Abstract: The disclosed embodiments relate to an electronic device comprising a logic circuit comprising a plurality of logic banks. In accordance with embodiments of the present technique, at least one of the plurality of banks is configured to provide standby functionality to the electronic device. The electronic device further comprises a power supply coupled to the logic circuit, configured to power the at least one bank without powering all of the plurality of banks.

Abstract: Low power level shifter latch circuits with gated feedback for high speed integrated circuits, and a design structure on which the subject circuit resides are provided. A latch input stage operating in a domain of a first voltage supply receives a data input responsive to being enabled by predefined clock signals. A latch storage element coupled to the latch input stage includes a latch output stage operating in a domain of a second voltage supply provides a data output having a voltage level corresponding to the second voltage supply. The latch storage element includes a level shifting device providing level shifting from the first supply level to the second voltage supply level. The latch storage element includes feedback gate devices receiving the predefined clock signals to gate feedback to the latch input stage when data is being written to the latch input stage.

Abstract: 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.

Abstract: A semiconductor device includes a level shift circuit to convert an input signal having an amplitude from a first power supply potential to a second power supply potential to a signal having an amplitude from the first power supply potential to a third power supply potential, a first output portion to output voltage generated from the third power supply potential to an output terminal based on the output of the level shift circuit, the first output portion including a NMOS transistor, and a second output portion to output voltage generated from the third power supply potential to an output terminal based on the output of the level shift circuit, the second output portion including a PMOS transistor.

Abstract: In a program circuit that can reduce exhaustion of a switching element that uses oxidation-reduction reactions of an electrolyte material, a voltage source (106) applies voltage to a switching element (100), a measurement circuit (107) measures a parameter that changes in accordance with the resistance value of the switching element (100), and a control circuit (104) causes the voltage source (106) to apply voltage to the switching element (100) while progressively increasing the voltage. The control circuit (104) further causes the voltage source (106) to halt the application of voltage when the parameter measured by the measurement circuit (107) reaches a prescribed value.

Abstract: Various serial interface implementations and related methods are provided for establishing serial data links with programmable logic devices (PLDs). In one example, a PLD includes a plurality of programmable logic blocks adapted to be programmed to configure the PLD for its intended function. The PLD also includes a serial interface comprising a transmit port, a microcontroller, a transmit register, and transmit logic. The microcontroller is adapted to adjust pre-emphasis settings associated with the transmit port to tune a serial data link between the PLD and an external device. The transmit register is adapted to receive a data signal from the programmable logic blocks. The data signal comprises transmit data to be provided over the serial data link through the transmit port. The transmit logic is adapted to prepare a serial signal for transmission from the transmit port over the serial data link. The serial signal comprises the transmit data.

Abstract: 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.

Abstract: 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.

Abstract: Memory devices and systems incorporate on-die termination for signal lines. A memory device comprises an integrated circuit die. The integrated circuit die comprises a pair of input signal pins that supply a pair of input signals, and an on-die termination circuit coupled between the pair of input signal pins that differentially terminates the pair of input signals.

Abstract: An interface detecting circuit and interface detecting method are provided, whereby operations can be carried out depending on peripheral devices connected to USB terminals, and whereby the system can be simplified and software load can be reduced. A pull-down resistor is connected to an ID terminal of a Mini-A receptacle of a peripheral device, the voltage generated by the pull-down resistor, which is pulled down by the ID terminal of the Mini-A receptacle of the peripheral device, and a pull-up resistor, which is pulled up by the ID terminal of a Mini-B receptacle of a device, is detected in an analog fashion, using a detecting section comprised of comparators, and, via a logic section, a logic output is subjected to noise cancellation in a filter section and is memorized in a register section. The operations of other devices are determined according to the states memorized in the register section.

Abstract: An input signal is routed to a first logic one reference signal generator or alternatively routed to a second logic one reference signal generator based at least one a voltage level of the input signal. When the voltage level of the input signal is less than a threshold value, the first logic one reference signal generator selectively generates a first logic one reference signal. When the voltage level of the input signal is greater than or equal to the threshold value, the second logic one reference signal generator alternatively generates a second logic one reference signal. The first and second logic one reference signals may be used to control a first voltage scaling circuit that drives a scaled output signal having a logic one value corresponding to the voltage level of the first logic one reference signal.

