Abstract: A level shifter transfers a first voltage signal to a second voltage signal. The level shifter comprises a comparison circuit, a delay circuit, and a selection circuit. The comparison circuit generates a first signal according to the comparison result between the first voltage signal and the reverse-phase signal of the first voltage signal. The delay circuit generates a second signal according to the first voltage signal. The selection circuit receives the first and the second signals and chooses the higher voltage one from the first signal and the second signal to be the second voltage signal.

Abstract: A voltage level shifter for translating a binary input signal representing a binary sequence to a binary output signal representing the same binary sequence. The voltage level shifter comprises an input port for receiving the binary input signal as an input voltage varying between a first input voltage level and a second input voltage level. An output port is connected to a node for outputting the binary output signal as an output voltage varying between a first output voltage level and a second output voltage level. A supply voltage node connectable to a voltage supply, can provide the second output voltage level. A first switch is arranged to couple the supply voltage node to the node and to decouple the supply voltage node from the node based on a voltage at the node. A feedback voltage loop is connected to the node for providing a feedback voltage based on the voltage at the node.

Abstract: In accordance with an embodiment, a level shifter circuit includes a reconfigurable level shifting core coupled to a first node and a second node. The reconfigurable level shifting core is configured as a current mirror in a first mode, and as a cross-coupled device in a second mode. In the first mode, the current mirror mirrors a current at the first node to the second node, and in the second mode, the cross-coupled device produces a current at the second node in response to a voltage at the first node, and a current at the first node in response to a voltage at the second node.

Abstract: A circuit includes a first capacitive device and a first latch. The first capacitive device includes a first end configured to receive a first input signal and a second end coupled with the first latch. The first latch includes a first transistor and a second transistor that are of a first type. A first terminal of the first transistor and a first terminal of the second transistor are each configured to receive a first voltage value. A second terminal of the first transistor is coupled with a third terminal of the second transistor. A third terminal of the first transistor is coupled with a second terminal of the second transistor and with the second end of the capacitive device, and is configured to provide an output voltage for the first latch.

Abstract: A semiconductor device includes: a DLL circuit that generates an internal clock signal based on an external clock signal; a clock dividing circuit that generates two complementary internal clock signals having different phases based on the internal clock signal; and a multiplexer that outputs two internal data signals in synchronization with the two clock signals based on internal data signals, respectively. An internal power supply voltage supplied to the clock dividing circuit and an internal power supply voltage supplied to the multiplexer are generated by respective different power supply circuits and are separated from each other in the semiconductor device. This prevents interaction among noises.

Abstract: A flip-flop operating with standard threshold voltage MOS devices as compared with high threshold voltage MOS devices may have improved speed performance, but greater leakage current. Likewise, a flip-flop operating with high threshold voltage MOS devices may reduce the leakage current and have better power efficiency, but decreased speed and performance. An optimized flip-flop may include a combination of standard threshold voltage MOS devices and high threshold voltage MOS devices. The optimized flip-flop may have less leakage during stand-by mode as compared to a flip-flop with standard threshold voltage MOS devices. In addition, the optimized flip-flop may have better performance and speed as compared to a flip-flop with high threshold voltage MOS devices.

Abstract: A level shifter system includes an inverting portion, a non-inverting portion and a cross latch output component. The inverting portion is configured to receive an inverting input, a supply voltage and to generate an intermediary inverting output. The non-inverting portion is configured to receive a non-inverting input, the supply voltage and to generate an intermediary non-inverting output. The cross latch output component is configured to drive the intermediary inverting and non-inverting outputs to inverting and non-inverting outputs, respectively. The inverting and non-inverting outputs are at selected upper and lower levels according to the inverting input and non-inverting inputs, respectively.

Abstract: An apparatus comprising a first stage and a second stage. The first stage may be configured to generate an intermediate signal having a first voltage in response to an input signal having a second voltage received from a pad. The second stage may be configured to generate a core voltage in response to the first voltage. The voltage received from the pad may operate at a voltage compliant with one or more published interface specifications.

Abstract: A level-down shifter includes: a first load device between a first voltage and a first node; a second load device between the first voltage and a second node; a first input device between the first node and a third node, receiving a reference voltage signal, and adjusting a first node voltage of the first node based on the reference voltage signal; a second input device between the second node and the third node, receiving an input signal, and adjusting a second node voltage of the second node based on the input signal; and a current source between a second voltage and the third node, receiving the second node voltage of the second node, and adjusting a third node voltage of the third node and a bias current based on the second node voltage of the second node, wherein a level of the input signal is higher than the first voltage.

