JP2017153068A5 - - Google Patents

Description

The control unit 405 drives the first and second SOAs 201 and 202 with the control setting as (X _i , Y _j ). Here, the control settings (X _i , Y _j ) are gains set in the first and second SOAs 201 and 202.

First, the control unit 405, a _{i = 0, Y j = 0} , sets a predetermined initial value _{X i.} The control setting is (X _i , 0) (step S102). Here, Y _j = 0 means that the gain in the second SOA 202 is zero. That is, since no current flows through the second SOA 202, there is no output or only a small light output.

Through the above processing, control settings (X _i , Y _j ) that are gains of the first and second SOAs 201 and 202 are determined (step S110).

<Embodiment 3>
<Configuration>
In the optical transmitter according to the third embodiment, the optical transmitter and the optical transceiver 700 are optically interconnected via a transmission path such as an optical fiber, and the code error rate is transmitted from the optical transceiver 700 via the transmission path. it is possible to obtain a: (BER bit erro r rate) information about.

The control unit 603 drives the first and second SOAs 201 and 202 with the control setting as (Z _i , Z _i ). Here, the control settings (Z _i , Z _i ) are gains set in the first and second SOAs 201 and 202. First, the control unit 603 sets i = 0 to a predetermined initial value for Z _i (step S202). The reason for setting the first gain of the second SOA201,202 commonly performs rough gain adjustment in step S205 from the step S 203 to be described later, first at step S211 from the subsequent step S206, the This is because the time required for gain adjustment is shortened by finely adjusting the gains of the two SOAs 201 and 202.

In step S 2 05, counts up the i (i = i + 1) , the control unit 603 up and down the value of a common gain _{Z i} to the first, second SOA201,202, BER becomes smaller control Find the setting (Z _i , Z _i ). Then, the _{B i} by measuring the BER at step S203 again. In step S <b> 204 again, the control unit 603 determines whether B _i is greater than or equal to B _i−1 . FIG. 7 is a diagram illustrating the relationship between BER (B _i ) and control setting count. For example, if i = 1, B ₀ is compared with B ₁ in step S204 to determine whether B ₁ is equal to or greater than B ₀ . In FIG. 7, since B ₁ is not _{equal to} or greater than B ₀ , the process proceeds to step S 205 again.

In step S207, j is counted up (j = j + 1), and the control unit 603 raises and lowers the values of the control settings (X _j , Y _j ) of the first and second SOAs 201 and 202 by a specified interval, and BER. Find the control setting (X _j , Y _j ) where becomes smaller. Then, as in step S203 , the BER is measured and set to B _j (step S208).

In step S210, j is counted up (j = j + 1), and the control unit 603 individually raises and lowers the control settings (X _j , Y _j ) of the first and second SOAs 201 and 202, and the BER is increased. Find a smaller control setting (X _j , Y _j ). Then, the _{B j} by measuring the BER at step S208 again. In step S209, the control unit 603 determines again whether B _j is greater than or _equal to B _j-1 .

When the control unit 603 determines in step S209 that B _j is greater than or equal to B _{j −1} , the control setting that gives the smallest BER is determined to be (X _j−1 , Y _j−1 ) (step S211).

Therefore, by changing the gains of the first and second SOAs 201 and 202 in a periodic manner and resetting the gain to a more appropriate value based on the detection value of the optical transceiver 700 , the first, Even when the performance of the second SOAs 201 and 202 changes with time, it is possible to continue to set an appropriate gain.

Therefore, by changing the gains of the first and second SOAs 201 and 202 in a periodic manner and resetting the gain to a more appropriate value based on the detection value of the optical transceiver 700 , the first, Even when the performance of the second SOAs 201 and 202 changes with time, it is possible to continue to set an appropriate gain.

Next, the control unit 904 sets the control setting for the first and second SOAs 201 and 202 to (0, Y _j ) (corresponding to step S106 in FIG. 4). Here, as the initial value of X _i, a smaller value is set than the target gain G2. Next, in the control setting (0, Y _j ), the third detector 903 detects the light output intensity of the third optical multiplexing / demultiplexing unit 803 to obtain a detection value YP (corresponding to step S107 in FIG. 4). . Here, since the first SOA 201 has no output, the optical output intensity of the third optical multiplexing / demultiplexing unit 803 can be regarded as the optical output intensity of the second SOA 202.

Next, the control unit 904 determines the gain Y _j of the second SOA 202 by performing feedback control from step S107 to step S109 in FIG. The determined gain Y _j of the second SOA 202 is equal to or less than the target gain G2.

Through the above processing, the control settings (X _i , Y _j ) that are the gains of the first and second SOAs 201 and 202 are determined (corresponding to step S110 in FIG. 4).

Images