JPH08181722A - Receiver in multi-level signal communication system - Google Patents

Abstract

PURPOSE: To obtain a reference level accurately at demodulation by controlling an amplification factor of an amplifier based on a mean value between a minimum voltage and a maximum voltage detected for a prescribed preceding period. CONSTITUTION: A maximum/minimum voltage amplifier arithmetic unit 53 detects a minimum value of data Q for a class A basic period and a maximum value of the data Q for a class B basic period. Then a mean value for a prescribed period is calculated. Moreover, the mean value of a voltage difference at that time is calculated based on the mean value of the minimum voltage and the mean value of the maximum voltage. The voltage difference mean data R are given to a D/A converter 56, and a maximum minimum mean voltage difference signal S is given to an inverting input terminal of a differential amplifier 58 via a low pass filter 59. Furthermore, a reference voltage is given to a noninverting input terminal of the differential amplifier 58 and a difference voltage U between the mean voltage difference signal S and a reference voltage T is inputted to a control terminal of gain control amplifiers 11, 12 to change the amplification factor of the amplifiers 11, 12.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a receiver used in a communication system for converting binary data into a multilevel signal and transmitting the multilevel signal. In particular, it relates to one in which the amplitude of the received signal is stabilized.

[0002]

2. Description of the Related Art Conventionally, in data transmission, a method is known in which a carrier of a predetermined frequency is modulated in amplitude, frequency and phase by using binary data. However, this method has a problem in terms of transmission efficiency, and there is known a method of performing amplitude, frequency, and phase modulation on a carrier wave by using multilevel data obtained by collecting 3 to 4 bits of binary number data.
In this method, the number of states of the modulated carrier wave increases and the transmission efficiency improves.

[0003]

However, for example, in the case of a communication method in which a carrier wave is amplitude-modulated by multivalued data and transmitted, it is necessary to quantize the demodulated wave into multivalued levels. Therefore, in order to perform accurate demodulation, it is necessary to accurately detect the amplitude reference and the sampling reference from the received signal. However, since the amplitude level of the received signal changes due to attenuation of the transmission line, temperature characteristics of the amplifier, aging, and the like, automatic gain control (AGC) is usually performed to keep the amplitude stable. However, when the modulation signal is a multilevel random signal, it is difficult to always obtain a stable and accurate control voltage.

The present invention has been made to solve the above problems, and an object thereof is to stabilize the level of a received multilevel signal in mutual conversion between data and multilevel signal. In addition, the reference level at the time of demodulation can be accurately obtained from the received signal.

[0005]

The invention according to claim 1 relates to a receiver used in a communication system for converting the following new binary data into a multilevel signal. The structure of binary data is 2 per 1 data (also called symbol).
It is a decimal number n bits. The multilevel signal is the data value m
Is a multilevel signal corresponding to = 2 ⁿ . In the area of the multilevel signal, one basic period is composed of m time slots from the 0th time slot (also referred to as a symbol period) to the (m-1) th time slot, and the level is from the 0th level to the mth time slot. -1 level and the upper reference level above the (m-1) th level, which is a total of m + 1 multilevel levels. Further, consecutive basic periods are defined alternately as type A basic period and type B basic period.

The type A basic period is a period in which the data value is shifted to the upper level by one level to generate a multilevel signal as will be described later, and the type B basic period uses the data value as it is as a multilevel signal. It is a period to do.

In the binary data area, one group of data is m
Of the m pieces of data of one group, the data that appears at a predetermined kth position from the beginning of the group is defined as index data. The value of the index data is the time index value T, and the remaining m-1 pieces of normal data j are the level values L _j.
It is said.

In order to obtain the amplitude reference and the timing reference at the time of reception, with respect to the index data, in the T-th time slot, the multi-value having the 0th level in the type A basic period and the upper reference level in the type B basic period is used. It is used as a level signal. Regarding the normal data j, only the T-th time slot is skipped, and the level value L _j of the normal data j is shifted up one level in the A type basic period in the time slot corresponding to the position where the normal data j exists in the first group. A multilevel signal having the level value L _j +1
In the B type basic period, it is a multilevel signal which takes the level value L _j of the normal data j.

The present invention is a receiver for receiving a multilevel signal in the above communication system. That is, the receiving apparatus of the present invention detects the minimum voltage value of the multilevel signal within the basic period for the type A basic period and the amplifier that receives and amplifies the multilevel signal from the transmission line. ,
For the type B basic period, a maximum / minimum value detecting means for detecting the maximum voltage value of the multilevel signal within the basic period, and an average value of the minimum voltage value and the maximum voltage value detected in a certain past period. And an amplification factor control means for controlling the amplification factor of the amplifier.

