| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 326063000 | Logic level shifting (i.e., interface between devices of different logic families) | 84 |
| 20080197880 | SOURCE DRIVER AND LEVEL SHIFTING METHOD THEREOF - The present invention provides a source driver comprising a shift register, a line buffer for storing a data signal and outputting a buffered data signal, and a level shifter for generating a level-shifted data signal based on the buffered data signal. The line buffer further comprises a charge pump supplying a pumped voltage based on a voltage source and a buffer powered by the pumped voltage and outputting a buffered data signal based on the data signal. | 08-21-2008 |
| 20080197881 | RECEIVER CIRCUIT USING NANOTUBE-BASED SWITCHES AND LOGIC - Receiver circuits using nanotube based switches and logic. Preferably, the circuits are dual-rail (differential). A receiver circuit includes a differential input having a first and second input link, and a differential output having a first and second output link. First, second, third and fourth switching elements each have an input node, an output node, a nanotube channel element, and a control structure disposed in relation to the nanotube channel element to controllably form and unform an electrically conductive channel between said input node and said output node. The receiver circuit can sense small voltage inputs and convert them to larger voltage swings. | 08-21-2008 |
| 20080231321 | Drive circuit with a TOP level shifter for transmission of an input signal, and method for transmission - A TOP level switch for use in a drive circuit in power-electronic systems having a half-bridge circuit formed by two power switches, a first so-called TOP switch and a second so-called BOT switch, which are arranged connected in series. The TOP level shifter transmits an input signal from drive logic to a TOP driver. In this case, the TOP level shifter is designed as an arrangement of an UP and a DOWN level shifter path, as well as a downstream signal evaluation circuit. In the associated method for transmission of this input signal, the signal evaluation circuit passes an output signal to the TOP driver when either the UP or the DOWN, or both, level shifter paths emit a signal to the respectively associated input of the signal evaluation circuit. | 09-25-2008 |
| 20080290899 | Integrated circuit and method of detecting a signal edge transition - The invention relates to an edge transition detector, and a method of operating an edge transition detector. An integrated circuit includes an edge transition detector for producing an output signal at an output node in response to an input signal. The edge transition detector includes a switch coupled to the output node. The edge transition detector includes a logic device with a first input coupled to the input node and an output coupled to a control terminal of the switch to enable the switch to conduct, thereby effecting a transition of the output signal from a first logic level to a second logic level in response to the input signal. A feedback path is provided from the output node to a second input of the logic device to disable switch conductivity when the output signal completes the logic transition from the first logic level to the second logic level. | 11-27-2008 |
| 20080303550 | INTEGRATED CIRCUIT WITH PLURAL LEVEL SHIFTERS - An integrated circuit is provided. The integrated circuit includes N level shifting devices. Each level shifting device receives a first digital signal and a second digital signal, and includes a first level shifter converting a first voltage of the first digital signal into a third voltage and converting a second voltage of the first digital signal into a fourth voltage, and a second level shifter converting a first voltage of the second digital signal into a fifth voltage and converting a second voltage of the second digital signal into a sixth voltage. | 12-11-2008 |
| 20090027082 | Level shifter - A level shifter is operated at high speed. An input unit | 01-29-2009 |
| 20090033364 | INTEGRATED CIRCUIT DEVICE FOR RECEIVING DIFFERENTIAL AND SINGLE-ENDED SIGNALS - An integrated circuit device includes a receiver that is capable of receiving and converting either differential input signals or two unrelated single-ended input signals. | 02-05-2009 |
| 20090140768 | Low-noise PECL output driver - An integrated circuit output driver is provided that exhibits improved performance and signal integrity. In one embodiment, the integrated circuit output driver is fabricated in a process having thin-gate MOS transistors and thick-gate MOS transistors and includes a predriver circuit, a level shifter circuit, and a driver circuit. The predriver circuit is formed predominantly of thin-gate transistors, and the driver circuit is formed predominantly of thick-gate transistors. In other embodiments, a low-pass power supply filter is provided. In still other embodiments, a voltage regulator circuit is provided, wherein an operating potential of at least one of the predriver circuit and the level shifter circuit is less than the specified supply voltage. In one embodiment, the voltage regulator circuit produces: i) a reduced internal supply voltage that is applied to the predriver circuit; and ii) an elevated ground voltage that is applied to the level shifter circuit. | 06-04-2009 |
| 20090153190 | Voltage Control - A circuit for converting a lower voltage logical signal to a higher voltage. The circuit comprises a current mirror structure having first and second branches, each comprising at least a first transistor of a first kind, an input transistor of a second kind, and a second transistor of the first kind coupled between them. The first transistors are arranged as a current mirror. The input transistors are driven using a logical signal at the lower voltage, controlling the current mirror structure to output a corresponding logical signal at the higher voltage. The second transistors are driven by an intermediate reference voltage so as to reduce the operating voltage of the third transistors. The first kind is tolerant of a higher operating voltage than the second kind. | 06-18-2009 |
| 20090167356 | MONOLITHICALLY INTEGRATED MULTIPLEXER-TRANSLATOR-DEMULTIPLEXER CIRCUIT AND METHOD - A monolithically integrated multiplexer-translator-demultiplexer and a method for multiplexing and translating an electrical signal or demultiplexing and translating an electrical signal. A multiplexer and a demultiplexer are monolithically integrated with a translator. Circuits that operate at different voltage supply levels from each other may be coupled to the multiplexer and a circuit that operates at a different voltage supply level from the circuits coupled to the multiplexer or that operates at the same voltage supply level as at least one of the circuits coupled to the multiplexer is coupled to the demultiplexer. The monolithically integrated multiplexer-translator-demultiplexer selects a signal from one of the circuits coupled to the multiplexer, translates its voltage level and provides the translated signal level as an output signal. Alternatively, the monolithically integrated multiplexer-translator-demultiplexer creates demultiplexed signals from an electrical signal and translates the voltage levels of the demultiplexed signals. | 07-02-2009 |
