DE19626651C1 - Method of exchanging data between units contg. chip card and terminal - Google Patents

Abstract

The method involves passing data about the transfer characteristics of one unit to the other unit at the start of the exchange. A control signal causes the transmission rate from a unit with a lower reception rate to be raised to the effective data reception rate of the other unit. The transmission rate can be raised to the maximum reception rate of the terminal.

Description

The application concerns a procedure for Data exchange according to the generic term of Claim 1 and a chip card.

In Funkschau 6/94, pages 74 to 79, an article worth reading is about published the properties and possible uses of chip cards, which also the method for data exchange between a chip card and a Terminal device can be found, which is defined in detail in ISO 7816 as the norm is nated. This standard mainly contains the necessary specifications for the synchronization of data exchange between the chip card and the end device met.

With the standardized procedure, the maximum data rate for the exchange is so far of data, i.e. H. when outputting and receiving data in both Units determined by the reception routine in the chip card. In the Receive routine in both units of both the chip card and the Terminal is a synchronization to the serial data stream and one Oversampling required. The limitation of data exchange by the Receive routine of the chip card in practice is due to the fact that a higher data rate in the receiving routine requires more effort. However, this effort should be kept to a minimum in the chip card  To be able to provide users as cheaply as possible and thus theirs to support wide use.

For reasons of history and transmission security, a initial data exchange between the chip card and the terminal worked at a lower data rate than the maximum possible receive da rate of the chip card. During this initial data exchange, the individual bits one in ISO 7816 as "initial ETU" defined duration, while the later exchange of work data individual bits usually have a shorter duration called "work ETU" to have.

According to ISO 7816, the dialogue between the end device and that of the user chip card inserted into the terminal by the "reset" signal of the terminal tes opened, to which the chip card responded with the "Answer-to-Reset" signal tet. In this signal the chip card gives the terminal information about its Characteristics; because, as is well known, there are now a large number of under different applications of the chip card. To the reported property Among other things, the maximum receive data rate of the chip card belongs to ten.

In addition to this maximum value, the chip card can also work with low data receive data rates work. The currently valid data rate when switched off Exchange of work data is done by the terminal after receiving the "Answer-to- Reset "signal, if necessary in a" Protocol Type Select "signal to the Chip card transmitted and set in the chip card.

The invention has for its object the known Training data exchange procedures so that the Binding of data exchange to the maximum receive data rate of the chip card can be overcome and the data exchange time between the end device and chip card can shorten significantly with the same data content without cause significant additional costs for the chip card.

This task is characterized by the in the Part of claim 1 specified features solved.

drawing

In the drawing shows

Fig. 1 is a processor chip card,

FIG. 1a whose enlarged contact pad,

Fig. 2 is a block diagram of a circuit of an embodiment in a chip card for implementing the method according to the invention,

Fig. 3 is an alternative to a detail of the circuit in Fig. 2.

Description of the embodiment

In the exemplary embodiment, the usual conditions are when using Chip cards and devices based on the maximum possible data rate the reception routine in the chip card is lower than in the terminal. The Terminals are usually designed to be more complex, if only because of their number is far less than that of smart cards. In addition, the easily implement serial interface in the terminal in hardware that high reception data rates allowed while the serial interface in the Chip card is mostly implemented in the software.

However, it should be noted that auxiliary terminals with a pure reading radio one day maybe with a lower maximum data rate in the Receive routine will work as the smart cards. Then the consequences apply the explanations about the chip card analogously for the auxiliary terminal and the Comments on the terminal analogously for the chip card.

Each chip card, and accordingly also the processor chip chip shown in FIG. 1, has several standardized contact fields 2 to 6 in the connection area 1 , with which the connection to a terminal device, not shown, when the chip card is inserted into the card slot of the terminal device is provided. The contact fields are assigned to certain functions in the chip card.

