CN115001574B - Parallel interconnection optical communication network component detection system - Google Patents

Abstract

The invention provides a parallel interconnection optical communication network component detection system, which comprises a basic parameter acquisition module, a transmission parameter acquisition module and a detection processing module, wherein the basic parameter acquisition module is used for acquiring basic parameters of an optical communication network component, and the transmission parameter acquisition module is used for acquiring transmission parameters generated in a transmission process of the optical communication network component; the invention obtains the comprehensive matching result by detecting the basic parameters and the transmitted parameters of the network component of the optical communication and comprehensively processing the basic parameters and the transmitted parameters, provides a reference basis for the parallel interconnected optical communication, improves the practical application matching degree of the network component of the parallel interconnected optical communication, and solves the problem of lower practical application matching degree of the network component of the existing parallel interconnected optical communication.

Description

Parallel interconnection optical communication network component detection system

Technical Field

The invention relates to the technical field of communication detection, in particular to a parallel interconnection optical communication network component detection system.

Background

Optical communication is communication using light waves as carriers. Along with the process of digitization, data processing, storage and transmission have been rapidly developed. The need for high bandwidth makes short-range interconnects a bottleneck in system development. Due to factors such as loss and crosstalk, the transmission distance in the case of high bandwidth of the copper wire-based electrical interconnection is limited, and the cost increases. And too many cables can increase the weight of the system and the complexity of wiring. Optical interconnects based on multimode optical fibers have the advantages of high bandwidth, low loss, no crosstalk and matching, electromagnetic compatibility, etc., compared to electrical interconnects, and optical fiber communication technology has shown its importance in future communications. Optical communication technology is mature, optical fiber communication is a main transmission mode of various communication networks, and optical fiber communication plays a crucial role in the construction of information highways.

In the prior art, in the process of optical communication, if relay problems such as optical amplification are not considered in some short-distance optical fiber transmission modes, the cost of continuously adopting serial optical transmission equipment is too high, so that the connection cost can be reduced by adopting a parallel transmission mode, but the prior art is difficult to ensure the stability and the effectiveness of transmission while reducing the cost, and therefore, a method capable of balancing the transmission efficiency and the transmission cost is lacking to solve the problem.

Disclosure of Invention

Aiming at the defects existing in the prior art, the invention aims to provide a parallel interconnection optical communication network component detection system, which is used for detecting basic parameters and transmission parameters of an optical communication network component, comprehensively processing the basic parameters and the transmission parameters to obtain a comprehensive matching result, providing a reference basis for the parallel interconnection optical communication, improving the actual application matching degree of the parallel interconnection optical communication network component and solving the problem of lower actual application matching degree of the existing parallel interconnection optical communication network component.

In order to achieve the above object, the present invention is realized by the following technical scheme: the detection system comprises a basic parameter acquisition module, a transmission parameter acquisition module and a detection processing module, wherein the basic parameter acquisition module is used for acquiring basic parameters of a network component of optical communication, and the transmission parameter acquisition module is used for acquiring transmission parameters generated in a transmission process of the network component of the optical communication;

the detection processing module comprises a basic detection processing unit, a transmission detection processing unit and a comprehensive detection processing unit; the basic detection processing unit is used for processing basic parameters of the network component of the optical communication and obtaining a basic parameter processing result; the transmission detection processing unit is used for processing transmission parameters of the network component of the optical communication and obtaining a transmission parameter processing result; the comprehensive detection processing unit is used for comprehensively processing the basic parameter processing result and the transmission parameter processing result to obtain a comprehensive processing result, and the comprehensive processing result is used for reflecting the matching degree of the basic parameter and the transmission parameter of the network component of the optical communication.

Further, the basic parameter acquisition module is configured with a basic parameter acquisition policy, where the basic parameter acquisition policy includes: and acquiring the bus width, the bus length and the number of parallel lines of the network component, and conveying the acquired bus width, bus length and number of parallel lines to the basic detection processing unit.

