NO763089L - - Google Patents

Description

Coupling device for a

selective signal receiver.

The present invention relates to a coupling device for

a selective signal receiver where the time intervals between the zero crossings for the alternating voltage input are measured during a measurement period comprising a first number of periods of the alternating voltage input, and in particular such a device used in telephone systems.

Signal receivers of this type are previously known, e.g.

from the German DOS Nos. 2,341,225 and 2,341,224. In these known signal receivers, one counter determines during each measurement the time interval between the first zero crossing and a last zero crossing for a first number of periods of an incoming alternating voltage. In order to allow the detection as early as possible of a signal which is peculiar to the system, but which is burdened with certain disturbances, the relevant signal recognition in a main check is not started until it has already been found in a preliminary check which comprises only a few periods and which has a larger bandwidth, that the input voltage can contain a signal frequency. In addition to this pre-check and the main check, a periodic or semi-periodic check can be performed at the same time to protect against speech signals.

The received signals, which are specific to the system, can have different lengths. This is particularly the case for systems where number impulses are carried out using a keypad, because the duration of the operation of the push buttons depends on the habits of the individual user.

When the occurrence of a signal peculiar to the system has been detected in the main control, a direct voltage signal is sent from an assigned output on the evaluation circuit to a signal output circuit. The duration of this DC signal depends on the signal duration. With such a digital signal receiver, the following problems arise with regard to accurate signal separation and short interruptions in the signal.: a) In the intervals between two signals which are both peculiar to the system, noise in the form of speech can

or other disturbances reach the signal receiver. Such disturbances can be very similar

very much on the signals that are specific to the system

Therefore, it can happen that a signal has been transmitted and that this signal has been replaced by a disturbance that is very similar to a signal.

To be able to detect the termination

of a signal, the measurement must continue to determine whether the same signal is still present.

It is therefore an object of the present invention to be able to detect the termination of a signal which is peculiar to the system at an early time, but still in a reliable way. b) After the presence of a signal that is specific to the system has been detected, disturbances to the signal can occur in the form of signal interruptions that divide the DC signal at the respective output from the evaluation circuit, so that two output signals will appear even if only one signal is present . It is therefore another purpose of the present invention to prevent a signal disturbance from being registered at the respective output from the evaluation circuit.

This is achieved according to the present invention by

to design the coupling device according to the patent claims set out below.

It has been shown that the additional measurements according to the present invention, which each cover a small number of periods, ensure a sufficient frequency selectivity. A lower degree of frequency selectivity that would be obtained if each of the additional measurements spanned only a single period, as in the conventional periodic control, could result in the first emitted signal being retained for too long and the subsequent signal therefore not being recognized . This can particularly occur if two identical signals follow each other. If, on the other hand, each of the additional measurements covers several periods,

as in a conventional master control, the intervals between successive signals must be relatively long. However, if the intervals between the signals e.g. is

relatively short, the proportional rule for the multivibrator's retention time in accordance with the present invention ensures that a signal interruption caused by disturbances can be overlapped, while an interval between two signals can still be recognized.

To be able to satisfy even more stringent requirements with regard to separating pulses/intervals, such as e.g. for keypad telephones, the circuit according to the present invention can be made even more selective by the fact that the multivibrator can be switched to its 1-th state by means of pulses generated by the zero-crossings of the alternating voltage input, and that the retention time of the multivibrator includes at least the duration of the longest signal disturbance and the duration of a further measurement. This allows the area where an accurate detection of a pulse interval or of signal disturbances is uncertain to be shortened by the duration of a further measurement.

The equipment according to the present invention can advantageously be used for a selective signal receiver as described in the previously mentioned German DOS No. 2,341,224. In such a signal receiver, each signal recognition process includes several periods of the alternating voltage input, and it is determined in a semi-periodic or periodic control that is performed at the same time as the main control, whether the alternating voltage input can have a signal frequency. In another embodiment of the present invention, the multivibrator can be switched to its 1 state by means of pulses that are generated at the zero crossings of the alternating voltage input if, during the half-period control or the period control, it is determined that the alternating voltage input can have a signal frequency. Thus, not every zero crossing of the AC input, but only every correct zero crossing that falls within the specified times, is used to trigger the multivibrator. This allows the number of errors in the evaluation to be reduced.

