Entries |
Document | Title | Date |
20080197882 | LOGIC CIRCUITS - A logic circuit includes a logic unit, a driving unit, and a voltage level adjuster. The logic unit includes an output node having a logic state, the logic unit being coupled to a first voltage reference. The driving unit includes an input node, the driving unit being coupled to a second voltage reference, the driving unit and the first logic unit being constructed from a single type of transistor. The voltage level adjuster provides a control signal that causes the driving unit to reduce a current flowing through the driving unit when the output node of the first logic unit has a first logic state, and causes the driving unit to drive an output node of the logic circuit to a voltage level substantially equal to that of the second voltage reference when the output node of the first logic unit has a second logic state. | 08-21-2008 |
20080204077 | LEVEL SHIFTER - A level shifter for shifting an input signal to an output signal. The level shifter includes an input buffer biased a first voltage and a ground voltage; an output buffer and a level-processing unit both biased between a second voltage and the ground voltage; and a voltage-drop unit coupled to the level-processing unit and biased between the first voltage and the second voltage. While the first voltage is in an OFF state and the second voltage is switched on, the voltage-drop unit provides an initializing voltage for the level-processing unit according to the second voltage to shift the input signal to provide the output signal. | 08-28-2008 |
20080231322 | Circuit Device and Method of Controlling a Voltage Swing - In particular illustrative embodiments, circuit devices and methods of controlling a voltage swing are disclosed. The method includes receiving a signal at an input of a digital circuit device including a capacitive node. The method also includes selectively activating a voltage level adjustment element to regulate an electrical discharge path from the capacitive node to an electrical ground to prevent complete discharge of the capacitive node. In a particular illustrative embodiment, the received signal may be a clock signal. | 09-25-2008 |
20080231323 | INTEGRATED CIRCUIT CHIP WITH IMPROVED ARRAY STABILITY - A multi-threshold integrated circuit (IC) that may be supplied by multiple supplies, with an array of latches such as an array static random access memory (SRAM) cells and a CMOS SRAM with improved stability and reduced subthreshold leakage. Selected devices (NFETs and/or PFETs) in array cells and support logic, e.g., in the data path and in non-critical logic, are tailored for lower gate and subthreshold leakage. Normal base FETs have a base threshold and tailored FETs have a threshold above. In a multi-supply chip, circuits with tailored FETs are powered by an increased supply voltage. | 09-25-2008 |
20080265940 | INTERFACE CIRCUIT - An interface circuit according to one aspect of the present invention may includes a receiving circuit operating on a supply voltage lower than a high-level voltage value of an input binary signal, an input level determination circuit generating an input level determination signal having a frequency higher than a frequency of the binary signal and controls whether to output the input level determination signal or not, based on a voltage level of the binary signal, and an AC coupling element connected between an output terminal of the input level determination circuit and an input terminal of the receiving circuit. | 10-30-2008 |
20080284468 | METHOD AND APPARATUS FOR CONTROLLING A COMMUNICATION SIGNAL BY MONITORING ONE OR MORE VOLTAGE SOURCES - An integrated circuit is capable of controlling a communication signal by using power ramp controlled communication buffer logic to generate an outgoing communication signal based on a detected voltage on a voltage source. The voltage source is necessary to supply power for power ramp controlled communication buffer logic. The voltage on the voltage source may be detected using power ramp sensor logic. The outgoing communication signal is based on a core logic output signal if the detected voltage is greater than or equal to a predetermined voltage level. If, the detected voltage is less than the predetermined voltage level, the outgoing communication signal is predetermined to be one of: a tristate outgoing communication signal, a logic one outgoing communication signal and a logic zero outgoing communication signal. Power ramp controlled communication buffer logic may also generate a core logic input signal based on an incoming communication signal in response to the detected voltage. | 11-20-2008 |
20080315918 | Thin film transistor logic - A thin-film logic circuit, which can be fabricated entirely of TFTs of the same conductivity type, includes a logic stage connected to a supply voltage and a level shifter connected to a wider voltage range provided by the supply voltage and ground. The logic circuit produces output signals with full rail-to-rail signal range from ground to the supply voltage and can implement or include a basic logic component such as an inverter, a NAND gate, or a NOR gate or more complicated circuits in which many basic logic components are cascaded together. Such logic circuits can be fabricated directly on flexible structures or large areas such as in flat panel displays. | 12-25-2008 |
20090002027 | LEVEL SHIFTER HAVING LOW DUTY CYCLE DISTORTION - A level shifter includes an inverting circuit, a cross-coupled level shifting latch, and a SR logic gate latch. The first and second outputs of the level shifting latch are coupled to the set (S) and reset (R) inputs of the SR latch. The inverting circuit, that is powered by a first supply voltage VDDL, supplies a noninverted version of an input signal onto a first input of the level shifting latch and supplies an inverted version of the input signal onto a second input of the level shifting latch. A low-to-high transition of the input signal resets the SR latch, whereas a high-to-low transition sets the SR latch. Duty cycle distortion skew of the level shifter is less than fifty picoseconds over voltage, process and temperature corners, and the level shifter has a supply voltage margin of more than one quarter of a nominal value of VDDL. | 01-01-2009 |
20090002028 | MIXED-VOLTAGE I/O BUFFER TO LIMIT HOT-CARRIER DEGRADATION - A Mixed-voltage input and output (I/O) buffer including a pre-driver unit, a bulk-voltage generating unit, a first to a third transistors and an input stage unit is provided. The pre-driver unit outputs a first source/drain and a second signal. The bulk-voltage generating unit determines whether a first voltage or a pad voltage is used as a bulk voltage according to the pad voltage level. A gate of the first transistor receives the first signal, and a bulk, a first source/drain and a second source/drain of the first transistor are respectively coupled to the bulk voltage, the first voltage and the pad. A gate of the third transistor receives the second signal, and a first source/drain and a second source/drain of the third transistor are respectively coupled to the input stage unit for receiving an input signal from the pad and a second voltage. | 01-01-2009 |
