WO2009115432A2 - Method for operating a radio system and radio system - Google Patents

Abstract

The invention relates to a method for operating a radio system comprising at least one receiving unit (REC2) that is designed to provide a data signal (S_BIT2) on the output side dependent on a predetermined receiving signal (SREC) on the input side and a predetermined receiver frequency (f2). A signal pattern of the data signal (S BIT2) on the input side is compared to signal patterns of several predetermined identification codes (ID1, ID2) that are associated with the predetermined receiver frequency (f2). Depending on the comparison, the identification code having the signal pattern with the greatest match with the signal pattern of the data signal (S_BIT2) is associated with the predetermined receiver frequency (f2).

Description

description

Method for operating a radio system and radio system

The invention relates to a method for operating a radio system and a radio system.

Radio systems are used, inter alia, in modern motor vehicles and are preferably designed to receive data from a radio data system (RDS). By means of RDS additional information can be received on the currently received radio program. The additional information includes, for example, information about a program service name of the radio program or alternative reception frequencies. The RDS data is periodically broadcast by transmitting stations and preferably includes a program identification associated with the currently received radio program. By means of the program identification, a radio broadcasting station and its radiated radio program can be identified.

The object on which the invention is based is to specify a method for operating a radio system and a radio system which enables reliable identification of radio programs.

The object is solved by the features of the independent claims. Advantageous embodiments of the invention are characterized in the subclaims.

The invention is characterized by a method for

Operating a radio system and a radio system having at least a first and a second receiving unit. The first receiving unit is designed to provide a first data signal on the output side as a function of an input signal applied on the input side and a predetermined first receiving frequency. The second receiving unit is designed, depending on the input side given predetermined received signal and a predetermined second receiving frequency on the output side to provide a second data signal. A signal pattern of the first data signal present on the input side is compared with signal patterns of a plurality of predetermined identification codes, which are assigned to a predetermined alternative frequency of the second reception frequency. Depending on the comparison, that identification code is assigned to the first reception frequency whose signal pattern has the greatest agreement with the signal pattern of the first data signal. If the associated identification code matches the identification code currently assigned to the second reception frequency, the first reception frequency is specified as an alternative to the second reception frequency. In this case, the second receiving frequency is assigned a currently received radio program. The predetermined identification codes that are compared are each assigned to a predetermined alternative frequency of the second reception frequency. In this case, a predetermined alternative frequency is typically associated with a plurality of identification codes. The first data signal is typically disturbed or noisy and includes a previously unknown identification code. By comparing the signal pattern of the identification code of the first data signal and with the signal patterns of the predetermined identification codes, the hitherto unknown identification code of the first data signal can be reliably identified. This has the advantage that even a disturbed or noisy data signal, an identification code can be assigned and thus the radio program associated with this data signal can be identified. If the assigned identification code matches the identification code assigned to the second reception frequency, the reception frequency assigned to the data signal can also be used as the alternative frequency of the currently received radio program. According to an advantageous embodiment, depending on a comparison of a first reception quality, which is assigned to the first reception frequency, with a second reception quality, which is assigned to the second reception frequency, the first reception frequency is specified as a new second reception frequency. The consideration of the respective reception quality allows a particularly reliable reception of a given radio program.

According to a further advantageous embodiment, the first reception frequency is specified as a new second reception frequency as soon as the value of the first reception quality is higher than the value of the second reception quality. Thus, the second reception frequency is changed only when the first reception frequency has a higher reception quality. This ensures that only alternative frequencies are used, to which a higher reception quality is assigned, than that of the currently received reception frequency.

According to a further advantageous embodiment, depending on the comparison of the signal patterns of the first data signal with the signal patterns of the predetermined identification codes, noise margins are calculated and assigned to the first reception frequency depending on the interference distances of the identification code. By means of the signal-to-noise ratio, which prefers a

Signal-to-noise ratio of a given received signal represents such. As the first data signal, a predetermined identification code can be assigned particularly reliable. The greater the value of the signal-to-noise ratio, the greater the probability of a match of the identification code of the first data signal with the respective predetermined identification code.

According to a further advantageous embodiment, the radio system comprises a memory which is designed to store predefined identification codes with the respectively assigned at least one alternative frequency and which provide supply identification codes to the at least one signal filter unit. Preferably, the memory is designed as a non-volatile memory, so that already known identification codes for reliable detection of previously unknown identification codes and for a radio program list can be used.

