DE1548100B2 - Method and circuit arrangement for measuring the rate of clockworks with a pulse shaper that generates electrical pulses from the clock noises picked up by a microphone - Google Patents

Description

The invention relates to a method and a circuit arrangement for measuring the gear of clockworks with an impulse shaper that derives from the clock noises picked up by a microphone forms electrical impulses.

In such known methods, that number is used as a measured variable for the rate of the clockwork Periods of a normal frequency between a clock strike that triggers the measurement and a later, the end of the measurement clock strike is counted.

The microphones used to carry out these known methods now also take those for measurement If clock striking noises also use interference noises from the environment or the clock itself, which, transformed into impulses capable of interfering with the measurement.

A method is already known in which such disturbances in the measurement are at least thereby can be partially avoided that the input of the beat counter is only open during limited times is.

Since in the known method, the blocking and opening times of the strike counter input by the Impulses can also be determined easily, in addition to the impulses resulting from clock strikes Pulses trigger the measurement that originate from background noise.

This disadvantage is now eliminated in the method of the invention in that the pulse intervals by a counter can be continuously checked, and the impact counter only within a specified period Time interval in which the expected pulse falls, is opened.

The opening times are expediently set at twice the amount of the period after experience is the greatest deviation of a watch from the mean value at 0 gear, the mean value the opening time is set to the point in time at which there is a measuring pulse in the O gear.

One for carrying out the method of the invention Circuitry used to advantage is characterized in that the counter detects the oscillations of a calibration oscillator, which is possibly identical to the one used for the interval measurement, counts and with an adjustable number of oscillations defines the period within which the receipt of the Pulse interval counter is open.

In this case, a logic circuit between a goal and the strike counter is expediently used automatically the opening times of the beat counter and the number of beats that determine the measuring interval Adjust the number of vibrations of the test object.

The drawing shows, for example, schematically a known circuit arrangement and two embodiments of a circuit arrangement according to the invention. This drawing shows in detail

F i g. 1 a known circuit arrangement for checking the accuracy of a watch,

F i g. 2 shows a circuit arrangement of the invention,

F i g. 3 shows a section from another circuit arrangement of the invention,

F i g. 4 another section from the circuit arrangement according to FIG. 3 and in

F i g. 5 that for the embodiment according to FIG. 3 and 4 associated pulse scheme.

The in Fig. 1 shown conventional circuit arrangement consists of a microphone M, a pulse shaper 2, the beat counter 3, a calibrated oscillator of constant frequency 5, the electronic gate circuit 6 and a counter 10 for the pulses of the calibrated oscillator 5 passed by the gate circuit 6 Fig. 2 supplemented according to the invention by an electronic locking counter 7 which is controlled by a quartz oscillator 8 (which can be identical to the calibration oscillator 5). As explained below,

ίο this circuit arrangement is used for suppression the parasitic impulses caused by background noise.

At the beginning of the measurement, switch C _{1 is set} to / so that the "and" circuit E _{0 is} open. The first pulse / Iz ₁ , which comes from the pulse shaper and comes from the microphone, can then reach flip-flop B ₀ and toggle it to state "1", in which the voltage at the output of B ₀ becomes negative. This opens the logical "and" circuit E _b. The pulses of the quartz oscillator 8 then reach the lock counter 7, the z. B. can be a binary counter, and are counted. After the time interval T ₀ - DT ₀ has elapsed, the locking counter 7 emits a pulse N ₁ , which also flips the flip-flop Bm into the "1" state, in which the voltage at the output of Bm becomes negative. This opens the logical "and" circuit Em. After the time interval T ₀ + DT ₀ has elapsed, the locking counter 7 emits a further pulse N ₂ , which flips the flip-flop Bm back to the "0" state, in which the voltage at the output of Bm is again 0 and thus the logical "And." «Circuit Em is blocked again.

If the second pulse Iu _z , which the pulse shaper 2 emits, falls within the time interval limited by T ₀ - DT ₀ and T ₀ + DT ₀ , it can run through the logical "And" circuit Em and reach the beat counter 3. At the same time, the pulse Iu ₂ at the output of Em triggers the monoflop AZSjT ₀ , which with a short pulse brings the locking counter and the flip-flop Bm back to the "O" state. If, on the other hand, the second pulse Iu ₂ does not fall within the interval T ₀ - DT ₀ to T ₀ + DT ₀ , it can _{not pass through £ Λ} /, the blocking counter 7 is not set to "0", but continues to count and gives to one Point in time, which is somewhat after the point in time T ₀ + DT ₀ , a pulse Nn occurs . This triggers a circuit 11 which initiates the repetition of the measurement.

In this way, the noise that the microphone M picks up and that, if it is strong enough, causes interference pulses to occur at the output of the pulse shaper 2, will not falsify the measurement as long as the parasitic pulses are outside the time interval 2 DT ₀ .