20090002029 | TEST CONTROL CIRCUIT AND REFERENCE VOLTAGE GENERATING CIRCUIT HAVING THE SAME - A test control circuit according to an embodiment of the invention includes a test mode control unit that outputs a control signal according to a voltage trimming test signal, a decoding portion that receives the control signal and outputs a decoding signal, and a trimming signal adjusting portion that receives the decoding signal and outputs a trimming signal adjusted by a low level test signal. | 01-01-2009 |
20090015292 | Semiconductor device having transfer gate between pre-buffer and main buffer - A semiconductor device includes a pre-buffer for transferring a data signal on the basis of a first power supply voltage, a main buffer for amplifying and outputting the data signal transferred by the pre-buffer on the basis of a second power supply voltage different from the first power supply voltage, a switch unit for controlling a conductive state between the pre-buffer and the main buffer on the basis of a switch control signal, and a control circuit for generating the switch control signal for controlling the pre-buffer to set an output level of the pre-buffer to ground potential in accordance with transition of logical level of the switch control signal. | 01-15-2009 |
20090045843 | LEVEL SHIFTER CIRCUIT WITH PRE-CHARGE/PRE-DISCHARGE - A level shifter circuit and method of operating therefor. The level shifter circuit is coupled to receive a data signal via an input circuit, wherein the input circuit is in a first voltage domain. The level shifter circuit is also coupled to receive a clock signal from a second voltage domain. On a first portion of the clock cycle, true and complementary output nodes of the level shifter circuit (which are in the second voltage domain) are pulled to a first voltage by activation of respective pull transistors. On a second portion of the clock cycle, one of the true or complementary output nodes is pulled to a second voltage on a second voltage node by enabling the supply to the latch. Data is captured by the keeper, outputting true and complementary versions of the data signal in the second phase of the clock. | 02-19-2009 |
20090058465 | Circuit Combining Level Shift Function with Gated Reset - A circuit ( | 03-05-2009 |
20090066367 | INPUT OUTPUT DEVICE FOR MIXED-VOLTAGE TOLERANT - An input output device coupled between a core circuit and a pad and including an output cell, an input cell, and a pre-driver. The output cell includes an output stage and a voltage level converter. The output stage includes a first transistor and a second transistor connected to the first transistor in serial between a first supply voltage and a second voltage. The voltage level converter generates a first gate voltage to the first transistor according to the first voltage and a data signal. When the first supply voltage is increased, the first gate voltage is increased. When the data signal is at a high level, the first transistor is turned on. The input cell includes a pull unit and a first N-type transistor. The pre-driver turns off the first and the second transistors. | 03-12-2009 |
20090108871 | METHODS, DEVICES, AND SYSTEMS FOR A HIGH VOLTAGE TOLERANT BUFFER - Methods, devices, and systems are disclosed, including those for a buffer having pre-driver circuitry configured to provide voltages to thin-gate dielectric transistors One such buffer may comprise a primary pull-up pre-driver operably coupled to a primary pull-up transistor, a secondary pull-up pre-driver operably coupled to a secondary pull-up transistor, a primary pull-down pre-driver operably coupled to a primary pull-down transistor, and a secondary pull-down pre-driver operably coupled to a secondary pull-down transistor. Each of the primary pull-up pre-driver, the secondary pull-up pre-driver., primary pull-down pre-driver, and the secondary pull-down pre-driver are configured to provide a voltage to a gate of a transistor operably coupled thereto at a voltage level so as to sustain gate dielectric integrity of the transistor. | 04-30-2009 |
20090115455 | VOLTAGE LEVEL TRANSLATION - A virtual zero delay unidirectional high voltage logic to low voltage CMOS logic voltage level translator can be achieved using a capacitive voltage divider coupled with the standard protection diodes commonly incorporated in low side logic (e.g. Xilinx Spartan-3E FPGA's). The complete voltage level translator will work equally well on frequencies from DC up to the rated operational frequency of the driver and receiver. Load side parasitic CMOS input capacitance in this case is ironically an asset rather than a liability since it can be used effectively as one element of the capacitive voltage divider. High voltage logic (e.g. 0 to 5V) can thus interface to lower voltage CMOS logic (e.g. 2.5V or 3.3V) with a minimum of additional external components and with virtually zero time delay. | 05-07-2009 |
20090115456 | Level shift circuit and method for the same - The present invention discloses a level shift circuit which comprises: a basic level shift circuit for receiving inputs of first high and low operational voltage levels and generating outputs of second low and high operational voltage levels at a first node; and an output circuit for outputting a signal of one of the second operational voltage levels according to a voltage level switching at the first node. | 05-07-2009 |
20090140769 | System-in-package - A System-in-Package includes a first chip to be mounted in common for a plurality of product types, a second chip having different specifications for each product type, and a wiring substrate being common to a plurality of product types, on which the first chip and the second chip are to be mounted. A setting signal is supplied from the second chip to the first chip. | 06-04-2009 |
20090160485 | Providing Higher-Swing Output Signals When Components Of An Integrated Circuit Are Fabricated Using A Lower-Voltage Process - An output block fabricated using a lower-voltage process provides output signals with a higher voltage swing. The output block contains a differential amplifier portion and a hold circuit portion. The differential amplifier portion is activated only when the logic level of an output signal needs to be switched. Once the logic level is switched, the hold circuit portion maintains the logic level. As a result, high switching speeds may be achieved with relatively low power consumption. The circuits of the output block are also designed so that no constituent components are subjected to excessive voltages, thereby providing enhanced reliability. | 06-25-2009 |
20090184731 | Apparatus and method of adjusting driving voltage for selective pre-charge - An output of a driving circuit is controlled by selectively outputting a first voltage or a second voltage as an N-th output voltage level in response to a first control signal and an N-th input voltage level, where N is a natural number, and pre-charging the selected N-th output voltage level to a third voltage or a fourth voltage, in response to a second control signal, the pre-charging being preformed based on the selected N-th output voltage level and a newly input (N+1)th input voltage level. | 07-23-2009 |
