DE2320574A1 - READER FOR CARD-SHAPED DATA MEDIA, IN PARTICULAR IDENTIFICATION CARDS - Google Patents

Description

Reader for card-shaped data carriers, in particular identity cards or the like.

The invention relates to a reading device for static scanning and evaluation of card-shaped data carriers, in particular ID cards or the like., containing coded information consisting of several data fields Coding field are occupied, with a reading head that scans the code field.

The data fields on the data carrier are shown below for the sake of simplicity referred to as a map, are as zones of changeable conductivity, permeability or dielectric constant.

For reading the coded cards, especially ID cards for banks, Companies, authorities or the like, it has been customary or necessary to present the identification card to move past the read head of the reader when reading data. This reading method leads often to reading errors. Another disadvantage is that the reading result can possibly be falsified by manipulation during the reading process.

On the other hand, it is for other data carriers such as punch cards or the like. already known, for example through contacts statically to be scanned.

The invention is based on the object of a static reading to create a reading device suitable for identification cards in particular, which with relative simple structure and small external dimensions, regardless of the direction of insertion the ID card works against the device and is easy to manipulate and is fail-safe is to use.

According to the invention, this object is achieved by aass that in lines and column-divided coding field of the card to be read on one card side a generator scanning head with an active probe for each data field and on the on the other side of the card a receiver scanning head with a passive probe for each Data field opposite is assigned that the active probes according to lines or Columns are interconnected in groups and by a pulse generator in groups A decoder is used to control the passive probes with a time delay like the active ones in groups, but connected together in opposite directions according to columns or rows and each group is assigned an amplifier 7tl =, whose output is above each a vog strobe pulse of the generator controlled memory flip-flop with a Input of a multiplexer is connected, which generates data output signals.

by means of this circuit, the air-core coils can be used Probes are advantageously controlled only briefly and one after the other without this despite the relatively small distances between adjacent probes Shielding is required. The device is therefore very interference-free. aside from that the power consumption is low because the generator coils each only briefly can be controlled.

In the case of capacitive interrogation of the data field, probes are used instead to provide capacitively effective elements of coils, Advantageously can, as is known per se with dynamically operating card readers, three additional Lagekennfe: which are scanned on the map by two additional probes, which control the counter and the multiplexer in such a way that the scanning of the data fields automatically always in the correct order regardless of the insertion position he follows.

According to a further proposal of the invention is at the rear end of the Receiving slot provided a scanning switch actuatable by the card, the on the one hand triggers the reading process and on the other hand a magnetic card ejector which automatically ejects the card after the reading process.

Further features according to the invention are characterized by the subclaims and below with reference to a preferred embodiment shown in the drawing explained in more detail. 1 shows an overall perspective view of the card reading device with data card, rig. 2 shows a vertical section through the device according to FIGS. 1, 3 a perspective individual representation of a scanning head of the device according to Fig. 2, Pig. 4 an exploded view with details of the device according to FIG. 2, FIG. 4a an enlarged sectional view of the arranged at the end of the card slot Ejector magnets, 5 shows a schematic representation of a coding field the data card according to FIG. 1, FIGS. 6 and 7 each have a schematic representation of the coil arrangements of the generator and receiver scanning heads according to FIG. 2, Sig. 8 the schematic circuit diagram of the generator scanning head, Fig. 99 is the schematic circuit diagram of the receiver scanning head, Fig. 10 circuit diagram of a receiver amplifier for the circuit arrangement according to Fig. 9 and 11 pulse diagram of the entire circuit arrangement.

The reader shown in perspective in Fig. 1 has a housing ' 100 with a front card funnel 31 for receiving a data card K, for example an ID card containing coded information. The information is located in the present exemplary embodiment in a coding field with a number of Data fields F, which can be changed in their conductivity, are available in a total of thirteen Columns and five rows I - V are subdivided (see Fig. 5). In addition to the first column two position maps a and b, and behind the last column a position map c arranged.

Like a vertical section through the reader in Pig. 2 shows is located located below the slot for loading through the card funnel 31 the data card K has a generator scanning head 37 and above this slot a receiver scanning head 38. Each scanning head 37 and 38 contains one for each data field F of the card K Generator coil 60 or a receiver coil 61. All generator and receiver coils 60 and 61 are potted with a potting compound to form a unit and mechanically as well as electrically with one liter plate 32 each for a generator circuit or one PCB 33 for a Receiver circuit connected. The generator and receiver circuits are described in detail below.

