DE10252348A1 - Chip card for contact and contactless data transfer with antenna conductively connected with contact surface but short cut when in contact reader - Google Patents

Abstract

Chip card (1) has antenna (5) conductively connected with contact surface (4) by two contacts (3). Chip (2) is connected to contact surface (4) by contacts (3) and can transfer data via the contact surface (4) or via the antenna. When inserted into reader unit, data is read using contacts while antenna is deactivated by connecting both contacts (3) to short cut them. Independent claims included for 1) end unit/reader with contact unit for data carrier, deactivating antenna during contact data transfer 2) procedure for data transfer between portable data carrier and end unit

Description

The invention relates to a portable disk according to the generic term of claim 1. Furthermore, the invention relates to a terminal with a contacting device to the touching Contacting a portable data carrier and a method for data transmission between a portable disk and a terminal.

Portable media can be used in a variety of different ways Applications are used, for example as identification documents at access controls, as a carrier for one electronic signature for processing payment transactions etc. Data transfer takes place within the scope of the applications between the disk and a terminal or another medium. Depending on the application, this data transfer is via a touching contact a contact area of the disk through the terminal or handled contactless. Touching contact is often used Preferred applications where security and reliability the data transmission are in the foreground. A contactless data transfer is then usually selected if with the disk a transaction if possible should be processed quickly or if the environment of the application An introduction of the disk into the terminal difficult or impossible makes. this leads to that both a first type of data medium is in circulation, which has a contact area for one touching Has contacting, as well as a second type, which is an antenna for contactless data transmission having. As it is increasingly tried to use the same disk Different applications are in the meantime also data carriers become known who both about a contact surface for touching contact as well over an antenna for a contactless data transfer feature.

Such a data carrier is in the DE 39 35 364 C1 disclosed. A chip card is described there, in which the energy supply and the bidirectional data exchange take place via a contact field. In addition to the contact field, coils for power supply and data exchange are also provided. The AC voltage induced in the coils is rectified and smoothed by a diode-capacitor network and fed to a circuit to which there is also a DC voltage that may be supplied via the contact field. The circuit is connected to your contact field, to the coils and to a chip on the chip card. Depending on whether a voltage is present on the coils or on the contact field, the signals from the coils or the signals from the contact field are switched through to the chip.

A disadvantage of the known chip card is that a relatively high amount of circuitry is required is. There is also a potential risk with the switch mechanism a malfunction that interferes with the data transmission or could even be interrupted.

The invention is based, with a reasonable effort a reliable working portable disk to realize who both for a data transfer through a touching Contacting as well for a contactless data transfer is trained.

This task is done with a portable disk the combination of features of claim 1 solved.

The data carrier according to the invention has an electronic one Circuit for storing and / or processing data, a contact area for data transmission through a touching Contacting and an antenna device for contactless data transmission on. The data carrier according to the invention records is characterized in that the antenna device with the contact surface is electrical is conductively connected.

The invention has the advantage that created a portable data carrier with relatively simple means will be both in a touching and works very reliably in contactless operation. Because the antenna device is permanently connected to the contact surface is, no switchover is required, through the optional one Communication path from the contact surface or from the antenna device is switched through to the electronic circuit.

The antenna device can with two contacts of the contact surface be electrically connected, which is the ISO designation four and wear eight. It is also possible that the antenna device with two more to the existing ones according to ISO Contacts of the contact surface is electrically connected.

In the terminal device according to the invention, a contacting device for contacting a portable data carrier is provided, which has a contact area for contacting data transmission and an antenna device for contactless data transmission. Furthermore, the terminal according to the invention has a device for deactivating the antenna device of the portable data carrier. This can ensure that the data transmitted via the antenna device are not disturbed, manipulated or intercepted during a data transmission by touching contacting. The contacting device can have a plurality of contacting elements for the contact-making contact, one contact each of the contact surface of the portable data carrier. In a preferred embodiment, two of these contacting elements are electrically conductively connected to the device for deactivating the antenna device of the portable data carrier. This has the advantage that the deactivation of the antenna device processing can be carried out fully automatically and with a high degree of reliability. In particular, these two contacting elements are arranged in such a way that they contact the contact surface in front of the other contacting elements in order to deactivate the antenna device before the touching data transmission begins. The leading deactivation of the antenna device can be realized in that the two contacting elements for the deactivation project beyond the other contacting elements. The device for deactivating the antenna device of the portable data carrier is preferably designed as a short-circuit connection and thus hardly causes any additional effort.

In the method according to the invention for data transmission between a portable disk and a terminal has the portable disk over a contact area for data transmission through a touching Contacting and about an antenna device for contactless data transmission. The peculiarity of the method according to the invention is that the end device in data transmission through a touching Contacting the antenna device deactivated. To one if possible early To achieve deactivation of the antenna device are preferred first contacted those contacts of the contact surface on which the Antenna device of the portable data carrier is connected. The Deactivation can in particular be carried out in that the antenna device is short-circuited. This can be done using an electrically conductive connection are established between the two contacts of the contact surface to which the antenna device is connected. To achieve one if possible The portable data carrier can be designed to meet high security standards be that it detects a fault condition when the antenna device as part of data transmission through touching contact is not deactivated. Recommended in the event of an error it itself, the data transmission to lock.

