KR101778314B1 - Wavelength iitialization apparatus and method - Google Patents

Abstract

A wavelength initializing apparatus in a wavelength division multiplexing passive optical network (WDM-PON) using at least one wavelength, wherein the wavelength initializing apparatus according to an embodiment changes a parameter value for a light source system A parameter determination unit for determining a parameter value corresponding to a wavelength of a channel to be matched based on the calculated singularity, and a light source control unit for controlling the light source with the determined parameter value, And a light source control unit for initializing the wavelength.

Description

TECHNICAL FIELD [0001] The present invention relates to a wavelength initializing apparatus and a wavelength initializing apparatus,

The present invention relates to a wavelength initializing and monitoring path setting apparatus and a method thereof in a wavelength division multiplexing passive optical network (WDM-PON) using one or more wavelengths.

WDM-PON is a technique for transmitting optical signals having different wavelengths to one optical fiber. Generally, in order to construct a WDM-PON system, a light source operating at different wavelengths, that is, a specific channel (optical path), must have a light source operating at a wavelength corresponding to the channel. That is, the number of operating wavelengths in a WDM-PON system must be provided for system management, which is called an inventory problem. In order to solve this inventory problem, when the light source is matched to a specific channel, it is necessary to recognize the channel corresponding to a certain wavelength and operate at the wavelength. Such a characteristic is called a colorless characteristic.

Generally, a light source such as RSOA or FP-LD using a seeding method can obtain a colorless characteristic relatively easily because a signal is modulated and transmitted at a wavelength of an injected light source. However, incoherency such as a broadband light source (BLS) Because of the use of incoherent light sources, the signal quality is degraded due to the high relative inductance noise (RIN) characteristics. On the other hand, the tunable laser has a coherent characteristic, which is superior to the seeding method using the BLS light source, but it is difficult to secure the colorless characteristic without a method of recognizing the wavelength corresponding to the connected optical path.

To solve this problem, there is a " multi-wavelength alignment apparatus using a fiber grating in a multi-channel transmission system "(Korean Patent Application No. 10-1996-0019876), but there are many wavelengths having the minimum reception power, It is difficult to distinguish between cases where wavelengths are aligned and cases where wavelengths are not.

Although WDM-PONs and Wavelength Initialization Method of Optical Subscriber Networks (Korean Patent Application No. 10-2006-0071648) are disclosed, wavelength division multiplexing passive optical network (WDM-PONs) It is necessary to perform wavelength initialization using a separate module of the main control part and the sub control part. Therefore, there arises a problem of space requirement for cost and PBA production, and there is a problem that the optical module of OLT and ONT operates in association with each other.

An apparatus and method for initializing and stabilizing a wavelength while maintaining colorless characteristics in a system using a wavelength variable light source is presented. In addition, an apparatus and method for shortening the wavelength initialization time of a multi-channel system and increasing the operational availability of the monitoring time and space are proposed.

According to an aspect, in a wavelength initializing apparatus of a WDM-PON (Wavelength Division Multiplexing Passive Optical Network), a wavelength initializing apparatus may include a singular point calculating unit for calculating at least one singular point with respect to a monitoring value by changing a parameter value with respect to a light source system A parameter determination unit for determining a parameter value corresponding to a wavelength of the channel to be matched based on the calculated singularity, and a light source control unit for controlling the light source with the determined parameter value to initialize the wavelength of the channel.

In this case, the light source system may be a light source itself or an optical source combined with the light source itself.

On the other hand, the singularity point calculation unit can calculate the singular point by setting the magnitudes of the parameter change values differently for at least two or more parameter value change periods.

At this time, the change interval of the parameter value may be set to correspond to at least one predetermined threshold value.

On the other hand, the parameter determining unit can determine the singular value as the parameter value when the calculated singular value is one.

The parameter determination unit may determine any one of the singular points as a parameter value based on at least one or more predetermined thresholds when the calculated singular points are plural.

At this time, the predetermined threshold value may be determined using the monitoring value or a mathematical process value of the monitoring value.

At this time, the mathematical processing value may include any of arithmetic operation, differential operation, and integral value of the monitoring value.