20090189639 | CIRCUITS AND METHODS FOR COMMUNICATING DATA BETWEEN DOMAINS DURING VOLTAGE AND FREQUENCY SHIFTING - When communicating data between different voltage and frequency domains, for example chiplets, in an integrated circuit, the data signals can be formatted to compensate for propagation delays and different operating frequencies between the domains, and the signaling voltage level of the formatted data signals can then be changed from the operating voltage of the transmitting domain to the operating voltage of the receiving domain so that the formatted and changed data signals can be transmitted. As such, voltage crossings are combined with frequency crossings, which can have the effect of hiding the voltage shifting within the propagation delays. | 07-30-2009 |
20090195268 | Level Shifting Circuit and Method - In a particular embodiment, a method includes receiving an input voltage at an input to a level shifting circuit that includes voltage pull-up logic. The method includes providing an output signal from the level shifting circuit. The method also includes selectively activating the voltage pull-up logic circuit of the level shifting circuit. | 08-06-2009 |
20090206878 | LEVEL SHIFT CIRCUIT FOR A DRIVING CIRCUIT - Provided is a level shift circuit for a driving circuit. The level shift circuit includes: a cross-coupled transistor pair, for receiving a first input signal and a second input signal and for providing a first output signal and a second output signal; a first transistor, coupled to a first power supply and to the cross-coupled transistor pair, further receiving a first control signal; a second transistor, coupled to the cross-coupled transistor pair and for receiving a second control signal; and a third transistor, coupled to the cross-coupled transistor pair and for receiving the second control signal. The first control signal, the second control signal, the first output signal and the second output signal are all referenced to the first power supply, and the first input signal and the second input signal are referenced to a second power supply lower than the first power supply. | 08-20-2009 |
20090267648 | Apparatus for configuring I/O signal levels of interfacing logic circuits - Apparatus for configuring input/output signal levels of interfacing logic circuits operating at different voltage levels comprises: a logic circuit for operating at a first voltage level; a bank of input/output gates coupled to the logic circuit for interfacing input/output signals at a second voltage level, different from the first voltage level, to the logic circuit, the bank of gates including a port for setting the operational voltage level thereof; and a control circuit coupled to the port and governed by a control signal to configure the operational voltage level of the bank of gates to render the logic circuit and the interfacing input/output signals voltage level compatible. | 10-29-2009 |
20090278567 | SEMICONDUCTOR DIGITAL CIRCUIT, FIFO BUFFER CIRCUIT, AND DATA TRANSFERRING METHOD - A FIFO buffer circuit is provided which, in data transmission between two circuit areas having different combinations of a power supply voltage and an operation clock frequency, can perform a voltage level conversion and a clock rate conversion at the same place at the same time. In an input side area | 11-12-2009 |
20090284282 | LEVEL SHIFTER - Input transistors have sources which are connected to a first input reference node and gates to which a pair of input signals are input. Input-side voltage relaxing transistors have sources connected to drains of the pair of input transistors and gates connected to a second input reference node. Output-side voltage relaxing transistors have sources connected to output nodes, gates connected to a first output reference node, and drains connected to drains of the input-side voltage relaxing transistors. First and second inverter circuits are in correspondence with the output nodes, and are connected between second and third output reference nodes. Each of the first and second inverter circuits also supplies a voltage at one of the second and third output reference nodes to its corresponding one of the output nodes, depending on a voltage at its non-corresponding one of the output nodes. | 11-19-2009 |
20090295429 | BIDIRECTIONAL BUFFER CIRCUIT AND SIGNAL LEVEL CONVERSION CIRCUIT - A bidirectional buffer circuit includes a first terminal, a second terminal, a first output buffer to which a signal from the first terminal is input and which outputs the signal to the second terminal, a first one-shot buffer control circuit outputting a first control signal according to an earlier arriving signal out of a signal from the first terminal and a signal from the second terminal, a first one-shot buffer temporarily driving the second terminal by the first control signal, a second output buffer to which a signal from the second terminal is input and which outputs the signal to the first terminal, a second one-shot buffer control circuit outputting a second control signal according to an earlier arriving signal out of a signal from the first terminal and a signal from the second terminal, and a second one-shot buffer temporarily driving the first terminal by the second control signal. | 12-03-2009 |
20100026343 | CLOCKED SINGLE POWER SUPPLY LEVEL SHIFTER - First circuitry is powered by a first power supply domain and provides a data signal referenced to the first power supply domain. Second circuitry is powered by a second power supply domain that differs from the first power supply domain. The data signal becomes referenced to the second power supply domain by a clocked level shifter that couples the first circuitry to the second circuitry and buffers the data signal from the first power supply domain to the second power supply domain by only using a single supply voltage. The clocked level shifter is clocked by a signal that is used to precharge a first node and a second node of the clocked level shifter until the data signal is valid for at least a setup time period. The first and second nodes are precharged to establish a known state in the clocked level shifter. | 02-04-2010 |
20100060320 | SIGNAL DRIVER CIRCUIT HAVING AN ADJUSTABLE OUTPUT VOLTAGE - Processor-based systems, memories, signal driver circuits, and methods of generating an output signal are disclosed. One such signal driver circuit includes a signal driver configured to generate an output signal at an output node in response to an input signal and a transistor coupled to the signal driver that is configured to couple and decouple the output node and the voltage supply according to a control signal. A voltage comparator circuit coupled to the output node and the transistor is configured to generate the control signal to control coupling and decoupling of the output node and the voltage supply through the transistor based on a voltage of the output signal relative to the reference voltage. | 03-11-2010 |
20100102850 | SEMICONDUCTOR DEVICE - A semiconductor device includes an inductor configured to supply a current to a first node based on a higher voltage region power supply voltage. A first switch is configured to selectively supply a current from the first node into a third node based on a voltage on a second node; a second switch is configured to selectively supply a current from the first node into the second node based on a voltage of the third node; a third switch is configured to supply the current from the third node into a ground terminal based on a lower voltage region input logic level; and a fourth switch is configured to be turned ON/OFF alternately with the third switch to supply the current from the second node to the ground terminal. | 04-29-2010 |
