Abstract: An example front-end module includes a channel to connect to a device under test (DUT). The front-end module includes a transmission line between the DUT and the front-end module that is configured for bidirectional transmission of oscillating signals including test signals and response signals, and in-phase and quadrature (IQ) circuitry configured to modulate a test signal for transmission over the transmission line to the DUT and to demodulate a response received over the transmission line from the DUT. The front-end module include at least four taps into the transmission line to obtain direct current (DC) voltage values based on the oscillating signals. Scattering (s) parameters of the channel are based on the DC voltage values. The front-end module includes at least six ports.

Abstract: A device includes a signal input to receive a data input as part of a bit stream. The device also includes a reference input to receive a reference signal. The device further includes push circuitry to receive a first weight value, receive a first correction value, and generate a push signal based on the first weight value and the first correction value to selectively modify the data input as well as pull circuitry to receive a second weight value, receive a second correction value, and generate a pull signal based on the second weight value and the second correction value to selectively modify the data input.

Abstract: A circuit includes a first circuit, a second circuit and a third circuit. The first circuit is configured to receive a first phase of a clock signal, a second phase of a clock signal and a first control signal. The first circuit is configured to generate a first interpolated phase of a clock signal. The second circuit is configured to receive a third phase of a clock signal, a fourth phase of a clock signal and a second control signal, and generate a second interpolated phase of a clock signal. The third circuit is configured to receive the first interpolated phase of the clock signal and the second interpolated phase of the clock signal, and generate the first control signal. The first control signal dynamically adjusts the first interpolated phase of the clock signal.

Abstract: An oscillation device includes an oscillator, an oscillation detection unit that detects oscillation of the oscillator and outputs an oscillation detection signal, and a drive unit that generates a drive signal in keeping with the oscillation detection signal and outputs the drive signal to the oscillator. The drive unit includes a phase shift unit that shifts the phase to provide the drive signal as positive feedback to the oscillator. The phase shift unit includes a disturbance generating unit that outputs the periodic signal, a fluctuation unit that causes the amount of phase shift to fluctuate based on the periodic signal, a drive amplitude detection unit that detects the amplitude of the drive signal and outputs a drive amplitude signal, a product detection unit that outputs a detection signal after performing product detection on the drive amplitude signal based on the periodic signal, and an adjustment unit that adjusts the phase-shift amount based on the detection signal.

Abstract: Embodiments of a high-resolution link-path delay estimator and method are generally described herein. The high-resolution link-path delay estimator may estimate a signal-path delay of a signal path between a master and remote device. The high-resolution link-path delay estimator may phase-shift a transmit signal of alternating symbols by phase-shift values and may sample a loopback signal. A noise-reduced version of the sampled signal output may be correlated with a step function to generate a correlation value for each of the phase-shift values. One of the phase-shift values may be selected to generate a fine-delay estimate which may be added to a coarse delay estimate to determine the signal-path delay. The coarse delay estimate may be an estimate of the signal-path delay to a nearest symbol period of the transmit signal and the fine-delay estimate may be an estimate to within a fraction of the symbol period.

Abstract: Techniques to compensate for sources of temperature and process dependent errors within an oscillator system for frequency control oscillator output clock signal. The oscillator system may include a controller and an oscillator circuit. The techniques may include generating a pair of voltages, a first of which is temperature variant, having (approximately) known temperature variations across process, and a second of which is (approximately) temperature invariant. Each voltage may be scaled by a corresponding trim factor. The scaled voltages may be combined to generate a reference voltage. The reference voltage may compensate for process and temperature dependent error sources within the oscillator system to set the oscillator output clock signal frequency.

Abstract: There is disclosed a power supply stage, comprising: generating means for generating a power supply voltage from a high efficiency variable voltage supply in dependence on a reference signal; adjusting means for receiving the generated power supply voltage, and adapted to provide an adjusted selected power supply voltage tracking the reference signal in dependence thereon.