The receiver scanning head 38 is shown in perspective and partially in FIG shown broken. 4 shows both scanning heads 37 and 38 in an exploded manner Depiction.

At the rear end of the slot for the data card is partially An ejector magnet 35 protruding from the housing 100 is provided, which holds the card K automatically ejects after completion of the reading process. The ejector magnet 35 has an under the action of a spring armature 36, which is energized IlAgneten held in its retracted position and when the magnet is de-energized by the tensioned spring is brought into its starting position.

Above the ejector magnet 35 is a connector 34 for generated output signals of the reader provided.

The housing 100 itself is made in a structurally very simple manner a two-part cover 28, a Frotflansch 29 and a rear flange 3G formed.

From Fig. 4 it can be seen that the generator coils 60 for the five lines 1 - V of each column are combined with a generator coil strip 42 and are electrically connected in series.

The coil bar 42 is attached to a support plate 41 and has a generator coil connection 43., Deviating from the generator scanning head 37 are at Receiver scan head 38 includes the thirteen receiver coils 61 of each row I-V, respectively combined with a common receiver coil strip 59 and electrically in Switched in series. The plug contact 44 serves as the connection. The different types of circuit the generator coils 60 opposite the receiver coils 61 is shown in FIGS. 6 and 7 illusory.

There are two spacer bars between the two scanning heads 37 and 38 47, which form the slot for the K data card. The electric Connection between the scanning heads 37 and 38 takes place via plugs 45 and sockets 46.

The one provided at the end of the receiving slot for the data card K. Ejector magnet has a limit switch S / S ', which by means of the inserted Data card is operable.

- The circuit of the reading device is described below with reference to FIG. 8 - described in detail: by means of one made of one capacitor C 11 and a resistor R 15 existing oscillator 51 are square-wave pulses with a period of approx. 100 / us with a duty cycle of approx. 1: 1 (line a in Fig. 11). These square-wave pulses are made up of a differentiator 52 of a capacitor C 10, a resistor R 14 and a Schmitt trigger 26 in short square pulses transformed (Z. b in Fig.11). These short square pulses control the strobe input of a decoder on the one hand via a NAND gate 28 and 29 14 and, on the other hand, with their positive rise times via the RC element with capacitor a 12 and resistor R 16 a Schmitt trigger, the output of which is the pulse train c in 11 supplies, -the means of an inverter 24 in the strobe 1 signal.

according to line e in Fig. 11 converted for the receiver circuit of the device will. At the same time, the output of the gate 25 is a driver 54 of the generator 50 controlled. This driver consists of an input capacitor a 8, a Leak resistance R 17, a first transistor T 6, one for the positive supply voltage leading resistor R 18 and a final transistor T 7. Furthermore, it is connected to the collector of the transistor T 6 via a capacitor C 9 with bleeder resistor R 16, the base of a transistor T 8 connected, its emitter to ground and its collector Voltage- connected to the positive pole of the supply via a resistor R 9 is.

With the emitter of the transistor 2 7 are two connected in series position identification coils A and B of the generator connected, ..

to which the pulses d according to FIG. 11 are fed and those of the scanning the identification fields a and b of the data card K are used.

At the collector of the transistor T 8 - controlled by the trailing edge of the control pulse from T 7 - the strobe-2 signal according to f in Fig. 11 for the receiver circuit (Fig. 8) won.

The very short square-wave pulses generated by the differentiating element 52 preferably have a duty ratio of 1 1: 100, so that the recipient has a low power consumption and its components are only slightly thermally stressed. In addition, optimal immunity to interference is achieved in that the receiver circuit each only for 0.4 sec.

is strobed or activated per scanning period.

Due to the time offset in the control of transistor 2 7 compared to the control of the strobe input of the decoder (gate 29) is reached, that the coil groups, which are geometrically very close together, are used for position identification Ä and B and the first column cannot interfere with each other. Furthermore, due to the pulse control of the decoder 14 achieved that to a certain Time only one group responsible for one of the thirteen columns of generator coils 60 is in operation. In this way, the individual coil groups can be put together very closely without special shielding measures, without each other disturb. On the other hand, the unshielded and therefore relatively large Stray field of the generator coils 60 designed as air coils achieved that to the mechanical tolerances regarding the deviation between the axes of the generator and receiver coils no special requirements have to be made.

