DE4221305A1 - Card-shaped information provider and its use - Google Patents

Abstract

A card-shaped information carrier has an induction strip (4) with an induction loop (1) arranged in the plane of the card and within which is inserted a magnetizable material (3).

Description

The innovation concerns a card-shaped information provider for the transfer and storage of data. Different Designs of magnetic cards and chip cards are in the form of Plastic cards known, being single and multi-lane Magnetic strips made of magnetizable materials, such as Metal powder materials are used. Likewise, in Chip cards integrated microchips and flat coils to contactless data transfers in a close range of a perform electromagnetic field of a reader.

The innovation affects one as an induction strip executed magnetic stripes for transmission and storage of data. One such as an induction strip In its simplest version, magnetic stripes consist of one often subdivided metal layer made of magnetizable Materials with embedded meandering Induction coil. The induction strip is in one Carrier layer made of flexible plastic or upset.

Such an induction strip is easy in the Manufacture because the metal layer and the induction coil in are arranged on a single level, and therefore none Vias become necessary. The induction strip can also be used with conventional magnetic card readers described and read, the information in  magnetizable material, especially if it is made of hard magnetic material exists, is retained.

The is suitable for a short-circuited induction coil Induction strips for example as security stickers for Goods or objects in shops, museums and the like. the like Facilities, which can be made very small and on the back by means of an applied adhesive layer securing goods in the sense of theft protection in inconspicuous Way is attached, or is integrated into price stickers. Security systems for goods with short-circuited coils need one at a passage point in the goods store Alarm transmitter, which essentially consists of one as a transmitter executed oscillator exists. Will a short circuit coil in brought the area of the high frequency field of the oscillator, the short-circuit coil dampens the oscillator in particular when the oscillator and the short-circuit coil resonate occur because it induces an induction that Oscillator drains energy. This will make its energy release measured, and an alarm triggered if necessary.

In the embodiment of the induction strip according to the invention with short-circuit coil high sensitivities are achieved because in a high-frequency field the induction coil the supplied Energy of the transmitter in the magnetizable material dissipates and there are eddy current losses, resulting in a high damping of the excitation field is achieved. Through targeted Choice of the magnetizable material, for example with soft or hard magnetic properties and combinations from this, as well as its spatial arrangement and its volume, the damping properties can be changed. Furthermore, the turns of the induction coil form Coupling capacities, so that by choosing the distances between the turns, the properties of the resonant circuit,  especially its resonance frequency in a wide range is determined. A decrease in the resonance frequency from GHz range in the MHz and kHz range therefore means one Simplification of the circuitry for transmitters with Air coils in the GHz range and thus a saving of Costs. Due to the increased sensitivity, the Distance to a transmitter can be increased.

Such an induction strip is also used for Identification of goods as in the magnetizable Metal layer information about goods, such as prices and Delivery dates and Like. Saved by means of a magnetic head and also can be read out. The induction strip has on a place, for example in the short circuit turn Predetermined breaking point with very thin conductor track. The cancellation an induction strip described with information takes place in a simple manner in a radio frequency field defined performance, whereby the data is short-circuited Induction coil extinguished by an induced swirl field and the predetermined breaking point is destroyed with increased performance becomes.

Another option is to attach the induction coil a microchip integrated in the carrier layer to connect, which takes over several functions. In one Security system for goods can be the chip as a short circuit be programmed, which results in the aforementioned mode of operation is still guaranteed. On the other hand, the chip is used for Identification of goods and objects by the data in the chip can be programmed, the amount of data only is limited to the execution of the memory in the chip. The Information is provided via the induction strips in the Microchip saved and read out again. If those Chip card the size of a credit card in the traditional sense  has, the data transfer with known readers for Magnetic cards provided.

Another big advantage is that it doesn't the magnetic card with a specific one is required Pulling speed through the reader because the Data transmission both when you swipe the card and with the card stationary. By arranging the Induction coil and the magnetizable layer arise at Current flow through the coil at all boundary layers of Induction coil and metal layer vertical stray fields, causing an induction voltage in a reading magnetic head, is also caused when it stops. With that, in bidirectional direction, i.e. from a writing direction Magnetic head in the induction strips and further in the Microchip, and from the induction strip into a reading Magnetic head, a data transmission with digital signals carried out.

