DE2952151B1 - Circuit arrangement for the electronic locking or unlocking of security devices, in particular as anti-theft protection in a motor vehicle - Google Patents

Description

The object is achieved according to the invention by the features of the characterizing Part of the main claim. The essence of the invention is that a combination electronic key and electronic alarm device as a security device are combined in a single circuit arrangement and the functions of the Signal reception for unlocking and monitoring the status switch so in one another are nested so that parallel operation is possible. Because it mustn't happen that with an advantageous combination of the previous circuit arrangement as a new disadvantage arises that the alarm-giving protective devices during an unlocking process are turned off. As a result, using a wrong Signal transmitter the unlocking device with reception and Verification of the pulse code is so busy that the safety devices turn off the status switch no longer monitor. Just putting together an alarming safety device with status switches and an electronic key in the manner of the invention Solution indicates can eliminate the previous disadvantages without incurring new disadvantages to have.

Advantages of the invention The use of only one circuit arrangement has the advantages of convenient operation, low cost, convenient assembly, and high Security, as there are no additional connecting lines between different facilities are necessary.

By stimulating the monitoring of status switches with each received Pulse of the pulse code and alternative excitation from a clock generator if the The absence of pulses from the pulse code has the advantage that the status switch with very high frequency are monitored. Because the specified time after which the clock generator takes over the query, depends on the pulse intervals of the transmitter. It is inconceivable that there should be means or procedures that are within the short intervals in which the status switches are not monitored, the safety devices take out of order.

With the use of the longest of the three pulses of the pulse code as a synchronization signal for the reception of the pulse train in the signal receiver associated the advantage that this synchronization signal is recognized with great certainty will.

The assignment of twice as long pulse intervals for the I information compared to zero information has the advantage that it is particularly reliable and simple Type of information bits can be differentiated in the receiver.

In that the clock generator is designed so that in the pulse intervals The pulses of the pulse code will fall at the pulse repetition frequency it emits advantageously achieved that the circuit arrangement from pulses emitted on the transmitter side responds quickly.

There would be the possibility that the impulses given by the transmitter Pulse codes can be assigned a frequency that is a harmonic of Clock generator output pulse frequency, it would be conceivable that all synchronizing pulses and thus the key function is lost.

By inserting a time circuit that shows the pulses of the pulse code examined for a minimum width, all short interference pulses are advantageously masked out, so that only pulses of the pulse code can have an effect.

The monitoring of the status switch in a time interval in which no pulse of the pulse code is received, has the advantage that interference pulses that occurring during this time are disregarded.

Such glitches can occur despite the lock for too short pulses take place in that longer pulses than the transmitter side from any source of interference provided.

According to the characteristics from the identification part and the characteristics of the dependent claims, it is not possible for a circuit arrangement according to the invention using only discrete logic elements but also in a highly integrated form to build a single-chip processor, resulting in a particularly advantageous embodiment the invention leads.

DRAWING Further features and advantages of the invention result from the following description of two exemplary embodiments, once using discrete logic elements and on the other hand using a single chip microprocessor. It shows: F i g. 1 is a block diagram of a signal generator using discrete Logic elements, Fig.2 a functionally identical signal generator using a Single chip microprocessor, FIG. 3 is a program flow diagram for a signal transmitter with microprocessor, Fig. 4 a signal receiver using discrete logic elements, Fig. S shows a signal receiver with the same function using a single-chip microprocessor, F i g. Figure 6 is a flow diagram of that laid down in the microprocessor of the signal receiver Program.

In the transmitting device according to FIG. 1, a switch 1 is via a Line 2 is connected to an input 3 of an initialization circuit 4. An exit 5 of the initialization circuit 4 leads via a line 6 to the reset input 7 of a counter 8 and also to the reset input 9 of a flip-flop 10. A transmission output 11 of the counter 8 is connected to the set input 13 of the flip-flop 10 via a line 12 tied together. An output 14 is via a line 15 with a blocking input 16 of a Amplifier 17 connected. An output 18 of the initialization circuit 4 is via a line 19 is connected to an input 20 of an OR gate 21. An exit 22 of the OR gate 21 is connected to a set input 23 of a timing element 24 via a Line 25 connected. An output 26 is via a line 27 with an input 28 of an OR gate 29 and is also connected to the reset inputs 30 and 31 of the counters 32 and 33 are connected. An output 34 of the OR gate 29 is via a Line 35 is connected to an input 36 of a pulse shaper 37.

An output 38 of the pulse shaper 37 is via a line 39 with a Progress input 40 of the counter 32 connected. A transmission output 41 of the counter 32 is connected to an incremental input 43 of the counter 33 via a line 42. A carry output 44 of the counter 33 is via a line 45 with an input 46 of a pulse shaper 47 is connected. An output 48 of the pulse shaper 41 is over a line 49 with an input 50 of the ODEP gate 21 and with an incremental input 51 of the counter 8 connected.

An output 52 of the pulse shaper 37 is via a line 53 with a Input 54 of the amplifier 17 is connected. An output 55 of the amplifier is across a line 56 is connected to a light emitting diode 57.

Outputs 58 of counter 30 are connected to inputs 60 via lines 59 a diode matrix 61 connected.

Outputs 62 of counter 33 are connected to inputs 64 via lines 63 connected to the diode matrix. Outputs 65 of the diode matrix are via lines 66 connected to inputs 67 of an OR gate 68. An output 69 of the OR gate 68 is via lines 70 with an input 71 of an inverter 72 and with a set input 73 of a timer connected. An output 75 of the inverter is via a line 76 is connected to a set input 77 of a timing element 78.

An output 79 of the inverter 74 is via a line 80 with a Input 81 of the OR gate 29 connected.

An output 82 of the timer 78 is via a line 83 with a Input 84 of the OR gate 29 tied together. An output 85 of the pulse shaper 37 is via a line 86 both with a set input 87 of the timer 78 as also connected to a set input 88 of the timing element 74.

The function of the circuit is as follows: With the actuation of the switch 1, a signal is sent to input 3 of the initialization circuit, which then emits a pulse that is transmitted via line 6 of both the counter 8 and the flip-flop resets.