The invention is illustrated below of the embodiments shown in the drawing explained in more detail which the inventive disk as Chip card is formed. However, the invention is not on chip cards limited, but also refers in the same way to other types of training Disk.

Show it

1 1 shows an exemplary embodiment of a chip card as a possible implementation of the data carrier according to the invention in a schematic illustration,

2 a further embodiment of the chip card in one 1 corresponding representation,

3 another modified embodiment of the chip card in one 1 and 2 corresponding representation,

4 two application situations for the chip card in a schematic representation,

5 an embodiment of the contacting device in a schematic plan view and

6 the embodiment of the contacting device 5 in a schematic side view.

1 shows an embodiment of a chip card 1 as a possible implementation of the data carrier according to the invention in a schematic representation. The chip card 1 and their components are each represented symbolically as function blocks. The chip card 1 has a chip 2 on the one with contacts 3 a contact area 4 is electrically connected. In the illustrated embodiment, the contact surface 4 a total of ten contacts 3 on that in the form of two parallel rows, each with four contacts 3 are arranged, with another contact in each of the two end regions between the rows 3 is available. On the two contacts 3 which are arranged between the rows is in addition to the chip 2 an antenna 5 connected. Two contacts 3 , which are arranged in the end area of the two rows and have the designations four and eight according to the ISO numbering, are neither with the chip 2 still with the antenna 5 connected and can be used for other purposes if necessary. The chip 2 is designed so that it both over the contact surface 4 as well as via the antenna 5 can perform a data transfer so that the smart card 1 can be used both in applications with contacting and in applications with contactless data transmission. Further embodiments of the chip card 1 that regarding the formation of the contact surface 4 from the embodiment of 1 are different in the 2 and 3 shown.

2 shows a further embodiment of the chip card 1 in a 1 corresponding representation. In this embodiment, the contact surface has 4 the chip card 1 also ten contacts 3 on, the two rows of four contacts each 3 train between which two more contacts 3 are arranged. In contrast to 1 are the other two contacts 3 however arranged together in an end region between the two rows. The antenna 5 is in turn at the contacts arranged between the rows 3 connected and the contacts 3 with the ISO designations four and eight are again free.

3 shows a further modified embodiment of the chip card 1 in a den 1 and 2 corresponding representation. In this embodiment, the contact surface 4 only eight contacts 3 provided in two parallel rows of four contacts each 3 are arranged. The antenna 5 is on two contacts 3 is Schlos sen, which are arranged adjacent to each other in the end region of the two rows and which are designated according to ISO with the numbers four and eight. Free contacts 3 are not present in this embodiment.

4 shows two application situations for the chip card 1 in a schematic representation. Within the scope of the applications, data is transferred between the chip cards 1 and a terminal 6 , The terminal 6 has a contacting device 7 for data transmission through contacting and a terminal antenna 8th for contactless data transmission.

The chip card is in the first application situation 1 for touching contact in the end device 6 introduced. In this position the chip card 1 become contacting needles 9 the contacting device 7 against the designated contacts 3 the contact area 4 pressed and thereby each formed an electrically conductive connection. An operating voltage is applied to the chip via the connections formed in this way 2 and the data transfer between the chip required for the application is created 2 the chip card 1 and the terminal 6 carried out. It is essential for the invention that the terminal 6 the antenna as part of the contacting contact 5 the chip card 1 disabled. Deactivating the antenna 5 is necessary because of the chip 2 does not switch between contacting and contactless data transmission, but both types of transmission run parallel to each other. Thus, by deactivating the antenna 5 in the case of contacting contacting, the contacting data transmission via the antenna can be prevented 5 is disturbed, manipulated or bugged. The deactivation is preferably carried out right at the beginning of the contacting contact, ie before an operating voltage is applied to the chip 2 is created and a data transmission is carried out. To the antenna 5 to disable the two contacts 3 the contact area 4 to which the antenna 5 is connected, electrically connected to each other. Details on this are given in the 5 and 6 explained. If in the context of contacting the chip card 1 no deactivation of the antenna 5 the chip recognizes 2 an error state and blocks data transmission on the part of the chip card 1 , For a touching data transfer with the chip card 1 To be able to carry out, it is therefore necessary that the terminal 6 via a device for deactivating the antenna 5 the chip card 1 features. However, this does not require that the end device 6 how this in 4 the case is, must also be designed for contactless data transmission.

