JP4772476B2 - Optical receiver and method for determining discrimination threshold in optical receiver - Google Patents

Description

  The present invention relates to a method for determining an identification threshold in an optical receiver, and specifically relates to a method for obtaining an identification threshold used when an optical signal received by an optical receiver is converted into an electrical signal.

  As a technique that discloses an identification threshold value for identifying binarization of 0 or 1 used when converting an optical signal received by an optical receiver constituting an optical transmission system into an electric signal, Patent Literature 1 or Patent Document 2.

  In the technique related to Patent Document 1, a substantially U-shaped curve (including a portion where the BER becomes constant due to the measurement limit of the BER) indicating the relationship of the bit error rate (hereinafter referred to as BER) with respect to the threshold is a settable threshold. It is assumed that the entire range is spread and that an optimum discrimination threshold exists near the center of the settable threshold range. Then, approximate straight lines are drawn for the right curve portion and the left curve portion of the U-shaped curve. And based on the said premise, the intersection of the said two approximate straight lines is determined as an optimal identification threshold value.

  Here, the settable threshold range is a range determined by hardware factors of the threshold control unit provided on the optical receiver side. That is, the optical receiver cannot set a threshold value outside the settable threshold range.

  Further, the technique related to Patent Document 2 is a technique for tracking (following) an optimum identification threshold value. In other words, Patent Document 2 discloses an operation of tracking the optimum identification threshold as time elapses after the optimum identification threshold is once captured by some method.

JP 2000-341344 A JP 2003-348019 A

  As described above, in the technique related to Patent Document 1, it is confirmed that the U-shaped curve extends over the entire settable threshold range, and that the optimum identification threshold exists near the center of the settable threshold range. It is assumed. That is, this matter is based on the premise that the quality of the signal (transmission) does not deteriorate in the optical transmission line.

  Therefore, when the signal quality deteriorates in the optical transmission line, the technique according to Patent Document 1 cannot identify the position of the U-shaped curve and can no longer draw the approximate straight line of the U-shaped curve. Patent Document 1 does not disclose how to draw the approximate line when signal quality deteriorates in the optical transmission line.

  Therefore, ultimately, when the signal quality deteriorates in the optical transmission line (this is because the signal is deteriorated in the optical transmission line and the optimum discrimination threshold is greatly deviated from the settable threshold range. ), It is impossible to determine the optimum discrimination threshold with the technique according to Patent Document 1.

  Note that the technique related to Patent Document 2 is a technique related to an operation after an optimal identification threshold value is once determined. Therefore, in the situation where the optimum discrimination threshold is not specified at first, the technique according to Patent Document 2 does not exhibit its effect.

  Therefore, the present invention is an invention for determining an optimum discrimination threshold, and even if signal quality degradation occurs in an optical transmission line, an discrimination threshold determination method in an optical receiver capable of determining an optimum discrimination threshold. The purpose is to provide.

In order to achieve the above object, an optical receiver according to the present invention includes a light receiving unit that receives an optical signal, and a threshold control unit that determines an identification threshold used when the optical signal is converted into a binary electric signal. The threshold control unit sets (a) any threshold existing within a settable threshold range in the optical receiver as a first threshold, and (b) the first A first bit error rate (hereinafter referred to as BER) with respect to the threshold value is obtained, (c) a second threshold value that is changed by a predetermined threshold width with respect to the first threshold value is set, and (d) the second threshold value is set. And (e) the relationship between the threshold value and the BER in the received optical signal based on the magnitude relationship of the first BER, the second BER, and a preset initial threshold value determination BER. Determine the first and second points on the coordinates, before In (e), the threshold control unit (e-1) sets the second threshold as the first threshold when the second threshold is less than the maximum threshold of the settable threshold range. In (c), the first threshold value is increased by the predetermined threshold width, and (a) to (d) are repeated until the second threshold value reaches the maximum threshold value, (e-2) In (e-1), each time the above (a) to (d) are repeated, it is determined whether or not the relationship of the first BER <the initial threshold setting BER ≦ the second BER is satisfied ( e-3) When the relationship (e-2) is satisfied, the second threshold value is determined as a first initial threshold value that is the threshold value of the first point, and (e) In the above, the threshold control unit (e-5) wherein the second threshold value is the settable threshold range. When larger than the minimum threshold, the second threshold is set as the first threshold, the first threshold is decreased by the predetermined threshold width in (c), and the second threshold is reduced to the minimum threshold. (A) to (d) are repeated until the threshold value is reached. (E-6) In (e-5), each time (a) to (d) is repeated, the first BER <the initial threshold value. It is determined whether or not the relationship of the set BER ≦ the second BER is satisfied, and when the relationship (e-7) (e-6) is satisfied, the second threshold is set to the second point. The threshold value controller determines the identification threshold value using the first initial threshold value and the second initial threshold value.
An identification threshold value determining method in an optical receiver according to the present invention is an optical reception method for determining an identification threshold value used when converting an optical signal received by an optical receiver constituting an optical transmission system into a binary electric signal. In the identification threshold value determining method in the optical device, (a) setting any threshold value that is within a settable threshold range in the optical receiver as a first threshold value; and (b) a first value for the first threshold value. Obtaining a bit error rate (hereinafter referred to as BER), (c) setting a second threshold value that is changed by a predetermined threshold width with respect to the first threshold value, and (d) the second threshold value. Obtaining a second BER for the threshold; and (e) based on the magnitude relationship of the first BER, the second BER, and a preset initial threshold determination BER, in the received optical signal Determining a first point and a second point on the relational coordinates of the value and the BER, wherein the step (e) includes (e-1) the second threshold value can be set. When the threshold value is less than the maximum threshold value, the second threshold value is set as the first threshold value, and the first threshold value is increased by the predetermined threshold width in the step (c), and the second threshold value is increased. Steps (a) to (d) are repeated until the threshold value becomes the maximum threshold value, and (e-2) step (e-1) is repeated each time steps (a) to (d) are repeated. A step of determining whether or not the relationship of the first BER <the initial threshold setting BER ≦ the second BER is satisfied; and (e-3) when the relationship of the step (e-2) is satisfied. The second threshold value is the threshold value of the first point. Determining as a first initial threshold, and the step (e) includes (e-5) when the second threshold is greater than a minimum threshold of the settable threshold range. Using the second threshold value as the first threshold value, decreasing the first threshold value by the predetermined threshold width in the step (c), and until the second threshold value becomes the minimum threshold value, Steps (a) to (d) are repeated. (E-6) In the step (e-5), each time the steps (a) to (d) are repeated, the first BER <the initial threshold value. A step of determining whether or not a relationship of setting BER ≦ the second BER is satisfied; and (e-7) when the relationship of the step (e-6) is satisfied, the second threshold is set to the second threshold A second first that is the threshold of the second point And determining as a period threshold. And (f) determining the identification threshold using the first initial threshold and the second initial threshold.