Abstract: A virtual ground restoration circuit is used to substantially eliminate excessive current from occurring in an integrated circuit device having two or more logic circuit modules in different voltage domains. Excessive current is caused when a signal between the two or more logic circuit modules in different voltage domains is at logic “0” and one of the logic circuit modules is biased at a voltage level above the true ground or common power source voltage, VSS, of the integrated circuit device.

Abstract: An integrated circuit includes multiple power domains. Supply current switch circuits (SCSCs) are distributed across each power domain. When a signal is present on a control node within a SCSC, the SCSC couples a local supply bus of the power domain to a global supply bus. An enable signal path extends through the SCSCs so that an enable signal can be propagated down a chain of SCSCs from control node to control node, thereby turning the SCSCs on one by one. When the domain is to be powered up, a control circuit asserts an enable signal that propagates down a first chain of SCSCs. After a programmable amount of time, the control circuit asserts a second enable signal that propagates down a second chain. By spreading the turning on of SCSCs over time, large currents that would otherwise be associated with coupling the local and global buses together are avoided.

Abstract: An integrated circuit comprises a processor, a controller and plural terminals. Each terminal constitutes a connection between the integrated circuit and a peripheral device. Each terminal is connected to a logic circuit on the integrated circuit by a respective IO cell in series connection with a respective IO isolation circuit and wherein the controller is operable on power up of the integrated circuit to activate a reset state and to release the reset state prior to releasing IO isolation by one or more of the IO isolation circuits. Each IO isolation circuit may be arranged so that a default state of the IO isolation circuit is a state in which the IO cell is isolated from the logic circuit. The IO isolation circuits may be controllable by software, for instance a driver for a peripheral device connected to the terminal associated with the IO isolation circuit. Plural IO isolation circuits may be connected so as to be commonly controllable by a single control signal from the controller.

Abstract: A CMOS output driver is provided for driving a capacitive load over a circuit trace in high speed applications. The CMOS output driver comprises a signal input and a signal output. The output driver has a first buffer amplifier with an input connected to the signal input and an output connected to the signal output through a resistor. A second buffer amplifier is also provided, which has an input connected to the signal input and an output connected to the signal output through a capacitor.

Abstract: A bidirectional signal separation module includes a comparator having a first input node communicatively coupled to a bidirectional single-ended bus, a second input node communicatively coupled to a first voltage source, and an output node communicatively coupled to a unidirectional data transmission node; and a resistive network having a first node communicatively coupled to the second voltage source, a second node communicatively coupled to the bidirectional single-ended bus, a third node communicatively coupled to ground, and a fourth node communicatively coupled to an electronic switch. The electronic switch is configured to alternately couple the fourth node of the resistive network to the second voltage source or ground according to a voltage level on a unidirectional data receiving node.

Abstract: A voltage level shifter with an input transistor pair, a cross-coupled load chain transistor pair and a pair of current sources, effects reduced power consumption through the use of the cross-coupled load chain transistor pair to minimize the DC current component present in known voltage level shifters. In specific embodiments, feedback elements may be used to minimize delays in signal transitions. A reference voltage that corresponds to a current capability of the input transistor pair may be used to regulate the current sources in the load chain. Changes in a swing of the input signal voltage received by the input transistor pair may be reflected in corresponding changes to the reference voltage. The voltage level shifter may be of particular use in a buffer.

Abstract: Low-leakage level-shifters with reduced leakage are disclosed. In one example, a level-shifter circuit to reduce leakage when there is an invalid supply voltage is described, including a level-shifter configured to shift a voltage of an digital input signal based on a first supply voltage to a digital output signal based on a second supply voltage, comprising a first transistor and a second transistor configured to set the digital output signal based on the digital input signal, a supply detector configured to generate a detection signal based on the first supply voltage, a disabler configured to, based on the detection signal, set the digital output signal of the level-shifter to a predetermined state, and a leakage reducer configured to, based on the detection signal, electrically disconnect the first and second transistors from the level-shifter.