Another pulse from the initialization circuit arrives via the Line 19 through the OR gate 21 to line 25 and thus to the set input 23 of the timer 24. This has a duration of 20 msec. At his exit 26 a correspondingly long pulse arises, which is reset via line 27 the counter 32 and 33 makes and also the pulse shaper 37 via its input 36 causes a pulse to be emitted at its output 52. This impulse has one Width of about 100 sec and is a pulse of the pulse code to be output, namely the start impulse. The pulse generated by the pulse shaper 37 passes through the line 53 to the amplifier 17 and drives the light-emitting diode 57 via the line 56. This gives a light pulse, the length of which corresponds to the pulse duration of the pulse shaper 37. The pulse shaper 37 simultaneously gives an incremental signal to the counter 32 and a set signal to the timers 74 and 78. Only one of the two can be set, according to the logic state at their set inputs 73 and 77. For the start or synchronization step of the pulse code, the pulses emitted by these timers fall within the running time of the timer 24 so that they do not come into effect. This can do the same The first pulse of the pulse code is not used to advance the counter 32, since this Counter reset via reset input 30 by the pulse of timer 24 is held.

After the period specified by the timer 24 has elapsed is, the pulse shaper 37 is triggered again. He's now giving an impulse which with its leading edge one of the timing elements 74, 76 abuts with its trailing edge the counter 32 advances from the initially held 0 position to the 1 position. In addition, a signal of the pulse code is used for the amplifier 17 and the light-emitting diode 57 that indicates the end of the synchronization interval.

Which of the two timing elements 74, 78 was triggered is determined then which set input 73, 77 had the level required for switching on the Timers are necessary. This level depends on what information is read from the diode matrix 61, the lines and counters 32, 33 is controlled column by column. Sits at the intersection of the row and column lines a diode from the counters 32, 33 in the diode matrix, then via the OR gate 68 and the inverter activates the timer that has the longer running time. It kicks immediately a rising edge, which in turn the pulse shaper 37 via its input 36 could start again. However, since the pulse shaper 37 is still running, it remains Edge for a pulse generation in pulse shaper 37 ineffective. Only from the back flank of the pulse that is generated by the addressed timing element is again the pulse shaper 37 addressed. Another pulse of the pulse code results. Simultaneously the counter 32 is incremented via the incremental input 40. As soon as the outputs a carry signal to its output 41, the incremental input 43 the Counter 33 advanced one step. So are the individuals in turn Crossing points of the diode matrix from the outputs 58, 62 of the counters 32, 33 are addressed and in turn control one of the timing elements via OR gate 68 and inverter 62 74, 78. The light-emitting diode 57 supplies a sequence of pulses of equal width, the pulse intervals according to the bit pattern predetermined by the diode matrix 61 between 2 and 4 msec vary, depending on which of the two timing elements 74, 78 was addressed.

Finally, a signal occurs at the carry output 44 of the counter 33 from, which abuts the pulse shaper 47 via the line 45. One delivered by him Impulse switches the counter 8 on and starts via the OR gate 21 and the Line 25 the timer 24 again, so that the 20 msec long pulse pause for the Synchronization step occurs.

The timers 74, 78 and the pulse shaper 37 thus work together as a variable clock generator for the pulses of the information part of the pulse code. The timer 24 cooperates with the pulse shaper 37 and the counters 32, 33 and the pulse shaper 47 for generating the synchronization step of the pulse code.

The output of pulses continues until the incremental input 51 of the counter 8 leads to an overflow thereof. An impulse on the line 12 sets the flip-flop 10, so that via its output 14 and line 15 of now from the amplifier 17 is blocked.

There is no emission of light pulses via the light-emitting diode 57. It does not matter whether the clocking and counting processes continue within the send processes. The main power consumer is switched off with the light-emitting diode.

Another embodiment of the transmission device according to the invention is in Fig. 2 shown. A key 90 is over a differentiator 91 is connected to a reset input 92 of a microprocessor 93. Outputs 94 of the Microprocessor 93 are connected to a quartz 96 via lines 95.

Port outputs 97 are via lines 98 with inputs 99 of a diode matrix 100 connected. Outputs 101 of the diode matrix are connected via lines 102 Port inputs 103 of the microprocessor 93 connected.

A port output 104 of the microprocessor 93 is via a line 105 connected to an input 106 of an amplifier 107. An output 108 of the amplifier 107 is connected to a light emitting diode 109.

The function of the circuit arrangement according to FIG. 2 is from the program of the microprocessor 93 dominated.

Such programs run sequentially so that interlocks, which are necessary for circuits without a microprocessor, can be omitted here. That considerably simplifies not only the circuit complexity, but also the structure of the Program.

The following register assignments are made in the microprocessor 93: SP stack pointer, A accumulator, B, C time counter, D cycle counter, E shift register, H Register pointer for the storage registers B: C: D: E 'H'.

F i g. 3 shows a flow diagram of the microprocessor program. the The function of the program is as follows: With an impulse on the reset input 92 of the microprocessor 93, the program jumps to the starting point. So begins the Initialization process a, which consists of freezing the stack pointer and the To set cycle counter D to a number that corresponds to the number the desired Transmission cycles. The initialization program ends at node DST1. The program part occupies the shift register E to zero and the register pointer H so that it points to register B '. In program part c, registers B: C: D 'E' H 'is filled with the contents of the diode matrix 100 in that the diode matrix is addressed line by line and each byte of its lines is recorded in one of the registers will. This is followed by a pulse with the subroutine pulse (UP pulse) of the pulse code. The pulse duration of 100 usec is suitably many NOP commands reached. This is followed by the synchronization pause in program part e from 20 msec on. To do this, the register pair B, C is loaded with such a number, that the desired time interval is obtained during the subsequent counting down to zero results. After each decrementing step for the register pair B, C is therefore checked whether zero has already been reached. The program node is then reached DST2.

