JP3127546B2 - Optical transmission circuit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical transmitter for transmitting an optical signal using a lithium niobate optical modulator (hereinafter abbreviated as LN modulator).

[0002]

2. Description of the Related Art With the advance of optical transmission technology, studies on ultra-high-speed optical transmission technology using a long wavelength band optical device and a single mode fiber have been studied as a possibility of a large capacity long distance transmission system. In order to realize a broadband information communication network that provides a wide variety of services including data, voice, and the like, speeding up and stable practical use of an optical transmission device are expected. The transmission capacity of the backbone transmission system in such a broadband information communication network reaches several gigabits / second in a time division multiplex transmission system, and an optical transmission / reception device is also required to have a wide band and high speed.

The basic function of an optical regenerator is (1)
Waveform shaping (reshaping) by equalization amplification,
These are roughly classified into three "R" of (2) retiming, and (3) identification reproduction. (See, for example, "Optical Fiber Communication" Telecommunications Technology News.) In particular, for an optical transmitter having a regenerative function, an optical modulation means having an ultra-high-speed and long-distance transmission capability is required. A lithium niobate optical modulator (LN modulator) having a small ping and excellent in long-distance transmission is used as an optical modulator in an optical transmitter, and its applicability has reached the 10 Gbps range. (For example, "10
Jitter characteristics of Gb / s regenerative repeater "(See the paper B-955 of the 1991 IEICE Spring National Convention). As an optical transmitter using an LN modulator, the configuration shown in FIG. The data signal applied to the data input terminal 10 is transmitted to the LN modulator 2 by the optical modulator driving circuit 1.
Is amplified to the signal amplitude necessary to drive the signal. LN
Although the drive voltage of the modulator 2 has a trade-off with the transmission speed, 3 to 6 (V) is required at a transmission speed of 10 Gbps . Therefore, it is difficult to convert the optical modulator drive circuit 1 into an IC in the state of the art from the viewpoint of the IC breakdown voltage. Therefore, at present, the optical modulator driving circuit 1 is configured by a hybrid circuit using discrete transistors and employing AC coupling from the viewpoint of stability.

The optical modulator drive circuit 1 has, for example, a multi-stage configuration of a field effect transistor Q as shown in FIG. Adopt AC coupling type as circuit coupling type,
The operating point voltage of each transistor is fixedly set to an appropriate value, and a good and large amplitude signal is secured as a final result.

The signal output from the light modulation drive circuit 1 is
The voltage is applied to the input terminal of the LN modulator 2 by AC coupling.
The termination terminal of the LN modulator 2 has a termination resistance R of, for example, 50Ω.
_L is connected and AC grounded by a capacitor C. The offset bias _Vb to the LN modulator 2 is applied via a terminating resistor _RL . This offset bias _Vb is the average level of the signal input from the optical modulator drive circuit 1.

[0006]

As described above, L
In the conventional optical transmitter using the N modulator, the offset bias to the LN modulator 2 is supplied independently of the state of the data signal. Therefore, when the mark rate of the data signal (the occurrence rate of the signals “1” and “0”) changes from, for example, ２ to ８, the signal application state to the LN modulator 2 changes, The optical signal transmitted from the optical transmitter has a problem that, for example, waveform distortion, a decrease in optical signal level, and the like occur.

Also, large signal amplitude (for example, 3 to 6 V amplitude)
Is supplied to the LN modulator 2, the configuration itself of the optical modulator drive circuit 1 is an AC coupling circuit. Therefore, when the mark ratio fluctuates as described above, the output signal itself of the optical modulator drive circuit 1 has waveform distortion. the resulting, consequently cause deterioration in the output signal of the optical transmitter, there are atmospheric problems that the transmission function can not be secured.

