DE2726707A1 - Electronic switch for HF receiver - avoids switching noise by rapid switching between two states with variable mark-space ratio switching waveform - Google Patents

Abstract

The electronic switch is switched from one state (7) to the other (9) intermittently with a varying switching ration. Pref. the switching voltage (Us) comprises a binary voltage with fixed levels (H, L). Its frequency may remain constant during the switching interval and this frequency may be about double the upper limit frequency of the signal to be transmitted. The switching ratio may vary linearly over the switching interval or it may initially be longer, becoming shorter in the middle of the switching interval and then becoming longer again. The switch may be used in h.f. receivers to avoid switching noises or to provide a soft transition between two signals.

Description

Electronic switch, especially for interference suppression

Pressing or a dissolve When switching on or off suddenly a tone signal is known to arise due to the steep switching edges in the Sound signal crackling noises. It is known to reduce such clicking noises to use as a switch a transmission element in the signal path of the audio signal, the with a switching voltage with smooth transitions between the switching states is controlled. In the DT-PS 865 477 such a circuit is described, the serves to suppress interference in a high-frequency receiver. The transfer rate the circuit is in each case for the duration of an incident interference signal by a Switching voltage controlled by the interference signal is reduced. The waveform of the switching voltage is deformed or rounded in such a way that the voltage generated by the cut-off voltage Interference voltage remains as small as possible.

The invention is based on the object of providing a universally applicable to create an electronic switch with which a signal can be switched without interference, in particular faded from one signal to another signal without interference can be.

One area of application is e.g. the interference voltage suppression described above.

This object is achieved by the invention specified in claim 1. In the subclaims are advantageous embodiments the Invention specified.

In the case of the invention, a controlled, defined Bouncing of a switch prevents the occurrence of a cracking noise. The controlled one The bouncing process consists in the transition to the new switching state being intermittent takes place with a steadily increasing duty cycle. The bounce frequency is not required to be constant. You must e.g.

be above the audible range for audio signals. In general it is sufficient if the bounce frequency is twice as high according to the known sampling theorem as high as the upper limit frequency of the useful frequency range of the relevant transmission system lies. In order to achieve a very large or small duty cycle, in particular Avoid very short pulses at the beginning and at the end of the switching process it is advisable to reduce the frequency there so far, i.e. to increase the period duration increase as it is with regard to the frequency range of the signal to be transmitted is permissible.

The invention is illustrated below with reference to in the drawing Exemplary embodiments explained. They show: FIG. 1 a symbolically represented electronic switch on which the consideration of the invention is based, FIG. 2 shows the voltage curves in the circuit according to FIG. 1 in the case of an erratic Disconnection of a low-frequency signal, FIG. 3 voltage curves in the event of a through-connection according to the invention, FIG. 4 shows a circuit for cross-fading between two signals, FIG. 5 shows a circuit for suppressing interference, FIG. 6 shows voltage curves in the circuit according to FIG. 5 with a hard switchover and with a soft switchover according to FIG of the invention, Fig. 7 shows a circuit for generating those used in the invention Switching voltage, Fig. 8 voltage curves at different points in the circuit according to Fig. 7 and Fig. 9 shows a particularly advantageous circuit for Generation of the switching voltage.

In Fig. 1, a circuit is shown schematically with an electronic On-off switch 4, which is controlled via an input terminal 3 with a switching voltage U5 can be.

When the switch 4 is closed, a signal connected to an input terminal 1 is activated Transfer input signal U1 to an output terminal 2. The output signal at the Terminal 2 is labeled U2. The output terminal 2 is via a resistor 5 connected to the ground potential of the circuit, so that when the switch is open the Output signal U2 corresponds to the ground potential.

In Fig. 2, the voltage profiles U1, U2 and U are shown.

The signal U1 is a sinusoidal alternating voltage that is generated by a Voltage jump from logic level H to logic level L of the switching voltage U5 is switched off. At the bottom of FIG. 2, the signal U2 has a steep switching edge 6 shown. This switching edge 6 contains interference frequency components that in the case of a NF signals cause cracking noises.