| 20090261859 | RECEIVER CIRCUITRY FOR RECEIVING REDUCED SWING SIGNALS FROM A CHANNEL - A receiver for receiving a reduced swing signal from a transmission channel is disclosed, in which the swing of the reduced swing signal is less than the power supply of the receiver and possibly is less than the power supply of the transmitter. The receiver comprises a level shifter for offsetting the reduced swing signal, and an amplifier which receives both the reduced swing signal and its offset to produce a full swing signal output referenced to the power supply of the receiver. The full swing signal can thereafter be buffered, and eventually can be captured by a clock. Optionally, the disclosed reduced swing receiver also contains calibration circuitry for improving the integrity of the full swing signal output, and in particular for countering the effects of process, and in some embodiments temperature, variations, which alter the characteristics of the transistors which make up the receiver circuitry. More particularly, the calibration circuitry compensates for the unbalanced way in which process and temperature variations impact transistors of differing polarities (e.g., n-type and p-type). | 10-22-2009 |
| 20100026342 | HIGH VOLTAGE INPUT RECEIVER USING LOW VOLTAGE TRANSISTORS - A high voltage input receiver using low voltage transistors is disclosed. In one embodiment, an input receiver circuit includes a comparator circuit and an inverter circuit. The comparator circuit includes a differential input module for generating a control signal by comparing an external voltage and a reference voltage, and a decision module for generating an inverter input signal based on the control signal. In addition, the reference voltage is used to set dc trip point of the input receiver. Moreover, the input receiver includes one or more stress protection modules to protect key components of the input receiver from exceeding their reliability limits. | 02-04-2010 |
| 20100039140 | BUFFER CIRCUIT OF SEMICONDUCTOR MEMORY APPARATUS - A buffer circuit of a semiconductor memory apparatus includes a buffering section configured to increase or decrease a voltage level of an output node by comparing a voltage level of an input signal with a voltage level of a reference voltage. A voltage compensation section applies a voltage to the output node in proportion to a variation of the reference voltage when the level of the reference voltage is lower than a target level. | 02-18-2010 |
| 20100085078 | Digital Logic Voltage Level Shifter - A digital logic level shifter having three stages. An initial stage includes a conventional 4-terminal bridge-type inverter circuit. A middle stage includes a 5-terminal first logic reversing circuit that has two middle stage inputs that are not connected in common. And a final stage includes a 5-terminal second logic reversing circuit that has two final stage inputs that are not connected in common. | 04-08-2010 |
| 20100188119 | LEVEL SHIFTER FLIP-FLOP - A flip-flop or other state circuit that includes level-shifting functionality. In connection with a flip-flop, embodiments include an inverter circuit element that has a data input line as its input and a data complement line as its output. The inverter resides in voltage domain that is lower than the voltage domain associated with remainder of the flip-flop. | 07-29-2010 |
| 20100225351 | Resolving Mestastability - A logic circuit latch including an input stage for receiving a logical input signal and a pair of differential amplifiers, each having an input operatively coupled to the input stage, and at least one of them having an output arranged to supply the logical output of the latch. Each of the differential amplifiers includes a transistor connected as a load, and an output of each of the differential amplifiers is coupled to bias the load transistor of the other differential amplifier. If the latch switches from the transparent state to the closed state while the logical input signal is transitioning between logical levels, the differential amplifiers drive up the logical output of the latch if the logical input signal transitions from a first to a second logical level, and drive down the logical output of the latch if the input signal transitions from the second to the first logical level. | 09-09-2010 |
| 20100253388 | INTERFACE CIRCUIT - An interface circuit comprising: a first output circuit configured to allow an access signal to be input thereto and output the access signal to a storage circuit, the access signal capable of being changed to one logic level or the other logic level for accessing the storage circuit; a second output circuit configured to output the access signal outputted from the first output circuit; and a comparison circuit configured to compare the number of times a logic level of the access signal inputted to the first output circuit is changed and the number of times a logic level of the access signal outputted from the second output circuit is changed, and output a comparison signal indicating whether predetermined access has been performed based on the access signal inputted to the first output circuit, after at least a part of the access signal is inputted to the first output circuit. | 10-07-2010 |
| 20110148464 | SEMICONDUCTOR DEVICE - A semiconductor device includes a first input buffer adjusting a logic threshold voltage, a first replica circuit, a first reference voltage generating circuit, and a first comparator circuit. The first replica circuit is identical in circuit configuration to the first input buffer. The first replica circuit has an input and an output connected to the input. The first replica circuit generates the logic threshold voltage as an output voltage. The first reference voltage generating circuit generates a first reference voltage. The first comparator circuit compares the logic threshold voltage as an output voltage of the first replica circuit to the first reference voltage to generate a first threshold adjustment signal. The first comparator circuit supplies the first threshold adjustment signal to the first input buffer and the first replica circuit. The first threshold adjustment signal allows the first input buffer to adjust the logic threshold voltage. | 06-23-2011 |
| 20110298493 | VOLTAGE LEVEL SHIFT CIRCUIT AND SEMICONDUCTOR DEVICE - A voltage level shift circuit in which a difference in response characteristic depending on the signal level of an input signal is suppressed. The voltage level shift circuit generates an output signal VOUT having a voltage amplitude different from that of the input signal. An inverter INV | 12-08-2011 |
| 20120025870 | METHOD AND APPARATUS FOR VOLTAGE LEVEL SHIFTING WITH CONCURRENT SYNCHRONIZATION - Methods and apparatus provide for voltage level shifting with concurrent synchronization. The apparatus includes level shifting logic that in response to a non-level shifted clock signal from a first voltage domain, provides level shifted concurrently synchronous differential data signals in a second voltage domain based on pre-level shifted differential data signals from the first voltage domain. The first voltage domain may be, for example, a core logic voltage domain in which core logic operates. The second voltage domain may be, for example, an input/output (I/O) voltage domain in which an I/O buffer operates. The voltage level of the level shifted concurrently synchronous differential data signals is shifted from the pre-level shifted differential data signals, and the timing of the level shifted concurrently synchronous differential data signals is concurrently referenced to the non-level shifted clock signal. | 02-02-2012 |