Further, in the receiver of the invention of claim 2, in the area of the multilevel signal, the invention of claim 1 sets the upper reference level, while the lower reference level below the 0th level, The only difference is that it is configured by a total of m + 1 multi-valued levels from the 0th level to the (m-1) th level. Therefore, A
In the seed basic period, the index data is a multivalued level signal of the m−1th level, and the normal data j is a multivalued level signal that takes a level value L _j −1 obtained by shifting the level value L _j to one level lower, A device having the same configuration as in claim 1, which is used in a communication system in which index data is a multilevel signal of a lower reference level in the type B basic period, and normal data j is a multilevel signal having a level value L _j. Is.

Further, in the above-mentioned claims 1 and 2, each level number is an index of the level and does not indicate an absolute voltage level. The level is based on the B type basic period so that there is no level shift in the B type basic period.
It shall be indexed. Therefore, when considering a multi-valued level with an absolute voltage level, a voltage value corresponding to a binary data value that is shifted by one voltage scale to an upper position is a type A basic period voltage memory that is not shifted. In addition to the type B basic period, one shifted to the upper side by 1 voltage scale / 2 may be set as the type A basic period and one shifted to the lower side by 1 voltage scale / 2 may be set as the type B basic period. That is, in the definition of the above claims, the voltage level of the B type basic period after conversion is defined as a level after indexing. Therefore, the 1-level shift is a relative concept in the type A basic period and the type B basic period.

According to a third aspect of the present invention, there is provided a receiving apparatus, wherein the level of the multilevel signal is set to m levels, that is, a lower reference level lower than the 0th level and an upper reference level higher than the (m-1) th level.
It is the addition of one level. Therefore, regarding the index data, in the T-th time slot, a multi-level signal having a lower reference level in the type A basic period and an upper reference level in the type B basic period is used. Regarding the normal data j, it is used in a communication system in which only the T-th time slot is skipped and a multi-value level signal that takes the level value L _j of the normal data _j is taken in the time slot corresponding to the existing position of the normal data j in the first group. The device has the same configuration as that of claim 1.

In all claims, the values 0, 1, ..., M-1 of the 0th level, the 1st level, ..., The m-1th level are indexes attached to the levels of the multilevel signal, Value L
_j also means the value of the level index. Therefore, the absolute voltage values corresponding to the lower reference level, the 0th level, the first level, ..., The m−1th level, and the upper reference level do not have to be at equal intervals. For example, from the 0th level to the m-1th level, absolute voltage values are set at equal intervals, and the lower reference level and the 0th level are set.
The voltage difference with the level and the voltage difference between the upper reference level and the (m-1) th level can be arbitrarily set to twice, 3/2 times, or the like of the above-mentioned equal-interval voltage difference. The absolute voltage values of the lower reference level and the upper reference level are used to generate the absolute reference voltage value corresponding to each level in order to quantize the voltage value of the time slot detection timing and the multilevel signal. . Since the levels do not have to be equally spaced in voltage, the concept of levels merely means an indicator. Therefore, shifting to one level higher or lower means shifting to one level higher or lower by one index even if the voltage values are unequal intervals. Level value L _j one by level was higher or shifted to a lower value L _j + 1, L _j -1
Also means the level index value, not the absolute voltage value.

According to a fourth aspect of the present invention, the amplification factor control means removes a value having a deviation of a predetermined value or more from the average value in the minimum voltage value and the maximum voltage value detected in a certain past period. The amplification factor of the amplifier is controlled on the basis of the average value after the above. The invention according to claim 5 is such that the voltage difference between the average value of the maximum value and the average value of the minimum value becomes a predetermined value. It is characterized by controlling the amplification factor of.

[0015]

According to the present invention, the value T of the index data is alternately set to the 0th level or the upper reference level (in the Tth time slot of the multilevel signal in consecutive basic periods). It is converted as a multivalued level signal of claim 1), the m-1th level or the lower reference level (claim 2), the lower reference level and the upper reference level (claim 3). The values L _j of other normal data j excluding the index data are as follows:
It is shifted to the level L _j +1 one level above (claim 1) or to the level L _j -1 one level below (claim 2). In the B type basic period, the value L _j of the normal data j becomes the level value of the multilevel signal as it is. The method of claim 3 has no level shift. The type A basic period and the type B basic period appear alternately. Information on the maximum amplitude of the multilevel signal can be transmitted by the level value of the multilevel signal of the index data. Further, in this method, one group of m data having n bits as one data has m time slots of m + 1 level (claims 1 and 2) and m + 2 level (claim 3) as one basic period. Is converted into a multilevel signal. At this time, the index data uses the time slot number as the transmission information, but m time slots can be taken.
Since the index data can also be data having the same number of bits as the normal data, the transmission efficiency is the same as when all m data are multivalued level signals.

In the communication system according to claim 1, the multilevel signal is irrespective of the value of the original binary data,
A 0th level signal always appears in one time slot in the type A basic period, and an upper reference level signal always appears in one time slot in the type B basic period. Therefore, the minimum voltage value detected in the type A basic period is the 0th level signal, and the maximum voltage value detected in the type B basic period is the upper reference level signal.