Further, the basic detection processing unit is configured with a basic detection processing strategy, and the basic detection processing strategy comprises substituting the received bus width, bus length and parallel line number into a basic parameter transmission reference formula to obtain a basic parameter transmission reference value;

substituting the received bus width, bus length and parallel line number into a basic parameter cost reference formula to obtain a basic parameter cost reference value;

and substituting the basic parameter transmission reference value and the basic parameter cost reference value into a basic parameter efficiency conversion formula to obtain a basic parameter efficiency conversion value.

Further, the basic parameter transmission reference formula configurationThe method comprises the following steps:

the base parameter cost reference formula is configured to: cjcb= (Kzx ×cdzx) ^Sbx The method comprises the steps of carrying out a first treatment on the surface of the The basic parameter efficiency conversion formula is configured to:

wherein Cjcs is a basic parameter transmission reference value, kzx is a bus width, CDzx is a bus length, sbx is the number of parallel lines, cjcb is a basic parameter cost reference value, xjcz is a basic parameter efficiency conversion value, and X1 is a parameter efficiency conversion reference coefficient.

Further, the transmission parameter acquisition module is configured with a transmission parameter acquisition policy: the transmission parameter acquisition strategy comprises the following steps: acquiring a bus maximum transmission frequency and a bus maximum transmission speed of a transmission bus in a first time period;

and then respectively acquiring the parallel maximum transmission frequency and the parallel maximum transmission speed of each parallel line in the first time period.

Further, the transmission detection processing unit is configured with a transmission detection processing policy, the transmission detection processing policy including: substituting the maximum transmission frequency of the bus, the maximum transmission speed of the bus, the maximum transmission frequencies of the parallel and the maximum transmission speeds of the parallel into a parallel transmission reference formula to obtain a total parallel transmission reference value;

substituting the parallel maximum transmission frequencies and the parallel maximum transmission speeds into a parallel stable reference formula to obtain a parallel stable reference value;

outputting a total parallel high-efficiency transmission signal when the total parallel transmission reference value is smaller than or equal to a first total parallel reference threshold value; outputting a total parallel intermediate transmission signal when the total parallel transmission reference value is greater than the first total parallel reference threshold and less than or equal to the second intermediate parallel reference threshold; outputting a total parallel low-efficiency transmission signal when the total parallel transmission reference value is larger than a second total parallel reference threshold value; the first total parallel reference threshold is smaller than the second total parallel reference threshold, the transmission efficiency of the total parallel high-efficiency transmission signal is higher than that of the total parallel medium-efficiency transmission signal, and the transmission efficiency of the total parallel medium-efficiency transmission signal is higher than that of the total parallel low-efficiency transmission signal; the lower the total parallel transmission reference value is, the smaller the transmission loss is, the higher the total parallel transmission reference value is, and the larger the transmission loss is;

outputting a parallel high-stability signal when the parallel stability reference value is smaller than or equal to a first parallel stability reference threshold value; outputting a parallel medium-stability signal when the parallel stability reference value is greater than the first parallel stability reference threshold and less than the second parallel stability reference threshold; outputting a parallel low-stability signal when the parallel stability reference value is greater than a second parallel stability reference threshold value; the first parallel stable reference threshold is smaller than the second parallel stable reference threshold, the parallel transmission stability of the parallel high stable signal is higher than the parallel transmission stability of the parallel medium stable signal, the parallel transmission stability of the parallel medium stable signal is higher than the parallel transmission stability of the parallel low stable signal, the smaller the parallel stable reference value is representing the lower the parallel fluctuation and the higher the parallel transmission stability, the larger the parallel stable reference value is representing the higher the parallel fluctuation and the lower the parallel transmission stability.

Further, the parallel transmission reference formula is configured to:

the parallel stability reference formula is configured to:

wherein Czbc is the total parallel transmission reference value, pzx is the maximum transmission frequency of the bus, pbx ₁ To Pbx _n Respectively a plurality of parallel maximum transmission frequencies, vzx is the maximum transmission speed of the bus, and Vbx ₁ To Vbx _n The parallel transmission method comprises the steps of respectively obtaining a plurality of parallel maximum transmission speeds, wherein n is the number of a plurality of parallel lines, cbxw is a parallel stable reference value, w1 is a parallel transmission frequency stable conversion coefficient, and w2 is a parallel transmission speed stable conversion coefficient.