According to another aspect of the present invention, there is provided an apparatus for initializing a wavelength for a light source set comprising at least two light sources in a WDM-PON (Wavelength Division Multiplexing Passive Optical Network) using at least two or more channels of wavelengths, And a parameter determiner for adjusting the parameter value so that the wavelength of the output light is output at the wavelength of the channel corresponding to each of the light sources.

According to a further aspect, the light source control unit controls the light source to output light with a first parameter value with respect to any one of the light sources, and for the remaining light sources, the parameter value adjusted by the parameter determination unit Based on the first parameter value.

At this time, the second parameter value may be a value calculated based on the operating wavelength that is changed by adjustment of the parameter value.

In addition, the second parameter value may be a parameter value for controlling, for each light source, a channel corresponding to the light sources to operate in a predetermined wavelength range.

In addition, the light source control unit controls the light sources to sequentially output light of the corresponding channel with the first parameter value, and when the wavelength is changed by any one of the light sources, Can be controlled.

According to a further aspect, the wavelength initialization apparatus may further include a path control unit for controlling the paths of the channels in consideration of the control time or the number of components.

According to another aspect of the present invention, there is provided a method for initializing a wavelength of a WDM-PON (Wavelength Division Multiplexing Passive Optical Network), comprising the steps of: calculating at least one outlier for a monitoring value by changing a parameter value for a light source system; Determining a parameter value corresponding to a wavelength of a channel to be matched based on the calculated singularity, and initializing a wavelength of the channel by controlling the light source with the determined parameter value.

In this case, the singularity point calculating step may calculate the singular point by setting the magnitude of the parameter change value differently for at least two or more parameter value change periods.

On the other hand, the parameter determination step may determine any one of the singular points as the parameter value based on at least one predetermined threshold value when the calculated singular points are plural.

According to another aspect of the present invention, there is provided a method of initializing a wavelength for a light source set including at least two light sources in a WDM-PON (Wavelength Division Multiplexing Passive Optical Network) using at least two channels of wavelengths, Controlling the light sources to output light at predetermined parameter values, and adjusting the parameter values such that the wavelength of the output light is output at the wavelength of the channel corresponding to each of the light sources.

According to a further aspect, the step of controlling to output light may be controlled to output light with a first parameter value for any one of the light sources, and for the remaining light sources, And output light with a second parameter value based on the parameter value.

At this time, the second parameter value may be a value calculated based on the operating wavelength that is changed by adjustment of the parameter value.

In addition, the second parameter value may be a parameter value for controlling, for each light source, a channel corresponding to the light sources to operate in a predetermined wavelength range.

In addition, the step of controlling to output light may be performed such that the light of the corresponding channel is sequentially output to the light sources with the first parameter value, and when the wavelength is changed by any one of the light sources, So that light can be controlled to be output as a parameter value.

Wavelength initialization of a system operating in more than one channel in the WDM-PON is possible, and a variable wavelength light source can be used while maintaining colorless characteristics. The monitoring path can be simplified and the manufacturing cost can be reduced and the wavelength initialization time can be shortened. In addition, the wavelength initialization time can be shortened for an array light source providing one or more light sources in one chip.

1 is a block diagram of a wavelength initialization apparatus according to one embodiment.
2A to 2E are diagrams for explaining the calculation of the singular point.
Figs. 3A to 3C are diagrams for explaining critical point calculation. Fig.
4A and 4B are exemplary diagrams illustrating wavelength initialization for a plurality of light sources.
5A to 5E are examples for explaining a monitoring path for a plurality of channels.
6 is a flowchart of a wavelength initialization method according to an embodiment.
7 is a flowchart of a wavelength initializing method according to another embodiment.

The details of other embodiments are included in the detailed description and drawings. BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, a wavelength initializing apparatus and method according to embodiments of the present invention will be described in detail with reference to the drawings.

1 is a block diagram of a wavelength initialization apparatus according to one embodiment. Referring to FIG. 1, the wavelength initialization apparatus 100 may include a singularity point calculation unit 110, a parameter determination unit 120, and a light source control unit 130.

The singularity point calculating unit 110 may calculate at least one singular point with respect to the monitoring value by changing the parameter value with respect to the light source system. Here, the parameter means a control element of a light source that affects a wavelength, and may be a control element for controlling the reflectance of the resonator according to the current, voltage, temperature, resonator length, control value of the resonator length, have. Also, the monitoring value means a measurable value, for example, light output, current, voltage, temperature, and the like. On the other hand, the monitoring value may indicate a maximum value, a minimum value, or a distinguishable specific value at a desired specific wavelength according to a change in a parameter value, and the maximum value, minimum value, or distinguishable specific value may be defined as a singular point.