In a system for securing and / or identifying Goods where a small version of the induction strip is necessary instead of a reader for Magnetic cards also have a read / write head in the form of a pen be provided. With this writing / reading pen for example the cashier prices and other dates in the Save the chip of the card or when selling goods that Read programmed prices and directly into one Take over and register the cash register. In connection with that can also be an automatic and error-free system for Posting and settlement of goods are due to input errors in conventional cash registers with a keyboard be avoided. It is also provided a small one Integrate LC display to, for example, the Show price information to the customer. Also open up  other areas of application, such as electronic legible stamps for automated mail management.

Through controlled short circuits with the integrated chip also a contactless data transmission in a nearby Area of a controlled with digital signals electromagnetic field possible. Different shapes the induction strip, for example with longitudinal coils and magnetisable materials embedded therein provided for greater sensitivities within To achieve excitation fields, because high number of turns possible are. Embodiments with multiple subdivisions are also Vertical stripes or embedded metal powder materials with defined grain size provided.

There are a large number of non-contact chip cards Areas of application in the credit card system. There is one Chip card with induction strips in an electromagnetic Field, a read / write unit, which with digital signals is controlled, bidirectional data transmission be performed within this field, with the integrated chip in the card short circuits of the induction coil generated as serial data signals. Such a disk For example, the size of a credit card can be considered more active Data carriers in banking, as a means of payment Access control, as a key, as a parking card, as personal data storage, as an electronic driver’s license, as a club card, as a health pass, as a gene code memory, as a Emergency ID, as a passport and identity card u. the like Find application. Due to the compatibility achieved already existing different systems with readers for magnetic cards and / or contactless readers several applications combined in a single chip card will. For example, a personal smart card can both  as a phone prepaid card, as a ticket, as a house key, as electronic checkbook or for flexitime recording in Operation and used in the industrial field.

For such a multi-functional chip card Induction strips formed in several layers, creating a spatially arranged induction coil a solid, in particular made of soft magnetic materials Layer, for example made of ferrite materials. A such induction strip has essentially the same Features and benefits like the single layer Induction strips, however, will be even higher Sensitivity in an electromagnetic field reached, if a large number of turns in the induction coil are executed. Since the magnetic field strength to Number of turns is proportional, the also increases Sensitivity.

Such an induction strip becomes multilayer, for example by applying, evaporating or etching different layers of material. Can too Manufacturing process of hybrid and thick film technology, or in Screen printing, plasma polymerization, ion implantation or electroplating processes u. Like. Be used. The easiest manufacture is using a ferrite core very thin painted conductor, such as copper wire. General advantages of these chip cards result from the contactless data transmission, which causes contamination of Contacts and thus sources of error, as with conventional Chip cards can be avoided. In this embodiment, the Ferrite material preferably in the entire length of the Magnetic stripe pulled through, the induction coil this surrounds. At the top are between the turns Induction coil also with magnetizable materials  hard magnetic properties stored on the one hand the Readability with conventional magnetic card readers too ensure, and on the other hand a magnetizable layer to create what information can store. Be too thereby magnetically closed circles with a gap on the Surface formed which is used for data transmission Magnetic head are suitable. By varying the gap width the characteristics of the transmission of data, as well as the Sensitivities controllable. In such a Induction strips are therefore combinations of different magnetizable materials are provided. There are also multilayer induction coils in the magnetic circuit stored, and also taps of the induction coil intended. Other shapes with staggered designs Induction coils and staggered magnetizable Layers are provided to ensure a more uniform to form a magnetizable surface, which a represents continuously continuous magnetizable layer, and largely independent of walking pace of a read head.

Subdivisions of the induction coil are also provided in order to simultaneous in a reader with multiple magnetic heads Bidirectional data transfers and perform simultaneous energy transfer. Thus, the Data transfer speeds increased, and with it the processing times of chip cards are significantly reduced because parallel data transmission is possible. This also makes the Security factor against manipulation significantly increased because the information is distributed.

