KR100521669B1 - Transponders configured for contactless inductive communication - Google Patents

Abstract

The transponder 1 for contactless communication with the base station 2 processes the antenna resonant circuit 10 for receiving the modulated HF signal 5, processes the modulated HF signal, and processes the data signal DS and the clock signal CLK. A data processing means 23 for receiving, the clock signal CLK defines a processing speed of the data processing means 23, and the data processing means 23 for terminating the processing of the data signal DS. Receiving reset information (RI), the transponder 1 receives the clock signal (CLK) and compares the reset signal (RI) by comparing the frequency of the clock signal (CLK) and at least one limiting frequency (f _G1 ). Also provided is a frequency detector 31 for supplying the data processing means 23.

Description

Transponders Configured for Contactless Inductive Communication

The present invention relates to a transponder for contactless inductive communication with a base station, comprising: an antenna resonant circuit for receiving a modulated HF signal supplied by a base station and supplying the signal to a signal processing means; Signal processing means for processing a modulated HF signal and for supplying a data signal and a clock signal, wherein the data signal comprises data contained in the modulated HF signal and the frequency of the clock signal is derived from the frequency of the HF signal And data processing means for receiving the data signal and the clock signal and processing the data signal, the processing speed of the data processing means being dependent on the clock signal, and the data processing means receiving the reset information for terminating the processing of the data signal. And the data processing means.

The invention also relates to an integrated circuit for realizing a transponder configured to provide contactless inductive communication with a base station, wherein the transponder receives a modulated HF signal supplied by the base station and supplies the signal to the signal processing means. An antenna resonant circuit, and signal processing means for processing a received modulated HF signal and supplying a data signal and a clock signal, wherein the data signal includes data contained in the modulated HF signal and the frequency of the clock signal is the frequency of the HF signal. Data processing means for receiving a data signal and a clock signal and processing the data signal, the processing speed of the data processing means being dependent on the clock signal and the data processing means Comprising said data processing means for receiving reset information for terminating processing. All.

Transponders of the type defined in the first paragraph and integrated circuits of the type defined in the second paragraph are known, for example, from the specification US 5,345,231 A. Known transponders include an antenna resonant circuit having an operational link with an antenna resonant circuit of a base station for contactless inductive communication over a modulated HF signal. The modulated HF signal is generated by the base station and has an operating frequency.

During operation of the base station, the received modulated HF signal generated in the antenna resonant circuit of the transponder may be applied to a power supply stage, which is for the power supply of the stages present in the transponder from the received HF signal. Derive the DC voltage. The power supply stage also terminates the operation of the transponder and thus resets the supply of reset information to the stages of the transponder when the voltage drops below the minimum voltage to ensure reliable operation of the transponder. Includes only.

The modulated HF signal received in the transponder's receive mode is generated in the antenna resonant circuit of the transponder, and the signal transmits digital data to be transmitted from the base station to the transponder in a modulated form. The modulated HF signal may be applied to signal processing means for generating a clock signal having a frequency of the HF signal. The clock signal can be applied to the data processing means formed by the microcomputer and defines the processing speed at the system clock and thus the data processing means, so that the processing speed of the data processing means is dependent on the clock signal.

Moreover, the signal processing means demodulates the received modulated HF signal and supplies the data signal to the data processing means. In the data processing mode the data processing means can process the digital data present in the data signal, after which the processed digital data can be stored in the memory, which also allows the data already stored in the memory to be changed.

In the transmission mode of the transponder, the digital data processed by the data processing means can be supplied to the signal processing means as a data signal. The signal processing means forms loading modulation of the unmodulated HF signal through the antenna resonant circuit of the transponder and the antenna resonant circuit of the base station, whereby the digital data processed in the transponder in a contactless manner is inductively directed to the base station. Can be sent.

The data that can be transmitted from the base station to the transponder and from the transponder to the base station and stored in the transponder's memory is almost always security related data, for example representing the amount of money and should only be changed by an authorized person. do. At the base station these security-related data are encoded by means of a digital key and after transmission from the data processing means of such transponders to known transponders they are decoded in the data processing means of such transponders by means of a digital key stored in the memory of the transponder. Thus, high data security is realized.

