DE4036851A1 - RECEIVER - Google Patents

Description

The invention relates to an RDS receiver according to the Oberbe handle of claim 1.

With the RDS transmission type (radio data system) the information associated with the program being broadcast with a Main signal multiplexed and demodulated on the receiver side so that the listeners receive this information. The RDS system was in Europe put into use. The RDS becomes a two-phase coded data signal on a subcarrier of 57 kHz FSK-mo dulated (modulation by frequency shift keying), this Subcarrier has three times the frequency as the pilot tone (19th kHz) with FM stereo transmission. The data signal exists at RDS of four blocks, each of which has 26 information bits  points. One of the four blocks contains the CT signal that is for the time is indicative and for example every minute will.

This type of vehicle-side receivers is often stolen, for example at night, while the driver is away from his vehicle for a longer period of time. For this reason, the receiver is usually inserted into an easily releasable mechanism (quick-out bracket), which enables the user to pull the receiver out of the holder to take it with them when the vehicle user leaves the vehicle. This quick release mechanism has a holding box made of a metal sheet formed in a rectangular case as shown in Fig. 8 to hold the RDS receiver therein removably, and by screws or the like is arranged in a corresponding gap within the vehicle cabin of the vehicle. This receiving unit 1 has a plurality of pins 3 which extend in the direction of the receiver and through which the receiver is fed.

The invention has for its object an RDS receiver to create, in which the time information based on the CT data is displayed.

This object is achieved by the features of characterizing part of claim 1 solved.

Further configurations of the receiver result from the Subclaims.

The invention particularly provides an RDS receiver that a "built-in" clock to display the time information points out if the recipient is in an area where no CT Data is sent, used or if the flawless  Reception of the CT data is disturbed. The Erfin continues to create an RDS receiver that has a built-in clock, which are corrected by the CT data so that the clock maintains an exact time setting corresponding to the CT data. The RDS receiver also has a mechanism for quick release and a built-in clock for display the time display, which is automatically updated to the exact present time is set based on the CT data, when the receiver is returned to the trigger mechanism becomes.

Preferred embodiments of the receiver are described below gers using the drawing to explain other features described. Show it

Fig. 1 is a block diagram of an embodiment of the RDS receiver according to the invention,

Fig. 2 to 7 flowcharts for explaining the operation of embodiments of the invention, and

Fig. 8 is a side sectional view for explaining a mechanism that enables quick removal or release.

A preferred embodiment of the receiver is described below with reference to FIG. 1. An RF signal received via an antenna 10 is applied to an RF amplifier 11 for amplification. The amplified RF signal is then mixed with the frequency of a heterodyne receiver 13 by a mixer 12 and converted into an IF signal. The local oscillator 13 is a PLL type oscillator which changes its frequency in accordance with a strobe signal of a control circuit 19 which is in the form of a microcomputer. The IF signal is amplified by an IF amplifier 15 and then applied to an FM detector 16 for FM demodulation. The IF amplifier also outputs a signal on a signal line 23 which is indicative of the strength of the IF signal, the control circuit 19 receiving this signal via the line 23 . The demodulated output signal of the FM detector 16 is applied to an MPX (multiplex) circuit 17 and divided into R _out and L _out audio signals. The output of detector 16 is also fed to a data decoder 18 so that the CT data is extracted together with other RDS data. The CT data of the data decoder 18 are supplied to the control circuit 19 . The RF amplifier 11 , mixer 12 , Os zillator 13 , IF amplifier 15 and FM detector 16 together give a tuner 14th

A manual keyboard 20 is connected to the control circuit 19 and sends a station selection command via an input channel 19 b to the control circuit 19 for the selection of RDS-Sendestatio NEN. A CPU 19 c outputs a scan signal to the local oscillator 13 via a tuning control line 24 depending on the station selection command applied. The control circuit 19 includes a clock 19 d, which is equipped with associated circuits not shown, and which appropriately divides the pulse frequency of an oscillator 22 to provide suitable time information which is shown on a display unit 21 . In this way, the clock 19 d is incremented, for example, every second by a pulse CLK, this pulse being generated on the basis of the pulses of the oscillator 22 . The CPU 19 c outputs the time information TIME from the clock 19 d via an input channel 19 a to the display unit 21 . This built-in clock 19 d enables the user to tell the time, even if he is going to a district in which the CT data are not being sent. The initial time setting of the clock 19 d is carried out externally by using the hand keyboard 20 . When the CT signal is received, the CPU 19 c decodes the CT data so that the time information of the clock 19 d is corrected depending on the time or clock signal CLK, so that the display unit 21 displays the new exact time information. The clock 19 d is able to set the time in increments of one second, but it is not as accurate as the CT data usually be updated every minute and therefore the clock 19 d in an error of a few minutes per month result, if it runs without correction. However, this error can be corrected in the present invention in that the clock 19 d is corrected, for example, every minute based on the CT data in the manner mentioned above. This exact time information is shown on the display unit 21 . The decoded CT data can be sent directly to the display unit 21 for time display. The microcomputer 19 is provided with a built-in reserve supply or reserve energy source, which is not shown in the drawing. If the receiver is returned to the quick release mechanism within a day or so, bridging capacitors in the power line are sufficient to maintain the data stored in a memory, not shown, since the microcomputer actually draws only a small amount of current. In this case, the circuit connection of the shunt capacitors (or parallel capacitors) is suitably arranged, for example by reverse current protection diodes, in order to avoid a current flow which is generated by circuits other than the microcomputer.