The time interval in which the measurement could be disturbed by interference pulses is limited to the time 2 DT ₀ . This time interval will therefore be chosen as short as possible, e.g. For example, for a watch with 18,000 balance movements per hour, it would be practically 20 msec (thebretically 2.8 msec). The F i g. 3 to 5 show a circuit arrangement with which an automatic adaptation to different balance frequencies of z. B. 2.5, 2.75 and 3 Hertz succeeds in corresponding to the balance vibration numbers of 18,000, 19,800 and 21,600 per hour. The corresponding time spans are denoted by T ₁ , T ₂ and T ₃ , the time span tolcranz ranges correspondingly with 2 DT ₁ , 2 DT ₂ and 2 DT _a .

At 21,600 balance movements per hour, T ₃ = - 166.7 msec, 2 DT ₃ t 13 msec. The range in which emerging impulses are passed on to the beat counter extends from 160 to 173 msec. The corresponding numbers for 19,800 balance movements per hour are: T ₂ - 181.8 msec, 2 DT ₂ ~~ - 17 msec; the range is between 173 and 190 msec. The corresponding numbers for 18,000 balance movements per hour are: T ₁ -200 msec, 2 DT ₁ - 20 msec, and the range is between 190 and 210 msec. In the case of the FIG. 3, the first ImPuIsZiZ ₁ triggers the blocking counter 7. This emits a pulse N ₁ at time T ₃ - DT ₃ , in the example at 160 msec. The pulse / ^ toggles the flip-flop B ₁ into the »Ιβ state. This makes the logical "and" circuit E ₁ permeable. At time T ₃ -f- DT ₃ , in the example after 173 msec has elapsed, the lock counter 7 emits a second pulse, V ₂ . This tilts the flip-flop B ₁ back into the "O" state, in which E ₁ is blocked again.

If the second pulse Iu, at the output of the pulse shaper 2, falls within the time interval T ₃ - DT ₃ , in the above example at the earliest at 160 msec and at the latest at 173 msec after the first pulse Iu ₁ , it can use the "And" -Circuit E ₁ run through and flip-flop B ₁₀ toggle into the "1" state. This state means negative voltage at the output of B ₁₀ . This opens the logic circuit E 21 600 (FIG. 4), which is located between the electronic gate circuit 6 and the strike counter. After a predetermined number of balance strokes, in the example 36 (at 21,600 per hour), the gate 6 closes again.

If, on the other hand, the second pulse Iu ₂ does not occur within the period of time which is limited by T ₃ -DT ₃ on one side and T ₃ -f- DT ₃ on the other side, the flip-flop B _{1 toggles} due to the pulse N ₂ in the »Od state, whereby the flip-flop B ₂ flips into the» 1 «position.

The logic circuit E ₂ is open during the time interval limited by T ₂ -DT ₂ and T ₂ -H DT ₂ , in the example for 17 msec from 173 msec to 190 msec. If the pulse Iu _{1 occurs} within this time, it runs through the logic circuit E ₁ and toggles the flip-flop A ₂₀ into the "1" state. This opens the logic circuit E 19 8OD (FIG. 4) for a certain number of balance strokes, 33 in the example. If, on the other hand, the second pulse Iu ₂ does not occur in the time interval between T ₂ - DT ₂ and T ₂ + DT ₂ , the lock counter 7 emits a pulse N ₃ at time T ₂ + DT ₂ , which the flip-flop B, flips back into its "0" state, whereby the flip-flop B _{3 is} flipped into its "1" state.

The logic circuit £ ₃ is open in the time interval that is limited by T ₁ - DT ₁ and T _x + DT ₁ , in the example from 190 and 210 msec after the occurrence of Iu ₁ . After the time T ₁ -f- DT _U, ie after the time interval has elapsed, the locking counter emits a pulse N ₄ which flips the flip-flop B _{3 back} into the "0" state. If the second pulse Zw _{2 occurs} in the time interval between T ₁ - DT ₁ and T ₁ + DT ₁ , then Iu ₂ can run through the logic circuit E ₃ and toggle the flip-flop B _M into the "1" state. This opens the logic circuit E 18 000 (FIG. 4) between gate 6 and the strike counter. The gate remains open for a predetermined number of movements of the balance wheel, in the example 3D, and then closes again.

If, on the other hand, the second pulse Iu occurs in none of the three time intervals, because e.g. As the cr »te I.npuls / (/, not st.unnt of a balance rash, s m.lern a StörimpuU was s> sends the locking / .üiler 7 at a time shortly after the de: n Zeilpunkt T ₁ r DT ₁ lies, thus nujh the E: ide of the longest time interval, a reset pulse Nn, which

ίο brings the entire circuit into the starting position (O-state).

