JP2021057785A - Receiving device and program - Google Patents

Abstract

To provide a technique for dynamically setting a threshold value used for determining which reference symbol corresponds to a received symbol in a receiving device.SOLUTION: A receiving device comprises: noise determination means of determining distribution of noises on the basis of each noise of a plurality of received symbols; histogram determination means of determining a histogram of an amplitude of a first direction in a complex plane of the plurality of received symbols, in which the first direction is a real axial direction or an imaginary axis; distribution determination means of determining a plurality of distributions of the amplitude of the first direction in the receiving device for each of a plurality of reference symbols defined with an orthogonal amplitude modulation on the basis of the histogram determined by the histogram determination means and the distribution determined by the noise determination means; and threshold value determination means of determining one or more threshold values for determining which one of the plurality of reference symbols corresponds to the symbol to be received on the basis of a plurality of distribution intersection points.SELECTED DRAWING: Figure 4

Description

The present invention relates to a receiver and program of a communication system that uses stochastic shaping techniques.

In recent years, long-distance optical communication systems have shifted from the direct detection method to the coherent detection method in order to expand the transmission capacity. In the coherent detection method, multi-value (M-value) quadrature amplitude modulation (M-QAM) is used. In M-QAM, the coordinates (constitutations) of M reference symbols are defined on the complex plane. Each reference symbol is associated with a predetermined number of bit strings determined according to the value of M. The transmission device divides the transmission bit string into a predetermined number of bit strings, and sequentially transmits signals of the corresponding reference symbols according to the transmission order of the predetermined number of bit strings. Note that transmitting the signal of the reference symbol means transmitting a signal having an amplitude and a phase corresponding to the coordinates of the reference symbol. The period for transmitting one reference symbol is called the symbol period, and the switching speed of the reference symbol is called the symbol speed or the modulation speed.

In an optical communication system, a receiving device receives a modulated signal which is a reference symbol string transmitted by the transmitting device. However, when the symbol received by the receiving device (hereinafter referred to as the receiving symbol) is indicated on the complex plane due to the non-linear characteristics and noise of the optical communication system, the receiving symbol has coordinates different from the coordinates of the reference symbol. In the case of a modulated signal using M-QAM, the influence of this non-linear characteristic differs for each reference symbol. This means that the error probability differs depending on the reference symbol. For this reason, Non-Patent Document 1 discloses an optical communication system using a probabilistic shaping (PS: Probabilistic Shipping) technique.

The PS technique is a technique for converting a transmission bit string according to a predetermined rule in a transmission device so that a reference symbol having a smaller absolute amplitude in the I-axis and Q-axis directions has a higher appearance probability. As a result, the larger the average power of the reference symbol, the smaller the probability of appearance, so that the probability of occurrence of an overall error can be made smaller than that of normal M-QAM.

Further, Non-Patent Document 1 discloses that maximum posteriori probability (MAP) detection is performed in a receiving device of an optical communication system using PS technology. Specifically, in Non-Patent Document 1, the threshold value for the receiving device to determine which reference symbol defined by M-QAM corresponds to the receiving symbol is determined based on the appearance probability of each reference symbol. It discloses that.

S. Hu, et al. , "MAP Detection of Professionally Shaped Constellations in Optical Fiber Transitions", 2019 Optical Fiber Communications Constellation, San Diego, California, California, Optics, California. 1-3, 2019

However, Non-Patent Document 1 only discloses that the threshold value is calculated by calculation based on the appearance probability of each reference symbol obtained in advance, and the receiving device dynamically sets the threshold value based on the measured value in each communication system. It does not disclose the configuration for setting.

The present invention discloses a technique in which a receiving device dynamically sets a threshold value used to determine which reference symbol the received symbol corresponds to.