The light source system may be a light source itself or an optical source combined with the light source itself. The specific light source may have a singular point only by a change in the parameter value, but in some cases, one or more optical elements (passive element or active element) may be combined with the inside or outside of the light source to have a singular point. Here, the light source system can be defined as a light source per se or a light source combined with an optical element.

According to a further aspect, the singularity point calculation unit 110 may set two or more change intervals of parameter values, and set different change values for the change interval of each parameter value. As will be described later in detail, the change period of the parameter value can be set to correspond to at least one predetermined threshold value, and the wavelength initialization time can be shortened by setting the change value of the change period of each parameter value differently.

The parameter determination unit 120 can determine the parameter value to correspond to the wavelength of the channel to be matched based on the singular point calculated by the singularity point calculation unit 110. [ For example, when the number of singularities calculated by the singularity calculation unit 110 is one, the value of the singularity can be determined as the parameter value. Further, when the calculated singular points are plural, any one singular point can be determined as the parameter value based on at least one predetermined threshold value.

The predetermined threshold value may be determined using the measured monitoring value, or using a mathematical process value of the monitoring value. At this time, the mathematical processing value may include any of arithmetic operations, differentials, and integral values of the monitoring value, and may be a value calculated by combining them if necessary.

The light source control unit 130 may control the light source with the parameter value determined by the parameter determination unit 120 and initialize the wavelength so that the light source outputs light at the wavelength of the corresponding channel.

2A to 2E are diagrams for explaining the calculation of the singular point. The singularity calculation method according to one embodiment will be described with reference to FIGS. 2A to 2E.

FIGS. 2A to 2D illustrate a light source system showing a singular point by coupling an external passive element to a light source. In other words, AWG is the external passive element which can cause the laser to have a laser, a parameter that changes the wavelength, and a singularity at a specific wavelength. The singular point is the simulation result using the maximum value at the maximum transmittance. FIGS. 2A and 2B show output changes and wavelength changes according to current changes before coupling the AWG. FIG. 2C shows a transmission curve according to the AWG wavelength, FIG. 2D shows an optical output Respectively. Here, as shown in FIG. 2B, since the wavelength changes due to the current change, the parameter becomes the current, and as shown in FIG. 2D, the light output corresponds to the monitoring value since the light output has a singular point.

As shown in FIGS. 2A and 2B, before passing through the passive device AWG, the optical power and the oscillation wavelength continue to increase without changing a specific point from the starting current of 0 mA to the end point of 10 mA according to the parameter change (current change) Show graphs. However, when the passive element is placed on the AWG, the singularity point calculating unit 110 can calculate the maximum value as a singular point since it has one singular point as a maximum value as shown in FIG. 2D. It is possible to induce the light source to oscillate at a desired wavelength.

That is, in FIG. 2C, the AWG has the maximum value at 1557 nm. Therefore, if it is desired to match the oscillation wavelength to this value, the oscillation wavelength is 1557 nm at the current of 7 mA in FIG. 2B. Can be determined by the parameter value. If the parameter value (current 7 mA) determined so as to maximize the optical power transmitted through the AWG is applied as shown in FIG. 2D, the oscillation wavelength can be 1557 nm.

On the other hand, if a system is constructed together with other optical devices to calculate a singular point and initialize the wavelength, the wavelength to be aligned may be different from the wavelength actually aligned. For example, in the case of FIGS. 2A to 2D, when the current is applied larger than 7 mA, the light output continues to increase and the loss of the AWG also increases. It can be set to allow it when it comes within the wavelength alignment error of the preset system.

2E is an example of calculating a singular point and determining a parameter value when there are two or more singular points. As shown in FIG. 2E, in the case of a light source system having one or more outliers, a predetermined threshold value can be set, and a singular point of a wavelength to be aligned can be distinguished from other singular points. Figure 2e shows a light source system with three singularities. Since each singular point is larger than the surrounding value, it can be regarded as a specific value that can be distinguished. Here, the threshold value can be set to more than one if necessary, and the current interval can be set to one or more.

