Patent application number | Description | Published |
20080258813 | Sense Amplifiers Operated Under Hamming Distance Methodology - A semiconductor device includes a first sense amplifier coupled to an input for generating a first output; a second sense amplifier couple to the input for generating a second output; and a third sense amplifier coupled to the input for generating a third output, wherein a fourth output amplifying the input is generated based on combinations of logic states of the first, second and third outputs. | 10-23-2008 |
20090290446 | Memory Word-line Tracking Scheme - A word-line tracking system for a memory array having a plurality of memory cells, the word-line tracking system comprises a dummy row having substantially identical structure as one or more regular rows of the memory cells, the dummy row including a dummy word-line having a first and a second end at the opposite longitudinal ends of the dummy word-line, the first end being connected to a word-line driver, a self timing generator configured to receive a clock signal and generate a pulse signal in sync with the clock signal for the dummy word-line driver, the self timing generator having a first terminal for receiving a feedback signal to determine the falling edge of the pulse signal, a voltage-to-current converter connected to the second end of the dummy word-line, a current-to-voltage converter connected to the feedback terminal, and a wire connecting the voltage-to-current converter to the current-to-voltage converter. | 11-26-2009 |
20110158007 | MULTI-POWER DOMAIN DESIGN - In some embodiments related to a memory array, a sense amplifier (SA) uses a first power supply, e.g., voltage VDDA, while other circuitry, e.g., signal output logic, uses a second power supply, e.g., voltage VDDB. Various embodiments place the SA and a pair of transferring devices at a local IO row, and a voltage keeper at the main IO section of the same memory array. The SA, the transferring devices, and the voltage keeper, when appropriate, operate together so that the data logic of the circuitry provided by voltage VDDB is the same as the data logic of the circuitry provided by voltage VDDA. | 06-30-2011 |
20110188326 | DUAL RAIL STATIC RANDOM ACCESS MEMORY - A static random access memory (SRAM) macro includes a first power supply voltage and a second power supply voltage that is different from the first power supply voltage. A precharge control is connected to the second power supply voltage. The precharge control is coupled to a bit line through a bit line precharge. At least one level shifter receives a level shifter input. The level shifter converts the level shifter input having a voltage level closer to the first power supply voltage than the second power supply voltage to a level shifter output having a voltage level closer to the second power supply voltage than the first power supply voltage. The level shifter output is provided to the precharge control. | 08-04-2011 |
20110194362 | WORD-LINE DRIVER USING LEVEL SHIFTER AT LOCAL CONTROL CIRCUIT - A representative circuit device includes a local control circuit having a level shifter, wherein in response to receipt of a first address signal the level shifter shifts the first address signal from a first voltage level to a second voltage level, providing a level shifted first address signal; and a word-line driver having at least one input for receiving a plurality of address signals, wherein the at least one input includes a first input that is coupled to the local control circuit to receive the level shifted first address signal, and an output that is electrically coupled to a word line of a memory cell array. | 08-11-2011 |
20120020176 | GENERATING AND AMPLIFYING DIFFERENTIAL SIGNALS - Some embodiments regard a circuit comprising: a first left transistor having a first left drain, a first left gate, and a first left source; a second left transistor having a second left drain, a second left gate, and a second left source; a third left transistor having a third left drain, a third left gate, and a third left source; a first right transistor having a first right drain, a first right gate, and a first right source; a second right transistor having a second right drain, a second right gate, and a second right source; a third right transistor having a third right drain, a third right gate, and a third right source; a left node electrically coupling the first left drain, the second left drain, the second left gate, the third right gate, and the third left drain; and a right node electrically coupling the first right drain, the second right drain, the second right gate, the third left gate, and the third right drain. | 01-26-2012 |
20120061764 | MODIFIED DESIGN RULES TO IMPROVE DEVICE PERFORMANCE - The layouts, device structures, and methods described above utilize dummy devices to extend the diffusion regions of edge structures and/or non-allowed structures to the dummy device. Such extension of diffusion regions resolves or reduces LOD and edge effect issues. In addition, treating the gate structure of a dummy device next to an edge device also allows only one dummy structure to be added next to the dummy device and saves the real estate on the semiconductor chip. The dummy devices are deactivated and their performance is not important. Therefore, utilizing dummy devices to extend the diffusion regions of edge structures and/or non-allowed structures according to design rules allows the resolution or reduction or LOD and edge effect issues without the penalty of yield reduction or increase in layout areas. | 03-15-2012 |
20120092939 | SINGLE-ENDED SENSING SCHEME FOR MEMORY - A memory having a single-ended sensing scheme includes a bit line, a memory cell coupled to the bit line, and a precharge circuit. The precharge circuit is configured to precharge the bit line to a precharge voltage between a power supply voltage and a ground. | 04-19-2012 |