Abstract: A line angle shift logic controller for use with a power generation system coupled to an electrical grid is disclosed. The line angle shift controller includes a line angle shift controller configured to receive a phase locked loop (PLL) error signal representative of a difference between a phase angle of the power generation system and a phase angle of the electrical grid, receive a threshold phase from the electrical grid, and generate a PLL shift signal based at least partially on the PLL error signal and the threshold phase.

Abstract: A data acquisition system includes an analog-to-digital converter (ADC) having a MUX control outputs, a controller coupled to the ADC, a multiplexer coupled to the MUX control outputs of the ADC, and an operational amplifier coupling an analog data output of the multiplexer to an input of the ADC. An ADC having integrated multiplexer control includes control logic circuitry, ADC circuitry, MUX logic and an oscillator coupled to the control logic circuitry, the ADC circuitry, and the MUX logic.

Abstract: A phase adjustment apparatus for providing a clock signal to a core circuit is provided. The core circuit is powered by a core voltage. The phase adjustment apparatus includes two clock receiving ends, a plurality of digital receiving ends and a combination circuit. The two clock receiving ends receive two original clocks having a same frequency while the two original clock signals possess different phases. The digital receiving ends receive a plurality of phase selection signals. The synthesizing circuit is powered by a first voltage lower than the core voltage, and generates the clock signal according to the phase control signals and the two original clock signals.

Abstract: Methods and systems to adjust a phase difference between signals, such as to perform quadrature phase correction. First and second signals are digitally compared, such as with exclusive OR circuitry, to provide a comparison signal having a duty cycle representative of a phase difference between the signals. A phase delay of one or both of the first and second signals is adjusted until the duty cycle of the comparison signal corresponds to a desired phase difference. In a clock and data recovery system, the signals may correspond to a zero degree phase of a first phase interpolator and a ninety degree phase of a second phase interpolator, and digital codes to the first and second phase interpolators may be adjusted to provide a fifty percent duty cycle in the comparison signal.

Abstract: An interpolation circuit, includes a bias generating module, a load module consisting of a current source sub-module and a load resistance sub-module, first and second clock control modules, and an output module. The first clock control module includes a first input sub-module, a first source terminal negative feedback sub-module, a first multiplex switch sub-module and a first multiplex current sink sub-module. The bias generating module includes first, second and third FETs, and a bias current terminal. The current source sub-module includes fourth and fifth FETs. The load resistance sub-module includes first and second resistors. The first input sub-module includes sixth and seventh FETs. The first source terminal negative feedback sub-module includes a third resistor and a first capacitor. The first multiplex switch sub-module includes first and second groups of switches. The first multiplex current sink sub-module includes first and second groups of FETs. An interpolation system is further provided.

Abstract: An interface apparatus for a semiconductor integrated circuit and an interfacing method thereof controls the VOX of differential signals to a target level in response to the differential signals being outputted by an output block. The interface apparatus for a semiconductor integrated circuit includes an output block configured to output differential signals output by an internal circuit a detector configured to detect a timing error of the differential signals; and a controller configured to control a timing of the differential signals output by the internal circuit according to a detection result of the detector.

Abstract: The present invention relates to a PLL circuit and an associated method that allows the PLL circuit to operate at a higher operating frequency with a wider bandwidth and a better out-band noise suppression. The PLL circuit comprises a delay locked loop (DLL), a phase-frequency detector (PFD), a loop filter, a voltage controlled oscillator (VCO) and a frequency divider.

Abstract: A digital phase detector circuit and corresponding monitor and control logic is presented. The digital phase detector has two storage elements, where the data input of the first storage element receives a first clock signal and the data input of the second storage element receives a second clock signal. A time shifter shifts the second clock signal by a shift period, and transmits the shifted signal to the clock input of the storage elements. The signals applied to the data inputs are transmitted from the storage elements when the clock input receives the shifted second clock signal from the time shifter. A monitor and control module samples the data output from the storage elements after each shifted second clock signal is transmitted by the time shifter. The sampling of the output data provides the data used to determine the time relationship between the first and the second clock signals.