In the selective signal receiver described therein

German DOS No. 2,341,224, the signal recognition process comprises several periods of the AC input and is not started in a main control until it has been determined in a pre-control which comprises one or a few periods and has a larger bandwidth,

whether the switching voltage input can have a signal frequency.

For a signal receiver that uses this method it can also be created

an embodiment where each of the further measurements has the duration corresponding to a preliminary check. This allows the equipment in the receiver that is used for preliminary control to be used in further measurements so that a saving in costs is achieved.

The aids that are used in connection with the present invention can also be used in connection with a receiver for keypad telephone signals in a telephone system where signal frequencies that are peculiar to the system include a double

(1-of n ) code, and where for each frequency group, the time intervals

between the zero crossings for the alternating voltage input is measured during a measurement period comprising a first number of periods of the alternating voltage input, this being the output voltage from a group filter which is assigned to the respective frequency group. In this case, the receiver for the keypad signals should be

designed so that the multivibrator is affected only by the frequencies of one frequency group. However, a better signal selectivity can be achieved if the multivibrator can be influenced by other frequency groups as well. In a further embodiment of the present invention, the multivibrator therefore no longer receives trigger pulses

to switch to their 1 state when they exhibit further measurements or the half-period control or the period control

negative results only in one frequency group.

At the end of a signal interruption it may occur that

in the periodic check, the presence of a frequency deviating from the previously recognized frequency is detected, which results in a continuation of the simultaneous pre-check, which could show one positive result despite the change from the recognized frequency to the other frequency. In another embodiment of the present invention, the detection of the presence of signal frequencies which do not correspond to those already recognized is therefore prevented while the multivibrator is in the 1 state. This allows the uncertainty area after a signal disturbance to be kept very low

card. It also allows recognition of a relatively short keying interval between two different signals.

In order to provide a clearer understanding of the present invention, reference is made to the following detailed description of some embodiment examples and to the accompanying drawings where

Fig. 1 shows a block diagram for a receiver of a double-group code signal in accordance with the present invention. Fig. 2 shows a logic diagram for a part of the evaluator circuit as shown in fig. 1, and this part is essential for understanding the present invention, and Fig. 3 shows a graphical representation of a signal (A) at the input E, for the signal (B) at the output 01, and for the durations of the period control (B) and for for-main and additional controls

(C).

The signal receiver in figure 1 is used as a code or button rate signal receiver in a telephone system. During numbering, each digit is formed by generating and sending signals with two different frequencies, one of which belongs to a first frequency group, while the other belongs to a second frequency group. The signal frequencies in the first frequency group can e.g.

have the following values: 697,770,852,bg 941Hz, while the second frequency group e.g. can consist of the frequencies: 1.209, 1.336, 1.477,

and 1,633 Hz. These signals, which contain two different frequencies, are generated in the phone using signal generators.

The signal received at input E is first amplified

in one input amplifier V and then passes through a number-signal filter WF, and is then fed to the group filters GF1, GF2, where the two frequency groups are separated. If the received signal is composed of two number code frequencies, the separation of the two frequencies is performed using these group filters.

Each of the signal voltages assigned to these frequencies is used to drive a limiting circuit B1, B2 which transforms the sinusoidal signal voltage into a square voltage. A free-edge pennii is supplied (over an input Tl) to an evaluation circuit Al,

and the second square voltage is fed to an evaluation circuit A2. The evaluation circuits determine whether the frequency in the received signal lies within predetermined ranges assigned to the digit code frequencies. The result from the evaluation circuit is fed via the four outputs ( 01 ) of each evaluation circuit Al,A2 to a signal output circuit ZA which checks whether a signal frequency

available in each frequency group. If this is not the case, the code signal is delivered via output A.

