DE3903468A1 - INPUT TO PLAY WARNING MESSAGES - Google Patents

Abstract

A system is described for the reception and reproduction of warning messages by means of broadcast receivers in warning systems, wherein, via an additional signal in the broadcast signal, a warning message can be retrieved from a library of stored warning messages resident in the receiver. <IMAGE>

Description

The invention relates to the preamble of claim 1 defined facilities for the reproduction of warning messages in warn systems that are equipped with radio receivers.

It is known to play traffic reports for the general I use the radio transmitter and radio receiver. The traffic announcement is broadcast by a speaker in the studio read out transmitter. These announcements will continue during their duration additionally a special announcement identification of 125 Hz over a 57 kHz subcarrier broadcast. The radio receivers are thereby enabled automatically during such an announcement increase the volume of the playback of the traffic announcement. The Reading the traffic announcement requires a lot of time because the verbal formulation of each message through a high level of redundancy the information is marked.

In certain emergency situations, the necessary may be necessary Airtime is not available. For example, if on the radio path to a larger number of persons to be warned groups of different instructions in a short period of time ben transmitter or the same transmitter chain should be transmitted.

The invention was therefore based on the object of receiving time shorten a warning message.

The solution to this problem according to the invention is that in claim 1 marked characteristics marked.

An embodiment of a device is shown in the drawing with the invention explained in more detail below.

Fig. 1 shows a block diagram.

The device for receiving and reproducing warning messages is connected to an FM radio receiver, which receives the carrier of the transmitter via an antenna 1 , which is set by means of the tuner 2 . The signals modulated onto the carrier are separated from the carrier in IF stage 3 . The usual MPX signal, which contains all information, is available at the output of IF stage 3 .

A 57 kHz filter 4 extracts the signal components in the vicinity of the 57 kHz subcarrier frequency from the MPX signal.

Parallel to the input of the filter 4 is the input of the usual NF level 7 , which further processes the normal program contribution of the transmitter and makes it audible through the loudspeaker 8 .

If radio data signals or traffic announcements are also transmitted via the set transmitter in addition to the program contributions, then a 57 kHz auxiliary carrier can be removed from the filter output, the amplitude of which is modulated. This 57 kHz subcarrier is supplied, inter alia, to an RDS demodulator 5 connected to the filter. If the set transmitter transmits radio data signals, the demodulator 5 feeds an RDS block decoder 6 with pulses. At the data outputs a ₀ - a _{15 of} the block decoder 6 , 16 bit wide data words are alternately output in the block cycle. At the output b _o the block cycle itself and at the output b _n the block number can be removed.

Two 16-bit wide pre-memories 9 , 10 are connected in parallel to the data outputs a ₀ - a ₁₅ . Which is also 16-bit wide output of the Prior memory 9 on the one hand of a associated with the 16-bit input latch 11, on the other hand with the 16-bit wide input of a transcoder 12, the 3-bit-wide output on the 3-bit wide A gang c ₁ - c _{3 of} a first coincidence circuit 13 is performed.

The 16 bit wide data output of the second pre-memory 10 is connected to the inputs of a second coincidence circuit 14 , at whose other inputs a 16 bit wide address memory 15 is connected, in which the address of the alarm system is permanently stored.

The 1-bit wide output of the second coincidence circuit 14 is connected on the one hand to a wake-up tone generator 16 , and on the other hand is routed to the first control input of a takeover gate circuit 17 , the output line of which is connected to the takeover input of the intermediate store 11 . A second control input of the acquisition gate circuit 17 is controlled by a clock gate 23 via a timing element 18 and a first release gate 19 .

A third control input of the takeover gate circuit 17 is connected to the 1-bit output of the first coincidence circuit 13 .

The three further data inputs d ₁ - d _{3 of} the first coincidence circuit 13 are connected to the outputs of three control flip-flops 24 , 25 , 26 , each of which has data adjacent to the LSB (Lowest Significant Bit) output Data outputs a ₂ , a ₃ and a _{4 of} the block decoder 6 take over if their takeover input is controlled by the clock gate 21 .