Due to new developments of new method techniques, HF signals whose frequencies are lower than the operating frequency are transmitted to the transponders, resulting in data processing means having relatively low processing speeds. Security-related data which is available in unencoded form in the transponder by a complex but possible method process and is transmitted between the data processing means and the memory of the transponder via the electrically conductive connection during this process, with the aid of the electrically conductive connection. It has been found that it can be detected in the environments of. Such method processing can be performed without permission by those who are not authorized to detect such security related data. With this recent development, the desired high data security for security-related data can no longer be obtained with sufficient reliability by known transponders for contactless communication, which is an undesirable result.

1 is a schematic block diagram of a transponder in accordance with the present invention for contactless inductive communication with a base station;

2 illustrates a signal waveform of a pulse spacing coded HF signal generated in an antenna resonant circuit of a transponder during communication with the transponder and base station of FIG.

3 are frequency values of the fundamental wave of an unmodulated and pulse spacing coded HF signal, which frequency values are also generated in the transponder of FIG. 1 upon receiving such pulse spacing coded HF signal at certain time intervals. The frequency values shown in the clock signal and the frequency values of the limiting frequencies defined by the frequency detector of the transponder of FIG.

EXAMPLE

1 shows a transponder 1 for contactless inductive communication with a base station 2. The base station 2 has a processing means 3 and an antenna resonant circuit 4. The processing means 3 can generate an HF signal which can be modulated with digital data to be transmitted to the transponder 1 as is generally known. Pulse spacing coding is used for modulation of the HF signal, which is particularly stable and immune to interference.

2 shows a signal waveform of a pulse spacing coded HF signal 5. The HF signal 5 has a signal portion 6 in which the HF signal is formed by the carrier signal 7, and the carrier signal 7 has an operating frequency f _B. The HF signal 5 has further signal portions 8, in which the carrier signal 7 is substantially absent and each forms a pulse spacing. The "0" data bit is coded in a sequence of another signal portion 8 of length T and a signal portion 6 of length 2T. A "1" data bit is coded into a sequence of another signal portion 6 of length T, another signal portion 8 of length T and another signal portion 6 of length T. Both the "0" data bits and the "1" data bits are coded with data bits of length 3T.

The pulse spacing coded HF signal 5 has a fundamental or first harmonic whose frequency f _GH essentially conforms to the equation f _GH = 1 / T. The fundamental wave is the ac component of the lowest frequency of the pulse spacing coded HF signal 5, the amplitude of which is appropriate for practical purposes. The unmodulated HF signal is formed entirely by the signal part 6, ie the carrier signal 7. The fundamental wave of the unmodulated HF signal thus has the operating frequency f _B of the carrier signal 7.

The processing means 3 of the base station 2 is also adapted to encode the security related data with the first digital key formed by the data code. The security related data may be, for example, data representing an amount of money or data granting access to an area space to be accessed only by authorized persons. The memory 9 of the transponder 1 stores a second digital key corresponding to the first digital key and enabling security related data encoded at the base station 2 to be decoded at the transponder 1. Encoding security related data by digital keys has long been known. For example, when the first digital key and the second digital key are the same, using so-called symmetrical coding, or alternatively so-called asymmetrical coding if the two digital keys are different. It is possible to use

The pulse spacing coded HF signal 5 in the transmission mode of the base station 2 can be supplied from the processing means 3 to the antenna resonant circuit 4 of the base station 2. The transponder 1 also has an antenna resonant circuit 10 which is inductively coupled to the antenna resonant circuit 4 of the base station 2 when the transponder 1 is within the reception range of the base station 2. The antenna resonant circuit 10 of the transponder 1 can receive the modulated HF signal 5 supplied by the antenna resonant circuit 4 of the base station 2.

The HF signal 5 appearing in the antenna resonant circuit 10 in the reception mode of the transponder 1 is transmitted from the antenna terminal 11 and another antenna terminal 12 of the antenna resonant circuit 10 by the signal processing means 13. Can be supplied to. The signal processing means 13 processes the modulated HF signal to supply a data signal DS and a clock signal CLK, the data signal DS comprising data present in the modulated HF signal 5 and clocked. The frequency of the signal CLK is derived from the operating frequency f _B of the carrier signal 7 present in the HF signal 5. For this purpose, the signal processing means 13 comprises a signal preparation stage 14 and a processing stage 15.

The signal preparation stage 14 has an analog processing stage 16 which is connected to the antenna resonant circuit 10 and receives the HF signal 5 represented by the antenna resonant circuit 10. The analog processing stage 16 includes filter stages and amplifier stages to increase the signal-to-noise ratio of the HF signal 5, which filter stages and amplifier stages are not shown in FIG. The HF signal 5 processed at the analog processing stage 16 is available on the output 17 of the analog processing stage 16.

