JP2005214986A - Optical memory - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical memory capable of extending a storage time without sacrificing efficiency, compared with a conventional single loop type optical memory. <P>SOLUTION: This optical memory is formed by connecting an optical transmission path 11, a selective light amplifier 12, a wavelength selection means 61, and a coupling part 3 introducing optical pulse inputted from the outside and outputting the circulated optical pulse to the outside in a ring shape. The optical memory comprises a saturated absorber 5 adapted so that the light transmission coefficient is small when the input optical pulse is in a space state, and the light transmission coefficient is large when the input optical pulse in a mark state. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

The present invention relates to an optical buffer that temporarily holds an optical cell in an optical ATM switch and an optical pulse train in an optical digital computer, or an optical memory for single emission waveform observation.

An optical ATM switch requires an optical memory (optical buffer) that temporarily holds a fixed-length signal light pulse train called an optical cell (cell) from an external line when the routing unit is busy. For this purpose, the optical loop memory shown in FIG. 13 is disclosed in, for example, a document “Electronics Letters, Vol. 27, pp. 1585-1586”. In this optical loop memory, a loop is constituted by a delay optical transmission line, an optical coupler, and an optical amplifier that compensates for these losses, and an optical gate is provided on the output side of the loop.

The delay optical transmission line is constituted by an optical fiber having a predetermined length, and the optical coupler 53 is constituted by an optical fiber coupler. The optical amplifier 52 uses an optical amplifier using a semiconductor laser or a rare earth-doped optical fiber. Further, in order to reduce the influence of spontaneous emission light emitted from the optical amplifier, an optical filter 56 is provided at the output of the optical amplifier 52 to cut off spontaneous emission light in an unnecessary band. Further, as shown in FIG. 16, these optical amplifiers 52 can change the gain by adjusting the current or the pumping light, and can also absorb the signal light by reducing the current.

Hereinafter, the operation of the optical loop memory 51 will be described. In the technical field of transmitting information for transmitting light, a unit of an optical signal (for example, one optical pulse) is often called an optical cell. The optical cell used in the description of the prior art and the optical signal used later in this specification have the same meaning. It is assumed that there is no signal light in the optical loop memory 51 in the initial state. Next, the signal light input from the input terminal 6 provided on the input side of the optical loop memory 51 is incident on both the optical gate 8 and the optical loop memory 51 by the optical coupler 53. The signal light entering the loop is delayed in accordance with the length thereof, and after being compensated for the loss of the optical amplifier 52, the optical transmission line 54 and the optical coupler 53, enters the optical coupler 53 again. Here, it is sent again to the optical gate 8 and the loop, and a series of operations are repeated. The signal reaching the optical gate 8 is not output to the output terminal 7 because the optical gate 8 is closed until a read command is issued. Further, the signal light in the loop circulates without being attenuated or oscillated because the optical amplifier 52 has a closed loop gain slightly lower than 1. The closed loop gain is obtained by subtracting the loss of the loop and the loss of the optical coupler 53 from the gain of the optical amplifier 52. When the busy state of the connected routing unit (not shown) is canceled, the optical loop memory 51 opens the signal light held by the optical gate 8 by the gate signal from the output terminal 7. Output to an external circuit. The signal light remaining in the loop is erased and returned to the initial state by setting the drive current of the optical amplifier 52 to zero.

Here, as shown in FIG. 14, the time for one round of the loop is the frame time (tframe), and the maximum value (K) × frame time (tframe) at which the signal light can circulate is the longest storage time. The cell time / frame time becomes efficient. In the present specification, this is called a single loop type optical memory. The ratio between the optical power in the space state (information “0”) and the optical power in the mark state (information “1”) is called the extinction ratio.

However, in this memory, every time the signal light goes around, the noise of the optical amplifier 52, that is, the spontaneous emission light accumulates, the optical power level in the space state increases and the extinction ratio decreases. Discrimination from the mark state becomes impossible. Therefore, the maximum number of laps K that can be circulated is, for example, about 5 to 7 times. In this case, in order to lengthen the longest storage time, if the length of the loop is increased, the frame time is extended and the efficiency is lowered. For this reason, a combination of tap delay circuits described below has been proposed by the document “1993 Autumn Meeting of the Institute of Electronics, Information and Communication Engineers, B-915, Loop Memory for Optical ATM Replacement Combining Tap Delay Circuits”.

