CN203608179U - Full-digital successive approximation register type rapid-locking delay lock ring - Google Patents

Abstract

The utility model discloses a full-digital successive approximation register type rapid-locking delay lock ring. A circuit structure is characterized in that a numerical control delay chain capable of being reset is used for reducing the frequency dividing ratio between an input clock and a controller working clock to 1, the 2-b successive approximation register algorithm is used for reducing the searching cycle index by 50%, and therefore the purpose of rapid locking is achieved. Circuits comprise a front end circuit, a numerical control delay chain, a phase synthesis circuit, a 2-b successive approximation register controller, a phase judging circuit and a reset pulse generating circuit. As is shown in the experiment results, according to the circuits, the locking frequency range is from 100MHz to 400MHz, the locking time is 5 clock periods, clock signals of 50% duty ratio are output after locking, and harmonic wave locking is prevented.

Description

A kind of digital successive approximation register formula quick lock in delay-locked loop

Technical field

The utility model relates to integrated circuit (IC) design field, particularly, relates to a kind of digital integrated circuit clock synchronization module.

Background technology

The demand driving of the mankind to low-power consumption, high-performance electronic product constantly advancing of semiconductor process technology, the designing technique of integrated circuit is updated.In design, start to be widely used the reusable modules such as silicon intellectual property (Intellectual Property, IP) core, and complex art and IP kernel are combined, shorten as much as possible the design cycle of System on Chip/SoC (System on Chip, SoC).Meanwhile, SoC chip is also towards the future development of multinuclear multi-clock zone, and the complexity of chip internal clock architecture promotes.Nowadays main flow processor cores, sheet internal clock frequency has reached GHz, and has multiple different clock zones simultaneously, and the relation between clock zone is increasingly sophisticated.Therefore the accurate distribution that, how to realize fast the inner high-frequency clock signal of SoC within the limited design cycle has become one of bottleneck of current integrated circuit development.

Due to the requirement of high-performance SoC chip to clock network quality, rear end clock tree synthesis technical development has gone out multiple clock tree structure, this locality-overall multi-level clock tree structure combining as grid Clock Tree structure (mash tree), fish-bone Clock Tree structure (H-tree) and various technology.Adopt these clock networking distribution techniques to carry out clock tree synthesis, have compared with minor clock deviation and compared with the clock network of strong anti-interference ability although can generate, but this class technology often comprises too much Redundancy Design, in implementation procedure, need to take extremely many interconnection resources, not only can be for placement-and-routing leaves congested hidden danger, the huge power consumption simultaneously producing on Clock Tree also allows designer be difficult to accept.In addition the process relative complex of its physics realization, in today of SoC design cycle shortened, does not often have the too many time to leave rear end engineer for to complete the clock network of this complexity.

Therefore this locality-global clock network stratification area distribution clock tree synthesis the strategy that, adopts balanced tree clock network to combine with clock delay lock-in circuit is widely used in SoC chip.

For the research of delay locked circuit, substantially different according to the structure of circuit and compensation of delay principle, launch along the delay locked circuit of open loop and the delay locked circuit both direction of closed loop, for the design level of this circuit, the U.S. and Korea S maintain the leading position.Delay-locked loop (Delay Locked Loop, and the delay locked circuit of synchronous mirror (Synchronous Mirror Delay Circuit DLL), SMDC) be exactly the Typical Representative of these two kinds of lock-in circuits, both have feature separately for different application.

, there is the problem of long, harmonic wave locking locking time and deadlock in tradition digital successive approximation register (Successive Approximation Register, SAR) formula delay-locked loop, has greatly limited its application in real system.

Summary of the invention

The purpose of this utility model is, the problems referred to above that locking exists for the digital successive approximation register formula of tradition delay-locked loop, its circuit structure and the course of work have been carried out in depth analyzing and studying, design a kind of digital successive approximation register formula quick lock in delay-locked loop, by adopting the numerical control time delay chain that can reset that the frequency dividing ratio between input clock and controller work clock is reduced to 1, adopt 2-b successive approximation register algorithm will search for cycle-index simultaneously and reduce by 50%, increase substantially lock speed, thoroughly avoid the generation of harmonic wave locking and deadlock situation.

