FR2515902A1 - DIGITAL CLOCK SYNCHRONIZATION DEVICE AND ITS APPLICATION TO CONNECTION NETWORKS - Google Patents

Abstract

THE PRESENT INVENTION CONCERNS THE SYNCHRONIZATION OF CLOCK SIGNALS WITH RESPECT TO A GIGUEE REFERENCE CLOCK. THE INVENTION ESSENTIALLY CONSISTS OF USING A DIGITAL PHASE COMPARATOR, EVALUATING THE PHASE DIFFERENCE BETWEEN THE LOCAL CLOCK AND THE REFERENCE CLOCK, AND A DEVICE PROVIDING THE AVERAGE VALUE OF THE REPRESENTATIVE VOLTAGE OF THE SAID DIFFERENCE. THE INVENTION ALSO MAKES IT POSSIBLE TO STORE THE LAST PHASE DIFFERENCE FROM THE LOSS OF A PULSE OF THE REFERENCE CLOCK. APPLICATION TO THE SYNCHRONIZATION OF CONNECTION NETWORKS.

Description

The present invention relates to the synchronization of

  clock signals with respect to a reference reference clock

  and its use as a timebase for a connection network. A connection network must be capable of receiving digital signals with jitter of up to one

  Sliding of several frames The CCITT G 811 notice

  the period between two frame jumps to 70 days, which imposes oscillator accuracy better than 10 11,

  which imposes the synchronization of the networks of connections.

  The synchronization junction is a 2048 kHz signal whose long-term relative accuracy is 1011 This junction aims to synchronize the network's local master clock

on the reference clock.

  The present invention aims to correct the phase of hor-

  local network box by synchronizing it to the pilot clock

  fe provided by the synchronization junction.

  The present invention relates more particularly to a

  digital phase control loop for adjusting

  ter a local fs frequency on a reference fe frequency

  and filter the jitter that affects fe.

  In addition, the present invention provides, in the event of a loss of synchronizing rhythm, of maintaining an adjustment of the local frequency fs corresponding to the frequency correction existing before the loss by means of memory storage means.

said previous phase error.

  The digital device of the invention essentially comprises

  essentially first means for numerically discriminating the phase difference between the frequency signals fe and f, said difference being converted into a voltage by second means, the average value of said voltage being effected over a period of the reference signal fe, said mean value controlling an output oscillator providing

the slave frequency fs.

  According to another characteristic, the first means of the invention comprise an N-state counter, each state representing a phase state of the reference frequency signal fe and an N countdown counter as well, each state representing a phase state of the signal. frequency fsi an adder circuit effecting the addition of the state n of said counter with the state p of said down counter, the state of said addition circuit varying between n + p and n + p + 1 and representing

said phase difference.

  According to another characteristic, the second means of the invention perform a digital-to-analog conversion of

said difference.

  In addition, the device of the invention comprises a device

  memory of said phase difference resulting from

  so-called first means, said stored difference being

  at the input of said second means upon the disappearance of the incident clock signal of frequency fe

  In addition, the device of the invention comprises third

  average seats to compare the current phase from said first means and the stored phase from said device

  of storage, said third means allowing the re-

  taken from the current phase only after an identity of the said phases

  his. Finally, the third means of the invention generate a VHCH phase selection signal at the input of a multiplexer, said selection signal VHCH also making it possible to block the advance of the counter of said first means in order to accelerate

  searching for the identity of said phases.

  Other advantages and features will appear in the

  reading the following description illustrated by drawings.

  Figure 1 is a schematic representation of the

phase loop according to the invention.

  FIG. 2 is a representation of the state of the counter and down counter of FIG.

  Figure 3 is the characteristic curve of discrimin-

  digital phase driver of FIG. 1 in slave mode.

  FIG. 4 is an embodiment of FIG.

phase shift.

  FIG. 5 represents a detail view of FIG. 4.

  Referring to FIG. 1, the clock signal f of hor-

  reference box is applied to the counter input i to N states while the local clock signal f is applied to the input of a down-counter 2 to N states as well.

  and down-counter 2 respectively provide a signal representative of

  of the phase state of the frequency signals fe and f s, at the input of an adder 3 to N states as well Thus the adder 3 can make the difference between the phases

of these two signals.

