DE1213891B - Pulse counting circuit - Google Patents

Description

Pulse Counting Circuit The invention relates to a pulse counting circuit with a chain of series connections connected in parallel.

Counting circuits can be found in automatic calculators, digital - voltmeters, digital control devices for machine tools, self-connecting telecommunication exchanges and in many other fields of application.

A counting circuit has already been proposed in which n Counting stages made up of a luminous capacitor and at least two photoconductors are. This proposed counting circuit requires two photoconductors for each counting stage with significantly different internal time constants and continues to be required alternately actuated impulse lines with a complicated switching device for actuation of the impulse lines.

The invention aims to provide a new, simple and inexpensive counting circuit indicate in the gas-filled tubes with two electrodes, z. B. neon diodes, and light-sensitive resistors, e.g. B. CdS cells can be used.

A counting circuit according to the invention is characterized in that that the series connections are each the series connection of a light-sensitive resistor and a gas-filled tube with two electrodes, the gas-filled Tube connected in series optically with the light-sensitive resistor the next series connection in the chain is coupled, which series connections on the side of the photosensitive resistor with one terminal of a voltage source and on the side of the gas-filled tube, one side rides one for all series connections common parallel connection of a resistor and a capacitor the other side of which is connected to the second terminal of the voltage source, being the connection point of the photosensitive resistor and the gas-filled Tube each series connection through a separate resistor with a common one Pulse line is connected, which is connected to a counting pulse source.

The invention is explained in more detail below with reference to the drawing.

F i g. 1 shows an example of the counting circuit according to the invention, and F i g. FIG. 2 shows a control circuit for controlling the in FIG. 1 shown Counting circuit.

The counting circuit shown in FIG. 1 contains several connected in parallel identical series circles, which can be numbered from 1 to 4, while the same Elements of the series circles by the same designation and the number of the series circle can be specified.

A series circuit contains the series connection of a light-sensitive resistor LDR, e.g. B. a CdS cell, and a neon-filled diode D. Each series circuit is connected via the series connection of a common resistor 1 and a light-sensitive resistor 2 on the side of the light-sensitive resistor LDR with the positive terminal of a supply source (not shown), the negative terminal of which is connected Earth lies. The other side of each series circuit is connected to one side of a parallel circuit, common to all series circuits, of a resistor 3 and a capacitor 4, the other side of which is grounded. Furthermore, the connection point of the light-sensitive resistor LDR and the neon diode D of each series circuit is connected to a common pulse line P via a separate resistor R. Each neon diode D is optically coupled to the light-sensitive resistor in the next series circuit, while the neon diode D 4 in the last series circuit is coupled to the light-sensitive resistor LDR 1 in the first series circuit. These optical couplings are shown in the figure by arrows and are produced in that the photosensitive resistor is applied to the glass envelope of the neon diode. In this way, an ignited neon diode illuminates the light-sensitive resistor in the next series circuit and sets its resistance to a low value. The light output. an ignited neon diode is such that the CdS cell used has a resistance of about 3000 S2 at this exposure level. The dark resistance of a CdS cell is a multiple of the -resistance ixri- "exposed state and can reach a value of several megohms.

The pulse line t'- are supplied with counting pulses that counteract their saving Reduce soil temporarily. These counting pulses with a negative sense of direction are like this designed to have a sharp leading edge and a slowly exponentially decreasing one Have the trailing edge so_. That they have the shape of a differentiated rectangular pulse exhibit.

To explain the operation of the ring counter, it is assumed that one of the neon diodes D, z. B. the diode D 1 is ignited and that all other neon diodes are extinguished, and further that the light-sensitive resistor 2 is held by a light signal S at a low resistance value. The discharge current of the neon diode D 1 essentially flows in the circuit -f-, 2, 1, LDR 2, R 2, R 1, D 1, 3, -. In this circuit, the light-sensitive resistor LDR 2 is exposed by the neon diode D 1, see above. that it has a low resistance value. The other photosensitive resistors are not exposed and have a high resistance value. The ignition voltage of the neon diodes used is 170 V and the burning voltage is 105 V. The voltage of the voltage source is 220 V. In the circuit shown, the capacitor 4 is charged to a voltage of about 50 V by the voltage drop across the resistor 3. The voltage of the pulse line P with respect to the ungrounded end of the resistor 3 is equal to the burning voltage of the neon diode D 1 plus the voltage drop across the resistor R 1 and is about 135 V. This voltage is below the ignition voltage of the neon diodes D 2 to D 4 so that they remain deleted.

. A counting pulse fed to the pulse line P- suddenly reduces the voltage of the pulse line to earth to such an extent that the neon diode D 1 is extinguished. The voltage of the pulse line P then increases exponentially, while the voltage of the ungrounded end of the resistor 3 decreases exponentially as a result of the discharge of the capacitor 4 through the resistor 3. After the neon diode D 1 has been extinguished, the light-sensitive resistor LDR2 maintains a relatively low resistance value during the switch-off time, which is of the order of magnitude of several milliseconds, as a result of which the connection point of the resistor R 2 and the light-sensitive resistor LDR 2 has a higher voltage than the corresponding ones -Connection points in -the other series circles: 'As a result, the neon diode D 2 ignites first. - As soon as the neon diode D 2 ignites; the capacitor 4 is charged again, whereby the voltage across the other neon diodes cannot reach the ignition value, so that these neon diodes remain extinguished. The neon diode D 2 exposes the light-sensitive resistor LDR3 in the next series circuit, as a result of which the discharge current of the neon diode D 2 is essentially in the Ströpäkreis. -I-, 2, '1, LDR 3; R3; R2, D 2, _ 3, - flows. Sdhäld-die; neon diode D2 ignites; -The voltage of the connection point of the resistor R 2 and the light-sensitive resistor LRD 2 with respect to the ungrounded end of the resistor 3 drops from the ignition voltage to the burning voltage of the neon diode D-2 '. Then as a result of the charging of the capacitor 4. the voltage of the connection point to earth increases exponentially. In this way the timing arises. the ignition of a neon diode at the connection point between the resistor R and the light-sensitive resistor LDR, a pulse with a negative sense of direction, which is passed on via the resistor R and the pulse line P. The next counting pulse fed to the pulse line P extinguishes the neon diode D 2 during its leading edge and ignites the neon diode D 3 during its exponentially decreasing trailing edge: Each counting pulse thus shifts the discharge of a neon diode by one position in the counting circuit, whereby after igniting the neon diode D 4 the light-sensitive resistor LDR 1 in the first series circle is exposed, whereby the next counting pulse ignites the neon diode D 1.

