RU2533105C1 - Information transmission method - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: information transmission method, involving transmission of a data array as packets, consisting from data words, where each bit is encoded by a direct and an inverse value, stipulates for the continuous data array transmission as a continuous two-frequency two-level signal, symmetrical relatively to the zero level. A logical marker is used to divide the packets. The marker consists of bits, virtually identical to other bits of the packet.

EFFECT: higher noise immunity.

5 cl, 4 dwg

Description

The invention relates to the field of geophysical and geological and technological research of wells, in particular to methods for transmitting measurement signals from a well to the surface or between modules of a geological and technological monitoring station, and can be used to communicate via cable, fiber optic and wireless communication channels, as well as when recording information on digital media.

A known method of transmitting information from a downhole tool to a ground-based equipment, in the implementation of which the underground part (downhole device) contains geophysical sensors, matching devices, a switch, an analog-to-digital converter, a control unit, a clock generator and a signal signal generator. The ground part includes a filter corrector, a synchronization pulse shaper, a registration unit. An increase in noise immunity and information transfer rate is achieved by introducing two-frequency coding and using a synchronization signal of increased frequency and increased amplitude (see AS USSR 1564579, IPC G01V 1/22, publ. 05.15.1990).

However, in this case, one of the main disadvantages of the method is the need to transmit, as a sync packet, eight half-periods of increased frequency of increased amplitude, i.e. the formation of qualitatively different pulses, which complicates the hardware of the downhole tool and reduces the noise immunity of the telemetry system. The presence of more than two voltage levels in the output signal is a drawback, since in this case the requirements for the accuracy of forming the shape of the output signal of the transmitter increase. In addition, multilevel signals are more critical to the presence of reflected signals and interference signals in the transmission line.

There is also known a method of transmitting information through a wireline cable comprising the formation of a continuous signal consisting of a set of signals. Each signal from the set represents one period of a periodic signal that is symmetrical with respect to the zero level, the start and end points of which are determined at the point where the signal reaches zero level. In this case, the values of the period, and / or amplitude, and / or phase of the periodic signal are selected from discrete sets formed for the period, amplitude and phase, respectively. The total number of elements of sets is more than two, their combination encodes a unit of transmitted information, and at the output of the logging cable, the registered signal is decoded by the values of its period, and / or amplitude, and / or phase (see RF patent No. 2455697, IPC G08C 19/00 , published on July 10, 2012).

The disadvantage of this method is the complexity of the hardware-software implementation (the need to change the amplitude or frequency of the downhole telemetry signal) of this method - which is difficult to implement in a small downhole tool.

In practice, when implementing logging transmission protocols, continuous transmission is widely used (without pauses between data packets) using the Manchester-2 code. In the Manchester-2 code, two different pulse durations are used - for informational and synchronizing pulses (S.T. Hvoshch, N.N. Varlinsky, E.A. Popov, reference book. Microprocessors and microcomputers in automatic control systems. Under the general revision of C .T. Horsetail. Leningrad Publishing House "Engineering", 1987. UDC 681.3.01 (031), pp. 503 - 505). Due to the presence of clock bits that differ in frequency from the data bits, it becomes possible to separate the beginning of the data packet in a continuous sequence of data, as well as to separate the data related to different sensors inside the packet from each other. Physically, the clock and data bits should have a duration as shown in FIG. 1 down. The data word encoded in Manchester-2 is shown in FIG. 2.

In fact, when a signal is generated in the Manchester-2 code, pulses of four different durations are formed. Pulses of minimum duration are formed when identical bits are transmitted one after another, that is, zeros or ones. Pulses of double duration are formed in the vicinity of two different bits. For synchronization, a pulse of triple duration is used. The fourth pulse width is obtained if a “single” bit is transmitted after the “data clock” signal or if a zero bit is transmitted after the “command or response” clock signal.

The disadvantages of transmitting data over a geophysical cable with the Manchester-2 code are due precisely to the presence of several frequencies in the spectrum of the telemetry signal. When a signal passes through a communication line, it experiences attenuation, i.e. the amplitude of the signal at the input of the receiver does not correspond (less) to the amplitude of the signal at the output of the transmitter. Moreover, the signal attenuation for different components in the signal spectrum is different. A relative increase in the low-frequency components of the signal spectrum occurs due to their lower attenuation in the geophysical cable. Thus, the more frequencies there are in the telemetry signal spectrum, the stronger the signal is distorted in amplitude when passing through a geophysical cable. In addition, it should be noted that when using the “one and a half” duration of these signals, it becomes difficult to recognize telemetry by the receiver (after distorting the signal when passing through the geophysical cable it is difficult to distinguish the clock signal from the transition of data bits 1.0 or 0.1).