Abstract: Circuits, methods, and apparatus for low-skew input/output level-shift circuits. One low-skew input/output circuit includes a single-ended-to-differential converter, a level-shift circuit, and a differential-to-single-ended converter. The circuit employs a low-skew single-ended-to-differential converter that provides an output to a level-shift circuit. To reduce skew, the single-ended-to-differential converter includes multiple paths from the input to its inverting and non-inverting outputs. The level-shift circuit translates signal levels between voltages used by the core and voltages used by the input and output circuits of the integrated circuit. An output from the level-shifter is received by the differential-to-single-ended converter. This converter also includes multiple signal paths coupling inverting and non-inverting signal paths.

Abstract: An electronic circuit arrangement is disclosed for converting an input voltage signal having a first voltage level into an output signal having a second voltage level. An input unit is provided for inputting the input voltage signal at the first voltage level, while an output unit is arranged for outputting the output signal at the output of the electronic circuit arrangement. A threshold value comparison unit serves for comparing the first voltage level of the input signal with a switch-on threshold value. The circuit arrangement furthermore contains an input impedance changeover unit for changing over an input impedance of the circuit arrangement from a low value to a high value after a predetermined delay duration after the first voltage level of the input voltage signal exceeded the switch-on threshold value.

Abstract: During transition, level shifters in a source driver output logic high signals to PMOS DACs and output logic low signals to NMOS DACs for shutting down current paths in the PMOS DACs and in the NMOS DACs. Therefore, during transition, the PMOS DACs and the NMOS DACs are at high-impedance stage for preventing gamma coupling effect.

Abstract: A data output circuit includes a plurality of drivers configured to drive data output terminals to a logic level corresponding to levels of input data in response to driving control signals, and a control section configured to activate and output driving control signals that supplied to a first group of the plurality of drivers, and to activate or inactivate and output driving control signals that supplied to a second group of the plurality of drivers, depending upon a level of a supply voltage.

Abstract: An integrated circuit includes multiple power domains. Supply current switch circuits (SCSCs) are distributed across each power domain. When a signal is present on a control node within a SCSC, the SCSC couples a local supply bus of the power domain to a global supply bus. An enable signal path extends through the SCSCs so that an enable signal can be propagated down a chain of SCSCs from control node to control node, thereby turning the SCSCs on one by one. When the domain is to be powered up, a control circuit asserts an enable signal that propagates down a first chain of SCSCs. After a programmable amount of time, the control circuit asserts a second enable signal that propagates down a second chain. By spreading the turning on of SCSCs over time, large currents that would otherwise be associated with coupling the local and global buses together are avoided.

Abstract: A method for a mix mode driver to accommodate traces of different lengths includes storing in the mix mode driver a set of one or more control signals and coefficient signals for a trace length. The one or more control signals select a number of the stages to generate a variable amplitude data output signal. Each stage is operable to increase or decrease a data signal, and each of the coefficient signals determines the magnitude of increase or decrease of the data input signal by a stage. A method for operating the mix mode driver includes generating the variable amplitude data output signal with one or more of the stages, and providing the variable amplitude data output signal to a trace.

Abstract: A semiconductor device includes an external pin, a control parameter decision circuit, and a register update circuit. The control parameter decision circuit includes a register and an output selector. The register is initialized in accordance with resetting of the semiconductor device. The output selector, according to a level value of an external input signal supplied via the external pin, selects one of a signal whose level value is set equal to a register value of the register and a signal whose level value is set opposite to the register value of the register, and outputs the selected signal as a control parameter signal. The register update circuit updates the register value of the register when a level value of the control parameter signal need be changed.

Abstract: The present invention provides for a device to reduce the voltage swing for control signals. An input signal with a maximum potential of DVDD and minimum potential of AVSS is level shifted to a maximum potential of AVDD and a minimum potential of AVDD-DVDD. A series of control signals are generated from the level shifted input signal by standard logic cells. The shifting of the input signal reduces the voltage swing for the control signals. These control signals are then used to drive a device operating at a potential of AVDD.

