64results about How to "Short lock time" patented technology

A delay locked loop (DLL) circuit having a structure in which a method of performing duty cycle correction (DCC) using two DLLs and an intermediate phase composer and a method of performing DCC by forming a closed loop using a negative feedback are combined with each other is provided. The DLL circuit includes a first DLL for receiving an external clock signal and generating a first clock signal and a second DLL for receiving an external clock signal and generating a second clock signal. The first clock signal and the second clock signal are synchronized with an external clock signal. The DLL circuit further includes an intermediate phase generation circuit for receiving the first and second clock signals and generating an intermediate phase clock signal and a DCC loop for receiving the intermediate phase clock signal and generating an output clock signal. The intermediate phase clock signal has an intermediate phase between the phases of the first and second clock signals. The output clock signal is generated through correction of the duty cycle of the intermediate phase clock signal using a value obtained by integrating the output clock signal.

The invention relates to a rapid locking method for a full digital phase-locked loop, which is used for locking the frequency of the full digital phase-locked loop comprising a phase detection discriminator, a time-to-digit converter, a digital filter, a digital controlled oscillator and a frequency divider in a short time. The method is characterized by comprising the following steps: finding a control word controlling the frequency of the digital controlled oscillator by a designed algorithm; dividing the frequency of a clock output by the digital controlled oscillator which is controlled bythe control word to obtain a divided-frequency clock with the frequency approximate to a reference clock frequency; and then, controlling the digital controlled oscillator to lock based on a phase difference between the reference clock and the divided-frequency clock which are distinguished by the phase detection discriminator. The full digital phase-locked loop is provided with a rapid frequencycapture loop and a phase-locked loop which alternately work, i.e. firstly, the rapid frequency capture loop finishes frequency capture, and then, the phase-locked loop finishes accurate locking.

The invention relates to a full digital phase-locked loop applying a rapid frequency capture method for locking the frequency of the full digital phase-locked loop comprising a phase detection discriminator, a time-to-digit converter, a digital filter, a digital controlled oscillator and a frequency divider in a short time. The full digital phase-locked loop is characterized by comprising the following steps: finding a control word controlling the frequency of the digital controlled oscillator by a designed algorithm; and dividing a frequency output by the digital controlled oscillator which is controlled by the control word to obtain a divided-frequency clock with the frequency approximate to a reference clock frequency. The full digital phase-locked loop is provided with a rapid frequency capture loop and a phase-locked loop which alternately work, i.e. firstly, the rapid frequency capture loop finishes frequency capture, and then, the phase-locked loop finishes accurate locking.

The invention provides a frequency generator for quick locking, which comprises a phase frequency detector, a charge pump, a filter, a voltage controlled oscillator and a first locking unit connected with the charge pump and the filter. When no phase difference is existed between reference clock signal and feedback clock signal, the first locking unit outputs a quick locking signal of decreasing charge-discharge current of the charge pump and increasing resistance of the filter. The frequency generator can shorten locking time of frequency and phase.

Locking reliable also can fixed reconciliation locks or fast door interlock switch, has opens dog hole (1) substrate (5) and lap (12), the substrate (5) in is equipped with the magnet coil (9) and the operation slide (6), operates the slide (6) on the company to have the ferrite core (8) besides the jacket to have the spring (7) to be located the magnet coil between the operation slide, operates the slide (6) in to be equipped with 'the localization/replacement' guide way (11), is equipped with the guide pin (10) its end to fix to the substrate (5), another end is located guide way (11), The substrate (5) in is equipped with the slide (3) to be located dog hole (1) upside within the side direction region, is equipped with the release lever (4) its middle to be possible the pivot shaft change of scene set to the fulcrum pin (41), the release lever (4) an end AND-OPERATION slide (6) is connected, another end and the slide (3) unite. This invention mainly is suitable for rotary drum washer door lock locking and the solution lock.

