Abstract: In a charge-pump booster circuit, the control clock is controlled on a small-step basis to thereby suppress the boost amplitude and the occurrence of various noises. Provided are a charge-pump booster circuit section for boosting an external power voltage in absolute value level, a boost-voltage feedback section for controlling the booster circuit section, and a clock buffer section. In the boost-voltage feedback section, an output level of the booster circuit section is detected by a voltage detecting section. This is compared with a reference level, and depending upon the comparison result, a count operation is made in an up/down counter section. Based on the count value, the control amount is shifted on a small-step basis from the D/A converter section, thereby controlling the power voltage of the clock buffer section 300 through the level shifter section.

Abstract: A single-ended to differential converter uses a cross-coupled latch that maximizes the output zero-crossing symmetry and is self compensating over PVT variations. An in-phase driving signal is provided by an always-on transmission gate coupled to the input. An out-of-phase driving signal is provided by an inverter coupled to the input. The in-phase and out-of-phase driving signals each drive an input of the cross-coupled latch. The in-phase driving signal from the always-on transmission gate starts to bring the cross-coupled latch into conduction, and when the out-of-phase driving signal arrives, the simultaneous driving of the cross-coupled latch causes a rapid and symmetric transition of both outputs of the cross-coupled latch.

Abstract: An apparatus comprising an input section, a first delay circuit and a second delay circuit. The input section may be configured to present a first intermediate signal by selecting either (i) an input clock signal or (ii) a feedback of an output signal. The first delay circuit may be configured to generate a second intermediate signal by delaying the first intermediate signal by inserting one of a plurality of fixed delays in response to a first control signal. The second delay circuit may be configured to generate the output signal by delaying the second intermediate signal by inserting a programmable delay in response to a second control signal.

Abstract: An integrated circuit device having an output driver circuit and a control circuit. The output driver circuit outputs a first signal having a signal level according to a control value. The control circuit is coupled to receive the first signal from the output driver and adjusts the control value by a first increment until a transition event is detected. After the transition event is detected, the control circuit adjusts the control value by a second increment, the second increment being smaller than the first increment.

Abstract: A controlled delay circuit has a first gate chain, and a second gate chain. The first gate chain is used to measure a time difference between a changeover point of a first control signal and a changeover point of a second control signal. The second gate chain, which receives third signals generated in the first gate chain and representing the time difference, is used to provide an appropriate delay time from an input to an output depending on the time difference. The controlled delay circuit is capable of properly controlling the timing of the control signal according to the period of the control signal.

Abstract: A duty cycle correction circuit and a delay locked loop (DLL) including the duty cycle correction circuit, are capable of controlling their operation in order to correctly analyze the cause of generation of a duty cycle error when the duty cycle error is generated in the DLL. The duty cycle correction circuit selectively outputs to a DLL core duty cycle offset information for controlling a duty cycle of an internal clock signal synchronized to an external clock signal under the control of a switching control signal. The DLL corrects the duty cycle of a reference clock signal according to the duty cycle offset information, thereby outputting a reference clock signal having a 50% duty cycle.

Abstract: A low power charge pump is disclosed. A pump driving node of a first pump stage is selectively coupled to a pump driving node of the subsequent pump stage. Subsequent to a transfer of charge from a first pump stage to a subsequent stage, the first and subsequent pump driving nodes are coupled. Residual charge on a first stage pump driving node is thereby transferred to a subsequent pump driving node. Subsequent to the transfer of charge from the first pump driving node to the second pump driving node, the nodes are uncoupled. By selectively coupling a first pump stage to a pump driving node of the subsequent pump stage, the first pump driving node may pre-charge the subsequent pump driving node, thereby reducing the energy that must be provided by clock driving circuitry to produce a positive-going transition of a driving clock.

Abstract: One embodiment is a clock gater circuit comprising an inverter block for driving an output clock signal responsive at least in part to an input clock signal that is selectively driven via a clock generator circuit to an input node of the inverter block responsive to a qualifier signal. Also included is circuitry for restoring a logic level at the input node of the inverter block to a particular value, the circuitry operating responsive to the qualifier signal.

Abstract: A dual-modulus prescaler circuit for a frequency synthesizer comprises a plurality of asynchronous dividers-by-two connected in series, a phase selector unit (11) between two dividers-by-two (10, 12) and a control unit (13) for supplying control signals (S0, S1, S2) to the selector unit as a function of a selected mode. Said selector unit receives four signals phase shifted by 90° in relation to each other from a master-slave first divider and supplies a selected one of the four phase shifted signals. The control signals (S0, S1, S2) are supplied to the selector unit for selecting one of the four phase shifted signals (F2) at the output in a particular division period. As a function of the control signals supplied by the control unit (13) in one selected of the modes, the selector unit effects phase switching in each division period between two phase shifted signals selected by each branch. The second phase shifted signal i in phase lead of 90° in relation to the first phase shifted signal.

Abstract: Amplifier circuits that generate CM currents are provided. Amplifier circuits that generator DM currents are also provided. Fully differential current feedback amplifier circuits with separate CM and DM inputs are also provided. Such amplifier circuits combine the benefits of CFA designs, such as high slew rate and bandwidth, with independent control of DM and CM signals. This description is not intended to be a complete description of, or limit the scope of, the invention. Other features, aspects, and objects of the invention can be obtained from a review of the specification, the figures and the claims.