In the communication system according to the second aspect, the multilevel signal is A regardless of the value of the original binary data.
The m-1th level signal always appears in one time slot in the seed basic period, and the lower reference level signal always appears in one time slot in the class B basic period. Therefore, the maximum voltage value detected in the type A basic period is the m-1th level signal, and the minimum voltage value detected in the type B basic period is the lower reference level signal.

Further, in the communication system of claim 3,
Regardless of the value of the original binary data, a multilevel signal always has a lower reference level signal in one time slot during the type A basic period and an upper reference level during one time slot during the type B basic period. Signal appears. Therefore,
The minimum voltage value detected in the type A basic period is a lower reference level signal, and the maximum voltage value detected in the type B basic period is an upper reference level signal.

Therefore, if the amplification factor of the amplifier is controlled on the basis of the average value of the minimum voltage value and the maximum voltage value detected in the past fixed period, it corresponds to the level value of the multilevel signal output from the amplifier. The voltage applied is stable. As a result, the voltage of the multilevel signal is stable, and the stable reference voltage when quantizing the multilevel signal can be used, so that the accuracy of conversion into binary data is improved. In addition, by using an average value after removing a value having a deviation of a predetermined value or more from the average value in the minimum voltage value and the maximum voltage value detected in a certain period in the past, the quantization level is further improved. Be accurate. Further, by controlling the amplification factor of the amplifier so that the voltage difference between the average value of the maximum value and the average value of the minimum value becomes a predetermined value, a stable and highly accurate quantization level can be obtained.

[0020]

EXAMPLES The present invention will be described below based on specific examples. First embodiment

The conversion method of the present invention will be described below. In the method of this embodiment, 1 data, n = 3 bits, m = 8, the number of levels m + 1 = 9, and the upper reference level B on the (m−1) th level.
(M-th level) is set, the number of time slots is 8, the number of data of one group is 8, k = 1, that is, the index data is at the head of one group.

The data sequence is specifically a binary number, and the first group is 110,010,100,010,101,00.
1,010,100, the second group is 010,011,01
0,110,111,100,001,011, the third group is 111,100,011,111,011,01
It is 0,001,100. In octal notation O'x ', the eight data of the first group are O'6242 in the order of occurrence.
5124 ', the 8th data of the second group is O'23267
413 ', the 8th data of the third group is O'743732
14 '. Since the index data is the head data of each group, the first group is O'6 ', the second group is O'2', and the third group is O'7 '.

Conversion of First Group Data The first group of binary data is converted to the multivalued level of the first basic period. First, since the index data of the first group is O′6 ′, this value 6 is set as the time index value T, and is set as the 0th level signal in the Tth time slot, that is, the sixth time slot. Next, the second data to the eighth data are the normal data j, but in this order, only the sixth time slot is skipped and seven time slots from the 0th time slot to the 7th time slot are allocated. .
In this case, the second data is assigned to the 0th time slot, the third data is assigned to the first time slot, the seventh data is assigned to the fifth time slot, and the eighth data is assigned to the seventh time slot.

Next, 2 from the second data to the eighth data
The normal data j of the base number is multivalued. This level value L _j
Is specifically 2,4,2,5,1,2,4.
Next, since the first basic period is the type A basic period, the level value L _j is shifted upward by one level.
That is, 3,5,3,6,2,3,5.

Next, the signal level of the multi-valued data of the first group data including the index data is synchronized with the synchronization signal shown in (1) of FIG. 1 and the 0th time slot of the first basic period. From the 7th time slot to 3, 5, 3, 6, 2, 3,
It is arranged as 0,5.

Conversion of Second Group Data Next, the conversion of the binary data of the second group into multi-valued levels will be described. The second group of binary data is converted to a multivalued level for the second basic period. First, since the index data of the second group is O′2 ′, this value 2 is the time index value T,
In the T-th time slot, that is, the second time slot, the signal is of the upper reference level B (m-th level, eighth level). Next, the second data to the eighth data are the normal data j, but in this order, only the second time slot is skipped and seven time slots from the 0th time slot to the 7th time slot are allocated. . In this case, the second data is the 0th time slot, the third data is the first time slot, the fourth data is the third time slot, the fifth data is the fourth time slot ... The seventh data is the seventh time slot. Assigned.

Next, 2 from the second data to the eighth data
The normal data j of the base number is multivalued. This level value L _j
Is, specifically, 3,2,6,7,4,1,3.
Next, since the second basic period is the B type basic period, the level shift of the level value L _j is not performed.

Therefore, the signal level of the multi-valued data of the second group data including the index data is synchronized with the synchronization signal (clock) shown in (1) of FIG.
From time slot 7 to time slot 3, 2,
B, 6, 7, 4, 1, 3 are arranged.

Next, the third group data is converted into the multivalued level of the third basic period. Since the third basic period is the same type A basic period as the first basic period, the level value L _j of the normal data j is shifted by one level to the upper level, as in the first basic period. Is converted to. As described above, the level value L _j of the normal data is alternately shifted up by one level in the A type basic period and the B type basic period, as shown in (4) of FIG.