The signal preparation stage 14 also has a clock generator stage 18 connected to the terminal 11 of the antenna resonant circuit 10 and receiving the HF signal 5 supplied to the terminal 11. Clock generator stage 18 generates clock signal CLK. When the transponder 1 is in the receive mode and the pulse spacing coded HF signal 5 is supplied to the clock generator stage 18, the clock signal CLK is pulse pulse spacing coded HF signal of length T. Lower during time interval T when indicating spacing. As such, when the transponder 1 is in the receive mode, the fundamental wave of the pulse spacing coded HF signal 5 also appears in the clock signal CLK. The clock signal CLK generated at the clock generator stage 18 is available on the clock signal output 19 of the clock signal generator stage 18.

The processing stage 15 has a demodulator stage 20 connected to the output 17 of the analog processing stage 16. The processed HF signal shown on the output 17 can be applied to the demodulator stage 20, which signal continues the pulse spacing of the carrier signal 7 and the signal portions 8 of the signal portions 6. Include. Demodulator stage 20 also receives a clock signal CLK that appears on clock signal output 19 of clock generator stage 18. The demodulator stage 20 detects the data bits and stores them in the buffer memory of the demodulator stage 20, which uses the coding described with reference to FIG. 2 to detect the timing of the pulse spacings appearing in the processed HF signal. Is affected by the clock signal CLK. When a given number of data bits are stored in the buffer memory of demodulator stage 20, demodulator stage 20 generates a receive control signal ES and supplies this receive control signal ES to control output 21. . In this case, the demodulator stage 20 supplies the data bits stored in the buffer memory to the data bit connector 22 of the demodulator stage 20, and the data bit connector 22 has eight connector contacts.

The transponder 1 also comprises data processing means 23 formed by the microcomputer and processing the data signal DS in the data processing mode of the transponder 1. For this purpose, the data processing means 23 has a clock signal input 24 connected to the clock signal output 19 of the clock generator stage 18, the clock signal input CLK of the data processing means 23; 24 receives a clock signal CLK. The clock signal CLK then forms a system clock in the data processing means 23 formed by the microcomputer and defines the processing speed of the data processing means 23.

The data processing means 23 comprises another data bit connector 25, which has eight connector contacts and is electrically connected to the data bit connector 22 of the processing stage 15 via a data bus having eight conductive connections. ) Is connected. The data processing means 23 also has a control input 26 which is connected to the control output 21 of the demodulator stage 20 and receives the reception control signal ES from the demodulator stage 20. When the reception control signal ES appears, the data processing means 23 forms the data signal DS and reads out the data bits available on the data bit connector 22.

The data bits read by the data processing means 23 in the data processing mode correspond to the encoded security related data transmitted from the base station 2 to the transponder 1. The data processing means 23 is connected to the memory 9 which stores the second digital key via the electrically conductive connection 27. The second digital key can be transmitted from the memory 9 to the data processing means 23 via the connection 27 for decoding the encoded security related data transmitted to the transponder 1. The second digital key formed by the digital data code corresponds to the first digital key by security related data encoded at the base station 2. The processing means 23 decodes the security related data encoded by the second digital key.

In the application of the transponder 1 according to the invention, the base station 2 forms a cash dispenser 2 of the bank and the transponder 1 forms an IC card for connectionless inductive communication, thereby providing a card amount. The amount may be sent to the IC card electrically to allow the amount to be paid by the IC card at the store. In this application, the amount of money is represented by decoded security related data which can be transferred from the data processing means 23 to the memory 9 via the connection 27 and loaded into the memory 9.

In the data processing mode of the transponder 1, the security related data processed by the data processing means 23 is transferred to the data processing means 23 from the memory 9 via the connection 27. It can be encoded by the data processing means 23 with help and transmitted to another data bit connector 25 of the data processing means 23 to prepare such data for the transmission mode of the transponder 1. . The data processing means 23 also generates a transmission control signal SS and applies this transmission control signal SS to the control output 28 of the data processing means 23.

