DE2521522A1 - Signal selector for radio communications system - has blocking circuit briefly blocking frequency sweep and actuating identifier - Google Patents

Abstract

The signal selector, for a radio communications system, has a blocking circuit between the discriminator and the flipflop circuit. This blocking circuit responds to a control signal from the discriminator and briefly acts on the flipflop circuit such that this flipflop circuit output voltage is held constant. The output voltage controls the local oscillator, and when held constant in this manner effectively interrupts the scanning process for the short time for which the blocking circuit has blocked the flipflop circuit. During its blocking interval, the blocking circuit alss actuates the identifying circuit.

Description

Means for selecting a specially drawn signal below of a number of radio signals The present invention relates to a device which in a radio frequency band selects a signal from among a number of radio signals to be associated with a special mark, for example in the form of a carrier wave modulating low frequency tones. The device comprises a known one Receiving device, which has a high frequency part for receiving the radio signals, a Local oscillator and a relaxation oscillator connected to it, which when activating the local oscillator by means of its outgoing breakover voltage controls, has. The local oscillator is called breakover voltage like this affects that he has his outgoing frequency within a predetermined Frequency range varies. The receiving device further comprises one with the outputs of the high-frequency part and the local oscillator connected mixer, one after the mixer is switched on Medium frequency amplifier that works every time when the varying output frequency of the local oscillator to a predetermined one Way coincides with a radio signal, emits an amplified signal, one after the medium frequency amplifier switched on discriminator and an identification circuit, which can be switched on during the distancing of the Fuiiksignals and for the above special characters is sensitive. The discriminator is such that he emits a signal at a first output that corresponds to the one modulating the carrier wave Character corresponds, and on a second output the so-called discriminator signal which indicates the presence of the carrier wave. The discriminator signal is also called a control signal.

The invention can be used in such contexts where one device on a certain radio signal with one (for the device) not previously known frequency, along with a number of other radio signals within a frequency band scanned by the device lies, wants to lock. as Examples of use can be systems for mobile radio stations, mobile radio telephones and non-stationary call facilities (paging systems) are mentioned.

In the case of e.g. systems for mobile radio telephones, it is essential that that the scanning of the frequency band and the locking at the relevant frequency done quickly and automatically because it is desired, the radio telephone system in such a way that the call connection is transferred to another radio channel in the eaves of the conversation is made possible if the reception quality is in the existing radio channel falls below an acceptable level, for example because one is wondering what station is too far away.

One purpose of the present invention is to provide the above-mentioned device to improve so that a quick and convenient sampling of the radio signals of the frequency band and Select the one with the relevant character provided Funksi.gnCles are enabled. Still the idea of the invention is that Latching oscillation generator assigned a locking circuit, which by means of the Control signals from the discriminator can be activated and, when activated, the oscillating oscillation generator influenced so that the breakover voltage going out to the local oscillator during is kept constant for a relatively short time. During this short Time the receiving device checks the radio signal and if so the special character not has7 the locking circuit releases the tilting wave generator and this one can continue his interrupted Abts @ t @@ until a new radio signal is encountered will us.

on the other hand, the radio signal has the special symbol, the identification circuit reacts, and the oscillating oscillation generator is influenced in such a way that the scanning process is aborted will.

In a proposed embodiment, he mentioned locking circuit acts together with a receiving device, which is used to automatically hold on to the set Radio signal, e.g. for automatic frequency adjustment (AFN), is arranged.

Such a regulating function is well known per se and is thereby characterized by having the device sampled at the center frequency of the Radio signal remains, regardless of any migration tendencies on the device. The regulating function works by means of a closed loop, which except the mixer stage, the medium frequency stage, the discriminator, the relaxation circuit and the local oscillator one of the locking circuit of the Kippsehwin.gungsgenerator includes detachable detention circle, at least during the mentioned short Time is switched on and the regulating function mentioned when it is switched on activated. The activation of the locking circuit in connection with the scanning is best done by a rapid charge circuit that is predetermined during the short Time causes the closed loop with a relatively small Time constant work kami, which has the consequence that the device can quickly adjust to the medium frequency. The interlock circuit turns off the locking circuit when the scanned radio signal gives the sign not has. The activation of the detention circle, however, is done by the identification circle accepted if the radio signal shows the sign mentioned.

