DE4102735C2 - Procedure for selecting the reception frequency in an RDS receiver - Google Patents

Description

The invention relates to a method for selecting a Reception frequency in an RDS receiver according to the generic term of claim 1.

From DE 39 28 828 A1 an RDS radio receiver with a Device for automatically changing the reception frequency another station of the same program chain known. The transmitters are characterized by characteristic of them PI data, which may include a region code, around the To enable broadcasting of regionally different programs. Because the stations with the broadcast regional code are not are always regionalized on the frequency of a broadcasting station from the same program chain but with a different one Region code changed if no broadcasting station with the same region code can be received. With this device even then on one frequency with another Region code changed when the station is regionalized and broadcast different programs in the individual regions become. This then leads to an automatic switchover to another program, the original Regional program is lost.

Furthermore, DE 34 48 043 C2 describes the method for the determination another frequency described when a reception area to continue receiving the same program.

The invention has for its object the aforementioned  Train the device so that the automatic Switching reception frequencies of transmitting stations with different ones Region code one set before a change Regional program is not lost.

The task is characterized by the characterizing features of the claim 1 solved.

By storing the alternative frequencies of the one before Change the reception frequency received program and by the user can switch back, even if automatically is switched to another regional program, the reception of the regional program set before the change be restored.

Advantageous process variants are the subject of the subclaims.

The invention is described below using an exemplary embodiment with reference to the drawing explained. In the drawing shows

Fig. 1 is a diagram illustrating a base band coding structure of radio data,

Figs. 2A and 2B are diagrams of formats groups from 0a- and 0B-type illustrate

Fig. 3 is a block diagram illustrating the basic construction of an RDS receiver in which the inventive method is applied for selecting the reception frequency, and

Fig. 4 is a flowchart illustrating an example of the processing steps of the network function as an embodiment of the method for receiving frequency selection according to the invention.

Fig. 1 and 2 show the structure of RDS data.

As is apparent from Fig. 1, which shows a baseband coding structure of a radio data signal, data of 104 bits are processed as a group in the radio data signal and repeatedly transmitted by multiplex transmission. A group comprises four blocks, each with 26 bits. Each block comprises an information word with 16 bits and a check word with 10 bits. Each group is classified into 16 types, ie type 0 to type 15, which are designated by 4 bits according to the information content. Furthermore, two versions A and B are defined for each of the types (0 to 15).

In Fig. 2A and 2B, respectively, the format of groups of 0a- and 0B type illustrated. In the group of the 0A type, program identification data (hereinafter PI data) with 16 bits, consisting of a country code, a regional code and a program code, are arranged in a block 1. Different codes, e.g. B. a group type code, version or execution code (B ₀ code), a traffic information transmission station identification code (TP code), a program content identification code (PTY code) and the like, arranged in a block 2. In a block 3, transmission station frequency data or alternative frequencies (hereinafter referred to as AF data) of transmission stations which emit the same program are arranged. Name data from radio stations (hereinafter referred to as PS data) are arranged in a block 4. In the 0B type group, as illustrated in FIG. 2B, only the content of the block 3 differs from that in the 0A type group. In detail, the PI code is arranged in block 3. This means that the AF data of the network radio stations is only transmitted by the group of the 0A type. The PS data are transmitted by the groups of the 0A and the 0B type.

The block diagram shown in Fig. 3 generally illustrates an example of the basic structure of an RDS receiver to which a method for selecting the reception frequency is applied. According to the diagram, an FM-multiplexed radio wave received by an antenna 1 is fed to an input stage 2 , by means of which the desired station is selected and the signal of the selected station is converted into an intermediate frequency (IF). The signal is then fed to an FM detector 4 via an IF amplifier 3 . For example, a PLL synthesizer system with a PLL circuit including a programmable frequency divider is used in input stage 2 . The frequency division ratio of the programmable frequency divider is controlled by means of a control device 13 explained later, so that a station selection operation is carried out. The detection output signal of the FM detector 4 is supplied to an MPX (multiplex) demodulation circuit 5 and, in the case of stereo transmission, is separated into sound signals for the left (L) and right (R) channels. The signals of the left and the right channel are provided via a blocking or squelch circuit 18 as sound reproduction output signals. The blocking circuit 18 is activated by means of the control device 13 .

