DE3743766A1 - Optical receiver - Google Patents

Abstract

Optical receivers are frequently constructed as transimpedance amplifiers, a photoelectric element being connected to the input of the transimpedance amplifier. In the case of input signals having a high continuous-wave light component, a coupling capacitor is in most cases provided between photodiode and input of the transimpedance amplifier, but this coupling capacitor limits the bandwidth of the optical receiver. This coupling capacitor can be omitted when the circuit arrangement presented is used. For this purpose, the transimpedance amplifier is constructed as differential amplifier and the input of the transimpedance amplifier is connected to a current source circuit which is controlled by a control signal derived from the output signal of the transimpedance amplifier. The circuit arrangement is suitable, for example, for optical receivers of optical-fibre transmission links.

Description

The invention relates to an optical receiver with egg Nem transimpedance amplifier, at the input of a photo element is connected.

Such a circuit arrangement is e.g. in the essay "Receiver Design for Optical Fiber Systems" by S. D. PER SONICK in PROCEEDINGS OF THE IEEE, VOL 65, NO 12, DECEM BER 1977 on page 1676. It is a photodiode connected to the input of a transimpedance amplifier the. The transimpedance amplifier consists of an inverter ting amplifier between its inverting on gang and its output is a feedback resistor is closed. The transimpedance amplifier is a Current-voltage converter, which the photo current of the photo diode converts into a proportional voltage. Transimp dance amplifiers offer because of a low input wi derstandes the advantage of a high frequency bandwidth.

For input signals with a high proportion of constant light, between rule photodiode and input of the transimpedance amplifier a coupling capacitor is provided, which the same Blocked current portion of the photocurrent of the photodiode. The This coupling capacitor forms together with the input wi the state of the transimpedance amplifier has a low pass. There the input impedance of the transimpedance amplifier very much is low, the capacitance value of the coupling capacitor sators can be chosen very large in order to be sufficient To achieve bandwidth. Large capacity values are for to integrate one badly, on the other hand as a discreet one Executed as a component, they act as an antenna and begin  cause interference.

The object of the invention is a circuit arrangement of the type mentioned at the outset, that even with high DC signal components of the input sig nals can be dispensed with a coupling capacitor.

This object is achieved in that the transimpedance amplifier designed as a differential amplifier and that on Input of the transimpedance amplifier is a current source circuit, which is connected from one of the Output signal of the transimpedance amplifier derived Control signal is controlled.

Advantageous developments of the invention are in the Subclaims specified.

The invention is based on the Darge in the drawing presented described embodiment and he purifies.

The drawing shows an optical receiver which converts modulated light into electrical signals. The modulated light is supplied to a photodiode 1 via a glass fiber (not shown ) . The anode of the Photodio de 1 is biased with a negative bias voltage - U 1 . The cathode of the photodiode 1 is connected to the input -E of a transimpedance amplifier 2 . The transimpedance amplifier is designed as a differential amplifier with two transistors 8 , 9 . This has the advantage that symmetrical overloads only lead to a limitation of the output signal, without signal delays due to saturation effects of the active components having to be accepted, as is the case with other amplifier types or with asymmetrical control of a differential amplifier would.

In differential amplifiers, the emitters of two transistors are connected to a current source. An operating voltage + U is supplied to the collectors of these transistors via collector resistors. The base of the first transistor 8 forms an inverting input -E of the differential amplifier, while the base of the second transistor 9 is connected to a DC voltage source. The collector of the second transistor is connected to the base of a third transistor, which is designed as an emitter follower. The emitter of the emitter follower forms the output A of the differential amplifier. The amplified and inverted input signal can be picked up here. A feedback resistor R lies between the inverting input -E and output A of the differential amplifier 8 , 9 . Through this circuit, the differential amplifier becomes a transimpedance amplifier, the current flowing in the input -E is converted to a proportional voltage inverted by this input current. When light strikes the photodiode 1 , the reverse current of the photodiode increases accordingly. This reverse current flows from the output A of the transimpedance amplifier 2 via the feedback resistor R to the input -E of the transimpedance amplifier and from there to the photodiode. With regard to the input -E , this reverse current is a negative input current - ie flows out of the input of the transimpedance amplifier - and leads to a positive output signal of the transimpedance amplifier because of the inverting input.

The output A of the transimpedance amplifier 2 is connected to the input of a control amplifier 3 . The Regelver amplifier 3 consists in the embodiment of an inverting integrator constructed with an operational amplifier 5 and an upstream inverting amplifier 6 . The control amplifier 3 is thereby non-inverting. If a differential amplifier is used which additionally has an inverting output, the inverting amplifier 6 can be omitted. In this case, the input of the integrator must be connected to the inverting output of the differential amplifier.