As described above, one group of data consisting of 8 data of 3 bits is used as one unit, and the data of one group is 1
It is converted into a multilevel signal in the basic period. In the transmission line, each of the above 9 levels is transmitted at a voltage level of -4V to 4V in 1V intervals. In the level shift, when considering the absolute voltage level and shifting to 0.5V up in the A type basic period and 0.5V down in the B type basic period, the normal data is 1 level higher in the A type basic period. Will be shifted to.

After the multi-level signal is input to the low-pass filter, the output signal of the low-pass filter modulates the carrier wave of a predetermined frequency in amplitude, frequency, or phase to send it to the transmission line.

After demodulating the modulated signal received from the transmission line, a multilevel signal is extracted. Next, the reverse conversion of the multilevel signal into binary data will be described. First, each signal voltage of eight time slots in one basic period is sampled in synchronization with a synchronizing signal, converted into digital data, and temporarily stored in a buffer memory. next,
If one basic period is the type A basic period, the minimum voltage among the eight data is determined as the 0th level voltage value. If one basic period is the B type basic period, the maximum voltage among the eight data is determined as the voltage value of the eighth level. These voltage values are stored only for a predetermined fixed period for taking the average value. Also, the average value of them in the past certain period has been obtained, and the deviation between the average value and the detected minimum voltage value or maximum voltage value is calculated,
When the deviation is larger than the average value by a predetermined ratio or more, those values are removed from the values for calculating the average value.

Next, as shown in (3) of FIG. 1, the average voltage width W is calculated from the average maximum voltage value Max or the average minimum voltage value Min. This average voltage width W is a value that can change over time. If no noise is mixed in the transmission line or there is no instantaneous change in signal level, the maximum voltage value is + 4V and the minimum voltage value is -4V, so the average voltage width W is 8V. Next, from the average voltage width W to 1
The voltage difference between the levels is calculated by d = W / 8. As a result, each voltage value of the 9th level from the 0th level to the 8th level is determined at the receiving end.

Next, by using the voltage value of each level, 1
The voltage value of each signal in the basic period is quantized from 0th level to 9th level of 8th level. Specifically, in the example of the data of FIG. 1, the level values of the multilevel signal in the first basic period are 3,5,3,6,2,3,0,5.

Next, when the basic period is the type A basic period, the time slot number T of the data whose level value is 0 is calculated. In the example of the first basic period above,
Since the level value 0 exists in the sixth time slot, T
= 6. This value 6 is the demodulated value of the index data. Next, if the basic period is the type A basic period,
The level value 0 is erased from the data string and the level values are shifted by one level to the lower level for the remaining seven data. That is, 2, 4, 2, 5, 1, 2,
It becomes 4. Since the index data exists at the k-th position from the head of the group, that is, at the first position in this embodiment, the value 6 is located at the head of the group, and the other seven data are demodulated together. A group of data strings is generated. That is, the data string becomes O'62425124 '. In this way, the multilevel signal is converted back to the original binary data.

The multilevel signal in the second basic period is similarly processed. However, since the second basic period is the B type basic period, the maximum voltage value is detected as the voltage value corresponding to the upper reference level B (eighth level). By the same quantization processing as in the first basic period, the level values in the second basic period become 3,2, B, 6,7,4,1,3. In the case of the type B basic period, the level is not shifted downward. Next, the quantized level value is the upper reference level B
Is calculated. This value T is a value obtained by demodulating the index data of the B type basic period.
In the case of the second group data, T = 2. Next, the value 2 of the index data and the values of the other seven normal data j are set to 1
A group of demodulated data strings are generated by arranging them in a line.
That is, the data string becomes O'23267413 '. In this way, the multilevel signal is demodulated into the original binary data.

Thereafter, the multilevel signal is demodulated into binary data by the same processing. Also in the case of the reverse conversion, when the level shift is considered by the absolute voltage level as in the case of the forward conversion, it is possible to shift the A type basic period to one level lower than the normal data of the A type basic period. The voltage value of the multi-valued level signal is shifted by 1 V, the voltage value of the multi-valued level signal of the normal data of the B type basic period is not shifted, and the voltage value of the multi-valued level signal of the normal data of the A type basic period is −0. ．
There is a method of shifting by 5 V and shifting the voltage value of the multi-level signal of the normal data in the B type basic period by 0.5 V.

In the above embodiment, it is promised that the type A basic period and the type B basic period appear alternately.
Therefore, if the beginning of the data frame can be detected,
It can be determined that it is a type A basic period or a type B basic period. The detection of this data frame is performed when no data is transmitted.
By alternately outputting the maximum voltage and the minimum voltage and fixing the amplitude of the multilevel signal, the quantization level at the time of the inverse conversion can be determined. Further, as shown in FIG. 3, if the identification signal having the maximum level in at least two time slots and the minimum level in at least two time slots is transmitted in one basic period, the start of the data frame is detected. Is possible. This is because the data cannot take such a state.