After the synchronization pause, f by calling UP pulse another pulse of the pulse code is emitted. In the program part g becomes the contents of the shift register E are loaded into the accumulator and the first time, if E is still zero, the carry bit is set. The accumulator is then rotated and its bit pattern is stored in register E as the new state of the shift register. A logical link then occurs between the one addressed by the register pointer H Memory register (B 'C: D: E' H ') and the accumulator. So at the end of the Program part b one bit in the accumulator if a diode was set. Otherwise it is Accumulator zero. Accordingly, the accumulator is set to zero in part h of the program checked and either a time interval of 2 msec at zero or a time interval at 1 generated by 4 msec. These time intervals are corresponding to the synchronization pause generated in that serving as time counters registers B, C to corresponding Values are set in order to then be counted down to zero.

After these time intervals, the shift register is opened in program part i Then you are asked whether the bit entered with the carry bit has gone through the register has been pushed through, d. H. z. B. with left rotation that checked whether there is 80 H in the register. If this is not the case, the program runs for Back to node DST2. The result is a program loop that runs as long as until the shift register E, which serves as a mask, is multiplied (via the Accumulator) has read out the content of one of the storage registers B 'C: D: E' H '. each loop then begins after the node DST1 with the delivery of a pulse. So the pulses of the pulse code follow one another with time intervals that correspond to the set Diodes of the diode matrix 100 correspond in each case to one row.

Once the shift register E has run through, the program part K the register pointer H increased by 1. It is then checked in program part 1, whether the register pointer H still points to one of the storage registers 8 ', C: D: E' H '. If this is still the case, the shift register E is opened again in program part m Set to zero to the next memory register addressed by the incremented register pointer H to be queried bit by bit.

The program continues via node DST2.

If the register part has run out of the memory register, so there are 40 pulse pauses of lengths 2 or 4 msec has been generated. In the program part n the cycle counter Dum 1 is increased. Another impulse is generated in program part t output as the end of the time interval of the fortieth bit of the pulse code serves. In the subsequent program part q it is queried whether the cycle counter is already the number has reached 10. If this is not the case, the program jumps to the node DST2 and a new sequence of pulses of the pulse code is emitted. If the cycle counter has reached the number 10, the program goes into a »halt« loop.

In the receiving device according to FIG. 4 is a switch 201 connected to an initialization circuit 202. An output 203 of the initialization circuit 202 is connected to an input 205 via a multiply branching connection 204 an AND gate 206 and an input 207 of an OR gate 208 and a blocking input 209 of a timer 210 and an input 211 of an OR gate 212 and a Blocking input 213 of an actuation circuit 214 is connected. An output 215 of the OR gate 208 is connected to a blocking input 217 of a timing element 218 via a line 216. An output 219 of the OR gate 212 is via a line 220 with a blocking input 221 connected to a theft monitoring circuit 222. An output 223 of a receiving amplifier 224 is via a connection 225 to both an input 226 of a timing element 227 and an input 228 of the OR gate 206. An output 229 of the Timing element 227 is via a line 230 to an input 231 of the AND gate 206 connected. An input 232 of the AND gate 206 leads via a line 233 an output 234 of the theft monitoring circuit 222. To an output 235 of AND gate 206 a multiple connection 236 is connected. A pulse output 237 of a clock generator 238 is via a line 239 with an input 240 of a OR gate 241 connected. An output 242 of the OR gate 241 is through a connection 243 both with an input 244 of an OR gate 245 and with an input 246 of an OR gate 247 connected. An output 248 of OR gate 247 is over a line 249 is connected to an input 250 of the theft monitoring circuit 222. A blocking input 251 of the clock generator 238 is via a line 252 with a Output 253 of an OR gate 254 connected. An input 255 of the OR gate 254 is connected to a status output 256 of the timing element 210 via a line 257. Another input 258 of the OR gate 254 is via a line 259 with a Status output 260 of the timer 218 connected. The connection 236 links the Output 235 of the OR gate 206 with an input 261 of an AND gate 262 and an input 263 of an AND gate 264 and an input 265 of the OR gate 247. An output 266 of a flip-flop 267 is via a line 268 with an input 269 of AND gate 264 connected. A complementary to the output 266 of the flip-flop 267 Output 270 is via a line 271 to an input 272 of the AND gate 262 tied together. A reset input 273 of the flip-flop 267 is connected to an output 274 of the OR gate 245 via a line 275 connected.

A set input 276 of the flip-flop 267 is connected via a line 277 a pulse output 278 of the timing element 210 is connected. An input 279 of the OR gate 245 is via a line 280 with a Output 281 of a pulse shaper 282 connected. An input 283 of the OR gate 245 is via a line 284 with a pulse output 285 of the timing element 218 is connected. The pulse output 285 is at the same time also connected to an input 286 of the OR gate 247 via the line 284. An output 287 of the AND gate 264 is via a line 288 with a set input 289 of the timer 210 connected.

An output 290 of AND gate 262 is via a multiple connection line 291 with a set input 292 of the timer 218 and a set input 293 of the timer 294 and an input 295 of an OR gate 296 connected. The output 278 of the Timing element 210 is connected to both a reset input 298 via a line 297 a counter 299 and a reset input 300 of a flip-flop 301 and a Input 302 of an AND gate 303 connected.

A status output 304 of the timer 294 is via a line 305 connected to a control input 306 of a shift register 307. A clock input 308 of the shift register 307 is connected to an output 310 of the OR gate 296 connected. The output 310 of the OR gate 296 is on a line 311 is connected to a clock input 312 of the counter 299. An overflow exit 313 of the counter 299 is via a line 314 to a toggle input 315 of the flip-flop 301 connected. A status output 316 of the flip-flop 301 is via a line 317 connected to a blocking input of an incremental generator 319. A pulse output 320 of the increment generator 319 is connected to an input 322 via a line 321 of the OR gate 296 connected. Status outputs 323 of the counter 299 are via connecting lines 324 connected to inputs 325 of a decoding circuit 326.

Outputs 327 of the decoder circuit 326 are connected via lines 328 Inputs 329 of a diode matrix 330 connected, which internally a level converter 331 having. Outputs 332 of the level converter 331 are via lines 333 with inputs 334 of a comparator 335 is connected. Inputs 336 of the comparator are via lines 337 connected to status outputs 338 of the shift register 307. A result output 339 of the comparator 335 is connected via a line 340 to an input 341 of an AND gate 342 connected.