[0008]

[0009]

SUMMARY OF THE INVENTION An optical transmitter according to the present invention is an optical transmission circuit for transmitting an optical signal to an optical fiber transmission line using a lithium niobate optical modulator. A flip-flop circuit for performing waveform shaping, a modulator drive circuit for amplifying one output signal of the flip-flop circuit and supplying the drive signal as a drive data signal to the lithium niobate optical modulator, and a flip-flop circuit for the lithium niobate optical modulator. A terminating resistor for terminating the input terminal electrode, a capacitor connected between the terminating resistor and ground, a peak value detecting circuit for receiving another output signal of the flip-flop circuit and detecting a peak value level thereof; A DC amplifier for comparing an output voltage of the peak value detection circuit with a set voltage, and control by a comparison output voltage of the DC amplifier. A bias supply source for applying a DC bias according to a result of the peak value detection to a connection point between the terminating resistor and the capacitor; and a light output driving circuit controlled by a comparison output voltage of the DC amplifier to supply the peak value to the light modulation drive circuit. An offset bias supply circuit for supplying an operating point bias according to the detection result.

[0010]

[0011]

According to the present invention , a mark ratio of a data signal input to an optical transmitter is detected, and an offset bias suitable for the mark ratio is supplied to an optical modulator drive comprising an LN modulator and an AC coupling circuit. By supplying the signal to the circuit, a signal having a large amplitude and no waveform distortion can be supplied to the LN modulator. As a result, a mark ratio can be handled as an output signal of the optical transmitter, and a decrease in the transmission function is avoided. Can do things.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing an embodiment of the first invention of the present invention, wherein reference numeral 1 denotes an optical modulator driving circuit,
2 is an LN modulator, 3 is a flip-flop circuit (F /
F), 4 is a peak value detection circuit, 5 is a DC amplifier, 6 is a bias supply source, _RL is a terminating resistor, C is a capacitor, 9 is an optical fiber transmission line, 10 is a data signal input terminal, 11
Indicates an input terminal of the clock signal.

The data signal applied to the input terminal 10 is
The waveform is shaped at the timing of the clock signal input to the input terminal 11 in the flip-flop circuit 3. As the flip-flop circuit 3, one that operates in an ultra-high speed region of 10 Gbps or more in recent years is a GaAs-I
It is being realized by C and si-IC. As an output signal level of such a flip-flop circuit 3, an ECL level (0.8V to 1.0V output) is generally used. On the other hand, the drive voltage amplitude of the LN modulator 2 is, for example, 10
For a transmission rate of Gbps, 3 to 6 V is required. Therefore, the output signal of the flip-flop circuit is amplified to a sufficient amplitude in the optical modulator driving circuit 1 configured by AC coupling. The amplified signal is supplied to the LN modulator 2 as in the case of the conventional circuit.

One output signal (NRZ signal) of the flip-flop circuit 3 is input to a peak value detection circuit 4 where the mark ratio of the data signal is detected. The input terminal of the peak value detection circuit 4 is normally AC-coupled to avoid the influence of DC interruption. The ratio of the number (n) of marks to the total number (N) of binary pulses (marks or spaces) input to the peak value detection circuit 4 within a certain time is called a mark rate (m = n / N). , The input pulse train is subjected to DC cutoff, so that the DC level of the input pulse train varies depending on the mark rate. Assuming that the amplitude value of the NRZ pulse is 1, the amount of fluctuation from the DC reference level (P in the positive direction,
P ′ in the negative direction), P = 1−M and p ′ = M for an arbitrary mark ratio m = M. The DC level fluctuation amount P (or p ') is equal to the peak value of the pulse measured from the DC reference level. That is, in the present invention, the peak value (P or p ′) of the pulse is detected by the peak value detection circuit 4, the detected output is amplified to an appropriate level by the DC amplifier 5, and then input to the bias supply source 6. The bias supply source 6 generates an offset bias that changes in voltage according to a change in the input voltage with reference to the optimum data offset voltage for the LN modulator 2 when the mark ratio is １ ／. By applying this offset bias to the bias input terminal of the LN modulator 2 via the terminating resistor _RL , L
Appropriate bias setting can be performed with respect to the change in the mark ratio of the data signal applied to the N modulator 2. In this case, depending on whether the peak value detection circuit 4 detects the positive peak value P or the negative peak value p ', the phase between the input and output of the DC amplifier 5 is made positive or negative. You have to choose what to do.