| 20120068735 | INCORPORATING AN INDEPENDENT LOGIC BLOCK IN A SYSTEM-ON-A-CHIP - In one embodiment, the present invention includes a logic having a first link interface to enable communication with an intellectual property (IP) logic adapted on a single semiconductor die with the logic, where the IP logic includes a second link interface coupled to the first link interface via an on-die interconnect. In this way, the IP logic can be unmodified with respect to a standalone device having the IP logic incorporated therein. Other embodiments are described and claimed. | 03-22-2012 |
| 20120262202 | Output Buffer - An output buffer includes a level conversion module for generating a first logic signal having a first level range and a second logic signal having a second level range, a pre-driving module composed of low-voltage transistors for generating a first control signal and a second control signal according to the first logic signal and the second logic signal, and an output module for generating an output signal having a third level range according to the first control signal and the second control signal. Each of the first and second level ranges is smaller than the third level range. | 10-18-2012 |
| 20130021062 | PRINTED CIRCUIT BOARD FOR A COMPRESSOR HOUSING - This printed circuit board ( | 01-24-2013 |
| 20130271181 | SINGLE POWER SUPPLY LOGIC LEVEL SHIFTER CIRCUIT - A system and method of shifting a data signal from a first voltage domain having a first logic level to a second voltage domain having a second logic level, the second logic level having a second logical high state greater than a first logical high state in the first logic level and a single power supply logic level shifter circuit having a single power supply source, an input node and an output node, the input node coupled to a sender circuit in the first voltage domain and the output node coupled to a receiver circuit in the second voltage domain, the single power supply source being coupled only to a single power grid in the second voltage domain. | 10-17-2013 |
| 20140055163 | LOW VOLTAGE TRANSMITTER WITH VARIABLE OUTPUT SWING - Described herein are apparatus, system, and method for improving output signal voltage swing of a voltage mode transmitter (Tx) driver. The Tx driver may use a single power supply which is the same as the power supply of the core processor. The apparatus comprises: a voltage mode driver coupled to an output node; a switching current source, coupled to the output node, to increase voltage swing of a signal on the output node, wherein the signal is driven by the voltage mode driver; and a bias generator to bias the switching current source. | 02-27-2014 |
| 20140176188 | HETEROGENEOUS HIGH-SPEED SERIAL INTERFACE SYSTEM ARCHITECTURE - One embodiment relates to an integrated circuit having a plurality of four-channel serial interface modules. Each of the plurality of four-channel serial interface modules includes a first physical medium attachment (PMA) channel circuit, a second PMA channel circuit adjacent to the first PMA channel circuit, a third PMA channel circuit adjacent to the second PMA channel circuit, a fourth PMA channel circuit adjacent to the third PMA channel circuit, and at least one phase-locked loop (PLL) circuit which is programmably coupled to each of the first, second, third and fourth PMA channel circuits. Other embodiments and features are also disclosed. | 06-26-2014 |
| 20140361810 | Signal Transfer Device - A signal-transferring device having a first circuit and a second circuit that operate on different ground references, and a third circuit for transferring signals while providing insulation between the first circuit and the second circuit. The second circuit switches a logic level of an output signal in accordance with the logic level of an input signal notified by the first circuit, and notifies the first circuit about the logic level of the output signal. The first circuit notifies the second circuit about the logic level of the input signal not only when the logic level of the input signal has been switched, but also when the logic level of the output signal notified by the second circuit does not match the logic level of the input signal. | 12-11-2014 |
| 20150123708 | INTEGRATED CIRCUIT FOR MEMORY AND OPERATING METHOD THEREOF - An integrated circuit of a memory is provided. The integrated circuit comprises a first data driving circuit and a transmitting transistor. The first data driving circuit outputs a first data voltage to a first node. The transmitting transistor is coupled between the first node and a second node. When the transmitting transistor receives a bias voltage and the voltage level of the first node is a first voltage level, the transmitting transistor makes the voltage level of the second node to be set as a third voltage level, third voltage level is close to or substantially equal to the first voltage level. When the transmitting transistor receives the bias voltage and the voltage level of the first node is the second voltage level, the voltage level of the second node is independently of the voltage level of the first node. | 05-07-2015 |
| 20150137852 | LEVEL SHIFT CIRCUIT UTILIZING RESISTANCE IN SEMICONDUCTOR SUBSTRATE - An apparatus such as a level shift circuit includes a first signal output device configured to output a first level shifting signal, a second signal output device configured to output a second level shifting signal, and first and second detector devices. The level shifting signals are to control an output switching element of a high potential side of an output device that includes a power source and a load. The first and second detector devices are respectively configured to compare the first and second level shifting signals to a reference signal and output respective first and second comparison result signals. The first and second comparison result signals are configured to at least partly control switching of the first and second level shifting signals based at least in part on the presence of a parasitic resistance. | 05-21-2015 |
| 20160036441 | Output Signal Generation Circuitry for Converting an Input Signal From a Source Voltage Domain Into an Output Signal for a Destination Voltage Domain - Output signal generation circuitry | 02-04-2016 |
| 20160191058 | INTEGRATED CIRCUIT LAYOUT WIRING FOR MULTI-CORE CHIPS - An integrated circuit system-on-chip (SOC) includes a semiconductor substrate, a plurality of components made up of transistors formed in the substrate, and a plurality of interconnection lines providing electrical connectivity among the components. Use of a channel-less design eliminates interconnection channels on the top surface of the chip. Instead, interconnection lines are abutted to one another in a top layer of metallization, thus preserving 5-10% of chip real estate. Clock buffers that are typically positioned along interconnection channels between components are instead located within regions of the substrate that contain the components. Design rules for channel-less integrated circuits permit feed-through interconnections and exclude multi-fanout interconnections. | 06-30-2016 |
| 326064000 | Bi-CMOS | 7 |
| 20090243654 | LEVEL CONVERTER - A level converter includes a cross-coupled section for holding data and a first switching section connected in series with the cross-coupled section and supplied with a differential input signal. The level converter has a second switching section, a current mirror connection section, a third switching section, and an input/output matching evaluation section. The second switching section is connected in parallel with the cross-coupled section, and the current mirror connection section is connected in a current-mirror configuration with a transistor in the second switching section. The third switching section is connected in series with the current mirror connection section, and the input/output matching evaluation section is used to control a transistor in the third switching section by receiving the input signal and an output node signal. | 10-01-2009 |
