DE2126595A1 - Device for displaying if the measuring range has been exceeded - Google Patents

Description

Device for the display of exceeding the measuring range. The invention relates to a device for recognizing and displaying when the nominal measuring range is exceeded in the case of a digital measuring device equipped with one or more decade counters is and also has bistable switches that control the counter over the range of Extend the decade counter by one decimal place.

The cost of a digital measuring device depends to a large extent on the achievable measurement accuracy, so in particular on the number of to display coming decimal places. A multi-digit decadic display does not require only a measuring amplifier with a correspondingly large linearity range, but also a correspondingly large number of decoders, memories and counter decades.

If the linearity range of the measuring amplifier used exceeds the the measuring range specified for the counter and memory decades by, for example, no more than 100 up to 200%, the number of decades will not be increased, only add individual flip-flops. A measuring device equipped e.g. with three decades and therefore only covers a measuring range of 999 counting steps, you can access this Way to 1999, 2999 or 3999 counting steps.

It is assumed that in a digital measuring device the linearity range of the measuring amplifier goes up to approx. 2400, but without an accuracy guarantee for values over 2000 can be given. For a measuring technician working with this device is it is an advantage if there are also values that exceed the nominal measuring range of 2000, can measure. On the other hand, it is very important for him to exceed the nominal measuring range notice immediately. There are the following institutions are now known, by means of which an exceeding of the measuring range is made visible.

The simplest known possible solution provides that the display in the example mentioned only goes up to the value 1999 and exceeds this Value by flashing the number 1 or by the flashing or steady lighting of a separate signal lamp is displayed. In this respect, however, this facility is little satisfactory when the existing linear overflow range of the measuring device is not used will.

In another known device, values are also over Displayed in 1999, but the number of the highest decimal place remains stand or switches to zero so that a value 1087 or 087 is displayed. Self blinking of the display will not entirely prevent incorrect readings comes, at least the reading is very difficult here.

A clear reading of the display is possible if the measured Value is displayed in all digits by the correct digits, i.e. accordingly the example as 2087 and to identify the exceeding of the measuring range the whole Display flashes. The circuitry required in this known device However, the effort involved is also considerable. In addition, the reading is somewhat enhanced by the Troubled picture of the whole blinking display made more difficult.

The object of the invention is to overcome the disadvantages of the known devices and to find a type of display that is unambiguous and unambiguous on the one hand allows clear reading of the measured value and on the other hand with circuitry can be achieved with little effort.

This object is achieved according to the invention in that a switching logic is provided that controls a lamp when the nominal measuring range is exceeded, which is used once to display the next higher digit of the highest decimal place and together with the display for the remaining decimal places within the limits of the linearity range of the associated measuring amplifier the correct measured value indicates and which at the same time indicate that the measuring range has been exceeded by flashing.

The circuit developed for this purpose is designed in such a way that one after the meter transfer signal and the to determine the measuring and reference time serving signal controls a flip-flop that emits a periodically changing signal when the nominal measuring range is exceeded, which in turn controls the lamp for over the nominal measuring range via an electronic switch going beyond the next higher digit of the highest decimal place periodically entered and turns off. The signal for exceeding the measuring range also in data processing To be able to process it further, it is necessary to turn the changing signal into a continuous one Make signal. The invention therefore provides that a second flip-flop both output signals of the first flip-flop and the memory signal are supplied and the output signal of the second flip-flop when the nominal measuring range is exceeded goes from 0 to L once and does not change until the measuring range is exceeded is canceled.

The advantages achieved with the invention are in particular: that a reliable reading, that is to say that largely eliminates errors, is possible. The circuit according to the invention is distinguished by its particular simplicity. So the counter capacity can be increased by up to with the help of just one additional flip-flop to expand to 100 6 and at the same time the highest decimal place of the blinking To achieve ad. The ones required to control the required flip-flop Signals are all already available in the digital part of the measuring device, so they do not have to be can only be generated by additional multivibrators or frequency dividers.

An embodiment of the invention is shown in the drawings and is described in more detail below.

They show: FIG. 1 a basic circuit diagram of the digital measuring device. 2 shows a signal diagram for a measurement within the nominal measuring range Fig. 3 a signal diagram when the nominal measuring range is exceeded.

The basic circuit diagram shown in FIG. 1 is an analog-to-digital conversion according to the dual slope method.

With the electronic switches 1, 2, the reference voltage are alternately URef and the measuring voltage UM connected to zero potential. To the input of the integrator 3 only one of these two voltages is applied. As from the signal diagram B of FIG. 2, the measuring voltage is integrated during the time t0 to t1 and during the time t1 to t2 by the reference voltage until the Initial value integrated again. To keep the initial value constant and the output of a logical signal - as soon as this is reached - is the output of the Block 4 shown control circuit responsible. That from the control circuit 4 incoming signal E is given to a flip-flop 5 and a NAND gate 6, from one Differentiator 7 differentiates and shaped into a rectangular pulse C. Through a Inverter 8, the signal C is inverted to a signal D and together with the pulses a frequency generator fed to a NAND gate. This gate 10 now controls the counter 11 connected to the memory 12 and its overflow signal A is received by the flip-flop 5 and another flip-flop 13. The flip-flop 13 controls the display 14 for the number 2 and together with the differentiator 7 a flip-flop 15. In addition to the display 14 for the number 2, there is also a display 16 required for the other decimal places, which is controlled by memory 12.

