DE2603634A1 - Signal converter for DC and AC signals - has control circuit and at least one secondary circuit separated by optical coupler - Google Patents

Abstract

The signal converter for d.c. and a.c. signals includes a control circuit and at least one secondary circuit separated by an optical coupler. A dynamically active signal evaluating circuit is provided in the control circuit, connected to the two signal wires. It contains a light emitting diode in the optical coupler, and the secondary circuit contains a phototransistor operating as a switch. It is connected to a supply current corresponding to the required signal type, and to a load resistor. The circuit can be extended by a fourth resistor (R4) in series with the control circuits and a diode (D1) in parallel with the 1.e.d. (LD). A npn transistor (T1) is coupled to the phototransistor (FT1).

Description

Signal converter with otoelectronic coupling element.

The invention relates to a signal converter for direct and alternating current signals with a control circuit and at least one, through an optoelectronic coupling element (Optocoupler) connected, but potentially separated secondary circuit for control a load resistance.

When signals are transmitted over a signal path, as Result of swing in and swing out processes when changing signals Distortion. These distortions affect DC pulses in such a way that they are on their leading and trailing edges be flattened if they are transmitted over longer signal wires. Dependent on on the cable length, mainly due to the signal wire resistance and the signal wire impedance, can therefore be used in a signal recording circuit with a static threshold switch Signal distortion occurs. These distortions are undesirable because they are, for example can lead to dialing errors in the case of dialing pulses in a voter control; at a The transmission is already distorted by the single-key circuit Signals caused over the route.

AC signals, which are generally used as signals of a telephone channel Selection circles must go through due to the settling and decay times the relevant filter also has flattened leading and trailing edges. The pitch of the plank depends on the bandwidth of the band filter and is also different Signal level subject to very strong fluctuations.

To get distorted at the end of a transmission link from the received Signal to recover the original form of the transmitted signal are different Circuit arrangements for signal equalization in use. For example the use of a control amplifier to equalize AC signals subsequent rectification and signal evaluation using a static threshold switch an amplifier with subsequent rectification can also be used be combined with a signal evaluation by a dynamic threshold switch he follows.

With the equalization of the signals, conversion into another type of signal, for example from direct current to alternating current signals or be connected in reverse.

The use of amplifiers is possible for this implementation, these Implementation can also involve the separation of the potentials of the two signal circuits get connected. In addition to the possibility of control, there is also the possibility of electrical isolation a relay via a DC amplifier through the equalized and filtered signal The use of a blocking oscillator circuit is also possible, which is triggered by the received Character is stimulated.

It is also already known to use an optocoupler for potential separation to use, which consists of a light emitting diode and a phototransistor.

The object of the invention is therefore to provide a signal converter of the type mentioned to create the signal with as little effort as possible Equalization of alternating and direct current signals is made possible and in terms of potential from one another contains separate control and secondary circuits and also the implementation of Signals into another signal type allowed.

According to the invention the object is achieved in that in the control circuit a dynamically effective signal evaluation circuit connected to the two signal wires is provided, which contains the light emitting diode of the optocoupler and that the secondary circuit contains the phototransistor of the optocoupler operated as a switch, which is connected to a source for the supply current corresponding to the desired signal type and with is connected to a load resistor.

The main advantage of the signal converter according to the invention is that that by including the light emitting diode in the signal evaluation circuit the effort is reduced and at the same time, due to the elimination of relays and transformers higher signal frequency is possible An embodiment preferred because of the low complexity of the signal converter according to the invention results from the fact that the dynamic effective Signal pattern circuit a series circuit connected to the two signal wires from the light-emitting diode polarized for the signals in the forward direction and one through contains a first resistor bridged first capacitor and that to this Rethenschaltung a second resistor is connected in parallel.

With regard to the comparatively low blocking voltages of the in Qptokouplern used light-emitting diodes, it is appropriate that the light-emitting diode oppositely polarized protective diode is connected in parallel and / or the signal converter a protective resistor for the light emitting diode is connected upstream.

A further development of the signal converter according to the invention is thereby characterized in that for the transmission of alternating current signals the dynamically effective Signal evaluation circuit connected upstream via a second capacitor - an amplifier is that the light-emitting diode for the when the amplifier is switched on Charging current of the second capacitor is polarized in the reverse direction.

With this signal converter it is also possible by choice of the supply current to determine the type of signal in the secondary circuit. To implement change In direct current £ .ignale it is useful when connected to the output of the phototransistor or a follower transistor, an additional filter capacitor is connected.

The simple optical coupling of several photo transistors to one Light-emitting diode allows the creation of signal converters with several secondary circuits, which are potentially separated from each other. A corresponding signal converter according to the invention is characterized in that a first, equal current fed Secondary circuit and a second secondary circuit are provided, both of which are connected to the anste-aerkreis are optically coupled, but isolated from this and from each other in terms of potential and that the second circuit is a direct current superimposed by an alternating current is fed.