20120195139 | MULTI-POWER DOMAIN DESIGN - In some embodiments related to a memory array, a sense amplifier (SA) uses a first power supply, e.g., voltage VDDA, while other circuitry, e.g., signal output logic, uses a second power supply, e.g., voltage VDDB. Various embodiments place the SA and a pair of transferring devices at a local IO row, and a voltage keeper at the main IO section of the same memory array. The SA, the transferring devices, and the voltage keeper, when appropriate, operate together so that the data logic of the circuitry provided by voltage VDDB is the same as the data logic of the circuitry provided by voltage VDDA. | 08-02-2012 |
20120206953 | MEMORY EDGE CELL - A circuit comprises a first PMOS transistor, a second PMOS transistor, a first NMOS transistor, a second NMOS transistor, a third NMOS transistor, and a fourth NMOS transistor. The PMOS transistors and the NMOS transistors are configured to provide a first voltage reference node having a first reference voltage and a second voltage reference node having a second reference voltage. The first reference voltage and the second reference voltage serve as a first reference voltage and a second reference voltage for a memory cell, respectively. | 08-16-2012 |
20130010560 | GENERATING AND AMPLIFYING DIFFERENTIAL SIGNALS - A circuit includes a first node, a second node, a first current mirror circuit, and a second current minor circuit. The first current mirror circuit has a reference end and a mirrored end. The reference end of the first current minor circuit is coupled to the first node, and the mirrored end of the first current minor circuit is coupled to the second node. The second current minor circuit has a reference end and a mirrored end. The reference end of the second current minor circuit is coupled to the second node, and the mirrored end of the second current minor circuit is coupled to the first node. | 01-10-2013 |
20130094307 | BIT LINE VOLTAGE BIAS FOR LOW POWER MEMORY DESIGN - In a digital memory with an array of bit cells coupled to word lines and bit lines, each bit cell having cross coupled inverters isolated from bit lines by passing gate transistors until addressed, some or all of the bit cells are switchable between a sleep mode and a standby mode in response to a control signal. A bit line bias circuit controls the voltage at which the bit lines are caused to float when in the sleep mode. A pull-up transistor for each bit line BL or BLB in a complementary pair has a conductive channel coupled to a positive supply voltage and a gate coupled to the other bit line in the pair, BLB or BL, respectively. A connecting transistor also can be coupled between the bit lines of the complementary pair, bringing the floating bit lines to the supply voltage less a difference voltage ΔV. | 04-18-2013 |
20130128655 | METHOD AND APPARATUS FOR DUAL RAIL SRAM LEVEL SHIFTER WITH LATCHING - An apparatus includes a level shifter and a switching circuit. The level shifter includes an input, a first output, and second output having a logic value complementary to a logic value of the first output. The switching circuit includes a data input, a feedback input coupled to the second output of the level shifter, and an output coupled to the input of the level shifter. The switching circuit is configured to selectively latch, based on a select signal, a logic state of the level shifter at the second output. | 05-23-2013 |
20130194860 | Tracking for Write Operations of Memory Devices - Some aspects of the present disclosure relate to write tracking techniques for memory devices. In some embodiments, a memory device includes an array of SRAM cells, wherein each SRAM cell includes a pair of cross-coupled inverters having complimentary storage nodes, and a pair of access transistors that allow selective access to the complimentary storage nodes, respectively. To help ensure that wordline and bitline pulses are of sufficient length and intensity, one or more write tracking cells track a wordline tracking signal, which is representative of a wordline pulse applied to a wordline. In response to the wordline tracking signal, the write tracking cell internally generates a signal that models bitline loading, and provides an output tracking signal based on the wordline tracking and bitline loading signals. Bitline and/or wordline pulses can then be set based on the output tracking signal. | 08-01-2013 |
20130194877 | MEMORY AND METHOD OF OPERATING THE SAME - A memory includes a plurality of memory blocks, a plurality of global bit lines, a common pre-charging circuit, and a selection circuit. Each memory block includes a pair of bit lines, and a plurality of memory cells coupled to the pair of bit lines. Each global bit line is coupled to at least one of the memory blocks. The pre-charging circuit is configured to pre-charge the global bit lines, one at a time, to a pre-charge voltage. The selection circuit is coupled between the pre-charging circuit and the global bit lines, and configured to couple the global bit lines, one at a time, to the pre-charging circuit. | 08-01-2013 |
20130208533 | MEMORY HAVING READ ASSIST DEVICE AND METHOD OF OPERATING THE SAME - A memory includes a first bit line, a memory cell coupled to the first bit line, and a read assist device coupled to the first bit line. The read assist device is configured to pull a first voltage on the first bit line toward a predetermined voltage in response to a first datum being read out from the memory cell. The read assist device includes a first circuit configured to establish a first current path between the first bit line and a node of the predetermined voltage during a first stage. The read assist device further includes a second circuit configured to establish a second current path between the first bit line and the node of the predetermined voltage during a second, subsequent stage. | 08-15-2013 |
20130286708 | MEMORY EDGE CELL - A column of a memory includes a first edge cell and at least one memory cell. The first edge cell is located at a first edge of the column and includes a first edge cell reference node and a second edge cell reference node. Each of the at least one memory cells includes a first memory reference node. The first edge cell reference node is coupled to respective first memory reference nodes of the at least one memory cell. The second edge cell reference node serves as second memory reference nodes of the at least one memory cell. Front-end layers of the first edge cell are the same as front-end layers of a memory cell of the at least one memory cell. | 10-31-2013 |