In the present invention, (a) any threshold existing within a settable threshold range in the optical receiver is set as a first threshold, and (b) a first bit error rate with respect to the first threshold ( BER), (c) a second threshold value that is changed by a predetermined threshold width with respect to the first threshold value is set, (d) a second BER for the second threshold value is determined, e) Based on the magnitude relationship of the first BER, the second BER, and the preset initial threshold value determination BER, the first point on the relational coordinate between the threshold value and the BER in the received optical signal And in (e), the threshold value control unit (e-1), when the second threshold value is less than the maximum threshold value of the settable threshold range, The predetermined threshold value in (c) is set as the first threshold value. The first threshold value is increased by a threshold width, and the steps (a) to (d) are repeated until the second threshold value reaches the maximum threshold value. (E-2) In (e-1), Each time (a) to (d) are repeated, it is determined whether or not the relationship of the first BER <the initial threshold value setting BER ≦ the second BER is satisfied, and (e-3) the (e-2) ) Is satisfied, the second threshold value is determined as a first initial threshold value that is the threshold value of the first point. In (e), the threshold value control unit e-5) When the second threshold value is larger than the minimum threshold value of the settable threshold range, the second threshold value is set as the first threshold value, and the predetermined threshold width is set in (c). Decrease the first threshold and the (2) until the second threshold reaches the minimum threshold ) To (d), (e-6) In (e-5), each time (a) to (d) is repeated, the first BER <the initial threshold value setting BER ≦ the second It is determined whether or not the relationship of BER is satisfied. (E-7) When the relationship of (e-6) is satisfied, the second threshold value is the second threshold value that is the threshold value of the second point. Is determined as an initial threshold value. Further, (f) the identification threshold is determined using the first initial threshold and the second initial threshold.
  Therefore, the first point and the second point in the coordinate system including the threshold value and the BER are specified. The point is identified by, for example, a threshold range in which an optimum identification threshold can be set even if signal (transmission) quality deterioration occurs in the optical transmission line (and because of signal (transmission) deterioration in the optical transmission line) Even if it is far from the center of the). As described above, when the first point and the second point are specified, it is possible to determine the optimum discrimination threshold using the first point and the second point.

  Hereinafter, the present invention will be specifically described with reference to the drawings showing embodiments thereof.

<Embodiment 1>
The optical transmission system includes an optical transmitter, an optical receiver, and an optical transmission path existing between the two devices. The optical receiver converts the received optical signal into an electrical signal. It is necessary on the optical receiver side to obtain an identification threshold value for identifying binarization of 0 or 1 used in the conversion. The configuration of the optical receiver is shown in FIG. Here, FIG. 1 shows a configuration of a general optical receiver.

  As shown in FIG. 1, the optical receiver 100 includes a light receiving unit 1, an identification reproduction unit 2, an identification threshold value generation unit 3, an FEC (Forward Error Correction) combination unit 4, a bit error monitor unit 5, and a threshold control unit 6. It is composed of

  Note that an optical signal from the optical fiber transmission line 10 (more specifically, an FEC-encoded optical signal) is input to the light receiving unit 1. Further, the FEC composite unit 4 outputs an FEC composite signal to the outside of the optical receiver 100.

  Next, a general operation of the optical receiver shown in FIG. 1 will be described.

  In FIG. 1, the light receiving unit 1 converts an optical signal into an electrical signal. Then, the electrical signal is output from the light receiving unit 1 to the identification reproducing unit 2. The identification reproduction unit 2 performs binarization reproduction processing of the electric signal based on the identification threshold value (identification voltage) transmitted from the identification threshold value generation unit 3. The binarized electrical signal is output from the identification reproduction unit 2 to the FEC combination unit 4.