Abstract: A structure for performing cross-chip communication with mesochronous clocks. The structure includes: a data delay line; a remote clock delay line; a structure that captures at least one value of a state of a delayed remote clock signal on the remote clock delay line; and a control that influences a delay associated with the data delay line and the remote clock delay line.

Abstract: A method for source synchronous communication. The method includes dynamically adjusting a delay that is applied to a data signal and a remote clock signal until a delayed remote clock signal is synchronized with a local clock signal, and capturing data from a delayed data signal associated with the delay in a local domain.

Abstract: A clock signal recovery device has a digital data signal input for the input of a digital data signal and a clock signal output for the output of a recovered clock signal. The digital data signal has a given nominal clock signal frequency. The clock signal recovery device is a digital circuit.

Abstract: A method of compensating clock skew may include generating (2M+1) detected values by applying (2M+1) delay clock signals to (2M+1) pieces of delay data, wherein M is a natural number, determining a dominant logic value based on a comparison of a number of logic high detected values and a number of logic low detected values from among the (2M+1) detected values, determining a median delay time based on a number of the (2M+1) detected values having the dominant logic value, and adjusting a phase of a clock signal using the median delay time.

Abstract: Methods and systems to adjust a phase difference between signals, such as to perform quadrature phase correction. First and second signals are digitally compared, such as with exclusive OR circuitry, to provide a comparison signal having a duty cycle representative of a phase difference between the signals. A phase delay of one or both of the first and second signals is adjusted until the duty cycle of the comparison signal corresponds to a desired phase difference. In a clock and data recovery system, the signals may correspond to a zero degree phase of a first phase interpolator and a ninety degree phase of a second phase interpolator, and digital codes to the first and second phase interpolators may be adjusted to provide a fifty percent duty cycle in the comparison signal.

Abstract: This invention relates to a phase control circuit for an optical receiver (1). The phase control circuit (9, 19) comprises a non-linear element (22) and a power detector (24). The non-linear element (22) has a rectifying characteristic, inputs the received electrical signal (7, 17) and provides a rectified signal at its output. The power detector (24) provides an error signal which is used to obtain a phase control signal (5) which is output by the phase control circuit. The invention further relates to a corresponding method for phase control of an optical receiver (1).

Abstract: In various aspects, ion sources, mass spectrometer systems, and a power supply circuit coupled to a feedback circuit are provided. A power supply is provided that includes at least the power supply circuit and is operable to transfer charge to a load. The feedback circuit is responsive to a DC component of an output voltage supplied by the power supply in a first feedback loop and an AC component of the output voltage in a second feedback loop to produce a feedback signal representative of at least one of: a value of the output voltage before a charge transfer from a capacitor of the power supply to a load; the value of the output voltage during the charge transfer from the capacitor of the power supply to the load; or the value of the output voltage after the charge transfer from the capacitor of the power supply to the load.

Abstract: A programmable delay clock buffer circuit, preferably implemented in a single IC, includes a clock circuit and a plurality of variable delay lines. The clock circuit receives an input clock and is clock feedback signal and generates an intermediate clock. Each of the delay lines is configured to receive the intermediate clock and to receive at least one delay control input. A first variable delay line of the plurality is configured to generate, based on a first delay control input, a first delay from the intermediate clock to produce a clock output signal. A second variable delay line of the plurality is configured to generate, based on a second delay control input, a second delay from the intermediate clock to produce a clock feedback signal. A method of distributing clock with through programmable delay lines is also presented.

Abstract: A first signal processor performs predetermined signal processing on an input signal to provide a change to at least one of the characteristic values thereof. A second signal processor is provided in the subsequent stage of the first signal processor and performs predetermined signal processing on an output signal from the first signal processor to provide a change to a characteristic value thereof. An amount of change provided to the characteristic value of the signal by the second signal processor is dependent on a power supply voltage. An amount of change provided to the characteristic value of the signal by the first signal processor is configured to be adjustable. A control circuit monitors a power supply voltage supplied to the second signal processor and adjusts in accordance with the power supply voltage the amount of change provided to the characteristic value of the signal by the first signal processor.