F i g. 2 shows - a control circuit associated with the through -f-, P and - can be connected lines designated to the respective lines of the counter circuit shown in F Ig.1. With this control circuit, counting pulses can be generated, whereby the counting circuit, in cooperation with the control circuit, automatically shifts the discharge of a neon diode through the successive series circuits. The control circuit contains the series connection of a neon diode 5 and a parallel connection of a resistor 6 and a capacitor 7 between the pulse line P and earth. When a neon diode D has been ignited, the voltage of the pulse line P to earth increases to about 185 volts. During this increase, the ignition voltage of the neon diode 5 is exceeded and the voltage of the pulse line P suddenly drops to the burning voltage of the neon diode 5, after which the voltage increases exponentially again as a result of the charge on the capacitor 7. This pulse occurring on the pulse line P has the effect of a counting pulse, so that the neon diode D, which is conducting at this point in time, goes out and the neon diode in the next circle ignites. As soon as this neon diode has ignited, there is a pulse with a negative sense of direction - on the pulse line P, as already described above, and this pulse extinguishes the neon diode 5. The voltage of the pulse line P then increases exponentially as a result of the charge on the capacitor 4, wherein the ignition voltage of the neon diode 5 is exceeded again - is. In this way 5 counting pulses are generated by the alternating ignition and extinction of the neon diode, which always move the counting circuit to the next position.

The exponential increase in the voltage of the pulse line P after the initial voltage decrease as a result of the ignition, the neon diode -5 is through the time constant of the parallel connection of the resistor 6 and the capacitor 7 determined, where it has proven to be advantageous, the time constant in the The point in time at which the voltage of the pulse line P- increases the ignition voltage the neon diode 13 in the next row circle exceeds .. .._..- _-...... __ ° . -_-. . . In the circuit according to FIG. 2 this is achieved by that a second capacitor 8 via a rectifier diode 9, to the connection point a resistor 10 and a resistor 11, which between the positive terminal of the Voltage source and earth are connected in series, a bias voltage is applied, is connected in parallel to the capacitor 7. As soon as the voltage across the capacitor 7 exceeds the bias voltage, the rectifier diode 9 becomes conductive and decreases the voltage across the parallel connection of capacitors 7 and 8 and the resistor 6 closed, but now with a larger time constant and therefore slower. This measure is made with regard to the ignition delay of the neon diodes. Because it is possible that the voltage of the pulse line P between the time at which the Ignition voltage of the desired neon diode is exceeded, and the point in time in which this neon diode ignites, increases so much that meanwhile with the other neon diodes the ignition voltage is also exceeded, which could also ignite them. To this to prevent, becomes the time constant of the exponential voltage increase of the pulse line P increased at the point in time in which the ignition voltage for the desired neon diode is exceeded, whereby the voltage is temporarily held at this value.

The counting circuit can be switched off by the light signal S of the photosensitive resistor 2 is eliminated. To prevent the If the neon diode D ignited at the time of switch-off goes out, it will be powered Neon diode from the junction of two resistors 12 and 13 between the The positive terminal of the voltage source and earth are connected in series, maintained, wherein the feed circuit further comprises a resistor 14, a rectifier diode 15, the Pulse line P and a resistor R contains. The pulse line P has one such a voltage that the neon diode 5 can not ignite, so that the counting circuit stands still in the last assumed position. The counting circuit can thereby put back in motion that the light-sensitive resistor 2 again a light signal S is supplied.

Claims (3)

Claims: 1. Pulse counting circuit with a chain of parallel-connected Series connections, characterized in that the series connections are each the series connection a light-sensitive resistor and a gas-filled two-electrode tube included, the gas-filled tube optically connected in series with the light-sensitive resistor of the next series connection in the chain is coupled, which series circuits on the side of the photosensitive resistor with a clamp of a voltage source and on the side of the gas-filled tube with one side of a common parallel connection for all series circuits Resistor and a capacitor, the other side of which is connected to the second terminal of the Voltage source is connected, are connected, being the connection point of the photosensitive Resistance and the gas-filled tube of each series connection via a separate one Resistance connected to a common impulse line leading to a source of counting pulses is connected. 2. Counting circuit according to claim 1, characterized in that that the pulse line via a control circuit, which is the series connection of a gas-filled Two-electrode tube and a parallel connection of a capacitor and a resistor contains, is connected to the second terminal of a voltage source. 3. Counting circuit according to claim 2, characterized in that the time constant of the parallel connection of the resistor and the capacitor in the control circuit as a function of the voltage across the capacitor is adjustable. Legacy Patents Considered: German Patent No. 1163 382.