  Here, the optical signal transmitted through the optical fiber transmission line 10 is affected by various effects such as noise. Therefore, the regenerated electrical signal may contain an error (error) (deterioration of signal (transmission) in the transmission path). Therefore, the FEC composite unit 4 has a function of performing error detection and error correction and outputting the number of error corrections to the bit error monitor unit 5.

  The bit error monitor unit 5 that has received the number of error corrections calculates necessary information as appropriate. Then, a new identification threshold value is set in the identification threshold value generation unit 3 via the threshold value control unit 6 so that the influence of the transmission error can be reduced from the transmission error information calculated by the bit error monitor unit 5.

  Next, the identification threshold value determination method of the present invention will be described. In the present invention, the first point and the second point on the relational coordinate between the threshold and the BER are determined, and the identification threshold is determined using the first point and the second point.

  Here, before explaining the determination method of the identification threshold, the definition of each word will be explained based on the graph shown in FIG. FIG. 2 is a diagram obtained as a result of plotting a bit error rate (hereinafter referred to as BER) value measured when the threshold value is changed in the threshold value control unit 6.

  As shown in FIG. 2, the change in the BER with respect to the threshold value generally appears as a substantially U shape (hereinafter referred to as a U-shaped curve). In FIG. 2, the vertical axis is BER, and the horizontal axis is a threshold value. The U-shaped curve can be formed by plotting the measurement point of the BER value against the threshold value.

  Here, the result of the plot is discrete (that is, it is discrete because it is plotted with the “predetermined threshold width” described below). Therefore, the bottom of the U-shaped curve (that is, the threshold value with the smallest BER and the threshold value is the original optimum identification threshold value) is obtained from the U-shaped curve formed from the discrete plot. It is difficult to identify clearly. Note that if the “predetermined threshold width” is set too small as described below, it becomes easy to specify the bottom of the U-shaped curve, but this is not suitable from the viewpoint of speeding up.

  Therefore, by the method described below, the threshold is changed with an appropriate “predetermined threshold width” from the viewpoint of high speed, and the BER with respect to the threshold is measured. Based on the measurement result, the optimum discrimination threshold (this is the original threshold value). Which is approximated to the identification threshold or, in some cases, the original identification threshold itself).

  Now, since there is a BER measurement limit in the optical receiver 100, even if the threshold value is changed, the BER value reaches its peak, and a portion where the BER value is constant (BER value constant portion) exists in the U-shaped curve. There is.

  The measurement limit of the BER value is defined as a BER measurable range in FIG. Therefore, the BER measurable range is a range determined by hardware factors of the optical receiver 100 until the BER reaches the measurement limit (in FIG. 2, the range from the BER value of 0 to a constant BER). is there.

  In FIG. 2, the settable threshold range is a range determined by hardware factors of the threshold control unit 6 provided in the optical receiver 100. That is, the optical receiver 100 cannot set a threshold value outside the settable threshold range. Here, the maximum value of the settable threshold range is referred to as the maximum threshold, and the minimum value of the settable threshold range is referred to as the minimum threshold.

  In FIG. 2, the dotted line extending in the threshold direction is the initial threshold value determination BER. The initial threshold value determination BER is a value determined in advance in the optical receiver 100 before the operation for determining the identification threshold value. The initial threshold value determination BER is determined based on a predetermined threshold width and an empirical rule regarding a threshold shift described later. If the initial threshold determination BER is too small, the accuracy of the optimum threshold is adversely affected. On the other hand, if the initial threshold value determination BER is too large, the ends of the U-shaped curve shown in FIG. 2 (that is, the first initial threshold value and the second initial threshold value described later) cannot be determined, and the identification threshold value calculation is performed. Fail.

  In the present invention, the end portion of the U-shaped curve is an intersection of the U-shaped curve and the initial threshold value determination BER, or an intersection of the U-shaped curve and the maximum threshold value or the minimum threshold value. In the present invention, the end of the U-shaped curve is defined by the first initial threshold and the second initial threshold determined as a result of the flowcharts of FIGS. Here, the second initial threshold value is smaller than the first initial threshold value.

  Moreover, it can be grasped that the point composed of the first initial threshold and the BER corresponding to the first initial threshold is the first point. Moreover, it can be grasped that the point composed of the second initial threshold value and the BER corresponding to the second initial threshold value is the second point.

  In the present invention, the U-shaped curve is not actually created, and the U-shaped curve can be created from the threshold value and the BER, and is a curve showing the relationship between the conventionally known threshold value and the BER. It is. In the present invention, the BER at several threshold values is measured.

  Next, a method of determining the first initial threshold and the second initial threshold will be described based on the flowcharts shown in FIGS. Here, FIG. 3 is a flowchart for determining the first initial threshold. FIG. 4 is a flowchart for determining the second initial threshold value. As described above, the first initial threshold value and the second initial threshold value are values that define the end of the U-shaped curve determined as a result of the method according to the present invention.