20100117682 | Level-Shifter Circuit - One embodiment of the invention includes a level-shifter circuit. The circuit comprises a control stage that steers a current from one of a first control node and a second control node to the other of the first control node and the second control node based on an input signal to set a first initial voltage at the first control node and a second initial voltage at the second control node, the input signal having logic-high and logic-low voltage magnitudes that occupy a low voltage domain. The circuit also includes a logic driver that is coupled to the second control node and is referenced in a high voltage domain. The logic driver can be configured to provide an output signal having logic-high and logic-low voltage magnitudes that occupy the high voltage domain based on the second initial voltage. | 05-13-2010 |
20100123478 | LEVEL SHIFT CIRCUIT - A level shift circuit shifts a first voltage level to a second voltage level that is different from the first voltage level. The level shift circuit includes a set-level circuit | 05-20-2010 |
20100123479 | LEVEL-SHIFT CIRCUIT - A level-shift circuit converts a first voltage level into a second voltage level different from the first voltage level. The level-shift circuit includes a first high-side signal detection circuit, a second high-side signal detection circuit, a drive circuit and electric current detection circuits. The first high-side signal detection circuit sets a logical voltage state of the second voltage level via a first capacitor. The second high-side signal detection circuit resets the logical voltage state of the second voltage level via a second capacitor. The drive circuit on-off drives a high-side switch connected to a low-side switch in series by a set signal of the first high-side signal detection circuit and a reset signal of the second high-side signal detection circuit. The electric current detection circuits detect an electric current flowing into or from the first and/or second capacitors. | 05-20-2010 |
20100164544 | OUTPUT DRIVER FOR USE IN SEMICONDUCTOR DEVICE - An output driver for use in a semiconductor device includes a first pre-drive unit, a second pre-drive unit, and a main drive unit. The first pre-drive unit generates a pull-up drive control signal based on a data signal. The pull-up drive control signal swings between a power supply voltage level and a low voltage level. The data signal swings between the power supply voltage level and a ground voltage level. The second pre-drive unit generates a pull-down drive control signal based on the data signal. The pull-down drive control signal swings between a high voltage level and the ground voltage level. The main drive unit performs pull-up/down drive operations to an output terminal in response to the pull-up/down drive control signals, respectively. Herein, the high voltage level is higher than the power supply voltage level and the low voltage level is lower than the ground voltage level. | 07-01-2010 |
20100164545 | INTERFACE SYSTEM - An interface system delivers an output signal having a first signal characteristic in response to first and second input signals having the first signal characteristic and a second, different signal characteristic. The interface system includes a signal input for receiving a first signal having a first signal characteristic and a second signal having a second signal characteristic which is different from the first signal characteristic, a detector circuit for detecting whether the signal at the input is the first signal or the second signal, and a translator circuit for translating either of the first signal or the second signal into the output signal. | 07-01-2010 |
20100194433 | LEVEL SHIFTER AND SEMICONDUCTOR DEVICE HAVING OFF-CHIP DRIVER - Provided are a level shifter and a semiconductor device having an OFF-chip driver (OCD) using the same. The level shifter includes a plurality of series connected logic gates receiving a first-state input signal having a first power supply voltage level and generating a level-shifted first-state output signal having a second power supply voltage level. The logic gates receive as power supply voltages at least one intermediate power supply voltage having at least one voltage level intermediate between the first power supply voltage level and the second power supply voltage level, and an intermediate power supply voltage applied to the present logic gate is equal to or higher than an intermediate power supply voltage applied to the previous logic gate. | 08-05-2010 |
20100225352 | Integrated circuit with pin-selectable mode of operation and level-shift functionality and related apparatus, system, and method - An apparatus includes a digital interface circuit configured to provide a digital interface. The digital interface is configurable based on a mode of operation of the digital interface circuit. The apparatus also includes input and output level-shift circuits. The input level-shift circuit is configured to shift a voltage level of an input signal for the digital interface circuit. The output level-shift circuit is configured to shift a voltage level of an output signal from the digital interface circuit. The input level-shifting and the output level-shifting are based on first and second level-shift input voltages. The apparatus further includes a mode detector configured to identify at least two modes of operation for the digital interface circuit based on the first and second level-shift input voltages. For example, the digital interface circuit could be configured to function as a serial or parallel interface depending on which level-shift input voltage is greater. | 09-09-2010 |
20100231258 | SEMICONDUCTOR INTEGRATED CIRCUIT - A semiconductor integrated circuit includes logic circuits connected in a plurality of stages, a voltage-level inverting unit that is inserted in a signal transmission path of the logic circuits and inverts a voltage level input to the logic circuits, and an inversion-timing control unit that controls inversion timing for the voltage level inverted by the voltage-level inverting unit. | 09-16-2010 |
20100259299 | VOLTAGE CONVERSION AND INTEGRATED CIRCUITS WITH STACKED VOLTAGE DOMAINS - An integrated circuit (IC) system includes a plurality of ICs configured in a stacked voltage domain arrangement such that a low side supply rail of at least one of ICs is common with a high side supply rail of at least another of the ICs; a reversible voltage converter coupled to power rails of each of the plurality of ICs, the reversible voltage converter configured for stabilizing individual voltage domains corresponding to each IC; and one or more data voltage level shifters configured to facilitate data communication between ICs operating in different voltage domains, wherein an input signal of a given logic state corresponding to one voltage in a first voltage domain is shifted to an output signal of the same logic state at another voltage in a second voltage domain. | 10-14-2010 |
