RU2589360C1 - Method of receiving multiple frequency shift keyed digital signal - Google Patents

Abstract

FIELD: telecommunications.

SUBSTANCE: invention relates to telecommunication engineering and can be used for transmitting information over wire and wireless communication lines. For this method, based on simultaneous filtration, detection and formation of zero, first, second, third and to 2ⁿ-1 digital video signal from an input digital signal shift keyed multi-frequency number of digital video signals presented in binary system for calculating a_n-1a_n-2…a₁a₀, then all digital signals, in which index a₀= 0, and all digital video signals, in which index a₀= 1 , and a zero differential digital signal, wherein number of readings of same sign, is divided into number of samples in one bit and number and value of bit binary code with index b₀, then all digital signals, in which a index a_n-1= 0, and all digital video signals, in which a index a_n-1= 1, and first differential digital signal, wherein number of readings of same sign, is divided into number of samples in one bit and number and value of bit binary code with index b₁ and so to bit binary code with index b_n-1.

EFFECT: technical result is increase of information transmission speed.

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Description

The invention relates to telecommunication technology and can be used to transmit information over wired and wireless communication lines.

From the device (see RF Patent No. 211,250, IPC 6 H04L 27/14. 07/10/1998. A device for detecting signals with frequency telegraphy), a method for receiving a frequency-manipulated signal is known in which the input frequency-manipulated signal is filtered, detected and video signals are generated.

The disadvantage of the described analogue is the use of two frequencies to transfer one bit of information, which reduces the possible speed of information transfer.

The closest in technical essence to the claimed invention is the method of receiving a frequency-manipulated signal selected as a prototype (see RF Patent No. 2018206, IPC 5 H04L 25/38, H04L 27/14. 08/15/1994. Signal receiver with frequency manipulation), in which the input frequency-manipulated signal is filtered, detected and video signals are generated.

The disadvantage of the described analogue is the use of two frequencies to transfer one bit of information, which reduces the possible transmission rate of the system. In addition, buffering of intermediate signals leads to a delay in processing and, as a result, to a decrease in the processing speed of the signal.

The technical task of the invention is to increase the speed of information transfer.

The technical problem is solved by the invention. In the inventive method for receiving a multi-frequency manipulated digital signal, they simultaneously filter, detect and generate zero, first, second, third, etc. 2 ⁿ -1 digital video signal from the input multi-frequency manipulated digital signal. Unlike the prototype, the numbers of digital video signals are represented in the binary system a _n-1 a _n-2 ... a ₁ a ₀ , add all the digital signals with the index a ₀ = 0, and subtract all the digital video signals with the index a ₀ = 1, and a zero difference digital signal is obtained, in which the number of samples of the same sign is calculated, divided by the number of samples in one bit and the number and values of bits of the binary code with index b ₀ are generated, all digital signals with index a ₁ = 0, and subtract all digital video signals whose index a ₁ = 1, and the first difference digital signal is obtained, in which the number of samples of the same sign is counted, divided by the number of samples in one bit, and the number and values of bits of the binary code with index b _{1 are formed} , etc. add up all the digital signals whose index a _n-1 = 0, and subtract all the digital video signals whose index a _n-1 = 1, and get an n-1 differential digital signal, in which the number of samples of the same sign is counted, divided by the number of samples in one bit and form the number and values of the bits of the binary code with index b _n-1 .

A method of receiving a multi-frequency manipulated digital signal is as follows. The input multi-frequency manipulated digital signal is filtered to extract n-1 individual frequencies from which it is formed. The filtering operation can be implemented using n-1 digital bandpass filters. Filtered signals are detected independently of each other. We give a description of the method using the example n = 2. As a result, we obtain the zero, first, second, and third digital video signals, which are conventionally denoted by S0, S1, S2, and S3, respectively. The detection operation can be implemented using the mathematical operation of taking the module followed by filtering using a digital low-pass filter. Establish a connection between the digital video signals and the received digital code.

The zero difference digital signal, taking into account the introduced symbolic notation, is equal to S0 + S2-S1-S3. The first difference digital signal, taking into account the introduced symbolic notation, is S0 + S1-S2-S3. Thus, if the zero difference digital signal is greater than zero, then in the received symbol bit b ₀ corresponds to a logical unit, otherwise - to logical zero. Similarly, if the first difference digital signal is greater than zero, then in the received symbol bit b ₁ corresponds to a logical unit, otherwise - logical zero. By the number of samples in the zero (first) differential digital signal, you can determine the number of received bits b ₀ (b ₁ ) by dividing the number of constant samples by the number of samples in one bit.

Here is a description of the method in the General case. From the input multi-frequency manipulated digital signal with simultaneous filtering and detection form zero, first, second, third, etc. 2 ⁿ -1 digital video signal. Next, the digital video signal numbers are represented in the binary system a _n-1 a _n-2 ... a ₁ a ₀ , add all the digital signals with the index a ₀ = 0, and subtract all the digital video signals with the index a ₀ = 1, and get a zero difference digital signal in which the number of samples of the same sign is calculated, divided by the number of samples in one bit and form the number of bits of the binary code with index b ₀ (if the zero difference digital signal is greater than zero, then the bit with index b ₀ is equal to one, otherwise zero) add up all the digital signal In which the index a ₁ = 0, and subtracted all the digital video signals, in which the subscript a ₁ = 1, and obtaining a first difference digital signal, wherein the counted number of samples of the same sign, divided by the number of samples in one bit and generating the number of bits of the binary code with index b ₁ (if the first difference digital signal is greater than zero, then the bit with index b ₁ is one, otherwise it is zero), etc. add up all the digital signals whose index a _n-1 = 0, and subtract all the digital video signals whose index a _n-1 = 1, and get an n-1 differential digital signal, in which the number of samples of the same sign is counted, divided by the number of samples in one bit and form the number of bits of the binary code with index b _n-1 (if n-1 difference digital signal is greater than zero, then the bit with index b _n-1 is equal to one, otherwise it is zero).

Thus, increasing the speed of information transfer during the implementation of the method became possible due to the use of multi-frequency signals with their processing in real time, i.e. without using the processes of accumulating intermediate processing results.

The inventive method of receiving a multi-frequency manipulated digital signal can be implemented on modern microcontrollers, for example AT91SAM7S256.

Claims (1)

A method of receiving a multi-frequency manipulated digital signal, in which the input multi-frequency manipulated digital signal is simultaneously filtered, detected, and zero, first, second, third, and up to 2 ⁿ -1 digital video signals are generated, characterized in that the digital video signal numbers are represented in binary a _{n -1} a _n-2 ... a ₁ a ₀ , add up all the digital signals with the index a ₀ = 0, and subtract all the digital video signals with the index a ₀ = 1, and get a zero difference digital signal, in which the the number of samples of one character is divided, divided by the number of samples in one bit, and the number and values of bits of the binary code with index b ₀ are formed, all digital signals with index a ₁ = 0 are added, and all digital video signals with index a ₁ are subtracted = 1, and the first difference digital signal is obtained, in which the number of samples of the same sign is counted, divided by the number of samples in one bit, and the number and values of bits of the binary code with index b _{1 are formed} and so on to the value of bits of the binary code with index b _n-1 .