The invention discloses a digital phase-locked loop based on a Cordic algorithm, comprising: a controller for implementing a phase-locked loop algorithm for outputting a sinusoidal signal; the controller comprises: a frequency measuring module for performing segmental frequency measurement on a reference clock input signal; a phase and frequency discriminator for comparing the reference clock input signal with a feedback signal; a digital filter for equalizing an output signal of the phase and frequency discriminator; and an oscillator for receiving frequency measurement result from the frequency measuring module, generating an output signal having same frequency as the reference clock input signal, and receiving and adjusting phase of the output signal of the digital filter to be synchronous to the reference clock input signal; and a sine wave shaping module which is located at a feedback loop and used for converting the sinusoidal signal into a square signal. Compared with the priorart, the digital phase-locked loop based on the Cordic algorithm outputs a digital sinusoidal signal synchronous to a reference clock signal, and the digital sinusoidal signal is convenient for use in digital signal processing.

The invention is applicable to the field of integrated circuits, and provides a multi-loop self-biasing phase-locked loop circuit and a clock generator. The circuit comprises a multi-phase output phase frequency detector, a reverse unit, a first charge pump, a second charge pump, a third charge pump, a switch unit, a voltage-controlled oscillator array and a frequency divider, wherein when a frequency difference between a signal output by the frequency divider and input reference frequency is less than a first threshold, the first and second charge pumps work simultaneously, the output current of the first charge pump is used for controlling a voltage-controlled oscillator to work so as to achieve output with a wide frequency range; the second charge pump and the third charge pump forms a control voltage on a second energy storage unit to control the current of the switch unit, so as to achieve dynamic adjustment of a ratio between the current of the chare pump and the current of the voltage-controlled oscillator. The multi-loop self-biasing phase-locked loop circuit provided by the invention has the advantages of being wide in application range, good in transportability, wide in input and output range and free from being affect by PVT, and having extremely strong capacity of resistant to technology, supply voltage and ambient temperature.

The invention discloses a high-precision phase-locked loop comprising a frequency discriminator, a phase discriminator, a voltage-controlled oscillation module and a digital processing module. An input signal is inputted from the input ends of the phase discriminator and the frequency discriminator respectively. The output end of the frequency discriminator is connected with the digital processing module. The output end of the phase discriminator is connected with the input end of the voltage-controlled oscillation module. The input end of the voltage-controlled oscillation module is connected with the input end of the digital processing module. The output end of the digital processing module is connected with the feedback end of the phase discriminator. Frequency of an output signal is configured according to frequency of the input signal. Besides, phase difference between the input signals is adjusted via changing frequency change direction of the output signal so that the output signal is enabled to be matched with the input signal and an objective of phase locking is achieved.

The invention provides a clock pulse width modulation circuit and a clock pulse width modulation method. In the invention, an edge in one clock period of an output clock signal is generated by tracking one edge in one clock period of a to-be-modulated clock period, and another edge in one clock signal of the output clock signal is modulated directly by an initialized modulation circuit so as to obtain the output clock signal. The technical scheme provided by the invention can provide the output clock signal with high accuracy, low jitter and short locking time for a high-speed analog/digital conversion system on the premise of ensuring small chip area occupied by the modulation circuit.

A PLL circuit comprises a reference signal generating unit for generating reference signals of different phases, variable frequency dividers for dividing the frequency of the output signal of a voltage-controlled oscillator (VCO) and thereby outputting feedback signals, and a phase comparator for comparing the phase of each feedback signal with that of the corresponding reference signal and thereby outputting phase comparison signals. When the output signal is synchronized with a preset frequency signal, at least one variable frequency divider of the variable frequency dividers is operated, and the operation of the other is stopped.

The invention discloses a clock and data recovery circuit and a clock and data recovery method. The clock and data recovery circuit comprises a clock generation module, a clock selection module, a phase discriminator and a digital correlation processing module, wherein the clock generation module is used for receiving input clock signals, generating multi-channel clock signals identical in frequency and different in phase and sending the multi-channel clock signals to the clock selection module; the clock selection module is used for selecting continuous multi-channel clock signals from the multi-channel clock signals identical in frequency and different in phase to the phase discriminator and selecting one-channel clock signal serving as a data lock to the digital correlation processing module; the phase discriminator is used for receiving input data, oversampling the input data according to multi-channel oversampling clocks and sending the oversampled data to the digital correlation processing module; the digital correlation processing module is used for processing the oversampled data, recovering the data and feeding back one clock selection signal to the clock selection module; according to the feedback clock selection signal, the clock selection module selects and outputs the clock signals as same as the recovered data in phase. The clock and data recovery circuit has he advantages of simple structure, short locking time, small recovered clock jitter and the like.

