DE1270094B - Circuit arrangement for converting analog values into digital values - Google Patents

Description

Circuit arrangement for converting analog values into digital values Addition to registration: S 70660 VIII a / 21 a1 -Auslegeschrift 1203 821 The invention relates to a circuit arrangement for converting analog values into digital values. This includes conversion into digital values in the sense of the present invention both the conversion of the analog values into discrete amplitude levels (quantization) as also understand the implementation in a binary permutation code.

Coding tubes are used to convert analog values into digital values used. In these coding tubes, an electron beam is passed through one of the to be converted DC voltage corresponding to the analog value deflected and fed through a perforated screen, their hole distribution for reasons of clarity mostly the so-called Stibitz-Gray code corresponds to which, as is well known, with gradual change, in contrast For example, to the pure binary code, only one binary digit is changed at a time. the Conversion into the desired output code, e.g. B. the pure binary code then via additional code converters.

In another known method, the analog value to be converted is compared in chronological order with tensions, which in turn are compared with the stages? , 4 etc. to 1 (n = number of possible amplitude levels). Is equivalent to For example, the analog value to be converted to an amplitude level that is greater than 2, the voltage value corresponding to the amplitude level 2 is the one to be converted Analog value subtracted. If, on the other hand, the analog value to be converted corresponds to an amplitude value, which is less than 2, a subtraction does not take place. Then will the remaining analog value with a voltage corresponding to amplitude level 4 compared and determined whether the remaining analog value corresponds to a larger or smaller amplitude level. In an analogous manner, the process is repeated until the lowest amplitude value 1 is reached.

In another known method, the analog value to be converted is first converted into a time-length modulated pulse and this by means of a clock pulse certain repetition frequency sampled. The for sampling the time-length modulated The clock pulses required for pulses are counted into a binary counting chain. At the end During the scanning process, the binary number stored in the counter corresponds to that to be converted Analog value. Furthermore, an arrangement with magnetic cores is known in which a steady Variable measuring current passed through magnetic cores with different degrees of pre-magnetization will. These magnetic cores are chained in such a way that corresponding to the one to be measured Current value only one magnetic core repeatedly changes its magnetization state and emits a constant output signal.

From a completely different possibility of converting analog to digital Values makes use of the circuit proposed in the main patent application. she provides for a series connection of resistors with negative characteristic ranges, through which a current (analog current) corresponding to the analog value to be converted flows will. The individual resistors tilt at different values of the analog current from a low voltage drop state to a high voltage drop state, and vice versa.

The invention is based on the problem of a number of breakover resistors having circuit according to the main patent application in suitable for coding purposes Way to educate.

Based on a circuit arrangement for converting analog values into a pulse train corresponding to a binary permutation code with a series connection of current-dependent resistors with breakover properties (breakover resistors), which from a current (analog current) corresponding to the analog value to be converted flows through it the individual breakover resistors at different values of the analog current from a low resistance state to a high resistance state, and vice versa, tilt, the object is achieved according to the invention in that for each point of the binary permutation code, two parallel series connections of breakover resistors provided and their tipping points are graded so that with constantly changing Analog current alternating breakover resistances in one and in the other series connection tilt, and that the corresponding digit of the binary permutation code binary output signal dusch difference formation between the two series connections falling voltages is formed.

As already mentioned in the explanation of a known method it is advantageous to first convert the analog value into the Stibitz-Gray code, in which only one binary digit changes with step-by-step changes. To form the desired code, for example the pure binary code, are then additional code converters required. You can use these additional transcorders omitted in an advantageous embodiment of the invention. With this one The exemplary embodiment are the breakpoints of all breakdown resistors with the exception of the breakdown resistors in the two assigned to the least significant digit of the binary permutation code Series connections between the breakpoints of the breakdown resistances of these two Tipping points lying in series are set. The breakpoints of the breakdown resistances one or the other of two assigned to a position in the binary pulse train Series connections are made by the differential voltage between the voltages the derived series connections assigned to the first digit of the binary pulse train Streams additionally shifted.