For achieving the above object, the technical solution of the utility model is as follows:

The module of the digital successive approximation register formula of the utility model quick lock in delay-locked loop comprises: 1) front end circuit (Prepositive Delay Cell, PDC) PC0, PC1, PC2, PC3; 2) 4 groups of numerical control time delay chain HCDL, RCDL_org, RCDL_ad1, RCDL_ad2; 3) phase place combiner circuit; 4) 2-b successive approximation register controller; 5) phase place decision circuitry; 6) reset pulse produces circuit (Reset Generator, RG).Six module composition entirety delay-locked loop frameworks.

Described module 1) in, front end circuit, adopts Clock Tree structure, for guarantee that initial clock signal enters each delay unit of time delay chain simultaneously.Described module 2) in, one group of general NC time delay chain and 3 groups of reducible numerical control time delay chains comprised.Reducible numerical control time delay chain (Resettable Digital-Controlled Delay Line, RCDL) is a kind of time delay chain based on high fan-out structure.Described module 3) in, phase place combiner circuit, has adopted 50% phase generator of half time delay mode to realize phase place complex functionality.Described module 4) in, 2-b successive approximation register controller, is quick binary search (Improved Fast SAR, the IFSAR) controller that has adopted the quick successive approximation algorithm of 2bit.Described module 5) in, phase place decision circuitry, has comprised phase place judgement and phase failure and has restarted circuit.Phase place decision circuitry is for judging the phase relation between initial clock and feedback clock.In the time of phase failure, phase failure is restarted circuit provides the Restart Signal of delay-locked loop.Described module 6) in, reset pulse produces circuit, on the one hand, can each cycle completes time delay chain is carried out to zero clearing, guarantees during certain delay unit gating simultaneously, and its upper level delay unit output clock is 0.On the other hand, can guarantee that reset signal enters each delay unit of time delay chain simultaneously.

With respect to prior art, the beneficial effects of the utility model are: employing can reset delay unit (Resettable Delay Unit, RDU) composition time delay chain, eliminate the impact of frequency dividing ratio, avoid the generation of harmonic wave locking, adopt the 2bit time delay chain structure after improving simultaneously, in reducing search cycle-index, effectively reduced hardware designs expense.When designing finally by frequency dividing ratio and cycle-index, reduce, realize the function of quick lock in, simulation result shows that design can complete and lock and export the clock signal that approaches 50% duty ratio 5 cycles, and the lockable frequency range of design is 100MHz-400MHz.

Below by drawings and Examples, the technical solution of the utility model is described in further detail.

Accompanying drawing explanation

Accompanying drawing is used to provide further understanding of the present utility model, and forms a part for specification, is used from explanation the utility model with example one of the present utility model, does not form restriction of the present utility model.In the accompanying drawings:

Fig. 1 is digital successive approximation register formula quick lock in delay-locked loop system block diagram.

Fig. 2 is front end circuit structural representation.

Fig. 3 is reset signal generating circuit structural representation.

Fig. 4 is can reset delay unit R DU circuit structure diagram.

Fig. 5 be can reset delay chain RCDL general structure schematic diagram.

Fig. 6 is the logical relation circuit diagram between UC0 and UC1.

Fig. 7 is phase place combiner circuit structural representation.

Fig. 8 is the structure chart of phase place decision circuitry.

Fig. 9 is the oscillogram of phase place decision circuitry.

Figure 10 is the structure chart of losing lock decision circuitry.

Figure 11 is IFSAR controller architecture schematic diagram.

Figure 12 is 2bitIFSAR algorithm flow chart.

Figure 13 is IFSAR controller output control word change procedure figure.

Figure 14 is IFSAR control unit structure chart.

Embodiment

Fig. 1 is digital successive approximation register formula quick lock in delay-locked loop system block diagram.The process of system works can be divided into the search of the quick successive approximation register of 2bit and synthetic two steps of phase place, and wherein 2bit search has been used for phase place locking, and phase place is synthesized and is used for guaranteeing to lock rear output 50% duty cycle clock signal.Its course of work is as follows: clock signal is passed successively one and half time delay chains (Half Digital-Controlled Delay Line in system, HCDL) and 3 groups can reset delay chain, wherein RCDL_org, RCDL_ad1, RCDL_ad2 provides respectively a road output signal, as the feedback clock of phase place decision circuitry; Clock signal produces circuit by reset pulse simultaneously, and RCDL is carried out to reset operation by the cycle, removes residual signal of upper cycle in RCDL.Because system frequency dividing ratio is 1, sar controller is worked under system clock frequency.Main sar controller, according to phase place decision circuitry Output rusults control RCDL amount of delay, from the sar controller step that bit comparison is carried out according to phase, carries out time delay length adjustment to RCDL_adx, and this adjustment and phase place comparative result are irrelevant.When phase place locking, main sar controller adjustment output control word, by the clock signal of phase place combiner circuit output duty cycle 50%.