A status output 343 of the flip-flop 301 is via a line 344 both with a blocking input 345 of a pulse shaper 346 and with a trigger input 347 of the pulse shaper 282 and a reset input 348 of a flip-flop 349 connected. An output 350 of the decoding circuit 326 is via a line 351 with a trigger input 352 of the pulse shaper 346 connected. An output 353 of pulse shaper 346 is across a line 354 is connected to an input 355 of the AND gate 342. An exit 356 of the AND gate 352 is via a line 357 with a set input 358 of the flip-flop 349 connected. A status output 359 of the flip-flop 349 is via a line 360 connected to an input 361 of the AND gate 303. An output 362 of the AND gate 303 is via a line 363 with both the set input 364 of the actuation circuit 214 as well as with an input 365 of the OR gate 208 and an input 366 of the OR gate 241 connected. A status output 367 of the actuation circuit 214 is Connected via a line 368 to an input 369 of the OR gate 212. Of the Pulse output 281 of pulse shaper 282 is connected to an input 370 of the AND gate 303 connected. Outputs 371 of the theft monitoring switching circuit 222 are with status switch 372 connected, which in turn are connected to ground. Outputs 273 of the theft monitoring circuit 222 are connected to signaling devices 374.

To illustrate the function of the circuit, the function is shown in the following Subdivided into sections: 1. Initialization function 2. Receive function 3. Basic clock function 4. Function of theft monitoring circuit 5. Synchronization function 6. Detection function 1. The initialization function starts when the Receiver circuit (FIG. 2) via switch 201 with which also the supply voltage is applied to all components of the circuit. At output 203 of the initialization circuit 202 an initialization pulse occurs, which via the connection 204 the transition initiates the entire circuit in a basic state. The initialization pulse runs for this purpose via line 204 to input 205 of AND gate 206 and blocks this, so that no received pulses can pass through it. The initialization pulse runs via the input 207 of the OR gate 208 and blocks via the blocking input 217 the timing element 218, so that it falls back into its basic state. On the Blocking input 209 has the same effect on timer 210. Via entrance 211 of the OR gate 212, the pulse reaches the blocking input 221 of the theft monitoring circuit, so that this falls in an initial state.

The same happens via the blocking input 213 with the actuation circuit 214. After timers 210 and 218 have returned to their basic state. can via the OR gate 254 with its two inputs 255 and 258 no signal the blocking input 251 of the clock generator 238 come. This then begins with the generation of clock pulses that emerge at its pulse output 237 and over the line 243 also come to the input 244 of the OR gate 245, from its Output 274 which reset this flip-flop via the reset input 273 of the flip-flop 267. With its complementary outputs 266 and 270, it acts via inputs 269 and 272 of AND gates 263 and 262 so that AND gate 264 is a closed switch for pulses on line 236 and AND gate 262 t; nen open Switch for the same impulses.

The basic state is thus established. Working through the flip-flop 267 the two AND gates 264 and 262 so as a switch that a received pulse initially reaches the timer 210. Furthermore, the clock generator 238 is in the basic state in operation. After the reset process, which takes a few hundred msec.

can last, the reset pulse disappears, so that the previously Forcibly reset circuits are ready for operation again and are acting Signals can react.

2. The signals sent by a suitable transmitter exist from a pulse train. The pulses have a constant width, but different widths Distances. After an initial pulse there is a synchronization pause with an opposite one the following pulse intervals extend over a long period of time. On this interpulse period of about 20 msec. the information pulses follow, their intervals either 2 msec. or 4 msec. can be. 2 msec. correspond to one 0-bit4msec.one-n l-bit.

The signals of the pulse code picked up by the receiving amplifier 224 are emitted in the form of pulses at its output 223. A received impulse triggers via input 226 of timer 227.

this has an elapsed time of slightly less than the intended pulse width (about 100 psec). The timer 227 acts via its output 229 with the AND gate 206 in such a way that there are no signal pulses from the AND gate 206 can pass through. These signal pulses.

which is fed to the input 228 of the AND gate 206 via the line 225 must therefore be longer than the running time of the timer 227. Are they it doesn't, so it is probably glitching.

These are masked out by the action of the AND gate 206. Just Sufficiently long pulses of the pulse code become the output 235 of the AND gate 206 let through. Should pulses occur during the time of the initialization function are received, they find an AND gate 206 blocked via input 205 before and remain ineffective. The impulses remain ineffective even if during the function of the theft monitoring circuit 222 at its output 234 Lock signal occurs, which is sent via line 233 to input 232 of AND gate 206 is fed. This ensures that received pulses immediately after the arrival of a receive pulse, can be suppressed. As the theft monitoring circuit a working time of about one 600 usec. this means that all receive pulses which are a shorter distance than a 600 lisec. to have. Such Pulses are also not allowed to occur, since the shortest pulse interval is two msec. amounts to.

The receive function is used to monitor the time of the Pulses made so that only likely meaningful pulses with sufficient Width and sufficient pulse spacing fed to the rest of the receiving circuit will.

3. The clock generator 238 is the clock generator from which the Main claim speaks. He emits a pulse train that causes in one of the Clock generator 238 predetermined time interval a pulse is generated in any case, which triggers the theft monitoring circuit m via input 250. So that will periodically triggered a theft monitoring. The pulses of the clock generator 238 also run to the input 244 of the AND gate 245, from where they go through its Output 274 acts on reset input 273 of flip-flop 267. This becomes the flip-flop 267 held in a dormant state.

If the blocking input 251 is bad, the clock generator 238 can be switched off and keep it in an idle state as long as the rest of the circuit is used for the synchronization function or the detection function is working.

In both cases either the timer 210 or the timer 218 switched on, the status outputs 256 and 260 of the OR gate 254 combined and deliver a blocking signal to the blocking input 251 of the clock generator 238. The basic clock function is then switched off as long as. until the lock signal disappears again at blocking input 251. It should be noted that a short-term Disappearance of the blocking signal does not result in a pulse output at pulse output 237 of the clock generator 238 leads, special n that therefor a certain lead time in the clock generator necessary is. This ensures that the Lock signal disappear briefly may without the clock generator 238 starting again.

