JPH07231307A - Optical pulse receiving circuit - Google Patents

Abstract

(57) [Abstract] [Purpose] The circuit configuration from the photoelectric conversion circuit to the comparator that discriminates the pulse level is made completely symmetrical,
Provided is an optical pulse receiving circuit having improved common-mode noise removal characteristics due to temperature drift, power supply fluctuation, and the like. A pulse signal obtained by photoelectrically converting an optical pulse is connected to one input of a differential amplifier 4, and a reference potential is connected to the other input. The peak values V ₁₉ and V ₂₀ of the positive output V ₁₃ and the negative output V ₁₄ of the differential amplifier 4 are held by the peak value holding circuits 5 and 6. The voltage follower circuit 7 outputs the midpoint voltage V ₁₆ of the positive output and the negative output of the differential amplifier 4. The differential amplifier circuit 8 outputs the median value V ₂₃ of the amplitudes of V ₁₆ , V ₁₉ , V ₂₀ to V ₁₃ , and the pulse discrimination comparator 9
As a reference voltage.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical pulse receiving circuit for an optical communication device which transmits digital information by an optical pulse.

[0002]

2. Description of the Related Art In an optical communication device for transmitting digital information by an optical pulse, an optical pulse receiver has been used as a conventional technique for converting a received optical pulse into an electric pulse by a photoelectric conversion element and shaping the waveform. 58-114637) is known. FIG. 3 shows an example of this conventional optical pulse receiving circuit. In the figure, 1 is a light receiving element for receiving a transmitted optical pulse and converting it into an electric pulse, 2
Is a preamplifier for amplifying the signal of the light receiving element 1, 3 is a comparator for comparing the electric signal S ₂ of the output of the preamplifier ₂ with the reference voltage Vr, and reproducing and outputting as an output signal S ₃ , and 14 is a preamble peak value holding circuit for detecting and holding a maximum value V _P of the output signal S ₂ of the amplifier 2, bottom value holding circuit 15 for detecting and holding a minimum value V _B of the output signal S ₂ of the preamplifier 2, 4 variable resistor for setting the reference voltage Vr from the output voltage V _B of the output voltage V _P and the bottom value hold circuit 15 of the peak value hold circuit 14, 5 is a noise preventing capacitor.

In the above conventional optical pulse receiving circuit, the peak value holding circuit 14 is composed of a diode 6, a capacitor 7, a resistor 8 and an operational amplifier 9, and the bottom value holding circuit 15 is a diode 10, a capacitor 11 and a resistor. 12 and operational amplifier 13. The peak value hold circuit 14 accumulates the peak value of the output voltage S ₂ of the preamplifier 2 in the capacitor 7 through the diode 6 and outputs this voltage V _P to the variable resistor 4 through the operational amplifier 9 which operates as a buffer amplifier. Supply at one end.

Similarly, the bottom value hold circuit 15 outputs the bottom value of the output voltage S ₂ of the preamplifier 2 to the diode 10.
This voltage V _B is stored in the capacitor 11 via the operational amplifier 13 which operates as a buffer amplifier, and is supplied to the other end of the variable resistor 4. And V at each end
_An intermediate voltage is supplied as a reference voltage Vr to the comparator 3 from the variable resistor 4 to which _P and V _B are added, and the reference voltage Vr and the output voltage S ₂ of the preamplifier ₂ are compared, and depending on the magnitude thereof. Two binary voltages are obtained as the pulse output of the comparator 3.

[0005]

However, in the peak value hold circuit of the conventional optical pulse receiving circuit, when common mode noise such as power supply noise as shown in FIG. 4 occurs, the peak value of the noise is held. Therefore, there is a problem that the reference voltage of the comparator is deviated and the comparator is susceptible to common-mode noise such as no response even though the optical pulse is received.

In view of the above problems, an object of the present invention is to eliminate common-mode noise due to temperature drift, power supply fluctuation, etc. by using a circuit configuration in which the circuit from the photoelectric conversion circuit to the comparator for discriminating the pulse level is completely symmetrical. An object is to provide an optical pulse receiving circuit with improved characteristics.

[0007]

In order to solve the above problems, the present invention has the following constitution. That is, the first invention described in claim 1 is a first differential amplifier in which a pulse signal obtained by photoelectrically converting an optical pulse is connected to one input, and a reference potential is connected to the other input; A first peak value hold circuit for holding a positive output peak value of the differential amplifier, a second peak value hold circuit for holding a negative output peak value of the first differential amplifier, and the positive output Of the positive output amplitude of the first differential amplifier based on the peak value of the negative output and the peak value of the negative output, and a positive output of the first differential amplifier. An optical pulse receiving circuit, comprising: a comparator for comparing the detected 1/2 amplitude.

