DE4015195A1 - Signal selective radio device - produces call signal which can be transmitted or received and its origin identified from digital code - Google Patents

Abstract

A peripheral device for a radio appts. comprising a code generator (100) to produce a coded address which comprises a personal address and a call address and a radio transmission signal corresponding to the coded address. A code receiver receives a radio signal from the radio appts. and converts it to a digital signal. An analyser analyses the digital signal according to the call address and the address of the sender. At least the sender address is temporarily stored in memory and is read out and optically represented on a display. USE/ADVANTAGE - In CB, amateur or service radio.

Description

The invention relates to an additional device for a radio, especially for CB radio, amateur radio or company radio, for Generate and / or receive a send or receive signals according to claim 1.

Additional devices for radio devices with selective call jack are known for some time. Such devices generate or receive For example, one of five consecutive tones nalen existing analog call signal, which a certain is assigned to the radio subscriber, and make this possible Establishing a radio connection even if that Radio of the person to be called is not in the operating but is only in standby mode. To record a radio a call signal is generated by the caller, which encodes according to the identifier of the person to be called is. The call signal can be within the range of intended radio equipment can be received. Realize that Additional device in the call signal its own call sign, so the device emits an alarm signal. The identity of the Anru The call sign cannot be found. Will the Ange called find out who can get in touch with him would like, so he must switch his radio to broadcast and a corresponding request to the connected radio part judge participants. If the caller is no longer on reception, the identification request remains unanswered.

From the magazine "CB-Funk", May 1990 edition, is one Timer for selective call devices known in which the  Receiver after receiving and recognizing your own call time chens returns an acknowledgment signal to the transmitter and still remains on standby for a short period of time. During this period, the caller can identify Send ad message, which with a recording device of the receiving unit can be stored. Identified the caller is not at ease, but here too there is anger fene no direct way to determine the origin of the received To experience call signal.

The object of the invention is therefore to provide a device for a radio for generating and / or receiving a call signal to create nals whose origin is identifiable.

This problem is solved by the features of Claim 1.

An additional device for a radio, in particular for CB radio, Amateur radio or company radio, contains a code transmitter for Generate a first coded address, which is made from its own an address and a call address, and one of the coded address corresponding radio transmission signal for the Radio. A code receiver effects the inclusion of a Radio reception signal from the radio and the conversion of the radio reception signal into a digital signal. The additional ge advises a device for evaluating the digital signals according to call address and address of the sender, whereby min least the address of the transmitter in a memory between is saved. With a display device that is out the buffer address of the sender optically shown.

Advantageous further developments of the invention result from the subclaims.  

In order to be able to store more than one sending address, points According to claim 2, the memory has at least two digits Number of storage spaces on.

Since a variety of radio reception signals from the additional device len received, converted and saved one after the other that can be, according to claim 3, a memory counter Determination of the storage space saved in the memory provided address of the transmitter or transmitters.

The respective memory counter status is displayed according to claim 4 on an additional display of the ad contraption.

The number of display elements is thereby according to claim 5 reduced that the display of the send addresses and the display the memory counter is alphanumeric.

A storage location selection circuit enables according to claim 6 the special selection of a stored address.

To convert the first address into a radio transmit signal the code transmitter according to claim 7 has a first shift register ster with a defined bit width of preferably 32 Bit, a control logic and a linking device.

The first address generated by the code transmitter exists according to Claim 8 from its own address and a call address, which can be loaded via switches and in the first shift regi are storable.

Because the generation of the radio transmit signal and the conversion tion of the radio reception signal is digital, are according to Claim 9 of an oscillator of the control logic pulses provided a fundamental frequency. With the help of a divider  circuit can be pulses from the fundamental frequency generate derived frequencies.

According to claim 10, the radio transmit signal consists of a Synchronization signal and an address signal.

The control logic is designed according to claim 11 such that a first control device generating the synchronization tion signal with a defined bit width of in particular 8 bits and a second control device for generation of the address signal with a defined bit width of in particular special 32 bits.

For the gradual conversion of the coded address into the Radio transmit signal, performs the control logic according to claim 12 the first shift register and the linking device Clock pulses and the first shift register control signals.

Furthermore, the control logic of the link device leads device according to claim 13 pulses of the derived frequencies to.

The control logic effects according to claim 14 before generation the address signal the generation of the synchronization signal, whereby the reception and conversion of radio reception Signal is facilitated.

The first shift register becomes serial according to claim 15 read out. Signals according to the content of the first Shift registers are successively the logic pre direction fed.

The linking device arranges according to claim 16 serially supplied signals according to their logical State pulses of the derived frequencies too.  

To avoid harmonics, the content of the first shift register associated pulses of the derived ten frequencies according to claim 17 within the link device passed through a low pass filter.

To obtain a constant signal independent of the input level received, the code receiver according to claim 18 has one Control amplifier.

The radio reception signal is according to claim 19 in the code receiver through a multi-stage filter amplifier This defines impulses of the derived frequencies be reinforced.

To separate the pulses of the different frequencies points according to claim 20, the code receiver on a PLL circuit.

According to claim 21, the code receiver carries a further door tion of the radio receive signal in address data and clock pulses by.

The separated address data are stored as a digital signal in a second shift register according to claim 22 added.

By means of a comparator device according to claim 23 the call address contained in the digital signal with its own comparable address.

If the call address matches your own address a reconfirmation signal is generated according to claim 24. The sender of the call thus becomes aware of whether his call has reached a recipient.

Since according to claim 25, the address corresponding to the advertisement the transmitter can be transferred to the first shift register,  The caller does not need the address of the person to be called to enter yourself.

According to claim 26, the reconfirmation signal consists of the Address of the sender, the address of the recipient and one Confirmation signal. This makes it the recipient of the Rückbe confirmation signal possible, additional knowledge about receive who received his call.

According to claim 27, the additional device has a device for Reception of the confirmation signal.

To reach the highest possible number of radio subscribers or to be able to identify, is according to claim 28 Processing and the display of at least four digits Send address provided.

The additional device is according to claim 29 for CB radio, operation radio or intended for amateur radio.

According to claim 30 is an integration of the additional device in the radio provided.