Further, although it is necessary to generate a synchronization signal for detecting the time slot, the multilevel signal of the index data can be detected as the lowest level of the type A basic period and the maximum level of the type B basic period. Moreover, this signal always exists once in the basic period. With this signal, the phase locked loop (PL
L), and an accurate clock can always be reproduced.

FIG. 5 is a block diagram showing the configuration of the receiving apparatus of the present invention. The gain of the multilevel signal S1 received by the variable gain amplifiers 11 and 12 is controlled. The multilevel signal S1 is amplified by the amplifier 11, and then the signals from the local oscillator 13 are mixed and frequency-converted into the multilevel signal S1 of intermediate frequency. Thereafter, the bandpass filter 14 extracts a signal in a predetermined intermediate frequency band, and the amplifier 12 amplifies the intermediate frequency multilevel signal. The carrier recovery circuit 15 extracts a carrier from the signal and inputs it to the synchronous demodulator 16, and the synchronous demodulator 16 demodulates the multilevel signal S2. The demodulated multi-valued level signal S2 is input to the waveform equivalent filter 17 and shaped into a waveform. This signal A has the waveform shown in FIG.

This signal A is input to the non-inverting input terminal of the comparator 21 and the inverting input terminal of the comparator 22. The upper threshold voltage TH and the lower threshold voltage TL shown in FIG. 6 are input to the inverting input terminal of the comparator 21 and the non-inverting input terminal of the comparator 22 via the D / A converters 23 and 24, respectively. There is. This upper threshold voltage
TH and the lower threshold voltage TL can also be changed by a command value. As a result, the comparator 21 outputs the signal C shown in FIG. 6 and the comparator 22 outputs the signal D shown in FIG. The upper threshold voltage TH and the lower threshold voltage TL are voltages set to extract the 0th level signal and the upper reference level B signal, respectively. Therefore, the signal C is at H level only for the time slot having the upper reference level B, and the signal D is at 0th level.
It is a signal that becomes H level only in the time slot that takes the level.

On the other hand, the signal A is differentiated by the differentiating circuit 25 to obtain the signal B shown in FIG. The signal B is input to the non-inverting input terminal of the comparator 26, and the comparator 26
The inverting input terminal of is grounded. Therefore, the comparator 26 outputs the signal E shown in FIG. Signal E
Is a signal that becomes H level only during the rising period of the signal A. Further, the inverted signal E ^{* of the} signal E is obtained by the inverter 27.

The signal C is input to the AND gates 31 and 32,
The signal D is input to the AND gates 33 and 34. Also, the signal E
Is input to the AND gates 32 and 34, and the signal E ^* is input to the AND gates 31 and 33. Also, AND gates 33, 3
The period discrimination signal G is input to 4 and AND gates 31 and 32
A reversal period determination signal G ^* is input to. As a result,
From the AND gate 31, the signal I shown in FIG.
A signal H is output from 4. That is, the signal H is a signal which becomes the H level only in the latter half of the time slot which takes a voltage lower than the lower threshold voltage TL in the type A basic period, and the signal I is higher than the upper threshold voltage TH in the type B basic period. It is a signal that becomes H level only in the latter half of the time slot that takes a voltage. As a result, the time slot of the index data has been detected.

Signal H output from AND gate 33
^'Is a signal which becomes H level only the first half of the time slot to take a voltage lower than the lower threshold voltage TL in Type A base time period, the signal ^I' is above the threshold voltage in the B type basic period
This signal is H level only in the first half of the time slot that takes a voltage higher than TH. As a result, the time slot of the index data has been detected.

The signal I and the signal H are input to the OR gate 35, and the signal J is output from the OR gate 35 to the AND gate 37. The signal I ^'and the signal ^H' is input to the OR gate 36, the signal J ^'is output to the AND gate 38 from the OR gate 35. That is, the first half of the signal J is a signal representative of the second half of time slot index data of the A species fundamental period and Class B basic period, the signal J ^'is the time slot index data of the A species fundamental period and Class B basic period Is a signal that represents.

These signals J and J ^' , together with the signal L output from the frequency divider / 90 degree phase shifter 51, are combined with the AND gate 37,
38. The frequency divider / 90-degree phase shifter 51 outputs square wave signals K and L (FIG. 7) in which one time slot of the multilevel signal is one cycle. The signal L is 90 degrees ahead of the signal K in phase. Therefore, AND gate 37
The output signal M of the AND gate 38 is at the H level during the period in which the H level of the signal J and the H level of the signal L indicating the latter half of the time slot of the index data overlap, and the output signal N of the AND gate 38 is It is a signal that is at the H level in the section in which the H level of the signal J ^′ indicating the first half of the data time slot and the H level of the signal L overlap.