The series connections assigned to the higher-order binary digits are therefore only preset by the analog current and only by the differential voltage between the voltages of the least significant digit of the binary permutation code Associated series circuits are also diverted into one for formation of the assigned binary output signals brought to a suitable position.

The breakdown resistors that have recently become known can be advantageous Tunnel diodes are used.

Details of the invention are illustrated with reference to in the drawing advantageous embodiments explained with tunnel diodes.

F i g. 1 shows the current-voltage characteristic of a tunnel diode The current that increases from zero is initially the voltage that drops across the tunnel diode very low, d. that is, the tunnel diode has a low resistance. Upon reaching of the current II, the voltage drop across the tunnel diode changes abruptly from the low value U1 to the high value U1 ', i.e. i.e., the tunnel diode tips over Reaching the current II by leaps and bounds from a state of low resistance to one State of high resistance.

F i g. 2 a shows a series connection of four tunnel diodes D1 to D4 with different characteristic values. The various characteristics of these tunnel diodes are shown in FIG. 2 b shown. If the series connection according to FIG. 2 a an increasing current I is supplied, the tunnel diodes D 1 to D 4 in the currents II to 14 tilt one after the other from a state of low resistance to a state of high resistance. The total voltage drop across the series circuit is shown in FIG. 2 c shown as a function of the increasing current. Every time a tunnel diode trips, the voltage dropping across the series connection changes abruptly. Such a series connection of tunnel diodes with different characteristic values can therefore be used to quantify analog values.

F i g. 3 a shows a series connection of four tunnel diodes D1 to D4 with the same characteristic values. Different bias currents are passed through the tunnel diodes D1 to D4 via the high-resistance series resistors R1 to R4, so that the characteristic curves of the individual tunnel diodes are shifted parallel to the voltage axis according to FIG. 3 b results. If a steadily growing current 1 is supplied to the input E, the tunnel diodes D1 to D4 flip at different current values II to 14. Those on the series circuit according to FIG. 3 a decreasing total voltage is shown in FIG. 3 c and corresponds to the voltage curve according to FIG. 2 c. The series connection according to FIG. 3 a is therefore also suitable for the quantization of analog values.

F i g. 4 a shows two parallel series connections Rs1 and Rsl 'of FIG four tunnel diodes each. The tipping points of these tunnel diodes are via high-resistance series resistors as in the circuit according to FIG. 3 a set in such a way that with constantly increasing Current at input E is a voltage curve U1 across the series circuit Rsl and a voltage curve U1 'on the series circuit Rsl' according to FIG. 4 b results. The course of the between Differential voltage U1 to U1 'that can be tapped off at points 1 and 1' is shown in FIG. 4 c shown. This differential voltage is zero or greater at regular intervals as zero and is therefore used, for example, to form the low-order digit of the pure binary codes. The circuit arrangement according to FIG. 4 a corresponds to when the analog current is fed to input E, a partial encoder that is used to create the least significant digit of the pure binary code with three digits is suitable. In a manner analogous to FIG. 4 a, further partial coders can be used for the higher-order ones Build up digits of the pure binary code.

In Fig. 5 is a complete encoder for converting analog values represented in a pure three-digit binary code. To form the three binary digits three double rows of tunnel diodes Rsl to Rs3 'are provided. The tension curve at the series connections Rsl and Rsl 'corresponds to the voltage curves U1 and U1' according to FIG. 4 b. The voltage curve at the series connections Rs2 and Rs2 'corresponds the voltage curves U2 and U2 'according to p' 1 g. 6 a and the voltage curve at the Series connections Rs3 and Rs3 'the voltage curves U3 and U3' according to FIG. 7 a. The differential voltages between points 1 and 1 'baw. 2 and 2 'or 3 and 3' are in Fig. 4 c and 6 b and 7 b and correspond to the assigned Place the pure binary code. These differential voltages are used by the differential amplifiers V1, V2 and V3 supplied, each of which then provides an output pulse when the Differential voltage is greater than zero.

