JPH0793540B2 - Optical receiver - Google Patents

Description

TECHNICAL FIELD OF THE INVENTION The present invention relates to a DC-coupled optical receiver suitable for simultaneously satisfying low noise and stabilization of an operating point.

[Technical background of the invention and its problems]

When the optical communication receiver is composed of individual parts, the unit circuit consisting of active elements such as transistors and resistors has the advantages of easy DC bias design and excellent DC operating point stability. , Are mutually AC-coupled via capacitors. When the AC coupling circuit configuration is used, so-called frequency components below the low cutoff frequency are not sufficiently transmitted to the subsequent stage. That is, the low-frequency cutoff suppresses the low-frequency component of the transmission signal and loses the DC component. Therefore, low-frequency cutoff distortion occurs in the transmission signal and transmission quality is significantly impaired.
Although a DC regenerating means such as a clamp circuit can be considered in order to regenerate the DC component lost due to the low frequency cutoff, there are drawbacks such as the need for a clamp circuit and waveform distortion. The influence of low-frequency cutoff is a problem that cannot be ignored because the current optical communication technology carries out information transmission with unipolar light intensity.

In order to reduce the size and cost of optical communication receivers, when monolithic ICs are used, the capacitance value of the coupling capacitor used for AC coupling should be set to the required value due to restrictions on the manufacturing process of monolithic ICs. Is currently impossible, and only very small value capacitors can be realized on monolithic ICs. For this reason, the effect of low-frequency cutoff becomes significant, and the disadvantage of AC coupling appears significantly. This is because the low cutoff frequency shifts to the higher frequency side and the frequency range of the low frequency components to be lost is expanded, resulting in significant waveform distortion due to the low frequency cutoff.

In order to eliminate the above-mentioned drawbacks in the AC coupling circuit configuration, it is conceivable that the configuration of the optical receiver including the light receiving element and the amplification circuit is DC coupling. In the case of the DC coupling structure, since the low frequency cutoff does not occur, the above drawback is completely eliminated. However, in a DC-coupled configuration, when a very large gain is required as a whole like an optical receiver, a minute change in DC potential in the unit circuit near the front stage of the circuit can be ignored in the final stage of the circuit. There will be no size. In the amplifier circuit, the value obtained by converting the DC level deviation of the final disconnection output voltage when the input signal is zero to the input is called the offset voltage.In the case of the DC coupling configuration, the variation of the offset voltage due to the variation of the element, and A change in offset voltage due to a change in environmental temperature poses a problem. The latter effect due to temperature change is called drift, which causes a change in the DC operating point of the amplifier circuit due to a change in environmental temperature, causing a temperature change in the amplification characteristics, and in the worst case, the adverse effect of not operating as an amplifier circuit. is there.

The cause of the drift of the amplifier circuit is mainly due to the temperature change of the voltage drop V _BE between the base and emitter of the transistor. However, in the optical receiver, there is a new problem that the light receiving element is connected to the input terminal of the preamplifier and the dark current of the light receiving element changes depending on the ambient temperature. Factors of the dark current in the semiconductor light receiving element include diffusion current, generated current, surface leak current, etc., and the value of the dark current varies depending on the material of the element, the device manufacturing process, and the device structure. The temperature characteristic of the dark current Id in a well-made semiconductor light receiving element is approximately given by the following equation.

However, Eg: band gap of the light receiving element k: Boltzmann constant T: absolute temperature m: constant (almost 2 for Si, almost 1 for Ge) The dark current Id has a digit of 1 when the temperature rises around 20 °. Has temperature characteristics that are orders of magnitude larger. Therefore, the dark current changes by about two digits with respect to the change of the ambient temperature of 50 °. For example, in the case of Ge avalanche photodiode, 0-50
At ° C, the dark current changes from several tens nA to several µA. For the drift in the optical receiver, it is necessary to consider both the drift of the amplifier circuit alone and the drift caused by the dark current of the light receiving element. Therefore, the drift Vdrift in the optical receiver is given by the following equation.

However, Voff: Offset voltage of amplifier circuit Rin: Input resistance of preamplifier ΔT: Temperature change Drift of amplifier circuit alone is reduced by adopting differential amplifier, but drift due to dark current of light receiving element is based on semiconductor physical properties. However, in the original state, it is impossible to manufacture an element having a dark current that does not pose a practical problem.