Signals O and P are waveforms obtained by smooth integration of signals M and N. That is, the levels of the signals O and P are proportional to the pulse widths of the signals M and N. Therefore, the output signal of the differential amplifier 41 indicates the level difference between the signal O and the signal P, and the voltage controlled oscillator 5
Enter 0. In the voltage controlled oscillator 50, the phases of the output signals K and L change according to the voltage value of the input signal. This closed loop forms a phase locked loop. That is,
The phases of the signals L and K are determined so that the pulse widths of the signal M and the signal N are equal. Therefore, the H level period of the signal L exists in the center of the time slot, and is 9 times higher than that of the signal L.
The rising edge of the signal K which is delayed by 0 degree indicates the center of each time slot.

Therefore, if the signal A is sampled by the A / D converter 52 in synchronism with the rising edge of the signal K, the level value in each time slot of the multilevel signal can be obtained. The data Q output from the A / D converter 52 is input to the maximum / minimum voltage width calculator 53. The maximum / minimum voltage width calculator 53 is the basic period discriminator 5
5 is inputted, the minimum value of the data Q in the A type basic period, that is, the minimum voltage value of the multilevel signal is detected, and the maximum value of the data Q in the B type basic period, that is, , Detect the maximum voltage value of the multilevel signal.
Then, a plurality of these values for a certain period in the past are always stored, and the average value thereof is calculated for the certain period. Therefore, the average value also changes with time.

The deviation between the newly input minimum voltage value or maximum voltage value and their average value is calculated, and when the deviation is equal to or more than a predetermined ratio of the average value, the newly detected minimum voltage value or maximum voltage value. Is removed as an abnormal signal. Only the minimum voltage value or maximum voltage value that is not an abnormal voltage is valid,
The value is used to calculate a new average value. Then, from the average value of the minimum voltage values and the average value of the maximum voltage values, the average value of the voltage difference at that time (hereinafter referred to as the average voltage difference value) is calculated. This voltage difference average value data R is D / A
The maximum and minimum average voltage difference signal S is input to the converter 56.
Input to the inverting input terminal of the differential amplifier 58 via the low-pass filter 59. The reference voltage output from the D / A converter 57 is input to the non-inverting input terminal of the differential amplifier 58 via the low-pass filter 60, and the difference voltage U between the average voltage difference signal S and the reference voltage T is , Gain control amplifier 1
Input to the control terminals of 1 and 12, and the amplifiers 11 and 12
Change the amplification factor of.

That is, the amplification factors of the amplifiers 11 and 12 are such that the average value of the voltage difference between the minimum voltage value B of the type A basic period and the maximum voltage value of the type basic period in the past constant period has a constant value. Negative feedback will be controlled. Therefore, the voltage value of each level of the multilevel signal A is stable. As described above, the timing signal K for sampling the multilevel signal A is generated from the multilevel signal A, and the signal A is quantized by the quantizer / violation code discriminator 54 to each level value L _j. .

In this way, the amplitude of the multi-level signal A becomes constant, so that the voltage value at each level does not fluctuate, and accurate quantization is possible.

In the above embodiment, the amplitude modulation method is used as the method of modulating the carrier wave with the multilevel signal, but any modulation method can be adopted. In addition, a demodulation method that is suitable for these modulation methods can be adopted.
Can also be used for modulation.

Second Embodiment A conversion method of another embodiment will be described below. In the system of this embodiment, 1 data, n = 3 bits, m = 8, number of levels m + 2
= 10, with lower reference level A and upper reference level B,
The number of time slots is 8, the number of data of one group is 8, k = 1, that is, the index data is at the head of one group.

In the first embodiment, the multilevels of the index data are alternately set to the 0th level and the upper reference level B (mth level (8th level)) in a continuous basic period, and the 0th level is used as the index data. When it is used as the multi-valued level, the multi-valued level of the normal data is shifted up by one level so that the 0th level and the value 0 of the normal data do not overlap. On the other hand, in the second embodiment, two levels of the lower reference level A and the upper reference level B are additionally added to m levels, and the multi-valued levels of the index data are alternately lowered in consecutive basic periods. The reference level A and the upper reference level B are assigned, and the multi-value level of normal data is assigned to m multi-value levels. Therefore, in the second embodiment, it is not necessary to perform a shift operation of multi-value level at the time of conversion and inverse conversion.

The same data sequence as in the first embodiment will be described. That is, the first group data is O′62425124 ′, the second group data is O′23267413 ′, and the third group data is
In O'74373214 ', the values of the index data appearing at the head of each group are 6, 2, and 7, respectively. Therefore, the sixth time slot of the first basic cycle is set to the lower reference level A, the second time slot of the second basic cycle is set to the upper reference level B, and the seventh time slot of the third basic cycle is set to the lower reference level A. To be done. Then, except for those time slots, in order, in each time slot, the multilevel levels O'2425124 'and O'32674 of the normal data are sequentially arranged.
13 'and O'4373214' are allocated.

As described above, the multi-valued levels of the index data are alternately assigned to the lower reference level A and the upper reference level B.