According to a further advantageous embodiment, the memory is designed as a database system. Database systems allow particularly fast access to the identification codes or alternative frequencies.

According to a further advantageous embodiment, the comparison of the identification codes by means of signal-matched filter units. Signal matched filters may also be referred to as correlation filters, and are particularly suitable for providing an output representative of a degree of coincidence of the two signal patterns.

According to a further advantageous embodiment, the first and second data signal represent a data signal of a radio data system. Data of the radio data system are preferably digital and can therefore be processed particularly easily.

According to a further advantageous embodiment, the respective identification code represents a respective program identification of the radio data system. By means of the respective program identification a radio program can be clearly identified. This allows a simple and reliable assignment of reception frequencies to the respective radio program.

Furthermore, the invention is characterized by a method for operating a radio system and a radio system with at least one receiving unit, which is designed for this purpose is, depending on an input side applied predetermined received signal and a predetermined receiving frequency on the output side to provide a data signal. In this case, a signal pattern of the input signal applied to the input signal is compared with signal patterns of a plurality of predetermined identification codes which are assigned to the predetermined reception frequency. Depending on the comparison, that identification code is assigned to the predetermined reception frequency whose signal pattern has the greatest agreement with the signal pattern of the data signal. As a result, a radio program that is assigned to the second data signal can be reliably identified.

According to an advantageous embodiment, the reception frequency is marked as receivable as soon as it is associated with an identification code. Thus, all radio programs, which are assigned to the receivable marked receiving frequencies, identified as receivable.

According to a further advantageous embodiment, a predetermined identification code, which is associated with at least one reception frequency marked receivable, is assigned to a radio program list via which a radio program assigned to the identification code can be displayed. Thus, by means of the radio program list, all radio programs can be displayed to the user of the radio system, for example, who can be received at a current location of the radio system. If, in addition to the identification code, further information of the respective receiving frequency designated as receivable is assigned, these can be displayed to the user and thus ensure a particularly convenient selection of radio programs, in particular in the case of radio programs whose data signal is disturbed or noisy.

Embodiments of the invention are explained in more detail below with reference to the single schematic drawing. It shows :

Figure 1 is a schematic representation of a radio system.

Elements of the same construction or function are identified across the figures by the same reference numeral.

FIG. 1 schematically shows a radio system, as it can be used preferably in motor vehicles. Modern radio systems in motor vehicles are preferably designed to receive received signals of a radio data system (RDS). The RDS is standardized under DIN EN 62106 and can be received Europe-wide. By means of the RDS signals, additional information is essentially transmitted to the currently received radio program, which includes, for example, alternative frequencies which are assigned to the currently received radio program. Alternative frequencies are assigned to predetermined transmitting stations, which also broadcast the currently received radio program. Thus, by means of the RDS signals without user intervention, the reception frequency of the currently received radio program can be changed so that always the reception frequency is selected, which has the highest reception quality at the current location of the motor vehicle. This is particularly advantageous if, while driving, a transmission range of a transmitter that transmits the currently received radio program is exited and the transmission range of a new transmitter is traversed, which also transmits the currently received radio program, but at an alternative reception frequency.

In addition to the formation of the radio system for receiving received signals of the radio data system, the radio system can alternatively be configured to receive received signals, for example, an IBOC system or a DRM simulcast system, analogous to the radio data system as

Hybrid systems are formed and digital accompanying information to the audio signal include. In the following, based on the Radio data system explains the operation of the radio system.

The radio system comprises an antenna ANT, by means of which a received signal S_REC can be received. The received signal S_REC is assigned essentially all radio signals of different reception frequencies that can be received at the current location of the motor vehicle. In this case, the antenna ANT can be followed by a bandpass filter, which is permeable only to receive signals of a predetermined reception frequency range of, for example, 87 to 108 MHz. All received signals outside the specified receiving frequency range are filtered out. The received signal S REC received by means of the antenna ANT is fed to the input side of a first receiving unit REC1 and a second receiving unit REC2. The first and second receiving units REC1 and REC2 are arranged electrically in parallel.