Mode of operation

The method of operation of the receiver according to the invention is described below as soon as it is pulled out of the quick release mechanism, reference being made to the flow diagram according to FIG. 2. First, the user operates the keyboard 20 to interrupt the operation of the receiver. The control circuit 19 generates a scan signal to the local oscillator 13 via a tuning control line 24 (step 1 ). The control circuit 19 detects the IF signal level based on the signal present on the signal line 23 . If a required level of the IF signal is detected (step 2 ), then the sampling is interrupted (step 3 ). A decision is then made depending on whether the CT data are supplied by the data decoder 18 (step 4 ). If there is CT data in step 4 , the scanning operation is interrupted (step 6 ) and then the reception frequency of the station is stored in the control circuit 19 and the receiver is turned off. During the above steps, the frequency of the CT data sending station, which is received with good sensitivity, can be stored. The user now pulls the receiver out of the holder and carries it around with them.

The operation of the invention will now be described with reference to the flow chart of FIG. 3, provided that the receiver is returned to the quick release mechanism. When the user reinserts the receiver into this mechanism and turns the receiver on, this is detected by the program (step 1 ). The program reads the reception frequency that was stored in step 7 ( Fig. 1) (step 2 ) so that this station is received. A decision is then made as to whether the received station sends the CT data (step 3 ). When the CT data is received in step 3 , the control circuit decodes the CT data (step 4 ) to generate the time information and outputs the information on the clock signal CLK to the display unit 21 .

While the described embodiment is constructed in such a way that the station stored in step 7 ( FIG. 2) is automatically received, the receiver can also be modified in such a way that the scanning operation is carried out according to FIG sends the CT data, depending on the pressing of a particular key on the handheld keyboard 20 , when a vote has been made on a station that does not send RDS data.

The RDS receiver can be modified as shown in FIG. 4 so that the clock 19 d is incremented by each clock signal CLK in order to continue displaying the time information after the last CT data has been received in a suitable manner. The RDS receiver can also be modified in accordance with FIG. 2 in such a way that the clock 19 d is corrected by the decoded CT data and then the CPU outputs the time information TIME from the clock 19 d to the display unit 21 . The RDS receiver can also be modified as shown in Fig. 6 so that the scanning operation is performed to search for another station which transmits CT data if the CT data is lost during the reception of the RDS station went.

An RDS receiver receives a transmission signal on which a time-indicating signal (CT) is modulated by multiplexing with a main signal. The receiver has a tuner 14 for receiving and demodulating the transmission signal in order to emit a demodulated signal which contains a main signal and the time-indicating signal. Furthermore, a decoder 18 is provided to decode the demodulated signal and to extract the time-indicating signal. Furthermore, a control device 19 is provided in order to generate the current time information TIME, which is generated on the basis of the time-indicating signal. A display unit is used to display the current time information.

Claims (6)

1. RDS receiver for receiving a transmission signal on which a time-indicating signal (CT) is modulated with a main signal by multiplexing, characterized in that
that a tuner ( 14 ) is provided for receiving and demodulating the sensor design and emits a demodulated signal which contains the main signal and time-indicating signal,
that a decoding device ( 18 ) is provided for decoding the de-modulated signal and for extracting the time-indicating signal,
that a control device ( 19 ) for dispensing the current time information (TIME) is arranged, which is generated on the basis of the time-indicating signal, and that a display unit ( 21 ) is provided for displaying the current time information. 2. RDS receiver according to claim 1, characterized in that the control device ( 19 ) decodes the time-indicating signal and from it the current time information it generates. 3. RDS receiver according to claim 1, characterized in that
that the control unit ( 19 ) has a clock ( 19 d) for generating the current time information,
that the current time information of the clock is corrected by the time-indicating signal, so that the current time information is as accurate as the time-indicating signal. 4. RDS receiver according to claim 3, characterized in
that the control device ( 19 ) delivers a scanning signal to the tuner ( 14 ) if the tuner does not receive the appropriate station which transmits the signal indicating time, and
that the tuner ( 14 ) is looking for another station that transmits the time-indicating signal. 5. RDS receiver according to claim 3, characterized in
that the control device ( 19 ) emits a scanning signal to the tuner ( 14 ) when the control device is activated externally, and
that the tuner ( 14 ) is looking for a station that sends the signal signal indicating time. 6. RDS receiver according to claim 3, characterized in that
that the controller ( 19 ) records the frequency of the station which transmits the time indicating signal when the controller is activated externally, and
that the tuner ( 14 ) receives and demodulates the recorded transmission signal (transmission wave) to generate a demodulated signal which contains the time-indicating signal when the receiver is turned on again, so that the current time information of the watch is automatically generated by the time-indicating signal Signal is corrected.