Figure 2 shows a logic diagram for part of an evaluation circuit, i.e. for the evaluation circuit Al in figure 1. The square voltage is fed through the input II to which additional circuits (not shown in the figure) to improve the blocking of the speech frequencies are connected, to a zero crossing detector ND which provides a short-term pulse every time the square voltage passes through zero. These short pulses are counted by a zero crossing counter NZ whose counting capacity is adjustable. The zero crossing counter NZ has two outputs AV, AH. the output OFF corresponds to a relatively low count, i.e. up to a total count of e.g. 32.

When the adjusted final counter result AH for the zero-crossing counter NZ is reached, the latter circuit generates a reset pulse 3 across an OR gate OR and resets itself and the other circuits at the reset inputs R.

The reset pulse is also used to place a time pulse counter TZ in its zero position. The input T from this time pulse counter is fed with the time pulses from a time arrow generator (not shown in the figure). These time pulses have a relatively high frequency compared to the signal frequencies to be determined, and are counted by the time pulse counter TZ until the last one is reset by the zero crossing counter NZ across one of the outputs AV, AH. The time pulse counter TZ has several outputs. For each code signal frequency, two lower counts and two upper counts can be derived. Let's assume that e.g. for the frequency f^, an output Z11 is assigned to eh lower count and an output Z21 is assigned to the corresponding upper count. The output Zll is connected to the setting input of flip-flop Fli whose reset input is connected to the output Z21. In an analogous way, a flip-flop F21 is assigned to the frequency f2, and 2 additional flip-flops (not shown) are connected to the corresponding outputs from the time pulse counter TZ. The outputs of these flip-flops are connected via an OR gate OF to an input of an AND gate UF whose other input is connected to the output of a latch gate SG. The output from AND gate UF is connected to an input to OR gate OR and to the reset input for a flip flop SF. The setting output from this flip-flop is connected to an input on an AND gate UK and to an input on an AND gate UC. The output of the AND gate UK is connected to the latch input of a latch gate SG, whose enable input is connected to the output OFF of the zero-crossing counter NZ. The output of the AND gate UC is connected to an input of an OR gate OB whose output is connected to the input of a monostable multivibrator MK. This monostable multivibrator is constructed in such a way and has such proportions that it will produce a 1-state signal at its upper output when there is a trigger pulse at its input, and will remain in this state for a predetermined period of time (the retention time).

which includes at least the duration of the longest signal disturbance and the duration of a further measurement, as explained below.

The upper output from the monostable multivibrator MK is connected

to an input on AND port UC. The lower exit, i.e. the reset output ( Q ), on the monostable multivibrator MK

is connected to an input on AND port UK and to the dynamic reset inputs of flip-flops AFi, AF2, and to two further flip-flops (not shown). These flip-flops are resettable only if a transition from 0 to 1 is present at the reset output of the monostable multivibrator MK. The short-lived pulses generated by the zero-crossing

the detector ND is fed to a semi-periodic or periodic control device PP. This control device measures the time interval between the zero crossings of a half period or a period of the alternating voltage input and checks whether the measured time falls within the pattern of the relevant signal frequencies.

If this is the case, a short pulse will appear after each half period or after each period. This short pulse is fed to an input on AND port UC. The reset outputs for the flip-flops Fil, F22, etc. is connected via AND gate UA to an input on AND gate UB whose other input is connected to the output of gate SG, and whose output is connected to an input on OR gate OR.

It is also assumed that one output Z1 assigned to the second lower counter, and one output Z2 assigned to the assigned upper counter is provided for the frequency f^. the output Zl is connected to the reset input of a flip-flop Fl whose reset input is connected to the output Z2. In arialbg fashion, a flip-flop F2 is assigned to the frequency f2, and two extra frequency flip-flops]

(not shown in the figure) are connected to assigned outputs

from the time pulse counter TZ. Each of the outputs from these flip-flops is connected to an input on an individually assigned AND gate Ul, U2, etc. The other inputs on these AND gates and an input tj OR gate OR are connected to the output AH from the zero crossing counter NZ. The outputs from these AND gates are connected to the setting inputs for the flip-flops AF1, AF2, etc. The outputs from these flip-flops are connected to the signal output circuit ZA

as shown in Figures 1 and 2 at outputs 01 from flip-flop AFl. The outputs from AND gates Ul, U2 are also connected to an input to OR gate OB via an OR gate OA.