4. The function of the theft monitoring circuit is through a Pulse on input 250 of theft monitoring circuit 222 triggered. This Pulse can come from four different sources indicated by OR gate 247 be summarized. Receive pulses arrive at input 265 of the OR gate. The theft monitoring circuit works every time when pulses of the Pulse codes have been received. At the input 246 of the OR gate 247 come the Pulses of the clock generator 238 on. The theft monitor circuit 222 operates every time the clock generator 238 sends a pulse through its pulse output 237 gives up. The output pulse of the timer comes at input 375 of OR gate 247 210 so that the theft monitoring always works when the pulse output 278 of the timer 210 after expiry of the same a pulse occurs. At entrance 286 of the AND gate 247, a pulse occurs when the timer 218 expires Pulse output 285 on. The theft monitoring circuit 222 is then also activated.

The theft monitoring circuit 222 inquires in parallel or in series the status switches 372 connected via their inputs 371 off. The state of this Status switch is the status switch inside the anti-theft monitoring circuit for the idle state 222 saved. There is a comparison between the bit pattern that this idle state corresponds, and the actual position of the status switch 372 made. Finds if there is no match, then sps the anti-theft device, d. H. the theft monitoring circuit m excites the signaling devices 274 via the outputs 273. There in a variety of ways The theft monitoring circuit can be triggered via the OR gate 245, there is a frequent comparison between status switches and a given bit pattern instead, so that there is no chance from the time of the theft surveillance bypass. The theft monitoring can be switched via the blocking input 221 Switch off m immediately. This is done via OR gate 212 under two circumstances, namely once when the initialization function expires and secondly, when the actuation circuit 214 responds. The actuation circuit 214 responds whenever there is a match between the received pulse code and a bit pattern corresponding to it has been determined in the receiving device is. Then namely, the object secured with the receiving device is allowed to appear from the corrected one that could send the correct pulse code.

But if a correct pulse code is sent, and at the same time z. B. changed status switch by opening the doors, the theft monitoring circuit speaks 222 and would give an alarm via these signaling devices 374. Because the one out of many When it is received, the pulse code requires the monitoring function several times theft protection m. If the correct code is now received, they must Immediately switch off the signaling devices 374 again. This is done by the reset signal from actuation circuit 214 via line 368.

5. The synchronization function monitors the start step of the pulse code. This starting step draws through an excessively long pulse interval compared to the following information impulses. The synchronization function is triggered by a receive pulse that hits the timing element 210. That is only possible when flip-flop 267 turns AND gate 264 on has that the switch represented by AND gate 264 is closed. With the When the timer 210 is switched on, a blocking pulse comes from its status output 256 via the OR gate 254 to the clock generator 238, which then stops and in turn, no new trigger pulses to the theft monitoring circuit 222 gives.

The timing element 210 can be retriggered with respect to signals at its input 289. This means that its term starts all over again as soon as during this Runtime another pulse occurs. It is thereby achieved that the timing element 210 cannot emit an end signal at its pulse output 278, as long as there is not actually an excessively long pulse interval, the timer can 210 expire, however, for which about 17 msec. are provided so occurs at its exit 278 an impulse. With this pulse, the flip-flop 267 set via set input 276. The AND gates 262, 264, which act as switches switch over so that the following pulses of the pulse code are no longer to the timing element 210 but get on line 291.

This end pulse from pulse output 278 acts via the input 375 of the OR gate 247 as a trigger for a new monitoring function of the anti-theft device. This is entirely possible in terms of time, since the next, correct pulse of the pulse code only 3 msec. may occur later, so that for the 600 lisec.

Working time of the theft monitoring circuit 222 is enough time remain. The end pulse from timing element 210 continues to act as a reset signal on the counter 255 and the flip-flop 301 and the lock signal on the AND gate 303. When the flip-flop 301 is reset, a signal from a Status output 343 occur in such a way that via trigger input 347 of the pulse generator 282 the same is triggered and via its output 281 an interrogating pulse to the input 369 of the AND gate 303. This means that the AND gate 303 triggering of the actuation circuit 214 take place, which of course is not desirable is. Therefore, the AND gate 303 remains for the reset operation of the flip-flop 301 locked. When the timer 210 falls back into its idle state, this becomes Lock signal that emerges from a status output 256 as a lock signal for the clock generator 238 taken away. It can start swinging again, but only after a while Deliver a pulse to its pulse output 237. Usually, however, a new pulse of the pulse code, namely a first pulse of the series of information pulses occur and block the clock generator 238 again via the timer 218.

6. After the synchronization function, the detection function usually starts, if the synchronization pauses are followed by pulses of the pulse code, the are referred to as information impulses. Their distance is much shorter than that of the first two pulses that include the synchronization pauses. There is two different pulse lengths that are assigned to the bits of the information.

Each of the information impulses is effective after passing through the gate 262 to the two timing elements 218 and 294 and after passing through the OR gate 296 to shift register 307 and counter 299. With the pulse from the timer 210, which occurs at the end of the synchronization pause, the counter 299 uod das Flip-flop 301 reset and the AND gateer 303 for the duration of the reset pulse locked for the action of the pulse shaper 282, which may be used during Resetting of the flip-flop 301 can be initiated via its trigger input 347 can. The starting edge of one of the pulses of the pulse code switches via the clock input 308, the shift register 307 continues. Which bit is then entered depends on the potential at the control input 306 of the shift register 307. This input 306 is controlled by the output 304 of the timer 294, which with the trailing edge a pulse from the pulse code is triggered. That means that at the time of Clock edge at clock input 308 is that state of the output of timer 294 is applied, which is determined by the running time of the timer 294 that of the trailing edge of the previous pulse is triggered. Runs the timer 294, which has a running time of about 3 msec. has at the time of the next pulse of the pulse code still, this impulse occurs a short distance from the preceding one. A 0-bit is entered in the slide block. If, on the other hand, the runtime of the Timer 294 has expired, an 1-bit is entered with the next pulse. With each pulse of the pulse code, the counter 299 is also switched on, the one after 41 impulses a carry elgbt and thus via the switching input 315 of the flip-Flq 301 this toggles. Its status output 343 acts on the flip-flop 349, the pulse shaper 282, the pulse shaper 346 and the increment generator 319. The increment generator 319 is switched on and got a high frequency pulse train through its pulse output 320 from.

