DE3212270A1 - Control device for a recording circuit, in particular in an electronic clock circuit - Google Patents

Abstract

A control device for a recording circuit (9), in particular in an electronic clock circuit, by means of which prescribable control information can be generated depending on actuation as additive or subtractive correction information (27), is intended to be designed in conjunction with various possibilities of realisation for input signal transmitters (15) in such a way as to enable the delicate management of a large quantity of information in conjunction with a low additional outlay on circuitry for the generation and transmission of information. For this purpose, each of the two possible signs of the correction information (27) is assigned its own signal transmitter (15.1 or 15.2). A down counter (13) is counted down from an initial counting position (2<x>) between in each case one pair of successive actuations of one of these signal transmitters (15), and the final counting position thereby reached, which is thus proportional to the time interval (24) between two successive actuations of the signal transmitter (15), is processed as correction information (27). The signal transmitters (15) are preferably constructed as contact paths (37) which can be closed as a function of the direction of rotation by setting stem cams (45). The down counter (13) is preferably realised in a control circuit (6) with a microprocessor structure whose data bus sets a main memory area into the initial counting position (2<x>), starting from which the downward counting is performed using the program clock (23). <IMAGE>

Description

Setting device for a register circuit, in particular

in an electronic watch circuit. The invention relates to a Adjusting device according to the preamble of claim 1.

Such an adjusting device is known from DE-AS 27 26 383. To generate correction information to be evaluated additively or subtractively there is a phase shift between the two pulses depending on the direction of rotation a pair of pulses that is generated by rotating a handle, by way of digital signal processing determined. The pulse pairs represent a sequence of one-bit correction information by which the information content of a register area controlled by it changes (i.e. increased or decreased depending on the direction of rotation).

A timing circuit is also provided for monitoring whether the manual rotation with its rotation speed below or above a circuit-technically predetermined limit value lies. If this rotational speed limit value is exceeded there is a pulse multiplication, namely a correction information sequence with a Sequence that abruptly relates to a higher proportionality factor the rotational speed increases.

This is to ensure that especially with modern electronic Clock circuits with a microprocessor structure for information processing and provision of time information, even at high machine operating clock frequencies (for the internal signal processing control) the large amount of correction information can be fully processed.

In DE-AS 26 58 908 such information processing is within a clock circuit with a programmed microprocessor structure shown in more detail. The feeding in of correction information is also taken into account there. It acts However, it is about frequency deviations of the quartz-stabilized time-keeping Switching is not done by trimming the oscillating capacitance or by interfering with the to compensate downstream binary divider chain, but instead the limit values to modify for the digit carryover when feeding the register circuit, so that the register circuit again displays time-accurate time information as a result the display control circuit provides.

In contrast, the invention is based on the object of an actuating device of the generic type so that the usual, especially the manual Adjustments and other corrective interventions for the processing and provision of time-derived Information without much additional effort in an Enrenschaltung - in particular on the base of a microprocessor structure - can be integrated; being the generation of setting information for correction control can also optionally be made via pushbutton switches or in particular via an adjusting element that can be rotated in the manner of a clock adjusting shaft to be realized without the need for specific signal evaluation circuits, such as the effort required to determine an actuation directive from one another out of phase pulse series to require. A large adjustment range should be easy to handle.

According to the invention, this object is essentially achieved by that an adjusting device according to the preamble of claim 1 with the partial features is designed according to its characterizing part. So it becomes the setting information obtained in that> controlled by one and the same signal generator, a counting circuit temporarily.mit number clocks is applied so that the counting result is a measure for the time between two successive signals and thus a Measure for the setting input, i.e. for the size of the correction information to be evaluated is; a single counter designed as a backward counter is sufficient to slow down successive signals in a sequence of small amounts of information implement, and vice versa. It acts on this for both directions of correction common payer one of two selectively actuatable signal transmitters, that of the additive or subtractive correction with the setting information sequence assigned.