  The state of counter 1 and down counter 2 is illustrated on the

  Thus, for example, at a clock period corresponding to

  e is the state n In the following period, the counter 1 will be in the state n + 1 Conversely the down counter 2 will be in the state p and will go to the state p + 1 in the following period If the two clocks fe and fs are in different phase states, that is to say, shifted in time, the adder 3 will be in a state n + p when the counter 1 is in the state

  n and the down-counter 2 in the state p Suppose as on the bottom

  2 that the local clock f is delayed, then when the counter 1 goes to the state n + 1, the down counter 2 is still at

  the state p, therefore the adder 3 is in the state n + p + 1.

  As soon as the down-counter 2 advances in the next period, it

  goes to the p-1 state and then returns the adder 3 to the n + p state.

  Since the clock signals fe and fs have the same period but are

  simply shifted in phase, the states n + p + 1 and n + p of the addi-

  3 are periodically reproduced during a period of the reference clock signal. If the reference period corresponds to 2 TW and the phase shift to and then the average state at the output of the adder 3 over a reference period and 21 e and is equal to (n + p + 1) + (n + p) = n + p + 2 f 21 f 2 f The signal representing the state of the adder 3 is applied to the input of digital converter, which makes it possible to obtain a voltage VM proportional to the

  phase difference This voltage VM is used for commnan-

  der a controlled frequency oscillator 5.

  The average voltage VM, over a period of the reference signal

  rence, varies proportionally to e L since the adder 3 has a mean state equal to n + p + and the oscillator 5 has at its input a filter RC, not shown in FIG. 1 with a time constant of appropriate size, which allows to realize this average VM Thus the average value VM varies continuously proportionally to the difference and phase between the two clocks This allows an exact setting on the instant reference frequency of the clock f In practice, the filter RC can be deleted, this

  function being provided by the input circuits of the oscillator

frequency controlled transmitter.

  At the output of the oscillator 5, the frequency fs slaved in phase on the frequency fe is obtained. Thus, the phase discriminator according to the invention is

  essentially consisting of counter 1 and down counter 2, ad-

  editor 3 and digital-to-analog converter 4; it is characterized by the ratio Ki equal to the maximum variation of voltage Va continuous obtained at the output of the converter 4 on the maximum acceptable phase variation at the input of the

  discriminator This maximum phase variation is pro-

  proportional to the number of states of counter 1 and down counter 2 and of adder 3 The coefficient KI is written KI = XV max 21 tr (N-1) The measured phase error is a periodic function of

  the true phase error with an amplitude of 2 1 T (N-1).

  Figure 3 illustrates the characteristic curve of the error

  in phase, it is a continuous sawtooth curve of

  FIG. 4 shows a preferred embodiment of FIG. 1 of the invention. In case of loss of the incident frequency, it is advantageous to memorize the previous phase error in order to maintain the frequency correction existing before

the loss of rhythm.

  For this purpose there is a register 7 memorizing the signal from the adder 3 representing the phase difference between the local fs rhythm and the incident rhythm. The incident fc rhythm is received by the counter i at N states as well as by

  a device 6 for detecting a reference clock loss.

  The device 6 detects a loss of clock signal when a clock pulse is missing and provides a signal, at the input of the register 7, representative of the good reception of the input signal and allowing the reception of the signal. signal loading

  output of the adder 3 at the input of a multiplexer 8.

  In addition, the detection device 6 outputs a signal representative of the loss of the reference clock which is applied to the multiplexer 8. The valid multiplexer 8 alters the phase stored by the register 7 at the moment of the loss During the loss. of the reference clock signal, the counter 1 is blocked and the output of the adder 3 varies at the rate of the down-counter 2 which receives the signal HSYN of local clock. The multiplexer 8 then transmits the last result of the phase shift provided by the adder 3 and contained in the register 7 This signal representative of the phase shift is

  applied at the output of the multiplexer 8, that there is a loss of hor-

  reference box or not, at the input of a converter

analog digital 4.

