Abstract: In embodiments, a new analog-to-digital converter (ADC) architecture can be used with switch-mode power supplies (SMPS) operating at switching frequencies higher than 10 MHz. Analog-to-digital converter embodiments can achieve very low power consumption, fast conversion time, and can be implemented with a simple hardware. Another noteworthy benefit is that certain ADC embodiments feature a non-linear gain characteristic that provides improved load transient response for digital controllers.

Abstract: A voltage reference forces a constant voltage at the inputs to an amplifier, thereby negating a need for a dummy detector on the non-active input of the amplifier.

Abstract: A phase detector is adapted to receive first and second signals and generate third and fourth signals representative of the difference between the phases of the first and second signals. The phase detector assert the third signal in response to the assertion of the first signal and unasserts the third signal in response to the assertion of the second signal. The phase detector asserts the fourth signal in response to the assertion of the third signal and unasserts the fourth signal in response to unassertion of the first signal. The phase detector may include combinatorial logic gates, thereby to generate the third and fourth signals in response to logic levels of the first and second signals. The phase detector may include sequential logic gates, thereby to generate the third and fourth signals in response to transitions of the first and second signals.

Abstract: Methods and devices perform analog to digital signal conversion in shorter time and/or with less power consumption than that of a comparable analog to digital conversion that uses a conventional sequential approximation method based on a binary search. A predictive guess is supplied as a digital first signal. The digital first signal is converted (D/A) to a counterpart, analog guess signal. Fewer cycles and less power is consumed if the initial guess is within a certain range of the actual magnitude of the analog input sample signal. In one embodiment, a digital modeler is used to model a process underlying the analog input sample signal to thereby provide fairly good guesses.

Abstract: A low voltage CMOS output driver is adapted to generate an output voltage that stays within predefined limits at relatively low supply voltages. The output driver includes, in part, a voltage-controlled resistor, a voltage-controlled current sink, and a switching stage. A control circuit provides the voltages that are applied to the voltage-controlled resistor and the voltage-controlled current sink. The voltage applied to the voltage-controlled resistor defines the high output voltage. The voltage applied to the voltage-controlled current sink defines the low output voltage. The control circuit is a scaled replica of the output driver and is adapted to consume a current that is 1/L times the current consumed by the output driver.

Abstract: The input stage of an operational amplifier includes at least four signal-receiving stages adapted to receive four primary input signals. If the voltage level associated with any of the input signal changes, at least one transistor in each of the at least four signal-receiving stages conducts more current and at least one transistor in each of these stages conducts less current. The four signal-receiving stages collectively generate at least four intermediate signals that are delivered to the output stage of the differential amplifier, which in response, generates a pair of differential output signals. Two of the input signals are derived from the pair of differential output signals and are fed back to control the amplifier.

Abstract: A sub-bandgap reference voltage generator, generates a pair of variable voltages one having a positive temperature coefficient and one having a negative voltage coefficient. The pair of voltages are added to generate an output voltage whose value and temperature may be varied. To achieve this, a first voltage having a positive temperature coefficient is multiplied by a first ratio defined by first and second resistive values to generate a second voltage. A third voltage having a negative temperature coefficient is multiplied by a second ratio defined by third and fourth resistive values to generate a fourth voltage. The second and fourth voltages are added together to generate the output voltage of the sub-bandgap voltage generator.

Abstract: In a SONET apparatus, the data flow differences between OC-768 and OC-192 can be exploited to effectuate conversion between OC-768 and OC-192 using as little as 256 bytes of memory.

Abstract: A charge pump is configured to control current flow at an output node in response to input signals. A plurality of control signals are generated based upon the input signals. The control signals operate to control the timing and duration of current flows within the charge pump and to thereby reduce charge pump power consumption. Based upon the control signals, the conductivity of a first path between a power supply and the output node and a second path between the output node and a ground potential is varied. Optionally, the charge pump is disposed as part of a phase-locked loop (PLL), the input signals are produced by a phase/frequency detector, and current flow at the output node controls an oscillator element.

Abstract: A flip-flop is configured to operate either in a double data-rate mode or a normal mode. When configured to operate in the double data-rate mode, the flip-flop outputs data on both edges of the applied clock. When configured to operate in the normal mode, the flip-flop outputs data on either the rising or falling edges of the applied clock. In the double data-rate mode, when a first latch disposed in the flip-flop operates in a sampling mode, the second latch disposed in the flip-flop operates in a holding mode to supply the output data, and when the second latch operates in the sampling mode, the first latch operates in the holding mode to supply the output data. Accordingly, with each of the rising or falling edge of the clock, one of the latches supplies an output data.

Abstract: A driver includes, in part, a delay chain having disposed therein a multitude of accessible nodes, and a control logic coupled to the various nodes of the delay chain to generate the signals applied to the gate terminals of the PMOS and NMOS transistors disposed in the driver. The nodes that are accessed and tapped may or may not be the successive nodes disposed along the delay chain. Optionally four nodes of the delay chain are tapped to supply signals to the control logic. Two of the nodes, carrying in-phase signals, are tapped to generate a first signal, which is used to generate a second signal driving the NMOS transistor. The other two nodes, carrying in-phase signals, are tapped to generate a third signal, which is used to generate a fourth signal driving the PMOS transistor. The first signal is 180° out-of-phase with respect to the third signal.

