CIRCUIT - An internal voltage generation circuit includes: a selection unit configured to select one of first and second reference voltages as a selection reference voltage in response to a self refresh signal and a power-down mode signal and output the selection reference voltage; a driving signal generation unit configured to compare the selection reference voltage with a negative word line voltage applied to an unselected word line and generate a driving signal; and a driving unit configured to change the negative word line voltage in response to the driving signal. | 02-07-2013 |
20130308394 | REFRESH METHOD AND SEMICONDUCTOR MEMORY DEVICE USING THE SAME - A semiconductor memory device includes an all bank select signal generation block configured to receive level signals including information on at least one bank which has been refreshed, and generate all bank select signals, in response to an all bank refresh command; and a bank block including a plurality of banks which are configured to be refreshed in response to the all bank select signals or are refreshed in response to per bank select signals which are enabled when the level signals are enabled. | 11-21-2013 |
20140016418 | SEMICONDUCTOR MEMORY DEVICE - A semiconductor memory device includes a first core region and a second core region disposed along a first reference line parallel to a major axis, the first reference line connecting an input pad and an output pad; first and second cell blocks disposed in the first core region along the first reference line; third and fourth cell blocks disposed in the second core region along the first reference line; and a repeater positioned between the third and fourth cell blocks, and configured to receive data outputted from the first cell block or the second cell block, amplify the received data and transfer the amplified data to a second global input/output line. Reducing the number of needed global input/output lines leads to layout area reduction. Moreover, since repeaters are driven in read operations for a limited number of cell blocks, signal gain may be reduced, thus reducing overall power consumption. | 01-16-2014 |