The blocking input 345 of the pulse shaper 346 now receives such a potential, that the pulse shaper 346 is no longer blocked. The trigger input 347 of the pulse shaper 282 cannot handle the status margin that occurred when flip-flop 301 was switched over start and stay calm. The reset input 348 of flip-flop 349 receives after switching over the flip-flop 301 no more reset signal, so that the flip-flop can be brought into another state.

The high frequency pulse train produced by the incremental generator 319 is output, acts via the OR gate 296 as information pulses Mif Shift register 307 and counter 299. It does not matter which one Signal at the control input 306 of the shift register 307 is present. That in him at the reception The binary pattern entered in the information bits is generated with each pulse from the incremental generator 319 shifted towards the end of shift register 307.

At the status outputs 338, from which the states of the oldest bits exit in shift register 307, the comparator 335 is connected. To the status outputs 323 of the counter 299 is connected to the decoding circuit 326, which controls the the diode matrix 330, line by line. Everyone's bit states Row of the diode matrix 330 are picked up by the level converters 331 and over The lines 333 are fed to the inputs 334 of the comparator 3. The comparator 335 compares the bit states of the shift register 307 with those in the diode matrix 330 are stored. Depending on the result of the comparison, the result output 339 occurs of Comparator 335 from a logic state which, if necessary, the AND gate 342 for a pulse from the pulse shaper 346 can pass. Correct bit pattern in shift register 307 and bit pattern from a row of the diode matrix 330 match, the AND gate 342 remains blocked. If the comparator 335 does not Agreement found. thus a pulse from pulse shaper 346 passes through the AND gate 342 to the set input 358 of the flip-flop 349. The pulse shaper 346 gives always then off an impulse.

if both a blocking input 345 and its trigger input 362 allow this. Accordingly, the first pulse already emerges when the counter 299 after switching the flip-flop 301 is in its zero position. The further impulses are given. when so many pulses have been delivered by the time generator 319, that a next row of the diode matrix 330 via the decoder circuit 326 from the counter 299 is addressed. A line-by-line reading of the diode matrix 330 and a comparison with the shifted bit pattern of the shift register 307 instead. Should no match be found in any of these steps flip-flop 349 is set.

After another 241 pulses, the counter 299 emits an overflow signal on line 314, whereby the flip-flop 301 switches back. This will make the Stepping generator 319 blocked, the pulse shaper is blocked. Through a suitable When the flip-flop 349 is switched on, this is not immediately delayed, but rather slightly delayed reset. Therefore its status output 359 remains for a short time.

During this time a pulse emerges from the pulse shaper 282, which is triggered by the switching back of the flip-flop 301 via its trigger input 347 became. This pulse from pulse shaper 282 is used as an interrogation pulse for the status output of the flip-flop 349 via the AND gate 303. The flip-flop 349 was not switched during the working time of the increment generator 319, a pulse through the AND gate 303 pass through and thus the actuation circuit 214 via their Trigger set input 364.

This is recognized by the actuation circuit 214.

that a valid pulse code was available so that an authorized person had access to the protected object. This is then in front of the actuation circuit 214 started. At the same time, a signal emerges from the status output 367 of the actuation circuit 214 from, that a possibly ongoing theft monitoring by acting on the blocking input 221 of the theft monitoring circuit 222 breaks off. If the Code comparison also sends a pulse to the blocking input of the via line 363 Timing element 218 so that it falls back without a pulse from its pulse output 285 to submit. A pulse from OR gate 241 arrives on the same line, which resets the flip-flop 267 via the OR gate 245. so that a subsequent one Pulse of a pulse code encounters AND gate 264 in such a state that this pulse can come to timing element 210 as a synchronization signal.

If there is no code match, the next one must still be used Synchronization interval can be switched. This is done by the flip-flop 349 via the AND gate 303 interrogating pulse from the pulse shaper 282 also to the OR gate 245 and thus sets the flip-flop 267 so that a next pulse a pulse train as synchronization Impulse can act on the timer 210. These processes are repeated as long as signals from the receiving amplifier 224 be delivered. If this is not the case, the two timers run 210 and 218 and thus output the blocking input 251 of the via the OR gate 254 Clock generator 338 free, so that this again pulses via the OR gate 247 the input of the theft monitoring circuit 222 can give. Should this be from of the actuation circuit 214 are no longer blocked, the status switches 374 examined again for their prescribed rest position.

The inventive circuit of the receiving device can according to Flg.5 can also be built using a microprocessor, for which purpose in the following an embodiment is given. A microprocessor 381 is on line 382 connected to a resonant circuit 383. An input 384 of the microprocessor 381 is connected via a line 385 to an output 386 of the receiving circuit 387. Port inputs 388 of microprocessor 381 are connected to status switches 389. Port outputs 390 are connected to signaling and actuating devices 391 via driver stages 392 connected. Port outputs 393 and port inputs 394 are via lines 395 and 396 connected to a diode matrix 397. A power supply 398, which is not shown Lines that provide the supply voltage for all components of the circuit is over a line 399 is connected to the reset input 400 of the microprocessor 381.

The functional description of this further embodiment is divided into functional groups. The functional sequence according to the flow chart is similar to this of the embodiment 1. There are differences in that the operation of a microprocessor consists in the serial processing of program steps. It therefore, several processes cannot run at the same time. This creates differences when monitoring irregularly arriving signals for a circuit arrangement no separate component is provided with the microprocessor. Be reversed mutual interlocking of circuits due to the serial program sequence unnecessary when using a circuit arrangement with a microprocessor. there only one Function can be realized at the moment.

1. When you turn on the power pack 398 comes over the line 399 to the reset input 400 of the microprocessor 381 for a short time in the power supply unit 398 generated signal that the program of the microprocessor at a starting point represents. Since not several functions can be carried out at the same time, is a start for the functional sequence is defined. The next program steps of the microprocessor consist in switching off the signaling and actuating devices 391. In order to said circuit arrangement is at a starting point.

