DE19723272A1 - Electronic chip card with microcomputer - Google Patents

Abstract

The chip card has a microcomputer which can be connected to electrically-conductive contact surfaces for contact data transfer. It can also be connected to an antenna (4) for non-contact data transfer. A data memory (5) is directly connected to the antenna (4) for non-contact data transfer. An individual antenna (4) is provided for non-contact data transfer. A control unit (11) makes a connection between the antenna (4) and the data memory (5) or the antenna (4) and the microcomputer (2) in dependence on a control level (STPS). The control unit may have a comparator. When the control level is exceeded, the comparator makes a connection between the antenna and the microcomputer. When the control level is not reached, a connection is made between the antenna and the data memory.

Description

The invention relates to a chip card according to the preamble of Claim 1.

In addition to contact cards, there are contactless cards Chip cards in which the supply of the semiconductor device (Chip) on the card with energy and the data and Si Signal transmission with appropriate writing and / or reading devices contactless (inductive or capacitive). Correspond semiconductor chips in which a rectifier and Si integrated signal converter for contactless operation, is already on the market.

DE 39 35 364 describes a chip card that so probably for a contact as well as for a contact loose operation is designed. The chip card described there contains a semiconductor chip on which a microcomputer is the best consisting of a microprocessor, a program and command memory (ROM; Read Only Memory), a volatile memory (RAM; Random Access Memory) and a non-volatile memory cher (e.g. an EEPROM; Electricaly Eraseable Programmable Read Only Memory) is integrated. This semiconductor chip will either via the electrical contact surfaces of the chip card addressed and supplied with energy or contactless via a coil arranged in the chip card. The chip card has a comparator with which it works on the basis of a chip voltage level comparison determines whether the contactless or  the contact application is active. According to the Comparator output is also indicated in the chip card ordered multiplexer controlled so that the communication with the semiconductor chip either via the contact areas or the antenna is done. The necessary to supply the chip card electrical power is in the case of contactless Bet the same size as in the case of contact-based on sentence. In the case of non-contact use, the energy to supply the semiconductor chip after the transformer principle from the electromagnetic field of the chip card Writer and / or reader taken from outgoing radiation will. A problem here is that for the contactless to the same semiconductor chip is used as for the contact application, the current consumption of a such semiconductor chips is relatively high (on the order of magnitude 10 milliamps). A reliable contactless operation of a Such a chip card is only between small distances The chip card and the chip card writing and / or reading device possible; larger distances are only with one Adequate high transmission power can be implemented, but this corresponds high costs for installation and during loading instinct caused. They are also powerful Transmitter is also undesirable under the aspect of "electrosmog" value. Another disadvantage is the lack of security ner such chip card: With a contact-type chip card can access the sensitive memory areas of the semi-egg building blocks by entering a secret code will. This security that the contact operation offers, is in the chip card known from DE 39 35 364 undermine by contactless use (without  the possibility of entering a secret code) unprotected on the same semiconductor chip can be accessed.

A chip card is known from EP 0 534 559 A1 which is suitable for the contactless mode of operation of the chip card before two antennas sees. The first antenna is directly with a micropro processor connected and is used for data transfer with low Ab stood the chip card to the card reader / writer. The second antenna is directly connected to a storage unit bound and is used for data transfer at a greater distance Chip card to the card reader / writer. Disadvantage of the known chip card is that two antennas are required for data transfer.

The object of the present invention is a chip card form such that a data transfer in a simple manner is made possible in the contactless state of the chip card.

To achieve this object, the invention has the features of claim 1.

The advantage of the invention is in particular that by providing a control unit he only an antenna is required for data transfer in contactless operation as the chip card with both low and relative large distance between the chip card and a card reader / writer. It takes place automatically depending on the height of the transmission level signal present at the output of the antenna Switch to the microcomputer unit on the one hand or to the Data storage unit, on the other hand.  

According to one embodiment of the invention, the control can be unit have a comparator at its first input predetermined control level signal and at its second input a transmission level signal of the antenna is present, with over the control level signal is exceeded by the transmission level signal the transmit signal at the output of the antenna to the micro rake ner unit is switched through.

According to a development of the invention, the control unit designed as a control program, with one on the input side A / D converter is provided, which is the transmit level signal of the antenna converted into a digital transmit level value, which is then with ei is compared to a predetermined control level value. Is the Send level value greater than the control level value, there is a electrical connection of the antenna to the microcomputer Ness. Otherwise the antenna is connected directly with the data storage unit.

Exemplary embodiments of the invention are described below the drawing explained in more detail.

Show it:

Fig. 1 is a schematic representation of the smart card clock surfaces with Kon, microcomputer unit, integrated data storage means and a coil as the antenna,

Fig. 2 is a schematic representation of the data storage unit and

Fig. 3 is a block diagram of another embodiment of the invention.

Below are two application examples of the invention given.

Chip card as access authorization to a building and certain areas within that building

In the memory chip of the chip card different for one Buildings and specific areas within that building specific "key identifiers" are saved by integrated in contact locking systems, working without contact Chip card terminals are readable.

When a person enters the transmission and reception area such a contactless door locking system automatically the contactless semiconductor chip Akti fourth, so a query via the bus in the chip card the "key identifier" stored in the memory chip follows.

To assign such "key identifiers" are within ei company or authority only ever certain persons son, z. B. Superiors or safety officers, calculate does. To prevent misuse, the entry is made and the deletion of certain "key identifiers" only after previous secret code comparison (e.g. a PIN check; Personal Identification Number) about the Contact areas and the then active semiconductor chip for the contact-related use of the chip card. Via the bus in the  The "key IDs" are then stored in the chip card cherchip filed.