Abstract: A monolithic interface circuit for providing a voltage, from a control circuit supplied by a supply voltage referenced to a reference voltage, to a terminal likely to be at a high voltage with respect to the reference voltage, comprising a high-voltage N-channel MOS transistor having its gate intended to receive a control signal referenced to the reference voltage and having its source intended to be connected to the reference voltage, and a high-voltage PNP transistor having its base connected to the drain of the MOS transistor, having its emitter intended to receive the supply voltage and having its collector intended to provide a voltage to the terminal likely to be at a high voltage.

Abstract: Signal offset variation caused by transistor variation/mismatch in integrated circuits may be reduced. In one embodiment, a buffer circuit has variable-valued circuits elements. Offset variation measurements are made and the variable-valued circuit elements are calibrated to reduce the measured offset variation. In another embodiment, each amplifying stage of a multi-stage buffer provides variable gain. The total DC gain of the cascade is distributed unevenly across the stages, with more DC gain being provided by amplifier stages at the beginning of the cascade than at the end. An additional pre-amplifier stage can also be provided at the beginning of the cascade.

Abstract: Multi-state restore circuitry that allows storage elements of a power-managed functional block to be loaded when the functional block is repowered up so that the functional block is ready for operation virtually immediately after voltage ramp-up of the functional block. The multi-state restore circuitry includes a restore-state detector for determining which one of a plurality of restore states of the functional block is applicable to a particular repowering-up of the functional block. The multi-state restore circuitry also includes restore logic that loads the storage elements as a function of the restore state determined by the restore-state detector.

Abstract: An interface circuit and an electronic device are used for expanding an output port of a micro processing unit. The interface circuit includes an input port electrically connected to the output port of the micro processing unit for receiving a control signals, and a plurality of output ports selectively driven to control external circuits by inputting different values of the control signal at the input port.

Abstract: A reference clock receiver structure according to the invention is provided. The structure preferably includes an input buffer that is formed from a PMOS differentiated pair of transistors and a first supply voltage. The PMOS differential pair receives a pair of differential inputs, and produces a pair of differential outputs. The structure also includes a level shifter that is coupled to receive the pair of differential outputs from the input buffer to provide gain to the pair of differential outputs to form a gained pair of differential outputs. The level shifter that includes a second supply voltage. The second supply voltage may have a smaller magnitude than the first supply voltage. Finally, the structure includes a CMOS buffer that is coupled to receive the gained pair of differential outputs. The CMOS buffer boosts the gained pair of differential outputs and converts the gained differential pair outputs into a single signal.

Abstract: A semiconductor integrated circuit 1 judges whether a power unit is performing a discharge operation or a charge operation. To reduce clock skew between a plurality of logic blocks in the semiconductor integrated circuit 1, when the power unit is performing the charge operation, the semiconductor integrated circuit 1 determines a logic block that needs to be operated for the execution of a target process, as an operation block whose operation is to be started, and, determines, in the rest of the logic blocks, a logic block having a termination rate whose value is larger than a value of the minimum termination rate, as the operation block whose operation is to be started, the value of the termination rate being larger by more than a predetermined value.

Abstract: A two-wire transmitter for receiving power supply from an external circuit through two transmission lines and also transmitting a current signal based on the measurement value of a sensor includes a current control section to which a voltage is supplied from an external circuit, for controlling the current value of the current signal based on an electric signal responsive to the measurement value of the sensor, if current consumption of the two-wire transmitter becomes smaller than the current value of the current signal, the current control section for charging and if the current consumption becomes larger than the current value of the current signal, the current control section for discharging; a computation control section for outputting the electric signal to the current control section and also outputting a setting signal based on predetermined computation processing information; a clock supply circuit for controlling the frequency of a clock signal based on the setting signal and supplying the clock sig

Abstract: The present invention relates to a flexible multi-functional logic circuit which switches a current direction to a serial or parallel direction using at least two single electron transistors (SETs) having the same pattern and as many field effect transistors (FETs) as the number of the single electron transistors and performs operations on multi-valued signals using Coulomb oscillation that is the unique characteristic of SET to enable conversion of a single logic circuit to four basic logic circuits of NAND, OR, NOR and AND gates and a device using the same.