The processing stage 15 of the signal processing means 13 comprises a transmission signal preparation stage 29 for receiving the transmission control signal SS from the control output 28 of the data processing means 23. When the transmission control signal SS appears, the data signal DS can be applied to the transmission signal preparation stage 29, and the data signal is applied to another data bit connector 25 of the data processing means 23. Formed by data bits. The transmit signal preparation stage 29 processes the applied data bits into a series of data bit signals DBS. A series of data bit signals DBS may be applied to the modulator stage 3 of the signal preparation stage 14. The modulator stage 30 loads the antenna resonant circuit 10 according to the received series of data bit signals DBS, which has long been known as so-called loading modulation. When the transponder 1 is within the reception range of the base station 2, the loading modulation induces a loading modulated HF signal in the antenna announcement circuit 4 of the base station 2. The loading modulated HF signal generated in the antenna resonant circuit 4 can be supplied from the antenna resonant circuit 4 to the processing means 3, in which the demodulation and decoding is carried out by means of a first digital key. Can be.

Transponder 1 has a frequency detector 31 having a clock signal input 32 for receiving a clock signal CLK from the clock signal output 19 of the clock generator stage 18. The frequency detector 31 has a comparator stage 33 for receiving the clock signal CLK from the clock signal input 32 of the frequency detector 31.

The frequency detector 31 also has a time base stage 34 for supplying a time base signal ZS to the comparator stage 33, the time axis signal ZS being the first limiting frequency f _G1 . Have The comparator stage 33 compares the frequency of the clock signal CLK with the first limiting frequency f _G1 of the time base signal ZS, and the frequency of the clock signal CLK is lower than the first limiting frequency f _G1 . When the reset information (RI) is supplied. The reset information RI may be applied to the reset input 35 of the data processing means 23 from the comparator stage 33 of the frequency detector 31. When the reset information RI is generated, the data processing means 23 terminates the processing of the data signal DS. When the frequency detector 31 stops supplying the reset information RI to the data processing means 23, the data processing means 23 initializes the processing of the data signal DS starting from the initial state, which is Reset of the microcomputer is common in microcomputers.

This means that when the HF signal is supplied with respect to the antenna resonant circuit 10 of the transponder 1 whose frequency is less than the first limiting frequency f _G1 defined in the frequency detector 31, the processing means ( 23) has the advantage that the processing of the data signal DS is terminated. As a result, the measurement processing executed on the connection 27 to detect the undecoded security related data transmitted through the connection 27 between the data processing means 23 and the memory 9 may produce any useful measurement results. Rarely occurs. In this way, data security during the communication process between the transponder 1 and the base station 2 according to the present invention is substantially improved.

The processing stage 15 of the signal processing means 13 has a mode stage 36 for generating and supplying some other mode information signals on the mode output 37, thereby operating mode in the transponder 1. Activate them. Mode information signals BI characterized by a reception mode, a data processing mode, a transmission mode, and another mode of operation are transmitted from the mode output 37 to the time base stage 34 of the data processing means 23 and the frequency detector 31. ) May be applied. The data processing stage 23 activates the processing of the data signal in the data processing means 23 in accordance with the instantaneous mode of operation when the mode information BI occurs. The time base stage 34 of the frequency detector 31 defines at least one limiting frequency according to the active mode activated when the mode information BI occurs. This has the advantage that the frequency detector 31 defines the limiting frequency in the data processing mode so that the security related data is processed and as a result, a very high level of data security is ensured in the transponder 1 when the data processing mode is activated. Have In other modes where security-related data is not processed, for the benefit of stable and trouble-free communication over a wide range of frequencies, it is unnecessary to define a limiting frequency at the frequency detector 31 and ensure a particularly high level of data security.

The mode stage 36 activates a secure mode in the transponder 1, which receives the modulated HF signal 5. The security mode corresponds to the above-mentioned reception mode, but additionally, in the security mode, the data security level of the transpond 1 is defined by defining a first limiting frequency f _G1 in the frequency detector 31. Stage 36 also activates a high security mode in transponder 1, which transponder 1 processes the security related data. The high security mode corresponds to the above mentioned data processing mode and, where applicable, also corresponds to the transmission mode, but additionally, given a very high data security level, the second limiting frequency f _G2 is applied to the frequency detector 31. Guaranteed in the high security mode defined in. This has the advantage that the security related data is processed only in the high security mode, in particular a high level of data security in the transponder 1 is guaranteed. However, the data security level is also satisfied in the security mode of the transponder 1.