Fig. 2,3 are respectively the structural representation of front end circuit and reset signal generating circuit.System clock and reset signal needed respectively by front end circuit and reset circuit before entering time delay chain.Front end circuit shown in Fig. 2 adopts Clock Tree structure, initial clock signal can be distributed to each delay unit, the huge load of having avoided direct high fan-out to bring, guarantee that clock signal enters delay unit at synchronization simultaneously, avoided the existing system clock deviation of high fan-out time delay chain structure hidden danger.Fig. 3 is reset signal generating circuit, its circuit is by a clock buffer, two not gates, one two input NOR gate and one two input and door composition, by introducing the time delay of a clock buffer and a not gate, produce the reseting pulse signal that is narrower than clock-pulse width.

Fig. 4,5,6 be respectively can reset delay unit R DU circuit diagram and comprise preposition, the circuit such as resets can reset delay chain RCDL general structure schematic diagram and announcement UC0 and UC1 between the circuit diagram of logical relation.As shown in Figure 4, circuit is made up of with door two two input NOR gate and one two input, comprises two input end of clock mouths, two control ports and an output terminal of clock mouth.Wherein, clock port CLK0 is used for connecting input original clock signal, and another clock port CLK1 connects with the output of previous stage delay unit, and whether control port UC0 is by being strobed with gate control original clock, control port UC1 provide reset signal, is used for removing residual data in time delay chain.Fig. 5 is the structural representation of reset delay chain RCDL circuit, its circuit by can reset delay unit by being composed in series.System is made up of 3 groups of RCDL.Every group of RCDL inputs clock by front end circuit, and 3 groups of RCDL form together in the mode of series connection, and system clock passes through successively in order, wherein, RCDL_org is by main sar controller control, RCDL_ad1, RCDL_ad2 is by from sar controller control, and has on all four front end circuit.In RCDL_ad1 and RCDL_ad2 time delay length, be respectively 1/4 of RCDL_org.When RCDL_org is responsible for clock output system, also clock is fed back to phase place decision circuitry.Except RCDL_org, RCDL_ad1 and RCDL_ad2 also export respectively a road clock, compare for phase place decision circuitry.Reset signal is after Clock Tree fan-out, need to or carry out logic OR with next stage control signal UC0 by one, then export to delay unit.In the time that next stage delay unit control word is effective, time delay list output at the corresponding levels is forced to set to 0, and output clock is 0, outputs to the reset signal input UC1 of the each delay unit of time delay chain.Fig. 6 has provided the logical relation between UC0 and UC1.

For described in Fig. 4 can reset delay unit R DU design, clock signal, with needing to follow specific Timing Constraints between reset signal, guarantees that clock signal is not cleared signal and affects.If the cycle of input clock is T _clk, front end circuit time delay is D _pre, the reset pulse that clock signal produces after by reset circuit is poor with initial clock delay is D _reset, reseting pulse width is D _pulse.First need to guarantee that next cycle reset signal can not interfere with this cycle clock, circuit need to meet following constraint:

D _pre+T _clk/2＜T _clk+D _reset+D _pu

Constraint 1

Meanwhile, need to guarantee that this cycle reset signal can not interfere with the clock signal in this cycle, prevent that clock from crossing late arrival or reset signal arrives ahead of time, circuit need to meet following constraint:

D _pre＞D _reset+D _pulse

Constraint 2

In addition, also need to guarantee that clock is in time delay chain in communication process, the signal that is not reset disturbs, and prevents that clock signal from, in the process of signal zero clearing that is reset, producing extra clock bur, establish clock signal in time delay chain with D _unitfor unit is to next stage transmission, the width of reset signal need to meet following constraint:

D _pulse＞D _unit

Constraint 3

Comprehensive above three constraints, can show that the relation between front end circuit time delay, reset circuit time delay, reseting pulse width and unit amount of delay must meet following constraint:

D _pre+T _clk/2+D _pulse＞D _pre＞D _reset+D _pulse＞D _reset+D _unit

Constraint 4

If front end circuit PDC1 time delay is Dpre_org, PDC2 and PDC3 time delay are Dpre_add, for RCDL_org, still need to meet temporal constraint 1; And for RCDL_ad1 and RCDL_ad2, need to prevent the generation of such a case: when clock signal is in the time entering next stage from one-level time delay chain, because the time delay of front end circuit is excessive, cause clock signal by excessive deferral, its retardation exceedes reseting pulse width, causes producing unnecessary clock bur.Therefore the width of reset pulse is meeting on the basis of constraint 4, also must meet following constraint:

D _pulse＞D _{pre_add}+D _unit

Constraint 5

Fig. 7 is phase place combiner circuit structural representation of the present utility model.Design adopts the mode of half time delay to realize phase place complex functionality, by producing the delay inequality of half period between the R end at SR latch and S end, makes latch export 50% cycle clock signal.Circuit is by half time delay chain HCDL, can reset delay chain RCDL, two on all four pulse-generating circuit PG and one can enable SR latch composition, and the delay unit that wherein forms HCDL is in full accord with the delay unit structure in RCDL, the half that delay unit progression is RCDL.There are two kinds of operating states in circuit.When system is during in 2bit binary search state, HCDL output intrinsic amount of delay, Lock invalidating signal, SR latch, in closed condition, is only exported S end signal.2bit binary search finishes rear startup SR latch, now S end signal is directly provided by HCDL, lag behind the former clock half period, R end clock signal has been passed through HCDL and two groups of time delay chains of RCDL, hysteresis original clock one-period, make half period delay inequality by this structure, it is synthetic that phase place combiner circuit carries out 50% phase place.

Fig. 8 and 9 has provided structure and the oscillogram of phase place decision circuitry of the present utility model.Because output signal duty ratio under the effect of reset signal that can reset delay chain in phase search process may become minimum, and conventional phase decision circuitry mode cannot be processed the burst pulse situation that reset operation causes, therefore need circuit to adjust accordingly.Fig. 8 has provided the structure of phase place decision circuitry in design herein.Electricity routing state reads register DFFA, state judges register DFFB and pulse-generating circuit composition.Wherein DFFA is used to read the state of feedback clock, and DFFB is used for carrying out phase place judgement.CLK _fBwhen rising edge arrives, DFFA reads low level and will keep this state, thus expansion CLK _fBpulse duration, it can correctly be received by DFFB.Continue to keep low level for fear of DFFA, need to carry out periodicity to DFFA and reset, reset operation need to carry out after each cycle completes phase determination, therefore at reset terminal delay compensating unit DC1.Because register clk exists transmission delay D to Q end _clk-q, in fact the input of DFFB falls behind primary signal CLK _fBthe amount of delay of corresponding size, in order to guarantee the correctness of phase place judgement, also need to insert compensating unit DC2 at the clock end of DFFB, and its amount of delay is identical with trigger transmission delay.2bit time delay chain structure for the design need to be carried out respectively phase bit comparison to the output clock of RCDL_org, RCDL_ad1 and RCDL_ad2, therefore needs three groups of identical comparison circuits.Extra time delay output clock being caused in order to compensate front end circuit, needs respectively to CLK _out2and CLK _out3carry out extra compensation of delay, compensation rate is identical with front end circuit time delay.Fig. 9 has provided the process oscillogram of phase place judgement.

As from the foregoing, establishing reset pulse generation circuit delay is D _p, input clock cycle is T _clk, the clock signal time delay of DFFB is D _{pc_clk}, its retention time is D _{pc_hold}, correct reseting procedure must carry out after state judges register completion status, and the state that while reset signal can not affect next cycle DFFB reads in, therefore D _pmust meet:

D _{pc_clk}+T _clk＞D _{pc_clk}+D _{pc_hold}

Constraint 6

Because frequency dividing ratio is 1, phase place comparative result must input to sar controller within the same cycle, carries out control word adjustment by it, supposes that the time delay that clock enters sar controller is D _{sar_clk}, phase place comparative result exports SAR to and controls that to need the combinational logic time delay of process be D _logic, the sequential between them must meet:

D _{sar_clk}＞D _{pc_clk}+D _logic

Constraint 7

As mentioned above, phase place decision circuitry is for judging the phase relation between initial clock and feedback clock.In the time of phase failure, phase failure is restarted circuit provides the Restart Signal of delay-locked loop.Figure 10 is the structure chart of losing lock decision circuitry.In order to prevent the generation of losing lock situation, need a decision circuitry constantly to check the current state of circuit, once there is phase failure, send Restart Signal, sar controller is resetted, restart new round binary search.This losing lock decision circuitry adopts the mode of locking window to carry out phase place locking judgement.By at reference clock CLK _rEFclock path on insert a timelag matching unit and produce phase place locking window, in feedback clock falls into this locking window time, judge that phase place locks.Result of determination exists and lags behind, locking, leading three kinds of states.Only have register B in the time that register A samples high level to sample low level, circuit just judges locking, and under other states, circuit is all judged losing lock.Effective when Lock signal, system enters after lock-out state, and losing lock decision circuitry starts, if system remains on lock-out state, exporting Restart signal is high level, if system losing lock, output signal is low level, and system will enter restarts.

If Figure 11 is IFSAR controller architecture schematic diagram.IFSAR controller general frame comprises master controller, restarts circuit from controller and losing lock, and wherein master controller is controlled HCDL and RCDL_org, from controller, RCDL_ad1 and RCDL_ad2 is controlled.Following table has provided the semiotic function of main port.

IFSAR director port is described

Port	Direction	Function
			CLKin	Input	Input clock
IN_START	Input	Controller enabling signal
			IN_RESTART	Input	Controller Restart Signal
IN_STATE	Input	Phase place judged result
			Code	Output	Main sar controller control word
Code_ad	Output	From sar controller control word
			Lock	Output	Controller lock signal

The flow process of 2bitIFSAR algorithm as shown in figure 12.Suppose that RCDL_org is by the control word control of N position, N is even number, can produce 2N control code after decoding, and corresponding RCDL_org is 2N level RDU composition.The half that the time delay length of HCDL is RCDL_org, be subject to the control word control of N-1 position, therefore the control word Code of whole main sar controller is N+N-1 position, wherein Code[N-1:0] be Code_org control RCDL_org, Code[2N-2:N] be that Code_HCDL controls HCDL.The amount of delay of RCDL_ad1 and RCDL_ad2 is identical, is respectively 1/4 of RCDL_org, and is subject to identical control word control, is therefore N-2 position from the control word Code_ad of sar controller.Controller starts receives that enabling signal carries out initialization, if variable i equals the figure place N of Code_org, Code_HCDL all sets to 0 and remains unchanged in whole IFSAR search procedure, and the highest two of Code_org is set to 0 all the other positions and is set to 1, and all position of Code_ad is set to 1.Corresponding HCDL provides intrinsic time delay, and RCDL_org provides 1/4 of full amount of delay, and RCDL_adx provides full amount of delay.The same CLK of reference clock _out1, CLK _out2and CLK _out3carry out respectively phase bit comparison, may produce following four kinds of situations: 1, CLK _inbe ahead of all feedback clocks; 2, CLK _inhysteresis CLK _out1simultaneously leading CLK _out2; 3, CLK _inhysteresis CLK _out2leading CLK _out3; 4, CLK _inall feedback clocks lag behind.According to the result of phase bit comparison, Code_org N position and N-1 position control word determined, remaining control word moves to right two, and Code_ad moves to right two simultaneously, mends 0 for the highest two, and in the time that next cycle arrives, time delay chain is cleared, and system enters next round search, i=i-2.Second takes turns in search, may produce equally 4 kinds of phase place comparable situation, according to comparative result, determines Code_org N-2, N-3 position control word, and the remaining control word of Code_org and Code_ad are still moved to right to two.So circulation, until i=1, now Code_org except minimum two be 0, other all figure places are all determined, and Code_ad all sets to 0.Now, CLK _out1, CLK _out2and CLK _out3between only differ 1 delay unit amount of delay, can determine final locking time delay according to the result of phase bit comparison.Because every step search procedure can be determined 2 control words, and each circulation needs one-period to complete, and therefore, for the Code_org of N position, needs N/2 cycle to complete phase place locking.

If Figure 13 is IFSAR controller output control word change procedure in the utility model.Wherein RCDL_org can form reset delay unit by 64 grades, and in corresponding HCDL, RDU is 32 grades, and RCDL_ad1 and RCDL_ad2 comprise respectively 16 grades of RDU.Therefore N=6, in IFSAR controller, main sar controller figure place is 2N-1=11 position, is N-2=4 position from sar controller.Because frequency dividing ratio is 1, therefore locking time T _lock=(N+2) × DR=5.