These signal transmitters can be controlled from the clock circuit itself be - for example to compensate for a frequency deviation of the time-keeping circuit from a control circuit only when time information is processed in the register circuit. In particular, these signal generators can also be used as manual actuatable switch contact paths be designed and so in the form of push-button switches or of rotary actuation switches for manual input of setting specifications as the Correction data are used in signal processing for time-derived information.

When activating the signal transmitter - not via different switches for additive or subtractive generation the correction information, but - via a single handle on one that can be rotated depending on the input required Adjusting shaft are preferably two spiral spring contact paths in such a way against one another spatially and functionally offset that, depending on the direction of rotation, a fixed shaft fixed Eccentric deflects only one or only the other spiral spring in the contact-making direction. This realization of the signal generator enables a compact structure3 and a simple dimensioning of the practically occurring upper limit of the amount of Setting information by specifying the number of eccentric cams in relation to the Counter clock frequency, the counter volume and the mechanical handling conditions when turning the adjusting shaft manually.

On the other hand, sensitive corrective intervention is easy in this way ensure that - effective with any slow rotation of the control shaft (or if the pushbutton is pressed for any length of time) - on the meter a lock is provided to the effect that the smallest amount of control information does not fall below the value one1.

Further features and advantages of the invention emerge from the following Description of one in the drawing is simplified, restricting it to the essentials illustrated embodiment for the solution according to the invention.

It shows: FIG. 1 in the basic representation of a block diagram the information acquisition and evaluation within the control device according to the invention 1 Fig. 2 pulse-time diagrams relating to the function of the actuating device according to FIG. 1, FIG. 3 an implementation example for the electromechanical area of the actuating device 1 in plan view and FIG. 4 shows the arrangement according to FIG. 3 in a sectional view according to the section arrows IV-IV in FIG. 3.

Figure 1 shows the implementation of an inventive concept in a schematic diagram Setting device in a microprocessor-controlled electronic clock. One quartz stabilized High-frequency oscillating time-keeping circuit 1 provides output pulses with a pulse repetition frequency of the order of 4 MHz, which is in a downstream binary divider chain 2 is reduced, so that at divider outputs 3, for example Pulse repetition rates on the order of 10 Hz and / or 1 Hz are available. A pulse repetition frequency is of the order of magnitude at an operating clock tap 4 of 50 kHz and at a program clock tap 5 a pulse repetition frequency of the order of magnitude for example 16 Hz. A stored program information processing control circuit 6 causes the extraction wld, under in an information processing circuit 7 Constant updating refreshment, keeping all of those time-derived ones ready Information that is available on the individual request of the user by means of a display device 8 should be presentable. The information processing circuit 7 contributes to this a register circuit 9 together, in particular the extraction of the decimal display Time information taking into account the dimension carryover at the area boundary the respective display point is used.

In accordance with the call via a manually operated fusion beam switch 10, a control circuit 11 takes over the display from the register circuit 9 requested time-derived information to display device 8 accordingly head for. This display device 8 is generally a multi-digit digital display; In principle, however, it can also be a act analog (pointer) display, whereby the angular position of the (mechanical or electro-optically shown) pointer via the control circuit 11 in accordance with the retrieved part of the content of the register circuit 9 gradually retracted and is then switched on.

The signal processing for obtaining the from the register circuit 9 to display callable time-derived information is done with the microprocessor-like Applied information processing control circuit 6, its internal functional sequence controlled by the operating cycle from the divider tap 4, which is used as the machine cycle will.

The program clock 23 from the divider tap 5 is used in particular for continuous Transfer of the information to be displayed one after the other in the display control circuit 11 and in the case of a digital display possibly also gaining a functional adapted AC voltage multiplex control voltage, for example within the Control circuit 11.

