DE10025086C1 - Process for monitoring data transmission - Google Patents

Abstract

The invention relates to a method for monitoring the data transmission between a data carrier chain and a data carrier card reading device, in which a potential difference is created by a manipulation circuit, by voltage sensing within the connecting line between the data carrier card (1) and the data carrier card reading device (2) in front of and behind the manipulation circuit and by the formation of voltages U¶C2¶ and U¶K2¶ depending on these voltages, a direction detection of the data transfer between the data carrier chain (1) and the reading device (2) can take place. The direction detection enables the data sent and received to be selected and processed and displayed with the aid of suitable additional devices.

Description

The invention relates to a method for monitoring data transmission between a volume card and a volume card reader and an apparatus for performing the method.

Data carrier cards, in particular in the execution of chip cards, in which in the card body an electronic component for information storage and Information processing is being implemented today large number as access authorization cards, phone cards, bank cards and Like. Used. Such chip cards are used for the individual purposes an interface via which it is connected to an external reading device can be, so that a data exchange between chip card and read establishment can take place. This interface can be from one to one Flat side of the chip card arranged contact field or from within of the disk card body arranged coil exist. One speaks in this connection of contact-based or contactless data transfer possibility.

Based on the electrical connection between chip card and reader The necessary information between the chip card and the reader will be directed furnishings exchanged in digital form. For this data transfer is in the only a single line is available today. Out For this reason, the chip card and the Send the reader only alternately, the other participant must received at this time. This alternate sending and receiving gene is called the duplex method.  

In the described half-duplex method, the data is monitored transmission in such a way that the direction of the data sent on the Transmission line (I / O line) is determined, so far not possible.

DE 42 02 340 C1 describes a device for data transmission between a transmitter and a receiver known as Signal regeneration device for clear signal detection at Serves receiver. The signal regeneration device comprises one Destination direction detection, by means of which the sending direction of the signal processing is set to one of the two possible directions.

From DE 44 12 119 C1 a data terminal is known in which a Activation signal is formed on control lines as a voltage change and can be evaluated by means of a receiving circuit designed as a comparator.

From the post-published DE 198 55 813 A1 a component is known with which can be used to prove whether energy or data between one Device and a chip card can be exchanged.

The object of the present invention is to remedy this, and a Direction detection in communication between data card and To provide reading device.

This object is achieved by the method steps of tech African teaching of claim 1 and the features of the invention solved in claim 4 device.

For the method according to the invention it is provided that a manipulation circuit causes a potential difference within the connecting line (I / O line) between the data carrier card and the reading device, whereby on one side of the manipulation circuit facing the data carrier reading device on the one hand and the data carrier card on the other hand on the connecting line Voltage values U _C1 , U _{K1 are} measured and that, depending on the size of the measured values U _C1 and U _K1 sampled there, two further measured values U _C2 and U _{K2 are} formed by suitable comparator circuits, the measured value U _K2 having a size of almost during the sending process of the reading device or equal to 0 and during the transmission process of the data carrier card the measured value U _{C2 has} a size of almost equal to 0.

The described method steps determine which of the two communicating partners is the data carrier card or reader card sender of information. The direction detection is based on determining at which of the sampled measured values U _C1 and U _{K1 there is} a voltage level below a threshold value, ie which of the two pulls the I / O line to a low level. Direction detection makes it possible for the first time to selectively send and receive the data sent and received during chip card communication, for example with a table card reader, a bank card reader and reader module or a cell phone, and to process and display it with the help of a monitor as an analysis tool.

The device for carrying out the method according to the invention described above has a manipulation circuit according to the invention in such a way that a potential difference can be measured on the connecting line between the data carrier card and the data carrier card reading device, voltage values on the connecting line on one side of the manipulation circuit facing the data carrier reading device and on the other hand U _C1 , U _{K1 are} measured and that, depending on the size of the measured values U _C1 and U _K1 sampled there, two further measured values U _C2 and U _{K2 are} formed by suitable comparator circuits, with the measured value U _K2 having a size of almost during the sending process of the reading device or equal to 0 and the measured value U _{C2 has} a size of almost equal to 0 when the data carrier card is sent.