The first receiving unit REC1 is preferably designed to receive digital data and preferably comprises a first channel filter CF1, to the input side of the received signal S REC is supplied. Furthermore, a first control signal S_F1, which predefines a first receive frequency fl, is fed to the first channel filter CF1 on the input side. The first channel filter CF1 is designed to provide on the output side, depending on the received signal S REC and the specification of the first receiving frequency f1, a first received signal S_REC1 having the first receiving frequency f1 of a first signal processing unit DDEM1 on the input side.

The first signal processing unit DDEM1 preferably comprises a data demodulator and a bit decoder. By means of the data demodulator, a carrier signal having a frequency of, for example, 57 kHz is separated from the first received signal S REC1 present on the input side. The carrier signal is preferably associated with the radio data system and includes the information of the RDS signal. By means of the data demodulator the information of the RDS signal is separated from the carrier signal and then supplied to the bit decoder. The bit decoder is designed to generate from the separated signal of the demodulator a digital first data signal S_BIT1 designed as a bit pattern which comprises and represents the information of the radio data system. The first data signal S BIT1 is supplied to an input selector switch SW.

By means of the second receiving unit REC2 the radio program is received, which the user of the radio system has predetermined by means of the specification of the second reception frequency f2. The second receiving unit REC2 preferably comprises a first receiving path, which is preferably designed to receive analog data, and a second receiving path, which is preferably designed to receive digital data. Both receive paths are assigned a second channel filter CF2 and a second demodulator DEM. The second channel filter CF2 is designed analogously to the first channel filter CF1, with the difference that it is given a second reception frequency f2 by means of a second control signal S_F2. On the output side, the second channel filter CF2 provides a second received signal S REC2 with the second receiving frequency f2 to the second demodulator DEM. The second demodulator DEM is analogous to the first demodulator, with the difference that here a second analog receive signal

S AREC2 and a second digital reception signal S DREC2 are separated from the second reception signal S_REC2. The first receive path, the second analog receive signal S_AREC2 is supplied on the input side and the second receive path, the second digital receive signal S_DREC2 is supplied on the input side.

The second reception path is assigned a second signal processing unit DDEM2, which comprises a further bit decoder, and a data processing unit SYNC. The data processing unit SYNC comprises, for example, means for data synchronization, for checking the data integrity and at least one data interpreter. The further bit decoder is designed analogously to the bit decoder of the first signal processing unit DDEM1 and provides the input selector switch SW and the data processing unit SYNC on the input side with a second data signal S_BIT2, which provides the information of the digital accompanying signal, such. B. the RDS signal, which is associated with the second reception frequency f2. By means of the second signal processing unit DDEM2 the digital received signals of the currently received radio program are processed such that, for example, the user additional information, such. B. program service name of the radio program to be displayed.

The analog receiving path of the second receiving unit REC2 preferably has an analog processing unit ADEM with a stereo decoder and an audio processing unit, such. As an audio amplifier, on. By means of the analogue reception path, the analog audio signals are processed such that they can be supplied to the loudspeakers SP and thus the user of the radio system can listen to the currently received radio program.

The first and second data signal S_BIT1 and S_BIT2 each preferably comprise four data blocks which are periodically, so z. B. 10 times in one second, be made available by means of the radio data system. The four data blocks each comprise 104 data bits, each data block having 26 data bits each. The 26 data bits preferably divide into 16 payload data bits and 10 check data bits. By means of the data blocks of the radio data system, for example, information for identifying the currently received radio program is transmitted, information about the radio service name, a list of alternative frequencies, by means of which a radio program identical to the currently received radio program can be received. In principle, the first and second data signal S BIT1 and S BIT2 can also be different be formed, in particular, when other than the radio data system is received by means of the radio system.

The input selector switch SW is preferably arranged on the input side between the bit decoder of the first and second receiving units REC1 and REC2 and on the output side of a first signal filter unit MF1 and a second signal filter unit MF2. The first and second signal filter units MF1 and MF2 are preferably arranged electrically in parallel. By means of a drive signal S_SW the input selector switch SW can be controlled. In a first switching position, the latter assigns the first data signal S BIT1 to the first and second signal filter units MF1 and MF2. In a second switching position, the input selector switch SW assigns the second data signal S_BIT2 to the first and second signal filter units MF1 and MF2.

