HU186327B - Circuit arrangement for dampint electromagnetic disturbances in potical receivers - Google Patents

Abstract

In the optical receiving device, two anti-parallel-connected photodiodes are provided. The output signals of the photodiodes are supplied to the two inputs of a differential amplifier, preferably via transimpedance amplifiers. In this manner, the useful output signals of the photodiodes occur amplified at the output of the differential amplifier, but the electromagnetic interference signals coupled into the photodiode circuit branches with the same phase cancel out.

Description

The present invention relates to a circuit arrangement in optical receivers for suppressing electromagnetic disturbances.

The principle of the circuit arrangement according to the invention is that both circuits have the same number and type of photodiode and the same resistors, and the connection points of each diode and their respective resistors are connected to each input of a differential amplifier via a coupling capacitor.

-1- 186327

BACKGROUND OF THE INVENTION The present invention relates to a circuit arrangement for suppressing electromagnetic interference in optical receivers, preferably to an infrared transmission section of a conference apparatus for receiving both modulated light pulses and modulated light beams by photodiodes in which at least one photodiode is connected in the circuit branch, the cathode of at least one additional photodiode is connected to the positive pole of the voltage source, and the cathode is grounded through an additional working resistor.

Electromagnetic waves, especially those from radio transmitters, produce interference signals in light receivers, such as infrared conference equipment light receivers, as these light receivers are used to receive relatively weak light signals, especially those from battery-powered, low-light transmitters, and these receivers need to be. These high-sensitivity light receivers have the disadvantage that electromagnetic interference emitted by photodiodes, in particular infrared receiver diodes, is transmitted to subsequent amplifiers and causes noise and noise. This is done in particular because the photodiodes must be arranged on the receivers either relatively directly or with an optical lens.

It would be obvious to use customized rings or nets in the optical lens system of the receivers, which reduce the irradiation of the electromagnetic interference field, but have the disadvantage of creating a shadow effect due to the reduction of the useful signal and also providing a directional shadow effect.

SUMMARY OF THE INVENTION It is an object of the present invention to overcome the above drawbacks by providing a switching arrangement that suppresses electromagnetic disturbances in an optical receiver, particularly at high pulse or high pulse tracking frequencies.

The object of the present invention has been achieved by the circuit arrangement described in the preamble, according to the invention, that both circuits have the same number and type of photodiode and the same resistors, and the connection points of each diode and their resistors via a coupling capacitor led to one of its inputs.

The advantage of this solution is that the interfering irradiation of the electromagnetic fields interfering with the simple receivers into the optical receivers can be suppressed while at the same time providing the highest sensitivity since an optimum useful signal is obtained and no mechanical aid is required in the receiver.

According to a preferred embodiment of the invention, an impedance inverter consisting of integrated or discrete operational amplifiers and feedback resistor is inserted between each coupling capacitor and the differential amplifier input for processing fast useful signals.

The advantage of this embodiment is that it allows for fast processing of useful signals, especially when receiving male pulses with a sharp edge or high tracking frequency, by simply applying a switching arrangement.

The embodiment of the present invention will now be described in more detail with reference to the embodiments shown in the accompanying drawings, in which Figure 1 shows a first embodiment of a circuit arrangement according to the invention and Figure 2 shows another embodiment of a circuit suitable for processing useful signals.

In Fig. 1, in a first circuit branch, the anode Dj of a photodiode Dj is connected to the body or reference voltage, its cathode is connected to the + U positive pole of a voltage source via a working resistor Rj. Similarly, in another circuit branch, the cathode of an additional photodiode D _{2 is} connected to the + pole of the voltage source, while its anode is connected to a ground or reference voltage via a further working resistor R ₂ . To make better use of the useful signal, it is advisable to use its parallel-connected photodiode systems ·, shown in the drawing as only a second D / or D ₂ 'photodiode. The same number of same type D _|; A D /, has a D ₂ , D ₂ 'photodiode. Both working resistances R ,, R _{2 have the} same value. The point of the photodiodes D _p and D _2, which share the working resistance R _p and R ₂ , respectively, are connected via a coupling capacitor Cp or C _{2 to} each input of a DV difference amplifier, whereby a useful signal from one circuit branch inverts 5 inputs, and the useful signal from the other circuit branch to the non-inverting input of the DV difference amplifier. The useful light signal is transmitted to the Dp D ₂ photodiode and converted there into electrical signals. If electromagnetic disturbances coupled to Dp D ₂ photodiodes occur, they produce the same phase disturbance signals at the DV difference amplifier inputs which do not appear at the DV differential amplifier output, i.e. suppressing the electromagnetic disturbance. In order to achieve higher sensitivity and better signal-to-noise ratio, several parallel-connected photodiodes may be inserted into each circuit branch instead of individual photodiodes.

Figure 2 shows substantially the same circuit diagram as in Figure 1; wherein, however, the difference is that the coupling capacitors Cp and _C2 and the differential amplifier DV input to an amplifier is interposed a impedanciaváltó, whereby phase inversion occurs, so that the differential amplifier inputs of DV to be replaced. Thus, one circuit branch is connected to the non-inverting input of the DV differential amplifier and the second circuit branch is connected to the inverting input of the DV differential amplifier.

The impedance inverter consists of an operational amplifier OP1 and OP2, respectively, and an R ₃ and R ₄ resistor connected to their feedback loop.

When processing male pulses with either a sharp slope or a high tracking frequency, the induced voltage signals in the Dp D ₂ photodiodes thus pass through a fast current path. The same applies to interference suppression as described in Figure 1.

-2'86327,

Claims (2)

Patent claims A circuit arrangement in optical receivers for suppressing electromagnetic disturbances, preferably for infrared transmission of conference equipment, for receiving both modulated light pulses and modulated light beams by photodiodes, wherein at least one photodiode anode is connected to one of the circuits, one to the other, the circuit branch of at least one additional photodiode cathode of the voltage source positive pole, cathode via a further munkaellenálláson customized connected, characterized in that both circuit branches of the same number and the same type photodiode (D _t, D ₂₎ and the same working resistor (R _t, R ₂ ) are present and are connected to each photodiode (D [or D ₂ ) and their respective resistors (R _p and R ₂ ) It is connected to 5 inputs of a differential amplifier (DV) via 5 coupling capacitors (C, respectively C ₂ ). 2. Circuit arrangement according to claim 1, preferably useful for the rapid signal processing, 10 wherein said one impedanciaváltó amplifier is inserted between the individual coupling capacitors (C _p and C ₂₎ and the differential amplifier (DV) input, which is integrated with or it consists of discrete operational amplifiers (OP1 and OP2) and a feedback resistor _(R3 or _R4). Figure 1, Figure 2 Responsible for the publication: Director of the Publications and Legal Publishing House 87.2495.66-4 Alföldi Nyomda, Debrecen Chief Executive Officer: István Benkő Chief Executive Officer