DE2738423C2 - - Google Patents

Description

The invention relates to a circuit arrangement for an opto electronic remote control according to the preamble of the claim 1 or 2.

Such a circuit arrangement is from "Grundig Technical Information ", 1976, H. 1/2, pp. 689-702.

The operating state of television receivers with optoelectronic remote control (IR remote control) must not be from Noise can be affected. In particular, it must be prevented that the television receiver is switched on or off by the noise becomes or during operation from a receiving channel to other switches.

Therefore, in a circuit arrangement for amplitude control for IR remote control, great security against incorrect switching required.

From "Funkschau" 1976, Issue 8, pages 303 to 304, is a Known receiver for an optoelectronic remote control a photodiode, an integrated amplifier with input resonant circuit, a Schmitt trigger circuit, a decoder and a digital analog converter or a device for Channel selection. From "Der Elektormeister + Deutsches Elektrohandwerk" 1976, Issue 21, pages 1406 to 1407, is a receiving part known for an optoelectronic remote control with a Photodiode, a downstream selective circuit for ver prevention of transmission interference, with two integrated Operational amplifiers, the degrees of amplification because of Negative feedback networks have a bandpass characteristic, with a further amplifier stage with a downstream dmodulator and impedance converter. Two more, than monostable multivibrator interconnected transistors for Further processing in the decoder required pulse shaping. Neither of these two known receiving parts can be dependent one of the current signal-to-noise ratio  each have optimal sensitivity.

From "Internationale Elektronische Rundschau", 1966, Issue 12, Pages 681 to 687, a receiving amplifier is known in which a steep increase in momentum is to be achieved. To this end a way for negative feedback is provided. There is no two ways for the control path with different limits frequencies. There is no question of optimal sensitivity depending on the respective signal / noise ratio. There are none in this known receiving amplifier optimal gain and no optimal threshold depending on depending on the respective signal / noise ratio.

From the "Grundig Technical Information" already mentioned at the beginning, 1976, number 1/2, pages 689 to 702, a circuit arrangement for an optoelectronic remote control of the type mentioned at the beginning is known. In this known receiver module, the controller (k) sets a signal amplitude of 2 V _ss . Even with this known receiver module, the gain factor is not controlled as a function of the current signal / noise ratio. With this known receiver module, too, there is only one path in the control path for the gain factor. And this one way has nothing to do with an optimal sensitivity depending on the respective signal-to-noise ratio. In this known receiver module, noise should rather be suppressed by inserting a filter disk. In this known receiver module there is no optimal amplification and no optimal threshold value depending on the current signal / noise ratio. In this known receiver module, the output amplitude of this control amplifier is kept constant by the control itself with the aid of a control amplifier. Above all, this is to prevent the remote control command from being incorrectly evaluated in the case of input signals with a large amplitude due to overdriving. In addition, even if there is no input signal or no remote control command, it is necessary to prevent the Regelver from being regulated more strongly to such large output signals that the noise causes switching errors. It should also be noted that, in contrast to remote controls with radio waves or sound, strong fluctuations occur with optoelectronic remote controls depending on the ambient temperature. The known receiver module has the following disadvantages: if the useful signal evaluation is correct, the output level of the control amplifier is already defined with respect to the threshold value of the threshold value detector. If the gain is too high when there is no useful signal, the security against incorrect circuits is only low. A doubling of the gain means an increase in the probability of error by several orders of magnitude. On the other hand, too little amplification leads to a loss of sensitivity. In addition, z. B. a halving of the gain compared to the optimal gain that the area of the photodiodes provided at the television receiver for receiving the remote control command must be quadrupled.

From DE-OS 20 01 747 is an input circuit for Störspan voltage suppression known, in which the input signal over an amplifier connected as an integrator to an elec tronic control is given.

From DE-PS 11 49 440 and from "Siemens-Zeitschrift" 1960, issue 10, Pages 578 to 581 is a three-point controller for acquisition and regulation of the control error mean value with minimal Switching frequency known. If a controlled variable is temporary Deviations shows that ver after a short time again disappear (statistical fluctuations), these deviations not corrected. The scheme is based on an average value of the controlled variable. A featured here The control loop has an integrating amplifier and one only way of negative feedback in the sense of a feedback of the Integrating amplifier in its zero position on the input of this Integrating amplifier. In this way, temporary leads not to respond as long as the given time not taking into account the sign  is taken.

In no known circuit arrangement for an optoelectronic Remote control there are two ways for the control path with different cut-off frequencies. None of the known scarf Arrangements for an optoelectronic remote control has an optimal sensitivity depending on the respective signal / noise ratio.

The object of the invention is to provide a circuit arrangement according to the To create the preamble of claim 1 or claim 2, at which each an optimal sensitivity of the circuit order is achieved in that on the one hand the reinforcement is not too large in the absence of a useful signal and on the other hand there is no loss of sensitivity.

This task is accomplished by a circuit arrangement according to the Claim 1 and claim 2 solved.

The invention is dependent on the current Signal / noise ratio an optimal value for the amplifier factor or for the reference value of the threshold switching achieved.