The singularity point calculation unit 110 may drive the light source with the parameter value of the wavelength initialization start and find the singular point 1 through the process of the parameter change 1. [ In addition, the singularity point calculating section 110 can find the singular point 2 through the process of the parameter change 2.

The parameter determination unit 120 can ignore the measurement value corresponding to the singular point 1 because the measurement value corresponding to the singular point 1 is less than the threshold value and can determine the measurement value corresponding to the singular point 2 as the parameter value because the measurement value corresponding to the singular point 2 exceeds the threshold value.

The singularity point calculating unit 110 may set the same parameter change values for each parameter change interval, that is, the parameter change 1 interval and the parameter change 2 interval, but they may be set differently as needed. For example, if the parameter is a current, the current control interval between the parameter change 1 interval and the parameter change 2 interval can be set to be equal to 0.1 mA. Alternatively, the parameter change 1 interval can be set to 1 mA, and the parameter change 2 interval can be set to 0.1 mA. That is, in the parameter variation 1 section in which a value equal to or less than the measured value (optical power) corresponding to the threshold value is measured, the current is changed by increasing the current interval (for example, 1 mA) and the optical power value close to the threshold value is measured In the parameter change 2 section, the current can be changed by decreasing the current interval (for example, 0.1 mA). This shortens the time spent in the parameter change 1 section and reduces the total time required to initialize the wavelength.

Figs. 3A to 3C are diagrams for explaining critical point calculation. Fig.

3A shows an example of setting a mathematically processed value as a threshold value. In FIG. 3A, it is assumed that a mathematical process value is a differential value, a y-axis on the left is a measured value, a y-axis on the right is a differential value, Respectively. The wavelength varies with the parameter change, and the derivative value becomes zero at the maximum or minimum of the measured value.

The wavelength initialization apparatus 100 according to the present embodiment may further include a threshold value calculation unit (not shown). 3A, a threshold value calculating unit (not shown) calculates a threshold value. First, as shown in 1.1 and 1.2 of FIG. 3A, a half value (Δλ / 2) of the x-axis. Next, DELTA lambda is set to a value smaller than the half value of DELTA lambda _{CH which} is the wavelength interval of the WDM-PON. At this time, DELTA lambda _CH denotes a value provided by the WDM-PON standard.

Next, check how the corresponding point in the measured graph differs from the maximum optical power, and calculate the reference value. Here, the difference corresponds to? M1 and? M2, and? M1>? M2, and a large value can be regarded as a reference in this embodiment. However, this is only an example and a small value can be used in consideration of shortening of the initialization time.

Next, find the position (3.1, 3.2.) At the distance of ΔM1 from the maximum value of the measured value in the measured value graph.

Next, find the position (4.1., 4.2) corresponding to the position (3.1., 3.2.) At a distance of ΔM1 from the differential value graph.

Finally, find the value of the y-axis corresponding to 4.1 and 4.2 in the differential value graph. At this time, the value of the y-axis (5.1, Th1, 5.2, Th2) can be used as a threshold value, and only one value (for example, a large absolute value) can be used as a threshold value if necessary.

If the measurement value has a different form for each channel, the threshold value can be determined as the average value, minimum value, maximum value, etc. of the threshold value calculated by the threshold value calculating unit (not shown) for all channels.

FIG. 3B shows an example of a wavelength initialization method when a mathematically processed value is used as a threshold value. FIG. 3B shows a case in which a differential is used as a mathematical process, the initialization start point is on the left, and the parameter is largely changed in the parameter change 1 interval in which the mathematically processed value is larger than the threshold value. . However, this is only an example, and if the initialization start point is on the right side, it can be equally explained using the absolute value of the mathematically processed value. If the mathematical processing method is different or the shape of the measured value is different, And the initialization method may differ from those described above. Further, the parameter change interval may be set to one or more intervals by using one or more threshold values, and the parameter change value of each interval may be set differently as described above.

FIG. 3C shows a method of calculating a threshold value and initializing a wavelength by mixing measured values and mathematically processed values. FIG. Referring to FIG. 3C, a case where the measured value is set as the threshold value and a case where the mathematically processed value is set as the threshold value can be used in combination. In FIG. 3C, it is assumed that a differential is used as a mathematical process, and it is assumed that the differential value is zero when the measured value is differentiated at a wavelength to be matched.