A partial solution to the adverse effects of drift in optical receivers is described in Japanese Patent Publication No. 59-20210. FIG. 6 shows a configuration diagram of drift compensation according to this conventional technique. The output current of the light receiving element (1) is amplified by the preamplifier (2),
The output of the preamplifier (2) is input to the main amplification system of the next stage and thereafter, and also to the offset compensation circuit (7).
The offset compensation circuit (7) detects the offset voltage by extracting the low frequency component in the signal by a low pass filter or the like, and outputs an output current corresponding to the detected offset voltage to the input terminal of the preamplifier (2). Negative feedback. With the above-mentioned conventional technique, the drift due to the dark current of the light receiving element (1) can be compensated. However, although the drift compensation has become possible, a new problem arises because the drift compensation is performed by the configuration shown in FIG. These problems result from the fact that the signal compensating for the drift is fed back directly to the input terminal of the preamplifier. As is well known, it is no exaggeration to say that the performance of an optical receiver is calibrated by a light receiving element and a preamplifier. The output point of the light receiving element, that is, the signal handled by the preamplifier is a weak signal of the order of several nA in a remarkable case, and the preamplifier is required to have low noise. However, in the configuration shown in FIG. 6, the noise generated in the offset compensation circuit is directly applied to the preamplifier circuit, which deteriorates the noise characteristic of the optical receiver. Also,
Since an object other than the light receiving element is connected to the input point of the preamplifier, a new finite impedance is connected to the input point of the preamplifier as compared with the case where the drift compensation is not performed. Of the impedance connected to the input point of the preamplifier, the resistance component R causes an increase in current noise in the form of 4 kT / R, and the capacitance component causes a decrease in the signal bandwidth of the preamplifier, and at the same time, it causes voltage noise. Will increase.

[Object of the Invention]

SUMMARY OF THE INVENTION It is an object of the present invention to eliminate the above-mentioned problems of the conventional technique and to provide an optical receiver capable of compensating for a drift based on a dark current of a light receiving element without causing deterioration of noise characteristics. To do.

[Outline of Invention]

The present invention relates to a light receiving element that converts an input optical signal into an electric signal, an amplifier that amplifies an electric signal generated by the light receiving element, and a differential signal in which an output signal from the amplifier is input to one input terminal. An amplifier circuit, an offset detector for detecting the base level of the difference signal output from the differential amplifier circuit, and a reference voltage generation circuit having the same circuit as the amplifier are provided, and the other input end of the differential amplifier circuit is provided. And a control means for feeding back the output voltage and controlling the base level so as to substantially match the output signal of the amplifier.

〔The invention's effect〕

According to the present invention, in the configuration in which the light receiving element, the preamplifier, and the amplification circuit are DC-coupled, the dark current of the light receiving element, the drift due to the preamplifier, and the amplification circuit can be compensated, and at the same time, the drift compensation according to the prior art can be performed. It is possible to prevent the increase of thermal noise and the deterioration of frequency characteristics, which are problems in the method. In addition, malfunction of the optical receiver due to external noise can be reduced. Furthermore, the circuit configuration does not include many capacitors, so that it is suitable for monolithic integration.

Example of Invention

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is an example of a basic configuration diagram of an optical receiver of the present invention.
An optical signal input to the optical receiver is converted into an electric signal by the light receiving element (1). This signal is appropriately amplified by the preamplifier (2) and then input to the differential amplifier circuit (3). The output signal of the reference voltage generation circuit (4) is input to the other input terminal of the differential amplifier circuit (3), and the difference signal from the output signal of the preamplifier (2) is supplied to the differential amplifier circuit (3). ). Differential output (5) of the differential amplifier circuit (3),
(6) is input to the main signal amplification system after the next stage,
It is input to the input terminals (8) and (9) of the offset compensation circuit (7). The offset compensation circuit (7) appropriately amplifies the input signal, receives the output of the offset detector (10) for detecting the offset voltage, and the output of the offset detector (10), amplifies as necessary, and detects Control circuit that generates output current or voltage according to offset voltage (11)
And are provided. The output of the control circuit (11), that is, the output of the offset compensation circuit (17) is the reference voltage generation circuit (4).
Negative feedback is applied to the input terminal of to reduce the offset voltage when the offset voltage is large. Here, as the offset detector (10), a base level detection circuit corresponding to a DC level when the input signal to the optical receiver is zero, or a low pass filter is suitable.

Further, the control circuit (11) may be any one that can be controlled so that the output signal level of the reference voltage generation circuit (4) substantially matches the output signal of the preamplifier (2).

The base level detection circuit is realized by the configuration shown in FIG. 2, for example. Base level detection circuit input terminals (21), (22)
For example, an inverted signal V− and a non-inverted signal V + from the differential amplifier circuit (3) are input to each of them. Transistor Q1, Q
The 2 and the collector terminal of the transistor Q2 of the differential amplifier consists of a current source I ₀ (23) voltage V of the difference between the inverted signal and the non-inverted signal - voltage proportional to V + is generated. The peak voltage detector composed of transistors Q3, Q4, capacitor C, and resistor R3 has a difference V−− between an inverted signal and a non-inverted signal.
It functions to detect and hold the maximum value of V +.