On the one hand, the data is an integrated chip and so is of the induction strip with conventional magnetic reading heads and even in a close range of an electromagnetic field  readable without contact, on the other hand arises from the Version with continuous soft magnetic material, a transmission and, in particular, of ferrite materials Receiving system for the medium wave range, preferably at Frequencies from 10-900 kHz. With the continuous ferrite layer an antenna is formed thereby, making long-distance transmissions of data over long distances in the kilometer range possible are. Thus, for example, a system for Transfer of bank accounts within towns will be realized. In such a, as an ATM card Executed chip card, for example, with an integrated display The current account balance of one sending unit can be checked daily from the financial institution to the chip card and thus to the user, for example, transmitted at night.

To ensure the highest possible security standard it provided the induction strip for a cash card to be provided with multiple taps, so that each magnetizable segment in the induction strip from the microchip can be controlled. The chip card is thus approached turned on at an ATM, and the integrated Microchip writes the current data after confirmation of the Code number in the induction strips. The data can then read out using a conventional magnetic reading head and updated if necessary, and in the memory of the chip card be filed. To protect against manipulation, the Induction strips when leaving the ATM again deleted. It is also a continuous one Agreement of the balance of the chip card and the Bank computers can be checked, especially when transactions are made with ATMs can be made in different locations.

Applications in the motor vehicle sector are also included Transmission of traffic information is provided.  

Also, one can be found on the motorway entrance Information transmitter with integrated direction detector Send the signal to the chip card in the vehicle if that Vehicle drives in the wrong direction on a motorway. The Chip card in the vehicle can emit a beep that warns the driver. Likewise, when using several info stations on highways also an automatic Toll processing provided, or one when crossing the border contactless registration of data, and therefore also Multi-border tracking with automatic Data acquisition. An information sender can vary depending on Detection area as infrared transmitter, high frequency transmitter or Microwave transmitter, which stores the data in the chip card be carried out.

These chip cards are therefore suitable as universal Reception cards for information such as, Traffic data, environmental data, weather data, location data, Hazard data in the industrial area, or personal Notices and The like. It is generally intended for all cards with such induction strips also an energy transfer via the induction coil in the vicinity of a transmitter perform. Due to the version with a drawn Ferrite layer, and with appropriate choice of Transmission frequency, a high energy density is achieved. It can also be used to charge an integrated storage battery or within the radio frequency field of the transmitter ensures the energy supply for the components, and Data can be transferred or changed in the chip.

By embedding the induction strip and the microchip in a frame made of light-collecting and light-conducting plastic the system is expanded to include optical data transmission. There are also integrated micro buttons in the form of  Optical switches provided, for example Code entry can be used. Through recesses in the light-collecting material cavities are formed, whereby by pressing on a surface in the form of a button light-collecting material, a shift of refractive edges and thus an optical interruption or an optical one Direction of light rays is achieved. This optical Switches can be made very flat, including the There is the possibility of ambient light for forwarding to a use integrated photodiode as detector. In particular light-collecting plastics have the property Absorb ambient light and this through total reflection and embedded fluorescent materials in the frame to radiate. These materials are under the term LISA material known and are characterized by light-collecting and light-guiding properties, as well as edge brightness. A luminescent diode can also be used as the light source, or but also capacitive keys can be provided.

By entering a personal code number on the keys of the Smart cards generally become the security problem of smart cards solved, because using the card for example as Means of payment or ATM card by entering a code must be confirmed directly on the card. Compared to conventional ATM system will provide security against Manipulation increased many times over since the release of the Communication of reader and card also on this is confirmed. To cash withdrawals from ATMs the ATM will carry out a radio frequency field in broadcast in a near area, which one in the chip card located in the immediate vicinity is supplied with energy. By entering the personal code on the chip card there the card itself the authorization and thus the communication to the ATM free. Even if the card is lost  this largely prevents manipulation. As well the code can also be provided at the ATM to be entered and access to grant.

Optical data transmission is achieved through the integration of Transmitting and receiving diodes for the infrared range in the light-guiding frame reached. The chip card is thus too a combination card, which means that even if one card fails Possibility of transmission due to interference and. Like another can be switched. The infrared diodes are like this arranged that this horizontally in the light-guiding frame radiate. The light conduction in the frame is preferably carried out in a horizontal plane so that the radiation to the outer edges led, and is emitted from there. At the inner boundary to the components, the induction strip and the microchip, a light reflecting layer is attached so that none Radiation is lost. The radiation is thus emitted at least on three outer edges, which largely Location independence is achieved.