Referring to FIG. 3C, when mathematically processed values are used, three points having a differential value of 0 are displayed, and it is not possible to distinguish which value corresponds to a desired wavelength in the algorithm. In this case, the differential value (D_Th1, D_Th2) can be used as the threshold value near the maximum value of the measured value, and the measured value (M_Th1, M_Th2) can be used as the threshold value far from the maximum value of the measured value.

The wavelength initialization process shown in FIG. 3C will be described below. Here, the wavelength initialization start point is assumed to be left. It is also assumed that the parameter that changes the wavelength is the current and the wavelength shifts to the longer wavelength when the injection current increases. In Fig. 3C, the right side of the graph is assumed to be a long wavelength. It is also assumed that? In is the increment of the injection current of the n-th section, and? I1,? I2 and? I3 satisfy the relationship of? I1>? I2>? I3.

First, the current is increased by ΔI1 in the parameter change 1 period of the M_Th2> measured value and the M_Th1> measured value, and the current is increased by ΔI2 in the M_Th2> measured value and the parameter change 2 period of the measured value M_Th1 <measured value. Further, in the section of the parameter change 3 which is the differential value of M_Th2 <measured value and M_Th1 <measured value and D_Th2>, the current is increased by ΔI3, and finally the portion where the differential value is 0 is searched.

This procedure makes it easier to find singularities in multi-channels with different measured values. At this time, a weight can be given according to the kind of the threshold value. That is, the threshold value may be weighted so that the value of D_Th2 is not used in the parameter change 1 interval and the parameter change 2 interval. On the other hand, it is possible to configure a threshold on one or more measured values and a threshold on one or more mathematically processed values.

4A and 4B are exemplary diagrams illustrating wavelength initialization for a plurality of light sources. A method of initializing wavelengths of a plurality of light sources for a plurality of channels will be described with reference to Figs. 4A and 4B.

For each set of light sources outputting one or more wavelengths, it is possible to initialize each light source independently by wavelength or by using the associativity of various light sources. In this case, when wavelengths are initialized by using the associations of various light sources, it is possible to reduce the time required for wavelength initialization and reduce the path for monitoring. Here, the set of light sources may be in the form of a single chip, or may be in the form of a package of multiple chips. An example of a chip-type package is a VCSEL array of two or more channels. One example of a multi-chip package type is one in which two or more TOSAs are integrated into a single package. Another example of a multiple chip type package is one in which one or more independent chips are mounted on one mount.

In an aspect, an example of a procedure for initializing the wavelengths of one channel and initializing the wavelengths of the other channels in consideration of the relationship between the light sources will be described.

The light source control unit 130 may control the light source unit to output light with a first parameter value to any one of the light source sets including at least two or more light sources. Next, the parameter determination unit 120 can adjust the parameter value so that the wavelength of the light output by the light source is output at the wavelength of the channel to be matched. Then, the light source control unit 130 may control the light source control unit 130 to output light to the remaining light sources with a second parameter value based on the final adjusted parameter value for any one of the light sources. Then, the parameter determination unit 120 may initialize the wavelengths by adjusting each parameter value so that the wavelengths of light output by the remaining light sources are output at the wavelengths of the corresponding channels.

Here, the second parameter value may be an adjusted parameter value. Or may be a value calculated based on the operating wavelength that is changed by adjustment of the parameter value, or a parameter value for each light source that controls each of the light sources so that the corresponding channel operates in a predetermined wavelength range.

Will be described in more detail with reference to FIG. For example, it is possible to initialize the wavelength of the m-th light source satisfying 1? M? N with respect to the light source set composed of n light sources, and then to drive the light sources other than the m- have. FIG. 4A illustrates the case where m = 1, the parameter is the current, and the monitoring value is the optical power.

The light source control unit 130 controls the first current (first parameter value) to be applied to m = 1 light source to output light. At this time, it is assumed that m = 1 light source outputs light in the vicinity of the second channel wavelength. The parameter determining unit 120 controls the parameter (current) so that m = 1 light source is optically output at the first channel wavelength in the vicinity of the second channel wavelength.

Then, the light source control unit 130 applies a current to the light source other than m = 1 as the second parameter value for the light source with m = 1, and the parameter determination unit 120 determines that the light source other than m = And the current is controlled to be optically output at the channel wavelength.

