DE2102067A1 - Device for reading data carriers, in particular punched cards - Google Patents

Description

with the card.

A potentially successful solution is the number and positions To detect the holes representing the information consists in the positioning of electrical conductors of the reader on opposite sides of one to be read card or the like. and in detecting a shield hole through an intermediate individual ladders on opposite sides of the card, etc.

Like. Active electrical capacitance formed.

So far are the potential benefits of using punch cards or the like. with perforated electrical shields and capacitive sensing of Shield holes representing information have not been fully recognized since so far in practice inaccuracies and functional difficulties serious Problems with capacitive reading of these cards or the like.

raise with guaranteed accuracy. In particular, so far the functional capabilities and accuracy of capacitive sensing of data holes in punch cards or the like. constructed reader by the presence and the effect of unwanted and parasitic leakage capacitive couplings with adjacent structural parts of the presence and position of individual holes Detecting conductor adversely affected.

When operating the state-of-the-art reader for punch cards or the like. these unwanted and perasitic scattering capacities form a source for false signals and a "noise" that affects the reliable and accurate functioning of the Affect the reader.

The object of the invention is to read data cards or the like. with to Recording of information perforated, electrically conductive shields to propose novel and improved readers, the unwanted and pa- contraption for reading data carriers, in particular punch cards. The invention relates to devices for reading in punch cards or the like. contained information, in particular a Information holes in data carriers with electrical or electrostatic shielding Eriassenden reader for punch cards or the like.

It is already known that the use of data carriers with a thin electrical or electrostatic shield designed to accommodate Punching information selectively has many potential benefits. Usually of one in the card or the like. embedded, thin layer of electrically conductive Electrical shielding material formed can be used to store information in the map or the like. selectively in different positions by means of a punching process or any other preferred alternative method, e.g. photographic etching or the like, punch. By only making a direct electrical connection to each card must be, further increases the likelihood of occurrence of errors as a result bad Verbinrasitisch scattering capacitive couplings between the reading ladder prevents them from reading the cards reliably and accurately or the like. through the capacitive detection of the presence and position of information representing shielding holes, and the on extremely effective and practical way of the state of the capacitive reading technology of punch cards or the like. solves his own problems of noise and false signals in such a way that he Reliably and precisely assign the information recorded in the cards Data processing equipment transmits.

To solve this problem are capacitive in the reader according to the invention output conductors detecting the presence and location of data holes kept a largely constant voltage level in order to prevent the Input signals of the assigned data processing devices by parasitic Stray capacitances generated between the output conductors and neighboring structural parts Noise and unwanted signals are adversely affected. According to the invention becomes the tension of individual capacitive the presence and position of individual Hole detecting output conductors through one between the individual output conductors and voltage stabilizing capacitors connected to the associated output conductors flowing electrical charging current stabilized. The stabilization capacitors are on the input side with outputs assigned to the respective output conductors Amplifiers connected, their inputs connected to the assigned output conductors are. The capacitance of any stabilizing capacitor associated with an individual output conductor and the gain of the associated stabilization amplifier are relative to each other designed so that at one by charging one with the individual output conductor through a hole in the card or the like. capacitive coupled entrance conductor caused the initial voltage change of the output conductor the original Voltage of the output conductor is continuously restored so that the Accuracy of the input signals of the assigned data processing device is not due to unwanted stray capacitances between the output conductors and the neighboring ones Unwanted signals or noise generated by structural parts are impaired.

The associated data processing device is identical to that of the output conductor opposite side of the stabilization capacitor connected.

The invention is illustrated below with reference to one in the drawings exemplary embodiment described in detail. It shows: Fig. 1 a simplified plan view of an embodiment of a reader according to the invention for Punch cards or the like, in which some parts are cut away to the underlying Construction and other components shown schematically and in terms of circuitry to expose; Fig. 2 is an enlarged fragmentary section 2-2 of Fig. 1; Figure 3 is a fragmentary perspective view of the reader of the present invention according to Fig. 1, in the dielectric components of the punch card or the like.

and the reader is omitted to increase clarity and important capacitive connections, the stray capacitances in dashed lines, are shown; Fig. 4 shows a basic electrical circuit for on a larger scale reliable and precise capacitive detection of presence and positions from holes representing recorded information as shown in Figs an embodiment of a reader 10 according to the invention for punch cards or the like. a Grids of individual separate XBrten read conductors 14 and 16 interconnected in capacitive connection.

