JP4056927B2 - Optical transmitter and method for determining its fixed bias current - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical transmitter used in the field of optical communications and a method for determining a fixed bias current thereof.
[0002]
[Prior art]
As a conventional optical transmitter, a modulation current corresponding to input data from a laser driver is supplied to the laser diode, and a bias current is supplied from the bias current source to the laser diode. In the laser diode, an optical output corresponding to the input data is provided. Send with.
In the photodiode, the light output is converted into a current signal, the current signal is converted into a voltage signal by a preamplifier, the peak value of the voltage signal is held by a peak detector, and the peak of the voltage signal is stored in the bias current controller. The magnitude of the bias current supplied from the bias current source to the laser diode is controlled so that the value becomes constant.
In this way, by controlling the bias current in a feedback manner, the extinction ratio remains constant even if there are manufacturing variations in the laser diode, the ambient temperature of the laser diode changes, and the current-to-light output characteristics of the laser diode change. An optical transmitter can be obtained (see, for example, Patent Document 1).
[0003]
[Patent Document 1]
Japanese Patent Laid-Open No. 2000-269897
[Problems to be solved by the invention]
Since the conventional optical transmitter is configured as described above, the bias current is feedback-controlled. Therefore, a photodiode, a preamplifier, a peak detector, a bias current controller, etc. must be provided, and the number of parts is reduced. It becomes more expensive and expensive.
In addition, in the inspection stage after manufacturing the optical transmitter, the bias current from the bias current source must be adjusted together with the modulation current from the laser driver so that the laser diode outputs light at a specified level. There is a problem that it is difficult to simplify the light output adjustment work.
[0005]
The present invention has been made to solve the above-described problems. The number of components is reduced and the light output adjustment is simplified, and the light output waveform satisfying the pulse mask standard and the extinction ratio standard is generated from the laser diode. It is an object to obtain an optical transmitter and a method for determining a fixed bias current thereof.
[0006]
[Means for Solving the Problems]
An optical transmitter according to the present invention includes a bias current source that provides a predetermined optimum fixed bias current that satisfies a pulse mask standard and an extinction ratio standard with respect to manufacturing variations of a laser diode to the laser diode. is there.
[0007]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of the present invention will be described below.
Embodiment 1 FIG.
FIG. 1 is a block diagram showing an optical transmitter according to Embodiment 1 of the present invention, in which a modulation current driving circuit 2 converts a modulation current Imod according to a digital signal input from a data input terminal 1. The modulation current Imod is given to the laser diode 3.
The bias current source 4 supplies the laser diode 3 with a predetermined optimal fixed bias current Ib that satisfies the pulse mask standard and the extinction ratio standard with respect to manufacturing variations of the laser diode 3.
The temperature compensator 5 detects the ambient temperature of the laser diode 3, and changes the temperature of the modulation current Imod supplied from the modulation current driving circuit 2 so that the extinction ratio of the laser diode 3 becomes constant even if the ambient temperature changes. In addition to compensating, the temperature of the fixed bias current Ib applied from the bias current source 4 is compensated.
[0008]
Next, the operation will be described.
In FIG. 1, a digital signal is input from a data input terminal 1 to a modulation current drive circuit 2, and the modulation current drive circuit 2 converts it into a modulation current Imod corresponding to the digital signal. In the bias current source 4, an optimum fixed bias current Ib that satisfies the pulse mask standard and the extinction ratio standard is determined in advance with respect to manufacturing variations of the laser diode 3 by a fixed bias current determination method described later. These modulation current Imod and fixed bias current Ib are given to the laser diode 3 to drive the laser diode 3.
[0009]
Next, a method for determining the fixed bias current will be described.
FIG. 2 is a characteristic diagram showing the current vs. optical output characteristics of a laser diode. In the figure, the horizontal axis represents drive current and the vertical axis represents optical power.
In the figure, the laser diode emits little light with respect to the drive current up to the threshold current Ith, and thereafter the optical power increases linearly with a certain slope efficiency. Due to such characteristics of the laser diode, it is ideal to set the bias current Ib to the same value as the threshold current Ith. In that case, optical power of the level of DATA0 to DATA1 shown in the figure is generated according to the modulation current Imod. The ratio between the optical power of DATA0 and the optical power of DATA1 is called the extinction ratio.
However, since laser diodes have manufacturing variations in individual current-to-light output characteristics, the threshold current Ith also varies. Therefore, when the bias current Ib is a fixed current, it is necessary to determine an optimum value in consideration of manufacturing variations in the current vs. optical output characteristics of the laser diode.
[0010]
In order to obtain the optimum value of the bias current Ib, the following equation (1) is used.