20100271069 | INPUT/OUTPUT CIRCUIT AND INTEGRATED CIRCUIT APPARATUS INCLUDING THE SAME - An input/output circuit includes an I/O node connected to a pull up and pull down circuit having a pull up and pull down transistors. Data is sent and received at through the I/O node. A level shifter provides voltages including a supply voltage and a high voltage higher than the supply voltage. A signal control circuit controls the voltage level applied to the pull up and pull down circuit. During a data input mode, data is received at the I/O node and the pull up transistor is biased at the high voltage to cut off the pull up transistor. During a data output mode, data is output at the I/O node and the pull down transistor pulls down the I/O node to ground when the output data is low, and the pull up transistor is activated when the output data is high. | 10-28-2010 |
20100295575 | DIGITAL LEVEL SHIFTER AND METHODS THEREOF - A digital level shifter is disclosed that receives an input voltage from a first voltage domain, and provides an output voltage to a second voltage domain. The level shifter includes transistors configured in parallel with input transistors of the level shifter in order to place the output of the level shifter in a determinate state when one of the voltage domains is placed in a low power state. Further, the level shifter includes output transistors configured to equalize a rise time slew rate and fall time slew rate, improving the reliability of the level shifter as the voltage in each voltage domain varies. | 11-25-2010 |
20100295576 | Circuit Arrangement and Method for Shifting a Voltage Level - A circuit arrangement for shifting a voltage level comprises a data-current converter ( | 11-25-2010 |
20100327909 | Keeper circuit - Provided is a novel keeper circuit with a pull-up device whose strength changes for different operating supply levels so that the pull-up device is weaker for smaller supply levels and stringer for higher supply levels. | 12-30-2010 |
20110006809 | LEVEL CONVERSION CIRCUIT AND SOLID-STATE IMAGING DEVICE USING THE SAME - According to one embodiment, a level conversion circuit includes an intermediate voltage generating portion to generate an intermediate voltage between a first voltage and a second voltage upon receiving the first voltage and the second voltage higher than the first voltage. A buffer portion operates on the intermediate voltage upon receiving a first signal and an inverted first signal of a first amplitude corresponding to the first voltage. The buffer portion outputs a second signal and an inverted second signal having a second amplitude corresponding to the intermediate voltage. A level shift portion operates on the second voltage upon receiving the second signal and the inverted second signal, and outputs a third signal and an inverted third signal having a third amplitude corresponding to the second voltage. | 01-13-2011 |
20110018583 | HIGH VOLTAGE LOGIC CIRCUITS - High voltage logic circuits that can handle digital input and output signals having a larger voltage range are described. In an exemplary design, a high voltage logic circuit includes an input stage, a second stage, and an output stage. The input stage receives at least one input signal and provides (i) at least one first intermediate signal having a first voltage range and (ii) at least one second intermediate signal having a second voltage range. The second stage receives and processes the first and second intermediate signals based on a logic function and provides (i) a first drive signal having the first voltage range and (ii) a second drive signal having the second voltage range. The output stage receives the first and second drive signals and provides an output signal having a third voltage range, which may be larger than each of the first and second voltage ranges. | 01-27-2011 |
20110121860 | SEMICONDUCTOR DEVICE - A semiconductor device includes a swing level shifting unit configured to use a first power supply voltage as a power supply voltage, receive a CML clock swinging around a first voltage level, and shift a swing reference voltage level of the CML clock to a second voltage level lower than the first voltage level, and a CML clock transfer buffering unit configured to use a second power supply voltage as a power supply voltage and buffer the CML clock, which is transferred from the swing level shifting unit and swings around the second voltage level. | 05-26-2011 |
20110156753 | DUAL LOOP LEVEL SHIFTER - A method and apparatus are disclosed to control one or more input output (I/O) pads. An input signal is translated to an output signal having a desired logic level using a first latch loop. The state of the first latch loop is maintained by a second latch loop, integrated with the first latch loop, when a latching indication is received. The integration between the first latch loop and the second latch loop is such that the second latch loop creates an input-output connection if transmission gates in the second latch loop are conductive, and disables the input-output connection if the transmission gates are not conductive. | 06-30-2011 |
20110193592 | VOLTAGE LEVEL SHIFTER WITH DYNAMIC CIRCUIT STRUCTURE HAVING DISCHARGE DELAY TRACKING - An apparatus is disclosed. In a particular embodiment, the apparatus includes a a dynamic circuit structure that includes a dynamic node coupling a precharge circuit, a discharge circuit, and a gated keeper circuit. The gated keeper circuit is enabled by a signal from a discharge delay tracking circuit. | 08-11-2011 |
20110254591 | INPUT AND OUTPUT BUFFER INCLUDING A DYNAMIC DRIVER REFERENCE GENERATOR - A system having an input and output buffer includes a dynamic driver reference generator to generate dynamic driver reference signals based on a data signal and an IO buffer supply voltage, a level shifter to generate level shifted signals based, in part, on the dynamic driver reference signals, and a driver having at least one stress transistor. The driver dynamically adjusts a voltage across the stress transistor based on at least one of dynamic driver reference signals, the level shifted signals, and a current state of an IO pad. | 10-20-2011 |
20110316586 | LOW-VOLTAGE TO HIGH-VOLTAGE LEVEL TRANSLATION USING CAPACITIVE COUPLING - A voltage level translator circuit has a digital logic circuit having a digital logic signal at least one high-voltage capacitor having a first and second connection, wherein one of the first and second connections is electrically coupled to the digital logic signal, and a cross-coupled inverter pair having, the output of at least one inverter of the pair electrically coupled to the other connection of the at least one high-voltage capacitor. A high-voltage driving circuit has two low-voltage input signals, two high-voltage output signals, a first signal being a high-side drive signal and a second signal being a low-side drive signal, two level translators, a first level translator corresponding to the high-side drive signal, and a second level translator corresponding to the low-side drive signal, the level translators including a digital logic circuit having a digital logic signal, at least one high-voltage capacitor having a first and second connection, wherein one of the first and second connections is electrically coupled to the digital logic signal, and a cross-coupled inverter pair having, the output of at least one inverter of the pair electrically coupled to the other connection of the at least one high-voltage capacitor. | 12-29-2011 |