Here, the second parameter value may be a final adjusted parameter (current) value for m = 1 light source, or may be a parameter value satisfying Equation (1). That is, m-th channel and m + 1 as the wavelength interval between the second channel Δλ _{CH _M,} and m + 1 and m + 2 intervals as Δλ _{CH _M + 1} of the second channel, and the wavelength of the m + 1-th channel λ _{M + 1} , it may mean a parameter value in which the (m + 1) -th channel operates in the lower wavelength range.

According to a further aspect, the second parameter value may be a value obtained by calculating the operating wavelength with respect to the change of the parameter after completing the wavelength initialization of the mth light source. The operating wavelengths for parameter variations can have primary, secondary, tertiary, and higher order properties.

For example, the case where the wavelength change due to the parameter is of a primary type can be described as follows. At this time, the intervals of the operating wavelengths may be the same or may be all different. The following example applies when the operating wavelengths are all the same. It is also assumed that the first object to perform wavelength initialization is the first channel.

It is assumed that the wavelength change (Δλ _Prmt ) by the parameter change (ΔPrmt) is 1, the characteristic is Δλ _{P r mt} / Δprmt, and the interval between adjacent two channels is all the same and Δλ _CH . If the wavelength of the first light source coincides with the wavelength of the first channel when the parameter Prmt = X, the second parameter Prmt_n of the n-th channel can be calculated as shown in Equation (2) below.

More specifically, taking a VCSEL having a parameter current as an example, a wavelength change of a general VCSEL due to a current change is known as 0.6 nm / mA. Therefore, _{?? Prmt} /? Prmt = ?? _I /? I = 0.6 nm / mA. If the light source is controlled so as to operate at the same 0.8 nm between the adjacent two channels, that is, Δλ _CH = 0.8 nm. The current provided to the n-th light source when the current that makes the first light source operate at the wavelength corresponding to the first channel is XMA, can be calculated by Equation (3) as follows.

As another example, in the case of a VCSEL in which the parameter is a temperature, a change in wavelength of a general VCSEL due to a temperature change is known as 0.1 nm / 占 폚, and a second parameter value for the remaining light sources can be determined through the process described above.

According to a further aspect, in the case of an array operating at a specific interval of wavelength taking into account errors in the same operating conditions, the operating conditions can be determined without formulas. In this case, the operating wavelength in the actual system can not be the same in all conditions, so an error must be considered.

If the wavelengths are initialized for the n-th channel, operating the channels other than the n-th channel in the operating condition of the n-th channel will operate near the wavelengths desired by the desired light sources.

As shown in (f) of FIG. 4A, the output of the light source goes through the process of Mmin -> Mref -> Mmaxm. If another channel initialization method is used after one channel wavelength initialization, The wavelength initialization time can be shortened because only the process of Mref -> Mmax is performed. Where M is the monitoring value.

FIG. 4B shows a process of independently initializing all the light sources. Generally, the wavelength initialization process of one channel may affect the wavelength of another channel. For example, when current is applied to one channel in an array chip, the overall temperature of the chip may change and the wavelength of the other channel may be changed. In this case, if the other channel is initialized after initializing the wavelength of one of the channels, the wavelength initialization process itself may be difficult or the wavelength of each channel may be adjusted to the wavelength outside the desired wavelength after completion of the wavelength initialization.

In this case, it is preferable to perform wavelength initialization independently for each channel. In a method of performing wavelength initialization independently for each channel, the light source control unit 130 controls the light source control unit 130 to output light by applying a first parameter value, and the parameter determination unit 120 determines whether the light source Lt; RTI ID = 0.0 &gt; wavelength &lt; / RTI &gt; This process can be repeated several times to increase the wavelength accuracy roll.

As shown in FIG. 4B, when wavelength initialization is performed in this manner, a specific parameter value can be applied to a channel other than the channel for wavelength initialization in order to shorten the initialization time. At this time, if the wavelength is changed by the current, the second parameter value may be applied to a channel other than the channel for initializing the wavelength. That is, the light source control unit 130 controls the light sources to sequentially output light of the corresponding channel with the first parameter value, and when the wavelength is changed at the wavelength initialization for any one of the light sources, It is possible to control the output of light by applying the calculated second parameter value as described above.