Abstract: A phase detector apparatus and method used for clock recovery from a data signal is provided. The phase detector provides phase correction signals to a clock signal generator, where the phase correction signals are only generated if a predetermined data sample pattern is observed. In particular, the predetermined data sample pattern is preferably a transition from one to zero. Thus, transitions from zero to one will not provide a valid phase update output signal, even though a transition has occurred. In other embodiments the predetermined data sample pattern is preferably a one to zero transition preceded by an additional logic one sample.

Abstract: A scalable DLL (delay locked loop) circuit that has a calibration mechanism to auto tune locking precision. The delay locked loop circuit includes a multi-phase phase locked loop circuit for generating a plurality of phase signals according to a system clock, wherein one of the phase signals is a pixel clock; a phase detector for detecting an integral phase error and a fractional phase error between a reference signal and a feedback signal according to the pixel clock; a phase selector for selecting one of the phase signals according to the fractional phase error; and a delay circuit for shifting the phase of the reference signal according to the integral phase error and the selected phase signal to generate an output signal.

Abstract: A programmable delay lock loop system provides a delayed output signal having a programmed delay from an input signal. A phase detector provides a phase delay signal indicative of an actual phase difference between the input signal and the delayed output signal. An accumulator provides a delay command signal as a function of a difference between a commanded delay and the actual phase difference. A programmable phase delay circuit is configured to generate a ramp signal based upon the input signal, to adjust the ramp signal with respect to a threshold level in response to the delay command signal, to generate a trigger signal based upon a comparison of the ramp signal with the threshold level, and to clock the delayed output signal in response to the trigger signal.

Abstract: In various aspects, ion sources, mass spectrometer systems, and a power supply circuit coupled to a feedback circuit are provided. A power supply is provided that includes at least the power supply circuit and is operable to transfer charge to a load. The feedback circuit is responsive to a DC component of an output voltage supplied by the power supply in a first feedback loop and an AC component of the output voltage in a second feedback loop to produce a feedback signal representative of at least one of: a value of the output voltage before a charge transfer from a capacitor of the power supply to a load; the value of the output voltage during the charge transfer from the capacitor of the power supply to the load; or the value of the output voltage after the charge transfer from the capacitor of the power supply to the load.

Abstract: A multi-phase clock generator for generating a set of multi-phase clock signals is disclosed. The multi-phase clock generator includes a signal generator, a phase adjusting circuit, and a phase interpolator. The signal generator generates a plurality of first clock signals according to a reference clock signal. The phase adjusting circuit, which is a phase rotator or a phase selecting circuit and coupled to the signal generator receives the first clock signals and adjusts the phases of the first clock signals according to a control signal to generate a plurality of second clock signals. The phase interpolator, which is coupled to the phase adjusting circuit, interpolates the second clock signals to generate the set of multi-phase clock signals.

Abstract: A phase adjustor circuit and a phase adjusting method are capable of preventing a phase shift amount from fluctuating even if a frequency of a transmission carrier wave of a sensor signal fluctuates. A chopping wave converter circuit converts a pulse string signal into a chopping wave. A chopping wave amplitude control circuit compares the amplitude value of the chopping wave with an amplitude reference value and outputs an adjustment signal corresponding to a difference between those values to the chopping wave converter circuit. The chopping wave converter circuit changes a slope of the chopping wave according to the adjustment signal to adjust the amplitude value of the chopping wave. As a result, a feedback group is structured, and the amplitude value of the chopping wave is maintained to a constant value according to the amplitude reference value.