  As soon as the reference clock fe reappears, the phase validation provided by the counter 1 is delayed

  until the moment when the signal obtained at the output of the addition-

  neur 3 is identical to the stored phase shift signal provided by the register 7 Meanwhile counter 1 remains locked, in order to describe the cycle more quickly, by applying a

  X signal provided by the device 6.

  The digital-to-analog converter 4 outputs a voltage proportional to the phase difference which controls a frequency-controlled oscillator 9 at the output. The average value of this voltage is made by a not shown filter RC at the input of the oscillator. 9, on a

  period of the reference signal fe varies directly proportion-

  The oscillator 9 is thermostated and makes it possible to generate a 1.4 V peak-to-peak signal at 16.384 kHz, for example with a stability of some 108 in the range of 00 C to 500 C. A divider (10) divides the frequency supplied by the oscillator 9 by 8 and outputs an HSYN signal. The frequency control voltage is between 3.5 V

  and + 3.5 V and causes a frequency variation of a cen-

  hertz per volts on the 16.384 kHz frequency.

  FIG. 5 shows in detail the detection device 6 of FIG. 4 in memorized mode. It consists of various elements. The incoming reference signal H R E F is

  applied, at the entrance of a monostable 65 after a double in-

  version in the embodiment described by means of the two reverse

  61 and 62 in series which restore the signal HREF to the input of 65 This monostable 65 provides on its output Q a signal PHREF and its complement on its output Q The signal PHREF is a signal "a" as soon as it misses a impulse in the signal HREF input and is unsignal "zero" after

  one second of continuous presence of input signal H R E F.

  It is representative of the phase loss of the reference signal.

  A phase comparator 66 receives as input the signal

  H R E F from 62 and the signal H S Y N obtained in

  of the divider by eight (10), at the exit of the device

  synchronizing digital The phase comparator 66 allows

  to choose the phase of the loading clock H C H which is either in phase or in phase opposition with H S Y N, this in order to avoid any hazard due to the changes of state of

the adder 3.

  This choice is made by an exclusive OR circuit 67 which receives on the one hand the result of the comparison of 66 and

  on the other hand, the signal H S Y N The signal H C H from the circuit

  bake 67 is applied to the input of an AND circuit 68 which validates the signal H C H by a loading clock V H C H signal which will be introduced later The HC HV signal from the circuit 68 is applied to the memory register 7

  In addition, the incoming signal of hor-

  reference box H R E F after inversion in H R E F by means of the inverter 61 is applied to the input of a flip-flop 64

  whose input D receives the same signal V H C H which will be explained

  cited later The Q output of this flip-flop 64 provides a signal that validates the reference clock signal H R E F

  entering the input of the AND circuit 63 The signal H R E F V

  both of the circuit 63 is applied to the input of the counter 1 The

  counter 2 receives the signal H S Y N of synchronization clock

  sation obtained at the output of the synchronization device of the invention and applies its status signal to the input of the addition circuit 3 In the same way as for the previous figures, the addition circuit 3 performs an addition

  states of the counter 1 and down counter 2 and provides its

  sultat at the input of the multiplexer 8 and the memory register 7.

  This magnitude representative of the stored phase difference, resulting from the register 7 is applied to the input of a

  comparison circuit 69 which also receives the difference-

  current phase from the addition circuit 3 Thus the comparison circuit 69 can compare the state of the new

  phase-with the last phase state The result of the comparison

  Reason is applied to the input of a NAND circuit 70 This circuit 70 also receives the signal P H R E F representative

  the presence of the reference clock signal from the cir-

  The result of the circuit 70 is applied to the input of a flip-flop 71 whose input J is grounded, the input K receives the signal PHREF representative of the loss of the reference clock. The signal HCH d charging clock from the exclusive OR circuit 67 is also applied to

the clock input of the flip-flop 71.

  On the output Q of the flip-flop 71 the signal V H C H is obtained which is thus synchronized by the signal H C H Ce

  signal V H C H, representative of the normal operating mode

  wrong (slave), or stored is applied to the input of the AND circuit 68 and the input of the flip-flop 64 This VHCH signal is also applied to the input Ao of the multiplexer 8 in which it controls the choice of the phase difference applied to the converter 4 Indeed when the VHCH signal equals 0, the multiplexer 8 needle to the input O output that is to say the stored phase from the register 7 and when the signal VHCH equals 1, the multiplexer 8

  needle to the output the input 1, ie the phase

  coming out of the addition circuit 3.