Embodiments with an integrated LC display are likewise provided, for example with a simple parking card Display of the available parking time is realized. Such a card with infrared control can be used as a parking meter used for toll-free and toll parking areas will. This parking card is not like conventional ones Parking meter on the sidewalk, but can be in the motor vehicle, for example on the inside of the windshield, be attached. Disadvantages with current parking meters are often longer walkways from the parking lot to the parking meter, around one Obtain parking ticket and return to the parking lot to put it on the dashboard.  

A parking card like a chip card is so universal usable that both fee-free as well chargeable debits are possible and further the opportunity is opened in different cities or Zones have different ratings of parking times realize or the debiting fees from the time of day in Bring dependency. The parking card can be used for free short-term parking zones are used as time counters, on the other hand there is the possibility of the parking card for paid parking zones with parking time to load and during the parking process by expiring this parking time again unload. Parking time is purchased using Cash register terminals or vending machines, which are on Sales outlets, for example petrol stations, tobacco shops and the like. where the user is free to choose one buy any number of parking time. The sold Parking time can be with the appropriate city administration.

For example, a solution can be implemented in such a way that an electronic time display a counter for the parked Time with a display for that time, being for that Counter a start / stop device for starting or Shutdown is provided and that a memory for paid Parking time and a processor or controller in the microchip Debit the parked time from the time available in the memory and paid parking time are provided. That way each paid parking time from the time paid in the store Deducted parking time, exactly to the extent that the corresponds to the parking time used. The advantage is that the debiting process takes place only to the extent of the parking period, which the user has actually used, i.e. in Time interval from the start of the parking process until its Termination. With conventional parking meters, the user pays  however, a certain parking time in advance, regardless of this whether he fully consumes this parking time or not.

A chip card as a parking card has a free one Labeling field for the entry of user data, such as Name and vehicle number. So that is a transfer to other vehicles excluded. Since the parking card from the Outside of the windshield is visible and one has a large display, is at any time parked time visible from the outside. Furthermore, there is Possibility of user data and display on the part of Executive photograph. In case of doubt, this makes it easier essentially the evidence.

There is a start / stop button for free parking zones provided, which is to be pressed during the parking process. It is also a "CASH / FREE" button is provided to turn on toll-free Switch mode. From this point on the display will show started a time counting from zero, where one Seconds display indicates the time count. At the end of the parking process is the time counting by pressing the Start / stop button ended.

An additional information in the display can be an info-in indicator "FREE" or "CASH" to display the fee-free or paid mode. When using the Parking card in paid parking zones must first the corresponding number of parking hours can be purchased, the loaded parking time then for several parking processes Available. During a parking process, the Credit store subtracted the corresponding park values until the all available parking time has been used up. The The display then stops at the corresponding meter reading and signals an expired loan. To control the  Residual credits, the "CREDIT" button is pressed, which in the The remaining parking time is shown on the display becomes.

The start and stop process for debiting the in the memory existing paid parking time can be with paid parking zones automatically when you approach the Parking lot by a parking lot Information sender done. The information sender has that Form similar to a coin parkometer, at the upper end of which there is a transmission unit is located, which one in the parking lot has a limited detection area. The information broadcasters are installed in the parking lots and can be used simultaneously also serve as a parking lot boundary.

This information transmitter for controlling the parking card can be used as Infrared transmitter can be executed and several tasks take over, for example the control of the start and Stopping process, the activation of a certain zone or the Time of day control for highly progressive parking zones. The Use of the information transmitter includes the possibility for different cities also have different parking fees debit. Likewise, different zones within Cities have different tariffs. For continuous power supply on the transmitter unit solar cells can also be used.  

Below are different embodiments of the Induction strip explained in more detail with reference to the drawings. Each shows schematically:

Fig. 1 is designed as a short circuit induction loop in a meandering design.

Fig. 2 is a magnetic strip designed induction strip with short circuit winding and embedded magnetizable materials in an enlarged view.

Fig. 3 shows a longitudinal section through the induction strip in an enlarged view.

Fig. 4 is a side view of a security strip for goods and objects.

Fig. 5 shows an induction strip in an enlarged view with a connected microchip for storing data.