The structure of the device for detecting the direction of the data transfer is according to the invention clearly and with simple electronic means reali can be retrofitted so that existing readers can also be retrofitted easily directions can be carried out with the device according to the invention.

Special refinements of the method according to the invention result in conjunction with the technical teaching of claim 1 from the features of subclaims 2 and 3. In this regard, it has proven to be advantageous that the measured value U _C2 during the transmission process of the reading device is at the voltage level in the idle phase without data transmission between the data card and the reader. Likewise, it is expedient to determine the voltage level of the measured value U _K2 at the voltage level in the idle phase during the transmission process of the data carrier card without data transmission between the data carrier card and the reading device. This measure makes it possible to uniquely identify the transmission process from the data carrier card or reading device.

The method according to the invention and the device for Implementation of the method with reference to the accompanying drawings explained. It shows:  

Fig. 1 shows a schematic structure of the electronic circuit for direction detection in the communication between a chip card and a chip card reader and

FIG. 2a, b a plurality of voltage / time waveform diagrams that illustrate the sequence of process steps.

In Fig. 1 schematically shows a data carrier card 1 and a data carrier card reading device 2, which is in the following also referred to only as a reading means, shown, that can communicate via a connection line 3 mitein other. Into the connecting line 1 3 is shown in FIG. Manipulierschaltung an inserted for generating a potential difference, which may for example comprise a measuring resistor R1, whose size is determined by measuring state of the pull-resisting contained in the reading device 2 Rp. The pull-up resistor Rp is measured with the help of an ohm meter when the chip card is not connected, the reading device is switched off and without external circuitry between the contacts VCC and I / O. The value for R1 is set to the value of the measured pull-up resistance Rp.

If one assumes that the no-load voltage in the absence of data transfer between data card 1 and reader 2 is, for example, five volts, and that the voltage level to which the voltage level within connecting line 3 is reduced by one of the two reciprocally transmitting participants in the data transfer is a value of 0.35 volts as the so-called low level, so that a value of 0.4 volts can be defined as a value clearly above the low level, the calculation rule for determining the resistance R2 is as follows:

R2 = (0.4 volt × R1) / (5 volt - 0.4 volt).

The determination of R1 and the resulting determination of R2 takes place once for each reading device.

From Fig. 1 it is clear also that the circuit according to the invention comprise two sensors for measuring the voltages U _C1 and U _K1, two comparators (comparator circuits) 10 and 11 as well as two sensors for measuring the voltages U and U _{K2 C2} can. The arrangement of the individual components can be found in detail in FIG. 1. In the circuit shown, the comparators 10 and 11 serve, depending on an adjustable threshold value, which corresponds to the low level of 0.35 volts, on the sensors U _C2 and U _{K2 to} a voltage at the resting level in the absence of data transmission, for example 3 or to provide 5 volts or a voltage level of 0 volts. The course of the method steps according to the invention for direction detection in the communication between data carrier card 1 and reading device 2 is clear from FIGS . 2a and 2b.

In Fig. 2a four voltage timing diagrams are plotted, each representing the voltage waveform at the measurement points for U _C1, U _K1, U _C2 and U _K2. In the diagrams of FIG. 2a, the voltage curve at the measurement points is shown for the case in which the reading device sends data, whereas FIG. 2b shows the voltage curves in the case of data being sent by the chip card. In all cases, all voltages U _C1 , U _K1 , U _C2 and U _{K2 are} at a resting level U _H of, for example, 3 or 5 volts. As soon as the reading device sends data from a time t ₁ , the voltage level at measuring point U _{K1 changes} to a low level below the value of 0.35 volts. Due to this low voltage level, the voltage at the measuring point U _{K2 is} reduced to a level of almost or 0 by the comparator 11 . This reduction exists until the time t ₂ , up to which the reading device 2 sends data to the chip card 1 . The voltage levels U _C1 and U _C2 are additionally plotted in FIG. 2a. During the transmission time of the reading device 2 between the times t ₁ and t ₂ , the voltage U _{C1 is} at a voltage level of at least 0.4 volts. This value, which is above the set threshold value of the comparator 10 , causes the voltage at the measuring point U _{C2 to} rise to the high level of 3 or 5 volts.