The invention discloses an apparatus and method for realizing frame synchronization between time-division duplex synchronizing code division multiple access base stations. The invention takes global positioning system (GPS) as reference; each base station gets frame number consistent to other base stations' according to the time information provided by GPS; the control clocks of each base station keep frequency and phase synchronizations with the pulse timing signal of GPS by loosely-coupled phase-locking mode. Without the participation of wireless network controller, the base stations can get same phase, same frequency and same frame time. It has the advantages of short locking time and zero frequency and phase cumulative error.

An audio information detector extracts frequency information on audio data from a packet called an ASP in the HDMI standard and outputs the extracted frequency information to a frequency divider as audio information. The frequency divider determines a frequency division ratio based on the audio information, divides the frequency of a PLL clock signal output from an analog PLL circuit by the frequency division ratio and outputs the resultant signal as a comparison clock signal. The analog PLL circuit performs feedback control such that the comparison clock signal and a reference clock signal are synchronized with each other, and generates an audio clock signal obtained by performing frequency multiplication or division on the reference clock signal.

The invention discloses Sigma-Delta modulation circuit and method as well as a corresponding phase-locked loop. The Sigma-Delta modulation is realized by utilizing the feedback of quantization noise so as to flexibly select output bits when selecting quantization output. The Sigma-Delta modulation circuit comprises a first summator, a quantizer, a subtracter, a plurality of quantization noise delay circuits and a second summator, wherein the first summator receives a score input signal and a feedback signal, generates and outputs a sum signal; the quantizer receives a unit delay signal of the sum signal generated by the first summator and generates an integer output signal after the unit delay unit is quantized; the subtracter receives the unit delay signal of the sum signal generated by the first summator and the integer output signal generated by the quantizer, subtracts the integer output signal from the unit delay signal of the sum signal, then generates and outputs the quantization noise; the plurality of quantization noise delay circuits respectively output the quantization noise after being delayed; and the second summator receives outputs of the plurality of quantization noise delay circuits, generates a feedback signal after the outputs are summed and provides the feedback signal for the first summator.

Disclosed herein are a delay-locked loop circuit using a phase inversion locking algorithm and a method of controlling the same. There is provided a delay-locked loop circuit using a phase inversion locking algorithm, including a phase inversion controller configured to control whether or not to use the phase inversion locking algorithm by determining a phase error between an input clock signal and an output clock signal, an inverter configured to invert the input clock signal and output the inverted input clock signal, a multiplexer configured to receive the input clock signal and the inverted input clock signal of the inverter and output the input clock signal in response to the control signal of the phase inversion controller or the inverted input clock signal, and a delay-locked loop connected to the output terminal of the multiplexer and configured to perform phase synchronization in response to the output signal of the multiplexer.

The invention discloses a voltage type automatic gain control circuit. The voltage type automatic gain control circuit comprises an amplitude sampler used for sampling a controlled signal and a reference voltage signal respectively, voltage followers which are connected with the amplitude sampler and are used for isolating the sampled controlled signal and the reference voltage signal respectively so as to obtain a stable voltage signal, alternating current resistors which are connected with the voltage followers and are used for calculating an average value of the stable controlled signal and the reference voltage signal respectively by utilizing the resistors, and a bias current source, wherein a bias terminal of the bias current source is connected with the alternating current resistors, and an output terminal of the bias current source is taken as an output terminal of the voltage type AGC (automatic gain control) circuit and is used for outputting control current by utilizing the average value of the stable controlled signal and the average value of the reference voltage signal as bias voltage. According to the voltage type AGC (automatic gain control) circuit of the invention, output current can be stabilized in a short time, and proper locking precision is maintained.