20120169371 | INPUT BUFFER SYSTEM WITH A DUAL-INPUT BUFFER SWITCHING FUNCTION AND METHOD THEREOF - An input buffer system with a dual-input buffer switching function includes a first input buffer, a second input buffer, and a multiplexer. The first input buffer is used for outputting a first signal when an input signal is at a logic-high voltage, and the first input buffer is turned off when the input signal is at a logic-low voltage. The second input buffer is used for outputting a second signal when the input signal is at the logic-low voltage. The multiplexer is coupled to the first input buffer and the second input buffer for outputting the first signal or the second signal according to a self refresh signal. | 07-05-2012 |
20120212256 | Mode Latching Buffer Circuit - A voltage translator circuit includes an input stage adapted for receiving an input signal referenced to a first voltage supply, a first latch circuit adapted for connection with a second voltage supply and operative to at least temporarily store a logic state of the input signal, and a voltage clamp coupled between the input stage and the first latch circuit. The voltage clamp is operative to set a maximum voltage across the input stage to a prescribed level. The voltage translator circuit generates a first output signal at a first output formed at a junction between the first latch circuit and the voltage clamp. A second latch circuit is connected to the first output in a feedback configuration. The second latch circuit is operative to retain a logical state of the first output signal as a function of at least a first control signal supplied to the second latch circuit regardless of a state of the first voltage supply. | 08-23-2012 |
20120256656 | HIGH VOLTAGE LATCHING AND DC RESTORATION ISOLATION AND LEVEL SHIFTING METHOD AND APPARATUS - A device and method for dc isolation and level shifting includes a driver circuit powered by a first voltage range, a capacitor connected to the driver circuit, and a latching circuit connected to the capacitor. The latching circuit is powered by a second voltage range and is configured to restore and/or minimize charge loss of the capacitor during a voltage transition at the capacitor. A device and method for analog isolation and measurement configured to measure an analog voltage at a second potential without requiring analog circuits at the second potential. | 10-11-2012 |
20120286823 | SEMICONDUCTOR DEVICE - A semiconductor device in which an input terminal is electrically connected to a first terminal of a first transmission gate; a second terminal of the first transmission gate is electrically connected to a first terminal of a first inverter and a second terminal of a functional circuit; a second terminal of the first inverter and a first terminal of the functional circuit are electrically connected to a first terminal of a second transmission gate; a second terminal of the second transmission gate is electrically connected to a first terminal of a second inverter and a second terminal of a clocked inverter; a second terminal of the second inverter and a first terminal of the clocked inverter are electrically connected to an output terminal; and the functional circuit includes a data holding portion between a transistor with small off-state current and a capacitor. | 11-15-2012 |
20130015882 | Compact and Robust Level Shifter Layout DesignAANM Datta; AnimeshAACI San DiegoAAST CAAACO USAAGP Datta; Animesh San Diego CA USAANM Goodall, III; William JamesAACI CaryAAST NCAACO USAAGP Goodall, III; William James Cary NC US - Method and apparatus for voltage level shifters (VLS) design in bulk CMOS technology. A multi-voltage circuit or VLS that operate with different voltage levels and that provides area and power savings for multi-bit implementation of level shifter design. A two-bit VLS to shift bits from a first voltage level logic to a second voltage level logic. The VLS formed with a first N-well in a substrate. The VLS formed with a second N-well in the substrate, adjacent to a side of the first N-well. The VLS formed with a third N-well in the substrate, adjacent to a side of the first N-well and opposite the second N-well. A first one-bit VLS circuit having a portion formed on the first N-well and a portion formed on the second N-well. A second bit VLS circuit having a portion formed on the first N-well and a portion formed on the third N-well. | 01-17-2013 |
20130027082 | VOLTAGE LEVEL SHIFTER, DECOUPLER FOR A VOLTAGE LEVEL SHIFTER, AND VOLTAGE SHIFTING METHOD - A voltage level shifter for translating a binary input signal representing a binary sequence to a binary output signal representing the same binary sequence. The voltage level shifter comprises an input port for receiving the binary input signal as an input voltage varying between a first input voltage level and a second input voltage level. An output port is connected to a node for outputting the binary output signal as an output voltage varying between a first output voltage level and a second output voltage level. A supply voltage node connectable to a voltage supply, can provide the second output voltage level. A first switch is arranged to couple the supply voltage node to the node and to decouple the supply voltage node from the node based on a voltage at the node. A feedback voltage loop is connected to the node for providing a feedback voltage based on the voltage at the node. A second switch is connected to the feedback voltage loop and arranged to couple the input port to the node based on a voltage at the input port and the feedback voltage. A decoupler and a voltage shifting method are also disclosed. | 01-31-2013 |
20130043903 | RADIATION-TOLERANT LEVEL SHIFTING - A system and method for radiation-tolerant level shifting are disclosed. In some embodiments, an integrated circuit may include a plurality of level shifters, where each of the plurality of level shifters configured receive a same logic level in a first voltage domain and to output candidate logic levels in a second voltage domain, and where at least one of the candidate logic levels subject to being different from another one of the candidate logic levels. The integrated circuit may also include a voting circuit coupled to the plurality of level shifters, where the voting circuit is configured to evaluate the candidate logic levels and output a selected logic level based, at least in part, upon the evaluation. | 02-21-2013 |
20130147517 | SEMICONDUCTOR DEVICE AND OPERATION METHOD THEREOF - A semiconductor device includes a clock delay unit configured to delay a source clock by a given delay amount and generate a delayed source clock, a driving signal generation unit configured to decide logic levels of first and second driving signals based on a value of input data, to select one of the source clock and the delayed source clock based on current logic levels of the first and second driving signals, which are detected based on the source clock, and to use a selected clock as a reference of an operation for determining next logic levels of the first and second driving signals, and an output pad driving unit configured to drive a data output pad with a first voltage in response to the first driving signal, and to drive the data output pad with a second voltage in response to the second driving signal. | 06-13-2013 |