An example in which the tap delay circuit 61 is combined with the optical loop memory 51 will be described with reference to FIG. In this optical memory, an input optical signal is divided into n by a 1 × n optical splitter 62 and input to optical delay lines 63 having delay amounts of 0, τ, 2τ,..., (N−1) τ. This τ is the maximum number of laps (K) of the optical loop memory 51 × frame time (tframe). The output of each delay unit is input to the optical loop memory 51 by the n × 1 optical coupler 64. In this memory, the signal light circulating around the optical loop memory 51 is once erased every τ and replaced with new signal light from the tap delay circuit 61. Therefore, the longest storage time can be extended.
"Electronics Letters, Vol. 27, pp. 1585-1586"

However, the optical memory in which the tap delay circuit 61 described in FIG. 15 is provided on the input side of the optical loop memory 51 has the following problems. As a first problem, when the signal light in the optical loop memory 51 is read out early in the storage time, the signal light in the loop or the tap delay circuit 61 becomes unnecessary. In this case, the cells in the loop can be erased by lowering the gain of the optical amplifier 52, but the signal light remaining in each optical delay line 63 is erased until the output from the optical delay line 63 is completed. Cannot move to the next storage operation. This is a problem in terms of time efficiency.

As a second problem, there is a problem that loss due to the 1 × n optical branching device 62 and each optical delay line 63 is large, and signal power is attenuated. When an optical amplifier is inserted to compensate for this power, the extinction ratio of the signal is degraded by the spontaneous emission light. This 1 × n optical branching device 62 is composed of a combination of 1 × 2 optical branching devices. When each branching ratio is 1: 1, theoretically, the intensity of the optical signal becomes 1 / 2n. Since the n × 1 optical coupler 64 has the same characteristic, the loss becomes 1 / 22n when the two optical couplers for input and output of the tap delay circuit 61 are combined. Actually, an excessive loss generated in manufacturing is added to this, and the loss is further increased.

Therefore, in the present invention, the following two different means are adopted in order to solve the above problems. The first method is described in claims 1 and 2. First, combine two or more optical loop memories with different lap times, make each optical loop memory for short-term storage and long-term storage, and when the longest storage time τ of the optical loop memory for short-term storage has passed, long-term storage Replace with the signal light of the optical loop memory. This point is common to claims 1 and 2. According to the first aspect of the present invention, the optical loop memory for short-term storage, that is, the light circulating around the first optical loop memory reduces the gain of the first selective optical amplifier existing in the optical loop memory. Extinguish. According to the second aspect of the present invention, the optical loop memory for short-term storage, that is, the light circulating around the first optical loop memory, switches the optical switch among the plurality of optical branching means constituting the coupling unit. The circulating light is released to the outside and disappears. The second method is described in claim 3. In this method, a saturable absorber is inserted into an optical loop memory. If the saturable absorber is set so that the transmission coefficient is low for noise in space and the transmission coefficient is high for high power such as signal light power at the time of marking, the extinction ratio decreases. Can be suppressed, and the maximum number of laps can be increased. That is, the maximum number of laps is increased by suppressing the optical power level in space.

The optical memory described in claim 1 has the following configuration. That is, in an optical memory having an input terminal 6 for inputting an optical pulse and an output terminal 7 for delaying and outputting the input optical pulse, the first optical transmission line 11 and the first selective optical amplifier 12 A loop is formed by the first loop memory 1 having the first loop time T1, the second optical transmission line 21, and the second selective optical amplifier 22, and the first loop time. The second loop memory 2 having a second round time T2 that is an integral multiple of T1 and the optical pulse input to the input terminal are taken into the first optical loop memory, and the optical pulse that circulated around the loop is directed to the output terminal The optical pulse input to the input terminal is taken into the second optical loop memory, the optical pulse that circulated around the loop is taken into the first optical loop memory, and the optical pulse that circulated around the loop is directed to the output terminal. Output And the first selective light so that the optical pulse of the first optical loop memory is extinguished when the optical coupler takes in the optical pulse from the second optical loop memory to the first optical loop memory. And timing control means 4 for controlling the amplifier.