Next, demodulation of a multilevel signal into binary data will be described. The demodulation is performed almost in the same way as in the first embodiment. That is, in the case of the type A reference period (the period in which the lower reference level A is used), the minimum voltage among the signal voltages of the eight time slots in one basic period is determined as the voltage value of the lower reference level A. It On the other hand, in the B type basic period (the period in which the upper reference level B is used), the maximum voltage among the eight pieces of data is determined as the voltage value of the upper reference level B. These voltage values are stored until the demodulation of the signal in the next basic period is completed.

As in the first embodiment, as shown in FIG. 2C, the average voltage width W is calculated from the average maximum voltage value Max and average minimum voltage value Min excluding the abnormal voltage in the past fixed period. Is calculated, and the voltage difference between one level from the average voltage width W is calculated as d = W / 9. As a result, each voltage value of the lower reference level A, the 0th level to the 7th level, and the 10th level of the upper reference level B is determined at the receiving end.

Next, by using the voltage value of each level, 1
The voltage value of each signal in the basic period is quantized into the above 10 levels. Specifically, in the example of the data in FIG. 2, the level values of the multilevel signal in the first basic period are 2, 4, 2,
5, 1, 2, A, 4, the multilevel signal level value in the second basic period is 3, 2, B, 6, 7, 4, 1, 3, and the multilevel signal level value in the third basic period. Is 4, 3, 7,
It becomes 3,2,1,4, A.

Next, the time slot number T of the data whose level values are A and B is calculated according to the basic period of type A basic period and the type B basic period. This value is 6, 2, and 7 in the above three groups of data. Next, since these values are multi-level values of the index data of each group,
The data string excluding the value A and the value B is generated by being positioned at the k-th, that is, the head of each group. As a result, the multilevel halftoning level signal of the first reference period is O′62425124 ′, the multilevel halftone level signal of the second reference period is O′23267413 ′,
The multilevel signal for the third reference period is O'74732
14 'is converted back. In this way, the multilevel signal is converted back to the original binary data.

Thereafter, the multi-level signal is inversely converted into binary data by the same processing. In this embodiment, since the multi-level signal indicating the beginning or end of the data frame has the lower reference level A and the upper reference level B, the pattern shown in FIG. 4 can be considered. That is, if the signal of two basic periods is received, the maximum level and the minimum level can be detected, and the quantization level can be accurately determined. So after that, 1
It can be distinguished from data by a signal indicating that the maximum level appears in at least two time slots or the minimum level appears in at least two time slots in the basic period.

Also in the communication system of this embodiment, by using the receiving apparatus having the same configuration as that of the first embodiment to stabilize the amplitude of the multilevel signal, the quantization accuracy of the signal can be improved. It will be possible.

In addition, in the first embodiment shown in FIG.
The voltage values at each level from the level to the eighth level were set at equal intervals (u volts). However, as shown in FIG.
The level and the upper reference level B (eighth level) may be provided with a difference of 2 uV in voltage value from the first level and the seventh level. Further, in the second embodiment shown in FIG. 2, the voltage values of the respective levels from the lower reference level A to the upper reference level B are set at equal intervals (u volts). However, as shown in FIG. 9, the lower reference level A and the upper reference level B may be provided with a voltage difference of 2 u volts with respect to the 0th level and the 7th level.

Further, if the predetermined period for averaging is set to be long, it is not necessary to specifically perform the abnormal signal removing process for excluding the detected maximum voltage value and minimum voltage value having a large deviation from the average value thereof. In the above embodiment, the gain of the amplifier is continuously controlled in time so that the average voltage difference at that time becomes a constant value. However, the gain of the amplifier in the next predetermined period may be controlled discontinuously by using the deviation of the average difference voltage in the past certain period from the target voltage difference.

[Brief description of drawings]

FIG. 1 is a timing chart illustrating a conversion method according to a first specific example of the present invention.

FIG. 2 is a timing chart illustrating a conversion method according to a second specific example of the present invention.

FIG. 3 is a waveform diagram showing a pattern of a multilevel signal indicating the beginning or end of a data frame in the first embodiment.

FIG. 4 is a waveform diagram showing a pattern of a multilevel signal indicating the beginning or end of a data frame in the second embodiment.

FIG. 5 is a block diagram showing a configuration of a receiving device according to an embodiment.

FIG. 6 is a timing chart illustrating the operation of the receiving device according to the embodiment.

FIG. 7 is a timing chart illustrating the operation of the receiving device according to the embodiment.

FIG. 8 is a timing chart illustrating a conversion method according to a modified example of the first embodiment.

FIG. 9 is a timing chart illustrating a conversion method according to a modified example of the second embodiment.