| 20100244899 | Tuning High-Side and Low-Side CMOS Data-Paths in CML-to-CMOS Signal Converter - Electronic circuitry and techniques are disclosed for controlling one or more timing parameters associated with a circuit that converts a signal of a first type to a signal of a second type. For example, the converter circuit may convert a differential digital logic signal, such as a current mode logic (CML) signal, to a complementary metal oxide semiconductor (CMOS) signal. For example, apparatus for converting a first type of signal to a second type of signal comprises the following circuitry. First circuitry is configured for generating a first pair of CMOS signals in response to a differential digital logic signal, the first pair of CMOS signals comprising a first CMOS signal having a first polarity and a second CMOS signal having a second polarity. Second circuitry is configured for adjusting, with respect to the first pair of CMOS signals, a transition time of one of the first CMOS signal and the second CMOS signal relative to a transition time of another of the first CMOS signal and the second CMOS signal. | 09-30-2010 |
| 326066000 | ECL to/from CMOS | 5 |
| 20090045842 | LOW-DELAY COMPLIMENTARY METAL-OXIDE SEMICONDUCTOR (CMOS) TO EMITTER-COUPLED LOGIC (ECL) CONVERTERS, METHODS AND APPARATUS - Example low-delay complementary metal-oxide semiconductor (CMOS) to emitter-coupled logic (ECL) converters, methods and apparatus are disclosed. A disclosed example apparatus includes a reference level generator circuit to generate first and second reference signals and a bias signal based on a CMOS supply voltage, a source follower circuit to convert a CMOS input signal to a single-ended ECL signal based on the first and second reference signals, and an ECL buffer circuit to convert the single-ended ECL signal to a differential ECL output signal based on the bias signal and an ECL supply voltage. | 02-19-2009 |
| 20090174432 | System for Providing a Complementary Metal-Oxide Semiconductor (CMOS) Emitter Coupled Logic (ECL) Equivalent Input/Output (I/O) Circuit - A system for providing a CMOS I/O circuit design that may replace existing bipolar I/O circuitry, and thus behave in substantially the same manner as bipolar I/O circuitry. Thus, an I/O circuit using a standard CMOS process is made that mimics operation of an ECL I/O circuit created using bipolar transistors. The CMOS input circuitry can receive input signals from an ECL output circuit, so as to mimic traditional ECL input circuitry. The CMOS output circuitry can output signals to an ECL input circuit, so as to mimic traditional ECL output circuitry. The CMOS I/O circuitry is designed to mimic the temperature dependent signals level, as present within traditional ECL I/O circuitry. | 07-09-2009 |
| 20090302890 | TRANSLATOR CIRCUIT HAVING INTERNAL POSITIVE FEEDBACK - An integrated circuit ( | 12-10-2009 |
| 20110121859 | METHOD AND SYSTEM FOR IMPROVED PHASE NOISE IN A BICMOS CLOCK DRIVER - System and method for a clock driver. An input taking circuit is used for receiving small-signal logic inputs. A voltage follower circuit is coupled to the input taking circuit and used to generate a set of voltage follower outputs. An output circuit is coupled to the voltage follower circuit to receive the set of voltage follower outputs as inputs and generate output signals. The voltage follower circuit is coupled to a switching circuit, that is connected to the set of voltage follower outputs and is deployed for reducing the phase noise level of the output signals. | 05-26-2011 |
| 20150091616 | TECHNIQUE TO REALIZE HIGH VOLTAGE IO DRIVER IN A LOW VOLTAGE BICMOS PROCESS - An IO circuit capable of high voltage signaling in a low voltage BiCMOS process. The IO circuit includes a voltage rail generator circuit that receives a reference voltage and generates a voltage rail supply. A BJT (bi-polar junction transistor) buffer circuit is coupled to the voltage rail generator circuit and a pad. The BJT buffer circuit includes a pull-up circuit and a pull-down circuit. The pull-up circuit receives the voltage rail supply. The pull-down circuit is coupled to the pull-up circuit. The pad is coupled to the pull-up circuit and the pull-down circuit. | 04-02-2015 |
| 326068000 | Field-effect transistor (e.g., JFET, MOSFET, etc.) | 46 |
| 20080211541 | Precision voltage level shifter based on thin gate oxide transistors - A precision voltage level shifter based on thin gate oxide transistors is disclosed. A method of a voltage level shifter includes serially connecting thin n-channel gate oxide semiconductor FETs to think n-channel gate oxide semiconductor FETs to enable the voltage level shifter with a low input voltage. The method further includes permanently turning on a thick p-channel gate oxide semiconductor FET through grounding a gate of the thick p-channel gate oxide semiconductor FET to enable the voltage level shifter with an input voltage close to the I/O voltage of the voltage level shifter. | 09-04-2008 |
| 20080218212 | LOW TO HIGH VOLTAGE CONVERSION OUTPUT DRIVER - A low to high voltage conversion output driver. The low to high voltage conversion output driver has an output coupled to a first fixed voltage via a load device and comprises a current source, a low voltage transistor, and a high voltage transistor. The current source has one end coupled to a second fixed voltage. The low voltage transistor has a first terminal coupled to the other end of the current source, a second terminal receiving a low voltage data signal, and a third terminal. The high voltage transistor has a first terminal coupled to the third terminal of the low voltage transistor, a second terminal coupled to a bias source, and a third terminal coupled to the output. | 09-11-2008 |
| 20080238481 | LEVEL SHIFT CIRCUIT - In a level shift circuit, the threshold voltage of N-type high-voltage transistors, to whose gates the voltage of a low-voltage supply VDD is applied, is set low. An input signal IN powered by the low-voltage supply VDD is input to the gate of an N-type transistor by way of an inverter. Therefore, even if the potentials at nodes W | 10-02-2008 |
| 20080290900 | Two-Stage Level Shifting Module - For raising low voltage levels of a voltage range without over-broadening the voltage range, a first stage voltage level shifting circuit, which is capable of raising an upper bound of its input voltage range, is coupled to a second voltage level shifting circuit, which is capable of raising both an upper bound and a lower bound of its input voltage range. Therefore, a two-stage voltage level shifting module, which is generated by coupling the first voltage level shifting circuit to the second voltage level shifting circuit, is capable of providing appropriate voltages for external I/O devices having different biasing voltage ranges, where an upper bound and a lower bound of each of the provided biasing voltage ranges precisely indicates a digital logic 0 or a digital logic 1 indicated by a digital signal. | 11-27-2008 |
