DE2058013B2 - Discriminator circuit for signals of differing amplitude excursion - using capacitor discharged and recharged in sympathy - Google Patents

Abstract

The discriminator circuit is used to discriminate between signals with short term amplitude excursions, e.g. speech signals, and signals with long term excursions, e.g. signals of constant amplitude. It comprises an input circuit controlling the discharging and recharging of a capacitor in dependence on the amplitude excursions. The input circuit is coupled via a capacitor with a delay stage, controlling the discharging and recharging of a delay capacitor with a time constant greater or equal to the discriminator time duration. The load state of the delay capacitor is monitored by a threshold stage, the output of which is used for controlling further circuit means.

Description

Capacitively coupled via a capacitor, the discharging and recharging of a switch-off delay capacitor controlling delaying discharge stage such that the charging time constant of the switch-off delay capacitor is the same or is greater than the discrimination period, as well as by an on the state of charge of the delay capacitor appealing threshold switch stage «: at the output of which a for the to be distinguished Signal types characteristically different output signal for controlling downstream Units occurs, resolved.

According to appropriate refinements, it can be provided that the input discharge stage and the to this capacitively coupled delaying discharge stage one for each mode of operation in θ mode biased transistor of a first conductivity type and the threshold switch stage one for this purpose having complementary transistor, being adapted to the distinction between Speech and other signals have a critical fluctuation period of about 300 msec can that the charging time constant of the delay capacitor is at least 1.5 times the charging time constant of the discharge capacitor of the input stage or of the coupling capacitor between the first and second stage and that the charging time constant of the coupling capacitor between the first and the second stage at least twice as large as that of the first discharge capacitor is.

The circuit according to the invention is ultimately based on the distinction between signals with relative short-term amplitude fluctuations and those with (relatively) constant amplitude; the invention is therefore not to the special case of the distinction between speech signals on the one hand and signals limited with (continuous or interrupted) signals with constant amplitude on the other hand, as will be explained in more detail below.

In the following, exemplary embodiments of a discriminator circuit according to the invention are used for differentiation between speech signals on the one hand and any, interrupted or uninterrupted Signals of constant amplitude on the other hand described with reference to the drawing; in this shows

F i g. 1 is a circuit diagram of a discriminator circuit according to the invention in a transistorized design,

F i g. 2 different waveform representations («) to (d), which are differentiated by the circuit according to the invention,

F i g. 3 is a circuit diagram of a detail of a modified embodiment of the circuit of FIG Fig. 1.

The in F i g. 1 is connected to a supply voltage source with the terminals + Un and Minus. The circuit consists of an input rectification and discharge stage I, a delaying discharge stage II and a threshold switch stage III. Stage I has in the illustrated embodiment, an NPN transistor Tr 1 in the emitter circuit, which is by a base voltage divider with resistors R ₁ and R., in Ruheizustand (that is, without application of an input signal at the circuit input E) into the blocking state vorgesnannt. The collector of the transistor Tr 1 is connected to the supply voltage terminal 4- Uh via a collector load resistor R-λ ; In addition, the collector of Tr 1 is capacitively coupled to the base of the transistor Tr 2 of stage II via a discharge capacitor C: i. The emitter-collector path of the transistor Tr 1 is bridged by a capacitor Co.

In the exemplary embodiment shown, the delaying discharge stage II has an npn transistor Tr 2, the base of which is on the one hand via the mentioned coupling capacitor C _; is connected to the collector of the transistor Tr 1 and on the other hand via a base resistor R _t to the negative supply voltage terminal. In the idle state, the base of the emitter-connected transistor Tr 2 is at the (negative) emitter potential, so that the transistor Tr 2 is also blocked in the idle state. The collector of the transistor Tr 2 is connected to the positive supply voltage Un ' via a series connection of a resistor R _n and a variable resistor R-, these two collector resistors R ₁ -, and Rr, serve at the same time as a voltage divider for the adjustable bias of the base of the transistor Tr 3 of threshold level III. The collector-emitter path of the transistor Tr 2 is bridged by a delay _{capacitor C (.}

The threshold switch stage III has a switch that is complementary to the transistors Tr 1 and Tr 2, i.e. a pnp transistor Tr 3 in the exemplary embodiment shown, the base of which in the idle state (via the variable resistor R-) is at emitter potential (in this case the positive Voltage potential + Un) and is therefore also biased into the blocking state in the idle state. The collector of the transistor Tr 3 is connected to the negative supply voltage via a load resistor R _1. At the collector of the transistor Tr 3, the output signal of the discriminator circuit according to the invention is picked up at A , which - if necessary via a coupling capacitor C - is fed to the unit Z to be switched, which is shown in FIG. 1 is only indicated as a switching block and, for example, a timer, a relay driver stage or the like. Can be.