According to a second aspect of the present invention, the output voltage of the first peak value hold circuit and the output voltage of the second peak value hold circuit are the output voltage of the first peak value hold circuit. And a half point voltage of the positive and negative outputs of the first differential amplifier is added to the second differential amplifier.

[0009]

With the above structure, the optical pulse receiving circuit of the present invention becomes a completely symmetrical shape over the entire circuit structure from the photoelectric conversion circuit to the comparator, and in-phase noise is sufficiently suppressed,
An optical pulse receiving circuit having high noise resistance against common mode noise can be obtained.

[0010]

Embodiments of the present invention will now be described in detail with reference to the drawings. FIG. 1 is a circuit explanatory diagram showing an embodiment of an optical pulse receiving circuit according to the present invention. In FIG. 1, the optical pulse receiving circuit of the present invention comprises a photodiode 1, photocurrent amplifiers 2 and 3, a first differential amplifier circuit 4, first and second optical amplifiers.
Peak value hold circuits 5 and 6, a voltage follower circuit 7, a second differential amplifier circuit 8, a comparator 9,
It consists of resistors 11, 12, 15 to 20. The photodiode 1 is a light receiving device that receives a light pulse and converts it into a current. The photocurrent amplifiers 2 and 3 are amplifiers having the same characteristics. The differential amplifier 4 has two transistors 21 and 22 whose emitters are connected to each other and have the same characteristics.
And a constant current source 23 for supplying a constant current to the emitters of the transistors 21 and 22, and collector resistors 13 and 14 of the respective transistors.

The peak value hold circuits 5 and 6 are circuits having the same configuration, and the peak value hold circuit 5 is connected to the collector of one of the transistors 21 constituting the differential amplifier 4 and is connected to the positive amplifier of the differential amplifier circuit 4. The peak value of the output V ₁₃ is held and the peak value voltage V ₁₉ is output. The peak value hold circuit 6 is connected to the collector of the other transistor 22 constituting the differential amplifier 4, holds the peak value of the negative output V ₁₄ of the differential amplifier circuit 4, and outputs the peak value voltage V ₂₀ . The peak value hold circuit 5 includes a differential amplifier 24.
, A diode 25, a capacitor 26, and a voltage follower circuit 27. Similarly, the peak value hold circuit 6 includes a differential amplifier 28, a diode 29, a capacitor 30, and a voltage follower circuit 31. Since the internal connection of the peak value hold circuits 5 and 6 is the same as that of the conventional peak value hold circuit, the description of the internal connection is omitted.

The positive output V ₁₃ and the negative output V ₁₄ of the first differential amplifier circuit 4 are connected to resistors 15 and 16 having the same value and connected in series. At the point, the midpoint potential (V
₁₅ = (V ₁₃ + V ₁₄ ) / 2) appears. Then, this midpoint potential (V ₁₅ ) is input to the voltage follower circuit 7,
The output of the voltage follower circuit 7 has V ₁₆ equal to V _15.
Is output.

A differential amplifier circuit 8 which is a second differential amplifier circuit.
The output voltage V _{19 of} the first peak value hold circuit 5 is connected to the positive input of the via the resistor 17, and the output V ₁₆ of the voltage follower circuit 7 is connected via the resistor 19. The output voltage V _{20 of} the second peak value hold circuit 6 is connected to the negative input of the differential amplifier circuit 8 which is the second differential amplifier circuit via the resistor 18, and The output V _{23 of} 8 itself is connected via a resistor 20.

Between the resistors ₁₇ , ₁₈ , ₁₉ , ₂₀ connected to the inputs of the differential amplifier circuit 8, when the respective resistance values are R ₁₇ , R ₁₈ , R ₁₉ , R _20. , R ₁₇ = R ₁₈ and R ₁₉ = R ₂₀ are selected and used, the input and output voltages of the differential amplifier circuit 8 are:

[Equation 1] The relationship shown in Expression 1 is established. Here, further, R ₁₇ = R ₁₈
If the resistance value is selected so that = 2 × R ₁₉ = 2 × R ₂₀ , the gain of the differential amplifier circuit 8 becomes 1/2, and if V ₁₆ = Vref,

[Equation 2] Equation 2 is obtained.