  As can be seen from each step described later, based on the magnitude relationship of the first BER, the second BER, and the preset initial threshold value determination BER, the relational coordinates between the threshold value and the BER in the received optical signal The first point and the second point will be determined. That is, a predetermined curve (U-shaped curve) that can be formed based on the relationship between the threshold and the BER based on the magnitude relationship in each of the BER value A, the BER value B, and the preset initial threshold value determination BER. The end portion is defined by the first initial threshold value and the second initial threshold value.

  First, a method for determining the first initial threshold value (or the first point) will be described with reference to FIG.

  First, the threshold control unit 6 sets a central threshold as the “current threshold” for the threshold generation circuit 13 (step S1). Here, the central threshold is a central value of a settable threshold range. Note that what is set as the “current threshold value” may not be the central threshold value. What is set as the “current threshold value” may be any threshold value (which can be grasped as the first threshold value) within the settable threshold range.

  Next, the bit error monitor unit 5 measures the BER for the “current threshold value” (step S2). Here, the measurement result of step S2 is referred to as BER value A.

  Next, the threshold value control unit 6 shifts the “current threshold value” by a “predetermined threshold width” in the direction in which the threshold value increases (that is, the “current threshold value” is “ Only the value of “predetermined threshold width” is added) (step S3).

  The “current threshold value” shifted by the “predetermined threshold width” is referred to as “new current threshold value (can be grasped as the second threshold value)”. Here, the “predetermined threshold width” is a value set in advance in the optical receiver 100.

  The value of “predetermined threshold width” is determined by an empirical rule. If the value of the “predetermined threshold width” is too small, it takes time to calculate the optimum threshold value. On the other hand, if the value of the “predetermined threshold width” is too large, the accuracy of the optimum threshold value to be calculated is adversely affected.

  Next, the bit error monitor unit 5 measures the BER for the “new current threshold value” (step S4). Here, the measurement result of step S4 is referred to as a BER value B.

  Next, the bit error monitor unit 5 determines whether or not the relationship of BER value A <initial threshold value determination BER ≦ BER value B is satisfied (step S5).

  When it is determined in step S5 that the above relationship is satisfied (for example, the case of FIG. 5; “Yes” in step S5), “new current threshold” is set as a temporary “first initial threshold” ( Step S6). And step S7 mentioned later is implemented also after step S6.

  On the other hand, if it is determined in step S5 that the above relationship is not satisfied (for example, the case of FIGS. 6 and 7; “No” in step S5), the bit error monitor unit 5 sets “new current threshold value”. Is greater than or equal to the maximum threshold (the maximum value of the settable threshold range) (step S7).

  If it is determined in step S7 that the “new current threshold value” is greater than or equal to the maximum threshold value (for example, the case of FIG. 8; “Yes” in step S7), the process proceeds to the determination process of step S8.

  On the other hand, when it is determined in step S7 that the “new current threshold value” is less than the maximum threshold value (for example, the case of FIG. 9; “No” in step S7), the BER value B is changed to the BER value A. (Step S9) and the process returns to step S3. In step S9, “new current threshold value” is also replaced with “current threshold value”.

  In step S8, it is determined whether or not a provisional “first initial threshold” is set during the flow up to step S8 (that is, whether or not step S6 has been performed). To judge).

  In step S8, when a temporary “first initial threshold value” is set in the flow up to step S8 (case in which step S6 is performed, for example, the case in FIG. 10; “Yes” in step S8). The provisional “first initial threshold value” is determined as the formal “first initial threshold value”, and the flowchart of FIG. 3 ends. In FIG. 10, the intersection of the U-shaped curve and the initial threshold value determination BER is the first initial threshold value. However, the first initial threshold value is not always the intersection point depending on the value of the “predetermined threshold width” or the like.

  On the other hand, in step S8, when the provisional “first initial threshold value” is not set during the flow up to step S8 (a case where step S6 has not been performed. For example, the cases of FIGS. 11 and 12). In step S8, "No"), the process proceeds to step S10.

  Here, the case of FIGS. 11 and 12 is a case where the U-shaped curve is formed so as to be significantly deviated in the left and right directions in the drawing as a result of quality degradation in the optical transmission line.

  As can be seen from FIG. 11, since the U-shaped curve has shifted to the left, the BER with respect to the central threshold is already a constant BER value. Therefore, even if the flow up to step S8 in FIG. 3 is performed in the state shown in FIG. 11, the first initial threshold value is not determined.

  Further, as can be seen from FIG. 12, since the U-shaped curve has shifted to the right, the threshold measurement limit (maximum threshold) is reached on the right curve side of the U-shaped curve before reaching the initial threshold determination BER. ) Has been reached. Therefore, even if the flow up to step S8 in FIG. 3 is performed in the state shown in FIG. 12, the first initial threshold value is not determined.

  Next, in step S10, it is determined whether or not the BER values A and B measured up to step S10 are always less than the initial threshold setting BER.

  In step S10, when it is determined that the BER values A and B measured up to step S10 are always less than the initial threshold setting BER (case in FIG. 12, “Yes” in step S10), the maximum threshold value is set. (The maximum value of the settable threshold range) is determined as the formal “first initial threshold” (step S11). Then, the flowchart of FIG. 3 ends.

  If it is determined in step S10 that the BER values A and B measured up to step S10 are always greater than or equal to the initial threshold setting BER (case in FIG. 11; “No” in step S10), the center The threshold (the central threshold can be grasped as the first first threshold) is determined as the formal “first initial threshold” (step S12). Then, the flowchart of FIG. 3 ends.