Abstract: A digital DLL device is provided which can reduce an error with respect to a target delay amount. The device provides a delay to an input clock signal so as to equally divide a clock cycle T thereof into N parts, and includes first variable delay sections and second variable delay sections, each of which is formed of an arbitrary number of unit delay buffers connected in series with one another. A phase comparison section makes a compare between the phase of the input clock signal and the phase of an output signal which is the input signal having been delayed while passing through all the first and second variable delay sections, and outputs a result of the comparison. A delay control section calculates a total number of unit delay buffers S required based on the phase comparison result, sets a quotient Q of S divided by N to be the number of unit delay buffers for each of the first variable delay sections, and allocates a remainder R of S divided by N to the second variable delay sections, respectively.

Abstract: The present invention provides a clock signal input circuit that is able to provide inverse internal clock signals generated by the same input buffer as the address and data signals which exhibit reduced skew. When a skewed external noninverse clock signal and a corresponding external inverse clock signal are passed through respective reference voltage input buffers there is no reduction in skew between the two internal signals. In a preferred embodiment, the invention provides back to back inverters connected to both lines carrying the noninverted and inverted internal clock signals. The slower internal clock signal has an extra inverter driving it when it switches states and the faster internal clock signal has an extra inverter fighting it when it switches states. The skew of the two signals is reduced, allowing for faster operation of the integrated circuit and a reduction in misread data signals.

Abstract: A phase locked loop (PLL) is provided. In one implementation, the PLL includes a feedback loop having a frequency multiplier and an integer divider to generate a divided signal. The PLL includes a re-sampling circuit operable to re-sample one or more digital pulses of the divided signal using one or more phase signals if a multiplication factor of the frequency multiplier does not divide evenly into the integer divisor.

Abstract: Techniques of designing a digital phase lock loop are disclosed. In one embodiment, the digital phase lock loop comprises a synchronization unit producing a producing a plurality of clock signals in accordance with a seed clock signal having a frequency, each of the clock signals having a modified frequency over the frequency of the seed clock signal and a phase shift from each other; a phase-frequency detection unit receiving an input signal and a feedback signal, and sampling the input signal and the feedback signal in accordance with the clock signals to determine differences in phase and frequency between the input signal and the feedback signal; a digital control oscillator receiving the clock signals and producing an output signal in reference to the differences from phase-frequency detection unit, and subsequently, a digitally controlled clock signal is produced.

Abstract: A clock generator for generating an output clock signal synchronized with an input clock signal and having a corrected duty cycle. The clock generator includes an input buffer to buffer the input clock signal and generate a buffered clock signal and an output buffer to generate the output clock signal in response to first and second clock signals applied to first and second inputs. An adjustable delay loop coupled to the output of the input buffer and coupled to the first and second inputs of the output buffer has a single feedback delay loop and is configured to generate a first clock signal and a second clock signal. The second clock signal is out of phase from the first clock signal by 180 degrees.

Abstract: A circuit and a method for interpolative delay is provided. The circuit includes a delay locked loop with interpolation delay. The delay locked loop includes a differential inverter, an interpolation circuit, and a differential compare circuit. The differential inverter is coupled to receive a differential clock signal and coupled to provide an inverted differential clock signal. The interpolation circuit is coupled to receive both the clock signal and the inverted clock signal, and to provide an interpolated clock signal having a first delay relative to the clock signal. The differential compare circuit is coupled to receive the inverted clock signal and coupled to provide a non-interpolated clock signal having a second delay relative to the clock signal. The second delay corresponds to a full delay of the differential inverter and the first delay corresponds to a predetermined fraction of the full delay.

Abstract: There is provided a Delay Locked Loop (DLL) including a duty cycle correction circuit capable of controlling a duty error, when the duty error is generated in the DLL. The duty cycle correction circuit controls amounts of electric charges accumulated in storage units, in response to switching control signals received from the external, and outputs duty rate control signals each corresponding to a difference between the amounts of electric charges accumulated in the storage units. Therefore, the DLL including the duty cycle correction circuit can correct a duty cycle of a reference clock signal, in response to the duty rate control signals, and can output a reference clock signal with a duty cycle of 50%.

Abstract: According to some embodiments, a presence indication associated with an attachment is provided.

Abstract: The invention relates to a voltage processing unit comprising an integrated charge pump 11 for multiplying a voltage Vx applied to an input of the integrated charge pump 11 by a predetermined factor Xm. In order to enable a multiplication of an available voltage by a desired factor with a reduced required area for the integrated charge pump, it is proposed that the voltage processing unit further comprises an external voltage doubling circuit 12 for amplifying an available voltage Vdd and for applying the amplified voltage Vx to the input of the integrated charge pump 11. The invention relates equally to a corresponding method.

Abstract: A frequency-dividing circuit arrangement is disclosed that includes a divider chain having a plurality of frequency divider stages. The frequency dividers can be changed over between the division ratios 2 and 3. At least that frequency divider that is arranged on the output side of the divider chain has an additional through-switching input that makes it possible to switch through the input signal to the output of the divider stage without influencing the delay-time effects of the divider stage. The advantages of a cascaded 2/3 divider chain, such as a high cut-off frequency, a simple design and the ability to arbitrarily expand, are thus achieved without accepting a lower limit of the range of possible division values.