As already mentioned, for reasons of clarity it is advantageous to first carry out the recoding into a binary code in which only one binary digit changes with each step-by-step change. Such a code conversion means a considerable additional effort for the coder. It can be according to the embodiment according to FIG. 5, a further development of the invention that has already been put into use can be avoided by suitable dimensioning of the analog currents supplied to the individual parallel rows of breakover resistors with the aid of a simple additional device. For this purpose, the series connections Rs2 to Rs3 'are opposite their actually correct position according to FIG. 6 a to 7 b adjusted by approximately half an amplitude level. A setting according to FIG. 1 then results, for example, for the series connections Rs2 and Rs2 '. B. The aforementioned additional circuit ZS is connected to the output of the differential amplifier V1 (FIG. 5). This additional circuit supplies a current at its output b if no pulse occurs at the output of the differential amplifier V1 corresponding to a zero at the last digit of the binary code. In an analogous manner, the output a of the additional circuit carries current when a pulse occurs at the output of the differential amplifier V1. The additional current is conducted via the series connection Rs2 'and Rs3' or Rs2 and Rs3. Due to this additional current, the tipping points of the tunnel diode in the series circuits Rs2 'and Rs3' or Rs2 and Rs3 are shifted by approximately one amplitude level, so that, for example, for the series circuit Rs2 'or the series circuit Rs2, a voltage curve according to FIG. 9, curve U2 ' or curve U2 results. If, for example, an analog current that is slightly greater than 14 is now fed to input E, then between points 2 and 2 'according to FIG. 8 initially a differential voltage. No pulse occurs at the output of the differential amplifier V1, so that the output b of the additional circuit ZS carries current. At the series circuit Rs2 'there is now a voltage curve according to FIG. 9, curve U2 '. Now, according to the assigned binary digit (see FIG. 6b), there is no longer a differential voltage between points 2 and 2 '.

With the described presetting of the series connection Rs2 bis Rs3 'and by the additional circuit depending on the differential voltage between the points 1 and 1 'delivered additional currents is thus achieved that the Series connections Rs2 to Rs3 'can only be preset by the analog current, that their final location, however, depends on the least significant digit of the binary code is dependent. This avoids, for example, an analog current of approximately the size 14 certain tunnel diodes corresponding to small differences tilt or not tilt in their characteristic values.

'The encoder of FIG. 5 therefore supplies a dem at output A. at the input E supplied analog current corresponding pure binary permutation code in parallel representation. If a series display is desired, known Parallel to serial converter or delay lines with different transit times be connected. The use of tunnel diodes is particularly advantageous, because they only require low power and have high cut-off frequencies, so that it is possible to build very fast and broadband coders. By application the additional device ZS according to FIG. 5 as well as the described "wrong" presetting of the series connections Rs2 to Rs3 'it is also possible to have "bad" tunnel diodes should be used whose characteristic values do not exactly match.

Claims (3)

Claims: 1. Circuit arrangement for converting analog values into a pulse train corresponding to a binary permutation code with a series connection of current-dependent resistors with breakover properties (breakover resistors), which from a current (analog current) corresponding to the analog value to be converted flows through it the individual breakover resistors at different values of the analog current from a low resistance state to a high resistance state, and vice versa, tilt, according to patent application S 70 660 IX / 42 m (German Auslegeschrift 1203 821), characterized in that for each digit of the binary permutation code two parallel series connections of breakover resistors and their breakover points are graded in such a way that with constantly changing analog current, breakover resistances alternate toggle in one and the other series connection, and that the associated Binary output signal corresponding to the digit of the binary permutation code by forming the difference is formed between the voltages falling across the two series connections. 2. Circuit arrangement according to Claim 1, characterized in that the tipping points of all Breakover resistances with the exception of the breakover resistances in the two of the least significant Place the binary permutation code associated series connections between the breakover points of the breakover resistances of these two series connections are set and that the breakover points of the breakdown resistances of one or the other of two series connections assigned to one digit of the binary permutation code by the difference voltage between the voltages of the least significant digit of the binary permutation code assigned series connections and derived currents be moved. 3. Circuit arrangement according to claim 1 and 2, characterized in that tunnel diodes are provided as breakover resistors. Documents considered: German Patent No. 1062 280.