Td = τn × ln {Imod / (Imod + Ib−Ith)} (1)
However, Td is an oscillation delay time, τn is a carrier lifetime, Imod is a modulation current, Ib is a bias current, and Ith is a threshold current.
Here, the oscillation delay time Td is a delay time from when a current is supplied to the laser diode to when light is emitted. FIG. 3 is an explanatory diagram showing the oscillation delay time of the laser diode. When a current of I> Ith is passed through the laser diode as shown in FIG. 3, laser oscillation (light emission) occurs after time Td. This is called the oscillation delay time. Since such an oscillation delay is undesirable in optical transmission, the delay time is shortened by supplying a bias current Ib to the laser diode.
The carrier lifetime τn is one of the parameters indicating the physical properties of the semiconductor, and is the time required for recombination of electrons or holes. In the above equation (1), it is treated as a constant (predetermined value). .
[0011]
Next, the following equations (2) to (4) are substituted into the above equation (1) to perform deformation.
Iop = Imod + Ib (2)
a = Ib / Ith (3)
α = Ith / Iop (4)
The equation after the deformation is the following equation (5).
Td = τn × ln {(1-aα) / (1-α)} (5)
Where Iop is the laser diode operating current, a is the ratio of the bias current Ib to the threshold current Ith (hereinafter referred to as bias current ratio), and α is the ratio of the threshold current Ith to the laser diode operating current Iop.
[0012]
In the above equation (5), an allowable range value based on the pulse mask standard is set for the oscillation delay time Td, a predetermined value is set for the carrier lifetime τn, and the ratio α between the threshold current Ith and the laser diode operating current Iop is If the worst value (maximum value) obtained by the inspection of the current vs. optical output characteristic is substituted, the above equation (5) becomes an equation with only the unknown bias current ratio a, and therefore the allowable range of the oscillation delay time Td from the equation. The minimum value of the bias current ratio a satisfying the value is calculated (bias current ratio minimum value calculating step).
Here, the pulse mask indicates an optical output waveform. FIG. 4 is an explanatory diagram showing a pulse mask and a pulse mask standard. For example, a waveform as shown in the figure is called a pulse mask, and a mask such as an upper and lower rectangle and a central hexagon is called a pulse mask standard. The pulse mask must not cover the mask of the pulse mask standard.
FIG. 5 is an explanatory diagram showing the relationship between the allowable range value of the oscillation delay time and the pulse mask standard. In order to prevent the rising edge of the pulse mask from covering the mask of the pulse mask standard, the rising edge of the pulse mask is Since it suffices to exist between the dotted line A and the dotted line B, in this case, the oscillation delay of the time interval indicated by the arrow C can be obtained as an allowable range value.
Further, the worst value of the ratio α between the threshold current Ith and the laser diode operating current Iop is that the oscillation delay time Td increases when the laser diode operating current Iop is a fixed value and the threshold current Ith is large. This indicates the maximum value of Iop. Since the threshold current Ith and the laser diode operating current Iop are inspected for current-to-light output characteristics at the time of manufacturing the laser diode, the ratio α can be obtained. In the inspection at the time of manufacture, laser diodes having a ratio α equal to or higher than the worst value are excluded as defective.
[0013]
Next, using the threshold current maximum value Ith (Max) and the threshold current minimum value Ith (min) due to manufacturing variation of the threshold current Ith obtained by the inspection of the current vs. optical output characteristics at the time of manufacturing the laser diode, the following equation (6) The bias current Ib satisfying (7) is obtained and determined as the optimum fixed bias current Ib satisfying the pulse mask standard and the extinction ratio standard with respect to the manufacturing variation of the laser diode (fixed bias current determining step).
Ib = a × Ith (Max) (6)
Ib <Ith (min) (7)
Here, the above equation (6) is a conditional equation that satisfies the pulse mask standard with respect to manufacturing variations of laser diodes. This is because the minimum value of the bias current ratio a is obtained from the allowable range value of the oscillation delay time Td that satisfies the pulse mask standard.
Further, the above expression (7) is a conditional expression that satisfies the extinction ratio standard. In general, when Ib ≧ Ith, the extinction ratio deterioration becomes larger as compared with Ib <Ith. This is because the extinction ratio is determined by the ratio of the light output between data high and data low. As can be seen from the current-to-light output characteristics, the laser diode emits light at the threshold current Ith as a boundary. When Ib ≧ Ith, light is emitted even at low data, so the extinction ratio becomes small. Therefore, the condition of Ib <Ith is set to prevent extinction ratio deterioration.
The reason why the maximum value Ith (Max) and the minimum value Ith (min) are used as the threshold current Ith is because manufacturing variation in the current-to-light output characteristics of the laser diode is taken into consideration.