The voltage curves U _C1, U _K1, U _{K2 C2} and U are sent in the reverse case, in which the data carrier card 1 information to the Leseein direction 2 in FIG. 2b, clearly. During the transmission period between times t ₁ and t ₂ , the voltage level at measuring point U _{C1 is} reduced to a value below 0.35 volts. As a result, due to the comparator 10, the voltage level at the measuring point U _C2 is almost or equal to 0 volts. Since the voltage U _K1 remains at a level above 0.35 volts during the transmission process of the data carrier card 1 , and in the model case of FIG. 2b is 0.4 volts, the comparator circuit leads to an increase in the voltage U _K2 to the high quiescent voltage level of 3 or 5 volts. It is therefore clear from the voltage curves that a scan of the voltage curves U _C2 or U _K2 permits clear information as to whether the reading device 2 or the data carrier card 1 is transmitting data. Thus, based on the direction detection, the transmission data can be subjected to a logical and / or error analysis and can be processed and displayed accordingly depending on the direction.

Claims (4)

1. A method for monitoring the data transmission between a data carrier card ( 1 ) and a data carrier card reading device ( 2 ), characterized in that a manipulation circuit a potential difference within the connecting line, ( 3 ) (I / O line) between the data carrier card ( 1 ) and data carrier card reading device ( 2 ) is brought about, voltage values U _C1 , U _{K1 being} measured on one of the data carrier card reading devices ( 2 ) on the one hand and the data carrier card ( 1 ) on the other hand facing side of the manipulation circuit on the connecting line ( 3 ) and that depending on the size of the Measured values U _C1 and U _K1 sampled there are formed by suitable comparator circuits ( 10 , 11 ) two further measured values U _C2 and U _K2 , the measured value U _{K2 being} almost equal to or equal to 0 during the reading device transmission process and the measured value during the transmission process of the data card U _C2 a size of almost the same I have 0. 2. The method for monitoring the data transmission according to claim 1, characterized in that the measured value U _C2 during the transmission process data card reader ( 2 ) is at the voltage level in the idle phase without data transmission between the data card ( 1 ) and data card reader ( 2 ). 3. A method for monitoring the data transmission according to one of claims 1 or 2, characterized in that the measured value U _K2 during the transmission process of the data carrier card ( 1 ) is at the voltage level in the idle phase without data transmission between the data carrier card ( 1 ) and the data carrier card reading device ( 2 ) . 4. Device for monitoring the data transmission between a data carrier card ( 1 ) and a data carrier card reading device ( 2 ), characterized in that a manipulation circuit is provided, such that on the connecting line ( 3 ) between data carrier card ( 1 ) and data carrier card reading device ( 2 ) A potential difference can be measured, voltage values (U _C1 , U _K1 ) being measured on one side of the manipulation circuit on the one side of the data carrier card reading device ( 2 ) on the one hand and the data carrier card ( 1 ) on the other hand, on the connecting line ( 3 ) and that depending on Size of the measured values U _C1 and U _K1 sampled there, by means of suitable comparator circuits ( 10 , 11 ), two further measured values U _C2 and U _{K2 are} formed, the measured value U _K2 having a size of almost or equal to 0 during the transmission process of the reading device and the value during the transmission process Data carrier card the measured value U _C2 a size of almost gl I have 0.