  The first initial threshold value defining the right end of the U-shaped curve has been determined by the flowchart of FIG. 3 described above. That is, the first point composed of the first initial threshold value and the BER corresponding to the first initial threshold value is determined.

  Next, a method for determining the second initial threshold value (or the second point) will be described with reference to FIG.

  First, the threshold control unit 6 sets a central threshold as the “current threshold” for the threshold generation circuit 13 as in step S1 of FIG. 3 (step S21). Here, as described in step S1, the central threshold value is a central value of a settable threshold range. Further, as in the case of the superior technique, what is set as the “current threshold value” may not be the central threshold value. What is set as the “current threshold value” may be any threshold value (which can be grasped as the first threshold value) within the settable threshold range.

  Next, the bit error monitor unit 5 measures the BER for the “current threshold value” (step S22). Here, the measurement result of step S22 is referred to as a BER value C.

  Next, the threshold value control unit 6 shifts the “current threshold value” by a “predetermined threshold width” in the direction in which the threshold value decreases (that is, the “current threshold value” is “ The value is reduced by a value of “predetermined threshold width” (step S23).

  The “current threshold value” shifted by the “predetermined threshold width” is referred to as “new current threshold value (can be grasped as the second threshold value)”. Here, the “predetermined threshold width” is a value set in advance in the optical receiver 100.

  Note that the value of the “predetermined threshold width” is determined by an empirical rule as described in the description of FIG. If the value of the “predetermined threshold width” is too small, it takes time to calculate the optimum threshold value. On the other hand, if the value of the “predetermined threshold width” is too large, the accuracy of the optimum threshold value to be calculated is adversely affected.

  Next, the bit error monitor unit 5 measures the BER for the “new current threshold value” (step S24). Here, the measurement result in step S24 is referred to as a BER value D.

  Next, the bit error monitoring unit 5 determines whether or not the relationship of BER value C <initial threshold value determination BER ≦ BER value D is satisfied (step S25).

  If it is determined in step S25 that the above relationship is satisfied (for example, the case of FIG. 13; “Yes” in step S25), “new current threshold” is set as a temporary “second initial threshold” ( Step S26). And step S27 mentioned later is implemented also after step S26.

  On the other hand, if it is determined in step S25 that the above relationship is not satisfied (for example, the case of FIGS. 14 and 15; “No” in step S25), the bit error monitor unit 5 sets the “new current threshold value” to the minimum. It is determined whether or not it is equal to or greater than a threshold value (minimum value of a settable threshold range) (step S27).

  If it is determined in step S27 that the “new current threshold value” is equal to or smaller than the minimum threshold value (for example, the case of FIG. 16; “Yes” in step S27), the process proceeds to the determination process of step S28.

  On the other hand, if it is determined in step S27 that the “new current threshold value” is larger than the minimum threshold value (for example, the case of FIG. 17; “No” in step S27), the BER value D is replaced with the BER value C. (Step S29), the process returns to Step S23. In step S29, “new current threshold value” is also replaced with “current threshold value”.

  In step S28, it is determined whether or not a provisional “second initial threshold” is set during the flow up to step S28 (that is, whether or not step S26 has been performed). To judge).

  In step S28, when a temporary “second initial threshold” is set during the flow up to step S28 (case in which step S26 is performed, for example, the case in FIG. 18; “Yes” in step S28). The provisional “second initial threshold” is determined as the formal “second initial threshold”, and the flowchart of FIG. 4 ends.

  On the other hand, in step S28, when the provisional “second initial threshold” is not set during the flow up to step S28 (a case where step S26 is not performed, for example, the case of FIGS. 19 and 20). "No" in step S28), the process proceeds to the determination in step S30.

  Here, the cases of FIGS. 19 and 20 are cases in which the U-shaped curve is formed to be significantly shifted in the right and left directions of the drawing as a result of quality degradation in the optical transmission line.

  As can be seen from FIG. 19, since the U-shaped curve has shifted to the right, the threshold value measurement limit (minimum threshold) is reached on the left curve side of the U-shaped curve before reaching the initial threshold value BER. Has been reached. Therefore, even if the flow up to step S28 in FIG. 4 is performed in the state shown in FIG. 19, the second initial threshold value is not determined.

  Further, as can be seen from FIG. 20, since the U-shaped curve has shifted to the right, the BER value with respect to the central threshold is already a portion where the BER value is constant. Therefore, even if the flow up to step S28 in FIG. 4 is performed in the state shown in FIG. 20, the second initial threshold value is not determined.

  Next, in step S30, it is determined whether or not the BER values C and D measured until step S30 are always less than the initial threshold setting BER.

  In step S30, when it is determined that the BER values C and D measured up to step S30 are always less than the initial threshold setting BER (case in FIG. 19, “Yes” in step S30), the minimum threshold value (Minimum value of settable threshold range) is determined as a formal “second initial threshold” (step S31). Then, the flowchart of FIG. 4 ends.

  If it is determined in step S30 that the BER values C and D measured up to step S30 are always equal to or greater than the initial threshold setting BER (case in FIG. 20; “No” in step S30), the center The threshold is determined as a formal “second initial threshold” (step S32). Then, the flowchart of FIG. 4 ends.