In the secure mode, the signal processing means 13 processes the pulse spacing coded HF signal 5 received at the antenna announcement circuit 10 and the frequency detector 31 is the basis of the pulse spacing coded HF signal 5. The first limiting frequency f _G1 is defined at a frequency lower than the wave frequency. This has the advantage that the frequency detector 31 generates the reset information RI only at the frequency of the clock signal CLK that is less than the frequency of the fundamental wave of the pulse spacing coded HF signal 5 which also appears in the clock signal CLK. . As such, when the pulse spacing coded HF signal 5 is received, the frequency detector 31 generates the reset information RI and thus the data processing means 23 can be avoided from being reset to the initial state.

The mode stage 36 also includes a timing stage 38 for receiving the processed HF signal from the output 17 of the analog processing stage 16 as well as the clock signal CLK from the clock signal output 19. . Timing stage 38 detects pulse spacing in the processed HF signal. By means of a clock signal CLK applied to the timing stage 38, this stage 38 defines a time interval T _T and provides mode switching information, if the HF signal is used again during the time interval T _T. If no other pulse spacing is produced, form mode information BI. When the transpond 1 is in the secure mode, all stages 36 activate the high security mode in the transponder 1 by supplying mode switching information. This means that after receiving the last pulse spacing coded data bits at the transponder 1 in the secure mode of the transponder 1, a high security mode is automatically activated at the transponder 1, resulting in higher data security than the secure mode. The level has the advantage of being guaranteed.

The mode stage 36 includes a reset stage 39 which receives a control signal S from the signal preparation stage 29, which terminates the transmission mode when all data to be transmitted to the base station has been transmitted. Characterizes. The reset stage 39 supplies the frequency detector 31 with mode information BI formed by the mode switching information when the transponder 1 is in a high security mode and the control signal S appears. This means that the security mode is turned off in the transponder 1 which ensures the satisfactory reception of the pulse-spaced coded HF signal 5 immediately after transmission, where the last data bits are activated immediately after the high security mode is activated which ensures a high level of data security during transmission. Has the advantage of being activated. As such, the high security mode of the transponder 1 is only activated when necessary for the handling of security-related data. Due to the automatic activation of the security mode by the reset stage 39, the transponder 1 is again ready to receive the high spacing mode followed by the pulse spacing coded HF signal 5.

FIG. 3 shows the frequency values of the fundamental waves of an unmodulated pulse spacing coded HF signal, which frequency values are also used when the transponder 1 receives such pulse spacing coded HF signal at certain time intervals. Appears on the clock signal CLK generated by the transponder. These frequency values are shown by dashed line 40.

As shown in FIG. 3, at the instant t ₀ , the transponder 1 is in a secure mode, with the result that the frequency detector 31 defines a first limiting frequency f _G1 , and the transponder 1 Assume that an unmodulated HF signal is received. The frequency of the fundamental wave of the unmodulated HF signal corresponds to the operating frequency f _B of the carrier signal 7. Starting from the instant t ₁ , the transponder 1 receives the pulse spacing-coded HF signal 5 for a time T _E having a fundamental wave of frequency f _GH , the fundamental wave being clocked, as already described above. Assume that it is also generated in the signal CLK. Assume that the timing stage 38 of the mode stage 36 detects the final pulse spacing in the pulse spacing coded HF signal 5 at the instant t ₂ , and the HF signal 5 changes to an unmodulated HF signal. . Furthermore, after the time T _T after the appearance of the last pulse spacing in the pulse spacing coded HF signal 5, the timing stage 38 sets the mode information BI formed by the mode switching information to the second limiting frequency ( It is assumed to supply to the frequency detector 31 at the instant t ₁ to define f _G2 ). As a result, the transponder 1 is set to the high security mode at the instant t ₃ . Moreover, during the successive time interval T _D , the data processing means 23 processes the security related data and starts at the instant t ₄ and the security related data is transmitted from the transponder 1 to the base station during the successive time period T _S. It is assumed to be transmitted to (2).

The transmit signal preparation stage 29 supplies the control signal S to the reset stage 39 when the transponder 1 transmits the last data bit to the base station 2, and the reset stage 39 is connected to the mode switching information. Mode information BI formed by this is generated and supplied to the frequency detector 31. The frequency detector 31 defines the first limiting frequency G ₁ when this mode information BI appears and the transponder 1 is again in secure mode.

As can be seen from FIG. 3, the processing of security-related data in the data processing means 23 is carried out at a time interval T _D and at a time interval T _{S when the} transponder 1 is in a high security mode. If the HF signal whose frequency is less than the second limiting frequency f _G2 is transmitted to the transponder 1, it is interrupted. As a result, particularly high data security is obtained in the transponder 1.