If, for example, a radio program predetermined by the user is received by means of the second receiving unit REC2, a program identification assigned to the radio program is received by means of the RDS signal, which is assigned to the radio program, which is stored in the memory MEM. The program identification is, for example, a 16-bit value and preferably assigned to the first data block of the respective RDS signal and thus of the first or second data signal S BIT1 or S BIT2. By means of the received RDS signal further preferred alternative frequencies are received, which is associated with the program identification. The alternative frequencies include reception frequencies by means of which a radio program identical to the currently received radio program can be received. The program identification and the at least one alternative frequency assigned to it are fed by means of the feedback signal S FB from the data processing unit SYNC of the second receiving unit REC2 to a control unit CTRL. The control unit CTRL is adapted to the program identification and the at least one alternative frequency of the currently received radio program store in the memory MEM, if they have not yet been stored. Furthermore, an alternative frequency of the currently received radio program can be supplied to the control unit CTRL by means of the feedback signal S_FB. The control unit CTRL is further configured to determine, depending on the alternative frequency in the memory MEM, at least one program identification assigned to the alternative frequency, which program is subsequently supplied to the first and / or the second signal filter unit MF1 and / or MF2.

Different broadcast stations of radio programs can each radiate different radio programs on a given reception frequency, in particular if the broadcast stations are spatially far apart from each other. If the motor vehicle passes through the respective transmission areas of these transmitting stations and stores the received program identifications and the associated alternative frequency lists in memory MEM, a plurality of program identifications can be assigned to a predetermined reception frequency or alternative frequency.

Thus, it is necessary to first check whether the first data signal S BIT1 of the first received signal S REC1 comprises a program identification which is identical to that which corresponds to the second data signal S_BIT2 of the second received signal S_REC2 and thus to the second data signal S_BIT2 of the second received signal S_REC2 currently received radio program is assigned. If both program identifications are in agreement, you can switch to the alternative frequency without changing the radio program.

The program identification of the currently received radio program with the alternative frequencies assigned to it is preferably stored in the memory MEM. In addition to the alternative frequencies and other information in the memory MEM can be stored, such. Eg checksums, program services cename, synchronization data, etc. Preferably, the memory MEM is designed as a database to ensure particularly fast access to required data. This allows particularly rapid access to alternative frequencies if a program identification is specified or particularly fast access to program identifications if an alternative frequency is specified.

The program identification may be referred to as an identification code, which preferably identifies a radio broadcasting station and its broadcast radio program. The radio broadcasting station can be referred to as the source of the respective broadcast radio program. In addition to the program identification of the identification code may also include other data, with an identification of the radio program and / or the radio station should continue to be guaranteed. Thus, the identification code, in addition to the program identification, for example, be associated with constant data of the RDS signal, which do not change during the entire transmission duration. This has the advantage that filtering by means of the signal filter units is particularly reliable because the filtering takes place over a plurality of data bits of the respective data signal. Analogously to the program identification, the identification code represents the respective radio broadcasting station and the radio program assigned to the radio broadcasting station. In principle, it is also possible to use other than the program identification as an alternative identification code.

The first and second signal filter units MF1 and MF2 are preferably designed as signal-matched filter units or correlation filters. Signal matched filters are adapted to a signal pattern of an input side adjacent faulty digital input signal, such. B. the first data signal S_BIT1, with a signal pattern of a known

Useful signal, such. As an identification code, and on the output side an output signal available which is representative of a degree of coincidence of the two signal patterns. The output signal of the matched filter thus represents a correlation value which is greater the higher the degree of coincidence of the signal pattern of the known identification code with the signal pattern of the disturbed data signal. In this case, the specification of the signal pattern of the known identification code preferably takes place in a time-mirrored manner in order to obtain a particularly large correlation value on the output side of the signal-matched filter unit when the signal pattern matches. The use of the matched filter unit is also particularly advantageous because a temporal synchronization between the bit pattern of the disturbed data signal and the bit pattern of the predetermined identification code is not required, ie, a transmission time of the disturbed data signal is not required for the comparison. With regard to the radio system, the filtering by means of the signal-matched filter unit can be referred to as the comparison of the predetermined signal pattern of the first or second data signal S BIT1 or S_BIT2 with the predetermined signal pattern of the first or second identification code ID1 or ID2.

