DE3233728A1 - Circuit arrangement for suppressing the signal components generated from constant light in infrared receivers - Google Patents

Abstract

The invention relates to a circuit arrangement for suppressing the constant-light signal components in a pre-amplifier for an infrared receiver with a photodiode (3), whose operating point is determined by a series-connected resistor (4, 5). In order to minimise the power consumption of the photodiode (3) and ensure effective constant-light suppression in signal processing and provide a high-resistance input stage, a diode (6), through which the reverse current of the photodiode (3) flows, is connected in parallel with the resistor (4, 5) which determines the operating point of the photodiode and the received signal is applied to an impedance transformer (8) disposed in a bootstrap circuit and operating in conjunction with a following amplifier stage (9) as a cascade circuit. <IMAGE>

Description

Circuit arrangement for suppressing the from

Signal components generated by constant light in infrared light receivers The invention relates to a circuit arrangement for suppressing the constant light generated signal components in a preamplifier for an infrared light receiver according to the preamble of claim 1.

Infrared light is used as a medium for transmitting remote control signals and for sound transmission in consumer electronics and in many other areas used to an increasing extent. While with the sound transmission the signals always are transmitted in a carrier, the remote control commands are in In the form of individual pulses or pulse code modulated as a word with a pulse train (PPM, PCM or pulse spacing modulation) both non-carrier and carrier-transmitted. In the case of carrier transmission, the infrared light transmitter (diode or transistor) of the transmitter controlled by an HF generator, on whose frequency the signals are modulated or that of individual pulses or individual control pulses of a binary coded Control word is scanned. Depending on the distance between the transmitter and the infrared light receiver the infrared light hitting the photodiode of the receiver has one more or less high light intensity. The electrical converted by the photodiode Signals are therefore relatively large when the operating distance is short and when the distance is large Distance, on the other hand, is much smaller.

With the useful light signal, however, an undesired constant light component, which is caused by the ambient light, implemented with. For compensation or to suppress the constant light component are in infrared light preamplifiers various circuits known.

One solution is from the data book 1978/79 "Integrated circuits for consumer electronics11 from Intermetall, page 75, where the picked up by a photodiode and converted into a weak electrical signal Infrared light is amplified so that the amplitude for driving one of the remote control pulses processing circuit (MOS circuit SAA 1051) is sufficient. The photodiode is working thereby with a dynamic load resistance, which is formed by a transistor is, together, which is connected in series with her. The dynamic load resistance has the task of suppressing the signal generated by constant light. Through this the working point of the photodiode is independent of the ambient brightness.

For this purpose there is less anode of the photodiode, the cathode of which is connected to a Operating voltage is connected to the base of a first transistor, which is the emitter follower a second transistor controls, from whose emitter a negative feedback signal to DC light suppression is removed. The collector of the second transistor controls an amplifying transistor, which in turn is connected to a switching transistor is connected, which by specifying a threshold value, the noise signal from pulse-shaped useful signal separates. This is due to the collector of this switching transistor Pulse-shaped useful signal which, depending on the type, is either pulse-code-modulated or as a single signal is present.

This useful signal is sent to the receiver evaluation circuit. That as a negative feedback signal for suppression of constant light from the emitter of the second transistor the tapped signal is integrated in an RC memory. The tangible tension serves as the base bias for the transistor, which is the dynamic load resistance forms. The discharge time constant is so small that the constant light suppression is practically only effective during a pulse duration. Doesn't fall on the photodiode Light, the transistor is not conductive and the dynamic load resistance is very high great.

If, however, light falls on the photodiode, it becomes conductive, so that the first transistor and the downstream amplifying transistor are also conductive will. In doing so, a is proportional to the light intensity of the incident constant light amplified signal given to the RC memory. The dynamic load resistance becomes more or less larger depending on the voltage state of the RC storage system or smaller, depending on the level of the current flowing through the photodiode. At large Constant light component, the dynamic load resistance becomes low. Vice versa it becomes higher resistance as soon as light with a lower light intensity hits it. The sensitivity the diode rises and responds to every incident light. The here The control circuit used has the effect that the sensitivity of the photodiode is lower but the operating point remains constant.