In a transmission mode in which security-related data has already been coded, a high security mode does not need to be activated, but alternatively only when a high security mode is activated if appropriate and desired.

For another improvement of the superior data security level for the instantaneous processing mode in the transponder 1, the data processing means 23 of the transponder 1 activates the security mode and the high security mode of the transponder 1. Another mode stage 41 is included. For this purpose, another mode stage 41 generates and supplies processing mode information VBI to the time base stage 34 of the frequency detector 31. The time base stage 34 of the frequency detector 31 defines the first limiting frequency f _G1 when the processing mode information is displayed and the security mode is activated and the processing mode information VBI is displayed and the high security mode is activated. A second limiting frequency f _G2 is defined, and the second limiting frequency f _G2 is higher than the first limiting frequency f _G1 . This allows data processing means 23 to activate a high security mode at given time intervals in which security-related data is transmitted via connection 27 or another electrically conductive connection of transponder 1. 23) offers the advantage of activating the security mode immediately after completing the processing of the security related data. This has the advantage that another mode stage 41 of the data processing stage 23 can define the level of data security required for the instantaneous processing mode.

Note that the transponder 1 shown in FIG. 1 is realized by the integrating circuit 42 indicated by the dotted line in FIG. The memory 9 is connected to the integrated circuit 42 via the electrically conductive connection 27. It is emphasized that the memory 9 can be integrated into the integrated circuit 42.

Note that the method according to the invention can be implemented not only in the so-called passive transponder 1 shown in FIG. 1, but also in a so-called active transponder with a battery for the power supply of the transponder.

Moreover, the frequency detector of the transponder 1 shown in FIG. 1 may define further limiting frequencies to provide any number of data security levels in the transponder 1.

By way of example, instead of pulse spacing coding of an unmodulated HF signal in the embodiments described above, for example, pulse width coding may be used.

It is an object of the present invention to solve the above problems with transponders of the type defined in the first paragraph and integrated circuits of the type defined in the second paragraph and to ensure that high data security between the transponder and the base station It is to provide an improved transponder and improved integrated circuit realized during the transmission of security related data and the processing of security related data of the transponder.

According to the invention, in order to realize this object in a transponder of the type defined in the first paragraph, the transponder has a frequency detector for receiving a clock signal, the frequency detector having a frequency and at least one limiting frequency of the clock signal. If the frequency of the clock signal is lower than the limit frequency, the frequency detector generates reset information and supplies the reset information to the data processing means.

In this way, data processing at the data processing means is terminated when the processing speed at the transponder decreases below a given value defined by the cut-off frequency of the frequency detector. As such, security-related data, such as, for example, a digital key and any other security-relevant data transmitted between the data processing means and the memory of the transponder according to the invention, may only be transferred between the memory of the transponder and the data transmission means. Although the method processing can be carried out at the above-mentioned connection to detect security-related data by transmitting at a high processing speed through an electrically conductive connection between the data processing means, such method processing tends to produce any useful measurement results. Almost no.

In a transponder according to the invention with the special features defined in claim 1, it additionally turns out to be advantageous if the method defined in claim 2 is taken. Thus, if a given mode of operation in which security-related data is processed is activated in the transponder, the frequency detector defines a limiting frequency, and consequently, it is guaranteed that a particular, ie high level of data security for this given mode of operation is guaranteed in the transponder. It is beneficial. In other modes of operation where security-related data is not processed, there is no need to define a limiting frequency, and therefore a special, ie high level of data security, for the benefit of stable and trouble-free communication over a wide range of frequencies. In the transponder according to the invention, a plurality of different modes of operation can be activated, it is also possible to define different limiting frequencies in these different modes of operation of the frequency detector, and given data for each of these modes of operation. The level of security can be guaranteed at the transponder.

In a transponder according to the invention with special features according to claim 2, it additionally proves advantageous if the means defined in claim 3 are taken. Thus, particularly when the transponder in which security-related data read from or to be read from the memory of the transponder is processed by the data processing means is activated in a high security mode, a particularly high data security level defined by the second limiting frequency is achieved. Obtained and, as a result, measurement processing executed on an electrically conductive connection between the data processing means and the memory of the transponder for the purpose of unauthorized detection of the security-related data does not generate any useful measurement results, It is advantageously realized that it is almost impossible to detect data and as a result high data security is ensured. On the other hand, when the security mode is activated in a transponder in which the transponder communicates with the base station and security-related data is already available in the form encoded in the transponder, it is not lower than the data security level of the high security mode defined by the first limiting frequency. A sufficient level of data security is obtained for the desired data security, which has the advantage that substantially no restrictions are imposed with respect to the modulation form for communication with the base station or the low processing speed of the data processing means.