[0014]
In this way, the optimum fixed bias current Ib that satisfies the pulse mask standard and the extinction ratio standard with respect to the manufacturing variation of the laser diode is determined and applied from the bias current source 4 to the laser diode 3.
Further, in FIG. 1, the temperature compensator 5 detects the ambient temperature of the laser diode 3. Here, the laser diode 3 has a current-to-light output characteristic that changes due to a change in its ambient temperature. In the temperature compensator 5, even if its ambient temperature changes and the current-to-light output characteristic changes, The modulation current Imod supplied from the modulation current driving circuit 2 is temperature compensated so that the extinction ratio of the laser diode 3 is constant, and the fixed bias current Ib supplied from the bias current source 4 is temperature compensated.
[0015]
As described above, according to the first embodiment, the optimum fixed bias current Ib determined in advance that satisfies the pulse mask standard and the extinction ratio standard with respect to the manufacturing variation in the current-to-light output characteristic of the laser diode 3 is obtained. Since the bias current source 4 applied to the laser diode 3 is provided, the number of parts does not increase as in the case of feedback control of the bias current, and the number of parts can be reduced and the configuration can be reduced.
Further, since the fixed bias current Ib is determined in advance, it is not necessary to adjust the bias current source 4 in the inspection stage after manufacturing the optical transmitter, and the optical output adjustment can be simplified.
Furthermore, an optical output waveform that satisfies the pulse mask standard and the extinction ratio standard can be obtained from the laser diode 3.
Furthermore, an optical transmitter suitable for a continuous mode optical transmitter that performs data transmission continuously on the time axis can be obtained.
Furthermore, even if the ambient temperature of the laser diode 3 changes and the current-to-light output characteristic of the laser diode 3 changes, the temperature of the modulation current Imod and the fixed bias current Ib is compensated for, and the extinction ratio of the laser diode 3 is kept constant. can do.
[ 0016 ]
【The invention's effect】
As described above, according to the present invention, there is provided a bias current source that provides the laser diode with a predetermined optimum fixed bias current that satisfies the pulse mask standard and the extinction ratio standard with respect to manufacturing variations of the laser diode. Thus, the number of parts does not increase as in the case of feedback control of the bias current, and the number of parts can be reduced and the structure can be reduced.
Further, since the fixed bias current is determined in advance, it is not necessary to adjust the bias current source in the inspection stage after manufacturing the optical transmitter, and the optical output adjustment can be simplified.
Furthermore, an optical output waveform that satisfies the pulse mask standard and the extinction ratio standard can be obtained from the laser diode.
Furthermore, there is an effect that an optical transmitter suitable for a continuous mode optical transmitter that continuously performs data transmission on a time axis can be obtained.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an optical transmitter according to a first embodiment of the present invention.
FIG. 2 is a characteristic diagram showing current versus light output characteristics of a laser diode.
FIG. 3 is an explanatory diagram showing an oscillation delay time of a laser diode.
FIG. 4 is an explanatory diagram showing a pulse mask and a pulse mask standard.
FIG. 5 is an explanatory diagram showing a relationship between an allowable range value of an oscillation delay time and a pulse mask standard.
[Explanation of symbols]
1 data input terminal, 2 modulation current drive circuit, 3 laser diode, 4 bias current source, 5 temperature compensator.

Claims (2)

A modulation current drive circuit that converts the modulation current according to the input data and gives the modulation current to the laser diode;
An optical transmitter comprising: a bias current source that applies a predetermined optimal fixed bias current that satisfies a pulse mask standard and an extinction ratio standard with respect to manufacturing variations of the laser diode to the laser diode. In the relational expression consisting of the oscillation delay time of the laser diode used in the optical transmitter, the carrier lifetime, the modulation current and bias current for driving the laser diode, and the threshold current of the laser diode, the oscillation delay time is based on the pulse mask standard. The maximum value obtained by examining the current-to-light output characteristics at the time of manufacturing the laser diode, the allowable range value, the default value for the carrier lifetime, and the ratio of the threshold current to the laser diode operating current obtained by adding the bias current to the modulation current. And a bias current ratio minimum value calculating step for calculating the minimum value of the ratio between the bias current and the threshold current,
The ratio of the bias current to the threshold current calculated in the above bias current ratio minimum value calculation step is calculated from the threshold current maximum value and the threshold current minimum value due to manufacturing variation obtained by inspection of the current-to-light output characteristics at the time of manufacturing the laser diode. Calculate the product of the minimum value and the threshold current maximum value, and when the product is smaller than the threshold current minimum value, the product satisfies the pulse mask standard and extinction ratio standard with respect to the manufacturing variation of the laser diode. A fixed bias current determining method for an optical transmitter, comprising: a fixed bias current determining step for determining a fixed bias current.

Images