In this case, the identification circle also takes over the holding of the relaxation oscillation generator, while the detention circuit is deactivated disconnects the fast charging circuit from the retention circuit after the predetermined time, according to which this works with a larger time constant.

A proposed embodiment of a device which the for the invention has significant features, will be explained below with reference to the attached Drawings explained.

They show: FIG. 1 the device in the form of a block diagram, FIG. 2, in the form of a block diagram, various individual parts of the device according to FIG. 1, Fig. 3 in the form of a schematic diagram of the first parts of the individual parts according to Fig. 2, Fig. 4 in the form of a principle diagram other parts of the individual parts according to Fig. 2, FIG. 5a in a diagram the outgoing breakover voltage of a in the device utilized Kipps chwingungs Eenerat ors, Fig. 5b in a diagram in detail a single oscillation of the breakover voltage according to FIG. 5a, FIG. 5c in a diagram those on different units of the device during a first functional section occurring signals, Fig. 5d in a diagram that of the same purities as in Fig. 5c occurring during a second functional section Signals, and fig. 6 shows the identification circuit in the form of a basic circuit diagram.

In the figures, the corresponding parts are with the same Provided with reference numerals.

mig. Fig. 1 shows a receiving device in which Cirie Empfa antenna with Ant and a high frequency stage with HF. The equipment includes also a local oscillator LO, as well as one at the outputs of the high frequency stage and the local oscillator connected mixer M, at whose output a medium frequency amplifier MF is connected. There is a discriminator at the output of the medium frequency amplifier D connected and the local oscillator is powered by a relaxation oscillator SV controlled. The parts mentioned can be in a manner known per se and by means of a technique known per se and will therefore not be discussed in detail here explained.

The high frequency stage is tuned to frequencies in a predetermined Receive sand, for example in the band between 465 and 467 MHz. The local oscillator is controlled by the oscillating oscillation generator in such a way that it depends on the Control the frequency of its output signal to vary between 455 and 457 MHz can be what can be generalized as 445 + A MHz, where A = 2 MHz. The medium frequency stage MF gives a 10 MHz signal every time the difference between the frequency of the received carrier wave and that of the local oscillator output 10 MHz. The discriminator is arranged in such a way that a deep tone, which has been modulated onto a received radio signal as a special symbol, is separated and output at a first output of the discriminator. The discriminator is also arranged to be at a so-called second output Output discriminator signal, which according to the description below as control signal is used in the receiving device.

At the mentioned first exit of the discriminator there is also a known low-frequency amplifier connected in which the bass is amplified will. At the exit de. Low frequency amplifier is in turn an identification circuit TD connected, the one for the bass or the special character.

is sensitive. At the output of the low frequency amplifier LF is also a receiver Mot connected for speech signals, however, of the invention is not directly affected.

The receiving device shown in Fig. 1 is also for so-called automatic frequency adjustment arranged, i.e.

the device is connected to one of the device during the scanning process selected radio signal automatically recorded.

For this purpose, the device contains a retention circuit fTTC, which in its activated state to a closed symbolized by the arrow RS One of the regulating loops, the possible migration tendencies of the device counteracts it and picks it up at the center frequency of the radio signal in question.

The signal voltages mentioned above are of the following C orders of magnitude. The discriminator signal or the control signal from the second output of the discriminator is of the order of magnitude # 1 V, the regulation voltage (setting voltage) between the Discriminator and the locking circuit + 0.05 V and the regulating voltage between the relaxation generator and the local oscillator + 0.02 V (period 0i2 s). Know both the local oscillator signal and the medium frequency signal because of Variation of the regulation voltage, its frequency by + 500 Hz in relation to theirs Denominations vary. The breakover voltage varies between 2 and 10 V and the breakdown oscillation time is 0.5s in the case shown The aforementioned oscillating oscillation generator a special interlocking circuit LS is assigned to the relaxation oscillation generator, as soon as the receiving device encounters a radio signal during the scanning process, to influence is indicated.