The conductors 14 consist of a row on one side of one to be read Punch card 18 or the like. positionable, parallel and spaced apart Entrance manager. The conductors 16 consist of a row on the opposite side Side of the punch card to be read 18 positionable, parallel with a distance from one another arranged output conductor oriented transversely to the input conductors 14. It is obviously that between the input conductors 14 and the output conductors 16 a for receiving a punch card to be read 18 or the like. and necessary for isolation or, more desirable, layers of dielectric material with sufficient spacing consists. These dielectric layers simultaneously allow a capacitive coupling between each input conductor 14 and each output conductor 16, which are selectively by a punch card 18 or the like sliding in between.

interrupt.

The typical punch card 18 to be read consists of a thin layer 20 electrically conductive material that, when the card 18 is between the input conductors 14 and the output conductors 16 is arranged for reading, the capacitive coupling interrupts between individual input conductors 14 and individual output conductors 16, However, with the exception of those places where the capacitive coupling is more individual Input conductor 14 with individual output conductors 16 through in the electrically conductive Layer 20 formed opposed to one another selectively capacitively with one another to be connected Share the input conductor 14 and the output conductor 16 aligned holes 22 is specifically selectively created.

The electrically conductive layer 20 is also called "electrical" for the sake of simplicity Shielding "or" electrostatic shielding "called.

According to the known information recording and reproducing technique with the help of punch cards or the like.

this type represent the number and positions of those in the Shielding 20 formed holes 22 the coded recorded and described on the Type of information to be displayed.

According to the invention it is assumed that the holes 22 of the shield Selectively manufacture 20 in any preferred manner deemed advantageous let, e.g.

by stamping, photographic etching, or other processes.

1 and 2, the thin electrically conductive shield 20 is of the card 18 onto a paper dielectric base layer 24 of the card 18 piled up.

Depending on the manufacturing method of the holes 22 in the Shield 20, holes 22 may or may not extend through base layer 24 through the base layer 24.

In the illustration of FIGS. 1 and 2, the card 18 is oriented so that the base layer 24 lies on the output conductors 16 and thus an electrical Insulator between the output conductors 16 and the electrical or electrostatic Shield 20 forms. To isolate the input conductor 14 from the shield 20, the reader 10 of FIGS. 1 and 2 has one between the row of input conductors 14 and the shield 20 arranged layer 26 of dielectric material. the The thickness of the dielectric layer 26 is limited to the provided capacitive connection between the input conductors 14 and the output conductors 16 favor by keeping them physically close relative to one another at opposite one another Sides of the thin holes which are electrically encoded by information 22 perforated shield 20 are arranged.

The between each input conductor 14 and each output conductor 16 through the geometric relation of the input conductors 14 to the output conductors 16 is given and capacitive through individual input conductors 14 with individual output conductors 16 connecting iiividual holes 22 of the shield 20 produced electrical Capacities are shown in solid lines in FIG. 3 by symbols of electrical capacitors 28 shown.

As already mentioned, the entrance manager is usually individual 14 with individual output conductors 16 connecting electrical capacitance 28 with Exception at the places where the electrical shielding is pushed in between 20 of the card to be read 18 interrupted, where the holes 22 of the shield 20 with intersecting parts of an individual input conductor 14 and one individual output conductor 16 are aligned. According to Fig. 1 and 3 is the electrical Shielding 20 of the card 18 preferably via a contact 30 to earth or ground.

According to FIGS. 1, 2 and 3, the places where the shield are located 20 for recording information can be punched in with the associated Output conductors 16 aligned longitudinal rows and conductors with the associated input 14 aligned transverse split, as from the holes partially shown in FIG 22 can be seen.

To read a card 18, the 3 input conductors 14 in any desired, set in one of FIGS. 1 and 3 in the reader 10, the prior art input control unit 32 programmable sequence activated briefly. The activation of an input conductor 14 usually consists in the Applying a voltage to the input conductor 14 so that it temporarily has a other than its normal tension assumes. The presence and position of each with the special activated input conductor 14 aligned information recording holes 22 of the shield 20 is captured by the output conductors 16. As already mentioned is activated by the presence of one with a special input conductor 14 and a special output conductor 16 aligned hole 22 of this particular Input conductor 14 with this special output conductor 16 according to FIGS. 2 and 3 through the capacitance 28 connected. Accordingly, the change in voltage causes any particular, activated input conductor 14 a voltage change each through a hole 22 of the Shield 20 output conductor capacitively connected to the activated input conductor 14 16.

The number of times that a particular input conductor has been activated 14 output conductor 16 which is subject to a voltage change is dependent on the number of on the one hand with the special, activated input conductor 14 and on the other hand with the individual Auegangleiters 16 aligned shielding holes 22 between zero and all output conductors 16.