In the second application situation there is a contactless data transmission between the chip card 1 and the terminal 6 carried out. The chip card is there for this 1 outside the terminal 6 within range of the terminal antenna 8th , Contacting the chip card 1 through the contacting device 7 does not take place in the second application situation, so there is also no deactivation of the antenna 5 the chip card 1 comes and the antenna 5 is therefore available for contactless data transmission. Because the contact area 4 is not contacted, there is no risk that the contactlessly transmitted data through a data flow through the contact area 4 be disturbed. Contactless data transmission and usually also contactless energy transmission take place between the antenna 5 the chip card 1 and the terminal antenna 8th and are in 4 indicated by several dashed lines. Because the contacting device 7 is not involved in contactless data transmission, contactless data transmission can also be carried out with a terminal 6 without contacting device 7 be performed.

5 shows an embodiment of the contacting device 7 in a schematic supervision. A corresponding side view is in 6 shown. The exemplary embodiment shown is for contacting the chip card 1 according to 1 designed, ie the contacting needles 9 are arranged in a pattern that matches the arrangement of the contacts 3 the in 1 illustrated chip card 1 equivalent. The two contact needles 9 that the contacts 3 are assigned to which the antenna 5 the chip card 1 are connected by a line 10 connected and thus short-circuited. Furthermore, the two contacting needles mentioned 9 somewhat longer than the other contacting needles 9 so that they are over the remaining contacting needles 9 protrude. This configuration of the contacting device 7 is achieved by touching the chip card 1 first the two contacts 3 be contacted on which the antenna 5 connected. At the same moment the antenna 5 over the line 10 short-circuited and thus deactivated. The remaining contacts 3 will be contacted with a time delay.

Thus, when using the in 5 and 6 illustrated embodiment of the contacting device 7 the antenna 5 the chip card 1 deactivated before data transfer takes place.

The terminal 6 can each be designed as a stand-alone device or be part of a device that in addition to communication with the chip card 1 performs other functions.

Claims (14)

Portable data carrier with an electronic circuit ( 2 ) for storing and / or processing data, a contact area ( 4 ) for data transmission through contacting and an antenna device ( 5 ) for contact loose data transmission, characterized in that the antenna device ( 5 ) with the contact surface ( 4 ) is electrically connected. Data carrier according to claim 1, characterized in that the antenna device ( 5 ) with two contacts ( 3 ) the contact area ( 4 ) is electrically connected, which bear the ISO designations four and eight. Data carrier according to claim 1, characterized in that the antenna device ( 5 ) with two in addition to the existing contacts according to ISO ( 3 ) the contact area ( 4 ) is electrically connected. Terminal with a contacting device ( 7 ) for contacting a portable data carrier ( 1 ) that has a contact surface ( 4 ) for a touching data transmission and an antenna device ( 5 ) for contactless data transmission, characterized in that the terminal ( 6 ) via a device for deactivating the antenna device ( 5 ) of the portable data carrier ( 1 ) has. Terminal according to claim 4, characterized in that the contacting device ( 7 ) several contacting elements ( 9 ) for the touching contact of one contact ( 3 ) the contact area ( 4 ) of the portable data carrier ( 1 ), two contacting elements ( 9 ) with the device for deactivating the antenna device ( 5 ) of the portable data carrier ( 1 ) are electrically connected. Terminal according to claim 5, characterized in that the two contacting elements ( 9 ) for deactivating the antenna device ( 5 ) of the portable data carrier ( 1 ) are arranged in such a way that they 4 ) in front of the other contact elements ( 9 ) to contact. Terminal according to claim 6, characterized in that the two contacting elements ( 9 ) for deactivating the antenna device ( 5 ) of the portable data carrier ( 1 ) over the other contact elements ( 9 ) survive. Terminal according to one of claims 4 to 7, characterized in that the device for deactivating the antenna device ( 5 ) of the portable data carrier ( 1 ) as a short circuit connection ( 10 ) is trained. Method for data transmission between a portable data carrier ( 1 ) and a device ( 6 ), the portable data carrier ( 1 ) via a contact surface ( 4 ) for data transmission through contacting and via an antenna device ( 5 ) for contactless data transmission, characterized in that the terminal ( 6 ) during data transmission by touching the antenna device ( 5 ) deactivated. A method according to claim 9, characterized in that a plurality of contacts ( 3 ) the contact area ( 4 ) can be contacted, first the contacts ( 3 ) on which the antenna device ( 5 ) of the portable data carrier ( 1 ) is connected and then the other contacts ( 3 ) can be contacted. Method according to one of claims 9 or 10, characterized in that the antenna device ( 5 ) of the portable data carrier ( 1 ) is short-circuited for deactivation. A method according to claim 11, characterized in that the antenna device ( 5 ) of the portable data carrier ( 1 ) is short-circuited by an electrically conductive connection ( 10 ) between the two contacts ( 3 ) the contact area ( 4 ) is manufactured on which the antenna device ( 5 ) connected. Method according to one of claims 9 to 12, characterized in that the portable data carrier ( 1 ) detects an error state when the antenna device ( 5 ) is not deactivated as part of the data transmission by contacting. A method according to claim 13, characterized in that the portable data carrier ( 1 ) blocks data transmission in the event of an error.