Fig. 6 is a chip card with a plurality of divided or tapped induction coils in an enlarged view and connected microchip.

Fig. 7 shows a cross section through the chip card.

Fig. 8 shows an embodiment of the induction strip in a greatly enlarged illustration of the multi-divided magnetic materials.

Fig. 9 shows a longitudinal section through the induction strip in a greatly enlarged representation.

Fig. 10 is a chip card with induction strips in an enlarged view with a continuous ferrite layer, which is surrounded by an induction coil.

Fig. 11 shows an arrangement of an induction coil schematically illustrated.

Fig. 12 is a greatly enlarged illustration of the induction spatially strip coated by ferrite layer.

Fig. 13 an induction strips with staggered magnetizable layers and simultaneous induction coil.

Fig. 14 is a longitudinal section through the induction strip of Fig. 13.

Fig. 15 is a longitudinal section through an induction strip with a defined gap width.

Fig. 16 is a longitudinal section through an induction strip by a continuous ferrite layer.

Fig. 17 is a longitudinal section through an induction strip of multi-layer induction coil.

Fig. 18 is an induction coil strip having longitudinal and stored magnetizable longitudinal strips.

Fig. 19 shows an induction strip with a longitudinal coil and multiple divided longitudinal strips.

Fig. 20 is a cross section through the induction strips divided longitudinal strips.

Fig. 21 an induction strip having longitudinal coil and a ferrite layer in the center of the induction coil.

Fig. 22 an induction strip having longitudinal coil and ferrite core with enclosed executed magnetic stripe surface.

Fig. 23 is a cross-section through the induction strip of Fig. 22.

Fig. 24 is a cross-section through the induction strips on both sides of magnetizable magnetic layer.

Fig. 25 is a chip card with induction strips and integrated infrared transmitting diodes and receiving diodes and integrated optical keys.

Fig. 26 is a sectional view through a LISA material with an optical button and integrated photodiode.

Fig. 27, the spatial representation of an optical key made of light plastic.

Fig. 28 is a protective film for the top of a chip card.

Fig. 29 is a light-collecting plastic frame with recesses for the components and for the optical keys.

Fig. 30 a substrate plate with applied strip and induction devices.

Fig. 31 is a chip card with an integrated DOT matrix display of liquid crystals and integrated keys.

Fig. 32 is a schematic block diagram of a microchip for management and storage of data with attached induction strips.

Fig. 33 is a schematic representation of information channels in the form of infrared transmitters on parking.

Fig. 34 is an arrangement of information channels with simultaneous parking space boundary.

Fig. 35 shows another arrangement manner of information channels.

Fig. 36, the embodiment of an information transmitter.

According to Fig. 1 an induction loop 1 is formed meandering in one layer. The ends of the induction loop 1 are connected to one another via a short-circuit turn 2 .

According to Fig. 2 and 3 of the induction loop are arranged sections 3 1 of magnetizable material in the gaps between the meander. The sections 3 thereby form a multiple subdivided layer made of magnetizable material.

According to Fig. 2 and 3, the inductive loop 1 and the sections 3 of magnetizable material together form an induction strip 4 in a carrier layer 5, for example. B. is made of plastic. The turns of the induction loop 1 and the sections 3 are arranged in the strip 4 in longitudinal section alternately in one layer, as shown in FIG. 3.

The sections 3 made of magnetizable material can be magnetized with known readers with a magnetic head and thus read again, so that the induction strip 4 can be used as a data carrier. Due to the induction loop 1 provided with the short-circuit turn 2 with the magnetic material sections 3 embedded therein, the induction strip 4 absorbs energy in a high-frequency field, so that it can be used as a security strip for goods.

According to FIG. 4, the card-shaped information transmitter has a protective film 6 on an outside. The induction strip 4 is arranged on a carrier layer 5 , on the outside of which there is an adhesive layer 7 for fastening the information transmitter, for example on a product.

According to FIG. 5, the induction loop 1 of the induction strip 4 is connected to a micro chip 8. The microchip 8 can contain a memory for receiving information. The induction strip 4 with an integrated microchip 8 can be used as an identification strip for goods and objects of all kinds.