In another known preamplifier (P 31 36 565) it is known the dynamic load resistance of the photodiode as a function of the amplitude of the received useful signal to change, the working point of the photodiode such shifts that the amplitudes of the individual pulses of the remote control command almost are constant. Constant light components are compensated at the same time.

On the basis of this prior art, the object of the invention is to be found based on providing a circuit arrangement in a preamplifier with a photodiode, which without a control loop the load resistance of the photodiode depending on the Constant light components changed in such a way that the useful signal that can be tapped off is composed of direct current components is exempt, the receiver circuit having a particularly low power consumption and should have a simple circuit structure.

According to the invention, the object is reproduced in claim 1 technical teaching solved.

The input stage of the preamplifier is provided by the arrangement of the Impedance converter and the subsequent voltage amplifier according to claim 2 a Circuit that works according to the cascode principle. The impedance converter is working according to the bootstrap process, which results in an extremely high input resistance for alternating voltage and thus the lowest possible load is achieved.

In terms of DC voltage, the working resistance is due to the series connection of the base point resistances. The one provided in parallel with one of the resistors Diode works for an effective direct light suppression with favorable alternating light sensitivity. The dimensioning of the components is based on a maximum sensitivity of the infrared diode designed with low power consumption at the same time. By that on the photodiode incident infrared light, the reverse current of the same is increased. This flows through the series-connected diode which determines the operating point and makes this more or less conductive. By changing the base point resistance, the working resistance is of the photodiode shifted by the DC voltage component that comes from the constant light. Only AC voltage components are therefore present at the input of the impedance converter at. The impedance converter has a high differential resistance - conditionally through the provided bootstrap circuit -. The one that can be tapped off at the impedance converter output The signal is amplified via the downstream amplifier to the downstream circuits passed on.

Advantageous further developments of the invention are set out in the subclaims 3 and 4.

The invention is illustrated below with reference to one in the figure Embodiment explained in more detail.

In the figure is an example of a preamplifier for an infrared light receiver for a remote control receiver to receive carriers emitted by means of infrared light or unsupported control commands are shown in pulse form. To an operating voltage source UB is a filter element, consisting of resistor 1 and the electrolyte capacitor 2, switched. Connected to this is the cathode of a photodiode 3, which with its The anode is connected to a voltage divider consisting of resistors 4 and 5 is. The voltage divider 4.5 is connected to ground potential. Parallel to the resistance 4, a diode 6 and a resistor 7 arranged in series therewith are connected. At that of the connection of the anode of the photodiode 3, the anode of the diode 6 and the Resistance 4 formed node B is the basis of a pnp-doped Connected transistor 8, which is arranged in a collector circuit, the collector is connected to ground potential and the emitter with the emitter of another Transistor 9, which is doped npn, is connected. The impedance converter is in a bootstrap circuit arranged, including the emitter via a capacitive positive feedback branch with a Capacitor 10 at the voltage divider center point C, which is also the connection point forms with the resistor 7 is connected. The working resistance of the transistor 8 is through the voltage amplifier circuit consisting of the transistor 9, the Current-limited resistor 10, the high-resistance one, connected in the collector circuit Negative feedback resistor 11, which is connected between the collector and base, and a capacitor 12 connected to ground and connected to the base.

The output of the amplifier and the collector of transistor 9 are capacitively decoupled via a capacitor 13 with the subsequent circuits of the infrared light receiver connected, which are not shown for the sake of simplicity.