The memory MEM is assigned to the first and second signal filter units MF1 and MF2. If, for example, two different identification codes are assigned to the current second reception frequency f2, the first signal filter unit MF1 is supplied with a signal pattern, which is embodied, for example, as a bit pattern, a first identification code ID1 and the second signal filter unit MF2 a signal pattern of a second identification code ID2. The signal patterns of the first and second identification codes ID1 and ID2 are given, for example, time-mirrored to the first and second signal filter units MF1 and MF2.

Assuming that the drive signal S_SW of the input selector switch SW feeds the first data signal S BIT1 to the first and second signal filter units MF1 and MF2, the data is outputted. a comparison of the signal pattern of the first data signal S_BIT1 with the signal pattern of the first and second identification codes IDl and ID2, respectively, of the first and second signal filter units MF1 and MF2. In this case, the signal pattern of the first data signal S_BIT1 comprise all the data bits of the first block, such. B. every 26 bits of data. In principle, however, a plurality of blocks can also be assigned to the signal pattern. Preferably, a plurality of passes of the first block may be associated with the signal pattern of the first data signal S_BIT1, such. B. 10 or 11. In this case, the first and second identification code IDl and ID2 is specified by means of the memory MEM as a signal pattern such that at predetermined times preferably -1 for a known logical zero of the signal pattern of the first data signal S BITl or a 1 for a known logical one of the signal pattern of the first data signal S_BIT1 is specified. Since it may happen that not all the data bits of the signal pattern of the first data signal S BIT1 are known, in particular if, in addition to the respective program identification, further information is compared by means of the first and second signal filter units MF1 and MF2, a 0 for a respective one unknown data bit of the signal pattern of the first data signal S_BIT1 predetermined by the memory MEM.

On the output side, by means of the first signal filter unit

MFl a first output signal yl a first detection unit DETl provided on the input side. By means of the second signal filter unit MF2, a second output signal y2 of a second determination unit DET2 is provided on the input side. The values of the first output signal y1 respectively represent the degree of coincidence of the signal pattern of the first data signal S BIT1 with the predetermined signal pattern of the first identification code ID1, while the values of the second output signal y2 respectively indicate the degree of coincidence of the signal pattern of the first data signal S BIT1 with the predetermined one Represent signal pattern of the second identification code ID2. For example the signal pattern of the first data signal S BIT1 has a particularly high degree of coincidence with the first predetermined identification code ID1, the value of the first output signal yl is particularly high, for example compared to the value of the second output signal y2 at the output of the second signal filter unit MF2. If, for example, the signal pattern of the first data signal S BIT1 has a high degree of correspondence with the second predetermined identification code ID2, the value of the second output signal y2 is particularly high, for example compared to the value of the first output signal yl.

The first determination unit DET1 is designed to determine a maximum value of the first output signal y1 over a predetermined number of signal values of the first data signal S BIT1 and to determine a first signal-to-noise ratio S1 / N1, which is subsequently supplied to a decision unit DEC. The first signal-to-noise ratio S 1 / N 1 is defined as a ratio of the maximum value of the first output signal y 1 for undisturbed first data signal S_BIT 1 to the determined maximum value of the first output signal y 1 for a disturbed first data signal S BIT 1. The second determination unit DET2 is designed analogously to the first determination unit DET1 and determines a maximum value of the second output signal y2 and a second signal-to-noise ratio S2 / N2, which is also provided to the decision unit DEC on the input side.

The decision unit DEC is designed to compare the first and second signal-to-noise ratio S 1 / N 1 and S 2 / N 2 with a predefined first signal-to-noise ratio limit value. The first

Signal-to-noise ratio is designed in such a way that a signal-to-noise ratio which is greater represents a disturbed data signal which comprises a useful-signal component, such as a signal. B. a still unknown program identification. A signal-to-noise ratio which is less than the first signal-to-noise ratio limit value represents a data signal without a useful useful signal component. Are the first and second signal to noise ratio Sl / Nl and S2 / N2 greater than the first signal-to-noise ratio limit, the decision unit DEC is further configured to compare the two signal-to-noise ratios and to select the signal-to-noise ratio whose value is greater. In principle, however, the previous comparison of the respective interference margins with the first signal-to-noise ratio limit value can also be omitted.