  The second initial threshold value that defines the left end of the U-shaped curve has been determined by the flowchart of FIG. 4 described above. That is, a second point consisting of the second initial threshold value and the BER corresponding to the second initial threshold value is determined.

  As described above, the first initial threshold value and the second initial threshold value that define the end of the U-shaped curve are determined (that is, the first point and the second point in the coordinate system of the threshold value and the BER). Is determined).

  Therefore, the position of the U-shaped curve (particularly, the position of the end of the U-shaped curve) in the coordinate system composed of the threshold and the BER is specified. For example, the position is identified by a threshold range in which an optimum identification threshold can be set even if signal (transmission) quality degradation occurs in the optical transmission path (and because of signal (transmission) degradation in the optical transmission path. Even if it is far from the center of the).

  And if the edge part of a U-shaped curve is specified by the above steps (that is, if the 1st initial threshold value and the 2nd initial threshold value which specify the edge part are specified), the 1st The approximate straight lines of the right curve portion and the left curve portion of the U-shaped curve are respectively determined using the initial threshold value and the second initial threshold value. If the two approximate lines are determined, the intersection of the approximate lines is determined as an identification threshold.

  The method for determining the approximate straight line will be described in detail in the second embodiment.

  As described above, in the invention according to the present embodiment, even if signal quality degradation occurs in the optical transmission line, the end of the U-shaped curve is specified by the first initial threshold value and the second initial threshold value. The Therefore, even if signal quality degradation occurs in the optical transmission line, the identification threshold is determined by the approximate straight line of the U-shaped curve determined using the first initial threshold and the second initial threshold. be able to.

<Embodiment 2>
In the present embodiment, reference is made to how to determine the approximate line and how to determine whether or not the discrimination threshold determined from the approximate line is really the optimum discrimination threshold.

  FIG. 4 is a flowchart for determining an approximate straight line and determining whether the optimum discrimination threshold is appropriate. Before executing the flowchart of FIG. 4, a predetermined curve (for example, a U-shaped curve, which is created as a result of measuring BER values with respect to a plurality of threshold values, is a discrete plot as described above. And a first initial threshold value and a second initial threshold value are determined.

  In FIG. 4, first, the first approximate line is derived (determined) using the first initial threshold value (step S41), and the second approximate line is derived (determined) using the second initial threshold value (step S41). S42). Specifically, this will be described with reference to FIG.

  In the following description, reference will also be made to a U-shaped curve (or a predetermined curve). However, the curve is not actually created and is used for convenience (the same applies to the first embodiment). The curve is a well-known threshold-BER curve obtained when the threshold value is continuously changed and the BER with respect to the changed threshold value is measured.

  FIG. 22 shows a predetermined curve (in FIG. 22, a U-shape) that can be formed based on discrete measurement results (that is, the result of measuring each BER value by changing the threshold value by “a predetermined threshold width”). Curve).

  First, a first point on a predetermined curve with respect to a first initial threshold is determined. Also, a second point on a predetermined curve for the second initial threshold is determined.

  Next, a pair of points on a predetermined curve having a BER smaller than that of the first point and the second point and having substantially the same BER value is determined. Here, the point pair includes a third point relatively close to the first point on the predetermined curve and a fourth point relatively close to the second point on the predetermined curve. .

  More specifically, the third point and the fourth point are a part of points obtained as a result of the measurement of the BER with respect to the threshold value (the number of measurements is plural) in the first embodiment. That is, among the plurality of points obtained as a result of the measurement, the third point and the fourth point, which are two points existing in the vicinity of the BER smaller than the BER of the first point and the BER of the second point. Select a point.

  Thereafter, by connecting the first point and the third point, the first approximate straight line (which can be grasped as the first straight line) is determined (derived) (step S41). Thereafter, the second approximate line (which can be grasped as the second straight line) is determined (derived) by connecting the second point and the fourth point (step S42). Note that either step S41 or step S42 may be performed first.

  Here, the point pair may be at least one pair. Even when there are two or more pairs, each point pair is from the third point (a point relatively close to the first point) and the fourth point (a point relatively close to the second point) as described above. It is configured. Note that the BER of the third point and the fourth BER are substantially the same. Accordingly, each third point is used when determining the first approximate line, and each fourth point is used when determining the second approximate line.

  If the U-shaped curve is a quadratic curve having substantially symmetry, the third point may be a point closer to the first point or a point closer to the second point. good. Similarly, the fourth point may be a point closer to the first point or a point closer to the second point.

  Next, the intersection of the first approximate line and the second approximate line is determined as an identification threshold (see step S43, FIG. 22).

  Next, the threshold control unit 6 illustrated in FIG. 1 sets the identification threshold determined in step S43 in the threshold generation unit 3. Then, the bit error monitor 5 measures the BER for the identification threshold (step S44).

  Next, the preset optimum discrimination threshold determination BER is compared with the BER obtained as a result of step S44 (step S45).

  When the BER determined as a result of step S44 is less than the optimum discrimination threshold determination BER (“Yes” in step S45, for example, the case of FIG. 23), the discrimination threshold determined in step S43 is adopted as the optimum discrimination threshold. (Step S46).