| 20080290901 | Voltage Shifter Circuit - The present invention provides a voltage shifter circuit, in which a control circuit is used to control the pull-up circuit, so that the pull-up circuit is kept as off when the signal from the input signal source changes from a low voltage to a high voltage. Hence, the competition between the pull-up circuit and the pull-down circuit is avoided. The speed of the voltage shifter circuit is improved and the voltage shifter circuit can operate within a wider voltage range. The delay time of the pull-up circuit and the pull-down circuit is small and the duty cycle is small. In addition, since no direct current path is established, no current is wasted. Additionally, the voltage shifter circuit uses the second delayer to compensate the delay time between the pull-up circuit and the pull-down circuit and optimizes the duty cycle. | 11-27-2008 |
| 20080290902 | LEVEL CONVERTER - A level converter comprising an input circuit, coupled to a low power source and a first high power source, which generates a complementary first signal and second signal; and a shift circuit that outputs an output signal generated by shifting a voltage level of the input signal, the shift circuit including: a latch circuit having: a first inverter circuit provided in a first path between a second high power source and the low power source; and a second inverter circuit provided in a second path between the second high power source and the low power source, wherein the latch circuit is formed by coupling an input terminal and an output terminal of the first inverter circuit and the second inverter circuit; a first transistor coupled to the first path; and a second transistor coupled to the second path. | 11-27-2008 |
| 20090002026 | Level conversion circuit for converting voltage amplitude of signal - In a level conversion circuit, two P channel MOS transistors form a current mirror circuit. When an input signal rises from the “L” level to the “H” level, an N channel MOS transistor connected to a drain of one P channel MOS transistor is brought out of conduction to prevent a leak current from flowing through two P channel MOS transistors, which decreases a power consumption. In addition, when the input signal rises from the “L” level to the “H” level, a P channel MOS transistor connected to a drain of the other P channel MOS transistor is brought into conduction to fix a potential of a node of the drain of the other P channel MOS transistor to the “H” level, which prevents the potential of the node from becoming unstable. | 01-01-2009 |
| 20090009217 | TRANSFORMATION OF AN INPUT SIGNAL INTO A LOGICAL OUTPUT VOLTAGE LEVEL WITH A HYSTERESIS BEHAVIOR - It is described a circuit and a method for transforming an input signal into a logical output. The circuit ( | 01-08-2009 |
| 20090058464 | Current mode logic-complementary metal oxide semiconductor converter - A current mode logic (CML)-complementary metal oxide semiconductor (CMOS) converter prevents change of a duty ratio to stably operate during an operation for converting a CML level signal into a CMOS level signal. The CML-CMOS converter includes a reference level shifting unit configured to receive a CML signal swinging about a first reference level to shift a swing reference level to a second reference level; and an amplifying unit configured to amplify an output signal of the reference level shifting unit to output the amplified signal as a CMOS signal. | 03-05-2009 |
| 20090096484 | LEVEL SHIFTERS - Level shifters capable of setting logic level of the output signals thereof to a pre-defined known state during power-up are provided, in which a first logic unit is powered by a first power voltage, receives input signals with a core power voltage and comprises first and second output terminals. First and second drivers are coupled between the first output terminal and the first power voltage and between the second output terminal and the second power voltage respectively. When one of the first and second power voltages is not ready during power-up, the first driver matches a voltage level on the first output terminal with the first power voltage by AC coupling and the second driver pulls low or maintains a voltage level on the second output terminal. | 04-16-2009 |
| 20090108870 | I/O BUFFER CIRCUIT - An output buffer circuit is provided. The output buffer circuit receives a control signal (OE) and a data signal (Dout) from a first core circuit ( | 04-30-2009 |
| 20090189638 | LEVEL SHIFTER CIRCUIT - A level shifter comprises a voltage converting circuit, a voltage pull-up circuit, and a control signal generating circuit. The voltage converting circuit is configured to receive an input signal of a first voltage level and to output an output signal of a second voltage level. The voltage pull-up circuit is coupled to the voltage converting circuit and configured to expeditiously pull up a voltage of an output node of the level shifter to the second voltage level in response to a control signal. The control signal generating circuit is configured to receive the input signal and to provide the control signal to the voltage pull-up circuit. The control signal generating circuit includes three transistors. | 07-30-2009 |
| 20090195267 | High-Voltage tolerant output driver - A high-voltage tolerant output driver for use in a switching regulator is provided herein. The driver allows the switching regulator to regulate supply voltages that exceed device breakdown limits for the process technology from which the high-voltage tolerant output driver is fabricated. Unregulated supply voltages can vary over a wide range. The regulator only needs two intermediate voltages. | 08-06-2009 |
| 20090261860 | ELECTRONIC CIRCUIT - An electronic circuit is provided comprising an input (V | 10-22-2009 |
| 20100060319 | LOW LEAKAGE AND DATA RETENTION CIRCUITRY - An integrated circuit includes first circuitry and sleep transistor circuitry. The first circuitry receives input signals and processes the input signals. The first circuitry also retains data in a sleep state that has low leakage. The sleep transistor circuitry is coupled to the first circuitry and receives a sleep signal that has a negative voltage. The sleep circuitry reduces power consumption of the first circuitry in the sleep state to have low leakage based on the sleep signal while retaining the data in the first circuitry. | 03-11-2010 |
| 20100073027 | LATCH STRUCTURE, FREQUENCY DIVIDER, AND METHODS FOR OPERATING SAME - A latch includes three circuits. The first circuit drives a first output (QB) to a first level when a first input (D) and a first clock phase (CK) are both low, to a second level when D and CK are both high, and provides high impedance (HI-Z) when different logic levels are applied to D and CK. The second circuit drives a second output (Q) to the first level when a third input (DB) and a complimentary clock phase (CKB) are both low, to the second level when DB and CKB are both high, and provides HI-Z when different logic levels are applied to DB and CKB. The third circuit maintains voltages of Q and QB when the first and second circuits provide HI-Z at Q and QB. Odd-number dividers constructed with such latches produce 50% duty cycle operation without restricting output pulse widths to integer multiples of input periods. | 03-25-2010 |
| 20100085079 | Low Latency, Power-Down Safe Level Shifter - In one embodiment, an apparatus comprises a circuit supplied by a first supply voltage during use, the circuit having at least a first input signal; and a level shifter supplied by the first supply voltage during use and coupled to provide the first input signal to the circuit. The level shifter is coupled to receive a second input signal sourced from circuitry supplied by a second supply voltage during use, and is configured to generate the first input signal by level shifting the second input signal. Coupled to receive a power control signal indicating, when asserted, that the second supply voltage is to be powered down, the level shifter is configured to assert a predetermined level on the first input signal independent of the second input signal and responsive to an assertion of the power control signal. | 04-08-2010 |