Following the sending of the sending address, according to Claim 31 transmitted an alphanumeric message will. With a dedicated receiver this message will be received and recorded.

Another advantage of the invention is that Radio transmit signal is very short and therefore only from third parties recorded with very elaborate means and abusive can be sent.

Further details, aspects and advantages of the present Invention result from the following description with reference to the drawing.  

It shows:

Fig. 1 a first embodiment of the encoder of the dung OF INVENTION in the block diagram,

Fig. 2 shows a first embodiment of the first part of the code receiver of the invention in a block diagram,

Fig. 3 shows a first embodiment of the second part of the code receiver of the evaluation device, the address memory and the display of the invention diagram in block

Fig. 4 shows a first embodiment of the first part of the Sen DERS of the invention in the detailed diagram,

Fig. 5 shows a first embodiment of the second part of the transmitter of the invention in the detailed diagram,

Fig. 6 shows a first embodiment of the control amplifier, filter and comparator of the invention in detaillier th diagram

Fig. 7 shows a first embodiment of the PLL signal generating of the invention in the detailed diagram,

Fig. 8 shows a first embodiment of the second shift register, the address memory, the decoder, the display of the address and the comparator of the invention in the detailed circuit diagram and

Fig. 9 shows a first embodiment of the address counter, as well as decoder and display of the memory counter of the invention in the detailed circuit diagram.

Referring to FIG. 1, an encoder 100, a first Schieberegi edge 110, a control logic 130, and a processing Verknüpfungsvorrich 150. The shift register 110 consists of four shift register modules 111 , 112 , 113 , 114 connected in series. DIP switches 115 , 116 are connected to the shift register blocks 111 and 112 , while coding switches 117 , 118 are connected to the shift register blocks 113 and 114, respectively. The shift register 110 is pelt to both the control logic 130 as well as to the gekop linking apparatus 150th The control logic 130 has an oscillator and divider circuit 131 , which is connected to a first 132 and a second control device 133 . A switch 135 is connected to the control devices 132 , 133 . The control logic 130 is coupled to the shift register 110 and to the linking device 150 . The logic device 150 has a gate circuit 151 at its input, which in turn is connected to the control device 130 and to the shift register 110 . Furthermore, the linking device contains a low-pass filter 152 coupled to the output of the gate circuit 151 , the output of which is connected via an attenuator 153 to an LF output 154 of the code transmitter.

The code transmitter 100 is used to generate a first coded address, which consists of its own address and a call address, and a radio transmission signal corresponding to the coded address for the radio. The own address and the call address are recorded via the DIP switches 115 , 116 or via the coding switches 117 , 118 and loaded in parallel into the 8-bit wide shift register modules 111 , 112 , 113 , 114 . The oscillator and divider circuit 131 is connected to a quartz crystal 134 and generates an electrical fundamental vibration of 32.768 kHz, from which electrical vibrations with the frequency of 1.024 kHz and 1.365 kHz are derived by division. From the Oszilla gate and divider circuit 131 , the derived electrical vibrations of the gate circuit 151 are supplied. The radio transmit signal to be generated consists of a Sy chroni sierungssignal and an address signal. When the switch 135 is closed , the first control device 132 begins to generate the synchronization signal. An 8-bit long continuous tone of 1365 Hz is generated and fed to the NF output 154 . One bit is 32 ms long. Immediately after the 8-bit long tone has ended, the address signal is generated under the control of the second control device 133 . The shift register 110 are supplied signals from the control logic 130 control and clock formed, whereupon the contents of the shift register is read out serially and signals corresponding to the content of the shift register 110 bit by bit knüpfungsvorrichtung to the input of Ver 150, ie to the input of the gate circuit, 151 be directed. Another input of the gate circuit 151 , the clock pulses formed by the control logic are supplied. Furthermore, the gate circuit 151 is supplied by the oscillator and divider circuit 131 with pulses of the frequencies derived from the fundamental frequency. The formation of the address signal takes place in such a way that the content of the shift register is supplied bit-wise to the gate circuit 151 and, after being linked to the clock pulses, each of the signals is assigned oscillation pulses of the frequencies derived. A logic "1" is assigned pulses of frequency 1024 Hz and a logic "0" pulse of frequency 1365 Hz. The pulses are maintained over a period of 32 ms each. The address signal thus consists of 32 strings that are strung together and follow two different frequencies. Since the pulses of the radio transmit signal are square-wave pulses, a two-stage low-pass filter 152 is connected downstream of the gate circuit 151 to avoid harmonics. With a weaker 153 connected to the output of the low-pass filter 152 , the strength of the radio transmit signal can be weakened to a desired value for further processing. The output of the attenuator 153 is connected to the output terminal 154 of the code transmitter. After the radio transmit signal has been generated, the switch 135 is opened again.

Fig. 2 shows the part of a code receiver 200, which the receiving radio-receiving signals and the separation of the signals in clock and data signals is used.

The code receiver 200 has an input connection 220 to which an arrangement of components connected in series is connected. The arrangement consists of a control amplifier 201 , a filter 202 , a filter 203 , a limiter 204 , a PLL circuit 205 and a limiter 206 , the components being connected together in series in this order. The output of the limiter 206 is connected to a data line 223 , the input of an integrator 207 and the input of a differentiator 211 . The output of the integrator 207 is coupled to a limiter 208 , which in turn is connected to the SET input of a memory 209 . The output of the memory 209 is connected to a reset SR 221 line and to a timer 210 . The output of the timer 210 is fed back to a RESET connection of the memory 209 . The output of the differentiator 211 is connected to the input of a clock oscillator 212 . The output of Clockos zillators 212 is coupled to the Clock SR 222 line .

The radio reception signal arrives on the input line 220 and is fed to the control amplifier 201 , which generates a signal that is independent of the input level. The two-stage filter amplifier 202 , 203 coupled to the control amplifier 201 effects the defined amplification of the pulses of the frequencies 1024 Hz and 1365 Hz contained in the signal. The signal then passes through the limiter 204 into the PLL circuit 205 , which separates the two Frequen cen causes. The signal is then supplied to data line 223 via limiter 206 . The arrangement, which consists of the integrator 207 , limiter 208 , memory 209 and the timer 210 , generates the signal Reset SR required for further signal processing from the signal output by the limiter 206 . With the arrangement consisting of the differentiator 211 and the clock oscillator 212 , the clock signal also required for further signal processing is generated.