If Figure 14 is IFSAR control unit structure chart.IFSAR control unit is made up of asynchronous resetting trigger (or asynchronous set trigger) and three bit data selectors.The input of data selector is respectively state feedback signal Comp, self output signal Keep and shift signal Shift, therefore there are three kinds of operating states in IFSAR unit: maintenance, state read and be shifted, and these three kinds of states are by the control signal Flag[2:0 of data selector] select.When IFSAR cell operation is during at state read mode, its difference by state feedback signal Comp is divided into odd location and even location.Suppose State1, State2 and State3 represent respectively 3 tunnel output signals of phase-comparison circuit, wherein odd bits SAR unit Input Control Word odd_Comp controls by State2, even bit SAR unit Input Control Word even_Comp is subject to State1, State2 and State3 control simultaneously, and both expression formulas are provided by formula 1, formula 2.

$\mathrm{odd}\_\mathrm{Comp}=\stackrel{\&OverBar;}{\mathrm{<figure-callout\; id="2"\; label="State"\; filenames="HDA0000419671010000023.png,HDA0000419671010000051.png"\; state="\{\{state\}\}">State</figure-callout>}2}$

Formula 1

$\mathrm{even}\_\mathrm{Comp}=\stackrel{\&OverBar;}{\mathrm{<figure-callout\; id="2"\; label="State"\; filenames="HDA0000419671010000023.png,HDA0000419671010000051.png"\; state="\{\{state\}\}">State</figure-callout>}2}\&CenterDot;\stackrel{\&OverBar;}{\mathrm{<figure-callout\; id="3"\; label="State"\; filenames="HDA0000419671010000052.png"\; state="\{\{state\}\}">State</figure-callout>}3}+\mathrm{<figure-callout\; id="2"\; label="State"\; filenames="HDA0000419671010000023.png,HDA0000419671010000051.png"\; state="\{\{state\}\}">State</figure-callout>}2\&CenterDot;\stackrel{\&OverBar;}{\mathrm{<figure-callout\; id="1"\; label="State"\; filenames="HDA0000419671010000022.png,HDA0000419671010000023.png"\; state="\{\{state\}\}">State</figure-callout>}1}$

Formula 2

For in IFSAR controller from controller, its output state and phase place comparative result are irrelevant, only need to carry out shifting function by step, every wheel searched for rear control word two steps that move to right.Corresponding RCDL_ad1 and RCDL_ad2 output have the clock signal of equal delay inequality, and reduce gradually amount of delay, dwindle delay locked scope.

Claims (1)

1. a digital successive approximation register formula quick lock in delay-locked loop, it is characterized in that, it produces these 6 module compositions of circuit by front end circuit, numerical control time delay chain, phase place combiner circuit, 2-b successive approximation register controller, phase place decision circuitry, reset pulse, wherein, front end circuit adopts Clock Tree structure, for guarantee that initial clock signal enters each delay unit of time delay chain simultaneously; Numerical control time delay chain is a kind of time delay chain based on high fan-out structure, comprise one group of general NC time delay chain and 3 groups of reducible numerical control time delay chains, wherein reducible numerical control time delay chain is by the 2-bit time delay chain can reset delay unit forming, it reduces most 1 frequency dividing ratio between input clock and controller work clock, thoroughly eliminates conventional successive and approach the harmonic wave lockout issue of register delay-locked loop when improving lock speed; Phase place combiner circuit adopts 50% phase generator of half time delay mode to realize phase place complex functionality; 2-b successive approximation register controller adopts 2-b successive approximation register searching algorithm to reduce half cycle-index, thereby reaches the object of quick lock in; Phase place decision circuitry, comprise phase place judgement and phase failure and restarted circuit, phase place decision circuitry is for judging the phase relation between input clock and feedback clock, in the time of phase failure, phase failure is restarted circuit provides the Restart Signal of delay-locked loop to approach the Deadlock of register delay-locked loop to eliminate conventional successive; Reset pulse produces circuit can each cycle carry out zero clearing to time delay chain, guarantees during certain delay unit gating simultaneously, and its upper level delay unit clock signal is 0.

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