117 results about "Spread spectrum clock generator" patented technology

A spread spectrum clock generator (SSCG) control and inspection circuit provides a system and method for inspecting and controlling an external SSCG, and for verifying the modulation profile waveform of an external SSCG. An electronic circuit is included that can check for the presence of an optimal SSCG modulation profile in product subsystems, and in attached modular systems, including electronic plug-in features such as internal network adapters and cartridges. In one mode of the invention, an electronic circuit ensures continued radiated emissions compliance for field replaceable units or consumable parts within a product, such as a printer, a scanner, or a combination (or all-in-one) printer / scanner. In another mode of the invention, an electronic circuit may also act as a secondary security device for consumable products, such as toner cartridges or ink jet cartridges. In yet another mode of the invention, an electronic circuit may also adjust the attached SSCG clock.

A spread-spectrum phase-locked loop clock generator includes a PLL circuit, a modulation generator, a bit stream processor and a multiplexer. The modulation generator outputs a bitstream in response to an input signal and a control signal. The bitstream processor generates bitstream signals. The multiplexer outputs one of the bitstream signals in response to a frequency deviation control signal. The PLL circuit is controlled by the output of the multiplexer.

A spread spectrum clock generator is disclosed. The spread spectrum clock generator (SSCG) bases on the structure of the phase-lock loop. The SSCG uses the voltage control oscillator with multi-phase output function for outputting clock signals of different phases. The clock signals of different phases are selectively fed back to the phase frequency detector. In this way, the frequency of the output signal is changed, which achieves spreading spectrum.

A spread spectrum clock generator includes: a phase frequency detector, for generating a phase difference signal according to a frequency divided signal and a reference signal with a reference frequency; a charge pump, for receiving the phase difference signal and generating an output current according to the phase difference signal; a loop filter, for receiving the output current and converting the output current to a voltage-controlled signal; a voltage-controlled oscillator, for receiving the voltage-controlled signal and generating a plurality of voltage-controlled output signals, wherein the plurality of voltage-controlled signals have a specific phase difference and a same voltage-controlled frequency; a frequency dividing unit, for receiving the plurality of voltage-controlled output signal and generating the frequency divided signal; and a delta-sigma modulator, for controlling the frequency dividing unit to have an equivalent divided value of (N+b)S+(N−a)(P−S) through receiving the frequency divided signal and a control word; wherein N, P, and S are integers, and a, b are fractional numbers, and S can be adjusted by the delta-sigma modulator.

A clock signal generator varies a frequency of a digital clock over a selected range of frequencies. The generator employs a divider for lowering a frequency of a clock signal. A counter increments synchronously with the signal, and causes a selected sequence of outputs to be generated by a pattern generator. The pattern generator output forms an input to a digitally controllable delay line which receives the lower frequency clock signal. The pattern generator causes the digital delay line to vary a frequency of the lowered frequency clock signal between selected boundaries. The varying frequency clock signal is then raised up again such that a final clock has a varying frequency, and will exhibit less EMI spiking during switching of an associated, synchronous digital data device. The solid state nature of the generator allows for simple fabrication, inexpensive manufacture and ready integration into digital circuitry, such as multifunction integrated circuits.

A semiconductor device, a spread spectrum clock generator and method thereof are provided. The example semiconductor device may include a frequency dividing unit receiving an output signal, generating a first feedback signal and a second feedback signal by dividing a frequency of the received output signal, and a phase offset unit outputting the output signal having a predetermined or desired phase difference with a reference signal in response to the second feedback signal, wherein the second feedback signal having a higher frequency than the first feedback signal. The example spread spectrum clock generator may include a plurality of frequency dividers which are connected in series and a selector selecting and outputting one of a plurality of output signals, each of the plurality of output signals having a different phase difference with respect to a reference signal, in response to at least one output from one or more of the plurality of frequency dividers. The example method may include receiving a reference signal with a first frequency, generating a feedback signal having a second frequency, the second frequency higher than the first frequency and outputting at least one of a sequentially selected set of output signals in response to the generated feedback signal.

This invention provides a clock generator which is capable of improving modulation accuracy without accompanying an increase in consumption current by steady current when spectrum spread of a clock signal is executed. The phase balanced voltage Vf to be inputted to the voltage control oscillator (VCO) 9 is modulated within a dead band region in which no difference signals Pr, Pr are outputted from the charge pump circuit 7 when a difference in oscillation frequency between an output clock signal fo and a reference clock signal fr is detected. Consequently, the output clock signal fo is changed within the range of a lock frequency in a PLL circuit, so as to execute the spectrum spread of the output clock signal fo while maintaining the lock state of the oscillation frequency in the PLL circuit.