FIG. 3 shows the part of the code receiver 200 which serves to receive the digital signal, the evaluation device 320 , the memory 330 and the display device 350 , 370 .

A second shift register 310 consists of four shift register elements 311 , 312 , 313 , 314 connected in series, each of the elements being connected to the reset line 221 and to the clock line 223 . The shift register element 311 is also connected to the data line 223 . Furthermore, the shift register elements 311 , 312 are each connected to the memory elements 331 and 332 and to decoder components 341 , 342 and 343 , 344 , respectively. The decoder construction parts 341 , 342 , 343 , 344 in turn are each connected to display elements 351 , 352 , 353 and 354 . The evaluation device 320 contains an address receiver 322 and a comparator device 321 connected to it . The comparator device 321 is coupled on the input side to the shift register elements 313 , 314 and on the output side to an address meter / decoder component 362 . Another address counter / decoder component 361 is connected in series with the address counter / decoder component 362 . Both components 361 , 362 are each connected to the display modules 371 and 372 and connected to the memory elements 331 and 332, respectively.

After the reset has been carried out, the data of the digital signal are serially supplied to the 32-bit wide shift register in predetermined clock rhythm via the data line 223 . The digital signal consists of the 16 bit wide call address, which is stored in the shift register elements 313 , 314 , and the 16 bit wide address of the transmitter, which is stored in the shift register elements 311 , 312 . The 16- bit comparator 321 reads in parallel the call address stored in the shift register elements 313 , 314 and compares the call address with the address 322 of the receiver stored in the construction part. If both addresses match, the address counter / decoder 360 is increased by 1, the content of the shift register elements 311 , 312 is stored in the memory (RAM) 330 and fed to the 16-bit wide decoder 340 . The display of the address of the transmitter takes place like the display of the address counter 360 after decoding on the display elements 351 , 352 , 353 , 354 or 371 , 372 of the display devices 350 and 370 , which as an LED display, for example as a seven-segment display, liquid crystal display (LCD) is configured.

If the sender 's address matches the The recipient's address is a reconfirmation signal can be generated, which consists of a sending address and a confirmation supply signal, the sender address in turn from the Address of the recipient, i.e. their own address, and the Sender address exists. A facility for reception a reconfirmation signal is provided.

A memory selection circuit causes the address counter / decoder 360 back and the memory is again conceivable read 330 according to the count of the address counter / decoder 360 and the display device 350 provides Darge. Up to 99 send addresses can be saved and displayed.

The respectively displayed address of the transmitter can be transferred to the first shift register elements 113 , 114 , so that after receipt of a valid radio transmission signal, a callback is possible without programming the coding switches 117 , 118 .

The auxiliary device is powered by a built-in DC voltage source or an external DC voltage source, for example a car battery. About that in addition, the additional device is equipped with a power supply, so that the voltage supply with AC voltage via the Network can be done.

The additional device has an angular, rectangular shape, for aesthetic or safety reasons however, can be rounded as desired.

The received and stored address of the transmitter in the first embodiment of the invention consists of four digits, which can be displayed on the display 350 alphanumerically. In a second embodiment, the number of digits is increased from four to six, eight or any other number of digits.

The memory 330 contains, according to the first embodiment of the invention, a two-digit number of storage locations which can be represented alphanumerically on the display 370 . In a third embodiment, an expansion of the storage locations to a three or more-digit number of storage locations and a corresponding expansion of the display 370 are provided.

The additional device is for CB radio, amateur radio or company radio provided.  

According to a fourth embodiment of the invention also an integration of the additional device into the radio device provided.

In a fifth embodiment, the additional device contains Invention a device after sending the broadcast address the transmission of an alphanumeric message causes. A device for receiving and storing such a message is also provided.