20130162294 | LEVEL SHIFT CIRCUIT AND DRIVE CIRCUIT OF DISPLAY DEVICE - In a level shift circuit, input signals are input into gates of a first and a second MOS transistors whose sources are coupled to a first supply voltage VSS. Gates of a third and a fourth MOS transistors whose sources are coupled to a second supply voltage are coupled to drains of the second and the first MOS transistors. A first voltage generation circuit is coupled between the drains of the first and the third MOS transistors, and a second voltage generation circuit is coupled between the drains of the second and the fourth MOS transistors. The gate of the fifth MOS transistor is coupled to a connection node NDB, and the source of the fifth MOS transistor is coupled to the second supply voltage. | 06-27-2013 |
20130181741 | LEVEL SHIFTERS AND INTEGRATED CIRCUITS THEREOF - An integrated circuit including a first level shifter configured to receive a first input signal and a first power supply signal, and to output a first output signal. The integrated circuit further includes a first inverter configured to receive the first output signal, and to output a first inverter signal. The integrated circuit further includes a second level shifter configured to receive a second input signal and a second power supply signal, and to output a second output signal, wherein a voltage level of the second power supply signal is different from a voltage level of the first power supply signal. The integrated circuit further includes a second inverter configure to receive the second output signal, and to output a second inverter signal. The integrated circuit further includes an output buffer configured to receive the first inverter signal and the second inverter signal, and to output a buffer output signal. | 07-18-2013 |
20130321026 | VOLTAGE COMPENSATED LEVEL-SHIFTER - Described herein is a voltage compensated level-shifter with nearly constant duty cycle and matching rise and fall slopes of the output of the level-shifter, no meta-stability, and nearly constant propagation delay across power supply levels. The voltage compensated level-shifter comprises a first inverter to receive an input signal for level shifting from a first power supply level to a second power supply level, and to generate a first inverted signal, the first inverter operating on the first power supply level; a second inverter to receive the input signal and to generate a second inverted signal, the second inverter operating on the second power supply level; and a NOR logical gate to receive the first and second inverted signals and to generate an output signal, the NOR logical gate operating on the second power supply level, wherein the output signal is level shifted to the second power supply level. | 12-05-2013 |
20140002133 | APPARATUS FOR MIXED SIGNAL INTERFACE ACQUISITION CIRCUITRY AND ASSOCIATED METHODS | 01-02-2014 |
20140077840 | Low Swing Dynamic Circuit - Embodiments of the present disclosure enable low swing dynamic circuits with reduced dynamic power and leakage power. In an embodiment, a level detector circuit monitors the pre-charge voltage level of the dynamic node of a dynamic circuit and discontinues the charging of the dynamic node when the pre-charge voltage exceeds a logic high reference voltage. The logic high reference voltage is selected below a supply voltage of the dynamic circuit, resulting in a low swing dynamic circuit. In another embodiment, the pull-down logic circuitry is disconnected from the dynamic node when the dynamic node voltage falls below a logic low reference voltage, above a ground voltage. In another embodiment, a DC keeper circuit of the dynamic circuit is configured based on the pre-charge level of the dynamic node. | 03-20-2014 |
20140091836 | MULTI-DIMENSIONAL DATA REGISTRATION INTEGRATED CIRCUIT FOR DRIVING ARRAY-ARRANGEMENT DEVICES - The multi-dimensional data registration integrated circuit for driving array-arrangement devices, comprising: a plurality of the i-th hierarchy sets, each of the i-th hierarchy sets is divided into a plurality of the (i+1)-th hierarchy sets; a i-th hierarchy address selection circuit, comprising a signal generation unit and a multiplexing unit, wherein the former generates an enable signal, the latter is connected to the signal generating unit and shifts the input data based on the enable signal and a second timing signal to further generate n bits of address signals, the i-th hierarchy address selection circuit is used to scan the plurality of the i-th hierarchy sets and select at least one of the i-th hierarchy sets to function; and a data supply circuit to follow a scan sequence of a j-th hierarchy address selection circuit and write a plurality of data into the selected j-th hierarchy sets. | 04-03-2014 |
20140159773 | INTEGRATED CIRCUIT INCLUDING CIRCUITS DRIVEN IN DIFFERENT VOLTAGE DOMAINS - Provided is an integrated circuit including circuits driven in different voltage domains. The integrated circuit includes a logic circuit configured to be driven by a first power supply voltage having a first power supply voltage level, and a memory circuit configured to be driven by a second power supply voltage having a second power supply voltage level different from the first power supply voltage level. The memory circuit includes a circuit configured to interface with the logic circuit, configured to be supplied with power at the second power supply voltage level in response to an output signal, and configured to shift a level of a signal having the first power supply voltage level received from the logic circuit to the second power supply voltage level. The first power supply voltage corresponds to a first voltage domain, and the second power supply voltage corresponds to a second voltage domain. | 06-12-2014 |
20140210516 | Level Shifter Circuit Optimized for Metastability Resolution and Integrated Level Shifter and Metastability Resolution Circuit - A level shifter and integrated level shifter and metastability resolution flop circuit are disclosed. A circuit includes a generation circuit, in a first voltage domain, coupled to receive a logic signal via a single-ended input and configured to generate true and complementary values of the logic signal. The circuit further includes a storage circuit coupled to receive the true and complementary values of the logic signal from the generation circuit. The storage circuit is configured to store the true and complementary values of the logic signal. The storage circuit is in a second voltage domain. The circuit further includes an output circuit coupled to the storage circuit and configured to provide a differential output signal having true and complementary values corresponding to the true and complementary values of the logic signal. The circuit may be combined with a latch circuit coupled to receive the differential output signal. | 07-31-2014 |
20140210517 | HIGH-VOLTAGE LEVEL-SHIFTER - Described herein is a high-voltage level-shifter (HVLS) that can be used for both NMOS and PMOS bridges, exhibits a higher voltage tolerance for over-clocking than traditional level-shifters, has reduced crowbar current in its input driver, and no contention in its output driver. The HVLS comprises an input driver including a first signal conditioning unit, the input driver operating on a first power supply level and for conditioning an input signal as a first signal in the first signal conditioning unit; and a circuit to receive the first signal and to provide a second signal based at least in part on the first signal, the second signal being level-shifted from the first power supply level to a second power supply level, wherein the second power supply level is higher than the first power supply level. | 07-31-2014 |