Abstract: A semiconductor integrated apparatus includes a control circuit unit which is connected to a low potential power supply terminal and a ground potential power supply terminal, and to which a predetermined low potential power supply output is supplied via the low potential power supply terminal, an output circuit unit which is connected to a high potential power supply terminal and the ground potential power supply terminal, and to which an output from the control circuit unit is supplied, and a detection circuit unit which is connected to the low potential power supply terminal, and which detects a decline in the predetermined low potential power supply output. The apparatus further includes a level shifter circuit which is provided between the control circuit unit and the output circuit unit, and which controls an output level of the output circuit unit in accordance with a detected output from the detection circuit unit.

Abstract: 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.

Abstract: A pull-up circuit comprises an operational amplifier which forms part of a feedback circuit, acting to bring a pull-up circuit output equal to a reference voltage input. The pull-up circuit may form part of a USB transceiver for incorporation in a USB Device. When the supply voltage of the USB Device is sufficiently high, it is used to provide the required pull-up voltage, with the feedback circuit including the operational amplifier the USB Device is not high enough to provide the required pull-up voltage. In that case, the USB bus voltage is used to generate the reference voltage which is used as an input to the feedback circuit.

Abstract: An integrated circuit arrangement is disclosed. In one embodiment, the integrated circuit arrangement includes an output circuit having at least one first output connection which can provide a data signal, at least one first data output connection; and at least one first inductance connected between the at least one first output connection and the at least one data output connection.

Abstract: An input and/or output pad (P) is dedicated to an integrated circuit comprising a core with input and/or output pins. This pad (P) comprises a pad cell (PC) comprising a pad block (PB) connected to an input buffer (IB1, IB2) and/or an output buffer (OB) and arranged to be connected to one of the core input and/or output pins. The pad (P) also comprises a pad logic module (PLM) comprising a first boundary scan cell (BC1) and/or a second boundary scan cell (BC2), connected to the pad block (PB) through the input buffer (IB1, IB2) and/or output buffer (OB) and arranged to feed input signals to and/or deliver output signals from the pad block (PB), and control means connected to the first (BC1) and/or second (BC2) boundary scan cell(s) and adapted to receive control signals for controlling access to the first and/or second boundary scan cell(s) and feeding the first boundary scan cell (BC1) with the input signals and/or outputting the output signals delivered by the first boundary scan cell (BC 1).

Abstract: 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.

Abstract: The low power consumption CMOS high voltage driving circuit relates to a kind of high voltage driving circuit for output driving, and there is an out buffer stage between the output end of the level switch stage and the input end of the high voltage output stage, comprising a high voltage PMOS pipe and a high voltage NMOS pipe. The source of the high voltage PMOS pipe is connected with the power supply, its gate electrode is connected with the output end of the upper level out buffer unit as the input end of the current level out buffer unit. The source of the high voltage NMOS pipe is put to earth, and its gate electrode serves as the receiving end of the 3ith sequence signal. The drain region of the high voltage PMOS pipe is connected with that of the high voltage NMOS pipe and is connected with the input end of the lower level out buffer unit as the output end of the current level out buffer unit.

Abstract: An integrated circuit (200) includes a pulsed buffer (226) having dynamic logic. The dynamic logic includes a first input device (215) coupled to receive a data input signal, a first dynamic node (222), and a first pull up device (224) which when conducting couples the first dynamic node (222) to a positive voltage supply. A first (234) and a second pull down device (238) are connected between the dynamic node (222) and a negative supply operable to discharge the dynamic node (222) when the first input device (215) and both the first and second pull down devices (238, 234) are on. The first pull down device (234) is connected to a first clock signal (CLK), and the second pull down device (238) is coupled to an inverted second clock signal having an odd number of signal inversions being >3 inversions, such as 3 inversions (CLKXXX), relative to the first clock signal (CLK).