Abstract: A standard cell circuit including an input terminal to which input an input signal is input; an output terminal to output an output signal; a first wiring conductor, connected to an external power supply that outputs a first power supply voltage; a second wiring conductor to supply a second power supply voltage that is lower than the first power supply voltage; a standard cell to operate at the second power supply voltage supplied from the second wiring conductor; and a conversion circuit, connected to the first wiring conductor and the second wiring conductor, to convert the first power supply voltage input from the first wiring conductor into the second power supply voltage for output to the second wiring conductor.

Abstract: A floating gate driver uses a single-end level shifter to translate a set signal and a reset signal induced by a rising edge and a falling edge of a switch signal to a common output terminal to generate an output voltage for a bistable circuit to generate a level shifted switch signal. Under control of a well transient detect signal asserted by detecting noise in the output voltage, a masking circuit between the single-end level shifter and the bistable circuit masks noise in the output voltage. This configuration has lower area penalty and better noise immunity.

Abstract: A level shifting circuit with dynamic control includes a dynamic controller and a level shifter. The dynamic controller outputs a dynamic voltage and an output data signal. The level shifter under control by the dynamic controller includes an input signal receiver, an output signal generator, and a bias current controller, which are coupled in series between a ground voltage and a high level voltage. The input signal receiver receives the output data signal of the dynamic controller and the output signal generator produces a level-shifted data signal according to the input data signal. The bias current controller controlled by the dynamic voltage is at a first current-output capability when the level-shifted data signal is at a stable stage and at a second current-output capability when the level-shifted data signal is at an unstable stage. The first current-output capability is greater than the second current-output capability.

Abstract: The present disclosure provides an output control circuit including a signal feedback circuit and an enable control circuit, wherein the signal feedback circuit is configured to compare an output voltage with a set output voltage threshold and to output a disable signal to an enable control circuit when the output voltage arrives at the set output voltage threshold, and wherein the enable control circuit is configured to stop an operation of a translation circuit, upon reception of the disable signal from the signal feedback circuit.

Abstract: A voltage translator translates an input voltage signal in a low voltage domain into a output voltage signal in a high voltage domain using a latch that includes a pair of cross-coupled inverters. The bottom rail voltages for the cross-coupled inverters are varied dynamically to speed switching time for the voltage translator.

Abstract: A level shifter and integrated level shifter and metastability resolution flop circuit are disclosed. A circuit includes a generation circuit, in a first voltage domain, coupled to receive a logic signal via a single-ended input and configured to generate true and complementary values of the logic signal. The circuit further includes a storage circuit coupled to receive the true and complementary values of the logic signal from the generation circuit. The storage circuit is configured to store the true and complementary values of the logic signal. The storage circuit is in a second voltage domain. The circuit further includes an output circuit coupled to the storage circuit and configured to provide a differential output signal having true and complementary values corresponding to the true and complementary values of the logic signal. The circuit may be combined with a latch circuit coupled to receive the differential output signal.

Abstract: Described herein is a high-voltage level-shifter (HVLS) that can be used for both NMOS and PMOS bridges, exhibits a higher voltage tolerance for over-clocking than traditional level-shifters, has reduced crowbar current in its input driver, and no contention in its output driver. The HVLS comprises an input driver including a first signal conditioning unit, the input driver operating on a first power supply level and for conditioning an input signal as a first signal in the first signal conditioning unit; and a circuit to receive the first signal and to provide a second signal based at least in part on the first signal, the second signal being level-shifted from the first power supply level to a second power supply level, wherein the second power supply level is higher than the first power supply level.

Abstract: In accordance with some embodiments, the present disclosure relates to a dual mode control interface that can be used to provide both a radio frequency front end (RFFE) serial interface and a two-mode general purpose input/output (GPIO) interface within a single digital control interface die. In certain embodiments, the dual mode control interface, or digital control interface, can communicate with a power amplifier. Further, the dual mode control interface can be used to set the mode of the power amplifier.

Abstract: Embodiments of an apparatus are disclosed that may allow for the translation of signals from one power domain to another with well-balanced rise and fall times over a wide operational range. The apparatus may include an input buffer, a voltage shift circuit, and output circuit, and an output driver. The input buffer may be configured to generate a buffered version and delayed inverted version of an external signal at a first voltage level. The voltage shift circuit may be configured to generate two internal signals at a second voltage level dependent upon the output signals of the input buffer. The output circuit may be configured to generate two output driver signals at the second voltage level dependent upon the output signals of the voltage shift circuit. The output driver circuit may be configured to generate an output signal at the second voltage level dependent on the two output driver signals.