The interlocking circuit is by means of the second output of the discriminator outgoing control signal can be activated, which control signal with the trailing edge its negative part a monostable multivibrator located in the locking circuit triggers. The interlocking circuit influences the tilting oscillation generator, among other things. by an OR gate GR and the one shown in Fig.

line labeled L1. When activated, the Locking circuit the tilt generator SV so that its outgoing tilt voltage is kept constant, i.e. the scanning process of the device is interrupted. The interlocking circuit also influences the retention circuit by: L2 that the closed loop starts to work, which causes the device that narrow after fine adjustment to the center frequency of the scanned radio signal strives. The activation of the interlocking circuit also causes an activation in part from the identification circuit ID through a line L3, partly from a rapid charging circuit SL, which is connected to the retention circuit HK.

The fast charge circuit causes the breakdown capacitor of the breakdown generator gets fast charges and discharges, so the loop closed in this one Situation receives a small time constant, which causes the settling on the medium frequency can be carried out extremely quickly.

The one quickly tuned to the radio signal in question in this way The device checks whether the radio signal is assigned that character tone for which the also activated identification circle is sensitive. Is that sampled If the radio signal is not provided with the relevant character tone, the influence will be heard of the ripple generator from the interlocking circuit J.S, in that the monostable Multivribrator of the interlocking circuit to its starting position after its activation time knock over. The relaxation generator can then be Continue tilting process, i.e. the scanning process continues the deactivation of the interlock circuit, i.e. the overturning of the monostable multivibrator in the starting position also causes that the identification and retention circuits are blocked and that the rapid charging circuit and turn off the feedback loop. The identification circle is blocked during the tilt, so the noise signals from the discriminator s ont affect the identification circle and thereby the condition of identification could make you insecure. The retaining circle must also be blocked during the tipping otherwise the noise signal received by the device will be a variation around the zero value of the outgoing discriminator signal, which in turn would cause should have such an influence on the outgoing breakover voltage, that the tilt would be notched.

If the scanned radio signal contains the character tone, it will specified by the identification circle, after which the identification circle by a Line L4 and the OR gate its own activation and that of the detention circuit and d relaxation generator takes over. The interlocking circuit is also in this case deactivates and switches after the activation time of the monostable multivibrator when it is disconnected, the Schlmelladestromkreis St, which causes the closed Loop then works with a relatively large time constant.

Such a large time constant is necessary because the loop with a certain delay after that the device has to work on a has been locked with the mentioned sound drawn carrier wave. Otherwise were Disturbances caused by rapid changes in the speech signal receiver Mot be obtained.

Fig. 2 shows the structure of the locking circuit tS, as well as that of the Retention HK and the tilting circle SV in more detail. The locking circle has signal matching circuits for the incoming control signal from the discriminator on, which matching circuits have a capacitor C1 that has the influence of DC drift and slow interference eliminated, as well as a low-pass filter F1, which reduces the risk of interference with higher frequencies, unfolds. The interlocking circuit also includes a differential amplifier f1 and the monostable already mentioned Multivibrator. The monostable multivibrator emits an impulse of length # t which influences the oscillation circle through dns Oder-Tcr in such a way that the tilting is interrupted during the mentioned time @ t. The time mentioned is in the exemplary embodiment of the order of magnitude of 25 - 70 ms, but can of course take into account the practical application can be selected. The tilting time of the tilting circle is in the previous one Case 0.2 - 1.0 s. The hold circuit is also equipped with a low-pass filter F2 for the incoming control signal from the discriminator and with an amplifier f2, the can be activated by the outgoing signal of the monostable multivibrator. The arresting circuit is made up of two current generators G2 and G3, which are supplied by the relevant Outputs of the differential amplifier f2 are controlled v-see. The union point P between the current generators G2 and G3 is connected to the relaxation circuit SV one of the current generator that can be switched on and off by the signal from the monostable multivibrator G-1 contains, through which the capacitor labeled C of the relaxation circuit being charged. The on and off functions of the power generator G1 are indicated in Fig. 2 with t / f. The capacitor C of the relaxation circuit acts with a discharge circuit UR, which discharges the capacitor in question as soon as it has reached its higher state of charge. By the circuit shown can the capacitor C during the locking phase obtained by means of the locking circuit, since the current generator G1 is switched off, the frequency at the output is aimed at of the local oscillator corresponding charging voltage can be allocated. Tends the charging voltage to get too low, for example because of scattering, more charge is carried through the current generator G2 is supplied, and if the charging voltage on the other hand becomes too high, the capacitor discharges through the Power generator G3. Even the on and off functions of the current generators G2 and G3 are t / f indicated, while the designation h / l ül Fig. 2 means high / low (fast respectively slow loading).