All generator coil groups are connected via a resistor R t7, whose resistance is large compared to the inductive coil resistance with the operating voltage source tied together; This arrangement and dimensioning ensures uniform, steep and Rising edges independent of the coil tolerances, so that also those in the receiver coils 61 induced voltages lie within relatively tight tolerances and are uniform Have pulse shape and size. By one consisting of capacitor C 13 and choke Dr Filter element, interference pulses v:, Qn are kept away from the operating voltage source The circuit arrangement has the following mode of operation: If there is no data card K in the reader, the S / S 'switch is in the rest position. Via the NAND gate 22 and 20, a 4-bit counter 15 is held in its zero position.

A corresponding decoder output is generated via NAND gates' 17 and 18 a zero signal at the output of the reader. Is by an inserted data card When the switch S / S 'is actuated, the reset signal from the counter 15 disappears. At the same time, via a transistor circuit shown separately in FIG. 9, the Ejector magnet 13 energized. This transistor circuit consists of a transistor T 4 with resistor R 8, resistor R 9 and a diode D 1, Perner is the coil of the ejector magnet 13 is bridged by a further diode D, 2.

As long as the ejector magnet 13 is excited, it holds the armature 36 against the action of the spring and actuates the switch 5 so that the card remains in the reader and the reading process can take place. With each pulse at the clock input, a NAND gate 19, a capacitor C 4, a resistor R 10 and a NAND gate 16 emitted a narrow clock pulse to the counter 15 and this by one position forwarded. Depending on whether the position identification coil A 'excites the receiver circuit is or not, whereby it is determined whether the card K with column 13 or column 1 ahead in the card funnel 31 was inserted, the counting direction of the counter 15 switched to forward or backward3 and thus achieved that the coded information of the data card K always in the correct order, i.e. starting with column 1 is read.

When the counter setting (1 or 15) starts with the first cycle f: oX by means of an additional input circuit shown in FIG. 9, consisting of gates 7,8,9,10,11 and 12, depending on the receiver input A ', a block start signal generated, which, for example, can be used to enter additional Data outside of the map information allowed. The same happens as an end-of-block signal at the last counter setting (15th cycle). With such a reader it is expedient to use a counter whose capacity is three positions larger than the number of columns to be read.

By means of a feedback branch from the decoder outputs 0, 1 and 15 via the gates 28 and 29 to the strobe input of the decoder 14 is reached, that the output signals 0, 1 and 15 do not have the pulse shape of the control signals at the output of gate 26, but are present as DC voltage.

With the help of RO combinations R11 / C5, R12 / C6 acting as low-pass filters and R13 / C7 short interference pulses are kept away from the counter inputs.

Depending on the coding on the data card K, the Interconnected receiver coils 61 excite and control one per coil group downstream amplifier 1. These amplifiers consist of the two stages with the transistors T1 and T2, which are alternately coupled via the capacitor C2 are. The amplifier stage with transistor T1, base series resistor R1 and working resistor R2 in the collector circuit is controlled via a capacitor C1. In the collector circuit of second transistor C2, whose base voltage is generated with the voltage divider R3 ,, R4 is, lies: the resistor R5. At the output of the fransistor T2 is via the capacitor C3 the,? NP transistor T3 coupled, its emitter directly and its base via the resistor R7 to the positive pole of the supply voltage source and its Collector is connected to the base of transistor T2 through resistor R6.

As soon as a negative input pulse on capacitor C1 the voltage swing at the collector of T2 is the size of the base-emitter voltage of the transistor T3 is exceeded, this is switched through and also switches the transistor via R6 T2 fully through, so that a square pulse is produced at its output, the width of which is im is essentially determined by C3 and R7. This impulse is broader than @@@ @@@@@@ the control pulse on the generator coils and the associated strobe pulse.

At the output of each amplifier 1 is one input of a memory flip-flop 2 connected, so that these flip-flops each at the strobe time on the reading heads Accept pending information.

The memory flip-flops at the outputs of the memory flip-flops assigned to lines I - V 2 pending information is sent via a multiplexer and gate 4 tiplexer 3 / to data outputs I ', II', III ', IV' or V 'of the reader passed on. Depending on whether the receiver coil B 'is excited or not, the information is changed from I to I', II to II ', etc. or from I to V ', II to IV' IV to II 'resp.

V 'passed to I'. In this way it is achieved that independently from the insertion position of the data card K, the lines of the card always have the correct data outputs are assignedw A clock Ti (Fig.8 and 9) controls the gate 4 and a pulp input of the multiplexer 3, so that the data are only available at the data outputs when the input clock H-potential leads. Is the pulse width of the input clock is large compared to the period of the oscillator 51, so is even when the counter is incremented, always a complete, the new counter position corresponding information at the data outputs.