[Explanation of symbols]

 A ... Lower reference level B ... Upper reference level T ... Time index value

Claims (5)

[Claims] 1. A communication system in which data composed of binary n bits per data is converted into a multilevel signal corresponding to a value m = 2 ⁿ of the data and the multilevel signal is transmitted. Therefore, m time slots from the 0 th time slot to the m−1 th time slot are set as one basic period, and from the 0 th level to the m−1 th level and the upper reference level above the m−1 th level, A total of m + 1 multi-valued levels are set, and the continuous basic periods are alternately set as the A type basic period and the B type basic period, and one group corresponding to the basic period is configured by m pieces of data. Of the m pieces of data, the value of the index data that appears at the predetermined k-th position from the beginning of the group is the time index value T, and the remaining m
-1 is the level value L _j of the normal data j, and the index data is a multi-valued level having the 0th level in the type A basic period and the upper reference level in the type B basic period in the Tth time slot. For the normal data j, only the T-th time slot is skipped, and the level value of the normal data j in the A type basic period is set in the time slot corresponding to the position where the normal data j exists in one group. A multi-valued level signal having a level value L _j +1 obtained by shifting L _j one level higher is sent to the transmission line as a multi-valued level signal having the level value L _j of the normal data j in the B type basic period. In the receiving device used in the communication method, an amplifier that receives and amplifies the multilevel signal from the transmission line, and The minimum voltage value of the multilevel signal within the basic period is detected, and the maximum voltage value of the multilevel signal within the basic period is detected for the B type basic period. Minimum value detection means, and amplification factor control means for controlling the amplification factor of the amplifier based on an average value of the minimum voltage value and the maximum voltage value detected in a certain period in the past, Receiving device. 2. A communication system in which data composed of binary n bits per data is converted into a multilevel signal corresponding to the value m = 2 ⁿ of the data and the multilevel signal is transmitted. Therefore, m time slots from the 0th time slot to the (m-1) th time slot are defined as one basic period, and the lower reference level below the 0th level and the 0th level to the (m-1) th level, a total of m + 1. The multi-value level is set, and the consecutive basic periods are alternately set as the A type basic period and the B type basic period, and one group corresponding to the basic period is configured by m data, Value of the index data appearing at a predetermined kth position from the head of the group is set as the time index value T, and the remaining m
The value of one piece of normal data j is set as a level value L _j , and the index data has a m−1th level in the type A basic period and a lower reference level in the type B basic period in the Tth time slot. As a value level signal, regarding the normal data j, only the T-th time slot is skipped, and in the time slot corresponding to the existence position of the normal data j in one group, the normal data j A multi-valued level signal having a level value L _j -1 obtained by shifting the level value L _j to the lower level by one level and transmitted as a multi-valued level signal having the level value L _j of the normal data j in the B type basic period. A receiver used in a communication method for transmitting to a channel, an amplifier for receiving and amplifying the multilevel signal from the transmission channel, and the A-type basic period For the basic period, the maximum voltage value of the multilevel signal is detected, and for the B type basic period, the minimum voltage value of the multilevel signal is detected within the basic period. A maximum / minimum value detection means, and an amplification factor control means for controlling the amplification factor of the amplifier based on an average value of the minimum voltage value and the maximum voltage value detected in a certain period in the past. Receiving device. 3. A communication system in which data composed of binary n bits per data is converted into a multilevel signal corresponding to the value m = 2 ⁿ of the data and the multilevel signal is transmitted. Therefore, m time slots from the 0 th time slot to the m−1 th time slot are set as one basic period, and the lower reference level below the 0 th level, the 0 th level to the m−1 th level, the m th −
A total of m + 2 multi-valued levels are set with the upper reference level above one level, and the consecutive basic periods are alternately set as the A type basic period and the B type basic period, and one group corresponding to the basic period is set. It is composed of m pieces of data, and among the m pieces of data of one group, a value of index data appearing at a predetermined kth position from the head of the group is set as a time index value T, and the remaining m
-1 is the value of one piece of normal data j as a level value L _j, and with respect to the index data, in the T-th time slot, a multi-valued level having a lower reference level in the type A basic period and an upper reference level in the type B basic period With respect to the normal data j, a multi-valued level that takes the level value L _j of the normal data j in the time slot corresponding to the position where the normal data j exists in one group by skipping only the T-th time slot A receiver used in a communication system for sending out to a transmission line as a signal, comprising: an amplifier that receives and amplifies the multilevel signal from the transmission line; The minimum voltage value of the multilevel signal is detected, and the maximum voltage of the multilevel signal within the basic period is detected for the B type basic period. A maximum / minimum value detection means for detecting the above, and an amplification factor control means for controlling the amplification factor of the amplifier based on an average value of the minimum voltage value and the maximum voltage value detected in a certain period in the past. A receiving device characterized by the above. 4. The amplification factor control means after removing a value having a deviation of a predetermined value or more from an average value in the minimum voltage value and the maximum voltage value detected in the past fixed period. An amplification factor control means for controlling the amplification factor of the amplifier based on the average value, and the reception device according to claim 1. 5. The amplification factor control means controls the amplification factor of the amplifier so that a voltage difference between the average value of the maximum value and the average value of the minimum value becomes a predetermined value. The receiving device according to any one of claims 1 to 4.