According to one aspect of the present invention, the receiving device of the communication system using the orthogonal amplitude modulation is a noise determining means for determining the dispersion of noise based on the noise of each of the received plurality of symbols, and the complex of the received plurality of symbols. A histogram determining means for determining the histogram, which is a histogram of the amplitude in the first direction on a plane and the first direction is the real axis direction or the imaginary axis direction, the histogram determined by the histogram determining means, and the noise. A distribution determination means for determining a plurality of distributions of amplitudes in the first direction in the receiving device and a plurality of reference symbols defined by the orthogonal amplitude modulation based on the variance determined by the determination means. It is characterized by comprising a histogram determining means for determining one or more histograms for determining which of the plurality of reference symbols the received symbol corresponds to based on the intersection of the distributions.

According to the present invention, the receiving device can dynamically set a threshold value used to determine which reference symbol the received symbol corresponds to.

The block diagram of the receiving apparatus according to one Embodiment. The figure which shows the reference symbol and the threshold value set by one Embodiment. The explanatory diagram of the relationship between the received symbol string, the threshold set to be judged, and the threshold set used for demodulation. The block diagram of the threshold value determination part by one Embodiment. The figure which shows the histogram by one Embodiment. An explanatory diagram of how to obtain a threshold value set according to an embodiment.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. The following embodiments do not limit the invention according to the claims, and not all combinations of features described in the embodiments are essential to the invention. Two or more features of the plurality of features described in the embodiments may be arbitrarily combined. Further, the same or similar configuration will be given the same reference number, and duplicate description will be omitted. Further, in each of the following figures, components that are not necessary for the description of the embodiment will be omitted from the drawings.

<First Embodiment>
FIG. 1 is a configuration diagram of a receiving device of a communication system according to the present embodiment. The communication system of the present embodiment uses PS technology. That is, the transmitting device converts the transmission bit string based on a predetermined conversion rule to make the appearance probabilities of each reference symbol of M-QAM different. In the following description, the modulation method used by the communication system is 16QAM.

The receiving unit 2 coherently receives the modulated light received from the transmitting device based on the local light from the light source 1 and outputs an electric signal. This electric signal is a signal indicating a reception symbol that switches according to the modulation speed. The threshold value determination unit 4 obtains a threshold value set for determining which reference symbol of 16QAM the received symbol corresponds to, and notifies the demodulation unit 3. The demodulation unit 3 determines which reference symbol of 16QAM the received symbol corresponds to based on the threshold set notified from the threshold value determination unit 4, and outputs a bit string. After that, this bit string is converted by a conversion rule opposite to the conversion rule in the transmitting device. As a result, the transmission bit string in the transmission device is restored.

FIG. 2 is an explanatory diagram of a threshold value set determined by the threshold value determination unit 4. The black circles in FIG. 2 indicate 16 reference symbols defined in 16QAM. In the case of 16QAM, since the amplitude of the symbol is in four stages in each of the real axis (I axis) direction and the imaginary axis (Q axis) direction, three threshold values are obtained for each axial direction. In FIG. 2, the threshold values 51, 52 and 53 with respect to the amplitude in the I-axis direction and the threshold values 61, 62 and 63 with respect to the amplitude in the Q-axis direction are obtained. The threshold set is a set of these six thresholds. Generally, in the case of M-QAM, if N ² = M, N-1 threshold values are set in each axial direction. The demodulation unit 3 determines the reference symbol of 16QAM corresponding to the received symbol by comparing the amplitude in the I-axis direction and the amplitude in the Q-axis direction of the received symbol with each threshold value.

The noise generated in the coherent optical communication system is dominated by the amplified spontaneous emission light (ASE) in the optical amplifier, and there is no difference in the ASE in the I-axis direction and the Q-axis direction. Therefore, in the present embodiment, the threshold value 51 and the threshold value 61 are set to the same value, the threshold value 52 and the threshold value 62 are set to the same value, and the threshold value 53 and the threshold value 62 are set to the same value. That is, in the present embodiment, the threshold value determination unit 4 outputs a threshold value set including the three threshold values to the demodulation unit 3.