Fig. 4 shows the first part of the transmitter in the detailed circuit diagram. The additional device has connections A 1 and A 4 , which can be bridged with a jumper J 1 . The circuit contains four NAND gate elements 1 a, 1 b, 1 c, 1 d, four NAND gate elements 2 a, 2 b, 2 c, 2 d and three NAND gate elements 3 a, 3 b, 3 c. Four NAND gate elements are each grouped together in a component 1 , 2 or 3 , for example a CD4011. Terminal 4 of the circuit is coupled to a first terminal of a switch 406 . A second connection of the switch 406 is connected via an inductive resistor 404 to a positive voltage connection 422 and coupled via a capacitor 419 to a connection 2.1 of the gate 2 a. The terminal 2.1 of the gate 2 a is connected via an inductive resistor 405 with a positive voltage connection 421 . The terminal 2.1 of the gate 2 a is connected to the terminal A 1 of the circuit and to a terminal 2.13 of the gate 2 c. A terminal 2.2 of gate 2 a is coupled to terminal 2.4 of gate 2 b and to a first terminal of a capacitor 407 . A terminal 2.5 of the gate 2 b is connected to a terminal 2.3 of the gate 2 a, a terminal 1.6 of the gate 1 b and to the first terminal of an inductive resistor 409 . A terminal 2.6 of the gate 2 b is coupled to a terminal 1.11 of the gate ID. A terminal 2.12 of the gate 2 c is connected to a terminal 2.10 of the gate 2 d and to a terminal 3.6 of a gate 3 b. A terminal 2.9 of gate 2 d is connected to a terminal 2.11 of gate 2 c and a terminal P / S. A terminal 2.8 of gate 2 d is coupled to a terminal 1.10 of gate 1 c. A capacitor 420 is connected to a first connection to ground and a second connection to a connection 1.2 of the gate 1 a, a connection 1.1 of the gate 1 a, a first connection of a resistor 402 and a first connection of a quartz crystal 401 . A terminal 1.3 of the Gat ters 1 a b is connected to a first terminal of a resistor 403, a second terminal of the resistor 402 and one terminal of the gate 1.5. 1 A capacitor 441 is connected to ground at a first connection, to a second connection of the resistor 403 at a second connection and to a second connection of the quartz crystal 401 . A second terminal of capacitor 407 is coupled to ground via an inductive resistor 408 . The second connection of the capacitor 407 is further connected to a connection 5.11 of a component 5 and a connection 4.11 of a component 4 . Components 4 and 5 are designed as components CD4040. A connection 1.4 of the gate 1b is connected to a connection 4.10 of the gate 4 . A connection 4.3 of the block 4 is connected to a connection f 2 . A connector 4.7 of component 4 is connected to a connector 6.14 of component 6 , which is configured, for example, as component CD4017. A connection 4.14 of the component 4 is coupled to a connection 5.10 of the component 5 , to a connection 3.1 of the gate 3 a and a connection 3.2 of the gate 3 a. A second connection of the inductive resistor 409 is connected to the base of a transistor 418 , for example a transistor BC238C. A connection 5.5 of component 5 is connected to a connection 1.8 of gate 1 c, a connection 1.9 of gate 1 c and to a connection 1.12 of gate 1 d. A connection 5.2 of the component 5 is connected to a connection 1.13 of the gate 1d. A terminal 3.3 of the gate 3 a is connected to a terminal 3.5 of the gate 3 b. A terminal 3.4 of the gate 3 b is coupled to a terminal 3.9 and 3.8 of the gate 3 c. A terminal 3.10 of the gate 3 c is connected to a terminal CL. A connection 6.13 of component 6 is coupled to ground. A connection 6.2 of the component 6 is connected to a first connection of a resistor 410 . A connection 6.3 of component 6 is connected to an anode connection of a diode 411 , for example a diode 1N4148. A connection 6.4 of component 6 is coupled to an anode connection of a diode 412 , for example a diode 1N4148. Connections 6.5 and 6.15 of construction part 6 are interconnected. A second connection of the resistor 410 is connected to a connection f 1 together with a cathode connection of the diode 411 and a cathode connection of the diode 412 . A memory circuit is coupled to a positive voltage terminal 428 . The positive voltage terminal 428 is connected to a first terminal of a capacitor 414 and to a first terminal of an electrolytic capacitor 413 . A second connection of the capacitor 414 and the electrolytic capacitor 413 is connected to ground. An emitter terminal of transistor 418 is connected to ground. A collector gate connection of transistor 418 is connected to an anode connection of a diode 415 , for example a diode 1 N 4148 , the cathode connection of which is connected to a positive voltage connection 423 , and to a first connection of a relay 416 , the second connection of which is connected to a positive voltage connection 424 is. The relay 416 actuates a switch 443 , the first connection of which is coupled to a connection A 8 and the second connection of which is connected to a connection A 7 . The second connection of the switch 443 is connected to a connection 445 and can be connected to a coding bridge with a negative voltage connection 425 or a positive voltage connection 417 . The connections A 7 and A 8 can be connected with a jumper J 3 .

According to FIG. 5, the circuit contains shift register elements 7 , 8 , 9 and 10 , which are designed, for example, as CD4021. Furthermore, the circuit contains four EX-OR gate elements 11 a, 11 b, 11 c, 11 d, which are combined in a component 11 , for example a component CD4030. A connection 7.11 of component 7 is coupled to ground. The connection CL is connected to connections 7.10 of the component 7 , 8.10 of the component 8 , 9.10 of the component 9 and 10.10 of the component 10 . The connection P / S is connected to connections 7.9 of the component 7 , 8.9 of the component 8 , 9.9 of the component 9 and 10.9 of the component 10 . A connection 7.3 of component 7 is connected to a connection 8.11 of component 8 . A connector 8.3 of component 8 is connected to a connector 9.11 of component 9 . A connector 9.3 of component 9 is coupled to a connector 10.11 of component 10 . A row of switches 530 consists of 8 switches, the first connections of which are connected together and connected to a positive voltage connection 539 . A resistance network 540 consists of 8 inductive resistors, the first connections of which are interconnected and connected to ground. Second connections of the resistors of the resistance network 540 are each coupled to second connections of the switch row 530 and connected to connections 10.7 , 10.6 , 10.5 , 10.4 , 10.13 , 10.14 , 10.15 and 10.1 of the component 10 . The terminal CL is connected to a terminal 11.9 of the gate 11 a. A connection 11.8 of the gate ters 11 a is switched to a connection 10.3 of the component 10 . A terminal 11.10 of the gate 11 a is coupled to an anode terminal of a diode 508 and to a cathode terminal of a diode 507 . Diodes 507 and 508 are configured as diodes 1N4148. An anode terminal of the diode 507 is connected in 11 to a terminal b of gate 11.2 and a first terminal of a resistor 502nd A two ter terminal of resistor 502 is connected to terminal f 2 . A terminal 11.9 of the gate 11 b is connected to a positive voltage terminal 506 . A terminal 11.3 of the gate 11 b is connected to a first terminal of a resistor 514 . A terminal 11.6 of the Gat ters is c 11 gekop pelt to a positive voltage terminal 504th A terminal 11.5 of the gate 11 c is connected to the terminal f 1 . One terminal of the gate 11.4 c 11 is coupled a resistor 510 to a first terminal. A second connection of the resistor 510 is connected to a cathode connection of the diode 508 and to a connection 11.13 of a gate 11 d. A terminal 11.12 of the gate 11 d is connected to ground. A terminal 11.11 of the gate 11 d is connected to a first terminal of a resistor 512 together. A second terminal of resistor 512 is connected to a second terminal of resistor 514 , a first terminal of a resistor 516 and a first terminal of a capacitor 518 . A second connection of resistor 516 is connected to a base connection of a transistor 522 , for example a transistor BC238C, and to a first connection of a capacitor 520 . Second terminals of capacitors 518 and 520 are coupled to ground. A collector terminal of transistor 522 is connected to a positive voltage terminal 527 . An emitter terminal of transistor 522 is connected to a first terminal of a variable resistor 524 . The second terminal of variable resistor 524 is connected to ground. A third controllable connection of the resistor 524 is connected to a first connection of a capacitor 526 . A second terminal of capacitor 526 is coupled to a first terminal of a resistor 528 . A second connection of resistor 528 is connected to a connection A 5 . A terminal A 3 is connected to ground. The connections A 5 and A 3 can be bridged with the jumper J 3 .