In Fig. 3 is a shutdown of a circuit according to the invention shown. The signal U1 in FIG. 1 corresponds to the first signal and the ground potential the second signal in the invention. By means of the in Fig. 3 in the second line Switching voltage U5 shown, the AC voltage signal U1 is switched. The switching voltage U5 shown has three different ones for a switching process Sub-areas.

In a first sub-area 7, the switching voltage Us has the logical one Level H at which switch 4 is closed. With the beginning of the switchover the switching voltage goes in a sub-area 8 in an alternating voltage with a substantially constant period T over. In the course of sub-area 8 finds a shift in the duty cycle of the AC voltage from a value in which the previous state H (sub-area 7) predominates, to a value at over which the other logical state L predominates. In sub-area 9, the Switching voltage U only has the new logic state L.

The frequency of the switching voltage U5 in sub-area 8 is selected to be greater as the cutoff frequency of the transmission system in which the circuit according to FIG is used. The AC voltage components of the signal present at terminal 2 U2 are outside the transmission frequency range and are suppressed. In order to a voltage curve according to FIG bottom line in Fig. 3 (U21).

The sub-area 8 of the switching voltage U5 can be extended to any length will. The duty cycle of the alternating voltage in sub-area 8 is then corresponding slowly changing. With the switching voltage U5 described, a flowing, trouble-free transition between the alternating voltage U1 and the switch-off state, is at the ground potential at the output terminal 2 in FIG.

It is equipped with a circuit which, as shown in FIG. 4, contains a changeover switch 10, which is controlled according to the switch 4 in Fig. 1, also possible, a establish a smooth transition between two AC voltage signals U11 and U12. This creates an electronic cross-fading device that the otherwise can replace the usual slider. In a circuit not shown in FIG An adjustment option is expediently used to generate the switching voltage Us for the duty cycle change and thus for the length of the sub-area 8 of the in Fig. 3 provide switching voltage U5 shown to more or less rapid fading processes to be able to perform.

Fig. 5 shows an electronic switch with which between a Signal U1 and the mean DC voltage value 21 of the signal U; be switched can. The DC voltage mean value 81 is formed across a capacitor 13, the adf is charged via a resistor 12 from the voltage U1.

In Fig. 6 it is shown how the circuit of FIG Fade out a disturbance 14 in the AC voltage signal U1 can be used. In the Lines 2 and 3 show the masking with a hard switchover. Underneath shows how the interference signal can be faded in and out 15 resp. 16 according to Fi. 3 can be suppressed without interference. The duty cycle of the switching voltage in the fade-in process 16 must be changed in the opposite way, as in the fade-out process 15. Interfering noises of the type shown in FIG. 6 above come e.g. as cracking noises when playing a record. In oppression Choosing the correct length of the fade-out is important for such cracking noises. On the one hand, the fade times must be so long that there is no more cracking noise is perceptible. On the other hand, however, they must not be so long that a signal interruption is already perceptible. So that the fading out process 15 can be started early enough, there must be a delay circuit for the signal U1 can be provided. U2 is delayed compared to U1 by the time between Detection of the disturbance 14 and the reaching of the actual blanking area 9 lies.

In Fig. 7 is a particularly simple circuit for generating the Circuit voltage U5 shown. In Fig. 8 voltage curves are shown, which serve to explain the function of the circuit according to FIG. The circuit in Fig. 7 there is a voltage jump U17 at the input terminal 17 at the output terminal 23 a sequence of square-wave pulses with a steadily increasing or decreasing duty cycle until the output signal finally remains at the new voltage value.