FIG. 3 is an explanatory diagram of the relationship between the determination of the threshold value set by the threshold value determination unit 4 and the threshold value set used by the demodulation unit 3 for demodulation. The threshold value determination unit 4 determines the threshold value set #k based on the reception symbol sequence #k including a plurality of consecutive reception symbols. The demodulation unit 3 demodulates the received symbol string # k + 1 next to the received symbol string # k by using the threshold set # k. Then, the threshold value determination unit 4 determines the threshold value set # k + 1 based on the received symbol string # k + 1. At the start of communication, the threshold set # 0 used by the demodulation unit 3 for demodulation of the first received symbol string # 1 is stored in advance as an initial value in a storage unit (not shown) of the receiving device. Alternatively, at the start of communication, before transmitting the user data, the transmission device transmits a training sequence equal to the length of each received symbol string to cause the threshold value determination unit 4 to determine the threshold value set, and the demodulation unit 4 continues. The threshold value set determined by the threshold value determination unit 4 based on the training sequence may be used for demodulation of the reception symbol string # 1 transmitted by the transmission device.

FIG. 4 is a configuration diagram of the threshold value determination unit 4. Each received symbol of the received symbol string #k is input to the noise determination unit 41 and the histogram determination unit 42 in order. The noise determination unit 41 determines that the distance between the received symbol and the reference symbol having the closest distance to the received symbol is the noise of the received symbol. In other words, the minimum value within the distance between the received symbol and each reference symbol of 16QAM is determined as the noise of the received symbol. The distance between the received symbol and the reference symbol is the coordinates of the received symbol and the coordinates of the reference symbol (positions of black circles in FIG. 2) when the amplitude and phase of the received symbol are expressed in coordinates on the complex plane. Distance. The noise determination unit 41 determines the noise variance V obtained for each reception symbol of the reception symbol string #k and notifies the distribution determination unit 43.

The histogram determination unit 42 obtains the amplitude in the I-axis or Q-axis direction for each received symbol. The amplitude in the I-axis direction is the value of the I-axis of the coordinates on the complex plane corresponding to the received symbol, and the amplitude in the Q-axis direction is the value of the Q-axis. The axis for calculating the amplitude will be unified. In this example, the histogram determination unit 42 shall obtain the amplitude in the I-axis direction. The histogram determination unit 42 obtains the number of occurrences for each amplitude in the I-axis direction, generates histogram data, and outputs the generated histogram data to the distribution determination unit 43.

FIG. 5 shows a histogram shown by the histogram data generated by the histogram determination unit 42. In FIG. 5, the horizontal axis is the amplitude in the I-axis direction, and the vertical axis is the number of occurrences (frequency). In the case of 16QAM, the amplitude of the 16 reference symbols in the I-axis direction is one of -3, -1, 1, and 3 when normalized. Therefore, in general, the histogram has a shape having peaks in the vicinity of amplitudes -3, -1, 1, and 3 as shown in FIG. In a communication system in which the appearance probabilities of the symbols are the same, the peaks in the vicinity of amplitudes -3, -1, 1, and 3 have similar values. However, since the communication system of the present embodiment uses PS technology, the appearance probabilities of each symbol are not uniform, and therefore the peak values (frequency) are different.

The distribution determination unit 43 approximates the histogram showing the histogram data with a curve by curve fitting. Then, the distribution determination unit 43 determines the four Gaussian distributions of the variance V notified by the noise determination unit 41 so as to best match the approximated curve. The reason for setting four is that in 16QAM, the number of amplitudes in the I-axis direction is four. Generally, in the case of M-QAM, if N ² = M, N distributions will be obtained. The four Gaussian distributions are obtained so that the area of the region surrounded by the four Gaussian distributions and the straight line having a probability density of 0 is 1.