Fig. 3 shows in detail examples of the relevant components of the Locking and tilting oscillation circles. The differential amplifier f1 is in a per se known ztreise executed what also for the monostable multivibrator MV applies, which is not shown in detail in FIG. 3, however, since it consists of a normal and known monostable multi vibrator can exist. Between the amplifier f1 and the monostable multivibrator MV are fitted with matching circuits, partly in the form of a Zener diode Z, which only negative pulses from the discriminator to the monostable multivibrator MV, partly in the form of an amplifier stage, which provides the right supply voltage for the multivibrator.

The relaxation circuit has a no circuit INV and an the switching on and off of the switch circuit responsible for the current generator G1 S on. The discharge circuit UR comprises one which is switched on in a manner known per se Unijunction transistor. Between the output of the trigger circuit and the input of the Local oscillator there is still an adjustment circle.

Fig. 4 shows in an example in detail the structure of the holding and quick charge circles. The detention circuit includes switch circuits S2 and S3, which switches the power generators G2 and G3 on and off as a function of worried of controls from differential amplifier f2. The activation of the detention circle takes place through a switch circuit S4, which is the locking circuit during the tilt blocked. The quick charging circuit is switched on and off by means of a switch circuit S5 concerned, which is controlled by the monostable multivibrator iW.

6 shows an exemplary embodiment in the form of a basic circuit diagram of the identification group ID. A bandpass BP is provided by the line L5 Low frequency amplifier supplied to incoming low frequency signal. A switch circuit S6 worries that the integrator INT is disconnected during scanning on a radio signal that is modulated with the desired clock tone this signal passes the bandpass and the switch circuit and is fed to the integrator.

The voltage across the integration capacitor C2 increases in the process, bio. a level detector AD flips over and emits a high voltage at its output, which only the locking of the locking circuit and the activation of the switching circuit It is necessary to take over S6 in the identification circle.

The function of the device described above is based on the timing diagrams in Fig. 5a-5d explained in more detail, wherein the vertical axes the voltage U and the Horizontal axes ci.e time t- show. It is believed that the breakover circuit is in function, the breakover circuit giving the local oscillator a breakover voltage 5a until a radio signal ii.t has been identified as the low tone signal is. The tokaloszillator wobbles between 455 and 457 MHz, as above, so that the band 465 - 467 MHz in the incoming signal to the high frequency stage through the medium frequency stage MF can be scanned continuously, which only has difference frequencies of 10 MHz passes. Whenever a radio signal is encountered in the scanned band, should, as mentioned above, the device at the frequency in question during a be locked for a predetermined time1 so that the radio signal with regard to the relevant characters can be checked. After this test time, the sampling should continue if the sign is not present or the lock remains, when the mark is present. In Fig. 5b this is done with part of a single tilting curve shown in detail according to FIG. 5a. at is a radio signal found in the tape and tested during a time #t, which was also the case with II and III happened. In the case of IV, a relevant radio signal showed a sign to which the device is sensitive, which is why a lock after testing happened on the relevant radio signal.

If you use the device during wobbling between II and III viewed in Fig. 5b, the discriminator is made by the medium frequency amplifier sample noise only, which is also the case for the low frequency amplifier. While the interlocking circuit, the identification and the Retention circuits blocked, the fast charging circuit and the feedback loop switched off. If, according to FIG. 5b, a relevant radio signal is encountered, for example at III becomes the discriminator through the mixer and the medium frequency amplifier influences and gives a signal UD at its output to the interlocking circuit Fig. 5c, which shows the outgoing signals from the units LS, ID, D respectively. SV shows. The monostable multivibrator is triggered in the locking circuit, which in this way will emit a signal ULS according to FIG. 5c. Because after the Assumption that the radio signal encountered according to Fig. 5b does not have the special symbol, the signal ULF from the frequency amplifier will have such an appearance, for which the identification circle is not matched, which is why the signal of the identification group UID becomes zero. If that's why the monostable Multivibrator returns to its starting position, the locking of the relaxation oscillator stops and scanning continues in the same way as between II and III to IV. When the locking stops, the UD signal of the discriminator becomes positive Get a tip to which the following circles do not react.

