UA77621C2 - Method for transmitting digital data analog communication facilities - Google Patents

Abstract

The proposed method for transmitting digital data analog communication facilities consists in modulating a harmonic analog signal with a digital signal, transmitting the modulated analog signal over the communication line, and demodulating the received signal for restoring the digital signal. The method is distinctive by using, as the modulated parameter, the amplitude, frequency, or phase of the harmonic signal. The received modulated signal is demodulated by comparing the instantaneous values of the modulated signal with the instantaneous values of the initial harmonic analog signal and comparing the difference of the said values with the threshold value. The proposed method provides a possibility to increase the carrying capacity of a data transmission system.

Description

Description of the invention

The invention relates to the field of data transmission, in particular to the transmission of digital information via an analog channel, namely to the transmission of radio and television signals, satellite and mobile communication signals, as well as to wireline communication systems, etc.

Modulation of the carrier harmonic signal with a useful digital signal is used to transmit discrete data through analog channels. At the same time, the requirement for a significant excess of the carrier frequency over the highest frequency component of the modulating signal in the case of discrete modulating signals, set forth in fundamental literary sources, is expressed in the fact that for reliable reproduction of the useful signal on the receiving side, the duration of the bit must include at least several periods of carrier oscillations.

At present, in wireless transmission of digital information, the accepted ratio of the carrier frequency to the frequency of the modulating signal is from 10000:1 to 1000:1.

For example, the modern data transmission standard IEEE 802.114 provides for data transmission in the frequency range of 2500 or 5000 MHz. The maximum possible ideal data transfer rate is 54 Mb/s, which corresponds to the indicated ratio of 46:1. However, it should be noted that this ratio is extremely difficult to achieve, even according to the manufacturer's statement. The real values of the data transfer speed are 1 Mbit/s, which corresponds to a ratio of 2500:1.

For example, from the description of the invention to the patent of the Russian Federation 2211530 C2 (date of publication 27.08.2003, IPC": НОЗМ 11/00, НО4И. 27/19) a method of information transmission is known, which consists in converting the first sequence of digital readings on the transmitting side into the first analog signal by multiplying with the signal of the given counting function; transmit the generated analog signal over the communication line; on the receiving side receive the transmitted analog signal from the communication line; restore the first sequence of digital counts from the received analog signal, which differs in that on the transmission side, the second c 29 sequence of digital readings is converted into a second analog signal by multiplying with the signal of the specified counting function, while the counting timings for the second digital counting sequence are placed between the counting timings for the first digital counting sequence; the first analog signal is obtained by converting digital from medicines, the values of which are equal to the difference between the digital readings of the mentioned first sequence and the values of the second analog signal at the timing of the readings - for the mentioned first sequence; sum up the first and second analog signals, after which the combined analog signal is transmitted over the communication line; on the receiving side, the digital readings of the mentioned first sequence are restored by discretizing the received analog signal with a clock frequency; The restored digital readings of the mentioned first sequence are converted into the first analog signal using the signal of the mentioned preset counting function; subtract the restored first analog signal from the received analog signal; restore the digital readings of the mentioned second sequence from the received - difference analog signal. According to the publication, the information capacity of a signal transmitted by an analog channel and, accordingly, the speed of transmission and reception of discrete information using a telephone line can be increased almost twice compared to standard signal processing. Currently, the most advanced technology for digital data transmission by subscriber telephone lines on ordinary copper wires is the HOBBY technology. In particular, the asymmetric digital subscriber line (DSL) provides a data transfer speed of 8 Mbit/s in the direction of the subscriber, and 1.5 Mbit/s in the reverse direction. :z» Together, the total bandwidth is 9.5 Mbit/s. In the full-scale version of AOBI. by technology

OMT entire frequency range from 0 to 1104kHz is divided into 256 carrier frequencies with a step of 4.3125kHz. Thus, the average bandwidth of one frequency channel with a width of about 4 kHz is approximately -1,395 only 37 kbit/s, which corresponds to the above-mentioned number of fluctuations of the carrier per one bit of information about 15:1.

The task of the invention is to develop a method of transmitting digital data through analog channels, in which by - I changing one or more parameters of the carrier frequency with a useful digital signal that has a bit frequency b" that exceeds the carrier frequency, a significant increase in the information capacity of the carrier signal is achieved.

The problem is solved in the method of transmitting digital data through analog channels, in which one or more than 50 parameters of harmonic oscillation are modulated by a transmitted digital sequence, the modulated analog signal is transmitted through an analog communication channel, received, and by demodulation, the initial digital sequence is obtained, in which, according to according to the invention, modulation is carried out by changing one or more parameters of the primary harmonic oscillation - amplitude, frequency, phase, polarization - according to the law of the sequence sequence, which has a follow-up frequency that exceeds the frequency of the primary harmonic oscillation, transmission of the carrier signal formed in this way by an analog data transmission channel, moreover

HF) demodulation of the signal received from the data transmission channel is carried out by comparing the instantaneous values of the received signal with the unmodulated signal, determining the positions and maximum values of the signal deviations, selecting the bit sequence by comparing the modulated parameters of the signal relative to the empirically determined threshold level. because In the form of implementation of the invention by the method of amplitude modulation with frequency heterodyning, the modulation is carried out by multiplying the primary harmonic oscillation with a bit sequence, multiplying the received signal with the local oscillator signal, the frequency of which is close to the frequency of the primary harmonic signal, selection of the modulated carrier with a difference frequency by a bandpass filter. At the same time, the signal received from the data transmission channel is pre-processed by a filter having a frequency response, the inverse frequency response of the bandpass filter during modulation.