Abstract: The present invention relates to the reduction in errors in the phase of quadrature clock signals and provides a correction circuit for signals which are required to have as close to that precise phase relationship as possible. The arrangement is based upon a circuit which aims to bring signals which should be 180 degrees apart closer to a 50% duty cycle.

Abstract: A phase shift driver for phase shifting an input clock signal at a first phase to generate an output signal at a second phase without missing subsequent input signals. Input logic circuitry of the phase shift driver may receive an input signal at a first phase. Output logic circuitry of the phase shift driver may generate an output signal at a second phase relative to the input signal. The output signal may be a phase-shifted version of the input signal. A reset control circuit may receive a feedback signal from the output logic circuitry and an intermediate signal from the input logic circuitry and generate a reset signal based on the received feedback and intermediate signals. The reset control circuit may control a pulse width of the reset signal to reset the input logic circuitry within a period of time before the input logic circuitry receives a subsequent input signal.

Abstract: An adjustment technique allowing easy adjustment of a phase shifter is disclosed. A programmable device (PLD) is connected to the phase shifter so as to correct a standard vector depending on correction data written thereto. When supplying a standard input signal to the phase shifter, the phase and amplitude of the output signal are measured. A standard vector for a sequentially selected one of a plurality of phase points is generated and outputted to the phase shifter. Correction data for a selected phase point is calculated based on the measured phase and amplitude. A VHDL source program is generated from the corrected data for all the phase points to write the correction data into the PLD.

Abstract: A semiconductor integrated circuit comprises a phase control unit for shifting the phase of an input signal by two or more different fixed phases so as to generate two or more output signals out of phase. A phase detector detects phase differences among the two or more output signals from the phase control unit, and generates one or more correction signals each having a value corresponding to a deviation of one of the detected phase differences from a desired phase difference. The phase detector feeds the one or more correction signals back to the phase control unit so as to make the detected phase differences equal to desired phase differences, respectively.

Abstract: A delay-locked loop (DLL) circuit having a master-slave structure wherein the DLL circuit includes a master delay loop and a slave stage. The master delay loop delays an external clock signal by a predetermined delay time and generates a feedback signal which is phase-synchronized with the external clock signal. The slave stage delays the external clock signal by the predetermined delay time and generates an internal clock signal. The master delay loop includes a phase comparator, a delay controller, a delay part and a compensation delay part. The slave stage includes a low-pass filter and a slave delay part. The master delay loop may have a structure in which a plurality of delay parts are connected in series. According to the DLL circuit, the high frequency phase noise of the internal clock signal can be minimized in a locked state.

Abstract: There is disclosed a 90-degree phase shifter so configured that an input signal is supplied through a variable gain amplifying circuit and a phase adjusting circuit to a low pass filter and also supplied through another variable gain amplifying circuit and another phase adjusting circuit to a high pass filter, so that the low pass filter and the high pass filter generate output signals, respectively, which have a 90-degree phase difference therebetween. An amplitude error and a phase error between the output signals are detected, so that the variable gain amplifying circuits are gain-controlled by the detected amplitude error, and the phase shift amounts of the phase adjusting circuits are controlled by the detected phase error. Thus, the amplitude error and the phase error attributable to the variation in the device characteristics and the parasite component can be removed, so that it is possible to obtain the output signals having the 90-degree phase difference with no amplitude error and no phase error.

Abstract: A novel amplitude deviation correction circuit which corrects an amplitude deviation between an I signal and a Q signal is disclosed. An average amplitude deviation between an I signal amplified by a variable gain amplifier and a Q signal amplified by another variable gain amplifier is detected by an amplitude comparison circuit, and +1 volt or −1 volt is outputted in response to a result of the detection. An integration circuit integrates the output of the amplitude comparison circuit and controls the gains of the variable gain amplifiers in response to a result of the integration.