To transfer the data from the block decoder 6 in the prestore 9 of the takeover input of the prestore 9 is tor via the first release 19 driven by the clock gate 23 and cher for transfer to the Vorspei driven 10 whose transfer input via a second enable gate 27 from the clock gate 22 after setting the previously the clock gate 20 has caused the resetting of all control flip-flops in the device and the two before memories 9 , 10 .

The second inputs of the two enable gates 19 and 27 are connected to an enable bus 28 which is connected to the output of an AND gate 29 , which in turn is controlled by three further control flip-flops 30 , 31 , 32 . Of these, the control flip-flop 32 is initially each other via a second AND circuit 33 comprising the first five, the MSB (Most Significant Bit) data outputs a ₁₅ - a ₁₁ of the block decoder connected, while the further control flip-flop 31 is connected to the LSB data output a ₀ and the control flip-flop 30 with the data output a _{1 of} the block decoder 6 which is directly adjacent to it.

The clock gates 20 to 23 are connected on the input side to the block clock output b _o of the block decoder 6 and on the other hand to the block number output b _n of the block decoder 6 .

The circuit described so far works in the following way:

The FM radio receiver receives an endless stream of digital data via the 57 kHz subcarrier when tuned to an RDS transmitter. This data serves on the one hand to synchronize the receiver with the transmitter, to a certain extent to correct errors that occur the transmission path from the transmitter to the receiver have arisen, and finally the transmission of control signals for the radio receiver and for peripheral devices connected to it. In the present case, a library with memories 35 for defined warning messages forms the peripheral device to be controlled.

According to the RDS standard, the control signals for peripheral devices in group 9 of the RDS signal are transmitted and repeated continuously in the endless data stream at a predetermined time interval. The control signals of group 9 , like the signals of the other groups, are divided into four successive blocks. One of the clock gates 20 to 23 is assigned to one of these blocks. Via the clock gate 20 , which belongs to the first block, all six control flip-flops 24 to 26 , 32 to 34 and the pre-memories 9 and 10 are reset.

About the clock gate 21 , which belongs to the second block, the control flip-flops 24-26 , 30-32 to take over the bits at the assigned data outputs of the block decoder 6 are caused. If in the second block the control flip-flop 32 recognizes the signal for the group 9 , its output signal prepares the first AND gate 29 to receive the clock pulse from the clock gate 22 , which belongs to the third block, as a takeover pulse via the release gate 27 forward to the pre-memory 10 and to forward the clock pulse from the clock gate 23 , which belongs to the fourth block, via the release gate 19 on the one hand as a take-over pulse to the pre-memory 9 and on the other hand via the time element 18 and the take-over gate 17 to the buffer memory 11 .

The state of all outputs a ₀ - a _{15 of} the block decoder 6 is transferred to the latch 10 during the third block by the takeover pulse from the clock gate 22 . The combination of the assigned outputs represents the device address. If this corresponds to the device address stored in the address memory 15 , a control signal arises at the output of the coincidence circuit 14 , which triggers an alarm tone via the alarm generator 16 and, on the other hand, pre-unlocks the transfer gate 17 . The loudspeaker 8 of the radio via an OR circuit 38 can be used to reproduce the alarm tone, but this is not a mandatory measure.

The state of all outputs a ₀ - a _{15 of} the block decoder 6 is transferred to the pre-memory 9 during the fourth block by the take-over pulse from the clock gate 23 . On the one hand, this information is used to calculate a 3-bit keyword in a recoder 12 . If this keyword matches the output signal of the control flip-flops 24 , 25 and 26 , which have been set by the clock pulse from the clock gate 21 assigned to the second block, then the coincidence circuit 13 also enables the second input in the takeover gate 17 , so that the delayed by the timing element 18 takeover pulse, which is assigned to the fourth block, transfers the information contained in the preliminary memory 9 into the buffer memory 11 .

The output of the buffer store 11 forms the interface to the peripheral device, in which the store 35 forms a library for the defined warning message. A call unit 34 selects the warning message determined on the basis of the occupied outputs of the buffer memory 11 , which then z. B. is output via the display 36 . When the selection is complete, the buffer 11 is deleted by the call unit 34 via the reset line.