It therefore seems easy, the result of an activation of a special Input conductor 14 occurring voltage changes of the individual output conductor 16 to determine and thereby the number and position of all through with the activated Input conductor 14 aligned holes 22 to determine recorded information.

This attempt that appears logical and practicable was however, so far accompanied by serious problems of a practical nature that the commercial use containing electrical shielding and for capacitive use Detection of information representing holes of suitable punch cards is limited or have prevented.

In this context it should be noted that there are practical limitations of capacitance 28, through a hole 22 an individual input conductor with a individual output conductor 16 connects, due to practical limitations the size of the hole 22 exist. The limitation of the hole size results from the Necessity on a practical size punch card an appreciable number of To accommodate longitudinal rows and transverse columns of holes.

Due to these practical conditions, one is the exit conductor 16 through a hole 22 with an input conductor 14 connecting capacitance 28 extreme limited.

At the same time, however, due to the finitely close, parallel relation the output conductor 16 to each other, each output conductor 16 capacitively with each adjacent one Exit ladder 16 and, to a decreasing extent, ße with all other kasgangladders 16 tied together. The capacitive connection of each output conductor 16 with each directly adjacent output conductor 16 is represented in FIG. 3 by a symbolic capacitance 34. A significant capacitive connection of each output conductor 16 to each more distant one Output conductor 16 does exist, it is Pig. s, however, for reasons of clarity not shown.

Furthermore, each output conductor 14 is capacitive with the shield layer 20 of the card 18 connected to which all output conductors lo are capacitively connected. The capacitive connection of each output conductor 16 to the Shielding layer 20 as a whole results from the finite arrangement of the output conductors 16 relative to shield layer 20; it is shown in Fig. 3 by in dashed lines symbolized capacities 36.

So far succumb to voltage changes to detect the presence and the location of holes in cards of the type described serving exit conductors 16 responsive data processing equipment often deceptions and other functional Problems including inaccuracies and unreliability that result from unwanted Signals and the noise arise. The unwanted signals and the noise arise in the readers according to the prior art by voltage increases in various capacitive through the shielding holes 22 not only with individual input conductors 14 but also with other output conductors 16 and with neighboring, directly output conductors connected to structural parts subject to changing voltage changes 16.

As already mentioned, practical problems of this kind have their place capacitive to read punch cards or the like.

of the type described complicated and prevented. This the state Appropriate to the technology, complicating a perfect function of the punch card reader of this kind and debilitating operational problems are avoided in the reader 10 of the present invention solved by the fact that the voltage of each output conductor 16 is continuously on its normal value is stabilized even if the output conductor 16 passes through a Shielding hole 22 is capacitively connected to an activated input conductor 14. The desired stabilization of the voltage of each output conductor 16 at its normal Value is assigned to the respective output conductors 16 by several according to FIGS. 1, 3 and 4 Voltage stabilization units 40 carried out. Each stabilization unit 40 has a voltage stabilizing Capacitor 42, whose Output 44 with the associated output conductor 16 and its input 46 with the Output 48 of a voltage stabilization amplifier 50 according to FIG. 4 is connected. The amplifier 50 is characterized by a high voltage gain and a high input impedance. The input 52 of each amplifier 50 is associated with the Output conductor 16 and thus with the output side 44 of the associated stabilization capacitor 42 connected.

The one typical output conductor 16 through a shield hole 22 Capacitance 28 connecting to input conductor 14 may, for example, be approximately 1.5 x 10-13F be. Each stabilization capacitor connected to an output conductor 16 42 is designed so that its capacitance of the connection capacitance 28 of the conductor corresponds to, or is only a small multiple of the assigned capacitance 28. In the example already mentioned, each stabilization capacitor 42 advantageously has a capacity of approximately 5 x 10-13 F.

Fig. 4 shows an exemplary embodiment of the circuit of the characterized by a high input impedance and a high voltage gain Stabilization amplifier 50. The one connected to the associated output conductor 16 Input 52 of amplifier 50 is connected to a gate 54 of a g-channel field effect transistor 56, e.g. an MPF-105 transistor. The source 58 of transistor 56 is connected to a +3 V source 60 connected. The drain 61 of the transistor 56 is connected to the base 62 of a second transistor 64, e.g., a 2 N 4125 transistor. The collector 66 of the transistor 64 is connected to ground or to ground and the emitter 68 of the transistor 64 is connected to the emitter 70 of a similar transistor 72, e.g. also one 2 N 4125 transistors.