Abstract: An integrated delay line calibration method and apparatus are provided for a direct access storage device (DASD). A delay line, such as used in a direct access storage device (DASD) is calibrated by configuring the delay line as a ring oscillator for calibration. A delay line ring frequency is compared to a reference frequency. The delay of the delay line is adjusted until the delay line ring frequency and the reference frequency are equal. Each delay block within the delay line is controlled by a delay adjust digital-to-analog converter (DAC). A control logic circuit couples N-bit words to the delay adjust digital-to-analog converter (DAC) for calibration adjustment of the delay line delay.

Abstract: A phase-locked loop circuit is constituted in such a manner that a delayed signal created by causing an input signal to loop through a delay stage a plurality of times is compared in terms of phase with the input signal, and an amount of delay in the delay stage is controlled in accordance with the comparison result of the delayed signal and the input signal. Therefore, the circuit size can be reduced with a reduced number of delay units constituting the delay stage.

Abstract: An improved clock generation circuit is provided for changing the phase of one signal relative to the phase of another signal. Both signals presented to the clock generation circuit transition at the same frequency. One or both of those signals are delayed by dissimilar amounts to skew the phase difference between the signal pairs and 90.degree.. A phase detector, or logic gate, determines a phase differential between the incoming signals. A charge pump and storage device maintain a voltage level commensurate with that difference. The stored voltage is then used to control a feedback loop coupled from the output of the detector to a current path which traverses a buffer coupled between an input signal and a phase compensated output signal. The current path receives current necessary to change both the rise and fall rates produced by the buffer. According to another embodiment, two feedback loops may be used for a corresponding pair of buffers.

Abstract: A self-calibrating programmable phase shifter includes a tapped delay line for successively delaying a periodic reference signal to produce a set of phase distributed tap signals. A multiplexer selects one of the tap signals as input to a programmable delay circuit which further delays the selected tap signal to produce an output signal that is phase shifted from the reference signal. A conversion table converts input data indicting a desired phase shift between the reference signal and the output signal into output data for controlling the multiplexer selection and the amount of delay provided by the programmable delay circuit. The phase shifter includes calibration circuitry that convert the phase shifter into an oscillator by feeding the output signal back as input to the tapped delay line and adjusting relationships between the conversion table input and output data so that the period of the output signal has a desired linear relationship to the input data value.

Abstract: The circuit arrangement for generating two signals staggered in time from a clock signal and for measuring their time stagger receives at its input a clock signal, from which it generates an undelayed signal and a signal delayed relative to the undelayed signal. The generated signals appear at a first and second output of the circuit arrangement, respectively. A delay time measuring arrangement comprises a reversible inverter connected between the input of the circuit arrangement and the first output of the circuit arrangement and a NAND gate. The NAND gate receives at one input the delayed signal and at the other input the output signal of the inverter and furnishes an output signal from which the time stagger existing between the undelayed signal and the delayed signal can be precisely determined. The reversible inverter is switchable by a switching signal between a non-inverting condition in a working phase and an inverting condition in a measuring phase.

Abstract: A fractional divider divides an input by a non-whole number M.N, where M is the integer part and N is the fractional part of the divisor. A delay line generates a group of multi-phase clocks from an input clock. A mux selects one of the multi-phase clocks as a selected clock. The selected clock increments a counter that counts to the integer part M. The selected clock also increments a rotational state machine. The rotational state machine makes the mux select a different one of the multi-phase clocks for the first N clocks so that the phase of the selected clock is rotated for N cycles. When multi-phase clocks having slightly higher delays are chosen, the selected clock's period increases, adding a fraction. When multi-phase clocks having slightly smaller delays are chosen, the selected clock's period is reduced, effectively subtracting a fraction. The delay line is part of a delay-locked loop that compares the phase of the last multi-phase clock to the input clock.

Abstract: A voltage controlled delay circuit is formed by m number of gates connected in series, phases of a clock signal and a delay signal are compared by a phase comparator, an up signal or a down signal is output, an integrated signal is generated by an integrator, a voltage signal following this is generated by a buffer and fed back as an operating power source voltage to the voltage controlled delay circuit, and further an internal power source voltage following the voltage signal is generated by a buffer and a pMOS transistor, therefore the internal power source voltage of the required lowest limit can be supplied in response to the frequency of the clock and a reduction of the voltage and conservation of the electric power of the LSI circuit can be achieved.