20130311964 | MODIFIED DESIGN RULES TO IMPROVE DEVICE PERFORMANCE - A method of designing a layout of devices includes designing a layout of gate structures and diffusion regions of a plurality of devices. The method further includes identifying an edge device of the plurality of devices. The method further includes adding a dummy device next to the edge device and a dummy gate structure next to the dummy device, wherein the dummy device shares a diffusion region with the edge device, and wherein a gate structure of the dummy device is considered to be one of two dummy gate structures added next to the edge device. | 11-21-2013 |
20140035664 | VOLTAGE PROVIDING CIRCUIT - A voltage providing circuit includes a first circuit, a second circuit coupled with the first circuit, and a third circuit coupled with the second circuit. The first circuit is configured to receive a first input signal and to generate a first output signal. The second circuit is configured to receive the first input signal and the first output signal as inputs and to generate a second output signal. The third circuit is configured to receive the second output signal and to generate an output voltage. | 02-06-2014 |
20140036608 | TRACKING SIGNALS IN MEMORY WRITE OR READ OPERATION - A signal generating circuit includes a first circuit, a tracking circuit, and a delay circuit coupled with the first circuit and the tracking circuit. The first circuit is configured to receive a first clock signal and an output signal from an output of the delay circuit and to generate a second clock signal and at least one first tracking signal. The tracking circuit is configured to receive the at least one first tracking signal and to generate a second tracking signal. The delay circuit is configured to receive the second clock signal and the second tracking signal and to generate the output signal. | 02-06-2014 |
20140084374 | CELL DESIGN - One or more techniques or systems for designing a cell are provided. The cell generally includes one or more transistors, such as a pass gate transistor, a pull up transistor, or a pull down transistor, respectively associated one or more gate to gate distances. In some embodiments, a second gate to gate distance is selected based on a first gate to gate distance. For example, the first gate to gate distance and the second gate to gate distance are associated with a first transistor. In another example, the first gate to gate distance is associated with a first transistor and the second gate to gate distance is associated with a second transistor. In this manner, a cell design is provided to improve a static noise margin (SNM) or a write margin (WM) for the cell, for example. | 03-27-2014 |
20140211570 | Memory Read Techniques using Miller Capacitance Decoupling Circuit - Some embodiments relate to a sense amplifier output buffer configured to buffer an output of a sense amplifier. The sense amplifier output buffer includes a first pull-up element having a source coupled to a first DC supply terminal and having a drain coupled to an output terminal of the sense amplifier output buffer. A first pull-down element is in series with the first pull-up element and has a source coupled to a second DC supply terminal and has a drain coupled to the output terminal. A miller capacitance decoupling circuit is coupled between the drain of the first pull-up element and the drain of the first pull-down element. The miller capacitance decoupling circuit is configured to decouple miller capacitance associated with the drains of the pull-up and pull-down elements from the output terminal. Other embodiments are also disclosed. | 07-31-2014 |
20140266436 | Sense Amplifier - The present disclosure relates to a differential sense amplifier comprising first and second cross-coupled inverters with first and second complimentary storage nodes. A first current control element changes a current through the first cross-coupled inverter based upon an output of a second cross-coupled inverter, and a second current control element changes a current through the second cross-coupled inverter based upon an output of the first cross-coupled inverter. Other devices and methods are also disclosed. | 09-18-2014 |
20140269128 | SENSE AMPLIFIER - A sense amplifier includes a cross latch, a first pass gate, a second pass gate, a first data line, a second data line, a first circuit, and a second circuit. The cross latch has a first input/output (I/O) node and a second I/O node. The first pass gate is coupled between the first data line and the first I/O node. The second pass gate is coupled between the second data line and the second I/O node. The first circuit is coupled with the first I/O node and the second data line. The second circuit is coupled with the second I/O node and the first data line. The first circuit is configured to be turned off when the second data line has a first logical value and to be at least lightly turned on when the second data line has a voltage level between the first logical value and a second logical value different from the first logical value. The second circuit is configured to be turned off when the first data line has the first logical value and to be at least lightly turned on when the first data line has a voltage level between the first logical value and the second logical value. | 09-18-2014 |
20150021701 | MEMORY CELL ARRAY - A semiconductor memory cell array is disclosed that includes a memory cell unit. The memory cell unit includes an active region, a first transistor, a second transistor, a gate structure, and an interconnect. The first transistor and the second transistor are formed on the active region. The gate structure is formed on the active region and between the first transistor and the second transistor. The interconnect connects the gate structure and at least one of sources of the first transistor and the second transistor to a power line. | 01-22-2015 |