DE3825886C2 - Radio data system radio receiver - Google Patents

Description

The present invention relates to a method of identifying the Transmission method of frequency information data in Radio data systems and one RDS receiver that is suitable for performing the method.

A radio data system has been proposed to To offer radio listeners a service in which a ordinary radio station that broadcasts a program also information associated with the broadcast is, such as details of program content, as Sends out data by multiplex modulation to thereby the To allow broadcast listeners to be the personally preferred Program content based on that of the Radio receivers received and demodulated data to be selected (Funkschau 1/1986, pp. 43-47).

In this RDS system, a subcarrier of 57 kHz, the outside of the band occupied by the FM signals is the third harmonic of a 19 kHz stereo pilot signal is through a data signal amplitude modulated, filtered and biphase encoded and that is representative of the program content, in order to thereby delivering radio data signals. A main carrier with this amplitude-modulated subcarrier frequency modulated, and then the main carrier emitted.

Fig. 4 schematically shows a baseband coding structure of a radio data signal, which consists of 104 bits to form a group, and which is repeatedly multiplexed out.

A group consists of four 26-bit blocks, each block consisting of a 16-bit information word and a 10-bit check word. Figure 6 shows block 1 associated with a program identity code (PI), block 2 associated with a traffic program identity code (TI) or a traffic announcement identity code (TA), block 3 associated with a station frequency code (AF) Is associated with a network station that broadcasts the same program as the station currently being received, and block 4 is associated with program service information (PS) data such as a station name or a network name. Each group is distinguished by four bits in 16 types, ie Type 0 to Type 15 , which differ in their content. Furthermore, two versions, version A and version B, are defined in relation to the corresponding types ( 0 to 15 ). These identification codes are in block 2 . The station frequency code (AF) the network station is designed so that it is emitted only by Type 0, group A and PS data by Type 0, Type 0 and group A, group B. In this way, Type 0 , Group A radio data contains AF data of the network stations broadcasting the same program as the station currently being received. When the broadcast signal is received, the AF data obtained by demodulating the broadcast signal is read and then stored, and if the reception field strength of the station currently being received has become too weak due to interference or multipath, other network stations on the station may instead The AF data of the previously stored network stations can be selected in order to enable radio listeners to continue listening to the same program under good, interference-free reception conditions.

There are two methods of sending this AF data. In a first method A, multiple blocks are defined, as shown in Fig. 5 (A), to contain AF data (f ₁ to f _n ) for up to 25 network stations, which emit the same program, regardless of whether each station may or may not be received, with each block containing the AF data for two stations. A first data element in the first block indicates the number of stations n in that network. This group of blocks is broadcast sequentially in a repetitive manner.

In method B, several groups of stations are defined based on network stations (f ₁ to f _n ) which emit identical programs, each group consisting of a central station and network stations in a transmission area, as shown in Fig. 5 (B). Each block contains the AF data for a pair of stations that broadcast identical programs, one being a central station in that group and the other a station within that group. A first data element in a first block of each group represents the number m _n of stations in that group. This group of blocks is broadcast sequentially in a repetitive manner. The order of the arrangement of the two paired stations in each block is determined depending on which station has the higher or lower transmission frequency of the two stations. In both methods A and B, the AF data consist of 8 bits and are located in block 3 (from FIG. 4), which is to be sent out as a 16-bit information word (2 × 8 bits). The transmitting stations decide which of the methods A and B is used in the individual case.

The existence of these two different methods for Sending the AF data naturally sets two different methods for processing the AF data after demodulating the radio data on the Reception side ahead. It is therefore necessary to be quick and reliably identify which of the  Method A or B the AF data are transmitted.

The object of the invention is a method in to specify a radio data system with which the Reliable transmission of AF data in a short time can be identified.  

This task is characterized by the characteristics of the Claim 1 solved. Advantageous embodiments of the Invention and a receiver for performing the method with further training are the subject of Subclaims.

An example of the method according to the present Invention will now refer to the drawings explained. It shows

Fig. 1 is a block diagram of the basic structure of an FM multiplex broadcast receiver in which a method for identifying AF data transmissions of the present invention is applied in accordance with;

Fig. 2 is a flow chart for identifica tion the flow of the AF data transmission method according to the present invention, which method is executed by a processor;

Fig. 3 is a flowchart showing the procedure for selecting and storing AF data in the process B, which procedure is executed by a processor;

Fig. 4 is a diagram showing a structure of the baseband encoding of radio data;

Fig. 5 is a program showing the arrangement of paired AF data in accordance with the transmission method for AF data, (A) for the method (A) and (B) for the method (B);

Fig. 6 is a diagram showing the format of Type 0 , Group A.