Abstract: A phase detector is adapted to receive first and second signals and generate third and fourth signals representative of the difference between the phases of the first and second signals. The phase detector assert the third signal in response to the assertion of the first signal and unasserts the third signal in response to the assertion of the second signal. The phase detector asserts the fourth signal in response to the assertion of the third signal and unasserts the fourth signal in response to unassertion of the first signal. The phase detector may include combinatorial logic gates, thereby to generate the third and fourth signals in response to logic levels of the first and second signals. The phase detector may include sequential logic gates, thereby to generate the third and fourth signals in response to transitions of the first and second signals.

Abstract: To detect whether a closed-loop's voltage is out of range, a voltage detector includes first and second transistors that deliver first and second currents respectively to first and second high impedance nodes. The voltage detector further includes third and fourth transistors that draw third and fourth currents respectively from the first and second nodes. The first and second currents are scaled replicas of a current flowing through a current source of a voltage-to-current converter that converts the close-loop's voltage to a current and supplies a first voltage to the first and second transistors. The third and fourth currents are scaled replicas of a different current flowing through a current mirror of the voltage-to-current converter and that supplies a second voltage to the third and fourth transistors.

Abstract: A mechanism for dealing with faster clock speeds by increasing the pulse width of the pump-up and pump-down pulses of a Hogge-type phase detector without dividing the clock. In particular, the NRZ data stream is divided into two, interleaved data streams which are provided through two series of flip-flops. By connecting the exclusive-OR gates separately to the two series of flip-flops to generate the pump-up and pump-down pulses, a longer time between transitions can be achieved by having alternate transitions (up and down) used by the two different series of flip-flops. In addition, delay circuits are provided to compensate for the clock-to-data output delay of the flip-flops.

Abstract: The input stage of an operational amplifier includes at least four signal-receiving stages adapted to receive four input signals. If the voltage level associated with any of the input signal changes, at least one transistor in each of the at least four signal-receiving stages conducts more current and at least one transistor in each of these stages conducts less current. The four signal-receiving stages collectively generate four intermediate signals that are delivered to the output stage of the differential amplifier, which in response, generates a pair of differential output signals. Two of the input signals are derived from the pair of differential output signals and are fed back to the input stage of the amplifier.

Abstract: A differential digital-to-analog voltage converter (VDAC) includes, in part, a resistor, and at least two decoding stages. The resistor is divided into N equal segments each disposed in a different one of N decoders forming a first decoding stage. The resistor segment in each decoder is further divided into M equal segments to provide M tapped nodes. Each decoder of the first decoding stage delivers two of the M tapped voltages to a pair of associated output nodes, and that are complementary with respect to a voltage present at the center of the resistor segment disposed in that decoder. A second decoding stage receives the first and second voltages delivered by each of the N decoders and delivers two of these voltages, that are complementary with respect to a voltage present at the center of the resistor, to a pair of third and fourth output nodes.

Abstract: To detect whether a closed-loop's voltage is out of range, a voltage detector includes first and second transistors that deliver first and second currents respectively to first and second high impedance nodes. The voltage detector further includes third and fourth transistors that draw third and fourth currents respectively from the first and second nodes. The first and second currents are scaled replicas of a current flowing through a current source of a voltage-to-current converter that converts the close-loop's voltage to a current and supplies a first voltage to the first and second transistors. The third and fourth currents are scaled replicas of a different current flowing through a current mirror of the voltage-to-current converter and that supplies a second voltage to the third and fourth transistors.

Abstract: A differential output driver includes an output block, a replication block, and a feedback control block. Each of the output and replication blocks further includes a preamplifier and a source-follower stage. The preamplifier of the output block receives a differential input voltage and generates a first differential voltage. The source-follower stage of the output block receives the first differential voltage and generates a differential output voltage. The preamplifier of the replication block receives first and second supply voltages and generates a second differential voltage. The source-follower stage of the output block receives the second differential voltage and generates a third differential voltage. The feedback control block receives the third differential voltage and generates a differential control voltage applied to the output block. The generated differential output voltage stays within predefined limits, such as those defined by the LvPECL standard.

Abstract: A bandgap reference voltage generator includes, in part, a first closed-loop circuit having a first operational amplifier and adapted to generate a first current with a positive temperature coefficient and a second closed-loop circuit having a second operational amplifier and adapted to generate a second current with a negative temperature coefficient. The bandgap reference voltage generator is further adapted to include a multitude of output stages. Each output stage may be independently scaled to sum any selected multiple of the first current to any selected multiple of the second current to generate an output voltage having either a nearly zero, a positive or a negative temperature coefficient. For example, the first output stage may be scaled to generate a reference output voltage with a nearly zero temperature coefficient. Similarly, the second output stage may be scaled to generate a reference output voltage with a negative temperature coefficient.

Abstract: A differential digital-to-analog voltage converter (VDAC) includes, in part, a resistor, and at least two decoding stages. The resistor is divided into N equal segments each disposed in a different one of N decoders forming a first decoding stage. The resistor segment in each decoder is further divided into M equal segments to provide M tapped nodes. Each decoder of the first decoding stage delivers two of the M tapped voltages to a pair of associated output nodes, and that are complementary with respect to a voltage present at the center of the resistor segment disposed in that decoder. A second decoding stage receives the first and second voltages delivered by each of the N decoders and delivers two of these voltages, that are complementary with respect to a voltage present at the center of the resistor, to a pair of third and fourth output nodes.