Abstract: A floating gate driver uses a single-end level shifter to translate a set signal and a reset signal induced by a rising edge and a falling edge of a switch signal to a common output terminal to generate an output voltage for a bistable circuit to generate a level shifted switch signal. Under control of a well transient detect signal asserted by detecting noise in the output voltage, a masking circuit between the single-end level shifter and the bistable circuit masks noise in the output voltage. This configuration has lower area penalty and better noise immunity.

Abstract: A voltage conversion mask signal generation circuit generates a first main signal and a first mask signal by converting an output signal of the first transistor to a low-side voltage, and generating a second main signal and a second mask signal by converting an output signal of the second transistor to a low-side voltage. A mask signal generation circuit generating a third mask signal with higher sensitivity than the first and second mask signals with respect to a fluctuation in the high-side reference potential. A mask logical circuit generating a fourth mask signal by performing a AND operation between the first mask signal and the second mask signal, and masking the first and second main signals with the third and fourth mask signals; and a SR flip flop circuit generating the output signal from the masked first and second main signals.

Abstract: A system and method are provided for bidirectional communications between a master device and one or more slave devices. Each slave device is coupled to first and second opto-isolators which are effective to provide galvanic isolation of the slave device from the master device. An encoder circuit is coupled between the master device and the first opto-isolators. A decoder circuit is coupled between the master device and the second opto-isolators. The master device generates transmissions to the slave devices along a first low logic path including the encoder and the first opto-isolators, wherein the decoder and the second opto-isolators are non-responsive to signals on the first path. The slave devices generate transmissions to the master device along a second low logic path including the second opto-isolators and the decoder, wherein the encoder and the first opto-isolators are non-responsive to signals on the second path.

Abstract: A voltage level shifting circuit with an input terminal and an output terminal. The level shifting circuit has a field-effect transistor (FET) switch with a gate attached to the input terminal, a drain attached to the output terminal and a source attached to a current changing mechanism. The current changing mechanism includes a current mirror circuit having an output connected between the source and an electrical earth. The output of the current mirror circuit is preferably adapted to change a current flowing between the drain and the source based on an input voltage applied to the gate.

Abstract: A dynamic voltage scaling system having time borrowing and local boosting capability, including: a time borrowing circuit and a local boost circuit. The time borrowing circuit connected electrically between a primary stage logic circuit and a secondary stage logic circuit is activated by an all-domain clock signal, and then generates an output data to the secondary stage logic circuit based on input data to the primary stage logic circuit. The local boost circuit is connected to a low working voltage line, when input data of the time borrowing circuit lags behind a positive level of said all-domain clock signal, the time borrowing circuit delays fetching data by a flip flop and changes state to produce a warning signal, so that the local boost circuit disconnects its connection with said low working voltage line, and is connected electrically to a high working voltage line.

Abstract: An integrated circuit (IC) includes a plurality of pads adapted to communicate signals with a circuit external to the IC, and a first mixed signal interface block coupled to a first pad in the plurality of pads, where the first mixed signal interface block is adapted to receive a first trigger signal from the circuit external to the IC and to provide a second trigger signal. The IC further includes a second mixed signal interface block coupled to a second pad in the plurality of pads, where the second mixed signal interface block is adapted to receive and track a first input signal from the circuit external to the IC in a first mode of operation of the IC.

Abstract: Provided is an integrated circuit including circuits driven in different voltage domains. The integrated circuit includes a logic circuit configured to be driven by a first power supply voltage having a first power supply voltage level, and a memory circuit configured to be driven by a second power supply voltage having a second power supply voltage level different from the first power supply voltage level. The memory circuit includes a circuit configured to interface with the logic circuit, configured to be supplied with power at the second power supply voltage level in response to an output signal, and configured to shift a level of a signal having the first power supply voltage level received from the logic circuit to the second power supply voltage level. The first power supply voltage corresponds to a first voltage domain, and the second power supply voltage corresponds to a second voltage domain.

Abstract: A signal buffer circuit includes a buffer to conduct a buffering operation for transmitting a signal to a subsequent unit; a resistor connected between an input side and an output side of the buffer; and a variable impedance device connected in series to the output side of the buffer. The variable impedance device is at low impedance when the buffer is conducting the buffering operation and at high impedance when the buffer is not conducting the buffering operation.