Reference is now made to FIG. 1. A desired station is selected at an input part 2 from FM multiplex broadcast radio waves which are received by an antenna 1 , and is then converted into an intermediate frequency (IF). The intermediate frequency signal is fed to an FM detector 4 via an IF amplifier 3 . The input part 2 contains, for example, an RF amplifier, a mixer, a voltage controlled oscillator (VCO) and a PLL synthesizer containing a programmable frequency divider, the division ratio of which is controlled by a control unit 14 , which will be described later, in order to carry out the station selection. The rectified output voltage of the FM detector 4 is supplied to an MPX (multiplex) demodulator circuit 5 to generate audio signals which are divided into left (L) and right (R) channels when the program is broadcast in stereo. If the rectified output voltage of the FM detector 4 passes through a filter 6 , then a radio data signal or a subcarrier of 57 kHz, which is amplitude modulated by a biphase-coded data signal, is sampled and then demodulated in a PLL circuit 7 . The demodulated output voltage is fed to a digital D-PLL circuit 8 and a decoder 9 . The D-PLL circuit 8 generates a clock for data demodulation based on the demodulated output voltage of the PLL circuit 7 . The clock generated in this way is fed to a gate circuit 10 . A lock detector circuit 11 determines that the D-PLL circuit 8 has been locked and generates a lock detector signal which is supplied to the gate circuit 10 to open it. A data signal, which is a biphase-coded output of the PLL circuit 7 , is decoded in synchronism with the clock generated in the D-PLL circuit 8 .

The output data of the decoder 9 is a group of 104 bits consisting of four 26-bit blocks as shown in FIG. 4, and is sequentially supplied to a group / block synchronous / error detection circuit 12 . In the circuit 12 , block synchronization with the group is performed based on 10-bit offset words each associated with 10-bit checkwords of corresponding blocks, while error detection of a 16-bit information word is performed based on the checkword. The error-determined data are then corrected in an error correction circuit 13 and fed to the control unit 14 .

The control unit 14 can be formed by a microcomputer (microprocessor) which reads the code information from the corresponding blocks in the radio data or the radio information (PI code, AF data, PS data etc.) which are assigned to the program currently being received and is, and the information is supplied to the control unit 14 sequentially group by group, and it stores the information in a memory 15 such as a RAM. The control unit 14 also controls, based on a station selection command from an operation unit 16, the reception frequency data for determining the division ratio of the programmable divider (not shown) of the PLL circuit, which is part of the input part 2 , to thereby carry out the station selection. The frequency to be received is, for example, the counted value of a counter. The operation of the memory 15 and the preset channel selection will be explained later.

The output of a level detector circuit 17 for determining a decrease in the signal field strength based on the IF signal level and the output of a multipath propagation detector circuit 18 for determining interference due to multipath reception based on the FM detector output are supplied to the control unit 14 . When these detector outputs are fed to the control unit 14 , it detects whether the reception conditions of the station currently being received have deteriorated, and the control unit 14 then controls the division ratio of the programmable divider so that another station in the network can be selected based on the network AF data previously stored in the memory 15 .

The process flow for identifying the AF data transmission process executed by the processor of the control unit 14 according to the present invention will now be explained with reference to the flow chart in FIG. 2.

The processor first sets an internal data counter to zero (step S1) and then reads the radio data (step S2). Based on the group type code and the version code included in block 2 of the read radio data, a decision is made based on whether the group is of type 0 , group A or not, that is, whether AF data is included in the radio data , or not (step S3). If it is not Type 0 , Group A, then no AF data will be obtained, in which case it is not necessary to identify the sending process of the AF data, so that the identification process ends. If it is Type 0 , Group A, a decision is made based on whether the station number data indicating the number of stations broadcasting the same program is included in the AF data for two stations being broadcast receives the radio data. That is, a decision is made based on whether the data items are the two data items included in the first block shown in Fig. 5 (step S4), and if the data does not contain station number data, then returns the flow returns to step S1 to repeat the above steps. If the data includes the station number data, then the combination of the station number data and the associated AF data is stored in the memory 15 (step S5). The data element count is then incremented by two (step S6), and a decision is made based on whether the count value N is 4 or not (or whether reading two blocks, that is, four data elements, is complete) (step S7). If N is not 4, the flow returns to step S2 to read AF data until N is 4.

If N is 4, a decision is made based on whether the second data item of the four data items stored in the memory 15 is the third AF data item or the fourth AF data item (step S8, S9) . If the second data item is not the same as any of the third and fourth AF data items, then the transmission method of the AF data is recognized as the method A, and then all data in the blocks after the fourth block are read to be stored in the memory 15 (step S10). On the other hand, if AF data is recognized as the third data item in step S8 or the same as the fourth data item in step S9, then the transmission method of the AF data is recognized as the B method, and the processor then selects, for example, a lot of AF data only the AF data of a group in which the currently received station is broadcasting at the center frequency, and then stores the AF data.

As shown in Fig. 5, each block does not contain the same AF data as in the other blocks in diagram (A) indicating method A, while the center station AF data of the group necessarily in corresponding blocks of the group in the diagram (B) indicating method B exist. Identification of the transmission method of the AF data is therefore carried out reliably in a short time by comparing the AF data from two blocks which are obtained in succession from radio data of type 0 , group A in order to determine a coincidence between them.