With increasing light output striking the photodiode 1 , the reverse current of the photodiode increases. The control voltage of the control amplifier 3 is a current source circuit 4 supplied. The output of the current source circuit 4 is connected to the inverting input -E of the transimpedance amplifier 2 . When driving the current source circuit with a negative control level, the current source circuit 4 provides no output current. If, however, the current source circuit 4 is driven with a positive input voltage, the output current rises monotonically with this control voltage. Since the current source circuit 4 , like the control amplifier 3, is non-inverting, the negative feedback condition in the control circuit is thereby fulfilled for the entire circuit arrangement with the inverting transimpedance amplifier 2 .

Since the control amplifier outputs a control voltage, can the controlled power source in the simplest case from one between the output of the control amplifier and the input of the Transimpedance amplifier current limiting resistor stood. So with negative control voltage none Control current flows is in series with the current limit resisted to provide a diode.

In the exemplary embodiment, the current source circuit consists of a transistor 7 , the collector of which positive operating voltage + U is supplied. The base of the transistor forms the control input and its emitter the output of the current source circuit 4th This has the advantage that the output of the integrator is only insignificantly loaded.

The DC component of the photocurrent increases with increasing optical input levels. An integrator as a re gel amplifier 3 has the advantage that the higher-frequency signal components are screened out by the integration of the output signal and preferably the DC voltage component is amplified. In this way, the lower corner frequency of the optical receiver is determined with the time constant of the integrator. If the direct current component of the photocurrent exceeds a limit value specified by the comparison voltage U 1 , the control amplifier 3 supplies a positive control voltage. This he generates a positive control current through the current source circuit 4 . This control current flows through the Photodio de 1 .

At low light input powers, the output voltage of the transimpedance amplifier 2 is so small that the differential amplifier is not yet limited. The comparison voltage U 1 is therefore set so that no control current flows. In this way the control is inactive at low optical input levels. This has the advantage that the signal-to-noise ratio of the input signal is not impaired by the control circuit at low input levels. However, because of the galvanic coupling of the photodiode and transimpedance amplifier, the dif amplifier 8 , 9 is also driven with the direct current component of the photocurrent. The dif ferential amplifier 8 , 9 is therefore controlled only in the positive output voltage range, that is to say asymmetrically. As long as the output voltage is less than the voltage at which the output signal is limited, the output signal is not affected by the asymmetrical modulation.

If the input current continues to rise, the input signal in the differential amplifier 8 , 9 is increasingly limited. The rise and fall times of the input signals are shortened, since only a small part of the high-level AC component is required to fully control the limiter. This has the advantage that the edge steepness is improved in the case of smoothed rectangular pulse edges. However, since the comparison voltage U 1 is now exceeded by the output voltage of the transimpedance amplifier, the control circuit becomes active and feeds a control current into the input -E of the transimpedance amplifier. This control current causes a compensation of the DC component of the photocurrent, so that the working point on the input characteristic of the differential amplifier for large signals is kept constant. As a result, he reaches an almost symmetrical modulation of the differential amplifier, which enables the use of the limiter properties of a differential amplifier without accepting the known disadvantages of asymmetrical modulation.

Claims (6)

1. Optical receiver with a transimpedance amplifier, to the input of which a photo element is connected, characterized in that the transimpedance amplifier is constructed as a differential amplifier ( 8 , 9 ) and that at the input ( -E ) of the trans impedance amplifier ( 2 ) a current source circuit ( 4 ) is connected, which is controlled by a signal derived from the output signal of the transimpedance amplifier control signal. 2. Optical receiver according to claim 1, characterized in that a control amplifier ( 3 ) is used to derive the control signal, the input of which is connected to the output ( A ) of the transimpedance amplifier and the output of which is connected to the control input of the current source circuit ( 4 ) . 3. Optical receiver according to one of claims 1 or 2, characterized in that the current source circuit consists of a current limiting resistor between the output of the control amplifier ( 3 ) and the input ( -E ) of the trans impedance amplifier ( 2 ). 4. Optical receiver according to one of claims 1 or 2, characterized in that the current source circuit ( 4 ) consists of a transistor gate ( 7 ). 5. Optical receiver according to claim 1 or 2, characterized in that the control amplifier ( 3 ) has an input threshold. 6. Optical receiver according to one of claims 1, 2 or 5, characterized in that the control amplifier ( 3 ) is an integrator ( 5 , 6 ).