FIG. 3 shows waveforms at various points in the base level detection circuit shown in FIG. 3A and 3B show a non-inverted input signal and an inverted input signal, respectively. The signal V ₀ in the figure represents the level when there is no offset voltage and the input signal to the optical receiver is zero. The broken line in the figure shows the voltage level when the input signal to the optical receiver is zero, but there is an offset, and is called the base level. Third
FIG. 6C shows the signal appearing at the collector terminal (23) of the transistor Q2. When there is no offset in the differential input signal to the base level detection circuit and the inverted signal and the non-inverted signal are balanced, the collector terminal (2
Basal level appearing in 3) is given by Vcc-I ₀ R _2/2 but, if there is offset comes deviates from this value.
The peak voltage detector detects the positive peak level of the waveform shown in FIG. 3 (c), that is, the voltage level indicated by the symbol Vp in FIG. 3 (c).

FIG. 4 is a structural example of a reference voltage generating circuit suitable for the present invention. In the figure, the part surrounded by the broken line is the configuration of a parallel feedback type amplifier which is often used as a preamplifier for optical reception. The parallel feedback type amplifier can obtain wide band characteristics while maintaining low noise. A resistor connected to a parallel feedback amplifier
The circuit composed of R ₀ and capacitor C ₀ constitutes a low pass filter. This low-pass filter cuts off high-frequency components of noise generated in the main parts of the control circuit (11) and the reference voltage generation circuit (4), thereby preventing an increase in thermal noise due to drift compensation. It is provided for.

In the conventional drift compensation method shown in FIG. 6, since the input point of the optical signal and the input point of the drift compensation signal are both inputs of the preamplifier, noise included in the drift compensation signal can be suppressed. Therefore, if a low-pass filter is inserted, band limitation will be added to the main signal, and noise increase due to drift compensation cannot be prevented.

FIG. 5 shows another configuration example of the reference voltage generating circuit. In the figure, the part surrounded by the broken line has the same configuration as the parallel feedback type optical pre-amplifier for optical reception, and this may be adopted. The low pass function is realized by the capacitor Cf connected in parallel with the feedback resistor Rf. The high cutoff frequency fh of the input current vs. output voltage transfer characteristic is given by h _h 1 / (2πRfCf).

It is not always necessary for the reference voltage generation to have a portion configured by the same circuit as the preamplifier from the viewpoint of drift compensation, but in order to reduce the effect of external noise, the reference voltage generation circuit It is preferable to have a portion configured by the same circuit as the preamplifier because the whole system has a balanced configuration.

As described above, according to the present invention, when compensating for the drift due to the dark current of the light receiving element which is a problem in the DC coupled optical receiver, the drift compensation signal is not applied to the preamplifier input terminal, By taking the difference from the output signal of the preamplifier via a reference voltage generator provided in parallel with the preamplifier, it is to prevent noise increase caused by drift compensation and band deterioration of the preamplifier, The method of realizing each component is within the range not deviating from the above basic idea.
Various forms are possible.

[Brief description of drawings]

FIG. 1 is a diagram showing an example of a basic configuration of the present invention, FIG. 2 is a circuit configuration diagram of a main part when the offset detector in FIG. 1 is a base level detector, and FIG. 3 is a base level detector. FIG. 4, FIG. 4 and FIG. 5 are views for explaining the operation of FIG. 1, FIG. 4 is a view showing an example of the reference voltage generating circuit in FIG. 1, and FIG. 1 ... Light receiving element, 2 ... Preamplifier, 3 ... Differential amplifier circuit, 4 ... Reference voltage generating circuit, 17 ... Offset compensation circuit, 10 ... Offset detector, 11 ... Control circuit.

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Office reference number FI technical display location H04B 10/26 10/28

Claims (4)

[Claims] 1. A light receiving element for converting an input optical signal into an electric signal, an amplifier for amplifying an electric signal generated by the light receiving element, and a difference in which an output signal from the amplifier is input to one input terminal. A dynamic amplifier circuit, an offset detector to which an output signal of the differential amplifier circuit is input, control means connected to the offset detector, and the same circuit as the amplifier, which is controlled by the control means. And a reference voltage generating circuit which supplies the reference signal to the other input terminal of the differential amplifier circuit, the output signal level of the differential amplifier circuit when the input signal to the light receiving element is zero. Is detected by the offset detector, and the level of the reference signal and the output signal level of the amplifier when the input signal to the light receiving element is zero are controlled so as to substantially match each other. . 2. The optical receiver according to claim 1, wherein the offset detector detects the DC level of the output signal of the differential amplifier circuit. 3. The optical receiver according to claim 1, wherein the offset detector has a low-pass filter. 4. The optical receiver according to claim 1, wherein the reference voltage generating circuit has a low-pass filter.