This signal curve corresponds exactly to the required switching voltage Us. The heart of the circuit is an inverting Schmitt trigger 21. It can E.g. the well-known CMOS component 74014 can be used. Between the input terminal 17 and the input of the Schmitt trigger 21 is a series circuit of a first Resistor 18 and a second resistor 20 connected. From the one labeled b Connection point of the second resistor 20 to the input of the Schmitt trigger 21 is a capacitor 22 against ground potential exit of the Schmitt trigger 21 and the connection point of the first and second resistors 18 or 20 is a capacitor 19. The output of the Schmitt trigger 21 is with connected to the output terminal 23 of the circuit. The capacitance value of the capacitor 19 is selected to be significantly larger than the value of the capacitor 22. The capacitor 19 causes that at the connection point a of the resistors 18 and 20 only the AC voltage at the output of the Schmitt trigger 21 is effective.

In contrast, the DC voltage at this point a is derived from the input voltage U17 at input terminal 17 is determined. The Schmitt trigger 21 has a hysteresis afflicted and has an upper response value 25 and a lower response value 24 on. The circuit can only oscillate as long as the one fed back from the output AC voltage sweeps both response values 24 and 25. As soon as the DC voltage this no longer allows this at switching point a, the oscillation stops.

If there is a jump in voltage U17 at input terminal 17 the DC voltage Ua at the circuit point a corresponding to the second line in Fig. 8 after an exponential function. The oscillation begins as soon as that for the first Switching effective response value 25 is reached, and stops again as soon as one of the response values can no longer be reached. The steady rise in DC voltage at the circuit point a has the desired continuous change in the duty cycle of the Output voltage result. The third line in FIG. 8 shows the voltage profile shown at circuit point b.

The determined by the values of the resistor 20 and the capacitor 22 The time constant determines the frequency in the transition area 8 of the switching voltage Us. In contrast, the value given by the resistor 18 and the capacitor 19 is predetermined Time constant decisive for the duration of sub-range 8 of the switching voltage. In the case of a voltage jump opposite to the voltage jump in voltage U17 in FIG. 8 run the same processes in the opposite direction as shown in FIG away. This circuit is for both a fade-out and a fade-in usable.

In the circuit in FIG. 7, the pulse duty factor with which the sub-range 8 begins or ends, cannot simply be made arbitrarily small or large. FIG. 9 shows how this disadvantage is eliminated by an additional measure can be. It is an auxiliary circuit made up of a PNP transistor 31 and an NPN transistor 28 are each provided with a protective diode 30, 29 against excessively high base-emitter reverse voltage.

The collectors of transistors 28 and 31 are connected together and lie at switching point b. In each case in the emitter line of the transistors 31 and 28 are the forward polarized diodes 30 and 29. The emitters remote connection of the diodes is interconnected and connected to a tap 33 of the Resistor 20 connected. The base of the PNP transistor 31 is positive Supply voltage UB and the base of the NPN transistor 28 to the ground potential connected to the circuit. By amplitude values at the output of the Schmitt trigger 21, which exceed or fall below the operating voltage range, one of the Transistors open and thereby the time constant of the RC element from the resistor 20 and the capacitor 22 are reduced in size. This is for the first and last pulses the duty cycle is additionally reduced or increased, because - as from the Voltage Ua can be seen in FIG. 8 - the condition mentioned for these pulses is satisfied. The tap 33 is in the area of the resistor facing the point a 20 carried out adjustable, so that the effect of the additional transistors 31 and 28 can be dosed. Between the input terminal 17 and the resistor 18 is another pulse shaper 26 connected, which is designed as a Schmitt trigger.

For certain applications it could also be disadvantageous that the oscillation process does not occur immediately after the voltage jump in signal U17 (see Fig. 8) begins. In this case, a switch, for example, could help to reduce the resistance 18 bridged until the onset of vibrations.

The following is a dimensioning example for the circuit according to Fig. 9 stated: Resistor 18: 100 kQ Resistor 20: 10 kQ (with tap) plus 82 kQ (fixed) capacitor 19: 15 nF capacitor 22: 150 pF For the specified Values results for the switching voltage U5 in sub-range 8 a frequency of> 20 kHz, a duration of the sub-range 8 of approximately t2 = 2.1 ms and a switching delay compared to U17 of t1 = 1.6 ms. The times t1 and t2 are shown at the bottom of FIG. 8.