The required supply voltage is applied to the chip card via the contact field 2 , see FIG. 1 a , while the contact field 3 connects the chip card to the ground potential of the terminal. The chip card receives the aforementioned reset signal from the terminal via the contact field 4 . With this command, the terminal device generates an L signal according to ISO 7816 for a specified minimum duration. A clock frequency is fed in at contact field 5 . Details of this are explained in more detail below.

The input / output contact field 6 is used for the serial exchange of bits between the terminal and the chip card, wherein the chip card can both receive data and send data via the contact field 6 . Details of the data rates at which the bits are transmitted are presented below. The remaining non-numbered contact fields are still free for future use in connection with the described procedure.

The individual processes in the chip card during data exchange are explained in more detail below on the basis of a block diagram in FIG . Unless particularly emphasized, the corresponding congruent processes take place in the terminal.

When data is exchanged between the terminal and the chip card, there is a constant change in both units between the reception and the output of data, which is determined by the terminal. The data received and the corresponding control of the chip card are evaluated by a program-controlled processor 7 .

The switchability between transmission and reception mode in the chip card controlled by the terminal is symbolized by a switch 8 in the circuit connected to the contact field 6 . A data reception memory 11 is connected to the contact 9 of the switch 8 and a data transmission memory 12 is connected to the switch contact 10 . The memory 11 receives the data sent by the terminal, while the data intended for retransmission from the chip card to the terminal are stored in the memory 12 .

The data rate in the chip card and thus also in the memories 11 and 12 is determined by a clock generator 13 which is connected to the contact field 5 . The clock generator 13 contains several dividers A to G, which divide the clock frequency applied to the contact field 5 . The change from the "initial ETU" to the "work ETU" is symbolized by a selector switch 14 . The selector switch 14 can be switched over by the processor 7 . The control of the dividers D and F can also be controlled by the processor 7 for varying the data rate. Details of this will be discussed in more detail below.

During the output of the "Answer to Reset" signal, the divider A is switched between the contact field 5 and the clock input of the processor 7 via the selector switch 14 , while the selector switch 14 is switched over to receive the working data and the clock frequency applied to the contact field 5 is switched through the divider combination D and F is divided.

The chip card set up for carrying out the method according to the invention has a further second changeover switch 15 , which is operated by the processor 7 in synchronism with the changeover switch 8 as soon as work data are to be output from the chip card.

In the switch position corresponding to the receive mode, the second switch 15 is connected to the divider combination D / F, so that the previously known conditions are retained, while in the second position corresponding to the transmission mode of working data from the chip card, the second switch 15 has a divider combination E / G is switched on between the clock input of the processor 7 and the contact field 5 .

According to ISO 7816, at the beginning of a data exchange, the terminal device applies the "reset" signal to the contact field 4 connected to the processor. Within half of 200 clock pulses after the application of the "reset" signal, the processor 7 switches the changeover switch 8 to transmission and has the "answer-to-reset" signal read out from the memory 12 , from which the terminal gets to know the type of chip card . The second changeover switch 15 remains in its first position. The "Answer to Reset" signal can begin after 200 additional clock pulses and must have started after 40,000 clock pulses.

During this time, the clock frequency at the contact field 5 is in the range between 1 MHz and 5 MHz, depending on the type of the terminal. For reading out the "answer-to-reset" signal, this clock frequency is divided by the divider A switched on by 372. The distance between the front fronts of the output signal of this first, fixed divider A represents the so-called "initial ETU" already mentioned, with a permissible duration between 0.372 ms and 0.074 ms.

After sending the "answer-to-reset" signal, the switch 8 is automatically switched by the processor 7 into the receive mode, in which the switch arm of the switch 8 is then applied to the contact 9 .

The terminal then sends a "protocol type select" signal to the chip card via the contact field 6 . With this "Protocol Type Select" signal, the processor 7 receives, among other things, information about the divider factors D and F, which the processor 7 then sets in the clock generator 13 . At the same time, processor 7 switches selector switch 14 from the output of divider A to the output of divider combination D / F.