As described above, the data signal applied to the LN modulator 2 is compensated so that the DC level is always constant regardless of the change in the mark ratio of the data signal at this stage. . Therefore, the output optical signal of the LN modulator 2 does not have a waveform distortion or the like due to a change in the mark ratio of the data signal, so that good transmission characteristics can be secured.

FIG. 2 is a block diagram showing an embodiment of the second invention of the present invention. The basic function of this embodiment is the same as that of the first embodiment. However, in this embodiment, the mark modulation of the data signal is changed in the optical modulator driving circuit 1 with respect to the change of the mark ratio of the data signal. It is possible to respond to That is, the peak value (P or p ') of the pulse is detected by the peak value detection circuit 4 and the detected output is amplified by the DC amplifier 5 to a required level.
Bias supply source 6 and offset bias supply circuit 101
And enter The offset bias supply circuit 101
Based on the optimum data offset voltage of the amplifying transistor (for example, the field effect transistor Q in FIG. 4) when the mark ratio is 1/2, an offset bias that changes in voltage according to the change in the input voltage is generated. By applying this offset bias to the gate of the amplifying transistor via the bias application resistor R (see FIG. 4), it is possible to set an appropriate bias with respect to a change in the mark ratio of the data signal applied to the transistor.

Therefore, in the present embodiment, the output signal of the optical modulator drive circuit 1 and the output optical signal of the LN modulator 2 do not have waveform distortion or the like due to a change in the mark ratio of the data signal, and secure good transmission characteristics. You.

[0019]

As described above, according to the first aspect of the present invention, the mark ratio of the data signal input to the optical transmitter is detected, and an offset bias suitable for the mark ratio is supplied to the LN modulator. This makes it possible to cope with a change in the mark rate of the data signal. As a result, it becomes possible to cope with the mark rate using the output signal of the optical transmitter, and it is possible to avoid a decrease in the transmission function.

Further, according to the second aspect, the mark ratio of the data signal input to the optical transmitter is detected, and an offset bias suitable for the mark ratio is supplied to the LN modulator and the optical modulator driving circuit. This makes it possible to supply a signal having a large amplitude and no waveform distortion to the LN modulator,
As a result, the mark ratio can be handled by the output signal of the optical transmitter, so that the transmission function can be prevented from being deteriorated.

[Brief description of the drawings]

FIG. 1 is a block diagram of one embodiment of the first invention of the present invention.

FIG. 2 is a block diagram of one embodiment of the second invention of the present invention.

FIG. 3 is a block diagram showing a configuration of a conventional optical transmitter.

FIG. 4 is a circuit diagram showing a configuration example of an optical modulator driving circuit used in the related art and the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Optical modulator drive circuit 2 LN modulator 3 Flip-flop circuit (F / F) 4 Peak value detection circuit 5 DC amplifier 6 Bias supply source R _L terminal resistance C Capacitor 9 Optical fiber transmission line 10, 11 Input terminal 101 Offset bias Supply circuit

Continued on the front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) G02F 1/03-1/035 G02F 1/29-1/313 H04B 10/00-10/28 JICST file (JOIS) WPI (DIALOG)

Claims (1)

(57) [Claims] An optical transmission circuit for transmitting an optical signal to an optical fiber transmission line using a lithium niobate optical modulator, a flip-flop circuit for shaping a waveform of an input data signal using an input clock signal, and the flip-flop A modulator drive circuit for amplifying one output signal of the amplifier circuit and supplying the output signal to the lithium niobate optical modulator as a drive data signal; a terminating resistor for terminating an input terminal electrode of the lithium niobate optical modulator; A capacitor connected between a resistor and ground; a peak value detection circuit for receiving another output signal of the flip-flop circuit and detecting a peak value level thereof; an output voltage and a set voltage of the peak value detection circuit And a DC amplifier for comparing the terminal resistance and the capacitor, which are controlled by a comparison output voltage of the DC amplifier. A bias supply source for applying a direct current bias according to the result of the peak value detection to a connection point; and an operating point bias controlled by a comparison output voltage of the direct current amplifier and operating in the light modulation drive circuit according to the result of the peak value detection. And an offset bias supply circuit for supplying the offset bias.