The circuit comprises as shown in FIG. 6, four operational amplifiers 12 a, 12 b, 12 c, 12 d, which are in a device 12, in play as a LM324, summarized. The Opera tion amplifier 13 a, 13 b, 13 c, 13 d are combined in a component 13 , for example an LM324. The circuit device further contains NAND gate elements 14 a, 14 b, 14 c, which are contained in a component 14 , for example a CD4093. A connector NF-IN is connected to a first connector of a resistor 602 . A second terminal of resistor 602 is connected to a first terminal of a capacitor 604 . A second connection of the capacitor 604 is connected to a connection 12.5 of the component 12 a and to a first connection of a resistor 606 . A second connection of the resistor 606 is to a connection 12.1 of the component 12 d, a connection 12.2 of the component 12 d, a first connection of an electrolytic capacitor 614 , a first connection of a resistor 638 , a first connection of a variable resistor 640 , a first connection a resistor 654 , a first connection of a variable resistor 664 and coupled to a connection 13.10 of the component 13 c. A positive voltage terminal 608 is connected to a first terminal of a resistor 610 . A second connection of the resistor 610 is connected to a connection 12.3 of the component 12 d and to a first connection of a resistor 612 . A second terminal of resistor 612 is connected to ground. A terminal 12.6 of the device 12 a is connected to a first terminal of a resistor 634, a first terminal of a capacitor 632 and to a first terminal of a resistor 630th A second terminal of resistor 630 is coupled to a first terminal of an electrolytic capacitor 624 . A second connection of the electrolytic capacitor 624 is connected to a collector connection of a transistor 622 , for example a transistor BC238C. An emitter terminal of the transistor 622 is connected to ground. A base terminal of transistor 622 is connected to a first terminal of a resistor 626 , an anode terminal of a diode 620 , e.g. B. a diode 1N4148, and a first terminal of an electrolytic capacitor 618 connected. A second terminal of resistor 626 is coupled to a positive voltage terminal 628 . A cathode connection of the diode 620 is connected to an anode connection of a diode 616 , e.g. B. a diode 1N4148, and a first terminal of a capacitor 627 connected. A cathode connection of the diode 616 is connected to ground. A second connection of the electrolytic capacitor 618 is just if connected to ground. A second connection of the capacitor 627 is coupled to a second connection of the capacitor 632 , a second connection of the resistor 634 , a connection 12.7 of the component 12 a and to a first connection of a resistor 636 . A connection 12.11 of the component 12 is connected to ground. A connection 12.4 of the component 12 is connected to a positive voltage connection 615 . A second terminal of capacitor 614 is connected to ground. A second terminal of resistor 640 is connected to a first terminal of resistor 642 . A second terminal of resistor 642 is coupled to a terminal 12.10 of the component 12 c and to a first terminal of a capacitor 644th A second connection of the capacitor 644 is connected to a first connection of a resistor 646 and a first connection of a capacitor 648 . A second terminal of the capacitor 648 is connected to a terminal 13.12 of the component 12 b, and a terminal 14.12 of the construction elements 12 is connected b. A terminal 12.12 of the component 12 b is connected to a second terminal of the resistor 636 and a second terminal of the resistor 638th A second connection of the resistor 646 is connected to a connection 12.9 of the component 12 c, a connection 12.8 of the component 12 c and to a first connection of a capacitor 652 . A second terminal of capacitor 652 is coupled to a first terminal of a resistor 650 . A second connection of the resistor 650 is connected to a second connection of the resistor 654 and a connection 13.3 of the component 13 a. A connection 13.2 of the component 13 a is connected to a first connection of a capacitor 656 and to a connection 13.1 of the component 13 a. A second terminal of capacitor 656 is connected to a first terminal of a resistor 658 and a first terminal of a capacitor 660 . A two ter connection of the capacitor 660 is connected to a first connection of a resistor 662 and to a connection 13.5 of the component 13 b. A second terminal of resistor 662 is coupled to a second terminal of resistor 664 . A second terminal of resistor 658 is connected to a terminal b 13.6 of the device 13, a terminal 13.7 of the device 13 b and a terminal 13.9 of the device 13 connected together c. A connection 13.4 of the component 13 is connected to a positive voltage connection 665 . A connection 13.11 of the component 13 is connected to ground. A connection 13.8 of the component 13 c is connected to a connection 14.5 of the component 14 a and a connection 14.6 of the component 14 a. A terminal 14.4 of the device 14 a is coupled to a first terminal of a capacitor 666th A second connection of the capacitor 666 is connected together with a connection 15.14 of a component 15 .