The divider factor depends, among other things, on the clock frequency which the terminal can apply to the contact field 5 during the transmission of work data. The divider factors are, however, moreover and essentially dependent on the data rate that the chip card reception routine allows. As is known, the state of the contact field 6 is scanned several times for each incoming bit in the reception routine for security reasons. This is the reason for limiting the exchange rate of the working data to the data rate in the reception routine of the "slower" chip card.

From these three parameters defined in ISO 7816, the clock frequency, the Divider factor F - the clock rate conversion factor - and the divider factor D - the bit rate adjustment factor - the duration of the "work ETU" results with which then transfer work data from the terminal to the chip card.

The end device is the master device for this data exchange. With a specific command to the chip card, the terminal requests the chip card to switch the switch 8 back to transmit and then stands ready to receive data.

So this particular form of command is very general spoken a control signal for outputting work data from that Unit that allows the lower maximum data rate in the receive routine usually from the chip card.

The invention now provides that at the same time at the beginning of the output of working data from the chip card in the clock generator 13 there is a shortening of the "work ETU" and the terminal is accordingly ready to receive and process data at a higher data rate.

For this purpose, as already mentioned, a changeover switch 15 is provided in the clock generator of the exemplary embodiment, which is simultaneously controlled by the processor 7 with the changeover switch 8 and which switches on another divider combination E / G which applies a higher clock frequency to the clock input of the processor and so that the memory 12 is read out faster than is possible according to the prior art, in which the reception of work data and the transmission of work data take place at the same clock frequency.

Switching to a higher data rate when outputting work data from the unit with the lower received data rate brings the advantage yourself that one can use the previously unused but possibly higher data te in the receive data rate of the other unit, the terminal can bring.

The second switch can also, as shown in Fig. 3 with reference to the switch 15 ', be inserted into the circuit of the exemplary embodiment that only the divider factor D is changed by the divider factor E, while the divider factor F is retained.

The size of the divider factors E and possibly G can preferably be transmitted to the processor 7 in the chip card using the "protocol type selector" signal already mentioned. However, it can also be transferred using the switch command. Ultimately, this is a question of further standardization. It is essential that the average transmission speed is increased by using the invention by using different data rates for the different transmission directions.

For the sake of completeness, it should also be noted that in the terminal device itself possible higher receive data rate with the request of the chip card Output of working data, according to the invention with a higher transmission data rate occurs, must also be activated. The necessary for this Steps can be taken by a person skilled in the art from the description of the embodiment game of the invention using a chip card for the terminal without difficulty derive.

Claims (6)

1. A method for data exchange between two units, one of which comprises a chip card and the other a terminal, wherein at the start of a data exchange data about the transmission properties of a unit are transmitted from this unit to the other unit, characterized in that a control signal Unit with the lower maximum receive data rate causes an increase in the transmit data rate of this unit to the value of the effective receive data rate of the other unit. 2. Data exchange method according to claim 1, characterized, that a control signal / command corresponds to an increase in the transmission data rate according to the maximum receive data rate of the terminal. 3. Data exchange method according to claim 1, characterized in that a processor ( 7 ) in the chip card ( 1 ) on a control command from the terminal sets the amount of the transmission data rate of the chip card ( 1 ). 4. Chip card for a method according to one of the preceding claims with a clock generator for the exchange of data between the terminal and the chip card, characterized in that the clock generator ( 13 ) for the output of working data from the chip card ( 1 ) additionally to one of the received data rate independent, higher value of the transmission data rate is adjustable. 5. Chip card according to claim 4, with a clock generator connected between the contact field ( 5 ) of the chip card ( 1 ) and the clock input of the processor, which divides the clock frequency applied to the contact field ( 5 ) using a first divider combination (D / F) , characterized by a switch ( 15 ) controlled by the processor ( 7 ) during the output of work data, which switches on a second divider combination (E / G) instead of the first divider combination (D / F). 6. Chip card according to claim 5, characterized in that the changeover switch ( 15 ) only replaces the divider D during the output of working data from the chip card by the divider E.