The collector 74 of the transistor 72 is connected to the output 48 of the amplifier 5C connected. The output 48 of the amplifier 50 is like already mentioned connected to the input 46 of the stabilization capacitor 42.

To source 61 of transistor 56 and base 62 of transistor 64 is connected to a +12 V source 76 via a 6000 ohm resistor 78. The +12 V source 78 is also connected to emitters 68 and through a 2000 ohm resistor 80 70 of transistors 64 and 72 are connected. A +6 V source 82 is with base 84 of transistor 72 while connected to collector 74 of transistor 72 via a 4000 ohm resistor 88 is connected to a -6 V source 86.

Each stabilization amplifier 54 is preferably by means of one of the Output 48 with the input 52 of the amplifier 50 connecting resistor 90 stabilized.

The stabilization resistor 90 has a very high electrical level Resistance, e.g. 2 x 107 ohms. However, this is the input impedance of the typical voltage stabilization amplifier 50 significantly greater than the impedance of the stabilization resistor 90, whereby the static voltages of input 52 and output 48 of the amplifier 50 are always largely the same.

If desired, the voltage of the voltage source 60 can be customized set for each amplifier 50 to match the particular one used in amplifier 50 N-channel field effect transistor 56 to compensate for its own deviations from the design value and thereby the equality of the static voltage between the output 48 and the Ensure input 52 of amplifier 50.

In most cases, however, it is not necessary to reduce the tension of voltage source 60 to adjust the input and output voltage of the amplifier 50 to match each other, since only pulses of short duration from the amplifier 50 are transmitted and from the amplifier 50 to the input 64 of the associated Stabilization capacitor 42 transmitted voltage, as later described is detected by a clutch capacitor 92.

In relation to the example described, the voltage of a special input conductor 14 activated by the control unit 32 by 10 V opposite which is normally present on all input conductors 14 from the control unit 52 Change tension. For each through a shielding hole 22 with the special one a voltage difference of 10 V activated input conductor 14 connected output conductor 16, the reader 10 generates the associated stabilization capacitor 42 at the input 46 a voltage change of 3 V. These operating characteristics are only exemplary here described.

At the same time, the change at the input 46 of the stabilization capacitor 42 pending voltage due to the capacitive coupling of the assigned output conductor 16 through a hole 22 with an activated input conductor 14. The stabilization capacitor 42 stops under the influence of the electrostatic pressure of the changed at the entrance 46 of the capacitor 42 applied voltage largely the normal voltage of the associated Output conductor 16 upright. In this context it should be noted that the assigned Stabilization amplifier 50 for an initial change in the voltage of the output conductor 16 injected to provide sufficient electrostatic pressure over the associated Exercise stabilization capacitor 42, as desired, the associated output conductor 16 largely at its normal voltage level. The effective function values the voltage stabilization amplifier 50 and the voltage stabilization capacitor 42 are selectively designed for this purpose, as already described.

By having each output conductor 16 throughout the life of one special input conductor 14 assigned Holes 22 largely is held at its normal voltage level will affect the output conductors 16 connecting unwanted stray capacitances 34 and 36 the reliable and exact detection of the holes 22 is not possible.

It should also be noted that the transition or delay3 time between the presence of an activation voltage on an input conductor 14 and the resulting voltage change at input 46 each with a Stabilization capacitor 42 connected to the output conductor 16 sensing hole 22 with a magnitude of 20 x 1Q 9sec. in relation to other comparable Time intervals is very short. After the assigned stabilization amplifier 56 quickly to restore the largely normal voltage level the active output conductor 16 required voltage change at the input 46 of the associated stabilization capacitor 42 has caused the output voltage sounds of the associated stabilization reinforcement 50 as a result of leakage via the stabilization resistance qO slowly decreases again. In the design data used in the example for the individual Components, the decay time is in the order of 10 000 x 10 9 seconds. However, this decay process has no consequences, since the time interval for activation of each input conductor 14 and for completely capturing the Om individual input conductor 14 associated holes 22 to a range of 100 to 1000 x 1Q 9 sec. Limited is. That is, the reading operation has long been completed when the voltage subsides at the input 46 of the stabilization capacitor 42 assumes significant amounts.

As a result of the transition field effect transceivers own high input impedance of the transistor 56 of the individual stabilization amplifier 50, however, the resistor 90 stabilizing the individual amplifier 50 essential have higher resistance values than those given in the example. As a result of which it turns out it proves practical to set the individual input conductors 14 at individual time intervals to be activated with a duration of considerably longer than 1 000 x 10 9 sec. the Ability of the reader 10 such longer intervals of activation of the input Processing ladder 10 ensures sufficient time for the switching operations to run in that of the input conductors 14, the shield 20 and the output conductors 16 existing information matrix before the stabilization amplifiers 50 on the voltages acting on the individual stabilization capacitors 42 are detected, the number and position of the activated input conductor 1 assigned To determine shielding holes 22.