To a certain part of the information content of the register circuit 9, in particular, for example, the selection switch 10 for presentation on the Display device 8 called up time-derived information or part of such (especially digital) information display, to be able to change, e.g. to carry out the hour correction when the time zone or daylight saving time changes or but for specifying a signal time or a period of time for a count-down function, one of the circuits mentioned is, in particular the register circuit 9, an optionally additively or subtractively acting correction circuit 12 switched on. This takes over at a point in time that can be specified manually, for example setting information from a counter 13 in order to use this as digital correction information to be linked with the current information in that area of the register circuit 9, which is currently called for setting via, for example, the selector switch 10. This can be, for example, a small-dimension time information in the form of hours, Minutes and seconds total or around a selected one of these dimensions Act.

The counter 13 is a downward counter with, for example, a counting range designed by 2x = 24, which at its counting clock input 14 from the program clock tap 5 of the divider chain 2 can be fed.

The control of the down counter 13, including the control the end-of-count transfer into the correction circuit 12 takes place by means of signal transmitters 15 by a transfer control circuit 16. In the correction circuit 12 are a Addition generator 16 and a subtraction generator 17 are provided, which functionally the Addition signal generator 15.1 or the subtraction signal generator 15.2 are assigned. In addition, both signal generators 15 are used equally, namely linked via an OR gate 19 within the transfer control circuit 16, the function control of the down counter 13 3 for the acquisition of positioning information according to the amount.

The correction ion information to be input by means of the correction circuit 12 27, i.e. the setting information in the form of the counting end position at the output of the counter 13, should the lower the longer the time between two successive signals from one and the same signal generator 15.1 or 15.2 is. When one of the signal generators 15.1 or 15.2 is activated for the first time e.g.

a bistable stage 20.1 within the transfer control circuit 16 or 20.2 (which are reset by the next signal output will). From the set stage 20, first a reset input is provided via the OR gate 19 21 is temporarily controlled and then a gate in the form of an AND element 22 is opened. As a result, the operating cycle 23 (cf. FIG. 2) is transferred from the divider output 5 to the counting cycle input 14 of the down counter 13 switched through, from its highest counting position 2x is counted down step by step towards the lowest counting position. The next signal from the same signal generator 15.1 or 15.2 sets the assigned one bistable stage 20.1 or

20.2 back. This activates the release control of the sBS element 22 canceled before the counting clock input 14 and in the correction circuit 12 the addition encoder 17 or the subtraction transmitter 18 to take over the counter counting position that has now been reached and correction feed into the register circuit 9 is controlled.

As is readily apparent from this function, and in FIG. 2 as Pulse diagram shown for further clarification, it depends on the length of the Time span 24 between two successive signaling edges 25 on the assigned Reversing input 26 of the respective bistable stages 20.1 / 20.2 from how many Pulses of the program tei 23 of the down counter 13 from its counting start position 2 counts down. If two signaling edges 25 follow each other quickly, that is Correction information 27 represented by a large number; if a longer distance elapses between two activations of the signal generator 15, the counter 13 continue counting down, and the correction information 27 is through a smaller number is shown.

Since with a very long period of time 24 the payer 13 down to its final value Zero would be reset, so no correction information 27 would be evaluated (which could lead to confusion during operation) is a blocking coupling 28 provided by the counter counting position with the value "one" to the AND element 22, which (via an inverter 29) feeds into the counter clock input 14 when it is reached this smallest counting position above the value zero is blocked. This ensures that even with a very long period of time 24 the two actuations of one of the switches 15 at least in the register circuit 9 for a correction with the smallest occurring digital unit as the correction information 27 leads.

Since it cannot be ruled out that the operator of such an adjusting device mistakenly one of the signaling devices 15.1 or 15.2 only once and then the other Signal generator 15.2 (or 15.1) actuated, are to Rü between the bistable stages 20 reset couplings 30 are provided. This ensures that when actuated one of the signal generators, e.g. 15.2, the bistable stage 20.1 assigned to the other regardless of the previous switching status (and thus regardless of whether the other Signal transmitter 15.1 last twice, as required by regulations, or only once by mistake has been actuated) is reset to the functional rest position. So that such a The reset process does not lead to the control of the correction circuit 12 is in each case a short-term effective blocking element 31 its addition and subtraction inputs 32.1 / 31.2 upstream.