The working resistance of the photodiode 3 is through DC voltage the series-connected resistors 4 and 5 are determined. Falls on the photodiode 3 light on, the reverse current is dependent on the incident light intensity prevented. The current flowing through the photodiode simultaneously causes that too the diode is proportionately more or less conductive, so that parallel to the resistor 4 the instantaneous volume resistance of the diode 6 as well as that in series for linearization the resistor 7 provided for the characteristic of the diode 6 can be connected in parallel. Through this the DC load resistance changes depending on the DC light components proportional. At point B there is therefore an alternating light that is the actual one received light intensity corresponds to the control command transmitted at alternating frequencies. Through the impedance converter stage with transistor 8, which is in bootstrap circuit is arranged, it is achieved that in terms of alternating voltage, an extremely high input resistance is present and thus achieves the lowest load on the IR diode in terms of alternating current will. The working resistance of the impedance converter of the transistor 8 is through the An amplifier circuit arranged in a base circuit with the transistor 9 is formed. The gain factor of the transistor is increased by the changing direct current 8 changed so that normally also the transistor 9 of the amplifier would have to have a different gain factor. The working point of the transistor 9 is, however, placed independently of the high resistance 11 so that it lies in the most favorable working range of the transistor 9.

The direct current flowing through the transistor 8 affects the The gain factor of the transistor 9 is practically not sufficient. The diode 6 causes by their dynamic resistance as a result of the increased current passage with constant light incidence, that the positive feedback through the capacitor 10 is stronger. This increases the differential resistance at point B of the input resistance in corresponding Way. The dimensioning of the capacitors 12, 10 and the two selected transistors 8 and 9 and the resistance base point arrangement of the photodiode 3 is chosen so that the frequency signals received by the photodiode double as light Line frequency or light from the television receiving equipment. This is supported through the high-resistance negative feedback circuit of the transistor 9 via the resistor 11 and the transistor 12 connected to the base, via which the low-frequency Signal components are filtered off, whereby the gain of the transistor 9 increases.

With the circuit arrangement designed according to the invention, a high sensitivity of the photodiode achieved through an optimized operating point, constant light suppression with the greatest ambient brightness guaranteed and a low power consumption due to the selected cascode circuit principle working transistor arrangement guaranteed.

If the input resistance is very high, there is also a lower one Output resistance given so that the received and amplified signals without further impedance matching can be passed on to the arranged evaluation circuits can. Due to the arrangement, the operating voltage range is very high. With the specified dimensioning of the components, it is between 3 and 20 V.

L e r s e i t e

Claims (4)

Claims 1. Circuit arrangement for suppressing constant light signal components in a preamplifier for an infrared receiver to receive on one HF carrier frequency with modulated signals transmitted by means of infrared light a photodiode that converts the light signals into proportional electrical signals, amplified in an amplifier circuit and a downstream signal evaluation circuit are supplied, the working point of the photodiode by a series-connected Resistance is set, characterized in that parallel to the operating point the photodiode (3) determining resistor (4) one of the reverse current of the photodiode (3) through-flow diode (6) is arranged, and that at the connection point (8) between the photodiode (3) and diode (6) a transistor (8) as an impedance converter in a bootstrap circuit is arranged, the output of which is connected on the one hand to an amplifier circuit (9) and on the other hand via a capacitive positive feedback (10) to the second PolderDiode (6) and is connected to a resistor (5) connected to ground. 2. Circuit arrangement according to claim 1, characterized in that the cathode of the photodiode (3) is connected to a positive operating voltage source (UB) is that the anode is connected to the anode in parallel with the resistor (4) Diode (6) is arranged that a resistor (7) is arranged in series with the diode (6) is the one with the positive feedback branch of the bootstrap circuit and the one connected to ground Resistor (5) is connected, and that the impedance converter consists of a pnp transistor (8), which is arranged in a collector circuit. 3. Circuit arrangement according to claim 1 or 2, characterized in that that the amplifier circuit comprises an npn-doped transistor arranged in a base circuit (9), the base of which via a capacitor (12) to ground and via a high-resistance resistor (11) with the collector and its emitter with the impedance converter (8) are connected, and its collector is connected to a positive operating voltage (UB) is applied, the amplified output signal being tapped capacitively from the collector will. 4. Circuit arrangement according to claim 3, characterized in that the capacitor (12) at the base of the amplifying transistor (9) and the capacitor (10) in the positive feedback branch and the base point resistances (4 and 5) of the voltage divider in series with the photodiode (3) are dimensioned so that alternating extraneous light components are lower Frequency, e.g. double the network frequency or light from the television receiver and converted Higher-frequency alternating light components that are emitted by the infrared transmitter be strengthened.