If, in contrast, only one signal-to-noise ratio is greater than the predefined first signal-to-noise ratio limit, then this is selected. Alternatively, the selected signal-to-noise ratio can then be compared with a second signal-to-noise ratio limit value. The second signal-to-noise ratio limit value can, for example, be greater than the first signal-to-noise ratio limit value and the respective identification code. B. the first or second Identi identification code IDL or ID2, be assigned, which is also assigned to the selected signal to noise ratio. If the value of the selected signal-to-noise ratio is greater than the second signal-to-noise ratio limit, the respective identification code, which is also assigned to the currently received radio program and thus to the second receive frequency f2, can be assigned to the selected signal-to-noise ratio with a particularly high degree of certainty. In principle, however, the comparison of the respective signal-to-noise ratio with the second signal-to-noise ratio limit value can also be omitted.

If, on the other hand, the values of both interference margins are smaller than the first signal-to-noise ratio limit value, then neither of the two interference margins will be selected. In this case, the first receiving frequency fl is assigned a new alternative frequency of the currently received radio program and a new comparison is carried out by means of the signal filter units, as already described.

By means of the stored information in the memory MEM, the respective identification ratio selected, the respective identification code, such. B. the first or second identification code IDl or ID2 are assigned, which is then supplied to the control unit CTRL. The control unit CTRL is designed to compare the identification code supplied to it with the identification code associated with the currently received radio program and thus the second reception frequency f2. If the two identification codes do not match, that is the

Control unit CTRL supplied identification code assigned to a different than the currently received radio program. In this case, the identification code supplied by the control unit CTRL can be recorded, for example, in a list of receivable radio programs with the reception frequency assigned to it and made available to the user of the radio system for radio program selection, in particular with full name of the radio program. Furthermore, in this case, the first receiving frequency fl can be assigned a new alternative frequency of the currently received radio program, and a new comparison can be carried out by means of the signal filter units, as already described. On the other hand, if both identification codes match, then the frequency value of the first reception frequency f1 can be specified as a new second reception frequency f2. In this case, a reception quality of the reception signal of the first reception frequency f 1 is preferably compared to a reception quality of the reception signal of the second reception frequency f 2 before the specification of the new second reception frequency.

The respective reception quality preferably represents an evaluation of the respective received signal and takes into account, for example, a respective reception level, which is preferably detected as electric field strength by means of sensors of the first and second receiving units. Furthermore, the respective reception quality also takes into account, for example, adjacent channel influences, which are caused for example by radio programs which are arranged adjacent to the current reception frequency. However, other reception criteria known to a person skilled in the art can also be taken into account for assessing the reception quality. If the reception quality of the reception signal of the first reception frequency fl is better than that of the reception signal of the second reception frequency f2, the frequency value of the first reception frequency f1 is specified as the new second reception frequency f2. If, on the other hand, the reception quality assigned to the first reception frequency fl is lower than the reception quality assigned to the second reception frequency f2, then the second reception frequency f2 can remain unchanged and the first reception frequency f1 can be assigned as the new alternative frequency of the currently received radio program.

Furthermore, the control unit CTRL is designed to supply the second reception frequency f2 supplied by means of the feedback signal S_FB and the identification code associated with it, as well as alternative frequencies to the second reception frequency f2, to the memory MEM. During the entire operating time of the radio system, this has the advantage that a plurality of data sets of identification codes and the associated alternative frequencies are stored in the memory MEM which can be preset for the first and second signal filter units MF1 and MF2, in particular if the memory MEM is a non-volatile memory is trained. As a result, a particularly secure determination of the identification code of the received signal of the first receiving frequency fl can be ensured.

On the output side, the control unit CTRL is assigned the control signal S_SW of the input selector switch SW, from which the first or the second data signal S BIT1 or S BIT2 is respectively assigned to the first and second signal filter units MF1 and MF2. For example, if the user of the radio system manually changes the second reception frequency f2 to receive and listen to another radio program, it may happen that the audio signal associated with the new second reception frequency f2 is received with a sufficient reception level, while that associated with the new second reception frequency f2 RDS signal is received with poor reception quality and a detection of the associated identification codes, such. As the program identification, and alternative frequencies and other information is not possible. In this case, by means of the control unit CTRL, the input selector switch SW can be controlled by means of the drive signal S_SW such that the first and second signal filter units MF1 and MF2 are assigned the second data signal S BIT2 in order to assign the identification code associated with the new second receive frequency f2. to investigate. Thus, depending on the manually changed second receiving frequency f2, the input selector SW is controlled by means of the control unit CTRL.