During the ongoing half-period or full-period controls, the control device PP will also determine whether the measured time falls within the time pattern of the relevant signal frequencies or not. If this is not the case, it will provide pulses across its output AN at the moments when the AC voltage input has its zero crossings.

These pulses are fed to an input and an OR gate OC.

This gate has its second input connected to the output of AND gate UB, while its output is connected to the reset input of flip-flop SF. Thus, the flip-flop SF will be able to be reset either in response to a semi-periodic or a periodic check with a negative result or in response to a preliminary check (or a further check) with a negative result.

In the presence of an input signal on the input

II, a pre-check is always performed with the flip-flops Fil, F22 ... before the main check, i.e. the relevant frequency recognition process can be performed by the flip-flops Fl, F2 .... E.g. the flip-flop Fil is switched to its 1 state when the value counted during the time between the reset of the timer counter TZ and the appearance of a signal at the output AV of the zero-crossing counter SZ, which time span comprises only a few periods, is between the values Z11 and Z21 . In this case» flip-flop Fli sets the flip-flop SF across the gates OF, UF, after which the flip-flop SF blocks the blocking gate SG across the AND gate UK. At the same time, the flip-flop Fil causes the reset of the zero-crossing counter NZ, the time pulse counter TZ and the flip-flop Fli, across the gates OF, UF, OR (the reset of the flip-flop Fli is not shown). After the next zero crossing of the ac voltage input at input II, the counters NZ , TZ start counting again while the zero crossing counter NZ continues to count past its setting AV, because no reset can be performed across the latched gate SG. If the value that is counted during the time between the reset of the counter TZ

and the appearance of a signal at the output AH of the zero crossing counter NZ, lies between the values ZN1 and Z2, the flip-flop Fl is in its 1 state. As an indication that the frequency has been determined, a momentary output signal is emitted when the final counter state AH of the zero crossing counter NZ is reached.

This output signal sets flip-flop AFl, so that a 1-state signal appears at output 01, and at the same time this signal triggers the monostable multivibrator MK across gates OA and OB. The count of the zero crossing counter NZ up to the final counter value AH can be called the main control. This main control includes several periods of the alternating voltage

which is supplied to input II. Number of periods for the pre-check

and the main control is determined by the selection of the intermediate count AV and of the final counter reading AH for the zero crossing counter NZ. The lower counter Z11, Z1 and the upper counter Z21, Z2 as well as the analog counters for the other frequencies are selected depending on the predetermined number of periods, on the predetermined tolerances for the signal frequencies and on the permissible interference voltage components that can be obtained. The outputs from the counter TZ are connected so that the frequency band that is evaluated between the outputs Zl and Z2 e.g. is narrower than that evaluated between the outputs Z11 and Z21. With the pre-check which only includes a few periods of the input voltage, but extends over a larger bandwidth (Z11 to Z21), it can thus be determined according to Figure 2 that the input voltage can be a signal frequency, after which steps are taken to carry out the main check.

After a positive precheck and main check, the flip-flop SF and the monostable multivibrator MK as described will be in their 1 state. Therefore, the signals indicating 1 state will appear at the two lower inputs of AND gate UC. At each zero crossing of the alternating voltage input which is found to be correct by the control device PP, the latter device gives a pulse to the upper input of AND gate UC. These pulses pass through the OR gate OB to the input of the monostable multivibrator MK and cause the hold time of this multivibrator to be restarted. In the 1-state of the monostable multivibrator MK, an O-state signal appears at the reset output of this multivibrator, so that the AND gate UK is blocked, and the measurements or the additional controls

(WP, figure 3) which follows the main check has the same duration as the pre-checks, because after the middle position AV is reached the counters NZ and TZ are reset over the gates SG, UB, OR. At the end of the signal peculiar to the system, the control device PP terminates the supply of pulses, so that the monostable multivibrator MK no longer receives trigger pulses. The further control is also negative, so that the AND port UC is blocked. The monostable multivibrator MK then returns to its stable state at the end of its hold-time, with an o to 1 transition occurring at its reset output, causing flip-flop AF to reset. At the same time, OG-port UK is reopened and thereby creates the condition which once again requires a new pre-check and main check.