When the brushing process is complete, the application of H potential to the Input "card ejectors (Fig.9) the transistor 14 is blocked and thus the ejector magnet 13 de-energized. Thus, the spring of the armature 36 can eject the inserted data card K. At the same time, the switch S / S 'jumps back into its rest position.

The reader device according to the invention is designed in its structure so that it can be adapted to different card formats in a very simple manner. For this purpose, the spacer strips 47, which are between the receiver and generator plates 87 and 38 are located, designed to be exchangeable. Different by use dimensioned spacer strips 47 can be the receiving slot for the data card K change in its dimensions. Furthermore, since the distance afford 47 optionally to the Long and transverse sides of the generator and receiver plates can be attached, can the reader according to the invention can also be set up in such a way that the cards e.g. can be inserted.

Likewise, the ejector magnet 36 can optionally be on the longitudinal or transverse side assign the receiving slot, its anchor 36 against anchors of other dimensions is also designed to be exchangeable.

Claims (1)

Patent claims Reader for static scanning and evaluation of card-shaped Data carriers, in particular ID cards or the like. Which contain one of several data fields existing and coded information containing coding field are occupied with a reading head scanning the coding field, characterized in that the in lines and coding field of the card to be read (K) divided into columns on one card side a generator scanning head (57) each with an active probe (60) for each: data field () and on the other side a receiver scanning head (38) with a passive one Probe (61) for each data field is assigned opposite that the active one Probes (60) are interconnected in groups by rows or columns and by a pulse generator (50) offset in time in groups via a decoder (14) be controlled that the passive probes (61) like the active in groups, however oppositely connected according to columns or rows and each group ker (1) is assigned, the output of which is controlled by a strobe pulse from the generator Memory flip-flop (2) is connected to one input of a multiplexer (3) which Data output signals (I '...) generated. 2, reading device according to claim 1, characterized in that the probes (60,61) are designed as coils, preferably as air coils. 3. Reader according to claim 1, characterized in that the probes are designed as capacitive elements. 4. Reading device according to one of the preceding claims, characterized in that that the additional probes (A, B, A ', B') for the position identification of the data carrier (K), which is equipped with corresponding position maps (a, b) are provided, which generate a signal causing the counter (15) to run down, so that at With the data carrier (K) inserted the other way round, the data is read in the opposite direction takes place, or which switch the multiplexer (3) so that regardless of the Insertion position of the data card (K) whose lines are assigned to the corresponding data outputs 5. Reading device according to at least one of the preceding claims, characterized by a magnetic card ejector (13) with an electromagnet, whose of the inserted card (K) axially displaceable against the action of a spring Armature (36) in its end position a card scanning switch (S, S ') operated from which excited magnet held for the duration of the reading process and then is brought into its other end position by the pretensioned spring. 6. Reader according to claim 5, characterized in that the ejector magnet (13) in the circuit of an amplifier circuit controllable by a card ejector signal (T4) is arranged. 7. Reading device according to at least one of the preceding claims, characterized characterized in that the inputs of the counter (15) filter elements in the form of RC combinations (e.g. 3. C6, R12) are connected upstream. 8. Reading device according to one of the preceding claims, characterized in that that the capacity of the counter (15) is three greater than the number to be read Columns or rows is. 9. reading device according to claim 1, characterized in that the active Probes (60) and the passive probes (61) each with a plate-shaped scanning head (37 and 38) are structurally combined. 10. reading device nach'Anspruch 9, characterized in that the probes (60 or 61) of the scanning heads each with a plastic compound to form a unit are shed. 11. Reading device according to claim 9 and 10, characterized in that between the scanning heads (37,38) on their lateral edges spacer strips (47) are arranged so that a card slot is formed between them. 12. Reading device according to claim 9, 10 or 11, characterized in that that the plates (32, 33) supporting the generator and receiver circuit are below or are arranged above the scanning heads (37, 38) and all components are electrical and mechanically by means of detachable plug-in couplings or the like. are connectable to each other. 13. reader according to claim 11 or 12, marked by interchangeable Spacer bars (47) and / or ejector magnet armatures (36) of different dimensions, wherein spacer strips (47) on all four edges of the scanning heads (37, 38) for adaptation the device can be attached to various card formats as required, 'd. L e r s e i t e