Referring to FIG. 7, the circuit EX-OR gate includes elements 16 a, 16 b, 16 c, which are in a device 16, such as a CD4093, summarized. NOR gate elements 17 a, 17 b, 17 c, 17 d are combined in one component 17 , for example a CD4001. The circuit comprises the white NAND gate elements 19 a, 19 b, 19 c, 19 d, which are contained in a component 19 , for example a CD4093. NOR gate elements 20 a, 20 b are combined in a component 20 , for example a CD4001. Memory elements 18 a, 18 b are contained in a component 18 , for example a CD4013. The circuit further contains the component 15 , for example a CD4046, a component 21 , for example an NE555, and a component 22, for example a CD4017. A connector 15.3 of the component 15 is connected to a connector 15.4 of the component 15 . Connections 15.6 and 15.7 of the component 15 are connected to one another via a capacitor 702 . Connections 15.5 and 15.8 of the component 15 are connected to ground. A terminal 15.11 of the component 15 is coupled via an opposing 719 to ground. A terminal 15.12 of the component 15 is interconnected with a first terminal of a resistor 718 . A second connection of resistor 718 is connected to ground via a variable resistor 720 . A connection 15.10 of the component 15 is connected to a first connection of a resistor 722 and to a first connection of a resistor 716 . A second terminal of resistor 722 is coupled to ground. A connection 15.9 of the component 15 is connected to a first connection of a resistor 704 and a first connection of a resistor 708 . A second connection of the resistor 704 is connected to a connection 15.2 of the component 15 . A connection 15.16 of the component 15 is connected to a positive voltage connection 712 . A second terminal of resistor 708 is coupled to ground via a capacitor 706 . A second connection of the resistor 716 is interconnected with a connection 13.12 of the component 13 d and with a first connection of a capacitor 724 . A second terminal of capacitor 724 is connected to ground. A connection 13.13 of the component 13 d is connected to a first, controllable connection of a controllable resistor 710 . A second connection of resistor 710 is connected to ground. A third terminal of resistor 710 is connected to a positive voltage terminal 714 . One terminal of 13:14 of the device 13 is coupled to b terminals 14.1 and 14.2 of the component 14 d. A terminal 14.3 of the component 14 b is connected to a terminal 16.2 of the component 16 a, a first terminal of a resistor 726 , an anode terminal of a diode 760 , for example a diode 1N4148, and a terminal 18.6 of the component 18 a. A connection 16.1 of the components 16 a is connected to a positive voltage connection 732 . A terminal 16.3 of the device 16 a is the component 16 connected to a first terminal of a resistor 728, a terminal b 16.5 and 33.7 to a terminal of a component 33rd A second terminal of resistor 728 is connected to a terminal 16.6 of the device 16 b and to a first terminal of a capacitor 738th A second connection of the capacitor 738 is coupled to ground. A terminal 16.4 of the component b is 16 interconnected to a terminal 16.12 of the component 16 c. A terminal 16.13 of the component 16 c is ruled out to a positive voltage terminal 730 . A terminal 16.11 of the component 16 c is connected to a terminal 21.4 of the component 21 . A connection 21.8 of the component 21 is connected to a positive voltage connection 734 . A connection 21.7 of the component 21 is coupled to a first connection of a resistor 740 and to a first connection of a resistor 742 . A second connection of resistor 740 is connected to a positive voltage connection 736 . A second terminal of resistor 742 is connected to a first terminal of a variable resistor 744 . A second connection of the resistor 744 is connected to a first connection of a capacitor 746 , a connection 21.6 of the component 21 and a connection 21.2 of the component 21 . A second connection of the capacitor 746 is switched to ground. A connection 21.1 of the component 21 is coupled to ground. A terminal 21.5 is connected to ground via a capacitor 748 . A terminal 21.3 of the device 21 is connected to one terminal of 22:14 of the device 22 and to a terminal 18.11 of the component 18 b. A two-ter terminal of the resistor 726 is connected to a Kathodenan circuit of the diode 760, and c coupled to the terminals 14.8 and 14.9 of the component fourteenth The second terminal of resistor 726 is further connected to a first terminal of an electrolytic capacitor 758 . A second terminal of the 758 electrolytic capacitor is connected to ground. A connection 14.10 of the component 14 c is connected to a connection 17.6 of the component 17 a. A connection 17.5 of the component 17 a is connected to a connection 17.3 of the component 17 b, a first connection of a resistor 750 and a connection 18.3 of the component 18 a. A connection 17.4 of the component 17 a is coupled to a connection 17.2 of the component 17 b and to a connection 18.8 of the construction element 18 b. A connection 17.1 of the component 17 b is connected to a connection 19.10 of the component 19 b together. A second terminal of resistor 750 is sen to terminals 19.1 and 19.2 of the component 19 a and to a first terminal of an electrolytic capacitor 752 is Schlos. A second terminal of the electrolytic capacitor 752 is connected to ground. A connection 19.3 of the component 19 a is connected to a connection 19.8 of the component 19 b. A connection 19.9 of the component 19 b is coupled to a connection 19.11 of the component 19 c. Connections 19.12 and 19.13 of the component 19 c are connected to a first connection of a resistor 756 , a connection 22.10 of the component 22 and a connection 17.13 of the component 17 d. Connections 18.5 and 18.4 of the component 18 a are connected to ground. A terminal 18.2 of the device 18 a is connected to one terminal of 18:10 and with a line reset SR. Terminal 18.9 of component 18 b is connected to a terminal 18.12 of component 18 b and to a terminal 20.6 of component 20 b. A terminal 20.4 of the device 20 is coupled to a line CL SR b. A connection 20.5 of the component 20 b is connected to a connection 17.11 of the component 17 d and to a connection 17.9 of the component 17 c. A terminal 17.12 of the component 17 d is connected to a terminal 17.10 of the component 17 c and to a terminal 22.13 of the component 22 . A terminal 17.8 of the component c 17 is connected to a terminal of a device 23:11 23rd A terminal 22.15 is connected to a first terminal of a capacitor 754 and a second terminal of the resistor 756 . A second terminal of capacitor 754 is coupled to a voltage terminal 755 . A connection 22.4 of the component 22 is connected to connections 20.1 and 20.2 of the component 20 a and with a line. A connection 20.3 of the component 20 a is connected to a line WE. A connection 22.2 of the component 22 is connected to connections 19.5 and 19.6 of the component 19 d. A connection 19.4 of the component 19 d is connected to a line CL Add.