Abstract: A 90.degree.-phase shifter which operates in condition both of high-speed and low dissipation power, and an output signal with precise 90.degree.-phase difference is capable of taking off is provided. It causes input signals with complementary relation each other to input toward input terminals. A 1/2 frequency divider is composed of bi-differential transistors Tr5 to Tr12, and load resistances R1 to R4. The 1/2 frequency divider outputs a 90.degree.-phase difference signal to output terminals 11 to 14 based on collector current of signal input transistors Tr1 and Tr2. The collector current corresponds to the input signal. A duty ratio monitoring load 2 converts these collector currents into voltage. A low-pass filter 3 takes off a DC component corresponding to an offset from 50%-duty ratio of an input voltage from the converted voltage. A DC component amplifier amplifies the DC component thus performing feedback to the input terminals 8 and 9.

Abstract: A digital delay locked loop (DLL) includes a phase detector for outputting a comparing signal by comparing a system clock signal with a chip clock signal, a shift register for sequentially shifting data bit values in both the directions in accordance with the comparing signal, a phase delay unit for delaying and outputting the system clock signal in accordance with each bit value of the shift register, a domain selecting controller for detecting an overflow or an underflow condition of the shift register and outputting a domain selection controlling signal, and a domain selector for adjusting the phase of a driving signal from one region comprising 0.degree..about.180.degree. and to another area comprising 180.degree..about.360.degree. and carrying out a domain transition whenever an overflow or an underflow condition is generated when the phase reaches a boundary region of the two domains.

Abstract: A phase adjusting circuit includes a circuit for providing an internal clock signal in synchronization with a reference clock signal, a delay circuit for delaying the internal clock signal for a predetermined delay time and an adjusting section for adjusting a phase difference between a phase of the reference clock signal and a phase of the internal clock signal delayed for the predetermined delay time.

Abstract: A time interval division circuit that generates a delayed signal that is a precise integer fraction of the clock cycle. A digital delay loop including a digital delay line is locked to the clock cycle and controls a second digital delay line. The delay line characteristics determine the fraction of the clock cycle generated. The time interval division circuit tracks the clock cycle, rather than on-chip circuit delays as conventional delay lines.

Abstract: A circuit for synchronizing a periodic ramp signal utilized in a switching mode power converter to system clock signal. A capacitor is charged through a resistor. When a voltage across the capacitor reaches a predetermined level, the capacitor is discharged and the charging cycle is repeated, thereby generating the periodic ramp signal across the capacitor. A waveform shaping circuit shapes the ramp signal into a rectangular wave signal having a same frequency and phase as the ramp signal. A phase comparator compares a phase of the rectangular wave signal to a phase of the system clock signal for forming a phase error signal. The phase error signal controls a level of current supplied to the timing capacitor by a voltage controlled current source. When the frequency of the system clock signal is higher than the frequency of the ramp signal, the phase comparator causes the voltage controlled current source to supply additional current to the capacitor, increasing the frequency of the ramp signal.

Abstract: An IQ modulator incorporates a quadrature network that is responsive to a frequency dependent control signal and that has in-phase and quadrature signals that are of equal amplitude and in exact quadrature over a wide range of applied frequencies. The quadrature network includes RC and CR phase shifters whose C's are fixed capacitors of equal value and whose R's are made equal to each other and to the capacitive reactance of the C's by the action of the frequency dependent control signal. The R's may be FET's. The frequency dependent control signal may be generated without express knowledge of the applied frequency by a servo loop that nulls out the amplitude difference between the in-phase and quadrature outputs from the quadrature network; it may also be generated from a look-up table as an express function of frequency. The frequency dependent control signal is split into separate instances that are applied to each R, and an offset may be introduced therebetween to provide extreme precision.