If the first or second reception frequency f1 or f2 in the memory MEM is assigned only a first identification code ID1 which is fed to the first signal filter unit MF1, an identification code is supplied as the second identification code ID2 of the second signal filter unit MF2 having a predetermined signal pattern which has an unknown identity. tification code is represented and hereinafter referred to as unknown identification code. The unknown identification code can for example be generated dynamically, i. That is, during the comparison by means of the second signal filter unit MF2, a plurality of combinations of the identification code are compared. Depending on the output signal of the respective signal filter unit, a predetermined degree of agreement is achieved. The unknown identification code associated with this degree of coincidence and the reception frequency associated therewith are preferably stored in the memory MEM. However, a full name of the radio program can not be displayed to the user, but preferably the reception frequency.

The first and second signal filter units MF1 and MF2 and / or the first and second detection units DET1 and DET2 and / or the decision unit DEC and / or the control unit CTRL can each be stored as programs in a microcontroller. be trained or a digital signal processor and processed by them. Alternatively, however, the designated units may also be designed as individual units or as a common structural unit, such as, for example, As an ASIC.

The first and second receiving unit REC1 and REC2 and their components are preferably constructed as individual components by circuitry. In principle, it is also possible to integrate them in one unit.

In principle, it is also possible to arrange more than two signal filter units with their assigned detection units electrically parallel. This has the advantage that several of the respective receiving frequency or alternative frequency associated identification codes can be compared with the respective data signal and the identification code can be determined very quickly. Alternatively, it is also possible to arrange only one signal filter unit with its associated detection unit and at several predetermined the respective receiving frequency or alternative frequency associated identification codes to compare them successively with each input side applied data signal and thus determine the data code associated with the respective identification code. This has the advantage that a software technical and / or a circuit complexity can be kept very low. In principle, it is also possible to use a combination of both arrangements, wherein in each case a plurality of signal patterns of different identification codes are supplied for comparison by means of the memory MEM, with signal filter units arranged in parallel electrically.

The data records stored in the memory MEM can preferably be used for the creation of a radio program list. The radio program list provides the user of the radio system with a list of receivable radio programs. Addition, which can be received at the current location of the motor vehicle. By means of the radio system thus radio programs can be identified very early, even if they have a limited reception quality of the accompanying signal, such. B. the RDS signal, and be included in the radio program list. The user of the radio system is thus a large selection of receivable radio programs available, which can be named full preferred.

Claims

claims

1. A method for operating a radio system having at least a first and a second receiving unit (REC1, REC2), wherein the first receiving unit (REC1) is designed, depending on an input side applied predetermined received signal (S REC) and a predetermined first receiving frequency (fl ) on the output side to provide a first data signal (S_BIT1), wherein the second receiving unit (REC2) is designed to output a second data signal (S BIT2) on the output side, depending on the input received input signal (S REC) and a predetermined second reception frequency (f2) ), in which - a signal pattern of the input-side adjacent first data signal (S_BIT1) is compared with signal patterns of a plurality of predetermined identification codes (ID1, ID2) associated with a predetermined alternative frequency of the second reception frequency (f2), - depending on the comparison of that identification code of assigned to the first reception frequency (fl) whose signal pattern has the greatest agreement with the signal pattern of the first data signal (S_BIT1), - if the associated identification code matches the identification code currently assigned to the second reception frequency (f2), the first reception frequency (fl) is given as an alternative for the second reception frequency (f2).

2. The method of claim 1, wherein depending on a

Comparison of a first reception quality associated with the first reception frequency (fl) with a second reception quality associated with the second reception frequency (f2), the first reception frequency (fl) being specified as a new second reception frequency (f2).

3. The method of claim 1 or 2, wherein the first receiving frequency (fl) is specified as a new second receiving frequency (f2), as soon as the value of the first reception quality is higher, the value of the second reception quality.

4. The method according to any one of the preceding claims, in which depending on the comparison of the signal pattern of the first data signal (S BITl) with the signal patterns of the predetermined identification codes disturbance intervals are calculated and depending on the disturbance intervals of the identification code of the first reception frequency (fl) is assigned.