Referring to FIG. 6 has a chip card in the size of the known credit cards several induction loops 1 a to 1 c, which are connected to the micro chip 8. This division of the induction strip 4 enables parallel data transmissions to be carried out with multi-head readers. FIG. 7 shows a cross section through the chip card according to FIG. 6. The induction strip 4 is then embedded in the carrier 5 of the card.

According to FIGS. 8 and 9, the sections 9 made of magnetizable material are spatially arranged. That is, each section 9 extends from one side of the induction strip 4 through a meandering turn of the induction loop 1 to the other side of the induction strip 4 . Due to the alternating arrangement of the turns of the induction loop 1 and the magnetizable material in the order of magnitude of the gap width of magnetic reading heads, the individual sections 9 can thus be magnetized. On the other hand, by induction of an alternating field in the induction loop 1, the information in the induction strip 4 can also be erased or transmitted in the microchip 8 when it is connected. As can be seen from FIG. 8, the sections 9 made of magnetizable material have recesses 10 extending transversely to the induction strip 4 .

In Fig. 10 an induction strip 4 is shown with a continuous layer 11 of magnetizable material, in which an induction coil embodied as induction loop 1 is incorporated. The ends of the induction coil 1 are connected to the microchip 8 . The induction strip 4 acts like a transmitting and receiving antenna for the medium electromagnetic wave range from 10 to 900 kHz. Remote data transmission, in particular the reception of information, can thus be carried out. The data are stored in the integrated microchip 8 .

Referring to FIG. 11, the helical turns of the induction coil 1 extend around the continuous magnetizable material layer 11 around. The portions of the turns of the induction coil 1, which lie on one side of the magnetizable material layer 11, perpendicular to the longitudinal direction of the magnetizable material layer. 11 This also ensures the transfer of data using a magnetic head.

According to FIG. 12, rib-shaped projections 12 made of magnetizable material are arranged on one side of the magnetizable material layer 11 and extend between the turns of the induction coil 1 . The layer 11 is preferably made of soft magnetic material and acts as an antenna with the induction coil 1 surrounding it. The magnetizable material 12 arranged between the turns of the induction coil 1 serves to receive and store information from a magnetic reader.

According to FIG. 13, the projections 12 are divided on one side of the magnetizable material layer 11 and are arranged offset in the longitudinal direction, so that the sections of the turns of the induction coil 1 on this side each extend step-wise through a pair of projections 12 offset in this way. As a result, a continuous magnetizable layer is formed for a read head that scans the entire length of the induction strip 4 .

According to FIG. 14, the induction strip 4 is formed in two layers, namely from a meandering induction loop 1 with magnetizable material sections 3 embedded therein, corresponding to FIG. 1, and a meandering induction loop 1 d arranged underneath.

In the embodiment according to FIG. 15, U-shaped sections 3 made of magnetizable material are provided in cross section. An induction loop 1 extends through the U-shaped recesses of the sections 3 and between adjacent sections 3 , while the induction loop 1 d arranged below extends only between the U-shaped sections 3 .

In the embodiment according to FIG. 16, the sections 3 , which are embedded between the turns of the meandering induction loop 1 , consist of ribs which are arranged on one side of a strip 11 made of magnetizable material.

The embodiment according to FIG. 17 differs from that according to FIG. 16 essentially in that the turns of a multilayer induction coil 1 e to 1 g are arranged between the ribs 3 made of magnetizable material.

Referring to FIG. 18, the inductive loop 1 is formed as lying in a plane spiral with right-angled turns, which is arranged on the carrier layer 5, in which extend the portions 3 of magnetizable material in the longitudinal direction between the individual turns of the coil 1. This design of the induction loop 1 as a longitudinal coil enables high numbers of turns to be achieved in one plane. The embodiment of FIG. 19 differs from that of FIG. 18 essentially only in that the sections 3 made of magnetizable material are divided in the longitudinal direction. The parts can also be designed as magnetizable particles of different grain sizes. Fig. 20 shows a cross section of the induction strip 4 of Fig. 18 and 19 represent.

Referring to FIG. 21, the magnetisable material within the spiral induction loop 1 is disposed as extending in the longitudinal direction of rod 3. This produces a longitudinal coil with a high number of turns and an antenna designed as a ferrite rod 3 in the middle of the induction coil 1 , that is to say where the greatest induction occurs.