  On the other hand, when the BER determined as a result of step S44 is equal to or greater than the optimum discrimination threshold determination BER (“No” in step S45, for example, the case of FIG. 24. In the case of FIG. 24, the original discrimination threshold ( (The threshold value with the smallest BER) and the identification threshold value determined as a result of step S44 are greatly different), and the identification threshold value is not adopted as the optimum identification threshold value (step S47).

  As described above, by adopting the invention according to the present embodiment, two approximate lines for a predetermined curve (for example, a U-shaped curve) can be determined, and based on the two approximate lines. An identification threshold can be determined.

  Furthermore, by comparing the result of the optimum threshold determination BER and the BER for the identification threshold, it can be determined whether or not the identification threshold can be adopted as the optimum identification threshold. Therefore, when converting the received optical signal into an electrical signal, it is possible to prevent the use of an erroneously determined identification threshold.

  In order to determine the optimum discrimination threshold from the above two approximate lines, the change in BER with respect to the threshold becomes a quadratic curve (that is, a U-shaped curve), or as shown in FIG. It is desirable that the curve is a predetermined curve that vibrates somewhat on the curve (the predetermined curve can be grasped as a substantially U-shaped curve). That is, as shown in FIG. 24, in the case where the change in the BER with respect to the threshold value is W-shaped, it is difficult to determine the optimum identification threshold value from the two approximate lines.

  Here, in general, there are more cases where the change in the BER with respect to the threshold value is substantially U-shaped than in the case where it is W-shaped as shown in FIG.

  Note that, in the processing of each flowchart referred to in each embodiment, the threshold control unit 6 basically executes a block in which the subject of the processing is not described.

It is a block diagram which shows the structure of the optical receiver concerning this invention. It is a figure for demonstrating the definition of each name used by description of this invention. It is a flowchart for determining the value of a 1st initial threshold value. It is a flowchart for determining the value of a 2nd initial threshold value. It is a figure which shows an example in case it becomes "Yes" in step S5. It is a figure which shows an example in case it becomes "No" in step S5. It is a figure which shows the other example in case it becomes "No" in step S5. It is a figure which shows an example in case it becomes "Yes" in step S7. It is a figure which shows an example in case it becomes "No" in step S7. It is a figure which shows an example in case it becomes "Yes" in step S8. It is a figure which shows an example in case it becomes "No" in step S8. It is a figure which shows the other example in case it becomes "No" in step S8. It is a figure which shows an example in case it becomes "Yes" in step S25. It is a figure which shows an example in case it becomes "No" in step S25. It is a figure which shows the other example in case it becomes "No" in step S25. It is a figure which shows an example in case it becomes "Yes" in step S27. It is a figure which shows an example in case it becomes "No" in step S27. It is a figure which shows an example in case it becomes "Yes" in step S28. It is a figure which shows an example in case it becomes "No" in step S28. It is a figure which shows the other example in case it becomes "No" in step S28. 10 is a flowchart for explaining a method according to the second embodiment. 10 is a diagram for explaining a method according to Embodiment 2. FIG. It is a figure which shows an example in case the determined identification threshold value is judged to be the optimal identification threshold value. It is a figure which shows an example when the determined identification threshold value is not judged as an optimal identification threshold value. It is a figure which shows an example of a substantially U-shaped curve.

Explanation of symbols

3 identification threshold value generation unit, 5 bit error monitoring unit, 6 threshold control unit, 100 optical receiver, S1, S21 Set the central threshold value to the current threshold value, S2, S21 Measure the BER at the current threshold value, S3 Set the current threshold value + Shift by predetermined threshold width, S4, S24 BER measurement with new current threshold, S5 BER value A <initial threshold determination BER ≦ BER value B determination, S7 Judge whether current threshold is maximum threshold, S8 Determine whether first initial threshold has been set, change S9 BER value B to BER value A, determine whether S10 BER values A, B are always below initial threshold determination BER, S11 Use maximum threshold as first initial threshold Setting, S12 The central threshold is set as a first initial threshold, S23 The current threshold is shifted by a predetermined threshold width, S25 BER value C <initial threshold determination BER ≦ BER value D determination, S27 S28 determines whether the threshold value is the minimum threshold value, S28 determines whether the second initial threshold value has been set, S29 changes the BER value D to the BER value C, and S30 BER values C and D are always below the initial threshold value determination BER Determination, S31 minimum threshold is set as second initial threshold, S32 center threshold is set as second initial threshold, S41 first approximate line is derived, S42 second approximate line is derived, S43 identification threshold is determined, S44 BER measurement with the determined identification threshold, S45 measurement BER <optimal threshold determination BER determination, S46 determination that the determined identification threshold is the optimal identification threshold, S47 failed to calculate the optimal identification threshold.