The optical memory according to claim 2 has the following configuration. That is, in an optical memory having an input terminal 6 for inputting an optical pulse and an output terminal 7 for delaying and outputting the input optical pulse, the first optical transmission line 11 and the first selective optical amplifier 12 A loop is formed by the first loop memory 1 having the first loop time T1, the second optical transmission line 21, and the second selective optical amplifier 22, and the first loop time. The second loop memory 2 having a second round time T2 that is an integral multiple of T1 and the optical pulse input to the input terminal are taken into the first optical loop memory, and the optical pulse that circulated around the loop is directed to the output terminal The optical pulse input to the input terminal is taken into the second optical loop memory, the optical pulse that circulated around the loop is taken into the first optical loop memory, and the optical pulse that circulated around the loop is directed to the output terminal. Output And a timing control means 4 for controlling the coupling unit so as to extinguish the optical pulse of the first optical loop memory when the optical pulse is taken into the first optical loop memory from the second optical loop memory. Equipped with.

The second method is embodied by an optical memory according to claim 3. That is, this optical memory has a ring including an optical transmission line 11, a selective optical amplifier 12, wavelength selection means, and a coupling unit 3 for introducing an optical pulse input from the outside and outputting the circulating optical pulse to the outside. Saturable absorber that has a small light transmission coefficient when the input light pulse is in a space state and has a large light transmission coefficient when the input light pulse is in a mark state 5 is provided.

In the first method, two or more of the first optical loop memory 1 and the second loop memory 2 having different lap times are combined, and the first optical loop memory 1 is used for short-term storage and the second loop memory 2 is used. For long-term storage, signal light is incident almost simultaneously. When the longest storage time τ 1 of the first optical loop memory 1 for short-term storage elapses, the short-term memory is controlled by controlling the output of the first selective optical amplifier 12 and by controlling the coupling unit 3. The signal light having a reduced extinction ratio in the first optical loop memory 1 is erased, and the signal light of the second optical loop memory 2 for long-term storage is injected instead. The storage time of one optical loop memory 1 is extended.

The second method is a method of inserting the saturable absorber 5 into the optical loop memory. As shown in FIG. 17, the saturable absorber 5 is a substance having a characteristic that a transmission coefficient changes with respect to input optical power. Therefore, if the optical power at the time of space is set to P1, and the power at the time of marking is set to P2, the transmission coefficient is low with respect to the noise at the time of space, and the high power such as the signal optical power at the time of marking. As a result, the transmission coefficient increases. As a result, a decrease in extinction ratio can be suppressed, and the maximum number of rotations can be increased. The saturable absorber 5 is made of, for example, a semiconductor having the same type of quantum well structure as the semiconductor laser optical amplifier used. In this case, the characteristics can be changed to some extent by passing a bias current through the saturable absorber 5.

(1) Since the configuration of the present invention is adopted, the storage time can be extended without sacrificing efficiency as compared with the conventional single loop type optical memory. (2) Compared to an optical loop memory provided with a tap delay circuit, a plurality of delay circuits are not prepared, so that the apparatus becomes smaller. The memory can be cleared at a high speed by lowering the gain of the optical amplifier provided in each optical loop memory. (3) An optical loop memory including a saturable absorber has a simpler structure and a smaller size than a multi-loop optical memory.

Examples of the present invention will be described below. The first embodiment, the second embodiment corresponds to claim 1, the third embodiment, the sixth embodiment corresponds to claim 3, the fourth embodiment, the fifth embodiment is This corresponds to claim 2. In each embodiment, the first optical transmission line 11 and the second optical transmission line 21 which are delay optical waveguides are made of optical fibers or optical waveguides. As the optical amplifier, an optical amplifier using a semiconductor laser or a rare earth doped optical fiber is used. This optical amplifier has wavelength selection means including an optical filter or a Fabry-Perot resonator using a dielectric multilayer film, or a diffraction grating, and the gain can be adjusted. In particular, in the present specification, this is referred to as a selective optical amplifier, and the one used for the first optical loop memory 1 is the one used for the first selective optical amplifier 12 and the second optical loop memory 2. The second selective optical amplifier 22 is assumed. The timing control means 4 is composed of, for example, a sequencer, a computer, and a D / A converter for converting the digital signal into a drive current for the optical amplifier. The current of the first or second selective optical amplifier or the connection of the coupling portion is changed according to the timing chart stored in advance.