A signal converter according to the invention can also be created in an analogous manner in which several control circuits are coupled with a secondary circuit.

The invention is intended below with reference to the illustrated in the drawing Embodiments are explained in more detail.

1 shows the basic principle of the signal converter according to the invention, FIG. 2 shows a signal converter for direct current signals and FIG. 3 shows a signal converter for the conversion of alternating current into direct current signals according to the invention.

The signal converter circuit shown in Fig. 1 includes a Series connection of the light emitting diode 1) 1) 1 and the capacitor 01, to which the resistor R1 is connected in parallel. This series connection is with the two signal wires a and b are connected, and these signal wires are directly connected to the resistor R2 linked together so that an equalizing Control circuit arises. The secondary circuit of the signal converter contains the optically connected to the light emitting diode LD1 coupled phototransistor FT, its collector connection directly and its emitter connection connected to the outputs c, d of the secondary circuit via a load resistor R3 is.

A supply current source A is connected to these outputs, which a supply current corresponding to the desired signal type in the secondary circuit to the Photo transistor FT conducts. The phototransistor FT and the light-emitting diode LD1 are components of the optocoupler OK1.

The operation of the circuit for, for example, one on the signal wire an incoming direct current signal is briefly explained below. With the beginning of this symbol, a current flows from the signal wire a into the control circuit, wherein as a result of the discharged capacitor C1, the current initially essentially decreases Represents the charging current for this capacitor, which flows through the light-emitting diode LD1. At the same time, the light emitting diode through which the phototransistor begins to emit light FT is switched on. In the further course of the current, the charging current of the capacitor is C1 lower, the light-emitting diode remains due to the current flow through resistor R1 but in the emission state. Only at the end of the sign roof, i.e. when it is reduced the signal amplitude, provided that the capacitor C1 is sufficient is charged, the flow of current through the light-emitting diode and thereby the Photo transistor switched off. The signal change in the kissing circuit takes place with it almost instantaneous even with different steep character edges at the circuit input and thus distortion-free.

FIG. 2 shows the circuit according to FIG. 1, supplemented by one in series with the control circuit lying fourth resistor R4, one to the light emitting diode LD1 first diode D1 connected in parallel and a first diode D1 connected to phototransistor FT1 connected first npn transistor Tl. The fourth resistor R4 represents only a protective resistor for the light-emitting diode that is necessary in practical operation The first diode D1, which is polarized opposite to the light-emitting diode Lii, is used to protect the light-emitting diode from exceeding the permissible reverse voltage, which is set at Light emitting diodes is comparatively low.

The interconnection of the first npn transistor T1 and the phototransistor FTl is done in the manner of a Darlington pair to increase the gain in Secondary circuit. The mode of operation of the circuit arrangement according to FIG. 2 corresponds 1, as a feed current for the secondary circuit, in addition to a direct current a direct current superimposed with an alternating component can also be used.

Fig. 3 shows the application of the signal converter circuit according to Fig. 1 in a signal converter for real current signals. For this purpose, the control circuit of the signal converter according to FIG. 1, an amplifier V is connected upstream of the above the signal wire a and b æ led input signals E after sufficient amplification via the capacitor 013 to the control circuit. The control circuit exists from the light emitting diode LD11, the capacitor Cii and the resistors R11 and R12.

The LED Lnl? acts as a half-wave rectifier in this circuit, which generates a charging current for the capacitor C11 from the input signal E. will. Depending on the state of charge of the capacitor C11, the result is a dynamic one Threshold S, which is only from the, for example, positive peaks of the input signal E is overcome. Corresponding to these peaks, current surges result from the Light-emitting diode LD1i, which acts as flashes of light to the phototransistor FT11 of the secondary circuit be transferred

In the secondary circuit connected to a high voltage should DC signals are output in accordance with the incoming AC signals. For this purpose, an amplifier circuit is connected to the Fix11 phototransistor. The collector connection of the photo transistor Fit, 1 is directly connected to the base connection an npn transistor Til and a resistor R13 with the Connection for the positive operating voltage connected. The emitter connection of the npn transistor T11 is direct and across to the base of another npn transistor 212 a resistor R5 mi.t the emitter terminal of the Pototransistor FTli and via the Load resistor connected to the connection O for the negative operating voltage.

The collector connection of the npn transistor 211 is directly connected to the base connection a third npn transistor 213 and also via a parallel circuit of a Resistor R14 and a capacitor C12 with terminal d for the positive operating voltage tied together. The emitter connection of the transistor Tl2 is connected to the load resistor connected to terminal c for the negative operating voltage, while the collector terminal this transistor with the base connection of the transistor T13 and with the collector connection of a transistor X14 of the PNP type is connected.

The emitter connection of this transistor is nit the connection d for connected to the positive operating voltage, while the base terminal of this transistor is connected to the collector terminal of the transistor T13. The emitter connection this transistor is connected to the base terminal via a forward-biased diode D12 of a high voltage transistor T15 of the npn type connected, the collector terminal of which with the connection d for the positive operating voltage and with the cathode connection a Zener diode D 17 is connected, while the emitter terminal of the transistor T15 with the anode connection of the Zener diode D73 and with the load resistor Rel is connected to the terminal c for the negative operating voltage.