Next, the circuit operation will be described in detail with reference to FIG. 2 showing operation waveforms of the optical pulse receiving circuit of the present invention.
FIG. 2A shows an optical input waveform with a duty ratio of 50%. FIG. 2B is a waveform of the output voltage V ₁₁ of the photocurrent amplifier 2 which amplifies the photocurrent of the photodiode 1. Figure 2
(C) is a waveform of the output voltage V ₁₂ of the photocurrent amplifier 3 which generates the reference voltage of the differential amplifier circuit 4. Figure 2 (d) shows
Waveforms at various parts of the circuit diagram of FIG. 1, V ₁₃ , V ₁₄ , V ₁₆ (Vre
f), V ₁₉ and V ₂₀ are shown superimposed. As shown in FIG. 2, when the pulse period of the incident light becomes short, the output voltages V ₁₃ and V ₁₄ of the differential amplifier circuit 4 cannot accurately follow the change of the input pulse. At this time, the bottom value of the positive output V ₁₃ of the differential amplifier circuit 4 does not return to the level Vref when there is no signal.
It is necessary that the comparison voltage V ₂₃ of 1 is 1/2 of the output amplitude of the differential amplifier circuit 4.

In FIG. 2, the positive output V of the differential amplifier circuit 4
_Since the midpoint voltage between ₁₃ and the negative output V ₁₄ is V ₁₆ (Vref), the value V ₁₉ that holds the peak value of the positive output V ₁₃ and the value V ₂₀ that holds the peak value of the negative output V ₁₄ are V _When the difference between the bottom voltage of ₁₃ and V ₁₆ (Vref) is Va and the amplitude of V ₁₃ is Vb,

[Equation 3] Equation 3 is obtained, and when this relationship is substituted into Equation 2, Equation 4 is obtained.

[Equation 4] Therefore, the comparator 9 outputs the output V ₁₃ of the differential amplifier circuit 4.
It is possible to compare the voltage of ½ of the amplitude of 1 with the output voltage V ₁₃ of one side of the differential amplifier circuit 4. As a result, the output pulse of the comparator 9 can follow the input optical pulse even if the repetition frequency of the input optical pulse increases. Moreover, the photodiode 1 that receives the incident light
From the circuit arrangement to the reference voltage V ₂₃ of the comparator 9 is made has become all complete symmetrical, and temperature drift due to ambient temperature changes, the influence of supply voltage fluctuations, the common mode rejection of the differential amplifier circuit Sufficiently removed depending on the characteristics.

[0017]

As described above, according to the present invention, the potential of 1/2 of the peak-peak value (amplitude value) of the signal obtained by photoelectrically converting the received optical pulse is used as the comparison reference potential of the comparator. In the pulsed light receiver circuit, the circuit configuration from the photodiode that receives the incident light to the reference voltage of the comparator that determines the pulse level is completely symmetrical, and an optical pulse receiver circuit with high common-mode noise removal performance is provided. There is an effect that it can be provided.

[Brief description of drawings]

FIG. 1 is a circuit explanatory diagram showing a configuration of an embodiment of an optical pulse receiving circuit according to the present invention.

FIG. 2 is a waveform chart of each part for explaining the operation of the embodiment of the present invention.

FIG. 3 is a circuit diagram showing a configuration of a conventional optical pulse receiving circuit.

FIG. 4 is a waveform diagram illustrating a malfunction caused by common-mode noise in a conventional example.

[Explanation of symbols]

 1 Photodiode 2, 3 Photocurrent amplifier 4 Differential amplification circuit 5, 6 Peak value hold circuit 7 Voltage follower circuit 8 Differential amplification circuit 9 Comparator 11-20 Resistors 24, 27, 28, 31 Differential amplification circuit 25, 29 Diode 26, 30 Capacitor

Continuation of the front page (51) Int.Cl. ⁶ Identification code Office reference number FI technical display location H04B 10/04 10/06 10/02 10/18 H04L 25/03 E 9199-5K 25/06 9199-5K

Claims (2)

[Claims] 1. A first differential amplifier having a pulse signal obtained by photoelectrically converting an optical pulse connected to one input and a reference potential connected to the other input; and a positive output of the first differential amplifier. A first peak value hold circuit for holding a peak value, a second peak value hold circuit for holding a negative output peak value of the first differential amplifier, a positive output peak value and a negative output Amplitude detection means for detecting an amplitude of 1/2 of the positive output amplitude of the first differential amplifier based on the peak value, and a positive output of the first differential amplifier and the detected 1/2
An optical pulse receiving circuit comprising: a comparator for comparing the amplitude of the optical pulse. 2. The amplitude detection means according to claim 1, wherein a half of a difference between an output voltage of the first peak value hold circuit and an output voltage of the second peak value hold circuit, 2. An optical pulse receiving circuit, which is a second differential amplifier for adding the midpoint voltage of the positive and negative outputs of the first differential amplifier.