In the manner described, selectively on the inputs 46 of the stabilization capacitors 42 acting and an activated input conductor 14 associated shielding holes The voltages representing 22 are transmitted to data processing equipment94, which have suitable means to the represented by the holes 22 Information useful to store, transmit, tabulate or on any desired type to process. According to FIG. 4, the inputs 46 are the respective Stabilization capacitors 42 via individual coupling capacitors' 92 with the data processing devices 94 are connected.

By suppressing and effectively eliminating the disruptive consequences the described unwanted stray capacities and the disruptive, the operation of the Prior art according to readers of this type of accompanying noise is made possible by the invention Reader enables the reliable and exact detection of minimized shielding holes 22.

Minimizing the size of the individual shielding holes 22 is through a strong reduction in to achieve a reliable and accurate Operation of the reader according to the invention required coupling capacity 28 between an individual input conductor 14 and an individual output conductor 16 enables. It is obvious that the invention with a reliable and accurately detecting the presence of holes 22 compatible reduction in size of the shielding holes 22 the arrangement of a larger number of holes 22 in a card or the like. of a given size or, conversely, a reduction in accommodation a given number of holes 22 required card size or the like.

enables. Depending on your needs, the basic advantage of Holes of reduced size easily either by taking advantage of the larger ones made possible Number of holes by accommodating more information in one map or the like. given size or by reducing the map or the like. on the for Accommodation of a given amount of information required size or else take advantage of both approaches economically.

It is obvious that the capacitive reader according to the invention also in connection with other information in the form of holes in an electrical Shield containing data carriers can be used as punch cards.

The invention consists in the following: A reader for punched cards or the like. has several on one side of a punch card or the like. with an electric shielding layer positionable input conductor and several on the opposite Side of the punch card or the like. such positionable output conductor that between the Output ladders and the input ladders through recorded information holes in the electrically shielding layer representing a capacitive Connection is established. Several voltage stabilizing capacitors are included their outputs are connected to assigned output conductors. Multiple voltage stabilization amplifiers are with their inputs with assigned output conductors and with their outputs connected to the inputs of the associated stabilization capacitors.

Data processing equipment connected to the input of each stabilization capacitor record the when an input conductor is activated, with which the assigned Output conductor capacitive through a hole in the electrically shielding layer is connected, from the associated stabilization amplifier at the input of the stabilization capacitor generated voltage change. The capacitance of each stabilization capacitor and the Gain Each stabilization amplifier will work together at an initial one Voltage change on the assigned output conductor a continuous recovery of the original voltage level of the output conductor, so that the accuracy of the Input signals of the data processing devices are not caused by unwanted stray capacitances between the exit ladders and adjacent structures.

Claims (2)

Claims Device for reading data carriers that are in one of the recorded Patterns representing information are perforated and an electrical shielding layer have, wherein the device has a plurality of activatable, in the longitudinal direction of the data carrier has arranged input conductors and several output conductors assigned to them, between which there is a capacitive coupling, which is created by the interposition of a the data carrier having the shielding layer can be interrupted at the points at which the shielding layer is free of holes representing the data, thereby characterized in that the outputs (44) of a number of voltage stabilization capacitors (42) are each connected to an output conductor (16); that the inputs (52) a number of voltage stabilization amplifiers (40) each associated with one Output conductor (16) and the outputs (48) of the amplifier (40) to the inputs (46) the associated voltage stabilization capacitors (42) are connected; that the voltage stabilization amplifier assigned in each case to an output conductor (16) (40) and voltage stabilization capacitors (42) with regard to amplification or Capacity are matched to one another in such a way that they - resolved by the activation an input conductor (14) which is capacitive via a hole (22) in the shielding layer (20) can be coupled to an output conductor (16) - an extensive restoration the original voltage of the output conductor (16) cause a voF amplifier (40) the voltage change reaching the capacitor (42) creates a flow of electrical energy Charges between the capacitor (42) and the Output conductor (16) induced; and that a downstream data processing device (94) on the when activated individually, through the holes (22) capacitively with the output conductors (16) connected input conductor (14) from the associated amplifier (40) to the input (46) of the associated capacitor (42) respond to the voltage change transmitted. 2. Apparatus according to claim 1, characterized in that each Voltage stabilization amplifier (40) a high voltage gain and a has high input resistance.