If, however, none of the flip-flops Fil, F22 has been set at the end of the few periods of the input voltage and of the simultaneous marking of the output OFF ( precheck

AND gate UA will produce an output signal so that counters MZ, TZ will be reset across gates UB, OR, so that a

new preliminary inspection will be prepared. These counters will too

be reset if none of the flip-flops Fl, F2... are in their 1 state during the main control, in which case the reset is performed by the signal appearing at the output AH and passing through the OR gate OR. If there is no AC detection input at all at input II, the half-period or period control using the control device PP will be negative. This control device then transmits over the OR gate OR in a manner not shown in the figure * a reset signal by means of which the counters

NZ,TZ will be reset.

Figure 2 shows that the same circuits ND, NZ, TZ are used

for the pre-control, the main control and the additional controls and that for the main control the upper and lower outputs Zl, Z2 in the clock pulse counter TZ are activated instead of the lower and upper counter outputs Zll, Z21 which are used for the pre-control.

The other counter outputs (partially not shown) are activated

Similarly.

The processes that take place when a signal interruption occurs will now be described with the help of Figure 3.

Figure 3 A shows the alternating voltage input U_, at the input

Il as a function of time t. A signal with frequency f appears, and in the figure, apart from a few oscillations, only the envelope curve of this signal is shown. In the last third of the signal, an interruption occurs. The signal is framed by interference loops.

Figure 3B shows the results of the half period or period controls using the control device PP. Before the onset of the signal occurs, these checks can have a negative or, due to the interference voltages, a positive result. These controls are positive from the beginning of the signal until the interruption occurs, negative during the interruption itself, and positive again after the interruption until the end of the signal. At the end of the signal, these checks can again have a negative or, due to the interference voltages, a positive result. Only when the result is positive does the control equipment PP provide pulses over its outputs AP

to AND port UC.

Figure 3 C shows the results from the preliminary controls VP, from the main control EP, and from the additional controls WP. Let us assume that the first pre-check has a negative result and that the same is the case with the second pre-check due to the frequency shift during the build-up of the signal generator unit or of the group filter GF1. The third preliminary check has a positive result so that the flip-flop SF is set to its 1 state, and the main check begins. Let us assume that the main controller EP has a positive result, so that the flip-flop AFl and the monostable multivibrator MK are set to their 1 state at the instant t^

In Figure 3D, the voltage UQ1 at the output 01 is plotted against time. At time t^, a signal appears at output 01 of flip-flop AF1. Because the monostable multivibrator MK and flip-flop SF are in their 1 state at this time, the AND gate UC will send the pulses provided across the output AP to the control device PP, so that the monostable multivibrator MK can be repeatedly triggered until the beginning of the signal interruption. The time t^ also marks the beginning of a further control WP whose duration corresponds to the duration of a preliminary control. This further check has a negative result, and no setting pulses appear at flip-flop SF. This flip-flop is reset by the pulse appearing at the output AN of the control device PP, when half periods or the period control produces a negative result. When the flip-flop SF is reset, the AND gate UC is blocked so that all pulses appearing at the output AP can no longer trigger the monostable multivibrator MK. At the end of the signal interruption, the results of the half-period or period control become positive again. At the instant t^, a further check begins. The result of this additional check is positive, and therefore the flip-flop SF is reset at the moment

The t^,°9pulses appearing at the output AP can trigger the monostable multivibrator MK again until the end of the signal at the moment tj.. From this moment on, the results of the half-period or period controlne become negative again, so that the flip-flop SF is reset and OG -port UC is blocked. The monostable multivibrator MK remains in its 1 state during the intrinsic hold time which is at Tmin. This retention time is chosen so that it corresponds at least to the duration of the longest signal interruption that can be expected and to the duration of a further check as shown in figures 3C, 3D. In keypad systems, Tmin must be between 34 and 37 ms. The first value is determined by the longest

the signal disturbance of 25 ms, for a longest control time of

7 ms, and by a tolerance time for counting before and after the signal interruption, while the other value is determined by a specified silent interval of 33 ms and by a minimum time for a positive pre-check in the lower frequency group of 4 ms.