| 20100109705 | LEVEL SHIFTER - A device for shifting voltage levels includes an input stage, an output stage and multiple cascode sets connected between the input stage and the output stage. The input stage includes input transistors connected to a first voltage and an input for receiving an input signal. The output stage includes output transistors connected to a second voltage and an output for outputting an output signal having a voltage level different from a corresponding voltage level of the input signal. Each cascode set includes corresponding cascode transistors gated to a third voltage, which is between the first voltage and the second voltage, preventing excessive voltage across terminals of the input transistors and the output transistors. | 05-06-2010 |
| 20100134145 | System and Method for Converting Between CML Signal Logic Families - A system includes a first CML buffer configured to receive a first bias signal and a first CML signal of a first CML logic family. The first CML buffer produces a second CML signal of the first CML logic family based on the first CML signal and the first bias signal. A first coupling capacitor module couples to the first CML buffer. The first coupling capacitor module receives the second CML signal and produces a third CML signal based on the second CML signal. A second CML buffer couples to the coupling capacitor module and receives a second bias signal and the third CML signal, producing a fourth CML signal of a second CML logic family. A feedback module couples to the second CML buffer and receives the fourth CML signal producing a fifth CML signal. The second CML buffer is produces the fourth CML signal based on the second bias signal, the third CML signal, and the fifth CML signal. | 06-03-2010 |
| 20100194432 | DEVICE FOR TRANSFORMING INPUT IN OUTPUT SIGNALS WITH DIFFERENT VOLTAGE RANGES - Arrangement for accepting an input signal in a first voltage range and producing an output signal in a second voltage range. A transition detection circuit ( | 08-05-2010 |
| 20100213979 | SEMICONDUCTOR DEVICE AND METHOD FOR LAYOUTING SEMICONDUCTOR DEVICE - A semiconductor device is provided. The semiconductor device includes a first circuit provided between a power source voltage line and a ground line, including at least two first MOS transistors coupled in parallel and a second circuit, which is provided between the power source voltage line and the ground line, including at least two second MOS transistors coupled in series. The gate length and the gate width of the first MOS transistor are adjusted so that the first MOS transistor has a gate area allowing a first characteristic variation of the first MOS transistor to be substantially equal to a second characteristic variation of the second MOS transistor. | 08-26-2010 |
| 20100289526 | Level shifter - A level shifter includes a first level shift circuit that converts a signal level of a first pulse signal into an amplitude level of a power supply voltage, and a second level shift circuit that converts a signal level of the second pulse signal into an amplitude level. Each of the first and second level shift circuits includes a first conductivity type transistor having its gate receiving the first and second pulse signals respectively, its source connected to a ground, and its drain outputs a level shifted pulse signal, and a first transistor of a second conductivity type having its gate connected to the gate of the transistor of the first conductivity type, its drain connected to the drain of the transistor of the first conductivity type, and its source connected to the power supply via a connected transistor group, and the connected transistor group includes at least one of the second conductivity type transistors. | 11-18-2010 |
| 20110260753 | Level Shifter with Balanced Duty Cycle - A level shifter and method are provided for balancing a duty cycle of a signal. An input circuit receives a differential logic signal with two complimentary logic levels. A level transition balancing circuit balances the rise and fall times of a level shifted version of each complimentary logic level during a transition from a first to a second of the logic levels and a level shift. A logic element stores and provides outputs of the level shifted versions of the logic levels. The level transition balancing circuit can include a capacitor in parallel with a transfer element for each input. The capacitor destabilizes inputs to the logic element and balances the transition using a capacitance and a level previously stored in the logic element. | 10-27-2011 |
| 20120146688 | VOLTAGE LEVEL SHIFTING APPARATUSES AND METHODS - Level shifting circuits and related methods are disclosed herein. The level shifting circuit includes a cross-coupled pull-up circuit coupled to a higher supply voltage, an output signal, and an inverted output signal. An input signal transitions between a ground and a lower supply voltage and an inverted input signal transitions in a direction opposite from the input signal between the ground and the lower supply voltage. A first n-channel transistor has a gate coupled to the lower supply voltage, a drain coupled to the output signal, and a source coupled to the inverted input signal. A second n-channel transistor has a gate coupled to the lower supply voltage, a drain coupled to the inverted output signal, and a source coupled to the input signal. The level shifting circuit may be included in an IC with core logic in a first voltage domain and input/output logic in a second voltage domain. | 06-14-2012 |
| 20120249180 | SEMICONDUCTOR DEVICE - A device is disclosed herein, which may be used a level-shift circuit. The device includes first, second and third power supply lines supplied respectively with first, second and third power voltages that are different from one another, first and second input terminals and an output terminal, an output circuit coupled to the first power supply line, the first and second input terminals and the output terminal, a first inverter including an input node coupled to the first input terminal and an output node coupled to the second input terminal, a first transistor coupled in series to the first inverter between the second and third power supply lines, the fifth transistor being rendered non-conductive to deactivate the first inverter, and a control circuit configured to prevent the output terminal from being brought into an electrical floating state during deactivation of the first inverter. | 10-04-2012 |
| 20130002299 | LOGIC LEVEL TRANSLATOR AND ELECTRONIC SYSTEM - A logical level translator includes a first reference voltage provider, a second reference voltage provider, and a switching circuit. The first reference voltage provider provides a first reference voltage signal with a first logic level to a first connection terminal. The second reference voltage provider provides a second reference voltage signal with a second logic level to a second connection terminal. The switching circuit switches on a connection between the first connection terminal and the second connection terminal when a digital signal input to the first connection terminal or the second connection terminal is a logic high level signal. Then switches off the connection between the first connection terminal and the second connection terminal when the digital signals is a logic low level signal. | 01-03-2013 |
