Abstract: A comparator circuit having reduced pulse width distortion includes a differential amplifier operative to receive at least first and second signals and to amplify a difference between the first and second signals. The differential amplifier generates a difference signal at an output thereof which is a function of the difference between the first and second signals. An output stage is included in the comparator circuit for receiving the difference signal and for generating an output signal of the comparator circuit, the output signal being representative of the difference signal, the output stage having a switching point associated therewith. The comparator circuit further includes a voltage source coupled to the output of the differential amplifier. The voltage source is operative to generate a reference signal for establishing a common-mode voltage of the difference signal generated by the differential amplifier.

Abstract: A comparator circuit includes a reference generator connecting to a first source providing a first voltage. The reference generator is operative to generate a reference signal and includes a control circuit selectively operable in at least a first mode or a second mode in response to a first control signal, wherein in the first mode the reference signal is not generated, and in the second mode the reference generator is operative to generate the reference signal. The comparator circuit further includes a comparator connecting to a second source providing a second voltage, the second voltage being less than the first voltage. The comparator is operative to receive the reference signal and an input signal, and to generate an output signal which is a function of a comparison between the input signal and the reference signal.

Abstract: A bias circuit includes a reference generator for generating a bias signal at an output of the reference generator. The reference generator is selectively operable a first mode or a second mode in response to a first control signal applied to the reference generator, wherein in the first mode of operation, the reference generator is disabled, and in the second mode of operation, the reference generator is operative to generate the bias signal. The bias circuit further includes a shunt circuit connected to the reference generator. The shunt circuit is configured to provide a source of current to assist in charging the output of the reference generator to a quiescent operating level during the second mode of operation. The shunt circuit, in response to a second control signal applied thereto, is operable for a selected period time after the reference generator transitions from the first mode of operation to the second mode of operation.

Abstract: When a P-channel pass gate transistor is added in parallel to an N-channel pass gate, the resulting circuit improves overvoltage tolerance of an input buffer. A simple bias circuit including two small transistors controls a gate of this P-channel pass gate transistor in such a way that it is turned OFF when an overvoltage is applied, but turned ON when a normal voltage is applied. Another embodiment has two N-channel devices (M12, M13) coupled in series with each other and one of the N-channel devices (M13) being configured in a “turned off” position, by coupling the source and gate terminals to a ground voltage (VSS) and providing the supply voltage (VDD) at the gate terminal of another N-channel device (M12), whereby the device M12 protects the device M13 from overvoltage.

Abstract: An ESD protection circuit for protecting a circuit from an ESD event occurring between a first voltage supply node and a second voltage supply node associated with the circuit to be protected includes an MOS device having a gate terminal, a first source/drain terminal and a second source/drain terminal. The first source/drain terminal is connected to the first voltage supply node and the second source/drain terminal is connected to the second voltage supply node. The ESD protection circuit further includes a trigger circuit coupled to the gate terminal of the MOS device. The trigger circuit is configured to generate a control signal at the gate terminal of the MOS device for activating the MOS device during the ESD event.

Abstract: A voltage level translator circuit for translating an input signal referenced to a first voltage supply to an output signal referenced to a second voltage supply includes an input stage for receiving the input signal and a latch circuit for storing a signal at an output of the latch circuit which is representative of a logical state of the input signal. The latch circuit includes an input coupled to the input stage. The voltage level translator circuit further includes a feedback circuit coupled between the input and the output of the latch circuit. The feedback circuit is operative to maintain a desired logic state of the voltage level translator circuit when the second voltage supply powers up before the first voltage supply. In this manner, the voltage level translator circuit is configured to provide an output signal having a predictable logic state over a wide variation of PVT conditions and/or voltage supply ramp rates.

Abstract: A PUR circuit for generating a reset signal includes a first node for receiving a reference voltage and a second node for receiving a supply voltage that is referenced with respect to the reference voltage. The circuit further includes a voltage level detector coupled between the first node and a third node, the voltage level detector being configured to generate a first control signal at the third node. The voltage level detector includes a first transistor having a first threshold voltage associated therewith. A resistance element is coupled between the second node and the third node, the resistance element having a first resistance value associated therewith. The circuit also includes an inverter having an input coupled to the third node and having an output for generating a second control signal in response to the first control signal. The inverter includes a second transistor having a second threshold voltage associated therewith which is lower than the first threshold voltage.

Abstract: A buffer design for an integrated circuit that has adjustable slew rate control, yet requires significantly less space to fabricate than does a conventional buffer with slew rate control. A new slew rate control circuit design is added to a Complementary Metal Oxide Semiconductor CMOS buffer to implement slew rate control in the buffer (e.g., selection between a high slew rate and a low slew rate). The new slew rate control circuit requires significantly less space to fabricate, and when applied to each buffer in an given integrated circuit, e.g., input/output buffers that may be placed along the periphery of the integrated circuit, the savings can be extraordinary.

Abstract: A voltage level translator circuit for translating an input signal referenced to a first voltage level to an output signal referenced to a second voltage level includes an input stage for receiving the input signal. The input stage includes at least one transistor device having a first threshold voltage associated therewith. The voltage level translator circuit further includes a latch circuit operative to store a signal representative of a logical state of the input signal. The latch circuit includes at least one transistor device having a second threshold voltage associated therewith, the second threshold voltage being greater than the first threshold voltage. A voltage clamp is operatively connected between the input stage and the latch circuit, the voltage clamp being configured to limit a voltage across the input stage based, at least in part, on a control signal presented thereto.

Abstract: A circuit configurable for indicating a voltage level of an input signal applied to the circuit includes at least one transistor having a first terminal connected to a first voltage supply, a second terminal configured for receiving the input signal, and a third terminal operatively coupled to an output of the circuit. The circuit further includes a passive load connected between the third terminal of the transistor and a second voltage supply. The circuit is configured to generate an output signal at the output of the circuit. The output signal being at a first value indicates that the input signal is substantially at a first voltage level, and the output signal being at a second value indicates that the input signal is substantially at a second voltage level.

Abstract: A semiconductor resistor comprises a resistor body formed on a semiconductor substrate and first and second conductive terminals electrically connected to the resistor body at opposite ends thereof. The semiconductor resistor further includes at least first and second conductive paths between at least one of the first and second conductive terminals and the resistor body. The at least one conductive terminal is configured such that a resistance of the at least one conductive terminal between the at least first and second conductive paths is substantially matched to a resistance of the resistor body between the at least first and second conductive paths. In this manner, a current distribution between the at least first and second conductive paths is substantially matched.

Abstract: A compensation circuit comprises a reference circuit including a reference NMOS device and a reference PMOS device. The reference circuit is operative to generate a first reference signal and a second reference signal, the first reference signal being a function of at least one of a process characteristic, a voltage characteristic and a temperature characteristic of the reference NMOS device, and the second reference signal being a function of at least one of a process characteristic, a voltage characteristic and a temperature characteristic of the reference PMOS device. The compensation circuit further comprises a control circuit connected to the reference circuit.