On the other hand, by transmitting the detection output signal of the FM detector 4 via a filter 6, a 57 kHz subcarrier which is amplitude-modulated by a two-phase coded data signal, ie a radio data signal, is extracted and demodulated by a PLL circuit 7 . The de-modulated output signal is fed to a digital PLL circuit (D-PLL circuit) 8 and a decoder 9 . In the D-PLL circuit 8 , 7 clock signals for data demodulation are generated on the basis of the demodulated output signal of the PLL circuit. In the decoder 9 , the two-phase coded data signal is decoded as a demodulated output signal of the PLL circuit 7 in synchronism with the clock signals generated by the D-PLL circuit 8 . A hold state detection circuit 10 detects hold and unlock states of the D-PLL circuit 8 . The holding areas of the PLL circuit 7 and the D-PLL circuit 8 who the switching circuit controlled by means of a detection output signal of the detection 10 .

The output data signal of the decoder 9 has a group unit of 104 bits, comprising four blocks, each consisting of 26 bits as shown in FIG. 1. The output data signal is supplied to a group, block synchronization and error detection circuit 11 .

In the detection circuit 11 , group and block synchronization is carried out on the basis of an offset word of 10 bits, which are assigned in accordance with the check word of 10 bits of each block. Furthermore, errors in the information word with 16 bits are detected based on the check word. The error-detected data signal is corrected in the next stage by means of an error correction circuit 12 . The error-corrected data signal is then fed to the control device 13 .

The control device 13 is formed by a microcomputer and capable of performing the network following function in the following manner. First, the controller 13 retrieves the code information of each block in the radio data signal which is sequentially input on a group unit basis, that is, radio information regarding the program content of the broadcasting station that is being received, and stores the information in a read / write memory (in following RAM) 14 . In response to a station selection command from an operating unit 15 , the control device 13 regulates the frequency division ratio of the programmable frequency divider (not shown) of the PLL circuit, which forms part of the input stage 2 , where it is executed by the network follow-up function. The network follow-up function has a regional OFF mode in which the regional code is ignored during the PI test and the regional ON mode in which the PI test including the regional code is carried out. One of these modes of operation is entered via the control part 15 by the user.

A level detection circuit 16 is provided to detect the received signal level (field strength) based on the IF signal level in the IF amplifier 3 . Furthermore, a station detection circuit 17 is provided which detects the presence of a receiving station in order to generate a station detection signal in this way when the IF signal level in the IF amplifier 3 is higher than a predetermined level and at the same time the detection output signal of the so-called S-curves Characteristic in the FM detector 4 lies in a predetermined Pe gel range. The received signal level detected by the level detection circuit 16 and the station detection signal generated by the station detection circuit 17 are supplied to the control device 13 .

In the following, the processing steps of the network sequence function, which are carried out by the processor of the control device 13 , will be described with reference to the flow chart of FIG. 4. In this example, it is assumed that the regional OFF operating mode has previously been specified in the control unit 15 and a regional ON flag has been reset by this specification. It is further assumed that an AF data signal obtained by demodulating the received broadcast wave has already been recovered and the AF list of the network stations, which is the same as that of the station just received, has already been generated in the memory 14 .

The processor (control device) first retrieves the AF data signal and the PI data signal of the radio wave currently received and stores this data in predetermined areas of the memory 14 (step S1). According to the above-mentioned AF list, the processor reads out one of the AF data signals in the AF list from the memory 14 (step S2). Then the processor switches on the blocking circuit 18 to effect the sound blocking (step S3) and transmits the AF data signal read out to the PLL circuit (not shown) in the input stage 2 (step S4). At the same time, processor 13 sets a PLL timer to measure the time period T ₁ required to lock the PLL circuit (step S5). The AF data signal supplied to the PLL circuit is set to the programmable frequency divider PLL circuit, so that the reception frequency changes from the current reception frequency to another frequency of a network station within the time period specified by the PLL timer.

After the lock time of the PLL timer (step S6), the processor 13 judges the presence or absence of a receiving station by monitoring the station detection signal from the station detection circuit 17 (step S7). If there is a receiving station, the processor 13 recovers the received signal level of the received network station from the level detection circuit 16 (step S8). The processor 13 then judges whether or not the received signal level is equal to or higher than a predetermined set level Vs (step S9). If the received signal level is higher than the set level Vs, the processor recovers the PI data signal of the receiving station (step S10). Then, the processor 13 judges whether the regional ON flag is set or not (step S11). Since the regional OFF mode has previously been entered, the regional ON flag has been reset. Therefore, the processor 13 judges whether the recovered PI data signal and the PI data signal held in step S1 coincide with each other except for the area code (step S12a). If the PI data coincide with each other, the processor 13 turns the blocking circuit 18 off to release the sound block (step S13). Through these operations, the frequency of the network station currently being received is set as the new reception frequency.