Abstract: The present invention provides a level shifter. In an embodiment, the level shifter includes first to sixth transistors. The first and second transistors have common control nodes coupled to a first bias voltage, receive a pair of input signals and respectively provide a first output node and a second output node. The fifth and sixth transistors have common control nodes coupled to a second bias voltage to form a current mirror. The third transistor is coupled between the first and the fifth transistors and has a control node coupled to the second output node. The fourth transistor is couple between the second and the sixth transistors and has a control node coupled to the first output node.

Abstract: Level shifting circuitry and corresponding enable signal generating circuitry provides improved leakage current control while eliminating the need for supplying reference voltage input in the enable signal generator. The level shifting circuitry is a type of cascode free level shifting circuit that does not include cascode transistors as in the prior art but instead utilizes cross coupled logic to provide level shifting while also utilizing enable signal controlled transistors to control leakage current through the cross coupled logic during power up sequencing. The level shifting circuitry provides improved leakage current limiting structure for power up sequencing whether a lower level supply voltage ramps up faster than the higher level supply voltage or vice a versa.

Abstract: A digital to analog converter including at least one current steering source and a master replica bias network. Each current steering source includes a data current source, two switches, two buffer devices, and two activation current sources. The switches are controlled by a data bit and its inverse for switching the source current between first and second control nodes. The buffer devices buffer the control nodes between corresponding output nodes. The activation current sources ensure that each buffer device remains active regardless of the state of the switches. The master replica bias network includes a replica buffer device coupled to a replica control node and a master buffer amplifier. The master buffer amplifier drives the first, second and replica buffer devices in parallel to maintain the first, second and replica control nodes at a common master control voltage to minimize noise and glitches at the output.

Abstract: A device and method for dc isolation and level shifting includes a driver circuit powered by a first voltage range, a capacitor connected to the driver circuit, and a latching circuit connected to the capacitor. The latching circuit is powered by a second voltage range and is configured to restore and/or minimize charge loss of the capacitor during a voltage transition at the capacitor. A device and method for analog isolation and measurement configured to measure an analog voltage at a second potential without requiring analog circuits at the second potential.

Abstract: In an integrated circuit (IC) adapted for use in a stack of interconnected ICs, interrupted through-silicon-vias (TSVs) are provided in addition to uninterrupted TSVs. The interrupted TSVs provide signal paths other than common parallel paths between the ICs of the stack. This permits IC identification schemes and other functionalities to be implemented using TSVs, without requiring angular rotation of alternate ICs of the stack.

Abstract: A switched-mode level-shifter shifts a differential voltage superimposed on a common-mode voltage. In the level shifter, a common-mode inductive reactor has at least two windings, and at least one of the differential voltage and the common-mode voltage are applied to at least one of the windings of the reactor. A switch charges the inductive reactor when caused to be in a first state, where the inductive reactor when charged experiences a change of flux according to the applied voltage. The switch also actuates a reset of the charged inductive reactor when caused to be in a second state, where the inductive reactor when reset reverses the change of flux experienced thereby. A source of a chopping signal is provided to alternately drive the switch between the first and second states, where each of the first and second states is one of in and out of conduction.

Abstract: A level shifting circuit and methodology involving a switching current generator responsive to switching of an input signal for producing a switching current to switch an output signal, and a holding current generator for producing a holding current to hold the logic level of the output signal in accordance with the logic level of the input signal. The holding current is produced independently of the switching current.

Abstract: The multi-dimensional data registration integrated circuit for driving array-arrangement devices, comprising: a plurality of the i-th hierarchy sets, each of the i-th hierarchy sets is divided into a plurality of the (i+1)-th hierarchy sets; a i-th hierarchy address selection circuit, comprising a signal generation unit and a multiplexing unit, wherein the former generates an enable signal, the latter is connected to the signal generating unit and shifts the input data based on the enable signal and a second timing signal to further generate n bits of address signals, the i-th hierarchy address selection circuit is used to scan the plurality of the i-th hierarchy sets and select at least one of the i-th hierarchy sets to function; and a data supply circuit to follow a scan sequence of a j-th hierarchy address selection circuit and write a plurality of data into the selected j-th hierarchy sets.