The circuit receives an input signal at the input E via a coupling capacitor C _{1 as shown in FIG.} 2 at (β) to (d) indicated waveform. The waveform (c) therein represents an oscillation sequence of constant amplitude interrupted by a pause ar of, for example, 300 to 400 msec, such that a short pulse a _K of, for example, about 100 msec duration and a long pulse α /, for example of about 500 msec arise; the sequence "short pulse - pause - long pulse" can of course be repeated. This waveform corresponds, for example, to the dial tone of the public telephone network in Germany; waveform (b) in Fig. 2 illustrates a continuous waveform of constant amplitude such as may correspond to the USA telephone network seizure signal or a ringing signal in selective calling systems. At (c) in Fig. 2, the case is shown that no signal or a direct current signal is applied. The waveform (c /) in Fig. 2 corresponds to a speech signal; it shows the characteristic structure of an irregularly varying beat signal, where-

at the individual Schwcbungen a particular stood Ji _Λ and R \ the desired Zeitverhaltcn de

Duration, for example about 300 msec, not adapted to over-switching.

increase, that is, the speech signal in normal Fig. 3 shows a circuit detail of an aban

Speech at no time has a constant amplitude execution, which in the circuit of Fig.

tude over a period of, for example, more than 5 between points (a) and (b) in place of de

300 msec. This characteristic structure resistance R , used to think is to di

the human language or the discriminator circuit generated by it in their response behavior

Speech signal is controlled in the switching according to the invention by means of direct current, that is to say tactile zi

to distinguish between doing a language. In principle it is intended for this purpose

signal according to the waveform (rf) and any other in place of the resistance A _{1 of} the base voltage part

ren signal forms or lack of a signal (Zu- lersÄ ,, R., for the transistor Tr 1 in Fig

stands [o] to [c] in Fig. 2) are used. to set controllable switch. According to Fig. 3 came

In the following, the mode of operation of the switch - for this purpose the collector-emitter path of a Transi

Explained from Fig. 1: stors7> 4 are used whose conductivity

It is initially assumed that the circuit 15 or the blocking state by a corresponding direct current at the input E is a signal of a predetermined minimum control of the base of the transistor Tr 4 controllable least size and with a F i g. 2 a or 2 b is equivalent. The transistor Tr 4 is fed to the transistor Tr 1 corresponding waveform. Due to the complementary input signal (or its positive half-wave) described in the embodiment example, a pnp transistor plays; in series with dei, the collector-emitter path of Tr 4, which is biased into the blocking state at rest, has a collector transistor Tr 1 conducting; via the conductive collector resistance R »\ between the collector and the base! Emitter path discharges the capacitor C ₂ , which has a resistor R ,, in such a way that in the quiescent state, the discharge of the capacitor C, in the coupling means without applying a key signal to the keying capacitor Ch, produces a pulse-shaped shift S, the base is at collector potential and the training current of opposite polarity. This is 25 transistor Tr 4 is therefore conductive, which the operator controls the transistor Tr 2 in the conductive readiness of the overall circuit of Fig. I to the state; this also corresponds to the capacitor Ci function in the manner described above across the collector-emitter path of Tr 1 . By supplying a suitable equal charge; thereby at the same time the threshold current control signal at the control input S via a transistor Tr 3 in the conductive state throughput 30 base resistance R _w to the base of Tr 4 can diegeschaltet and the resistor A ₇ and therefore at the ser locked and thus the overall circuit of A constant voltage occurs at output A. If FIG. 1 remains in the non-responsive state, the input signal is now sampled with a constant amplitude. Of course, the arrangement can be made for a certain minimum time (for example, the other way around, so that the 300 msec) is applied, so the transistor Tr 1 35 transistor Tr 4 remains in the idle state, i.e. without guidance, the capacitor C ₂ remains connected to the voltage a key signal at the control input S, blocked minimum, the capacitor C: i., and the total circuit of Figure I therefore does not discharge its part, whereby at the base of the transistor Tr 2 is operative, and sets only by supplying an initial potential, and this DC control signal at the input S of the Tran transistor Tr 2 goes into the blocking state. The 4 "sistoi Tr 4 conductive, and therefore, the overall circuit capacitor Cj is, via the resistors Rr - Rr, is keyed of FIG I in the conducting mode, charged, the transistor Tr 3 thereby blocked and the invention has been described with reference to a the. Output voltage at A drops towards zero. special embodiment described that the