According to Fig. 8, the circuit comprises shift registers 33, 34, 35, 36, which are confi gured for example, as components CD4015. The circuit also contains memory elements 37 , 38 , for example 2016 memory. Decoder blocks 39 , 40 , 41 , 42 are configured as CD4511 components. EX-OR gate elements 29 a, 29 b, 29 c, 29 d are summarized in a component 29 , for example a component CD4030. The circuit also has NAND gate elements 23 a, 23 b, 23 c, 23 d, which are combined in a component 23 , for example a component CD4501. The circuit also contains EX-OR gate elements 30 , 31 , 32 , which are configured as module CD4030. The Lei device Reset SR is connected to connections 33.6 and 33.14 of component 33 , connections 34.6 and 34.14 of component 34 , connections 35.6 and 35.14 of component 35 and to connections 36.6 and 36.14 of component 36 . The line CL SR is connected to connections 33.9 and 33.1 of the component 33 , connections 34.9 and 34.1 of the component 34 , connections 35.9 and 35.1 of the component 35 and connections 36.9 and 36.1 of the component 36 . Connections 33.5 , 33.3 , 33.4 , 33.10 , 33.13 , 33.12 , 33.31 , 33.2 of the component 33 are each connected to an assigned connection of the component 37 and the component 39 or 40 . Connections 34.5 , 34.3 , 34.4 , 34.10 , 34.13 , 34.12 , 34.11 and 34.2 of the component 34 are each coupled to an assigned connection of the component 38 and an assigned connection of the component 41 or 42 . The components 39 , 40 , 41 , 42 are each connected to display elements 820 , 822 , 824 and 826 . The components 820 , 822 , 824 and 826 are each connected via a resistor to a positive voltage connection. The components 37 and 38 are connected to the line WE via one connection and to the line via another connection. Connection 33.7 is connected to the data line, ie to the connection 16.3 of the construction element 16 a. Connections 33.15 and 33.10 of the component 33 are interconnected. A connection 33.2 of the component 33 is connected to a connection 34.7 of the component 34 . Connections 34.15 and 34.10 of the building element 34 are connected to one another. A connection 34.2 of the component 34 is connected to a connection 35.7 of the component 35 . A connection 35.11 of the component 35 is coupled to a connection 36.7 of the component 36 . A terminal 35.5 of the component 35 is connected to a terminal 29.1 of the component 29 a. A terminal 35.10 of the component 35 is connected to a terminal b of the device 29.5 29th A terminal 35.13 of the component 35 is connected to a terminal c of the component 29.13 29th A terminal 35.11 of the component 35 is coupled d of the device 29 to a terminal 29.9. Connections 29.2 of the component 29 a, 29.6 of the component 29 b, 29.12 of the component 29 c and 29.8 of the component 29 d are each ruled out at first connections of a resistance switching network 812 . Second connections of the resistance switching network 812 are connected together with a positive voltage connection 816 and with second connections of a resistance switching network 814 . The components 30 , 31 and 32 , like the component 29, are connected to corresponding contacts of the components 35 and 36 and 812 and 814 , respectively. A connection 29.3 is connected to an anode connection of a diode 804 . A terminal 29.4 of the device 29 b is coupled to an anode terminal of a diode 806th A terminal 29.11 of the component 29 c is connected to an anode terminal of a diode 808th A terminal 29.10 of the component 29 d is coupled to an anode terminal of a diode 810th Cathode terminals of the diodes 804, 806, 808 and 810, which are configured as diodes 1N4148, are connected together to a first terminal of a resistor 802 and with connections 23:12 and 23:13 of the component 23 a. The components 30 , 31 and 32 are like the component 29 connected via a diode network to the terminal 23.12 of the component 23 a. A connection 23.11 of the component 23 a signa lized whether the address is recognized. A second connection of resistor 802 is connected to ground.

According to FIG. 9, the circuit address counters 24 and 25 which are configured for example as a component CD4510. Furthermore, the circuit contains decoder elements 26 and 27 , which are designed, for example, as component CD4511. The circuit also has NAND gate elements 28 a, 28 b, 28 c and 28 d, which are combined in a component 28 , for example a component CD4011. A cathode terminal of a diode 902, such as a 1N4148 diode, is connected to the terminal d of the device 19.4 19th An anode terminal of the diode 902 b connected to a first terminal of a resistor 904, a first terminal of a resistor 908, terminals 23.1 and 23.2 of the device 23, a first terminal of the ceramic capacitor 912, a first terminal of a switch 910 and a terminal 28.5 of Baulelements 28 c connected. The connection 28.5 of the component 28 c is coupled to J 1 . A second connection of resistor 904 is connected to a positive voltage connection 906 . A second terminal of switch 910 is connected to ground. A second connection of the capacitor 912 is connected to ground. A second connection of the resistor 908 is connected to a first connection of a ceramic capacitor 914 and to a connection 23.9 of the component 23 c. A second connection of the capacitor 914 is coupled to ground. A terminal 23.8 of the component c 23 is interconnected with a first terminal of a resistor 920, a first terminal of the ceramic capacitor 918 and a first terminal of a switch 916th A second terminal of switch 916 is connected to ground. A second terminal of capacitor 918 is connected to ground. A second terminal of resistor 920 is connected to a positive voltage terminal 922 . A connection 23.10 of the component 23 c is coupled to a connection 24.15 of the component 24 and to a connection 25.15 of the component 25 .

A connection 23.3 of the component 23 b is connected together with connections 24.10 of the component 24 and 25.10 of the component 25 . Connections 23.5 and 23.6 of the component 23 d are connected to a first connection of a resistor 926 and a first connection of a ceramic capacitor 928 . A second terminal of resistor 926 is connected to a positive voltage terminal 924 . A two ter connection of the capacitor 928 is connected to ground. A connection 23.4 of the component 23 d is coupled to connections 24.9 of the component 24 and 25.9 of the component 25 . Connections 24.7 of component 24 and 25.5 of component 25 are connected together. A terminal 24.5 of the component 24 is connected to ground. Further connections of the component 24 are coupled to the connections of the components 37 and to first connections of the component 26 . Further connections of the component 25 are interconnected with connections of the construction elements 38 and with first connections of the component 27 . Second connections of the component 26 are connected to connections of a display element 964 . The component 964 is coupled to a positive voltage connection 965 via a resistor 966 . Second connections of the component 27 are connected to connections of a display element 968 . The device 968 is coupled to a positive voltage connection 969 via a resistor 970 . A terminal 28.6 of the component c 28 is connected to a first terminal of a switch 962 and a first terminal of a resistor 958th A second terminal of resistor 958 is coupled to a positive voltage terminal 960 . A second connection of the switch 962 is connected to ground. A connector 28.4 of the component 28 c is connected to connectors 28.1 and 28.2 of the component 28 d. A connector 28.3 of the component 28 d is connected to a connector 28.13 of the component 28 b. A connection 28.12 of the component 28 b is interconnected with a connection 28.10 of the component 28 a. A terminal 28.11 of the component 28 b is connected to a first terminal of a resistor 936 and a terminal 28.9 of the component 28 a. A terminal 28.8 of the component 28 a is connected to a first terminal of a switch 934 and a first terminal of a resistor 932 . A second terminal of resistor 932 is connected to a positive voltage terminal 930 . A second terminal of switch 934 is coupled to ground. A second connection of resistor 936 is connected to a base connection of a transistor 938 , for example a transistor BC238C. An emitter terminal of the transistor 938 is connected to ground. A collector connection of the transistor 938 is connected to an anode connection of a diode 940 , for example a diode 1N4148, and a first connection of a relay 942 . A cathode connection of the diode 940 is coupled to a voltage connection 944 . A second connection of the relay 942 is connected to a voltage connection 946 . The relay 942 actuates a switch 948 , the first connection of which is connected to a connection A 1 . A second terminal of switch 948 is connected to a terminal 952 and a terminal A 2 is connected. A connection between the connection 952 and a connection 950 or a connection 954 can be established via a coding bridge. A terminal A 3 is coupled to ground. A connector A 4 is connected to the NF-IN connector. A connector A 5 is connected to a connector NF-OUT. A terminal A 6 is connected to ground. A terminal A 7 is coupled to a first terminal of a switch 926 . A terminal A 8 is connected to a second terminal of switch 956 .