The shaded parts of the output pulse in Figure 3D indicate the signals in which the trigger pulses for the monostable multivibrator MK occur.

In Figure 2, the upper input on AND port UC can also be connected to the input instead of to the output AP on the control device PP. However, this can lead to an extension of the length of the output pulse. It will also be possible to trigger the monostable multivibrator MK with each positive precheck. However, such a circuit would increase the uncertainty range for the accurate recognition of a silent interval or of a signal interruption by the duration of a precheck. This can be seen in Figure 3C, where the pre-control at time t2 is negative. The monostable multivibrator MK then receives no trigger pulses between the instants t^ and t^. Thus, the intrinsic holding time will necessarily correspond to at least the duration of the longest signal interruption and two further checks.

The monostable multivibrator MK is preferably produced in the form of a digital circuit with a counter, preferably using MOS technology, because the evaluation circuits A1, A2 are constructed as MOS modules.

Claims (8)

1. Switching device for a selective signal receiver where the time intervals between the zero crossings for the alternating voltage input are measured during a measurement period that includes a first number of periods of the alternating voltage input, and in particular for use in telephone systems, characterized in that, after it has been detected that there is a signal that is peculiar to the system, further measurements (WP) are made, each of which covers a considerably smaller number of periods than the first number, but still at least contains a few periods, that depending on the aforementioned detection and of a positive result of the additional measurements, a retriggerable, monostable multivibrator (MK) whose retention time includes at least the duration of the longest signal disturbance and the duration of no more than two additional measurements can be switched to its 1 state and that the multivibrator blocks the evaluation of the detected signal after the retention time has expired. 2. Switching device according to claim 1, characterized in that the multivibrator (MK) can be switched to its 1 state by means of pulses generated at the zero crossings of the alternating voltage input, and that the retention time of the multivibrator at least includes the duration of the longest signal disturbance and the duration of at least one additional measurement. 3. Switching device according to claim 1, and where the signal recognition process in a main control comprises several periods of alternating voltage the input, and where it is determined in a half-period or period check carried out at the same time as the main check whether the AC voltage input can have a signal frequency, characterized in that the multivibrator (MK) can be switched to its 1 state by means of pulses that are generated at the zero crossings of the AC voltage input if during the half-period control or the period control it is determined that the alternating voltage input can have a signal frequency. 4. Switching device according to claims 1-3 where the signal recognition process comprises several periods of the alternating voltage input and is first introduced in a main check when it is found in a preceding pre-check which includes one or a few periods and has a larger bandwidth, that the alternating voltage input can have a signal frequency, characterized in that each of the additional measurements (WP) has a duration corresponding to a preliminary control (VP). 5. Switching device according to one of claims 1-4, where the signal frequencies that are specific to the system consist of a 2nd ( <n> ) two-group code, and where the time intervals between the zero crossings of the alternating voltage input are measured separately in each frequency group during a measurement time which covers a first number of periods of the AC voltage input, the output voltage from a group filter assigned to the respective frequency group serving as the AC voltage input, characterized in that the multivibrator no longer receives trigger pulses to switch to its 1 state when the further measurements or the half-period controls or the period control shows a negative result only in one frequency group. 6. Switching device according to one of claims 1-5, characterized in that while the multivibrator is in its 1 state, detection of the presence of signal frequencies that do not correspond to the already recognized frequency is prevented. 7 i Connecting device according to one of claims 1-6, characterized in that the multivibrator (MK) is manufactured as a "one-shot" circuit using MOS technology. 8. Switching device according to one of claims 2,3,4,6 or 7, characterized in that an OR gate (OB) is connected before the multivibrator (MK), one input of which is supplied with a trigger pulse At the end of the main control if a signal is detected, and if the second input is connected to an AND gate (VC), that pulses generated by the zero crossings of this AND gate, that if the result of the further measurement is positive, a "good" signal is supplied to another input to the AND gate, and that the signal from the Output of the multivibrator is fed to a further input to the AND gate.