One of the transistors Til and T12 is connected to the phototransistor PU11 existing Darlington pair connected.

The output of the Darlington pair is on the one hand via a filter element connected to ground, on the other hand to the control connection of one of the two Ro chepannunge transistors v15 and T14 formed thyristor circuit. From the thyristor circuit the high-saving transistor 15 is controlled via the diode D12. The one when switching off voltage peaks occurring at transistor T15 are avoided by of the Zener diode D13 according to the collector-emitter reverse voltage permissible for the transistors limited. A relay Rel was used as the load resistance in the exemplary embodiment, that is connected between the secondary circuit and the negative operating voltage source is. The circuit arrangement described has the properties of a normally open contact. For the implementation of a normally closed contact, the circuit arrangement can be equipped with additional Insertion of a further amplifier stage or by eliminating the transistor Til be realized.

The signal converters described are particularly suitable for transmission of dialing characters with the least possible distortion of the character length, 8 claims 3 figures Blank page

Claims (8)

P a t e n t a n s p r ü c h e, 1. Signal converter for DC and AC signals with a control circuit and at least one through an optocoupler connected but potentially separated secondary circuit for controlling a load resistor, d a d u r c h g-e k e n n n z e i c h n e t that in the control circuit one with the two Dynamically effective signal evaluation circuit connected to the signal wires is provided, which contains the light emitting diode of the optocoupler and that the secondary circuit is used as a switch contains operated potentiometer of the optocoupler, which is connected to a source for the, The supply current corresponding to the desired signal type and a load resistor are connected is. 2. Signal converter according to claim 1 d a d u r c h g e -k e n n z e i c h n e t that the dynamically effective signal evaluation circuit one with the the two signal cores connected in series from the series connection for the signals in polarized light-emitting diode (LD3 and one bridged by a first Wtderstand (R1) first capacitor (C1) and that a second resistor to this series circuit tR2) is connected in parallel. 3. Signal converter according to claim 2, d a d u r c h g e -k e n nz e i c h ne t that the Leuchtdicde (ND) is an oppositely polarized protective diode (D1) is connected in parallel and / or a protective resistor for the signal converter the light emitting diode is connected upstream. 4, signal converter according to claim 2, d a d u r c h g e -k e n n z e i c h n e t that for the transmission of alternating current signals the dynamically effective Signal cutoff via a second capacitor (C13) is preceded by an amplifier (v) is that the light emitting diode (LD) for the occurring when switching on the amplifier Charging current of the second capacitor (C13) is polarized in the reverse direction. 5. Signalamsctzer according to claim Q, d a d u r c h g e ° k e n n z e i c h n e t that for converting alternating to direct current signals at the output of the phototransistor (FT) or the following transistor (part) an additional filter capacitor (g12) connected. 6. Signal converter according to claim 1, d a d u r c h g e -1 e n n z e i c h n zu e t that a first DC-fed secondary circuit and a A second secondary circuit is provided5, both of which are optically coupled to the control circuit are, but are potentially separated from this and from each other and that the second Circuit is fed by a direct current superimposed by an alternating current. 7. Sip; nalumetzer according to claim 4, d a d u r c h g e -k e n n z e i c h n e t that for controlling a relay provided as a load resistor (Rel) with high control voltages to the collector connection of the photo-transistor (FT11) from npn-type the base connection of a first npn transistor (T11) and also via a third resistor (R13) connected to terminal d for the positive operating voltage is that the emitter connection of the phototransistor (FT11) via the load resistor (Rel) is connected to the terminal c for the negative operating voltage that the emitter terminal of the first npn transistor (with the base connection of a second npn transistor (T12) and a fifth resistor (R5) with the emitter connection of the second npn transistor (212) and with the I.astviderstand (Rel) -qerbunden that the Collector connection of the first transistor rm11) to the collector connection of the second Transistor (T12) and a fourth transistor (T14) of the pnp type and with the Base connection of a third transistor (T13) of the npn type and via a parallel circuit from a third capacitor (C12) and a fourth resistor (R14) to the terminal d is connected for the positive operating voltage that the emitter connection z-; es fourth transistor (T14) to the collector connection of a fifth transistor (T15) of the npn type, with the cathode connection a zener diode (D13) and connected to terminal d for the positive operating voltage is that the base terminal of the transistor (T14) connected to the collector terminal of the transistor (T13) is that the emitter terminal of the transistor (T13) has a forward direction polarized diode (D12) connected to the base terminal of the fifth transistor (T15) and that the emitter connection of this transistor is connected to the anode connection of the Zener diode (dz3) and is connected to the load resistance (Rel). 8. Signal converter according to claims 1 and 5, d a d u r c h g e k It is noted that the phototransistor is followed by another transistor Kind of a Darlington formwork is connected.