To simplify the overview, FIG. 1 is only through symbolic indicated clock control lines 33 to express that the information processing The machine cycle that controls the microprocessor structure is expedient also for information processing within the handover control circuit 16 and within the correction circuit 12 for the synchronization or defined delay the individual signals are used against each other.

In addition, the adjusting device does not have to be within the scope of the invention by discrete circuit parts according to the one used for the explanation of the function Be implemented as a block diagram according to FIG. 1; expediently rather the Individual functions through appropriate program expansion in the information processing control circuit 6 moved into it. It is sufficient for this in one of the main memories of the microprocessor control circuit 6 as many digits x to be provided as the function of the binary down counter 13 counting levels, according to its counting scope 2x, should have. Preferably will the value of x is equal to the number of parallel channels of the bus structure of the microprocessor control circuit 6 elected. Because then that memory area that has the function of the backward counter 13 is assigned, with a single machine operating cycle by setting the x Memory cells are set to the count start position 2x by this data bus parallel, each assigned to a memory cell, these memory cells have an H signal applied to them; and then this memory output situation (with the function of the count start position 2x) processed step by step from program cycle 23 (i.e. counted down). Since the Function of the correction circuit 12 in any case within the framework of that of the register circuit 9 preceding information processing circuit 7, e.g. for incremental or decremental Change of time-derived information, is realized (namely in the principle illustration the Fig. 1 is shown separately for the sake of clarity zçurde), and as explained the function of the down counter 13 including its Set and switch back control within the framework of the already existing bus and memory structure can be implemented in the control circuit 6, it is necessary for the generation of the setting information and their transfer and processing as correction information 27, i.e. in the case of microprocessor-controlled Clock circuits do not involve any additional effort for the implementation of the invention Adjusting device; if one of the mutual interlocking measures in the connection apart from the two signal heads 15.1 / 15.2 - but they are also in the frame the control circuit 6 and coordinated by the machine operating clock from the tap 4 are realizable. This results in without - apart from the activation of the two Signal generator 15 - hardware intervention in the microprocessor-structured clock circuit by means of the measures according to the invention, the possibility of generation and correction being taken into account of setting information selectable sign, which in the cycle of the program cycle 23 Generated (changed) taking into account the actuator intervention and in the machine operating cycle further-processed as correction information.

In Fig. 3 / Fig. 4 is a preferred electromechanical Ausffflniigsbeispiel for the implementation of the two signal transmitters 15.1 / 15.2, especially in the case of a wristwatch, Represented symbolically simplified, As a uniform handle for the operation both signal generator 15 is a crown 34 at the front end of an actuating shaft 35, which in bearings 36 on the case and / or on the movement structure of a clock, in both directions of rotation rotatable, is supported. Peripherally offset from one another in the direction of rotation, preferably diametrically opposite one another, electromechanical contact paths 37 are in the form of spiral springs 38 factory fixed arranged. One of them is in one direction of rotation, the other in the opposite direction of rotation of the control shaft 35 until it rests on a mating contact 39, in each case in the opposite direction on the other hand free, deflectable. The two are seen in one direction of rotation Flexural springs 38 and the two mating contacts 39, which are radially directed to the axis of rotation to assign adjacent to each other. The deflections of the spiral springs 38 take place through tangential bending attack of an eccentric connected non-rotatably to the actuating shaft 35 40, in whose rotational movement path L1 the spiral springs 38 with their freely cantilevered Ends protrude. In this way it depends on the direction of rotation of the control shaft 35 from whether (with clockwise rotation) the contact path 37.1 (corresponding to the addition signal generator 15.1) or (when turning to the left) the other contact path 37.2 (corresponding to the subtraction signal generator 15.2) closed and thus the signaling edge 25.1 or 25.2 is triggered.