The manager or safety officer is therefore over a secret code known only to him, for one certain employees on their chip cards Store "key IDs". For this purpose the Chip card with the contact areas in a corresponding autori sied chip card terminal introduced and the secret code over entered a keyboard.

The assignment of "key identifiers" to new employees and the changes of "key identifiers" for employees de Their responsibilities have changed so they are flexible and perform safely.

Chip card as a ticket for local public transport

The smart card provides an electronic, rechargeable Driving license with which a payment touches "in passing" is possible. The charging then takes place again clocked and PIN-secured with the help of for the contact stipulate use provided semiconductor chips in the chip map.

Fig. 1 shows a chip card 1 , which Chen 3 has standardized contact surfaces. The contact surfaces 3 are connected to corresponding connection points of the microcomputer unit 2 via bond wires D. The individual components of the microcomputer unit 2 , namely the microprocessor, ROM, RAM, EEPROM, are not listed for the sake of clarity. In addition, a programmable data storage unit 5 is arranged on the card 1 . Between the microcomputer unit 2 and the data storage unit 5 there are a supply line V1 and a data line D1. The data storage unit 5 is connected to a coil 4 serving as a transmitting and receiving antenna for data exchange and data transmission.

In Fig. 2, the data storage unit 5 with its components th (coupling unit, control logic, storage unit) is Darge. The coupling unit 5 C is connected to the coil 4 and is used on the one hand to generate the supply voltage from the electromagnetic field of the transmitter and on the other hand to transform the data received and transmitted. The data can be read out of the EEPROM 5 C via the control logic 5 B and / or written into the EEPROM 5 C.

The data transfer in the case of contactless chip card use at a great distance is carried out with the data storage unit 5, which then operates autonomously. In this case, the work cycle is derived from the frequency of the transmitted electromagnetic radiation.

The control logic 5 B preferably contains a control program which processes an output signal of the antenna 4 which is dependent on the reception strength and compares it with a predetermined control level value. If the output signal is greater than the predetermined control level value, the coupling unit 5 C is connected directly to the microcomputer unit 2 via the line D2, so that corresponding data can be exchanged and processed. If the output signal is less than the predetermined control level value, the EEPROM 5 A is connected directly to the coupling unit 5 C, so that data can be exchanged between the data storage unit 5 and an external card reader / receiver.

According to an embodiment of the invention according to FIG. 3, a coupling unit 10 connected to the antenna 4 is connected downstream from a control unit 11 which, depending on the output signal of the antenna 4 , makes an electrical connection to the microcomputer unit 2 or the data storage unit 5 . For this purpose, the control unit 11 consists of a separating unit 12 and a comparator 13 . The separating unit 12 generates from the output signal of the coupling unit 10, a transmission level signal SPS, which is dependent on the field strength or voltage from the transmission signal received by the antenna 4 of the external read / write device. The transmit level signal SPS is fed to a comparator 14 of the comparator 13 , at whose further input a predetermined control level signal STPS is present. If the transmit level signal SPS is greater than the control level signal STPS, the comparator gate signal K of the comparator 14 acts on a changeover switch 15 to the effect that the transmit signal SS received by the antenna 4 is forwarded to the microcomputer unit 2 . If the transmit level signal SPS is smaller than the control level signal STPS, the comparator signal K of the comparator 14 acts on the order switch 15 in such a way that the transmit signal SS received by the antenna 4 is passed on to the data storage unit 5 .

However, the data (memory contents) in the data storage unit 5 can also be changed via the contact-based option of the chip card 1 via the microcomputer unit 2 . The Ar beitstakt T is supplied to the programmable data storage unit 5 via the microcomputer unit 2 . This in turn keeps the clock from the external card reader / memory device. The data exchange is preferably carried out by phase and / or frequency modulation.

The data storage unit 5 , the control unit 11 and the microprocessor unit 2 can be formed as separate components as well as integrated on a single semiconductor chip. If the data storage unit 5 is constructed separately, it is preferably configured as a transponder chip.

It is provided that the data lines or the supply lines are switched depending on the priority such that the contact-based mode of operation of the chip card 1 is the highest and the contactless mode of operation has the second highest priority. In this way, contactless access to the chip card is prevented in operation with contact loading.

Claims (5)

1. Chip card with a microcomputer unit that can be connected to electrically conductive contact surfaces for contact-based data transfer and can be connected to an antenna for contactless data transfer, and with a data storage unit that can be connected directly to an antenna for contactless data transfer, characterized in that a single antenna ( 4 ) is provided for contactless data transfer and that a control unit ( 11 ) depending on a control level (STPS) establishes a connection between the antenna's ( 4 ) and the data storage unit ( 5 ) or the antenna ( 4 ) and the microcomputer unit ( 2 ). 2. Chip card according to claim 1, characterized in that the control unit ( 11 ) comprises a comparator ( 13 ) which, when the control level (STPS) is exceeded, a connection between the antenna's ( 4 ) and the microcomputer unit ( 2 ) and when the Control level (STPS) establishes a connection between the antenna ( 4 ) and the data storage unit ( 5 ) for data transfer and energy supply. 3. Chip card according to claim 2, characterized in that the comparator ( 13 ) has a comparator ( 14 ), at the sen first input a predetermined control level signal (STPS) and at a second input a transmission level signal (PLC) of the antenna ( 4 ) is present . 4. Chip card according to one of claims 1 to 3, characterized in that the control unit ( 11 ) comprises a switch ( 15 ) which, depending on the output signal (K) of the comparator ( 14 ), the transmission signal (SS) of the antenna ( 4 ) through to the microcomputer unit ( 2 ) or the data storage unit ( 5 ). 5. Chip card according to claim 1, characterized in that the control unit is designed as a control program.