Closest to the technical nature of the claimed is a method of transmitting information through a wireline with a phase-shifted Manchester code. Each bit of information is encoded by a direct and inverse value - a logical zero corresponds to a transition to the upper level in the center of the bit interval, a logical unit corresponds to a transition to the lower level, i.e. encoding is carried out by the transition of a signal from one level ("0" or "1") to another. Moreover, a pause is necessary between the data packets to guarantee the separation of the beginning of the transmission of the packet (see Shevkoplyas BV, Microprocessor Structures, Engineering Solutions, Moscow: Radio and Communications, 1986, pp. 93-97, Fig. 6. 2c) . The main advantages of this code include: ease of generation, self-synchronization of data in each code interval, the absence of a constant component in the spectrum, due to which galvanic isolation of signals is performed in the simplest ways, for example, using pulse transformers. The advantages also include the presence of only two voltage levels in the output signal. (Two-level signals are less critical to the presence of reflected signals and interference signals in the logging cable).

The disadvantage of this method is that when data is transmitted by the Manchester code (with pauses between data packets) over a geophysical cable with a large distributed capacity, a transient occurs at the beginning of the data packet, which complicates the synchronization and reception of the first bits of the data packet.

The objective of the invention is to provide a noise-tolerant method for transmitting information using a two-frequency two-level continuous signal.

The technical result is to increase the noise immunity.

The problem is solved in that in a method of transmitting information, including transmitting an information array in the form of packets consisting of data words, where each bit in each data word is encoded with a direct and inverse value, according to the solution, the information array is transmitted continuously in the form of a symmetric with respect to the zero level periodic continuous two-frequency two-level signal, while for the separation of data packets using a logical marker, consisting of bits that are not physically different from the rest of the bi s package.

If the data word has a length of N bits, then at the end of each word an additional bit of one is transmitted, and a sequence of N + 1 zeros is used as a marker of the beginning of a packet.

If the data word has a length of N bits, a zero bit is additionally transmitted at the end of each word of the packet, and a sequence of N + 1 units is used as a marker of the beginning of the packet.

If the data word has a length of N bits, then at the end of each word, n bits of units are additionally transmitted, and a sequence of N + n zeros is used as a marker of the beginning of the packet.

If the data word has a length of N bits, then at the end of each word of the packet, n bits of zeros are additionally transmitted, and a sequence of N + n units is used as a marker of the beginning of the packet.

The invention is illustrated by drawings:

in FIG. 1 - shows the time characteristics of the Manchester-2 code.

in FIG. 2 - shows an example code of Manchester-2.

in FIG. 3 - shows the temporal characteristics of the signal and an example of the code of the cedar-38K downhole tool.

in FIG. 4 - shows an example of a circuit implementation of the transmitter of the downhole tool "Cedar-38K".

The claimed method is implemented in the following way.

The entire array of information to be transmitted is presented in the form of packets consisting of data words. Each bit in each data word is encoded by a direct and inverse value - a logical zero corresponds to a transition to the upper level in the center of the bit interval, a logical unit corresponds to a transition to the lower level, i.e. encoding is carried out by the transition of a signal from one level ("0" or "1") to another. If the data word has a length of N bits, then at the end of each word an additional bit is transmitted, and a sequence of N + 1 zeros is used as a marker of the beginning of the packet. Such a sequence of bits cannot occur in an information word, so receiving N + 1 zeros in a row means that the first word of the information packet follows.

Another embodiment of the claimed data transmission method

The entire array of information to be transmitted is presented in the form of packets consisting of data words. Each bit in each data word is encoded by a direct and inverse value - a logical zero corresponds to a transition to the upper level in the center of the bit interval, a logical unit corresponds to a transition to the lower level, i.e. encoding is carried out by the transition of a signal from one level ("0" or "1") to another. If the data word has a length of N bits, then a zero bit is additionally transmitted at the end of each word, and a sequence of N + 1 units is used as a marker for starting the packet. Such a sequence of bits cannot occur in an information word, so receiving N + 1 units in a row means that the first word of the information packet follows.

The inventive method has a novelty in comparison with the prototype, differing from it by such significant features as the absence of pauses between data packets, the absence of clock signals in the data stream that are physically different (in pulse duration or pulse frequency) from the pulses by which the data bits are encoded. The presence in the telemetry signal of a logical marker of the beginning of a data packet.

The applicant is not aware of technical solutions that have the indicated distinguishing features, which together ensure the achievement of a given result, therefore, he believes that the claimed method meets the criterion of "inventive step".

The described method of transmitting information was used in a small-sized integrated complex control device for the development of "Cedar-38K".

Modular borehole device "Kedr-38K" is intended for complex geophysical studies of oil producing, injection and other wells. Designed to work with a single-core geophysical cable up to 5500 m long.

To expand the range of geophysical problems to be solved, the device has a flexible modular structure, depending on the tasks to be solved, the composition of the device is made up of modules with the necessary sensors.

The following is a description of the Kedr-M-GKT-38K base module, which is part of the Kedr-38K instrument, since this module is connected to the geophysical logging cable. Additional modules included in the Kedr-38K device are connected to the Kedr-M-GKT-38K module.