The freely protruding areas of the spiral springs 78 are used for mechanical purposes Reinforcement and to define the bending point of inflection are provided with longitudinal beads 42. The spiral springs 38 and their mating contacts 39 are preferably directly on attached to a circuit carrier 43 of the clockwork, on which also the integrated circuit Mechanically fixed (for the functions explained in connection with FIG. 1) m1d electrically to the periphery (especially power supply and output terminals) connected.

The eccentric 40 is preferably a star wheel 44 - shown in FIG Example case according to FIG. 4 with three actuating cams 45 - designed. Through this Already two thirds of a manual turning process on the crown 34 leads to the two successive contacts for the Obtaining correction information 27, the sign of which is determined by the direction of rotation. Turn the Crown 34 causes rapidly successive signaling edges 25, so only in each case short downward counting of the counter 13 from its starting position 2x and thus one Sequence of high numerical values as correction information 27. The effect is the speed of rotation by the design of the setting wheel 44, that is, in accordance with the number of actuating cams that are present 45, to a higher turning speed compared to the actual manual transposed. In contrast, very slow turning of the crown 34 leads to long periods of time 24 (see FIG. 2) and thus to low end counting positions, in the extreme case to end counting positions the value "one"; i.e. the adjustment of the called up content of the register circuit 9 takes place step by step with a sequence of the smallest possible information unit.

The most significant correction information 27 is due to the start of counting position 2x of the down counter 13 given.

With a large diameter, the crown 34 can be more simple and thus faster manually, namely twist between the fingertips; and larger Number of actuating cams 45, the same angle of rotation leads to a higher repetition frequency of the signaling edges 25, that is to say to a shorter countdown time period 24. This time period 24 can in the extreme case, namely when the repetition frequency of the signaling edges 25 is greater than that of the program clock 23 at the counter clock input 14 is so short that none two consecutive counting clocks at the counting clock input 14 of the down counter 13 appear, i.e. the count start position 2x also the setting information at the same time for entering the correction. An increase in this interpretation in terms of the ability to rotate the crown 34 and the number of cams 45 on the star wheel 44 then obviously no longer makes sense. Tests have shown that with a counting or program clock 23 in the order of 16 Hz and fi.ir a counting start position @ 4 with a dimension of the crown 34 according to the training in conventional wristwatches, a star wheel 33 with three peripheries evenly against each other offset cam 45 for the manual, problem-free acquisition of the setting information "sixteen" the most significant correction information 27 is sufficient.

This means that one is functionally very problem-free and with the least possible Additional effort can be included, especially in clock circuits with a microprocessor structure - but also for such circuits for other purposes applicable -adjusting device simple mechanical structure created, which has the advantage of being conventional Control devices for (mechanical) wristwatches can be operated.

The adjustment of the register contents can be done very sensitively by slow The adjusting shaft 35 is rotated with a sequence of the smallest information units, fluctuations of this slow rotary movement within certain limits still without influence on the (desired) slight variation in information, additive or subtractive Direction, are. The correction information is the result of increasing the rotational speed 27 in proportion to the speed of rotation, except for one the circuit design specified maximum value can be increased; so that e.g. also complete Multi-digit time indicator (i.e. without the request for calling up certain places) run through quickly and then again in the target area by reducing the turning speed, if necessary, with a reversal of direction, can be retracted sensitively.