Abstract: Embodiments of the present disclosure enable low swing dynamic circuits with reduced dynamic power and leakage power. In an embodiment, a level detector circuit monitors the pre-charge voltage level of the dynamic node of a dynamic circuit and discontinues the charging of the dynamic node when the pre-charge voltage exceeds a logic high reference voltage. The logic high reference voltage is selected below a supply voltage of the dynamic circuit, resulting in a low swing dynamic circuit. In another embodiment, the pull-down logic circuitry is disconnected from the dynamic node when the dynamic node voltage falls below a logic low reference voltage, above a ground voltage. In another embodiment, a DC keeper circuit of the dynamic circuit is configured based on the pre-charge level of the dynamic node.

Abstract: Detection and deterrence of device tampering and subversion by substitution may be achieved by including a cryptographic unit within a computing device for binding multiple hardware devices and mutually authenticating the devices. The cryptographic unit includes a physically unclonable function (“PUF”) circuit disposed in or on the hardware device, which generates a binding PUF value. The cryptographic unit uses the binding PUF value during an enrollment phase and subsequent authentication phases. During a subsequent authentication phase, the cryptographic unit uses the binding PUF values of the multiple hardware devices to generate a challenge to send to the other device, and to verify a challenge received from the other device to mutually authenticate the hardware devices.

Abstract: A voltage switch circuit uses PMOS transistors to withstand high voltage stress. Consequently, the NMOS transistors are not subject to high voltage stress. The lightly-doped PMOS transistors are compatible with a logic circuit manufacturing process. Consequently, the voltage switch circuit may be produced by a logic circuit manufacturing process.

Abstract: A current mirror modified level shifter includes a pair of PMOS including a PMOS (MPL) and a PMOS (MPR), wherein a Vot node connected to a drain of the PMOS (MPR); a pair of NMOS including NMOS (MNL) and a NMOS (MNR), wherein sources of the PMOS (MPL) and the PMOS (MPR) are coupled to a high voltage (HV), respectively; gates of the PMOS (MPL) and the PMOS (MPR) coupled together through a Vm node which located between the gates of the PMOS (MPL) and the PMOS (MPR); and a suspended PMOS (MPM) coupled to drain of the PMOS (MPL), the Vm node being coupled to a Va node between drain of the suspend PMOS (MPM) and drain of the NMOS (MNL).

Abstract: Circuits, architectures, a system and methods for providing multiple power rails to a plurality of standard cells in a region of an integrated circuit. The circuitry generally includes a plurality of cells configured for connection to a first or second power rail, the first power rail providing a first voltage to at least one of the plurality of cells, and the second power rail providing a second voltage (which may be independent from the first voltage) to remaining cells in the plurality of cells. The method generally includes routing, in an IC layout, a first power rail providing a first voltage and a second power rail providing a second voltage, placing the plurality of cells, and selectively connecting first and second subsets of the plurality of cells to the first and second power rails, respectively. The present invention further advantageously minimizes regional layout design considerations and time delays.

Abstract: A level shifter includes first, second and third capacitively configured transistors, first and second switching transistors, and an inverting circuit. The first capacitively configured transistor has a first terminal that receives an input signal. Second and third capacitively configured transistor each have first terminal coupled to a second terminal of the first capacitively configured transistor. The second capacitively configured transistor is coupled in series with a first switching transistor that is also coupled to a first power supply terminal. The third capacitively configured transistor is coupled in series with a second switching transistor that is also coupled to a second power supply terminal.

Abstract: State definition and retention circuits are described. In one embodiment, a circuit includes two cross-connected PMOS transistors, first, second, and third NMOS transistors coupled to the PMOS transistors, an inverter circuit, and an output transistor connected to the PMOS transistors and to an output terminal of the circuit. The second NMOS transistor is connected to an input terminal of the circuit. A drain terminal and a gate terminal of the third NMOS transistor are connected to gate terminals of the PMOS transistors. The inverter circuit is coupled to the first and second NMOS transistors and to the input terminal. The inverter circuit is connected between a first power supply and a first base voltage. The PMOS transistors, the NMOS transistors, and the output transistor are connected between a second power supply and a second base voltage. Other embodiments are also described.

Abstract: Described embodiments include a level shifter that provides a voltage level shift to applied signals, the amount of voltage shift being accurately controlled and independent of PVT. The level shifter has first transistor configured as a voltage follower with the gate coupled to an input terminal of the shifter and the source coupled to a node, a diode-connected transistor coupled between the node and an output terminal of the circuit, a first controlled current source coupled to the node, and a second controlled current source coupled to the output terminal. A controller receives a bandgap-stabilized voltage, squares the stabilized voltage to produce a control signal that controls the first and second controlled current sources. The voltage shift is proportional to a digitally-controlled scale factor (K) times the stabilized voltage. The ratio of the current from the first current source to the second current source is (K+1)/K.