In the transponder according to the invention with the special features defined in claim 3, it has proved advantageous if additionally the means defined in claim 4 are taken. Thus, when the secure mode is activated, communication between the transponder and the base station can use pulse-spacing coding that is very resistant to noise in the HF signal transmitting the data to be transmitted, and additionally satisfactory data security. It is advantageously realized that the level is guaranteed in the transponder during communication. Moreover, since the first limiting frequency is a frequency less than the frequency of the fundamental wave of the pulse spacing coded HF signal, the frequency detector shows that despite the fact that the frequency of the fundamental wave of the pulse spacing coded HF signal also appears in the clock signal of the transponder. It is realized not to generate the reset information. As a result, the processing of the data signal of the data processing means is not terminated during the reception of the pulse spacing coded HF signal by the transponder.

In the transponder according to the invention with the special features defined in claim 4, it has proved advantageous if additionally the means defined in claim 5 are taken. Thus, when the transponder is activated in a data security mode in which the transponder receives a pulse-spaced coded HF signal, a high security mode that guarantees a higher data security level than the security mode results in the final data of the data sequence coded by pulse spacing. It is advantageously achieved automatically in the transponder upon receipt of the bit.

In a transponder according to the invention with the special features defined in claim 4, it additionally proves advantageous if the means defined in claim 6 are taken. Thus, when the transponder is activated in a high security mode where the transponder processes and also transmits security related data to the base station, the security mode in which the pulse spacing coded HF signal transmitted by the base station can be received is determined by the transponder. It is advantageously achieved to be activated automatically at the end of the transmission.

In a transponder according to the invention with the special features defined in claim 1, it additionally proves advantageous if the means defined in claim 7 are taken. Thus, at given time intervals, the security related data is processed and then processed and transmitted through the electrically conductive connection from the transponder's memory to the data processing means or from the data processing means through the electrically conductive connection to the memory. The high security mode can be activated by the data processing means, and it is advantageously achieved that the data processing means activates the security mode at the end of the processing of the security-related data. This has the advantage that in each case the data processing means can define the level of data security required for processing. Moreover, as a result of the activation of the high security mode by the data processing means, the overall time for which the high security mode is activated in the transponder can be shortened so that the transponder is long in the secure mode which enables stable and trouble-free communication over a wide range of frequencies. It works for cycles. The means according to the dependent claim 7 can also be advantageously applied in the transponders defined in the dependent claims 2 to 6.

According to the invention, in order to achieve the above object in the integrated circuit defined in the second paragraph, the integrated circuit has a frequency detector for receiving a clock signal, the frequency detector comparing the frequency of the clock signal with at least one limiting frequency. If the frequency of the clock signal is lower than the limit frequency, the frequency detector generates reset information and supplies the reset information to the data processing means.

In this way, such an integrated circuit according to the invention has the advantages corresponding to the advantages which will be described later with respect to the transponder as defined in claim 1.

Advantageous variants of integrated circuits with special features as defined in claims 9 to 14 are described below in connection with advantageous variants of the transponder according to the invention with special features as defined in claims 2 to 7. Has advantages corresponding to the advantages to be made.

These and other aspects of the invention will be apparent from the embodiments that will be described hereinafter in the manner of examples, and will be described with reference to these embodiments.

The invention will be described in more detail with reference to the embodiments shown in the drawings, which do not limit the invention.

Claims (14)