As an unmodulated signal for extracting the carrier from the signal transmitted by the communication channel, in the case of amplitude modulation with heterodyning, a signal having a difference frequency is used, and in the case of the remaining types of modulation, a signal having the frequency of the primary harmonic oscillation can be used.

In principle, possible forms of implementation of the invention relating to amplitude and/or frequency and/or phase modulation and/or change of polarization of the signal. The form of implementation of the invention given in this description concerns the use of amplitude modulation of a harmonic carrier signal, as the most obvious for understanding. However, it is not exhaustive and does not limit the scope of harassment. With this type of modulation, there is a simple possibility of transferring the carrier frequency transmitted by the analog channel into the low-frequency region of the spectrum by means of heterodyning, which simplifies the requirements for the channel and for the means of hardware implementation of the method.

In the described form of implementation of the invention, a harmonic signal with a frequency of 200kHz was taken as a basis (Fig. 1).

A 400Kbit/s random bit sequence processed by the MK2 code was superimposed on the negative and positive half-waves of the period of the harmonic signal, observing the polarity. At the same time, the amplitude of the pulses exceeded the amplitude of the harmonic signal by 1000 times (Fig. 2).

After that, the harmonic signal of the local oscillator with a frequency of 16b0kHz was superimposed on the received signal (Fig. 3), as a result of which two components of the signal spectrum were obtained at the total (36bOkHz) and difference (40kHz) frequencies

IFig. 4).

The signal was filtered with a Gaussian filter at a frequency of 40 kHz with a bandwidth of 1095 at a signal level of 3 dB (Fig. 5).

After transmitting the thus formed carrier signal (Fig. b) through an analog communication channel, the received signal was subjected to inverse filtering to raise high frequencies using a filter with an amplitude-frequency response (frequency response), the inverse response frequency of a bandpass filter (Fig./( and)). Then, the carrier component was removed from the received signal by subtracting the harmonic signal having the carrier frequency.

After that, the positions and maximum values of signal changes were determined (Fig. 7(6)). In Fig. 7, the curve (c) in Corresponds to the signal of Fig. 2 and is shown for clarity and ease of understanding of signal processing.

After suppressing the low frequencies, the absolute values of the amplitude changes were determined and the transmitted i) random bit sequence was selected by comparison with the empirically determined relative level of 0.2 (Fig. 8(a)). On this graph, the curve (b) also corresponds to the signal of Fig. 2 and is given for clarity and ease of understanding of signal processing. "- zo When transmitting on a carrier with a frequency of 40 kHz, a random bit sequence with a bit rate of 400 Kbit/s was transmitted, received and decoded, which corresponds to the value of the above ratio of 1:10. with

Number of errors: 0. Ge

In the above-mentioned version of AOBI based on UOMT technology, the average bandwidth of one frequency channel with a width of about 4 kHz is approximately 37 kbit/s. At the same time, the proposed method of transmitting e-digital information (the described embodiment of the invention) at a frequency of 40 kHz with a frequency channel width of 1090 M (4 kHz) provides a bandwidth of 40 Okbit/s, which is an order of magnitude higher.

The proposed method of digital information transmission also has the following advantages compared to AYU technology. First, AOBI is based on quadrature modulation (OAM), in which the amplitude and phase of the carrier are modulated. The basis of the described form of implementation of the invention is amplitude modulation, which in comparison with "

All other modulation methods occupy the smallest frequency band. This provides, in particular, a decrease in inter-channel interference during multi-channel communication. . Secondly, the described embodiment of the invention is based on two-position amplitude modulation. And so?" thus, the normalized distance between the points of the constellation on the complex plane, which characterizes the immunity, is equal to 1. At the same time, the 16-position quadrature modulation of CAM has a distance equal to 0.47.

Thus, by means of signal processing according to the invention, a significant reduction of the -I ratio between the frequencies of the carrier and modulating signals is achieved to a value of 1:11 or less, which means an increase in the information capacity of the signal transmitted by the analog channel, as a result of which an increased data transmission speed is achieved. b The specified signal transformations for the purpose of preliminary determination of the parameters of the device components for the implementation of the method were also modeled on a computer using the MATIAV 7.0 program. where The experimental data corresponded to the simulation results with an acceptable deviation.

Claims (4)

- The formula of the invention 1. The method of transmitting digital information through an analog channel, in which one or more parameters (Ф) of harmonic oscillation are modulated by a transmitted digital sequence, the modulated analog signal GI is transmitted through an analog communication channel, received, and through demodulation, the initial digital sequence is obtained, which differs in that modulation is carried out by changing one or more parameters of the primary harmonic oscillation - amplitude, frequency, phase, polarization - according to the law of the bit sequence, which has a tracking frequency that exceeds the frequency of the primary harmonic oscillation, transmission of the carrier signal formed in this way through an analog data transmission channel, and also by the fact that the demodulation of the signal received from the data transmission channel is carried out by comparing the instantaneous values of the received signal with an unmodulated signal, determining the positions and maximum values of signal deviations, selecting the 65 bit sequence by comparing the modulated parameters of the signals alu relative to an empirically determined threshold level. 2. The method according to claim 1, which is characterized by the fact that the amplitude modulation is performed by multiplying the primary harmonic oscillation with a bit sequence, multiplying the received signal with a local oscillator signal whose frequency is close to the frequency of the primary harmonic signal, isolating the modulated carrier with a difference frequency by a bandpass filter . C. The method according to claim 2, which differs in that the signal received from the data transmission channel is pre-processed by a filter having a frequency response, the inverse frequency response of the bandpass filter during modulation. 4. The method according to claim 2, which differs in that a signal having a difference frequency is used as an unmodulated signal in the case of amplitude modulation. 6) «- with (Se) in and - - and? -i -i (o) ime) - ime) 60 b5