(First Embodiment) First, the construction will be described with reference to FIG. The circulation time T2 in the second optical loop memory 2 is N times the circulation time T1 in the first optical loop memory 1. This N is an integer and is a value equal to or less than the maximum number of rotations K1 in the first optical loop memory 1. Here, it is assumed that N = 4. It is assumed that the distance between the first optical branching unit 31 and the second optical branching unit 32 constituting the coupling unit 3 is very short, and the propagation time is negligible with respect to the cell length. Both the first optical branching means 31 and the second optical branching means 32 are composed of branch circuits by optical fiber couplers or optical waveguides.

Next, the operation of the first embodiment will be described with reference to FIG. In the initial state (t = 0), it is assumed that no signal light exists in each optical loop memory. The optical signal input from the input terminal 6 is transmitted to the second optical loop memory 2 and the first optical branching unit 31 via the second optical branching unit 32. The light entering the second optical loop memory 2 circulates and is stored. On the other hand, the signal light transmitted to the first optical branching means 31 is transmitted to the first optical loop memory 1 and the optical gate 8. The light entering the first optical loop memory 1 is circulated and stored.

When 0 <t <4T1, the signal light in the first optical loop memory 1 periodically reaches the optical gate 8. When 4T1 <t <5T1, the signal light in the first optical loop memory 1 has a reduced extinction ratio. Therefore, the drive current of the first selective optical amplifier 12 is lowered to lower the gain, and this signal light is erased. . Instead, the signal light from the second optical loop memory 2 arrives and enters the first optical branching means 31. This signal light goes to the optical gate 8 and goes around the first optical loop memory 1 again. If a read signal enters the timing control means 4 at t = 6T1, the optical gate 8 is opened and the signal light is output to the output terminal 7. After this output operation, the signal light remaining in each loop memory is erased by lowering the gains of the first selective optical amplifier 12 and the second selective optical amplifier 22 and returns to the initial state.

(Second Embodiment) First, the construction will be described with reference to FIG. Compared with the first embodiment, the position of the second optical loop memory 2 is different, and the others are the same.

Next, the operation of the second embodiment will be described with reference to FIG. In the initial state (t = 0), it is assumed that there is no signal light in each loop memory. The optical signal input from the input terminal 6 is transmitted to the first optical loop memory 1 and the optical gate 8 through the first optical branching means 31. The light that has entered the first optical loop memory 1 is amplified by the first selective optical amplifier 12, then enters the second optical branching means 32, goes around the first optical loop memory 1, and 2 is transmitted to the second optical loop memory 2. Light entering each loop memory is circulated and stored. When 0 <t <4T1, signal light in the first optical loop memory 1 periodically reaches the optical gate through the first optical branching means 31. When 4T1 <t <5T1, the signal light in the first optical loop memory 1 has a reduced extinction ratio. Therefore, the drive current of the first selective optical amplifier 12 is lowered to lower the gain, and this signal light is erased. . Instead, the signal light from the second optical loop memory 2 enters the first optical loop memory 1 via the second optical branching means 32 and circulates again. If a read signal enters the timing control means 4 at t = 6T1, the optical gate 8 is opened and the signal light is output to the output terminal 7. After this output operation, the signal light remaining in each loop memory is erased by reducing the gains of the first selective optical amplifier 12 and the second selective optical amplifier 22 and returns to the initial state.

Compared with the first embodiment, the second embodiment has one optical branching means between the input terminal 6 and the output terminal 7, so that the optical loss during this period can be reduced. However, since the number of optical branching means increases in the first optical loop memory 1, it is necessary to increase the gain of the first selective optical amplifier 12. Since this causes an increase in spontaneous emission light, the maximum number of rotations K1 of the first optical loop memory 1 is smaller than that in the first embodiment.