Further, the comprehensive detection processing unit is configured with a comprehensive detection processing policy, and the comprehensive detection processing policy includes: substituting the basic parameter efficiency conversion value and the total parallel transmission reference value into a parameter transmission matching formula to obtain a parameter transmission matching value;

when the parameter transmission matching value is smaller than the first matching threshold value, outputting a parameter transmission low-level matching signal, and substituting the basic parameter transmission reference value and the total parallel transmission reference value into a basic parameter and total parallel transmission compensation formula to obtain a transmission compensation value; outputting a basic parameter compensation signal when the transmission compensation value is smaller than or equal to a first compensation threshold value; outputting a total parallel growth signal when the transmission compensation value is greater than or equal to a second compensation threshold value; wherein the first compensation threshold is less than the second compensation threshold;

when the parameter transmission matching value is larger than or equal to a first matching threshold value, outputting a parameter transmission normal matching signal, wherein the larger the parameter transmission matching value is, the higher the matching degree of the basic parameter and the total parallel transmission is.

Further, the parameter transmission matching formula is configured to:

the basic parameters and the total parallel transmission compensation formula are configured as follows: />

Wherein Pcc is a parameter transmission matching value, p1 is a transmission matching conversion coefficient, bcs is a transmission compensation value, and b1 is a transmission compensation coefficient.

The invention has the beneficial effects that: the invention can acquire the basic parameters of the network component of the optical communication through the basic parameter acquisition module, and can acquire the transmission parameters generated in the transmission process of the network component of the optical communication through the transmission parameter acquisition module; then, the basic parameters of the network component of the optical communication can be processed through the basic detection processing unit, and a basic parameter processing result is obtained; the transmission parameters of the network component of the optical communication can be processed through the transmission detection processing unit, and a transmission parameter processing result is obtained; finally, the comprehensive detection processing unit can comprehensively process the basic parameter processing result and the transmission parameter processing result to obtain a comprehensive processing result, and the comprehensive processing result can reflect the matching degree of the basic parameter and the transmission parameter of the network component of the optical communication.

Drawings

Other features, objects and advantages of the present invention will become more apparent upon reading of the detailed description of non-limiting embodiments, given with reference to the accompanying drawings in which:

fig. 1 is a system schematic block diagram of the present invention.

Detailed Description

The invention is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

Referring to fig. 1, the present invention provides a parallel interconnection optical communication network component detection system, which detects basic parameters and transmitted parameters of an optical communication network component, and performs comprehensive processing on the basic parameters and the transmitted parameters to obtain a comprehensive matching result, so as to provide a reference basis for parallel interconnection optical communication, improve the actual application matching degree of the parallel interconnection optical communication network component, and solve the problem that the actual application matching degree of the existing parallel interconnection optical communication network component is lower.

The detection system comprises a basic parameter acquisition module, a transmission parameter acquisition module and a detection processing module.

The base parameter obtaining module is configured to obtain a base parameter of a network component of optical communication, where the base parameter obtaining module is configured with a base parameter obtaining policy, and the base parameter obtaining policy includes: the bus width, the bus length and the number of parallel lines of the network component are acquired, and the acquired bus width, bus length and number of parallel lines are transmitted to the basic detection processing unit, wherein the bus width, bus length and number of parallel lines influence the final transmission frequency, and the connection point of the lines is increased by the wider bus width, so that the transmission frequency is reduced.

The transmission parameter acquisition module is used for acquiring transmission parameters generated in the transmission process of the network component of the optical communication; the transmission parameter acquisition module is configured with a transmission parameter acquisition strategy: the transmission parameter acquisition strategy comprises the following steps: acquiring a bus maximum transmission frequency and a bus maximum transmission speed of a transmission bus in a first time period; and then respectively acquiring the parallel maximum transmission frequency and the parallel maximum transmission speed of each parallel line in the first time period, wherein the transmission frequency and the transmission speed can represent the transmission efficiency of the network component, so as to reflect whether the configured network component is matched with the presented transmission parameters.

The detection processing module comprises a basic detection processing unit, a transmission detection processing unit and a comprehensive detection processing unit.