LIST OF REFERENCE NUMERALS 2 initial count position (of 13) x binary digits (of 13) 1 time-keeping circuit 2 divider chain (after 1) 3 divider outputs (for 7 ... 9) 4 operating clock tap (on 2) 5 program clock tap (on 2; for -23) 6 information processing control circuit (for 7 ... 9) 7 information processing circuit 8 display device 9 register circuit 10 Function selector switch 11 Control circuit (for 8) 12 Correction circuit (for 7/9) 13 Counter 14 Counter clock input (of 13) 15 Signal transmitter 16 Transfer control circuit (from 15 to 12) 17 addition giver 13 subtraction giver 19 OR element (before 22/14) 20 blstable stage (after 15) 21 reset input (of 13) 22 AND element (before 14) 23 Program cycle (from 5) 24 Time span (between 25-25) 25 Signaling edge (from 15) 26 Changeover input (at 20 for 25-15) 27 Correction information (from 13 to 12-9 / 7) 28 blocking coupling (at 13-22) 29 inverters (in 28) 30 reset couplings (between 20.1 and 20.2) 31 blocking levels (between 20 and 32) 32 addition resp. Subtraction input (from 12/17 or 12/18) 33 Clock control line (from 4 to 12 and 16) 34 crown. (at 35) 35 control shaft 36 bearing (from 35) 37 contact sections (for Realization of 15) 38 spiral springs (of 37) 39 mating contacts (to 38) 40 eccentrics (at 35 between 38-38) 41 torsion path (from 40 or 45) 42 longitudinal beads (in 38) 43 circuit carrier (for attaching 38 and 39) 44 star wheel (as 40) 45 Actuating cam (on 44)

Claims (13)

A n p r ü c h e Oil setting device for register circuit (9), especially in the case of an electronic clock circuit, in which, controlled according to Determination of the time span between two successive signaling edges (25), Correction information (27) depending on the operation, additively or subtractively a correction circuit (12) can be entered. characterized in that the correction circuit (12) is a down counter (13) and a transfer control switch (16) is connected downstream, and that the down counter (13) via the transfer control circuit (16), depending on the additive or subtractive Correction information (27.1 or 27.2) selectively from one or two from the other Signal transmitter (15.1 or 15.2), by successive signal transmitter activations can be started and stopped again and can be reset to its start counting position (2x). 2. Adjusting device according to claim 1, characterized in that the Signal transmitters (15) are designed as manually operable contact paths (37). 3. Adjusting device according to claim 2, characterized in that the Contact paths (37) formed in this way and relative to each other are arranged that depending on a manual direction of actuation only one or only the other of the two contact paths (37.1 or 37.2) switches through. 4. Adjusting device according to claim 3, characterized in that as Actuator an actuating shaft (35) with an eccentric (40) is provided with which the contact paths (37) are temporarily in wired connection depending on the shaft rotation stand. 5. Setting device according to claim 3 or 4, characterized in that that each contact path (37) consists of one in the rotational movement path (41) of the eccentric (40) protruding spiral spring (38) and one along the rotary movement path (41) opposite contact (39) is offset and the two spiral springs (3S) or Contacts (39) are each adjacent to one another in the direction of a rotational movement path. 6. Adjusting device according to claim 4 or 5, characterized in that that the eccentric (40) as a star wheel (44) with meiireren actuating cams (45) is trained. 7. Adjusting device according to claim 6, characterized in that the Star wheel (44) has so many actuation cams (45) that with a given Value for the manual speed of rotation of the control shaft (35) the following frequency of signaling edges (25) on the signal generators (15) the counting pulse frequency at the counting clock input (14) of the backward counter (13) in any case not significantly exceeds. 8. Adjusting device according to one of the preceding claims, characterized characterized in that the counter (13) has a blocking coupling (28) from the counting end position "Eins" zuul counting clock input (14) is provided. 9. Adjusting device according to one of the preceding claims, characterized characterized in that between the two signal generators (15.1 and 15.2) reset couplings (30.1 or 30.2) are provided. 10. Adjusting device according to one of the preceding claims, characterized characterized in that the down counter (13) as a memory area in the context of a microprocessor-structured control circuit (6) for controlling the register circuit (9) is formed. 11. Adjusting device according to claim 10, characterized in that de £ binary backward counter (13) has as many counter positions as a data bus the control circuit (6) has parallel channels. 12. Adjusting device according to claim 10 or 11, characterized in that that the backward counter (13) from a counter position (2X) out with the program clock (23) of the control circuit (6) is applied as a counting clock. 13. Adjusting device according to one of claims 10 to 12, characterized in that that the machine operating cycle of the control circuit (6) also the cyclical query the signal generator (15) and the transmission of the setting information as correction information (27) serves.