If one of the three flip-flops Uifen B ₁₀ , B _n , B _{M was} toggled by the second pulse Iu ₁ (as.) Assumes the "!" State), because Iu. appeared in one of the three time intervals, an in ^ nj of the logical "OJer-N circuit" receives negative Sp η mn; ". This negative voltage, which occurs in the "OJer-1" circuit aTi Auv> 1:13, is fed to a N ^ uivUufe / V (reversing stage). On originated the U.n'cehrstufe N, the voltage is then ~ 0. Dad ardi, the logical ^ unde circuits E _1, E, U ij £ blocked.

If one of the three flip FbpsUifen B _n , B ,,, B _{n has been} flipped into the '"!" Position, sd auj'i the z.ij; -hearing is logical; Se'.iultm .; £ ,,,. E _1n oJer E _n ge'j.Tiet.

The second pulse Iu _{1 also} triggers the M 11) .l>pW> T "

the end. which resets the lock counter 7 to 0 with a short pulse. For the following explanation it is assumed that the second impulse Iu ₁ flipped the fiip-flop B ₁₀ into the ">1" state: in J diljrcli the measuring arrangement for a U.ir with 19 8JJ U lruV deflects prepared in the lesson. If B _{10 is} in the "!" State, the 'U.iJ'-Sj'iakm; * E _{20 is} open. After each pulse Iu _{k of} the input former 2, the blocking counter 7 emits a pulse: V> after the period T ₃ - DT _{3 has} elapsed, which switches the flip-flop to the "1" state. Ni '. \ When the time period T ₂ - DT ₁ has elapsed, the locking counter 7 emits the λ pulse N ₃ , in the example 193 bad after the occurrence of Iu ₁ . The pulse Vj flips the flip-flop B _{1 back} into the >> 0 «state. D: r from j 113 of flip-flop B ₁ is connected to the "U lui-Sehallui ι £", which is opened by the "1"<- Vi iricierui ^ v> \ B _n . Dia

£ _{; l)} . E ₁₁ uil £ _l0 lead to the logical ι »OJ: r-2i-S; 'ia! T: ii», which lies at the entrance of the Schrnidt-Trigprs 5' .. D ^ e Spanuij at the entrance of the Se / imidt- Trigprs becomes negative about the time between T ₂ - DT ₁ to ~ 7, - DT ₁ , in the example for the time from 173 to 193 no. Wihrend the same time is also proceeding out of the Schmidt trigger negitiv and ö.T.iet the "Uii <circuit Em When the pulse on the ht / c ^ fol iiie pulse IIIk ^ -x diessn time interval dhzvisehei T _2. - DT ₂ to T ₁ -JrDT ₁ (173 to 193 m; e;) occurs so he can reach the »UjJa-Se'iiltung durjilaufei uiJ de; i beat counter. D ^ r I.tiduIs am Aui ^ nj vj.i Em triggers the M ^ noüjp MF , which emits a: i R. "u '<ste! Limpuls, which sets the locking number 7 to 0 u: iJ das Flip-flop 5, ₀ in dei 0-ZuUaii flips.

If the Irmuls /// does not fall within the time interval between T ₂ - DT, and T ₂ - (- DT, (173 to 19J m; e;), SD it can use the »U.iJ * -S: '. viltui " Em never! il run through. This is blocked because the A'.njnj of the Sc'imidt-Trigprs O-Spanunj. The pulse can never reach 1 ml aue'i do not trigger the M ^ nofbp .WF. The blocking / i'iler7 continues to count until time T ₁ | - DT ₁ and shortly thereafter sends the reset pulse .V / ·, which

brings the entire measuring arrangement into the starting position, so that the automatic measurement preparation, such as described, can start again.

Claims (4)

Patent claims: 1. Method for measuring the rate of clockworks with a pulse shaper, which is derived from the A microphone recorded clock noise forms electrical impulses, in which the measurement variable c that number of periods of a normal frequency is used for the movement of the clockwork, which between a clock that triggers the measurement and a later one that ends the measurement Clock strike is counted and in which the I: ingang of the strike counter only during limited Times gccflV.et is. characterized, that the pulse intervals are continuously checked by a counter (7) and the beat counter (3) only within ao a fixed time interval in which the expected pulse falls, gctffnct. 2. The method according to claim 1, characterized in that the opening times (2 DT) are twice as long as, according to experience, the greatest deviation (£>) of the clock from the mean value (T) in O-gear, the mean value (T ) the opening time is set to the point in time at which an impulse (Iu) from the balance wheel is in 0 gear. 3. Shall arrangement for carrying out the method according to claim 1 or 2, characterized in that that the counter (7) the oscillations of a calibration oscillator (8), which may be identical is with the one used for interval measurement (5), counts and with an adjustable number of oscillations defines the period within which the input of the pulse interval counter (3) is open. 4. Circuit arrangement according to claim 3, characterized by a logic circuit between a gate (6) and the strike counter (3), which automatically determine the opening times of the strike counter as well adjusts the number of beats determining the measuring interval to the number of vibrations of the test object. For this purpose 2 sheets of drawings