The PLL device includes means (6) for generating a, plurality of reference signals (FR1, FR2, FR3, FR4) having mutually differing phases, a variable frequency divider (11, 12, 13, 14) for dividing, in synchronization with the phases of a plurality of the reference signals, a frequency of an output signal (FO) of a voltage-controlled oscillator (15) that produces a signal having a frequency responsive to a control voltage (CV) supplied to generate a plurality of feedback signals (FV1, FV2, FV3, FV4) having mutually differing phases, phase comparators (7, 17, 8, 18, 9, 19, 10, 20) for comparing phases between the reference signals and the feedback signals corresponding to the reference signals respectively to produce a plurality of error signals (ER1, ER2, ER3, ER4), a low-pass filter (21) for filtering the error signals output from the phase comparators to produce the control voltage, and a control means (16, 26, 27) for controlling the number of the phase comparators that output the error signals to the low-pass filter in accordance with a phase difference between at least one of a plurality of the feedback signals and the reference signal corresponding to the one of a plurality of the feedback signals.

A delay locked loop circuit with improved restart features. The circuit includes a clock input (1120, a clock output (116), a divider circuit (114), phase detector (118) and control logic (124). The circuit includes a means (126) for implementing a binary search of outputs from the control logic (124) for generating a calibration bit, which is applied to the transmission on an output line (120).

The invention relates to a circuit structure and method for realizing clock recovery on the basis of a USB device. The circuit structure comprises a built-in oscillator module for generating oscillation signals; and a digital control logic module which includes a USB clock recovery unit for sampling the oscillation signals of the built-in oscillator and performing the clock recovery and a frequency adjustment unit for adjusting the oscillation frequency of the built-in oscillator according to a comparison result between USB signals and the oscillation signals of the built-in oscillator. By using the circuit structure and method for realizing the clock recovery on the basis of the USB device through such a structure, an accurate system clock can be generated, a frequency tracking feature is exhibited, a USB data transmission frequency is compared with the frequency of the built-in oscillator through adoption of the digital control logic module, the frequency of the built-in oscillator is automatically switched among a low-speed state, a medium-speed state and a high-speed state, the system precision and the stability are guaranteed, the production cost is decreased, and the application scope is wider.

The invention provides a capacity expansion method and device for a distributed database and electronic equipment. The method relates to the field of cloud computing, a database comprises a schedulingnode and a plurality of existing first data nodes, and the method takes the scheduling node as an execution main body and comprises the following steps: when a second data node is newly added to thedatabase, notifying the first data nodes to migrate target fragmented data to be migrated to the second data node; obtaining an LSN corresponding to the second data node; when the latest LSN reaches apredetermined LSN upper limit, receiving a table lock of the fragmentation table sent by the target data node to limit the operation on the fragmentation table; wherein the target data node is a second data node corresponding to target fragmented data reaching a predetermined LSN upper limit; and when the preset condition is met, releasing the table lock to respond to the operation on the fragmentation table. According to the method, in the database expansion process, it can be well guaranteed that the database is not shut down and is continuous in service, and the high availability of the distributed database is effectively improved.

The invention relates to a timing and carrier recovery device for a wireless transmission system and a recovery method, which belong to the technical field of wireless communication. The device comprises a receiver of a wireless transmission system, a computer and a development board, the receiver of the wireless transmission system and the development board are connected with the computer, wherein the development board is a circuit board with an FPGA chip with a program written in through software. The recovery method comprises the following steps: constructing a module, generating a program, and writing the program into the development board; receiving a data signal through the receiver, and sampling under the 32-time condition to obtain a sampled value at a four-time symbol rate; interpolating the sampled value to obtain a timing error in reception of the data signal; low-pass filtering the timing error; obtaining a sampling control signal and an interpolation control signal through a clock control unit; and controlling an interpolation filter through the interpolation control signal, recovering the frequency deviation under the control of the sampling clock control signal, and repeating the recovery steps to realize the continuous recovery of the bit timing error and the frequency deviation.