FIG. 6 shows four Gaussian distributions obtained by the distribution determination unit 43. The distribution determination unit 43 notifies the intersection determination unit 44 of the distribution data indicating the obtained four Gaussian distributions. The intersection determination unit 44 finds the intersections of two adjacent Gaussian distributions out of the four Gaussian distributions. For example, if the four Gaussian distributions obtained by the distribution determination unit 43 are as shown in FIG. 6, the intersection determination unit 44 obtains a total of three intersections of the intersection 71, the intersection 72, and the intersection 73. The intersection 71 corresponds to the threshold 51 and the threshold 61 of FIG. 2, the intersection 72 corresponds to the threshold 52 and the threshold 62 of FIG. 2, and the intersection 73 corresponds to the threshold 53 and the threshold 63 of FIG. The intersection determination unit 44 notifies the demodulation unit 3 of the three threshold values thus obtained as the threshold set #k.

For example, the threshold value 73 is used to determine whether it is a reference symbol having an amplitude of 3 or a reference symbol having an amplitude of 1. Here, even if the reference symbol has an amplitude of 3, if the amplitude of the receiving symbol is smaller than the threshold value 73, the receiving device erroneously determines that the reference symbol has an amplitude of 1. That is, the area of the rightmost distribution in FIG. 6 having a threshold of 73 or less indicates the probability of erroneously determining the reference symbol of amplitude 3 as the reference symbol of amplitude 1, and the area of the distribution to the left of the reference symbol of amplitude 73 or more. The area of the portion indicates the probability that the reference symbol having the amplitude 1 is erroneously determined as the reference symbol having the amplitude 3. As is clear from FIG. 6, by setting the intersection of two adjacent distributions as the threshold value, the overall probability of erroneous determination can be reduced.

As described above, the amplitude distribution in the I-axis or Q-axis direction of the actual received symbol is used to determine the threshold value used to determine which reference symbol of M-QAM the received symbol corresponds to. The amplitude distribution is determined in consideration of the noise dispersion of the actual received symbol. With this configuration, in a communication system using PS technology, the threshold value can be dynamically controlled based on the measured value.

In the present embodiment, the distance between the received symbol and the reference symbol of M-QAM closest to the received symbol is used as noise. However, the reference symbol transmitted by the transmitting device is not always the reference symbol closest to the received symbol, and if the transmitted reference symbol is not the reference symbol closest to the received symbol, the noise is evaluated to be small. .. However, in an actual communication system, the probability that the transmitted reference symbol is not the reference symbol closest to the received symbol is sufficiently small, and therefore does not significantly affect the required noise variance V.

<Other Embodiments>
In the above embodiment, the noise determination unit 41 determines that the distance between the received symbol and the symbol of M-QAM, which is the closest to the received symbol, is the noise of the received symbol. However, since the histogram is determined based on the amplitude in the I-axis direction, the difference between the I-axis value of the coordinates on the complex plane corresponding to the received symbol and the I-axis value of the coordinates of the reference symbol closest to the received symbol. Can also be configured to obtain the variance as the noise of the received symbol. In this case, when determining the histogram based on the amplitude in the Q-axis direction, the variance is obtained from the noise in the Q-axis direction.

Further, in the above embodiment, the threshold value 51 and the threshold value 61 are set to the same value, the threshold value 52 and the threshold value 62 are set to the same value, and the threshold value 53 and the threshold value 63 are set to the same value. However, the threshold value 51, the threshold value 52, and the threshold value 53 in the I-axis direction and the threshold value 61, the threshold value 62, and the threshold value 63 in the Q-axis direction can be individually obtained. In this case, the threshold in the I-axis direction is obtained based on the histogram based on the amplitude in the I-axis direction and the variance of the noise in the I-axis direction, and the threshold in the Q-axis direction is the histogram based on the amplitude in the Q-axis direction and the Q-axis. Obtained based on the dispersion of directional noise.