Abstract: An integrated circuit (IC) includes a plurality of pads adapted to communicate signals with a circuit external to the IC, and a first mixed signal interface block coupled to a first pad in the plurality of pads, where the first mixed signal interface block is adapted to receive a first trigger signal from the circuit external to the IC and to provide a second trigger signal. The IC further includes a second mixed signal interface block coupled to a second pad in the plurality of pads, where the second mixed signal interface block is adapted to receive and track a first input signal from the circuit external to the IC in a first mode of operation of the IC.

Abstract: An apparatus includes an integrated circuit, which includes an input terminal, a second terminal to communicate with circuitry external to the integrated circuit, a multiplexer, a level shifter and a processor. The multiplexer is adapted to selectively couple the input terminal, the level shifter and the second output terminal together.

Abstract: Described herein is a voltage compensated level-shifter with nearly constant duty cycle and matching rise and fall slopes of the output of the level-shifter, no meta-stability, and nearly constant propagation delay across power supply levels. The voltage compensated level-shifter comprises a first inverter to receive an input signal for level shifting from a first power supply level to a second power supply level, and to generate a first inverted signal, the first inverter operating on the first power supply level; a second inverter to receive the input signal and to generate a second inverted signal, the second inverter operating on the second power supply level; and a NOR logical gate to receive the first and second inverted signals and to generate an output signal, the NOR logical gate operating on the second power supply level, wherein the output signal is level shifted to the second power supply level.

Abstract: In various embodiments, a circuit arrangement may be provided. The circuit arrangement may include a level shifting stage configured to be coupled to a first reference voltage, the level shifting stage having an output node. The circuit arrangement may further include a first input electrode in electrical connection with the level shifting stage. The circuit arrangement may also include a second input electrode in electrical connection with the level shifting stage. The circuit arrangement may further include a load having a first end and a second end, the first end coupled to the level shifting stage and the second end for coupling to a second reference voltage. In addition, the circuit arrangement may include a bypass circuit element connected in parallel to the load. The bypass circuit element may be configured to allow current to flow through upon application of an external voltage for bypassing the load.

Abstract: A level shifter circuit includes a first voltage conversion circuit and a second voltage conversion circuit. The first voltage conversion circuit receives an input signal having an amplitude ranging between a power supply potential (GND) and a power supply potential (VDDL), a power supply potential (VDDH) which is higher than the power supply potential (VDDL) is supplied. Further, a current limiting circuit is provided that limits a current supplied from a power supply line of the power supply potential (VDDH), and outputs a voltage signal with a larger amplitude than that of the input signal according to the input signal. The second voltage conversion circuit is supplied with the power supply potential (VDDH, and outputs an output signal with an amplitude ranging between the power supply potential GND and the power supply potential (VDDH).

Abstract: A system and method for providing an accurate current reference using a low-power current source is disclosed. A preferred embodiment comprises a system comprises a first section and a second section. The first section comprises a first simple current reference, an accurate current reference, and a circuit that generates a digital error signal based upon a comparison of an output of the first simple current reference and an output of the accurate current reference. The second section comprises a second simple current reference providing a second reference current, an adjustment circuit providing an adjustment current based upon the digital error signal, and a circuit biased with current equivalent to a summation of the second reference current and the adjustment current. The first simple current reference and the second simple current reference may be equivalent circuits.

Abstract: In an amplitude conversion circuit that converts an input signal having a small amplitude into an output signal having a large amplitude, the input signal is supplied to a gate of a transistor that discharges an output terminal through a capacitance element. A charging/discharging circuit causes a gate voltage of the transistor to be substantially equal to a threshold voltage during an inactive period of the input signal.

Abstract: One embodiment of the present invention relates to a level shifter circuit having switchable current mirrors that can be selectively activated and deactivated in a complementary manner to translate differential input signals between logic sides (e.g., to translate a differential input signal received at a low-side to a high-side). A latch is connected to outputs of the switchable current mirrors. The latch is configured to receive a translated output signal from an activated current mirror and drive the other output signal to a complementary value. The latch is also configured to provide the translated output signal to a switching element that deactivates (e.g., turns off) the activated switchable current mirror. Storage of the output signals allows for the current mirrors to remain deactivated until a new input signal is provided to the level shifter circuit, thereby allowing for a reduction in the static power consumption of the level shifter.