Claims (31)

1. Additional device for a radio, in particular for CB radio, amateur radio or company radio, with
a code transmitter ( 100 ) for generating a first coded address consisting of its own address and a call address and a radio transmission signal corresponding to the coded address for the radio,
a code receiver ( 200 ) for receiving a radio reception signal from the radio and converting the radio reception signal into a digital signal,
a device for evaluating the digital signal according to the call address and address of the transmitter, at least the address of the transmitter being temporarily stored in a memory ( 330 ), and
a display device ( 350 ) for displaying the address of the transmitter retrieved from the buffer. 2. Additional device according to claim 1, characterized in that the memory ( 330 ) has an at least two-digit number of memory locations. 3. Additional device according to the preceding claims, characterized by a memory location counter ( 360 ) for determining the memory location of the address of the transmitter (s) stored in the memory ( 330 ). 4. Additional device according to the preceding claims, characterized in that the display device ( 350 ) has an additional display ( 370 ) for the memory counter. 5. Additional device according to claim 4, characterized in that the display of the send addresses and the display of the Memory counter alphanumeric. 6. Additional device according to claims 3 to 5, characterized through a memory selection circuit. 7. Additional device according to the preceding claims, characterized in that the code transmitter ( 100 ) has a first shift register ( 110 ) with a defined bit width of preferably 32 bits, a control logic ( 130 ) and a linking device ( 150 ). 8. Additional device according to claim 7, characterized in that the first address consists of its own address and a call address, can be loaded via switches ( 115 , 116 , 117 , 118 ) and can be stored in the first shift register ( 110 ). 9. Additional device according to claims 7 and 8, characterized in that the control logic ( 130 ) has an oscillator gate and divider circuit ( 131 ) with which pulses of a fundamental frequency and pulses of frequencies derived therefrom can be generated. 10. Additional device according to the preceding claims, characterized characterized in that the radio transmit signal from a Synchronization signal and an address signal. 11. Additional device according to claims 7 to 10, characterized in that the control logic ( 130 ) a first control device ( 132 ) for generating a synchronization signal with a defined bit width of in particular 8 bits and a second control device ( 133 ) for generating an address signal with has a defined bit width of in particular 32 bits. 12. Additional device according to claims 7 to 11, characterized in that the control logic ( 130 ) generates clock signals which are fed to the first shift register ( 110 ) and the linking device ( 150 ), and generates control signals which are the first shift register ( 110 ) are fed. 13. Additional device according to claims 9 to 12, characterized in that the control logic ( 130 ) of the linking device ( 150 ) supplies pulses of the derived frequencies. 14. Additional device according to claims 10 to 13, characterized in that the control logic ( 130 ) causes the generation of the synchronization signal before the generation of the address signal. 15. Additional device according to claims 7 to 14, characterized in that for generating the address signal of the linking device ( 150 ) serial signals accordingly the content of the first shift register ( 110 ) are supplied. 16. Additional device according to claim 15, characterized in that the linking device ( 150 ) assigns the serially supplied signals according to their logical state to pulses of the derived frequencies. 17. Additional device according to claims 7 to 16, characterized in that the linking device ( 150 ) has a low-pass filter ( 152 ). 18. Additional device according to the preceding claims, characterized in that the code receiver ( 200 ) has a control amplifier ( 201 ). 19. Additional device according to the preceding claims, characterized in that the code receiver ( 200 ) has a multi-stage filter amplifier ( 202 , 203 ). 20. Radio according to the preceding claims, characterized in that the code receiver ( 200 ) for separation of pulses of different frequencies has a PLL circuit ( 205 ). 21. Additional device according to the preceding claims, characterized in that the code receiver ( 200 ) has an on device for separating address data and clock pulses. 22. Additional device according to the preceding claims, characterized in that the code receiver ( 200 ) has a second shift register ( 310 ). 23. Additional device according to the preceding claims, characterized in that the evaluation device has a comparison device ( 320 ) with which the call address and one's own address are comparable. 24. Additional device according to claim 23, characterized in that if the call address matches your own Address a confirmation signal is generated.   25. Additional device according to claims 7 to 24, characterized in that the address of the transmitter corresponding to the display ( 350 ) is transferable to the first shift register ( 110 ). 26. Additional device according to claims 24 and 25, characterized characterized in that the reconfirmation signal is off a sending address and a confirmation signal exists, with the sending address from the address of the Receiver and the transmitter exists. 27. Additional device according to claims 24 to 26, characterized net by a device for receiving the confirmation supply signal. 28. Additional device according to the preceding claims, characterized characterized in that the processing and display of a at least four-digit sender address is provided. 29. Additional device according to the preceding claims, characterized characterized in that the additional device for a CB radio advice, amateur radio or company radio provided is. 30. Additional device according to the preceding claims, characterized characterized in that the additional device in the radio can be integrated. 31. Additional device according to the preceding claims, characterized characterized in that a device for sending and / or receiving an alphanumeric message is provided.