According to Fig. 22 and 23 of the rod 3 may be made from a magnetizable material according to Fig. 21 also be provided on a layer 11 of magnetizable material. Further, it may as shown in FIG. 24 is a are of magnetizable material between two layers 11 and 11.

Referring to FIG. 25 has a chip card for optical and magnetic data transfer to a keyboard 13. A transmitting and a receiving diode 14 , 15 are connected to the chip 8 . Furthermore, each key of the keypad is as shown in Fig. 30 can be seen, 20 to 23 associated with a photo-diode 13.

Referring to FIG. 29, the keys 16 to 19, the transmitting and receiving diodes 14, 15, the chip 18 and the induction strip 4 in the recesses 24 to 31 of a frame 32 made of light plastic material are provided.

The keyboard 13 can be used, for example, to enter a personal code for releasing the communication, in which a specific combination of the keys 16 to 19 is pressed.

The keys 16 to 19 are designed in the form of optical switches. For this purpose, as shown with the button 16 in FIG. 26, they are designed as elastically deformable parts of the frame 32 .

Referring to FIG. 26 and 27, the light is guided by total reflection 33 33 'in the button 16 to the refractive edge 34, it passes from the to the photodiode 20 when the button 16 is pressed. Then the edges 34 and 34 'overlap and the light is guided in the light-collecting plastic material to the photodiode 20 .

The radiation can take place by means of an integrated photodiode or from ambient light. Since light-collecting plastic has the property of absorbing direct or diffuse light from the environment and emitting the light in the plastic matrix, switching states can also be carried out in low ambient light. The optical chip card is covered with a protective film 6 to protect the components.

Referring to FIG. 31, the smart card 36 for displaying information to an integrated LCD screen. The display 36 can be designed as a DOT matrix in order to make it possible to display all numbers and letters as well as graphic characters. The embodiment according to FIG. 31 shows the use of a chip card as a parking card for debiting parking times or parking values. Applications for displaying different information, such as an account balance, can also be provided.

Fig. 32 is a schematic block diagram showing a microchip with attached induction strip 4 for transmission and storage of data. A read / write amplifier 38 for the induction strip 4 is connected to a central control unit 37 , which can also be designed as a transmitter / receiver unit for radio signals. Furthermore, the display 36 , the keyboard 13 , a memory 39 for receiving information and an optical unit 40 for infrared control are connected to the control unit 37 . The control unit 37 can also take over functions for encrypting data.

According to Figs. 33 to 35 41 information transmitter 42 are arranged on parking places, for example, one which is integrated in a vehicle chip card and debit eliminate or different values thereof. Fig. 36 shows an information transmitter 42 with a radiation window 43 and solar cell 44th The information transmitter 42 can be accommodated in a thin tube, which may only have to be inserted into the ground.

Claims (36)