Referring to FIG. 4B, the basic processes of wavelength initialization of each channel are (a) to (f). Since the wavelength initialization process of one channel affects other channels, the position of the actual wavelength can be fixed as shown in (g) when the process of (a) to (f) is performed. In this case, the processes (a) to (f) can be repeated.

5A to 5E are examples for explaining a monitoring path for a plurality of channels. The wavelength initialization apparatus 100 according to one embodiment may further include a path control unit 140. [ The path control unit 140 may control the monitoring path of the channels in consideration of the control time or the number of parts.

More specifically, FIG. 5A shows the configuration of the control unit 140 and the path for controlling the controlled object. The monitoring value is a measurable value such as optical power, current, voltage, temperature, pressure, and the object to be controlled is a controllable object such as a laser diode, an LED, or a device formed by combining electronic components. The path refers to a path made up of electrical wiring, optical wiring, and a device (ADC, DAC, resistor, coil, capacitor, LDD, LMT, TIA, etc.) and a combination thereof placed between these wirings.

The control unit may be a device capable of determining a parameter change based on one or more monitoring values measured analogously or digitally, such as an OP amp, a comparator, an FPGA, an MCU, an MPU, a CPU, an LDD and an LMT. It should not be construed as limited.

The path controller 140 can control the light source for wavelength initialization / stabilization through various path setting. As shown in FIGS. 5B to 5D, when there are one monitoring value and several monitoring values, the path and the control unit can be shared or independently configured. The path and the control unit from the monitoring to the control unit may be provided independently or integrally so as to correspond to one or more, or a combination thereof. Also, the path from the control unit to the light source can be provided independently or integrally, or a combination thereof is also possible.

In the case of independent configuration, the number of parts for the path and control part is increased, but the control speed is increased. When the integrated part is provided, the number of parts for the path and control part is decreased, but the control speed may be slowed down. Therefore, the path can be set using an appropriate method of independent configuration, integrated configuration, or a combination thereof, taking into account the control time and the number of components.

Will be described in more detail with reference to FIG. 5E. 5E is an actual application example. Monitoring is an optical power measurement using m-PD, and Path_R is an example of a combination of integrated and independent paths using a dual log converter and an ADC. In other words, in the case of the dual log converter, two paths are provided as one device, but since the two paths are independent, they correspond to FIG. 5c and one path is commonly used from the ADC to the FPGA. .

The FPGA can be used for current control and path_R control via monitoring values. The wavelength stabilization / initialization program can connect the microprocessor with the algorithm to the FPGA and replace the FPGA with this microprocessor. The LDD is used as the path _L to convert the digital form of the output provided by the FPGA to the analog value of the input. At this time, the configuration of path_L corresponds to FIG. 5C.

Although each component is specifically referred to for the sake of specific explanation, each component may be composed of one or more wires and one or more elements and combinations thereof. For example, in FIG. 5E, the FPGA, which is a control unit, can be configured with an EEPROM for storing monitoring values and a microprocessor for determining a current value based on monitoring values. In this case, the decision is made by the microprocessor, so the FPGA can correspond to the path.

6 is a flowchart of a wavelength initialization method according to an embodiment. A wavelength initializing method according to an embodiment will be described with reference to FIG. The present invention has been described in detail with reference to various embodiments and drawings, and will be briefly described below.

First, the wavelength initialization apparatus 100 may calculate a singular point by changing the parameter value with respect to the light source system (step 310). The singular point may be one or more, and when there are two or more singular points, one singular point may be calculated based on a predetermined threshold value, and the predetermined threshold value has been described in detail above with reference to FIGS. 3A to 3C. It is also possible to set two or more change intervals of the parameter values to be changed, and to set the change magnitudes of the different parameter values differently for the interval.

A parameter value corresponding to the wavelength of the channel to be matched may then be determined based on the calculated singularity (step 320). The parameter value can be a value of the singular point when the singular point is one, and can determine any one singular point exceeding a predetermined threshold value as the parameter value when there are two or more singular points.

Finally, the wavelength of the channel can be initialized by controlling the light source with the determined parameter value (step 330).