Abstract: A level shifter is presented that allows fast switching while requiring low power. In accordance with some embodiments of the invention, the level shifter is a two stage level shifting circuit with p-channel and n-channel transistors biased so as to limit the potential between the source to gate or drain to gate of any of the transistors. Pull-up transistors are placed in a transition state so that spikes resulting from an increasing or decreasing input voltage turn on or off the pull up transistors to assist in the switching.

Abstract: Methods and corresponding systems for buffering an input signal include outputting a first logic value in response to the input signal being below a lower threshold. A second logic value is output in response to the input signal rising above the lower threshold. Thereafter, the second logic value is maintained until the input exceeds a higher threshold and thereafter falls below the higher threshold. In response to the input signal falling below the higher threshold, the first logic value is output, and maintained at the first logic value, until the input falls below the lower threshold and thereafter rises above the lower threshold.

Abstract: At least one of the disclosed systems includes driver logic that is capable of driving a device and pre-driver logic coupled to the driver logic and that drives the driver logic. If the pre-driver logic receives an input signal of a first type, the pre-driver logic activates a first transistor such that the pre-driver logic provides an output signal. If the pre-driver logic receives an input signal of a second type, the pre-driver logic activates a second transistor and a third transistor that together cause the pre-driver logic to provide a different output signal. If the third transistor is not activated, the pre-driver logic provides the output signal.

Abstract: In one embodiment of the invention, an integrated device has interface circuitry that includes a dynamic monitor that monitors the relative potential between (at least) two different power supplies to enable the device to react to over-voltage conditions such that appropriate selections can be made for which power supplies are selected for different components in the interface circuitry, such as output drivers and input receivers. The dynamic monitor enables over-voltage protection to be automatically implemented before the device has been configured, such as during the device's power-on state.

Abstract: A design structure for a signal-handing apparatus or communication apparatus is provided which includes a common signal node operable to conduct a first signal, a first circuit coupled to the common signal node to utilize the first signal and a signal-handling element coupled to the common signal node. A signal-handling apparatus may include an isolating circuit coupled to a first conductor, a second conductor to conduct an output of the isolating circuit, and a signal-handling circuit coupled to the second conductor. A signal-handling circuit can perform a signal-handling function in response to the output of the isolating circuit. The signal-handling circuit and the first circuit may be isolated from the second conductor and the signal-handling circuit such that a communication signal may be conducted with less capacitance and be subject to less return loss.

Abstract: Techniques and circuits for ensuring undefined control signals are not inadvertently driven onto a bus due to core logic and I/O logic supply voltages reaching final voltage levels at different times are provided. According to some embodiments, an internal voltage supply sense circuit may monitor a level of a voltage supply that powers core logic that generates control signals to be driven on I/O pads. The sense circuit may generate one or more control signals used to keep I/O pads in a high impedance state.

Abstract: A level shift circuit prevents a through current in an output circuit connected to a high-voltage power supply, thereby reducing power consumption and noise and enabling a high-speed operation. The level shift circuit includes first and second bias generating circuits that supply a gate bias voltage to each of a PMOS transistor as a first transistor and a NMOS transistor as a second transistor. Each of the first and second bias voltage generating circuits includes a series connection of a diode-connected PMOS transistor and a diode-connected NMOS transistor. The discharge of a capacitor to the high-voltage power supply is prevented, and a through current is prevented when an output signal transitions from a high-level to a low-level and vice versa, whereby power consumption and noise can be reduced.

Abstract: The disclosure relates to a voltage converter, converting a first signal of a first voltage to output a second signal of a second voltage. A level shifter receives the first signal to generate the second signal. An isolation circuit is coupled to the output of the level shifter, passing the second signal out. When the input of voltage converter is floated, the isolation circuit stops passing the second signal as the output, instead, the isolation circuit outputs a substitution signal having a predetermined voltage level irrelevant to the input of the level shifter.