The Kedr-M-GKT-38K module (hereinafter referred to as the module) is intended for the study of oil producing, injection and other wells with the aim of measuring, indicating, monitoring and transmitting the following physical parameters to the surface:

temperature measurement (channel of the downhole thermal indicator of the inflow (hereinafter STI) with the STI heater turned off);

indication of the velocity of the well fluid (STI channel with the STI heater turned on);

pressure measurement;

measuring the exposure dose rate of gamma radiation of rocks along the wellbore (GC channel);

indication of the volumetric moisture content of the borehole fluid (moisture meter channel);

indication of casing couplings and perforation intervals (clutch locator channel).

While working in the well with additional modules included in the Kedr-38K device, the Kedr-M-GKT-38K module provides power to additional modules and transfers information from additional modules to the day surface.

The module works with the equipment of the Kedr-02 family ground-based geophysical laboratory and a PKS-5 type logging elevator equipped with a KG1-55-180 single-core geophysical cable up to 5500 m in length or any other similar cable.

The module is mechanically and electrically connected to the geophysical cable through the module head. The electronic circuit of the module collects information from the module’s own sensors, powers the additional modules and collects information from them, converts the received data and transfers them to the day surface using the inventive method of transmitting information.

The electronic circuit of the device is powered by a constant voltage of 110 V, while the maximum current consumption (all modules are connected) is not more than 400 mA. During operation, the device modulates the supply voltage with voltage pulses with an amplitude of 2.4 ... 2.6 V. For encoding information, a phase-shift code with a carrier frequency of 16 kHz is used.

The following is a description of the structure of the data packets that the module transmits through the geophysical cable to the day surface.

The data word consists of the following fields:

D15 D14 D13 D12 D11 D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 P F

where D15 .... D0 are the data bits, D15 is the most significant bit, P is the parity bit, it takes such a value that the total number of unit bits in the word is odd, F is the flag of the end of the word, equal to 1.

The packet start flag (FP) is a data word in which bits D15 .... D0, P and F are equal to zero.

The data packet consists of the following fields:

FP Wcc W0 W1 W2 ... W255 Wks

where FP is the start flag of the packet, Wcc is the status word, W0 .... W255 is the data word. In the shortest packet, 1 data word, in the longest packet of 256 data words, Wks - checksum - excluding XOR of all bytes of the packet, starting with the status word.

The status word consists of the following fields:

A3 ... A0 C3 ... C0 L8 ... L0

where A3 ... A0 is the module address, for a module connected directly to the cable, the address is zero, C3 ... C0 is the module status word (TC), L7 ..... L0 is the packet length in data words, not including 3 service words that are always there: FP (flag to start the packet), Wcc (status word), Wks (checksum). ATTENTION! If the packet length is zero, it means that the packet contains 256 data words.

List of Status Word (CC) Values

SS code Description 0 Invalid data - module did not respond one Data output mode, STD off 2 Flash system output mode 3 Mode of issuing calibration coefficients from flash (variable part) four GC SAW mode ... ... 9 Data output mode, STD is on

Physically, the module transmitter is implemented as shown below.

A geophysical cable is connected to pin 1, through which electronic circuit power is supplied to the downhole tool, and by which the downhole telemetry signal is transmitted to the day surface. Pin 5 connects the circuit power source. Contacts 2, 3, 4 are connected directly to the terminals of the control microcontroller circuit. A virtual inductance is assembled on transistor V3 (circuit elements V3, V1, R4, C6 can be replaced with a choke), eliminating the shunt of the telemetry signal by the power source of the electronic circuit.

Using the above transceiver and the proposed method of data transmission, the module receives commands from the equipment located on the day surface (the first 2 seconds after applying power to the module), as well as data transfer from the module to the day surface in the operating mode.

Claims (5)

1. A method of transmitting information, including transmitting an array of information in the form of packets consisting of data words, where each bit in each data word is encoded with a direct and inverse value, characterized in that the transmission of the information array is continuous in the form of a periodic continuous two-frequency symmetrical relatively to zero level a two-level signal, while for the separation of data packets using a logical marker, consisting of bits that are not physically different from the rest of the bits of the packet. 2. The method according to claim 1, characterized in that if the data word has a length of N bits, then at the end of each word an additional bit is transmitted, and a sequence of N + 1 zeros is used as a marker to start the packet. 3. The method according to claim 1, characterized in that if the data word has a length of N bits, a zero bit is additionally transmitted at the end of each word of the packet, and a sequence of N + 1 units is used as a marker of the beginning of the packet. 4. The method according to claim 1, characterized in that if the data word has a length of N bits, then at the end of each word, n bits of units are additionally transmitted, and a sequence of N + n zeros is used as a marker for starting a packet. 5. The method according to claim 1, characterized in that if the data word has a length of N bits, then at the end of each word of the packet, n bits of zeros are additionally transmitted, and a sequence of N + n units is used as a marker of the start of the packet.

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