20140320168 | LEVEL SHIFTER CIRCUIT AND OPERATION METHOD THEREOF - A level shifter transfers a first voltage signal to a second voltage signal. The level shifter comprises a comparison circuit, a delay circuit, and a selection circuit. The comparison circuit generates a first signal according to the comparison result between the first voltage signal and the reverse-phase signal of the first voltage signal. The delay circuit generates a second signal according to the first voltage signal. The selection circuit receives the first and the second signals and chooses the higher voltage one from the first signal and the second signal to be the second voltage signal. | 10-30-2014 |
20140340119 | VOLTAGE LEVEL SHIFTER AND SYSTEMS IMPLEMENTING THE SAME - According to the inventive concepts disclosed herein, a level shifter can include an input node in a first voltage domain and an output node in a second voltage domain, higher than the first voltage domain. The input node receives an input signal in the first, lower-voltage domain, and the output node is configured to output a representation of the input signal in the second, higher-voltage domain. A lower-voltage control circuit can control a supply of the lower-voltage level to a boundary node arranged at a boundary between the first and second domains. A higher-voltage control circuit can also be provided to control a supply of the higher-voltage level to the boundary node. The lower-voltage control circuit can cut off the lower-voltage supply to the boundary node when the higher-voltage control circuit supplies the higher-voltage level to the boundary node. The higher-voltage control circuit can, for instance, include logic circuitry that enables and disables a connection to the higher-voltage supply. Alternatively, the higher-voltage control circuit can include a boost capacitor coupled between the output node and the boundary node. | 11-20-2014 |
20150022238 | APPARATUSES AND METHODS FOR LINE CHARGE SHARING - Apparatuses and methods for charge sharing, between signal lines are disclosed. An example apparatus may include first and second lines and a charge sharing circuit The charge sharing circuit may be coupled to the first line and the second line and configured to receive a first data signal and a second data signal. The charge sharing circuit may be further configured to cause charge to be shared between the first line and the second line responsive, at least in part, to the first data signal and the second data signal having different logic levels. | 01-22-2015 |
20150109026 | ELECTRONIC DEVICE ASSEMBLY - An electronic device assembly includes a master device, and a plurality of peripheral devices. The master device includes a signal reading unit, a layer identification unit, and a selecting and controlling unit. The plurality of peripheral devices is coupled to the master device and connected one by one in series. The signal reading unit is configured to read layer signals from the plurality of peripheral devices, the layer identification unit is configured to identify a layer information of the plurality of peripheral devices according to the layer signals; and the selecting and controlling unit is configured to select and control one or more of the plurality of peripheral electronic devices according to the layer information. | 04-23-2015 |
20160105179 | LEVEL SHIFTING AN I/O SIGNAL INTO MULTIPLE VOLTAGE DOMAINS - Embodiments disclosed herein include an I/O module with multiple level shifters that establish a plurality of voltage domains. Using the level shifters, the I/O module converts data signals in a core logic voltage domain to data signals in an external voltage domain. In one embodiment, when transmitting data signals to an external device, the I/O module level shifts the data signals from a core logic voltage domain to a low voltage domain. The I/O module then level shifts the data signals from the low voltage domain to an intermediate voltage domain. The I/O module may further shift the data signals from the intermediate voltage domain to both a low voltage domain and a high voltage domain. Using the data signals from both of these domains, the I/O module outputs the data signals in a voltage domain corresponding to a communication technique used to transmit data to the external device. | 04-14-2016 |
20160105182 | LEVEL SHIFTING AN I/O SIGNAL INTO MULTIPLE VOLTAGE DOMAINS - Embodiments disclosed herein include an I/O module with multiple level shifters that establish a plurality of voltage domains. Using the level shifters, the I/O module converts data signals in a core logic voltage domain to data signals in an external voltage domain. In one embodiment, when transmitting data signals to an external device, the I/O module level shifts the data signals from a core logic voltage domain to a low voltage domain. The I/O module then level shifts the data signals from the low voltage domain to an intermediate voltage domain. The I/O module may further shift the data signals from the intermediate voltage domain to both a low voltage domain and a high voltage domain. Using the data signals from both of these domains, the I/O module outputs the data signals in a voltage domain corresponding to a communication technique used to transmit data to the external device. | 04-14-2016 |
20160118985 | CIRCUIT ARRANGEMENT AND METHOD OF OPERATING THE SAME - A circuit arrangement may be provided including a level shifting stage configured to be coupled to a first reference voltage and a second reference voltage. The circuit arrangement may also include a first input electrode in electrical connection with the level shifting stage for coupling a first input voltage and a second input electrode in electrical connection with the level shifting stage for coupling a second input voltage. The level shifting stage may be configured to generate an output voltage above a predetermined output level at the output node due to the first reference voltage when the first input voltage is in the first logic state and the second input voltage is in the second logic state. The circuit arrangement may also include a feedback circuit coupled to the output stage and the level shifting stage and a voltage stabilization circuit coupled to the level shifting stage. | 04-28-2016 |
20160142055 | SEMICONDUCTOR DEVICE - A semiconductor device includes a first circuit applying an enable signal having a first logic level and a clock signal having the first logic level, supplying a first voltage to a first node and converting a voltage level of the first node into a second logic level different from the first logic level, and a second circuit applying an enable signal having the second logic level and a clock signal having the first logic level, supplying a second voltage to a second node different from the first node and converting a voltage level of the second node into the second logic level. The second circuit includes an operation circuit performing a NAND operation on the logic level of the enable signal and the voltage level of the second node, and a switch turned on in response to an output of the operation circuit and supplying the second voltage to the second node. | 05-19-2016 |