If, however, the signal supplied at input E distinguishes between speech signals in (rf) a speech signal of the type of waveform (rf) shown in FIG. 2 from any other signals in FIG. 2, transistor Tr 1 is allowed in time ; only in the case of the waveform (rf) in Fig. 2 "beat", that is, the envelope curve of the speech occurs at output A a constant output signal, constantly reversed; accordingly lay on. while in the case of signals (a) or (b) in fert, the capacitor C3 is also in the speech rhythm F i g. 2 at most switch-on pulses, but otherwise voltage pulses to the base of the transistor Tr 2; 50 the output signal zero occurs; the same is true by a suitable design of the resistance - of course also for the case (c) in FIG. 2, would be R _T , and R _a and the capacitor C _A - that is, the absence of an input signal. For the connected /? C element, its time constant, the mode of action described in this way, can be counter-selected so that the capacitor C ₁ , which is located during the side ratio of the capacitors C ₁ , C _s and Cj of the conduction state of Tr 2 via its collector 55 essential; for the case described, "the sub-port-emitter path discharges, within the range of speech signals versus signals, the speech signal (for example, a maximum (or absence of signals) of a different type) should not be charged as briefly as the time constant for the capacitor C _{4 it} can be that the transistor Tr 3 would be switched to the blocking state equal to or greater than 1.5 times the time constant; the transistor Tr 3 therefore remains at 60 for the capacitors C ₃ or Cf; a signal is also applied with a fluctuating amplitude, the time constant for the capacitor C ₃ should be conductive and or greater than twice the time constant of the output voltage of the circuit in the capacitor C, in the same way as the speech signal (d) in FIG.

Point A constant. From the description of the mode of operation, in order to prevent that the circuit does not switch to the differentiation of transistors Tr 2 and of speech signals compared to signals of another type Tr 3 in the blocking state during pauses in speech of 65 times, the charging is limited. In general, the invention time _{constant of the capacitor C: i} enables a distinction to be made via the corresponding discriminator circuit

between signals with relatively brief amplitude fluctuations and signals with amplitudes that fluctuate only over longer times, and in particular with constant amplitude (being used in the case of distinguishing between speech and other Signals a critical value of about 300 msec as a criterion for the amplitude fluctuation or constancy has proven to be appropriate).

By suitably linking several elementary circuits according to the invention according to FIG. other application possibilities can be realized. For example, multiple, for Critical differentiation times designed differently from one another, elementary circuits according to FIG. 1 connected in parallel to a common input, which is a signal component input signal containing different lengths is supplied. Through suitable logical links of the outputs of the individual

According to elementary circuits, a discrimination can be made between the various components of the input signal with regard to their amplitude constancy duration achieve.

Circuit details of the exemplary embodiment described are of course not of restrictive importance. For example, transistors of the opposite conductivity type can be used with appropriate polarity reversal, instead of the use shown in emitter circuit, the transistors can also be used in a different switching configuration with appropriate adaptation. The bias of the transistors Tr 1 and Tr 2 in ß-operation is preferable for the simplicity and reliability of the mode of operation, but not essential. With regard to the type of downstream devices to be actuated by the circuit according to the invention, there is, as already mentioned, a wide variety.