In method B too, an arrangement according to  which reads the data of the two blocks, where the first block contains station number data, and then the second block is read, one reliable reading of the data from the two blocks used for belong to the same group. Will continue a data comparison between only two blocks required, which is not just a more reliable Identification of the transmission process in a short time allowed, but also a confirmation of the Returns the number of AF data elements.

The method for selecting and storing AF data, which is executed by the processor as a subroutine when the data transmission method is identified as belonging to method B in step S11 in FIG. 2, will now be described with reference to the flow chart of FIG. 3 are explained.

The processor first sets the internal data counter to zero (step S21), then reads the AF data block by block, that is, a pair of AF data elements (step S22) to make a decision based on whether the station number data element is for the number is characteristic of the network stations in this group (step S23). In the case where the paired AF data items contain the station number data, a decision is made based on whether the center station AF data belonging to the pair of this station number data is the same as the frequency of the station currently being received. If the answer is "no", then the flow returns to step S22. If the answer is "yes", the station number data Na is stored in an inner register (step S25), then the center station AF data is stored in the memory 15 (step S26), and the count N of the data counter becomes "1""increased (step S27). Then, the count of the data counter is compared with the value Na of the inner register (step S28). If N is not equal to Na, the flow returns to step S22. On the other hand, if N is Na, the AF data selection process is completed. On the other hand, if the paired AF data items do not include the station number data in step S23, then a decision is made based on whether one of the AF data items that has been read is equal to the frequency of the station currently being received (step S29). If the AF data is not equal to the frequency, the process returns to step S22, and if the AF data is equal to the frequency, then the process proceeds to step S26 to store the paired AF data in the memory 15 to save. Repeating the above steps allows all AF data to be stored in the group whose center station is the station currently being received, ie only AF data of the stations that can be received from all stations of the network are stored.

In the method A, if the reception conditions become poor due to decreasing signal field strength or due to multipath propagation, then the control unit 14 selects the AF data of a network station, which can be received among all network stations that have previously been stored in the memory 15 , depending on the situation from the output of the level detector circuit 17 or the multipath propagation detector circuit 18 . If, on the other hand, the method is operated according to method B, the control unit 14 selects from the AF data in the group which has been previously selected and stored, in any case allowing the radio listeners to continue listening to the same program without interruption.

As described above, according to the present Invention to identify whether the AF data after  Method A or B can be broadcast by reading the AF data from only two blocks, the first and second Blocks from those obtained by demodulation, and then by comparing the data of one block with that others to determine coincidence between the two The block can be run using the method Identification of the sending process reliably in a short time Time to run. In method B, reading represents the first block containing the station number data, and then the second block that follows the first block, Always make sure that two blocks are read that are used for belong to the same group. Also the data comparison executed between only two blocks. the number of AF data items can therefore be checked at the same time how the process is identified.

Claims (6)

1. A method for identifying at the receiving end, in which of two methods station frequency data, which are contained in an RDS broadcast signal, are transmitted immediately by a received transmitter, wherein
in the one transmission method, a group of data blocks is transmitted in a repetitive manner, with the exception of the first block, each block contains transmission frequency data from two stations of a network of stations broadcasting an identical program, and in the first block a first data element contains the number of stations in the Network and a second data element contains frequency data of one of the transmitters and all frequency data are different from each other and
in the second transmission method, a plurality of groups of data blocks are transmitted sequentially, which groups each represent groups of stations of a network which broadcast an identical program, and each group consists of a central station and a plurality of stations of the network which can be received in a local area, and with the exception of the first block, each block contains frequency data from two stations, one of which is the central station of the group in question and the other one of the other stations within that group and in the first block a first data element represents the number of stations in the group and a second data element contains frequency data of the central station,
characterized in that after demodulation of the received radio signals, the transmission frequency data is determined only from the first and second blocks and a comparison of this transmission frequency data is carried out for coincidence, data coincidence indicating that the second transmission method is being carried out and non-coincidence indicating that the first transmission method is being carried out becomes. 2. The method according to claim 1, characterized in that it is first determined whether station frequency data in the Blocks of read data are included. 3. The method according to claim 1 or 2, characterized in that the data contents to determine the first data block of all blocks are checked for information included about the number of stations in the group. 4. RDS radio receiver for performing the method according to claim 1, comprising:
means for reading station frequency data only from the first and second blocks after demodulation of the received broadcast signals and
means for comparing the station frequency data in the first and second blocks for coincidence. 5. RDS receiver according to claim 4, characterized in that that it has a device that determines whether Station frequency data in the read data blocks are included. 6. RDS receiver according to claim 4 or 5, characterized characterized in that it contains a facility that determines whether the data blocks contain data that is on the number of stations in a group Respectively.