| 20130049806 | SEMICONDUCTOR DEVICE - A semiconductor device is provided, which includes a switch having a first transistor and a logic circuit having an output terminal. The logic circuit includes a bootstrap circuit having at least one second transistor. The bootstrap circuit is electrically connected to the output terminal. The first transistor and the second transistor have the same conductivity type. Each of the first transistor and the second transistor includes an oxide semiconductor layer including a channel formation region and a pair of gate electrodes with the oxide semiconductor layer provided therebetween. | 02-28-2013 |
| 20130076394 | Compact High-Speed Mixed-Signal Interface - An apparatus is disclosed for converting signals from one digital integrated circuit family to be compatible with another digital integrated circuit family. The apparatus includes a primary interface and a secondary interface to convert a differential output signal from one digital integrated circuit family for use as an input signal by another digital integrated circuit family. The primary and secondary interfaces include gain stages that are configurable to provide rail to rail voltage swings and are characterized as having single pole architectures. The secondary interface may be unterminated such that a substantially equal load is presented to both components of the differential output signal. | 03-28-2013 |
| 20130082736 | SEMICONDUCTOR DEVICE INCLUDING MULTIPLE-INPUT LOGIC CIRCUIT WITH OPERATION RATE BALANCED WITH DRIVING ABILITY - A device includes first through third logic circuits. Each of first and second logic circuits includes a first circuit portion generating a first output signal in response to a first input signal when a second input signal takes a first logic level, and a second circuit portion transferring the first input signal to output the first output signal when the second input signal takes a second logic level. The third logic circuit includes a third circuit portion generating a second output signal in response to the first output signal supplied from the first logic circuit when the first output signal supplied from the second logic circuit takes a third logic level, and a fourth circuit portion generating the second output signal in response to the first output signal supplied with the first logic circuit when the first output signal supplied from the second logic circuit takes a fourth logic level. | 04-04-2013 |
| 20130099822 | CML TO CMOS CONVERSION CIRCUIT - The present invention provides a CML to CMOS conversion circuit comprising a first differential unit, a second differential unit, and an output unit. The output unit comprises a series connection of a first inverter and a second inverter, wherein, a resistor is connected with the first inverter in parallel. The CML to CMOS conversion circuit of the present invention omits the amplifier in the conventional circuit and reduces the delay time to 34 ps, which is almost half of the delay time of 64 ps in the conventional circuit, and thus provides more clock delay redundancy for the high speed parallel-serial conversion circuit. | 04-25-2013 |
| 20130176054 | OUTPUT BUFFER CIRCUIT - There is provided an output buffer circuit which can reduce the time differences of the rise time and fall time of the output voltages of a differential output signal and, furthermore, can make the rise time and fall time match with a good precision. To the resistance elements R | 07-11-2013 |
| 20130249595 | LEVEL SHIFT CIRCUIT AND SEMICONDUCTOR DEVICE USING LEVEL SHIFT CIRCUIT - A level shift circuit, for outputting a data output signal with a second level via an output inverter after a data input signal with a first level is stored in a latch, includes a level set circuit, when the output data signal outputs with a low level, setting the output data signal to a low level in response to a change of the input data signal. The level set circuit is connected to an output terminal of the output inverter, and has an NMOS transistor having a drain electrode and a source electrode coupled to a ground, wherein the NMOS transistor turns on in response to the input data signal with a high level. | 09-26-2013 |
| 20130328590 | SEMICONDUCTOR DEVICE HAVING FLOATING BODY TYPE TRANSISTOR - A semiconductor device includes a first circuit node supplied with a first signal changing between first and second logic levels, a second circuit node supplied with a second signal changing between the first and second logic levels, a third circuit node, a first transistor having a gate electrically connected to the first circuit node and a source-drain path electrically connected between the second and third circuit nodes, the first transistor being rendered conductive when the first signal is at the second logic level, a fourth circuit node supplied with a voltage level being close to or the same as the second logic level, and a second transistor having a gate electrically connected to the first circuit node and a source-drain path electrically connected between the third and fourth circuit nodes, the second transistor being rendered conductive when the first signal is at the first logic level. | 12-12-2013 |
| 20140320167 | LEVEL CONVERSION CIRCUIT AND LEVEL-CONVERSION-FUNCTION-EQUIPPED LOGIC CIRCUIT - A level conversion circuit ( | 10-30-2014 |
| 20150035563 | High Speed Level Shifter with Amplitude Servo Loop - A high speed level shifter interfaces a high speed DAC to the digital information that the DAC processes. The level shifter may convert CMOS level digital representations to, for example, CML level digital representations for processing by the DAC. The level shifter conserves the voltage swing in the CMOS level representations (e.g., about 1V). The level shifter also avoids voltage overstress, using a feedback loop to constrain the voltage amplitude, and thereby facilitates the use of fast thin film transistors in its architecture. | 02-05-2015 |
| 20150381178 | SIGNAL CONVERSION - A circuit may include an input terminal configured to receive an input signal with a first voltage swing and an output terminal. The circuit may also include a first transistor, a second transistor, a third transistor, and a control circuit. The control circuit may be coupled to the input terminal, a gate terminal of the first transistor, and a gate terminal of the second transistor. The control circuit may be configured to adjust voltages provided to the gate terminals based on the input signal such that the first transistor conducts in response to the input signal being at a first logical level and the second transistor conducts in response to the input signal being at a second logical level to generate an output signal output on the output terminal. The second voltage swing of the output signal may be different from the first voltage swing of the input signal. | 12-31-2015 |
| 20160079978 | LEVEL SHIFT AND INVERTER CIRCUITS FOR GAN DEVICES - GaN-based half bridge power conversion circuits employ control, support and logic functions that are monolithically integrated on the same devices as the power transistors. In some embodiments a low side GaN device communicates through one or more level shift circuits with a high side GaN device. Both the high side and the low side devices may have one or more integrated control, support and logic functions. Some devices employ electro-static discharge circuits and features formed within the GaN-based devices to improve the reliability and performance of the half bridge power conversion circuits. | 03-17-2016 |