1 sheet of drawings 609538 / i

Claims (5)

For the control of devices or machines it is patent claims: known and customary, an electrical signal of constant amplitude, for example an LF signal constant 1. Discriminator circuit to differentiate the amplitude, via a threshold amplifier between signals with short-term, below 5 or a trigger circuit and to use the resulting output function to trigger amplitude fluctuations, in particular of the desired processes.
Speech signals, and signals with long-term. In certain cases, the control of amateurs or machines or processes held over the discrimination period is selectively characterized by fluctuations in amplitude, in particular signals io desired or required with constant amplitude. In the case of a telephone network, for example, an answering machine with voice-controlled charging of a capacitor (C) is used to maintain the level of amplitude fluctuations in the device in the recording state as a function of the input signal (Fig. 2a to 2d) - 15 of the human language of the incoming, Aufgangsentiadestufe (I, Fig. 1), a conversation to be drawn with this only as long as a voice is _{capacitively coupled via a capacitor (C: 1} ), the device in the recording panel should discharge and recharge a state to be kept; If there are no voice signals controlling the switch-off delay capacitor (Ci), the device should (expediently after a delaying discharge stage (II, Fig. 1) of such a short delay to take account of the interpretation that the charging time constant of the natural speech pauses) into a switch-on delay capacitor (C ₄ ) Switch on the same or ren test state, for example in greater than the discrimination time period, as well as the transmission of a final rejection and / or the (and by means of a final shutdown based on the charge state of the delay). Rungskondensators (C ₄ ) responsive threshold 25 language switching organs, which speak on the human value switch stage (III, F i g. 1), at the output Sprichc corresponding electrical signals (A) for the types of signals to be distinguished and, depending on them, certain characteristically different output signals for triggering control functions are known per se. To control downstream units (Z) occurs. Differentiation or isolation from other 2. Discriminator circuit according to claim 1, 30 wide (interfering) signals, it is characterized, for example, that the input recognizes, narrow the voice frequency range or charge stage (I) and filter out the capacitively connected frequencies to the pelelled delaying discharge stage (fl) to bring about a desired control function in each case. These known circuits, which are biased to work in ß-mode, are consistently afflicted with the secondary transistor (Tr 1, Tr 2) of a first conductive part, that the separation of the interference frequencies keittyps and the threshold switch stage one of the useful frequencies only with a relative complementary Transistor (Tr 3) is possible and that, apart from that, only one for the given conditions 3. Discriminator circuit according to claim 1 condition is met. If a frequency-wise or 2, characterized in that the charging separation between the interference signals and the speech time constant of the delay capacitor (C 1) signals is not possible, these known at least 1.5 times the charging time constant circuits fundamentally fail. If, for example, from the discharge capacitor (C ₁ ) of the input stage to the public network in the audio frequency range or the coupling capacitor (Ci) between public tones (dial tone, busy tone or the like) in the first and second stage. 45 the device to be controlled in addition to the voice signals 4. A circuit according to one or more of the can occur or, for example, tone signals with the preceding claims, characterized by graduated frequencies in a selective call system, characterized in that the charging time constant of the coupling and if the separation of this particular Frelungskondensators (Ci) between the first and quenzen or .Frequency ranges for technical reasons or the second stage are at least twice as large as 5u is not possible for cost reasons, then disturbances are those of the first discharge capacitor (C ₂ ). the voice-controlled functions are inevitable. 5. Discriminator circuit according to one or the present invention, the task is for several of the preceding claims 2 reasons to create a discriminator circuit, to 4, characterized in that the basic, the simplest structure and reliable Wirspannungsteiler for the bias of the Tran- 55 way a not on frequency separation besistors (Tr 1) of the input discharge stage has a direct current test signal controllable by static, therefore fundamentally frequency-independent, conductivity differentiation between signals with short-term, keitsweg (Tr 4). amplitude fluctuations lying below a predetermined discrimination time period, in particular 60 voice signals on the one hand and signals with longer The invention relates to a discriminator circuit that is timed and longer than the discrimination period to differentiate between signals with short-term amplitude fluctuations on the other hand reliable gen, below a given discriminatory level guaranteed. Duration of amplitude fluctuations, ins- This object is achieved according to the invention by a special speech signals, and signals with long discharge and recharge of a condensation time, sator lying above the discrimination period as a function of the amplitude fluctuations amplitude fluctuations, in particular signals kungcn of the input signal (Fig. 2a to 2d) with constant amplitude. controlling unloading stage, one with this one