7 is a flowchart of a wavelength initializing method according to another embodiment. The wavelength initializing method will be described with reference to FIG. The present embodiment is a procedure for initializing a wavelength for a remaining channel after wavelength initialization for a certain channel in consideration of the relationship between light sources. This has been described in detail above with reference to FIG. 4A.

First, the light output may be controlled to a first parameter value for any one light source in a light source set of at least two light sources (step 510).

The first parameter value may mean a wavelength initialization start initial parameter value. The parameter value may then be adjusted such that the wavelength output from the light source is output at the wavelength of the corresponding channel (step 520).

The light output of the remaining light source may then be controlled with a second parameter value based on the adjusted parameter value (step 530). Finally, the parameter values may be adjusted such that the output wavelength of each light source is output at the wavelength of the corresponding channel (step 540).

If the wavelength initialization of one channel affects other channels, you can initialize the wavelength independently for all channels. In this case, the wavelength can be initialized by performing steps 510 and 520 for all channels. In this case, this process can be repeated several times in order to increase the accuracy of the wavelength initialization. In this case, it is controlled to output the light of the channel corresponding to the first parameter value sequentially to the light sources, and when the wavelength is changed at the wavelength initialization for any one of the light sources, the remaining light sources are calculated The second parameter value may be applied to control the light output.

Meanwhile, the embodiments of the present invention can be embodied as computer readable codes on a computer readable recording medium. A computer-readable recording medium includes all kinds of recording apparatuses in which data that can be read by a computer system is stored.

Examples of the computer-readable recording medium include a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disk, an optical data storage device and the like, and also a carrier wave (for example, transmission via the Internet) . In addition, the computer-readable recording medium may be distributed over network-connected computer systems so that computer readable codes can be stored and executed in a distributed manner. In addition, functional programs, codes, and code segments for implementing the present invention can be easily deduced by programmers skilled in the art to which the present invention belongs.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the foregoing detailed description, and all changes or modifications derived from the meaning and scope of the claims and the equivalents thereof are included in the scope of the present invention Should be interpreted.

100: Wavelength initialization device 110: Singularity point calculation unit
120: parameter determination unit 130: light source control unit
140:

Claims (22)

A wavelength initializing apparatus of a WDM-PON (Wavelength Division Multiplexing Passive Optical Network)
A singularity point calculating unit for calculating at least one singular point with respect to the monitoring value by changing a parameter value with respect to the light source system;
A parameter determination unit for determining a parameter value to be used in the light source system based on the calculated singular point and a channel to be used by the light source system; And
And a light source control unit for controlling a light source of the light source system with the determined parameter value to initialize a wavelength of the channel,
The above-
A change interval for changing the parameter value is divided by using a threshold determined in consideration of a wavelength of a channel to be used in the light source system,
And setting a change magnitude of the parameter value in the change interval including the singular point to be larger than a change magnitude of the parameter value in the change interval not including the singular point,
Wavelength initialization device. The light source system according to claim 1,
Wherein the light source itself or an optical element is coupled to the light source. delete delete The apparatus according to claim 1,
And determines the singular point as the parameter value when the calculated singular point is one. The apparatus according to claim 1,
And determines any one of the singular points as the parameter value based on at least one or more predetermined thresholds when the calculated singular points are plural. 7. The method of claim 6,
Wherein the monitoring value or the mathematical processing value of the monitoring value is used. 8. The method of claim 7,
And a wavelength initialization unit that includes any one of arithmetic operation, differential, and integral values of the monitoring value. delete delete delete delete delete delete A wavelength initializing method of a WDM-PON (Wavelength Division Multiplexing Passive Optical Network)
Calculating at least one outlier for the monitoring value by varying the parameter value for the light source system;
Determining a parameter value to be used in the light source system, based on the calculated singularity and a channel to be used by the light source system; And
And controlling a light source of the light source system with the determined parameter value to initialize a wavelength of the channel,
Wherein the calculating step comprises:
A change interval for changing the parameter value is divided by using a threshold determined in consideration of a wavelength of a channel to be used in the light source system,
And setting a change magnitude of the parameter value in the change interval including the singular point to be larger than a change magnitude of the parameter value in the change interval not including the singular point,
Wavelength initialization method. delete 16. The method according to claim 15,
And determining, as the parameter value, any one of the singular points based on at least one or more predetermined threshold values when the calculated singular points are plural. delete delete delete delete delete

Images