| 20160099709 | CURRENT MODE LOGIC CIRCUIT FOR HIGH SPEED INPUT/OUTPUT APPLICATIONS - A CML latch includes an input stage including input nodes to receive a differential input signal and output nodes to provide a differential intermediate output signal, and a negative output node to provide a negative side of the differential intermediate output signal, a negative resistance stage including an input node connected to a first voltage source and output nodes connected to the output nodes of the input stage, and a latch stage including input nodes connected to the output nodes of the input stage and output nodes to provide a differential output signal. The negative resistance stage increases a current gain of the input stage. | 04-07-2016 |
| 20160118987 | Level Shifter With Low Static Power Dissipation - In one embodiment, a level shifter has a cascade voltage-switching logic (CVSL) structure having two pull-up networks connected in a positive feedback arrangement, each pull-up network connected in series with a corresponding pull-down network. The effective transistor sizes of the two pull-up networks are different such that, at power on, if a level-shifter node connected to an output inverter initially has an in-between voltage level (e.g., at or near the midpoint between the output voltage-domain power-supply voltage and ground), the node voltage will quickly be driven either high or low (depending on the level-shifter design and other initial conditions), thereby reducing leakage current through the output inverter that could otherwise be maintained if the pull-up networks had the same effective transistor size. In addition, one of the pull-down networks has an additional pull-down transistor to accelerate node-voltage driving away from the midpoint to ensure proper operation of the level shifter. | 04-28-2016 |
| 20160380633 | SIGNAL CONVERSION - A circuit may include an input terminal configured to receive an input signal with a first voltage swing and an output terminal. The circuit may also include a first transistor, a second transistor, a third transistor, and a control circuit. The control circuit may be coupled to the input terminal, a gate terminal of the first transistor, and a gate terminal of the second transistor. The control circuit may be configured to adjust voltages provided to the gate terminals based on the input signal such that the first transistor conducts in response to the input signal being at a first logical level and the second transistor conducts in response to the input signal being at a second logical level to generate an output signal output on the output terminal. The second voltage swing of the output signal may be different from the first voltage swing of the input signal. | 12-29-2016 |
| 326070000 | TTL to/from MOS | 4 |
| 20110133779 | INTERFACE CIRCUIT - An interface of the present invention includes a first inverter circuit that inverts a logic level of an input signal given to an external input terminal and outputs the inverted logic level, a second inverter circuit that outputs a potential in which a logic level of an output signal of the first inverter circuit is inverted, that is, a potential higher or lower than a logic of an input signal applied to the first inverter circuit by the amount of a predetermined potential, and a feedback path that positive feedbacks an output signal of the second inverter circuit to the external input terminal The interface circuit of the invention positive-feedbacks a potential of the output signal of the second inverter circuit and shifts the potential of the external input terminal in a floating state to an H or L level potential. | 06-09-2011 |
| 20120293204 | SEMICONDUCTOR DEVICE - A semiconductor device in which a transistor using an oxide semiconductor containing In, Zn, or the like for a channel region can be driven like a p-channel transistor is provided. The semiconductor device includes a transistor and an inverter, wherein an output of the inverter is input to a gate of the transistor, a channel region of the transistor includes an oxide semiconductor film containing In, Zn, or Sn, and each channel region of transistors in the inverter contains silicon. When a high voltage is input to the inverter, a low voltage is output from the inverter and is input to the gate of the transistor, so that the transistor is turned off. When a low is input to the inverter, a high voltage is output from the inverter and is input to the gate of the transistor, so that the transistor is turned on. | 11-22-2012 |
| 20140347098 | Systems and Methods for Data Receipt from Devices of Disparate Types - Systems and methods are provided for a receiver device for receiving data signals from devices of disparate types. An amplifier is configured to receive a voltage reference signal and a data signal, the data signal being received from a device, the amplifier being configured to output an output signal based on a comparison of the data signal to the voltage reference signal. A voltage reference level shifter is configured to selectively level shift the voltage reference signal supplied to the amplifier based on a type of device with which the receiver is communicating. A data signal level shifter is configured to selectively level shift the data signal supplied to the amplifier based on the type of device with which the receiver is communicating. | 11-27-2014 |
| 326071000 | TTL to/from CMOS | 1 |
| 20100259298 | LOW-QUIESCENT-CURRENT BUFFER - An embodiment of an input-buffer circuit may include an input stage with an inverter having an input operable to receive a signal to be translated. The input stage may include a limiting circuit coupled to the input stage for arresting quiescent current. Additional embodiments of an input-buffer circuit formed according to the subject matter disclosed herein may include feedback transistors suited to provide additional current to the input stage and a hysteresis circuit suited to provide hysteresis current to the input stage when an input signal has a high-frequency change rate. | 10-14-2010 |
| 326073000 | ECL to/from MOS | 2 |
| 20090174433 | PECL/LVPECL input buffer that employs positive feedback to provide input hysteresis, symmetric headroom, and high noise immunity - A CMOS based input buffer suitable for use with PECL or LVPECL voltage levels is described. The input buffer utilizes a differential voltage comparator that employs positive feedback to provide input hysteresis, symmetric headroom and increased noise immunity. In addition, the input buffer can utilize a reference voltage that is substantially constant over process, voltage, and temperature. | 07-09-2009 |
| 20100253389 | Low-noise PECL output driver - An integrated circuit output driver is provided that exhibits improved performance and signal integrity. In one embodiment, circuitry for producing an oscillatory output signal having a peak voltage of V volts uses MOS transistor circuitry transistors of which are designed for a maximum port-to-port voltage of substantially less than V volts. A first inverter chain is coupled to an input signal to produce a predriver output signal. A second inverter chain of multiple of inverters including a first inverter produces a driver output signal. Circuitry is provided for AC-coupling the predriver output signal to the second inverter chain, it being configured to translate the predriver output signal to a higher voltage range to produce a translated predriver output signal. A driver transistor is controlled using the driver output signal to produce the oscillatory output signal, and circuitry coupled to the driver output transistor ensures that no port-to-port voltage of the driver output transistor exceeds the maximum port-to-port voltage. | 10-07-2010 |