In the invention, a combined signal at the output of the Amplifier divided into two ways. The noise is there compensated more than the useful signal. The noise is said to be strong be suppressed. The useful signal should not overdrive allowed to.  

In the invention, therefore, the disturbance variable of the control loop processed two different ways. One way speaks the noise. It has a low cutoff frequency and one large transmission factor. The other way speaks primarily to the useful signal. The cutoff frequency of this path is higher while the transmission factor is lower.

The second solution replaces information processing in the control loop the threshold or reference value controlled by the threshold detector.

In a development of the invention it is provided that both Paths are combined in a filter.

This results in a simple structure that is particularly suitable for use in tegration is suitable.

Another development of the invention is that for the cut-off frequency f _{g1 of} the channel with the smaller transmission factor:

with t _M = width of a pulse of the modulation signal or of the pre-pulse provided for control.

Finally, it is also advantageous that the following applies to the limit frequency f _{g2 of} the channel with the large transmission factor:

with t _M = width of a pulse of the modulation signal or of the pre-pulse provided for control.

In addition to information processing in the control loop, too the threshold of the threshold detector can be controlled.

The invention is based on the drawing he he purifies. Show it:

Fig. 1 shows a first embodiment of the invention, and

Fig. 2 shows a second embodiment of the invention.

A control amplifier 1 is connected to the output of a preamplifier 2 , which is connected downstream of the photodiodes that receive the remote control command. The output of the control amplifier 1 is connected to a possibly additionally controllable threshold detector 3 , the output of which is connected to the input of a television control circuit 4 . The output of the control amplifier 1 is also connected via a diode 6 to two paths for feedback. One path leads via a resistor 7 and a capacitor 8 connected in parallel to an adder 9 . The other way leads via a resistor 11 to the adder 9 , where another resistor 12 and a capacitor 13 are connected downstream of the resistor 11 . One way with the resistor 7 has a time constant in the order of 30 · 10 ^-3 s, while the other way with the resistor 11 has a time constant in the order of 10 ^-3 s. The output of Ad dierers 9 is connected to an input of the control amplifier 1 .

Finally, an input of the adder 9 is connected to an interfering light barrier from a capacitor 14 and a resistor 16 which, for example, does not transmit a useful signal when a lamp is being switched on. A terminal 20 of the capacitor 14 is supplied with DC voltage proportional to the stray light. The interfering light barrier from the capacitor 14 and the resistor 16 can optionally be omitted, or the bandwidth of the one channel with the resistor 7 can also be made dependent on the amplitude.

The two paths with the resistor 7 or the resistor 11 can be combined to form a filter, whereby the manufacture of the circuit arrangement in integrated technology is facilitated.

FIG. 2 shows another exemplary embodiment of the invention, in which parts that correspond to one another are provided with the same reference numerals as in FIG. 1.

Instead of the control amplifier 1 , an ordinary amplifier 21 is provided here. Between the output of the adder 9 and the control input of the controllable threshold detector 3 there is a link 23 with a transmission factor which is optimally adapted to the desired application and which emits the reference voltage for the threshold detector.

Claims (6)

1. Circuit arrangement for an optoelectronic remote control, in particular of television receivers, with an amplifier for the useful signal, with a control amplifier ( 1 ) for amplitude control for the useful signal and a threshold detector ( 3 ) between the control amplifier ( 1 ) and the input of the control circuit ( 4 ), the output of the control amplifier ( 1 ) being fed back to the control amplifier ( 1 ) via the control loop and the control loop having a path with a first cut-off frequency and a first transmission factor for guiding the useful signal, characterized in that the control loop has a second path has the transmission of the noise signal with a significantly lower cut-off frequency and a substantially larger transmission factor ( FIG. 1). 2. Circuit arrangement for an optoelectronic remote control, in particular of television receivers, with an amplifier ( 21 ) for the useful signal and with a threshold detector ( 3 ) between the amplifier ( 21 ) and the input of the control circuit ( 4 ), characterized in that the reference value for the threshold value detector ( 3 ) is controlled by the signal via a control path ( 6, 7, 8, 9, 11, 12, 13, 23 ) and that the control path is divided into at least two paths, essentially one of which has a low cut-off frequency and large transmission factor conduct the noise signal and the other with higher cut-off frequency and smaller transmission factor conduct the useful signal ( FIG. 2). 3. Circuit arrangement according to claim 1 or 2, characterized, that both ways merged purely in terms of construction in a filter are summarized.   4. Circuit arrangement according to claim 1 or 2, characterized in that the following applies to the cut-off frequency f _{g1 of} the channel with the smaller transmission factor: with t _M = width of a pulse of the modulation signal or of the pre-pulse provided for control. 5. Circuit arrangement according to claim 1 or 2, characterized in that for the cut-off frequency f _{g₂ of} the channel with the large transmission _factor applies: with t _M = width of a pulse of the modulation signal or of the pre-pulse provided for control. 6. Circuit arrangement according to one of claims 1 to 5, characterized by a stray light barrier ( 14, 16 ).