(Third Embodiment) First, the configuration will be described with reference to FIG. A saturable absorber 5 is installed in the optical loop memory 1. Let T be the circulation time of the optical loop memory. Next, the operation will be described with reference to FIG. In the initial state (t = 0), it is assumed that there is no signal light in the loop. When signal light enters the input terminal 6 (0 <t <T), the optical signal passes through the optical transmission path 11 and the selective optical amplifier 12 via the optical branching means 31 and enters the saturable absorber 5. In the present embodiment, since there is only one optical branching means, optical transmission line, and selective optical amplifier, the first feature is omitted. If the optical power at the time of the mark at this incident point is set to P1, and the power at the time of space is set to P2, the optical noise at the time of space has a low optical power, so the transmission coefficient is low, and thus the optical power further decreases. . For high optical power such as signal optical power at the time of marking, the transmission coefficient is high and the loss is small. The signal light exiting the saturable absorber 5 enters the optical branching unit 31 again and is output to the optical loop memory 1 again for the optical gate 8 and recirculation. The above operation is repeated. If a read signal enters the timing control means 4 at t = 6T, the optical gate 8 is opened and the signal light is output to the external circuit. After this output operation, the signal light remaining in the loop is erased by lowering the gain of the selective optical amplifier 12 and returns to the initial state.

(Fourth Embodiment) First, the configuration will be described with reference to FIG. The first optical branching unit 31 includes two 1 × 2 optical switches 31a and 31b. Others are the same as the first embodiment. Next, the operation will be described with reference to FIG. In the initial state (t = 0), it is assumed that no signal light exists in each optical loop memory. When signal light is input to the input terminal 6 (0 <t <T1), the signal light is transmitted to the second optical loop memory 2 and the first optical switch 31a via the second optical branching means 32. . The light entering the second optical loop memory 2 circulates and is stored. Further, the signal light incident on the terminal A of the first optical switch 31a is transmitted to the first optical loop memory 1 through the terminal D of the second optical switch 31b.

During storage (T1 <t <4T1), the connection of the first optical switch 31a and the second optical switch 31b is the terminal B and the terminal D, and the light entering the first optical loop memory 1 passes through these terminals. And circulate and save. When 4T1 <t <5T1, the signal light in the first optical loop memory 1 has deteriorated extinction ratio. Therefore, the first optical switch 31a is set to the terminal A side, and the second optical switch 31b is set to the terminal D side. Take it in again. The old signal light in the first optical loop memory 1 is emitted out of the loop from the first optical switch 31a terminal B and disappears. The newly taken signal light goes around the first optical loop memory 1 again. If a read signal is input to the timing control means 4 at t = 6T1, the optical switch 31a is switched to the terminal B, the optical switch 31b is switched to the terminal D, and the signal light is output to the output terminal 7. After this output operation, the signal light of the first optical loop memory 1 does not enter the loop again, so that there is no need to erase by adjusting the first selective optical amplifier 12. The signal light remaining in the second optical loop memory 2 is erased by lowering the gain of the second selective optical amplifier 22 and returns to the initial state. In this embodiment, it is possible to replace two 1 × 2 optical switches with one 2 × 2 optical switch. In this case, it is necessary to lower the gain of the first selective optical amplifier 12.

(Fifth Embodiment) First, the configuration will be described with reference to FIG. The first optical branching unit 31 includes two 1 × 2 optical switches 31a and 31b. The rest is the same as in the second embodiment. Next, the operation will be described with reference to FIG. In the initial state (t = 0), it is assumed that no signal light exists in each of the optical loop memories 1 and 2. When signal light is input to the input terminal 6 (0 <t <T1), the signal light is transmitted through the terminal A of the first optical switch 31a and the terminal C of the second optical switch 31b. It is transmitted to the loop memory 1. The light that has entered the first optical loop memory 1 is amplified by the first selective optical amplifier 12, enters the second optical branching means 32, goes around the first optical loop memory 1, and passes through the second light. It is transmitted to the loop memory 2. The light entering each optical loop memory is circulated and stored.

In T1 <t <4T1, the connection of the first optical switch 31a and the second optical switch 31b is the terminal B and the terminal D, and the light entering the first optical loop memory 1 circulates through these terminals. Saved.