A transponder for contactless inductive communication with a base station, An antenna resonant circuit for receiving a modulated HF signal supplied by the base station and supplying the signal to signal processing means; Signal processing means for processing a received modulated HF signal and for supplying a data signal and a clock signal, the data signal comprising data contained in the modulated HF signal, wherein the frequency of the clock signal is from a frequency of the HF signal The signal processing means derived; Data processing means for receiving said data signal and said clock signal and processing said data signal, wherein a processing speed of said data processing means depends on said clock signal, and said data processing means resets to terminate processing of said data signal In the transponder comprising the data processing means for receiving information, The transponder includes a frequency detector for receiving the clock signal, The frequency detector compares the frequency of the clock signal with at least one limiting frequency, And the frequency detector generates the reset information and supplies the reset information to the data processing means if the frequency of the clock signal is lower than the limiting frequency. The method of claim 1, The signal processing means comprises a mode stage for activating at least one operation mode in the transponder, And the frequency detector defines the at least one limiting frequency depending on the activated mode of operation. The method of claim 2, The mode stage activates a secure mode in the transponder, in which the transponder receives a modulated HF signal, The mode stage also activates a high-security mode in the transponder, in which the transponder processes security related data, The frequency detector defines a first limiting frequency when the secure mode is activated, a second limiting frequency when the high security mode is activated, and the second limiting frequency is higher than the first limiting frequency A contactless inductive communication transponder. The method of claim 3, wherein The signal processing means processes a pulse spacing coded HF signal received by the antenna resonant circuit, And said frequency detector defines a frequency lower than a frequency of a fundamental wave of said pulse spacing coded HF signal as said first limiting frequency. The method of claim 4, wherein The mode stage includes a timing stage for generating mode switching information, whereby such mode switching information can be generated for a given time interval after the appearance of the last pulse spacing detected in the pulse spacing coded HF signal, And wherein the mode end activates the high security mode in the transponder when the security mode is activated in the transponder and the mode switching information occurs. The method of claim 4, wherein The mode stage includes a reset stage for generating another mode switching information depending on the termination of the transmission mode of the transponder, And wherein said mode stage activates said security mode in said transponder when said high security mode is activated in said transponder and said another mode switching information occurs. The method of claim 1, The data processing means comprises another mode stage for activating a secure mode and a high security mode in the transponder, The data processing means processes security related data when the high security mode is activated, The frequency detector defines a first limiting frequency when the secure mode is activated and a second limiting frequency when the high security mode is activated, wherein the second limiting frequency is higher than the first limiting frequency A contactless inductive communication transponder. An integrated circuit for realizing a transponder configured to provide contactless inductive communication with a base station, the transponder receiving an modulated HF signal supplied by the base station and supplying the signal to a signal processing means. Including, the integrated circuit, Signal processing means for processing a received modulated HF signal and for supplying a data signal and a clock signal, the data signal comprising data contained in the modulated HF signal and a frequency of the clock signal derived from a frequency of the HF signal The signal processing means, Data processing means for receiving said data signal and said clock signal and processing said data signal, wherein a processing speed of said data processing means depends on said clock signal, and said data processing means resets to terminate processing of said data signal In the integrated circuit comprising the data processing means for receiving information, The integrated circuit comprises a frequency detector for receiving the clock signal, The frequency detector compares the frequency of the clock signal with the at least one limiting frequency, And if the frequency of the clock signal is lower than the limiting frequency, the frequency detector generates the reset information and supplies the reset information to the data processing means. The method of claim 8, The signal processing means comprises a mode stage for activating at least one operation mode in a transponder realized by the integrated circuit, And the frequency detector defines the at least one limiting frequency depending on the activated mode of operation. The method of claim 9, The mode stage activates a security mode in a transponder realized by the integrated circuit, in which the transponder receives a modulated HF signal, The mode stage also activates a high security mode in the transponder, in the high security mode the transponder processes security related data, The frequency detector defines a first limiting frequency when the secure mode is activated, a second limiting frequency when the high security mode is activated, and the second limiting frequency is higher than the first limiting frequency Integrated circuit. The method of claim 10, The signal processing means processes a pulse spacing coded HF signal received by the antenna resonant circuit, And the frequency detector defines a frequency lower than a frequency of the fundamental wave of the pulse spacing coded HF signal as the first limiting frequency. The method of claim 11, The mode stage includes a timing stage for generating mode switching information, whereby the mode switching information can be generated for a given time interval after the appearance of the last pulse spacing detected in the pulse spacing coded HF signal, Wherein the mode stage activates the high security mode in the transponder when the security mode is activated in the transponder and the mode switching information occurs. The method of claim 11, The mode stage includes a reset stage for generating another mode switching information depending on the termination of the transmission mode of the transponder realized by the integrated circuit, And wherein the mode stage activates the security mode in the transponder when the high security mode is activated in the transponder and the another mode switching information occurs. The method of claim 8, Said data processing means comprises another mode stage for activating a secure mode and a high security mode in a transponder realized by said integrated circuit, The data processing means processes security related data when the high security mode is activated, The frequency detector defines a first limiting frequency when the secure mode is activated and a second limiting frequency when the high security mode is activated, wherein the second limiting frequency is higher than the first limiting frequency Integrated circuit.