2. The signals picked up by the receiver 387 pass through the Line 385 to port input 384 of microprocessor 381. Depending on the type of microprocessor the signals 384 are either stored and are thus available to the program for longer periods Time available, or have to be taken over by the program while waiting will. A pulse width monitoring is carried out by the program that with a step a 1, the port input 384 of the microprocessor 381 is present an input signal is queried. Is the input signal not exists, the program continues to other parts of the program. Is a signal available, after a few program steps a 2, which is only the time delay to serve. The input port 384 of the microprocessor 381 is queried again. Depending on the result a 3 obtained, a program branch is carried out in this way. that the program reacts to the received signal for further processing or to other parts of the program that also monitor received signals include. Depending on the microprocessor used, the input port must be queried 384 the port status can be brought to a rest position, in order to then be replaced by a new or to be switched over when the received signal is still pending.

or if the input port 384 has no memory effect, such an operation is not necessary. As the receiver as a pulse code recorded signals only have a length of about 100 seconds, one is possible frequent query of the input port 384 necessary. Otherwise it will be input signals not recognized, since the query is either made at a time when there is no signal is present, or at a point in time that simulates a signal length that is too short, since the entire signal is no longer recorded by the interrogation loop a 1, a 2, a 3.

3. The basic clock function has the task of monitoring theft from time to time of the program. It consists of a counting program a 4, which each time when a register assigned to this counting program has been decremented to zero is to emit a signal to switch on the theft monitoring program a 5.

The decrementing takes place with each run of the loop a 1, a 2, a3, a4, that is, following a query of the receive function with a negative Result. The register works cyclically so that after zero it comes to FFH. One special register setting following register content is therefore zero not mandatory. The decrement cycle takes about 5 msec. While 256 queries of the input port 384 are made during these times. During the Theft monitoring of 0.6 msec, there is no query of the input port 384. Input signals arriving now are lost because the decrement cycle runtime is far longer than that of the theft monitoring program and the length of time of the former is so arranged that no synchronization with the pulse intervals of the pulse code occurs, is a reliable detection of the emitted by the transmitter Signals given. The counting register to be decremented sets up in its effect the theft monitoring is the clock generator of which the main claim speaks.

4. This function is required several times in the microprocessor program and is therefore structured as a subroutine (SR-DIEB), which means that this Program only needs to be contained once in the program memory of the microprocessor, and that for this part of the program from different parts of the rest of the program can be accessed, and that after this part of the program has been processed, the accessing Program is continued with its own next program steps. That Theft monitor function subroutine asks port inputs 388 which are connected to the status switches 389, in parallel. That at the port entrances 388 standing Binary pattern consisting of the operating voltage of the circuit arrangement or no operating voltage is supplied with a binary pattern that is stored in the program memory of the Microprocessor 381 is stored, compared. If there is agreement, it follows Direct jump from the subroutine to the respective calling program. Lies if the binary patterns do not match, port outputs 390 and the driver stages 392 the signal and actuation devices 391 from the program addressed here. This is done by outputting a bit cluster to the port outputs 390. Then there is a return to the respective calling program. Because Additional security and monitoring functions not described, which are included in the Sequence of the subroutine must be executed, the same takes about 0.6 msec. During this time the program of the microprocessor only executes the said subroutine theft monitor and is not ready for other tasks.

After successful detection of an input signal using the Program parts a 1, a 2, a 3 run the program for the synchronization function b 1 to b8.

During this function, it is checked whether there is a next input signal occurs at input port 384 at such a time interval that this input signal the end of the synchronization pause and thus the beginning of the information part of the Pulse code means.

A program loop h 1 waits for the input signal ends. Depending on the type of microprocessor, a distinction must be made here as to whether the Stationary input signal by means of storage at input port 384 or only for a short time is available to the program for its own duration. In the former case the state of the input port 384 must be reset in each case within the loop b 1 will. As soon as the input signal is no longer present, the theft monitoring function will be activated called as a subroutine (program part b2).

This is followed by a dead time of the microprocessor (b3), in which is done nothing more than one set at the beginning of program part b 3 Counting register down to zero. This part of the program takes about 1 msec. Together with the program part b2, the microprocessor is therefore not 1.6 msec long able to examine received signals. Usually expected during this time there is also no received signal. It could just be interference.

These are hidden. This has the advantage that the theft monitoring function b 2 is not called up again immediately after a corresponding program run will.

After the dead time (program part b 3) has elapsed, the program part b 4 counting registers set in such a way that they can be used in conjunction with other program steps cause the program to work 17 msec for counting down to zero. This is followed by the program parts b5, b6, b7, which correspond to those of a 1, a 2, a 3 correspond, but now not with a program part a4, but with a program part b8 work together, which, similar to the clock generator program a4, has a duration specifies. Whenever there is no input signal in the receive function b5, b6, b7 has been recognized, the named counting registers are within the program part b 8 humbled. If the content of the mentioned counting register is not yet zero, it closes a new program sequence b5, b6, b7 follows. If there is an impulse, so jumps the program back to program part b 1. There will be a new theft monitoring feature b2 is called and the synchronization function starts all over again. To this In the course of the reception of the pulse code, there must be a synchronization interval pause being found. Are those used as counters in the course of such a pause Register switched back to zero. a program part b9 is executed, which corresponds to the one after the start for the detection of an input signal has been run through. With larger intervals, which are determined by the program part 34 the theft monitoring function a 5 is called. In between will repeatedly with program parts a 1, a2, a3 on the end pulse of the synchronization pause waited. With such an arrangement it is ensured that the theft monitoring also starts again if after the expiry of the specified with program part b8 Delay of 17 msec no input signal occurs, as is the case with the premature Switching off the impulses of a transmitter is conceivable.

Otherwise the end pulse of the interpulse period is found in any case, since the counting register in the program part a 4 does not yet monitor the theft has switched on. Would it be otherwise there could be a received signal during too early activated theft monitoring a 4 remain undetected.

When the end of the synchronization pause is recognized, the program runs into the detection function.

At the beginning of this, a register MXVEC is set to zero in program part c0 posed. It serves as a vector register for addressing the memory locations the bits of the pulse code to be recorded now.