If after continued scanning the radio signal is encountered at IV is, a check is carried out as above and because after accepting this scanned radio signal a character in the form of a modulated on the carrier wave Has low frequency tones, according to Fig. 5d, the output signals ULF 'respectively. UID 'obtained from the low frequency amplifier and the identification circuit. Included is only to notice that the identification circuit gives its output signal quickly must, so that he can take over the locking of the tilt generator, before the monostable Multivibrator returns to its original position. The predetermined time (= the Activation time of the monostable multivibrator) and the identification circuit must be calculated in such a way that a safety margin #t 'is obtained.

The closed loop works like a known regulating circuit. If the breakover voltage wanders, e.g. 3. due to scattering in the tipping condensate, the Local oscillator frequency changed, causing a change in the center frequency and causes a migration of the discriminator signal from the zero voltage. By the holdover circuit is then changed to the breakover voltage so that the equilibrium is restored, i.e. the discriminator voltage becomes zero again.

The rapid charging circuit causes the discriminator signal UD to the solid line in Fig. 5e can quickly assume its zero value. In Fig. 5c is also with a dashed line the character of the discriminator signal, in the event that the quick charge circuit is missing or out of order, shown.

The device remains locked at the frequency in question until Switching back through the identification circuit from outside, not shown here Circling takes place.

The invention is of course not limited to the above as an example The specified embodiment is limited, but can be used in the context of the following Claims are modified.

Claims (4)

P a t e n t a n s p r ü c h e Device operating in a scan in a radio frequency band among a number of radio signals, a radio signal provided with a special symbol selects and a radio frequency part (HF) that receives the radio signals, a local oscillator (tc) and a Kispkreis (SV) connected to it, which when activated by means of its outgoing breakover voltage, the local oscillator controls which breakover voltage causes the local oscillator to have its outgoing frequency within a predetermined Frequency range varies, one at the outputs of the high-frequency part and the local oscillator connected mixer (M), a medium-frequency amplifier switched on after the mixer (MF), the each time the varying frequency emanating from the local oscillator corresponds to a radio signal in a prescribed manner, an amplified signal gives away. a discriminator (D) switched on after the medium frequency amplifier, which emits a control signal depending on the amplified signal, as well as a Identification circuit (ID) that is used while the radio signal in question is being scanned can be switched on and is sensitive to the named character, includes, thereby g e k e n n -z e i n e t that between the discriminator and the tilting circle Lock circuit is switched on, which depends on the control signal of the discriminator such an influencing of the tilting circle during a predetermined, short time it causes that the breakover voltage going to the local oscillator holds constant, and thus that the scanning process during the predetermined, short Time is interrupted. 2. Apparatus according to claim 1, characterized in that g e k e n n z e i c h -n e t that the locking circuit depends on the control signal of the discriminator (D) too. an activation of the identification circuit (ID) during the predetermined, short time causes. 3. Apparatus according to claim 1 or 23 wherein between dc. Discriminator and the tilting circuit a retention circuit (HK) switched on is, which together with the breakover circuit, the local oscillator, the mixer, the medium frequency amplifier and the discriminator is part of a closed control loop that works is determined after the identification of the radio signal in question, thereby g e no indication that between the output of the interlocking circuit u.nd the retention circuit a fast charging circuit (SL) that can be activated by the locking circuit is switched on by connecting a power generator to the detention circuit a decrease in the closed loop time constant during settling of the control signal. 4. Apparatus according to claim 3, characterized in that g e k e n n -z e i c h n e t that the locking circuit can be activated by the control signal of the discriminator monostable multivibrator (MV), the activation time of which is the predetermined, short time determined and that the multivibrator during its activation time the influences of the tilting circle and the Schnellandekreis caused-. L e r s e i t e