The measuring time from t0 to t1 is determined by the counter 11, which in the present example counts to 1999 and the 2000th from the frequency generator coming pulse u at time t1 emits an overflow signal. The overflow signal now causes the electronic switches 1 and 2 to switch over via the flip-flop 5 and the reference voltage URef is present at the input of the integrator 3. While the time t1 to t2, the downward integration takes place (FIG. 2). As soon as the initial value again is reached, the control circuit 4 emits a signal E, which during the time t2 until t0 remains unchanged. By differentiating this signal E, the memory signal C generated.

The counter reading reached by the counter at time t2 corresponds to the measured value and is displayed by the signal C. The inverted signal D prevents the counter continues to run until time t3. As soon as the memory signal C disappears, so goes to zero and the inverted signal D controls the NAND gate again, the counter begins to run and reaches its end value of 2000 counting steps at t0. The measuring process can now be repeated.

The logic circuit for recognizing and displaying an exceedance of the nominal measuring range consists of the J-K master-slave flip-flop 13 and the block 14 display combined with a transistor switch. The flip-flop 15 is only required for further processing of the signal G, since this is used to control a printer or the computer's used signal does not change according to the blinking of the display allowed.

The signal sequence of the logic circuit is shown in FIG. 2 and 3 described signal diagrams shown. During the time interval t0 The measured value is integrated up to t1.

The signal B at the output of the integrator 3 reaches a at time t1 The amplitude corresponding to the measurement voltage is greater in FIG. 3 than in FIG. 2. With the 2000th pulse coming from the frequency generator, the flip-flop receives 5 at the clock input from the counter the overflow signal A. At this time it is from the control circuit 4 incoming signal E = 0 and the signal D = L fed to the set input.

The flip-flop switches over and the output signal becomes F = L.

The flip-flop 5 needs a time of approx.

50 ns, so that the signal F only after the counter overflow signal has expired A goes to L. The outputs E and H from flip-flops 13 and 15 therefore remain at zero. The electronic switches 1, 2 are switched over by the signal F = L at time t1 and the reference time begins with the down-integration.

In FIG. 2, signal B already has the initial value at time t2 reached again, the signals E = L and D = 0.

Since the signal D is at the set input of the flip-flop 5, it decides the switch position and F = L remains. The signals G and H remain 0, there the clock signal A for the flip-flop 13 is missing.

In Fig. 3, the signal B has at time t2, although this is later lies than in FIG. 2, its initial value has not yet been reached again. The signal E at the output of the control circuit therefore remains 0 and accordingly D = L. That Signal F has now been low for some time when the clock pulse for flip-flop 13 comes, so that it switches over and G = L. The output signal H from the flip-flop 15 remains at zero, since the memory signal C serving as a clock pulse is still missing.

In FIG. 2, at time t2, the memory signal C = L and its inverted signal Signal D = 0. As a result, the counter is stopped until time t3. During this Time all switch positions remain unchanged. The counter only continues to count from t3 and emits an overflow signal at t0. As a result, the flip-flop 5 changes with E = L and D = L in the other switching state and it becomes F = 0. The electronic switches 1, 2 are switched over and the new measuring time begins. The flip-flop 13 remains with F = 0 to G = 0 and thus flip-flop 15 also keeps H = 0.

In FIG. 3, the downward integration is continued in the time from t2 to t3. At t3 this is ended and the signal E goes to L and, depending on this, C = L and D = 0. With D = 0, F = L and G = L.

Because the clock signal is still missing, H = 0. First the sloping one The edge of the memory signal C, which serves as a clock signal for flip-flop 15, switches at t4 its output to H = L.

The counter, which is idle during the time t3 to t4, starts counting at t4 continues and gives when it reaches its end position at 2000.

Counting step, an overflow signal begins, as shown in Fig. 2 at t0 the new measuring time.

As can be seen from FIG. 3, the signal G changes when the measuring range is exceeded periodically between 0 and L. By a clever choice of the duration of the memory signal C, which in the present example corresponds approximately to the time of a counter cycle, it is achieved that the square half-waves of the signal G are of equal length. That The blinking of the display 14 is therefore particularly easy to perceive and the deflection of the displayed number is no problem.

Claims (3)

Claims 19 Device for the detection and display of exceeding the Nominal measuring range for a digital measuring device with one or more Is equipped with decade counters and also has bistable switches that control the Extend the counter beyond the range of the decade counter by one decimal place, characterized in that a switching logic is provided which, when exceeded of the nominal measuring range controls a lamp that displays the next higher Digit of the highest decimal place and together with the display for the rest Decimal places within the limits of the linearity range of the associated measuring amplifier shows the correct measured value and at the same time the measuring range is exceeded by flashing signals. 2. Circuit for a device according to claim 1, characterized in that that in a digital measuring device operating according to the dual slope method, the counter transfer signal (A) and the signal (F) used to determine the measurement and reference time is a flip-flop (13) control that when the nominal measuring range is exceeded, a periodically changing Emits signal, which in turn switches the lamp for the Next higher digit of the highest decimal place beyond the nominal measuring range switches on and off periodically. 3. A circuit according to claim 2, characterized in that a second Flip-flop (15) the two output signals of the first flip-flop (13) and the memory signal (C) are supplied and the output signal (H) of the second flip-flop (15) when exceeded of the nominal measuring range goes from 0 to L once and does not change until the exceeding of the measuring range is canceled. L e r s e i t e