If the warning message is to be issued at the same time via a voice processor 37 , then one can again use the loudspeaker 8 of the radio via the OR circuit 38 for voice reproduction.

The time that the warning message is output through the speech processor needed can be exploited by means of the invention in whose, similarly constructed systems pre-output others initiate saved warnings. Thus, that of the invention underlying task completely solved.  

Legend

1 antenna
2 tuners
3 IF level
4 57 kHz filters
5 amplitude demodulator
6 RDS block decoders
7 NF level
8 speakers
9 First memory
10 Second pre-memory
11 buffers
12 recoders
13 First coincidence circuit
14 Second coincidence circuit
15 address memory
16 alarm tone generator
17 takeover gate
18 timer
19 First release gate
20, 21, 22, 23 cycle goals
24, 25, 26 control flip-flops
27 Second release gate
28 release bus
29 First and-gate
30, 31, 32 control flip-flops
33 second AND gate
34 Call switching
35 message memory
36 display
37 speech processor
38 OR circuit

Claims (1)

Which (5) comprise means for reproducing alerts in warning installations equipped with radio receivers (1, 2, 3, 7, 8), an amplitude demodulator for a means of a 57 kHz filter (4) the filtered subcarrier, characterized featured,
that the demodulator ( 5 ) is followed by a radio data signal block decoder ( 6 ) which controls the selection and playback of a number of warning messages defined in memories ( 35 ) via a 16 bit wide buffer ( 11 ), and that the Intermediate memory ( 11 ) is connected on the input side to a 16-bit wide preliminary memory ( 9 ), while its takeover input is connected to a takeover gate ( 17 ) which, via a timing element ( 18 ) and a first release gate ( 19 ), receives a takeover pulse from the clock gate ( 23 ). receives
that a first control input of the takeover gate (17) is connected to a first coincidence circuit (14) and a second control input of the takeover gate (17) having a second coincidence circuit (13), that the first coincidence circuit (14) on the one hand to a store (15) with the address of the warning system and on the other hand connected to the second 16 bit wide output of a second pre-memory ( 10 ),
that three data inputs ( d ₁ - d ₃ ) of the second coincidence circuit ( 13 ) with three control flip-flops ( 24 , 25 , 26 ) and three further data inputs ( c ₁ - c ₃ ) with the 3-bit wide output of a recoder ( 12 ) are connected, which is connected with its 16-bit input to the output of the first pre-memory ( 9 ),
that the first and also the second pre-memory ( 9 , 10 ) are connected in parallel to the 16-bit data output of the block decoder, that the takeover input of the first pre-memory ( 9 ) via the free gate ( 19 ) with a fourth clock gate ( 23 ), the Take-over input of the second pre-memory ( 10 ) via a second release gate ( 27 ) with a third clock gate ( 22 ), the reset inputs of both pre-memories and the control flip-flops ( 24 , 25 , 26 , 30 , 31 , 32 ) with one first clock gate ( 20 ) the transfer inputs of all control flip-flops are connected to a second clock gate ( 21 ) and all four clock gates are connected via a block number bus and a block clock bus to the corresponding outputs ( b _o , b _n ) of the block decoder ( 6 ) are,
that the second inputs of the two enable gates ( 19 , 27 ) are connected to an enable bus ( 28 ) which is connected via a first AND gate ( 29 ) to the outputs of the three further control flip-flops ( 30 , 31 , 32 ) is closed
that the data input of the first of these control flip-flops ( 32 ) via a second AND circuit ( 33 ) with the HS bit data output ( a ₁₅ ) and the four adjacent data outputs ( a ₁₄ - a ₁₁ ) of the block decoder ( 6 ), the data input of the second of these control flip-flops ( 31 ) with the LS bit data output ( a ₀ ) and the data inputs of the other control flip-flops ( 30 , 26 , 25 , 24 ) with the LSB Data output are connected in increasing order to adjacent data outputs ( a ₁ - a ₄ ) of the block decoder ( 6 ).