When 4T1 <t <5T1, the signal light in the first optical loop memory 1 has deteriorated extinction ratio, so the first optical switch 31a is set to the terminal A side, and the second optical switch 31b is set to the terminal D side. Take it in again. The old signal light in the first optical loop memory 1 is emitted out of the loop from the terminal B of the first optical switch 31a and disappears. The newly taken signal light goes around the first optical loop memory 1 again. If a read signal is input to the timing control means 4 at t = 6T1, the first optical switch 31a is switched to the terminal B, the second optical switch 31b is switched to the terminal C, and the signal light is output to the output terminal 7. After this output operation, the signal light of the first optical loop memory 1 does not enter the optical loop memory 1 again, so that there is no need for erasing by adjusting the first selective optical amplifier 12. The signal light remaining in the second optical loop memory 2 is erased by lowering the gain of the second selective optical amplifier 22 and returns to the initial state. In this embodiment, it is possible to replace one 1 × 2 optical switch with two 2 × 2 optical switches.

(Sixth Embodiment) First, the configuration will be described with reference to FIG. In the present embodiment, since there is only one optical branching means, optical transmission line, and selective optical amplifier, the first feature is omitted. The optical branching means 31 uses 1 × 2 optical switches 31a and 31b, and the optical gate 8 is not necessary. The rest is the same as in the third embodiment. The operation will be described with reference to FIG. It is assumed that there is no signal light in the optical loop memory 1 in the initial state (t = 0). When signal light is input to the input terminal 6 (0 <t <T), the signal light passes through the terminal A of the first optical switch 31a and the terminal C of the second optical switch 31b. Are sequentially incident on the selective optical amplifier 12 and the saturable absorber 5. The operation in the saturable absorber 5 is the same as that in the third embodiment. The signal light exiting the saturable absorber 5 enters the first optical switch 31a again. During the circulation (T <t <5T), the connection of the first optical switch 31a and the second optical switch 31b is the terminal B and the terminal D, and the light that has entered the first optical loop memory 1 passes through these terminals. It goes around and is saved. If a read command is input to the timing control means 4 at t = 6T, the first optical switch 31a is switched to the terminal B, the second optical switch 31b is switched to the terminal C, and the signal light is output to the output terminal 7. In this output operation, the signal light does not enter the optical loop memory 1 again, so that the signal light inside the optical loop memory 1 is erased, and the initial state is restored. In this embodiment, it is possible to replace one 1 × 2 optical switch with two 2 × 2 optical switches.

In each embodiment, when an optical switch is used as the optical branching means, no optical gate is required. Further, since the light is cut off from the external circuit during the circulation, the signal light is protected against sudden external light noise. In the multi-loop optical memory, the longest storage time can be further extended by increasing the number of loops. The embodiment has been described above in the case where the present apparatus is used in an optical ATM switch, but it goes without saying that the present apparatus can also be used in an optical memory of an optical digital calculator. Furthermore, it can be used for a device that converts a single light pulse into a light pulse having periodicity.

The figure which shows the structure of a 1st Example. The figure which shows the timing chart of a 1st Example. The figure which shows the structure of a 2nd Example. The figure which shows the timing chart of a 2nd Example. The figure which shows the structure of a 3rd Example. The figure which shows the timing chart of a 3rd Example. The figure which shows the structure of a 4th Example. The figure which shows the timing chart of a 4th Example. The figure which shows the structure of a 5th Example. The figure which shows the timing chart of a 5th Example. The figure which shows the structure of a 6th Example. The figure which shows the timing chart of a 6th Example. The figure which showed the structure of the simple optical loop memory. Diagram showing the relationship between cells and frames Figure of combination of tap delay circuit and optical loop memory Example of drive current vs. gain characteristics of a semiconductor laser optical amplifier. Example of input optical power versus transmittance characteristics of a saturable absorber

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 1st optical loop memory 2 2nd optical loop memory 3 Coupling part 4 Timing control means 5 Saturable absorber 6 Input terminal 7 Output terminal 8 Optical gate 11 1st optical transmission path 21 2nd optical transmission path 12 First selective optical amplifier 22 Second selective optical amplifier 31 First optical branching means 31a First optical switch 31b Second optical switch 32 Second optical branching means.

Claims (1)

An optical transmission line (11), a selective optical amplifier (12), a wavelength selection means (61), and a coupling unit (3 for introducing an optical pulse inputted from the outside and outputting the circulating optical pulse to the outside ) In a ring shape, the light transmission coefficient is small when the input light pulse is in the space state, and the light transmission coefficient is large when the input light pulse is in the mark state. An optical memory comprising a saturable absorber (5).

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