In a program part c 1 a loop waits for that the received signal ends. This part of the program corresponds to part b of the program 1. This is followed by a program part c2 in which, as in program part bl, the jump to Theft surveillance subroutine takes place. This takes place after each recognized Pulse of the pulse code a theft monitor. This is followed by two registers set as a counter in such a way that two time intervals are specified with them, the first for monitoring the pulse spacing of the information pulses of the Pulse codes are used, while the second counting register has the task of preventing that the program is in the loop for detection even if there are no pulses the pulse length gets stuck, but jumps back to the start if necessary. le according to Art The programming for the time generation are one or two registers of each a byte length to be used for each of the specified times. These times are 3.5 msec for the length monitoring and 5 msec for the exit from the length monitoring loop.

With the program parts c4, c5, c6 a length monitoring of the Input signal. as with the program part a 1, a 2, a 3 and b 5, b6, b7 happens. Should an input signal be detected as long as the Interval monitoring register has not yet been decremented below zero, see above the received signal is taken as an indication that it is a pulse interval which corresponds to a zero bit. If, however, the pulse interval runs of the pulse code determining counting register below zero, then a receiving Input signal assigned an 1-bit. Should the input signal fail, the second register used for backup runs to zero, the was set to 5 msec, thereby causing the program to jump to the start state.

The recognized zero or 1 bits are stored in a register set, which is arranged in the form of a matrix with 5 rows of 8 bits each. this happens in a program section c 10. The matrix is designated MX 1. On each The position of the register to be filled is shown by the vector register MXVEC, which is associated with each Entry is incremented. This register also serves as a counter. in the Program part cli is not only incrementing this register, but also the comparison is made to see if this register has been increased to 40. So long that is not the case, the loop continues.

Further input signals are checked and the bits are monitored for length recorded and stored in the form of a matrix in MX 1.

40 bits have been entered, resulting in 41 input pulses corresponds, a comparison is made between the registers storing the bits and the diode matrix 397 carried out.

The comparison is made by calling up the matrix position line by line, in that output ports 393 address the diode matrix row by row and input ports 394 take over the bit configuration corresponding to the diode distribution and in one Store register MX2.

The individual memory locations of the register arrangement MX 1 compared with the individual diode rows. If the comparison is positive, it becomes a flag set.

At the end of the comparison process, the flag is checked. Is the flag has not been set, the program jumps back to the start. Is the flag set has been, a possibly pending message via signal and operating devices 391 Theft signal is switched off and access to the protected object, here the motor vehicle allowed. This is done via program part d 2.

The program then continues with auxiliary and additional programs and then continues to take over monitoring functions.

Claims (8)

Claims: 1. Circuit arrangement for electronic control or Unlocking of electronic security devices, in particular as door locks and anti-theft protection in a motor vehicle, with a signal transmitter that can be read out Has binary pattern memory with signal transmitter on the output side and one of the safety devices assigned signal receiver with downstream comparators and assigned binary pattern memory and an actuation circuit downstream of the comparator, wherein the transmission takes place by means of pulse code, characterized in that the signal transmitter such is designed to have a pulse train of pulses representing the pulse code of the same width with pulse intervals of three different lengths gives that the signal receiver has status switches (372, 389) to be monitored and such is designed that each received pulse of the pulse code the security device to monitor the status switch (372, 389) stimulates, and that a clock generator (238) is present, the pulses of which refer to the function of the pulses of the pulse code of the safety device if the impulses of the impulse code exceed a predetermined Time not standing in line. 2. Circuit arrangement according to claim 1, characterized in that the signal transmitter is designed so that the longest of the three pulses of the pulse code occurs once in each pulse train, and that the signal transmitter is designed in this way is that these pulses are used as synchronization signals for receiving the contained in the pulse code Serve information. 3. Circuit arrangement according to claim 1, characterized in that the signal transmitter is designed so that the pulses of the pulse code for 1 information of the binary pattern memory are twice as long as for an O information of the same. 4. Circuit arrangement according to claim 1, characterized in that the signal transmitter is designed so that the pulses of the pulse code for O information of the binary pattern memory are twice as long as for 1 information of the same. 5. Circuit arrangement according to claim 1, characterized in that the signal receiver is designed so that the clock generator has a pulse frequency with such pulse intervals that at least every second pulse of the pulse code falls within the intervals. 6. Circuit arrangement according to claim 1, characterized in that the signal receiver has a timing circuit (27), the pulses of shorter duration than blocks those sent by the signal transmitter. 7. Circuit arrangement according to claim 1, characterized in that the signal receiver is designed so that the safety device does the monitoring which sends status signals in periods of time when there is no impulse from the Pulse code is received. 8. Circuit arrangement according to claim 1, characterized in that the transmitter is designed so that the pulses of the pulse code with a carrier frequency be delivered. PRIOR ART The invention relates to a circuit arrangement of the type mentioned in the preamble of claim 1. For the electronic unlocking of door locks, it is known that a pulse train emitted by a signal transmitter, which represents a pulse code, the unlocking can trigger if it is correct in an assigned signal receiver Will be received. Such devices have the functions of mechanical keys. They have the particular advantage that a wide variety of key combinations can be generated purely electronically, in such a variety that unlocking by trying code combinations is practically impossible. Safety devices with status switches are known and commercially available or as Microtronic from Robert Bosch GmbH according to their prospectus WEB 1 AAW 12 15.79. Such safety devices work through the one triggered by them Alarm. They are locked and unlocked with a mechanical key so that the Authorized access to the object protected by the alarm is given by the alert is switched off. Because these alarm-triggering safety devices can be armed or turned off with a mechanical key the disadvantage that the associated mechanical key can be copied relatively easily and that due to the electromechanical construction, the production is expensive and the service life is limited. If a motor vehicle is protected with such safety devices, this has the disadvantage that several separate installations are required, which increases the cost. The invention is based on the object of a circuit arrangement to create that while retaining the advantages of an electronic key system Avoids disadvantages of previous safety devices with alarm and the Has advantages that it can be manufactured at a low cost and is practical is maintenance-free and has a long service life.