On the other hand, in the regional ON mode in which the regional ON flag is set, the processor 13 judges whether the recovered PI data signal and the PI data signal held in step S1 coincide with each other (step S12b). The processor then proceeds to step S19 to release the tone lock when the PI data coincide with each other.

If it is judged in step S7 that there is no receiving station, it is judged in step S9 that the received signal level is below the set level, or if it is judged in step S12a or S12b that the PI data does not coincide with each other, the processor judges whether the operations of checking the existence of the receiving station, checking the received signal level and determining the match of the PI data have been performed for all the data in the AF list (step S14). If the operations have not been performed, the processor 13 returns to step S2 to repeat the procedure described above. When the operations for all the data in the AL list have been performed, the processor 13 reads out the previous AF data stored in step S1 (step S15), effects the sound lock (step S16) and then transmits the read AF data the PLL circuit (step S16). At the same time, the processor sets the PLL circuit (step S17). After the time of the PLL timer has elapsed (step S18), the processor releases the sound lock (step S19). Through these operations, the reception frequency is returned to the frequency of the previous reception station.

The normal network tracking function has been described above. According to the invention, the functions described below have been added to the operations described above. After the tone lock is released at step S13, the processor sets a switch-back timer to measure a certain constant time period T ₂ (step S20). Within the constant time period T ₂ before the time of the downshift timer has elapsed, the processor 13 monitors the generation of a downshift command which is issued by the user by means of the operating section 15 (steps S21 and S22). If the downshift command is not generated before the downshift timer has elapsed, the routine of this routine is ended without performing any further operation. When the downshift command is generated, the processor unlocks (step S23), sets the regional ON flag (step S24), and then proceeds to step S15.

In other words, if a station outside the area of the first receiving station is received in the regional OFF mode by the network follow-up function, the reception frequency can be within the constant time period T ₂ upon the triggering of the downshift command by the user by means of the operating section to the first one Receiving frequency be switched back, since the AF data signal of the receiving station selected or coordinated before the network follow-up function is recovered by the switch-back command.

When the regional OFF mode is operated by an operator error is specified erroneously and a station outside of a desired area is received even though the Be users of the network follow-up function on the same network stations in the Want to limit the area in which the first reception sta tion, the receiving station can be added by men of the function described above by triggering the Downshift command automatically to the previous station be switched back when the user hits the receiving station switch back to a station in the previous area wishes. Since the regional ON flag is set in step S24 has been in this case the regional EIN operation type automatically specified. Then the network sequence function limited to the same network stations in the area, in which the previous receiving station is located. How has been described in detail above, in which he inventive method for receiving frequency selection that  AF data signal of the first station saved in advance. When a Station outside the area in which the first station lies in the regional AUS-Be through the network follow-up function mode is received, the reception frequency can be changed the stored AF data signal in response to the command to previous reception frequency can be switched back. On due to this feature, the receiving station can become a sta tion in the desired area, although the same network station outside the desired area in the regional OFF mode is received.

Claims (4)

1. A method of selecting a reception frequency in an RDS receiver, for receiving an RDS broadcast wave on which a number of AF data signals (alternative frequencies) of the same program chain and PI data signals including a region code are superimposed to change the reception frequency to another Switch frequency of the same program chain, which is given by the AF data, comprehensive

• a first step (S1) for storing AF data and PI data of a radio wave of a currently selected reception frequency,
• a second step (S6-S9) for determining whether another transmission station can be received,
• a third step (S12a, S13) for setting a new reception frequency to the frequency of the transmitting station determined in the second step if PI data of the transmitting station obtained in the second step and the PI data obtained in the first step match up to the regional code,

characterized in that

• - In a fourth step (S20-S24 → S15-S19) the reception frequency is switched back to the reception frequency given by the AF data stored in the first step when the operator triggers a switch-back command.

2. The method according to claim 1, characterized, that the fourth step only during a set Duration (T₂) after the end of the third step can be. 3. The method according to claim 1 or 2, characterized, that match between the PI data at the third Step including the area code is performed after the operation of the fourth step is carried out has been.