Further, in the above embodiment, the distribution determination unit 43 approximates the histogram showing the histogram data with a curve by curve fitting, and determines a plurality of (N) Gaussian distributions of the dispersion V so as to best match the approximated curve. Was. However, the amplitude of N peak values is determined based on the histogram, the average value is used as this peak value, and the variance is determined as the variance V notified from the noise determination unit 41. Is also good. The range of amplitude for determining the peak value may be limited based on the amplitude of the reference symbol. Further, instead of finding the N peak values based on the histogram and finding the Gaussian distribution averaging them, the N amplitudes of the reference symbols are used as the averaging values, and the variance is notified by the noise determination unit 41. It is also possible to obtain a Gaussian distribution of N pieces as V.

Further, in the above embodiment, as shown in FIG. 3, the threshold value determination unit 4 continuously obtains the threshold value set for each received symbol string, but the threshold value set may be intermittently obtained. In this case, the demodulation unit 3 updates the threshold value set used for demodulation each time the threshold value determination unit 4 notifies the threshold value set. Further, the transmitting device may periodically transmit a known symbol string to the receiving device as a training sequence, and the threshold value determination unit 4 may be configured to obtain a threshold set each time the transmitting device transmits the training sequence. .. Further, the threshold value determination unit 4 may be configured to update the threshold value set aperiodically instead of periodically updating the threshold value set. For example, the threshold value determination unit 4 may determine the threshold value set from the training sequence or the received symbol each time a predetermined trigger such as when the communication is started or when the communication is returned from the communication interruption occurs.

The processing in the threshold value determination unit 4 according to the present invention can be performed by executing an appropriate program on one or more processors. That is, the present invention can be realized by a computer program that operates the device as the above-mentioned receiving device when executed by the one or more processors of the device having one or more processors. These computer programs are stored in a computer-readable storage medium or can be distributed over a network.

1: Light source, 2: Receiver unit, 3: Demodulation unit, 4: Threshold determination unit, 41: Noise determination unit, 42: Histogram determination unit, 43: Distribution determination unit, 44: Intersection determination unit

Claims (8)

A receiver for a communication system that uses quadrature amplitude modulation.
A noise determination means for determining the dispersion of noise based on the noise of each of a plurality of received symbols,
A histogram determining means for determining the histogram, which is a histogram of the amplitude of the received plurality of symbols in the complex plane in the first direction, wherein the first direction is the real axis direction or the imaginary axis direction.
A plurality of amplitudes in the first direction in the receiving device for each of the plurality of reference symbols defined by the quadrature amplitude modulation based on the histogram determined by the histogram determining means and the variance determined by the noise determining means. Distribution determination means for determining distribution and
A threshold value determination means for determining one or more threshold values for determining which of the plurality of reference symbols the received symbol corresponds to based on the intersection of the plurality of distributions.
A receiver characterized by being equipped with. The receiving device according to claim 1, wherein the noise determining means determines the minimum value of the distance between the received symbol and each of the plurality of reference symbols as the noise of the received symbol. The noise determining means determines the distance in the first direction between the received symbol and the reference symbol having the shortest distance between the received symbol among the plurality of reference symbols as the noise of the received symbol. The receiving device according to claim 1. The reception according to any one of claims 1 to 3, wherein the number of the plurality of distributions determined by the distribution determination means is equal to the number of amplitudes of the plurality of reference symbols in the first direction. apparatus. The receiving device according to claim 4, wherein the variance of the plurality of distributions determined by the distribution determining means is equal to the variance determined by the noise determining means. The receiving device according to claim 5, wherein the distribution determining means obtains a curve that approximates the relationship between the amplitude and the frequency shown by the histogram by curve fitting, and determines the plurality of distributions based on the curve. .. The receiving device according to any one of claims 1 to 6, wherein one or more threshold values determined by the threshold value determining means are used in both the real axis direction and the imaginary axis direction. A program according to any one of claims 1 to 7, wherein when executed by the one or more processors of a device having one or more processors, the device functions as a receiving device according to any one of claims 1 to 7.

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