Claims (6)

An optical receiver,
  A light receiving unit for receiving an optical signal;
  A threshold control unit that determines an identification threshold used when converting the optical signal into a binary electrical signal,
  The threshold control unit includes:
  (A) Any threshold existing within a settable threshold range in the optical receiver is set as the first threshold,
  (B) obtaining a first bit error rate (hereinafter referred to as BER) with respect to the first threshold;
  (C) setting a second threshold value that is changed by a predetermined threshold width with respect to the first threshold value;
  (D) determining a second BER for the second threshold;
  (E) based on the magnitude relationship of the first BER, the second BER, and a preset initial threshold determination BER, a first point on a relational coordinate between the threshold and BER in the received optical signal; Determine the second point,
  In the step (e), the threshold control unit
  (E-1) When the second threshold value is less than the maximum threshold value of the settable threshold range, the predetermined threshold width is set as the first threshold value in (c). Increasing the first threshold only, and repeating (a) to (d) until the second threshold reaches the maximum threshold,
  (E-2) Whether or not the relationship of the first BER <the initial threshold setting BER ≦ the second BER is satisfied each time the steps (a) to (d) are repeated in the step (e-1). Judging
  (E-3) When the relationship of (e-2) is satisfied, the second threshold value is determined as a first initial threshold value that is the threshold value of the first point,
  In (e), the threshold control unit
  (E-5) When the second threshold value is larger than the minimum threshold value of the settable threshold range, the second threshold value is set as the first threshold value, and the predetermined threshold width is set in (c). Decreasing the first threshold and repeating the steps (a) to (d) until the second threshold reaches the minimum threshold,
  (E-6) Whether the relationship of the first BER <the initial threshold value setting BER ≦ the second BER is satisfied each time the steps (a) to (d) are repeated in the step (e-5). Judging
  (E-7) When the relationship of (e-6) is satisfied, the second threshold value is determined as a second initial threshold value that is the threshold value of the second point,
  The identification control unit
  Determining the identification threshold using the first initial threshold and the second initial threshold;
An optical receiver. In (e-1), when the second threshold value is the maximum threshold value and the first initial threshold value is not determined, the threshold value control unit is
  (E-4-1) determining whether the first BER and the second BER are always less than the initial threshold determination BER;
  (E-4-2) If the result of (e-4-1) is less than the initial threshold determination BER, the maximum threshold is determined as the first initial threshold.
The optical receiver according to claim 1. In (e-1), when the second threshold value is the maximum threshold value and the first initial threshold value is not determined, the threshold value control unit is
  (E-4-3) determining whether the first BER and the second BER are always equal to or greater than the initial threshold determination BER;
  (E-4-4) If the result of (e-4-3) is equal to or greater than the initial threshold determination BER, the first threshold in the first (a) is determined as the first initial threshold. To
The optical receiver according to claim 1, wherein the optical receiver is an optical receiver. In (e-5), when the second threshold value is the minimum threshold value and the second initial threshold value is not determined, the threshold value control unit is
  (E-8-1) determining whether the first BER and the second BER are always less than the initial threshold determination BER;
  (E-8-2) If the result of (e-8-1) is less than the initial threshold determination BER, the minimum threshold is determined as the second initial threshold.
The optical receiver according to claim 1, wherein the optical receiver is an optical receiver. In (e-5), when the second threshold value is the minimum threshold value and the second initial threshold value is not determined, the threshold value control unit is
  (E-8-3) determining whether or not the first BER and the second BER are always equal to or greater than the initial threshold determination BER;
  (E-8-4) If the result of (e-8-3) is equal to or greater than the initial threshold determination BER, the first threshold in the first (a) is determined as the second initial threshold. To
The optical receiver according to claim 1, wherein the optical receiver is an optical receiver. In an identification threshold value determining method in an optical receiver for determining an identification threshold value used when converting an optical signal received by an optical receiver constituting an optical transmission system into a binary electric signal,
  (A) setting one of the thresholds within a settable threshold range in the optical receiver as a first threshold;
  (B) obtaining a first bit error rate (hereinafter referred to as BER) for the first threshold;
  (C) setting a second threshold value that is changed by a predetermined threshold width with respect to the first threshold value;
  (D) obtaining a second BER for the second threshold;
  (E) Based on the magnitude relationship of the first BER, the second BER, and a preset initial threshold value determination BER, a first point on a relational coordinate between the threshold value and the BER in the received optical signal; Determining a second point, and
  The step (e)
  (E-1) When the second threshold value is less than the maximum threshold value of the settable threshold range, the second threshold value is set as the first threshold value, and the predetermined threshold value in the step (c) Increasing the first threshold by a width and repeating the steps (a) through (d) until the second threshold reaches the maximum threshold;
  (E-2) Whether the relationship of the first BER <the initial threshold setting BER ≦ the second BER is satisfied every time the steps (a) to (d) are repeated in the step (e-1). Determining whether or not,
  (E-3) when the relationship of step (e-2) is satisfied, the second threshold value is determined as a first initial threshold value that is the threshold value of the first point; And
  In addition, the step (e)
  (E-5) When the second threshold value is larger than the minimum threshold value of the settable threshold range, the predetermined threshold width in the step (c) is set with the second threshold value as the first threshold value. Reducing the first threshold only and repeating the steps (a) to (d) until the second threshold reaches the minimum threshold;
  (E-6) Whether the relationship of the first BER <the initial threshold setting BER ≦ the second BER is satisfied each time the steps (a) to (d) are repeated in the step (e-5). Determining whether or not,
  (E-7) when the relationship of step (e-6) is satisfied, determining the second threshold value as a second initial threshold value that is the threshold value of the second point, And
  (F) further comprising the step of determining the identification threshold using the first initial threshold and the second initial threshold;
An identification threshold value determining method in an optical receiver.

Images