  Thus in summary: in normal operation P H R E F = O and V H C H = 1 in case of loss P H R E F = 1 then the signal V H C H passes

  to zero with synchronization by H C H to avoid dis-

  twist a pulse H C H V and the phase difference memo

  in the register 7 is switched by the multiplexer 8

to C N A 4.

  in case of recovery, when PHREF goes from -1 to 0, in order to avoid a jump between the stored state and the output state of the addition circuit 3, the output of the circuit 3 is not valid at the input of the multiplexer 8 (and a new loading in the register) after having made sure of the identity (by means of the comparator 69) of the memorized state (in the register 7) and of

  the state at the output of the addition circuit 3.

  The signal V H C H also allows multiplexing

  synchronized with the signal H C H by means of the multiplexer 8.

  The signal V H C H also blocks the counter 1 after synchronization by the signal H R E F at the circuit 63 as the comparator 69 displays a non-identity between the

  stored value and the value from the addition circuit 3.

  This accelerates according to the invention the search for the identity

  by blocking the counter 1 with the AND circuit 63 when

  the signal V H C H is equal to zero.

  In fact, while PHREF is equal to 1, the down counter 2 continues to count down After a resumption of the incident clock, the signal PHREF goes to zero and if the frequency HREF is very close to the servocontrolled frequency HSYN, the counter 1 and down counter 2 would cycle at the

  same speed and the IDENT signal from comparator 69 late

  As a result, blocking counter 1

  of the signal V H C H resynchronized by H R E F is parti-

advantageously.

  In the same way as in slave mode, the signal from the multiplexer 8 is applied to the input of a converter

analog 4.

  The digital-to-analog converter 4 provides

  A voltage is proportional to the stored phase difference which controls a frequency-controlled oscillator 9 at the output. The oscillator 9 is thermostated and makes it possible to generate a signal of 1.4 V peak-to-peak at 16.384 kHz, for example with a stability of some 10-8 in the range of

0 QC to 500 C.

  A divider (10) divides by eight the frequency provided by the oscillator 9 and outputs a signal H S Y N. The frequency control voltage is between 3.5 V

  and + 3.5 V and causes a frequency variation of a cen-

  hertz per volt on the frequency 16.384 kHz.

  Such a device is particularly interesting for synchronizing the clock signals of a connection network

  compared to a reference clock transmitted by a ring

synchronization 1

Claims (7)

  1 Digital clock synchronization device   of frequency f on a frequency clock fe inci-   dente comprising a phase-locked loop   characterized by the fact that it comprises first means for numerically discriminating the phase difference between the   frequency signals f and f, said difference being   in a voltage by second means, the average value of said voltage being effected over a period of the reference signal fe, said average value controlling an output   oscillator providing the slave frequency fs.   Digital device according to claim 1,   characterized in that said first means comprises an N-state counter, each state representing a phase state of the reference frequency signal fe and an N-state down counter as well, each state representing a phase state of the frequency signal fs, an adder circuit effecting the addition of the state N of said counter with the state p of said down counter, the state of said addition circuit varying between n + p and n + p + 1.   Digital device according to claim 1,   characterized in that said second means consist of   a digital-to-analog conversion of said difference.   Digital device according to one of the claims   1 to 3 characterized in that it comprises a device for   memorization of said phase difference resulting from said first   first means, said memorized difference being applied to the input of said second means as soon as the signal disappears. clock fe incident.   Digital device according to claim 4,   characterized in that it comprises third means for comparing the current phase derived from said first means and the stored phase from said storage device, said third means allowing the resumption of the phase   current only after an identity of said phases.   Digital device according to claim 5,   characterized in that said third means generate a phase selection signal at the input of a multiplexer, said selection signal VHCH further enabling the advance of the counter of said first means to be blocked in order to accelerate   searching for the identity of said phases.