5. Radio system with

- At least a first and a second receiving unit (RECL, REC2), wherein the first receiving unit

(REC1) is designed to, depending on a given input signal applied to the input side

(S REC) and a predetermined first reception frequency

(fl) on the output side, a first data signal (S_BIT1) to provide, wherein the second receiving unit

(REC2) is designed to provide a second data signal (S_BIT2) on the output side as a function of the input signal (S REC) applied on the input side and a predetermined second reception frequency (f2) on the output side,

at least one signal filter unit (MF1, MF2) which is designed to generate a signal pattern of the input-side first data signal (S_BIT1) with signal patterns of a plurality of predetermined identification codes (ID1, ID2) assigned to a predetermined alternative frequency of the second reception frequency (f2), to compare,

a decision unit (DEC), which is designed to assign, depending on the comparison, to the identification code of the first reception frequency (fl) whose signal pattern has the greatest agreement with the signal pattern of the first data signal (S BIT1), - A control unit (CTRL), which is adapted to predetermine the first reception frequency (fl) as an alternative to the second reception frequency (f2) in accordance with the identified identification code with the second reception frequency (f2) currently assigned identification code.

6. The radio system according to claim 5, wherein the control unit (CTRL) is adapted to a second reception quality associated with the second reception frequency (f2) depending on a comparison of a first reception quality associated with the first reception frequency (fl) to specify the first reception frequency (fl) as the new second reception frequency (f2).

7. A radio system according to claim 6, wherein the control unit (CTRL) is adapted to specify the first reception frequency (fl) as a new second reception frequency (f2), as soon as the value of the first reception quality is higher, the value of the second reception quality.

8. Radiosystem according to one of claims 5 to 7, comprising a memory (MEM) which is adapted to store predetermined identification codes (IDl, ID2) with the respectively associated at least one alternative frequency and the predetermined identification codes (IDl, ID2) supplying at least one signal filter unit (MF1, MF2).

9. Radio system according to one of claims 5 to 8, wherein the memory (MEM) is designed as a database system.

10. Radio system according to one of claims 5 to 9, wherein the at least one signal filter unit (MFl, MF2) is designed as a signal-matched filter unit.

11. Radio system according to one of claims 5 to 10, wherein the first and second data signal (S_BIT1, S_BIT2) represents a data signal of a radio data system (RDS).

12. The radio system according to claim 11, wherein the respective identification code (ID1, ID2) represents a respective program identification of the radio data system (RDS).

13. Radio system according to one of claims 5 to 12, comprising at least one determination unit which is adapted to calculate depending on the comparison of the signal pattern of the first data signal (S BITl) with the signal pattern of the predetermined identification codes disturbance intervals and depending on the disturbance intervals the Identkoko - Assign de the first receiving frequency (fl).

14. A method for operating a radio system having at least one receiving unit (REC2), which is designed to provide a data signal (S BIT2) on the output side as a function of an input-side predetermined predefined received signal (S_REC) and a predetermined receiving frequency (f2) , in which

a signal pattern of the data signal (S_BIT2) applied on the input side is compared with signal patterns of a plurality of predetermined identification codes (ID1, ID2) which are assigned to the predetermined reception frequency (f2),

- Is assigned depending on the comparison of that identification code of the predetermined reception frequency (f2), whose signal pattern has the greatest agreement with the signal pattern of the data signal (S_BIT2).

15. The method of claim 14, wherein the predetermined reception frequency is designated as receivable as soon as it is associated with an identification code.

16. The method according to claim 15, wherein a predetermined identification code, which is associated with at least one reception frequency marked receivable, is assigned to a radio program list via which a radio program assigned to the identification code can be displayed.

17th radio system with

with at least one receiving unit (REC2), which is designed to provide a data signal (S_BIT2) on the output side as a function of a predetermined received signal (S REC) applied to the input side and a predetermined receiving frequency (f2),

- At least one signal filter unit (MFl, MF2), which is adapted to a signal pattern of the input side applied data signal (S_BIT2) with signal patterns of a plurality of predetermined identification codes (IDl, ID2), which are assigned to the predetermined reception frequency (f2) to compare , - a decision unit (DEC), which is designed to allocate, depending on the comparison, that identification code of the predetermined reception frequency (f2) whose signal pattern has the greatest agreement with the signal pattern of the data signal (S_BIT2).