1. Card-shaped information transmitter with a magnetizable material, characterized by an induction strip ( 4 ) arranged in the card plane with an induction loop ( 1 ), in which the magnetizable material is embedded. 2. Information transmitter according to claim 1, characterized in that the induction loop ( 1 ) and / or the magnetizable material are formed as a layer. 3. Information transmitter according to claim 1 or 2, characterized in that the layer from which the induction loop ( 1 ) consists is meandering. 4. Information transmitter according to claim 3, characterized in that in the spaces between the windings of the meandering induction loop ( 1 ) sections ( 3 , 9 ) made of the magnetizable material are arranged. 5. Information transmitter according to claim 4, characterized in that the sections ( 3 ) of the magnetizable material together form a multiple, in the plane of the induction loop ( 1 ) lying layer ( Fig. 2). 6. Information transmitter according to claim 4, characterized in that the sections ( 9 ) made of magnetizable material each extend between the meandering windings from one side to the other side of the meandering induction loop ( 1 ) ( Fig. 8 and 9). 7. Information transmitter according to one of the preceding claims, characterized in that the induction loop ( 1 ) is short-circuited and / or has a predetermined breaking point. 8. Information transmitter according to one of the preceding claims, characterized in that the induction strip ( 4 ) on a carrier layer ( 5 ) made of plastic or is embedded therein. 9. Information transmitter according to one of the preceding claims, characterized in that it has an adhesive layer ( 7 ). 10. Information provider according to one of the preceding claims, characterized in that the magnetizable material is a hard magnetic material. 11. Information provider according to one of claims 1 to 9, characterized characterized in that the magnetic material Sections made of soft magnetic material and Sections made of hard magnetic material. 12. Information transmitter according to one of the preceding claims, characterized in that the induction loop ( 1 ) is connected to a chip ( 8 ). 13. Information transmitter according to claim 12, characterized in that the chip ( 8 ) is programmable to form short circuits. 14. Information transmitter according to one of the preceding claims, characterized in that the magnetizable material is designed as a layer ( 11 ) around which the induction loop ( 1 ) designed as an induction coil extends ( FIGS. 10 to 12). 15. Information transmitter according to claim 14, characterized in that the layer ( 11 ) made of magnetizable material has projections ( 12 ) which protrude between the spiral turns of the induction coil ( 1 ). 16. Information transmitter according to claim 15, characterized in that the sections of the turns of the induction coil ( 1 ) on one side of the layer ( 11 ) made of magnetizable material are perpendicular to the longitudinal direction of the induction strip ( 4 ). 17. Information transmitter according to one of claims 14 to 16, characterized in that the turns of the induction coil ( 1 ) are formed by wrapping the layer ( 11 ) made of magnetizable material with an electrical conductor. 18. Information transmitter according to one of the preceding claims, characterized in that several induction loops ( 1 a to 1 g) are provided in the induction strip ( 4 ). 19. Information transmitter according to claim 18, characterized in that the induction loops ( 1 a to 1 c) are arranged side by side ( Fig. 6) or have taps. 20. Information transmitter according to claim 18 or 19, characterized in that the induction loops ( 1 , 1 d to 1 g) are arranged one above the other or spatially connected ( Fig. 14, 15, 17). 21. Information transmitter according to claim 18 to 20, characterized in that the induction loops ( 1 , 1 a to 1 c) are connected to a chip ( 8 ). 22. Information transmitter according to one of the preceding claims, characterized in that the induction loop ( 1 ) is designed as a spiral lying in a layer ( Fig. 18 to 24). 23. Information transmitter according to claim 22, characterized in that the magnetizable material ( 3 ) between the turns of the spiral induction loop ( 1 ) is arranged. 24. Information transmitter according to claim 22, characterized in that the magnetizable material ( 3 ) is arranged as a rod inside the spiral. 25. Information device according to one of claims 22 to 24, characterized in that the magnetizable material ( 3 ), which engages between the windings or as a rod in the interior of the spiral, is arranged on a layer ( 11 , 11 a) made of magnetizable material . 26. Information provider according to one of the preceding claims, characterized in that the magnetizable material forms an antenna. 27. Information provider according to one of the preceding claims, characterized in that the card is replaced by a Transmitter has rechargeable storage battery. 28. Information transmitter according to one of the preceding claims, characterized in that it has a keyboard ( 13 ) to which the chip ( 8 ) is connected. 29. Information transmitter according to claim 28, characterized in that the keys ( 16 to 19 ) of the keyboard ( 13 ) are formed by optical switches. 30. Information transmitter according to claim 29, characterized in that the card has a frame ( 32 ) made of a light-collecting and light-conducting plastic and the buttons ( 16 to 19 ) are formed by deformable sections of the frame ( 32 ). 31. Information transmitter according to claim 29 or 30, characterized in that each key ( 16 to 19 ) is assigned a photodiode ( 20 to 23 ). 32. Information transmitter according to one of the preceding claims, characterized in that the card for optical data transmission has a transmitting and a receiving diode ( 14 , 15 ). 33. Information transmitter according to claim 32, characterized in that the transmitting and receiving diodes ( 14 , 15 ) are designed as infrared diodes. 34. Information transmitter according to one of the preceding claims, characterized in that it has an LC display ( 36 ) which is connected to the chip ( 8 ). 35. Use of the information provider according to one of the above claims for securing goods, Identification of people and goods, for booking and Settlement of values, as a means of payment and as Authorization card. 36. Use of the information provider according to one of the above claims in the automotive field Transmission of traffic information, as Direction detector, as a parking card and at the Toll processing and when crossing the border.