Claims (17)

Patent-claiming electronic switch, especially for a Interference suppression or dissolving, characterized in that to achieve a soft switching process (8) the transition from a switching state (7) to the other switching state (9) intermittently with changing duty cycle he follows. 2. Switch according to claim 1, characterized in that the switching voltage (Us) is a binary voltage with the fixed levels II and L. 3. Switch according to claim 1, characterized in that it is used as a changeover switch (10, 11) is designed with two inputs and one output and for cross-fading between two signals (U11, U12; U19 81) at the two inputs (Fig. 4 until 6). 4. Switch according to claim 1, characterized in that it is used as a changeover switch (11) for brief switching from a useful signal (U1) to a substitute signal (in,) is used for interference suppression (Fig. 5, 6). 5. Switch according to claim 1, characterized in that the Duty cycle changes linearly during the switching process (8). 6. Switch according to claim 1, characterized in that the Duty cycle changes non-linearly during the switching process (8). 7. Switch according to claim 6, characterized in that the Duty cycle at the beginning of the switching process (8) initially slowly, then faster and at the end of the switching process (8) changes more slowly again. 8. Switch according to claim 1, characterized in that the speed the change in the duty cycle is adjustable. 9. Switch according to claim 1, characterized in that the frequency (1 / T) of the intermittent switching voltage (Us) during the switching process (8) is constant. 10. Switch according to claim 1, characterized in that the frequency (1 / T) of the switching voltage (U5) is smaller in the range of large or small duty cycle is than in the range of the duty cycle 1: 1. 11. Switch oach claim 1, characterized in that the frequency (1 / T) of the switching voltage (Us) above the usable frequency range of the switch (4, 10, 11) led signal (U1, U11 U12 'U1) lies. 32, switch according to Claim ll, characterized in that the frequency the switching voltage (Us) about twice as high as the upper limit frequency of the zu transmitted signal is. 13. Switch according to claim 1, characterized by a circuit for generating the switching voltage (Us) with the following features: a) The circuit comprises an inverting hysteresis Schmitt trigger (21). b) Before the input of the Schmitt trigger (21) is a series circuit switched from a first (18) and a second (20) resistor. c) Between the connection point (6) of the second resistor (20) with the input of the Schmitt trigger (21) and a fixed potential (ground) of the A first capacitor (22) is connected to the circuit. d) Between the output of the Schmitt trigger (21) and the connection point A second capacitor (19) is connected to the resistors (18, 20). e) The capacitance value for the second capacitor (19) is essential greater than the capacity value of the first Capacitor (22) selected. f) The one facing away from the connection point (a) of the resistors (18, 20) Connection of the first resistor (18) forms the binary controllable for switching Input (17) of the circuit and the output of the Schmitt trigger the switching voltage (Us) output (23) of the circuit. 14. Switch according to claim 13, characterized in that the second Resistor (20) is bridged with an auxiliary circuit (28 to 32) which has a low resistance becomes when the voltage at the junction (a) of the resistors (18, 20) exceeds the voltage range above or below that caused by the voltages at the bases of the two transistors (31, 28) is limited (+ UB and mass) (Fig. 9). 15. Switch according to claim 14, characterized in that the auxiliary circuit (28 to 32) two transistors connected in parallel with their collector-emitter paths (28, 31), the collectors with the input of the Schmitt trigger (b) and the emitters are connected to the connection point (a) of the resistors (18, 20) are that the one transistor (31) is of the PNP type and with its base with the positive supply voltage terminal (32) is connected and that the other transistor (28) is of the NPN type and its base with the negative supply voltage terminal (Ground) is connected (Fig. 9). 16. Switch according to claim 15, characterized in that in the Emitter lines to protect against excessively high base-emitter reverse voltage diodes (30, 29) each lie in the flow direction of the transistor (31 to 28). 17. Switch according to claim 13, characterized in that the second Resistance (20) has a tap (33) and that the connection point (a) the resistors (20, 18) associated connection of the auxiliary circuit with the tap (33) is connected.