The basic detection processing unit is used for processing basic parameters of the network component of the optical communication and obtaining a basic parameter processing result; the basic detection processing unit is configured with a basic detection processing strategy, and the basic detection processing strategy comprises substituting the received bus width, bus length and parallel line quantity into a basic parameter transmission reference formula to obtain a basic parameter transmission reference value; the basic parameter transmission reference formula is configured as follows:

wherein Cjcs is the basic parameter transmission reference value, kzx is the bus width, CDzx is the bus length, and Sbx is the number of parallel lines.

Substituting the received bus width, bus length and parallel line number into a basic parameter cost reference formula to obtain a basic parameter cost reference value; the base parameter cost reference formula is configured to: cjcb= (Kzx ×cdzx) ^Sbx The method comprises the steps of carrying out a first treatment on the surface of the Wherein Cjcb is the base parameter cost reference.

Substituting the basic parameter transmission reference value and the basic parameter cost reference value into a basic parameter efficiency conversion formula to obtain a basic parameter efficiency conversion value; the basic parameter efficiency conversion formula is configured to:

wherein, the Xjcz basic parameter efficiency conversion value, X1 is a parameter efficiency conversion reference coefficient, and X1 is set by referring to the matching degree between the existing network component with the same configuration and the transmission efficiency.

The transmission detection processing unit is used for processing transmission parameters of the network component of the optical communication and obtaining a transmission parameter processing result; the transmission detection processing unit is configured with a transmission detection processing policy, the transmission detection processing policy comprising: substituting the maximum transmission frequency of the bus, the maximum transmission speed of the bus, the maximum transmission frequencies of the parallel and the maximum transmission speeds of the parallel into a parallel transmission reference formula to obtain a total parallel transmission reference value; the parallel transmission reference formula is configured to:

wherein Czbc is the total parallel transmission reference value, pzx is the maximum transmission frequency of the bus, pbx ₁ To Pbx _n Respectively a plurality of parallel maximum transmission frequencies, vzx is the maximum transmission speed of the bus, and Vbx ₁ To Vbx _n And n is the number of the parallel lines.

Substituting the parallel maximum transmission frequencies and the parallel maximum transmission speeds into a parallel stable reference formula to obtain a parallel stable reference value; the parallel stability reference formula is configured to:

cbxw is a parallel stable reference value, w1 is a parallel transmission frequency stable conversion coefficient, and w2 is a parallel transmission speed stable conversion coefficient, wherein w1 and w2 are used for converting the correlation between the transmission frequency and the transmission speed, and are required to be set with reference to the specific gravity of the transmission frequency and the transmission speed in the overall stable operation.

Outputting a total parallel high-efficiency transmission signal when the total parallel transmission reference value is smaller than or equal to a first total parallel reference threshold value; outputting a total parallel intermediate transmission signal when the total parallel transmission reference value is greater than the first total parallel reference threshold and less than or equal to the second intermediate parallel reference threshold; outputting a total parallel low-efficiency transmission signal when the total parallel transmission reference value is larger than a second total parallel reference threshold value; the first total parallel reference threshold is smaller than the second total parallel reference threshold, the transmission efficiency of the total parallel high-efficiency transmission signal is higher than that of the total parallel medium-efficiency transmission signal, and the transmission efficiency of the total parallel medium-efficiency transmission signal is higher than that of the total parallel low-efficiency transmission signal; the lower the total parallel transmission reference value is, the smaller the transmission loss is, the higher the total parallel transmission reference value is, and the larger the transmission loss is;

outputting a parallel high-stability signal when the parallel stability reference value is smaller than or equal to a first parallel stability reference threshold value; outputting a parallel medium-stability signal when the parallel stability reference value is greater than the first parallel stability reference threshold and less than the second parallel stability reference threshold; outputting a parallel low-stability signal when the parallel stability reference value is greater than a second parallel stability reference threshold value; the first parallel stable reference threshold is smaller than the second parallel stable reference threshold, the parallel transmission stability of the parallel high stable signal is higher than the parallel transmission stability of the parallel medium stable signal, the parallel transmission stability of the parallel medium stable signal is higher than the parallel transmission stability of the parallel low stable signal, the smaller the parallel stable reference value is representing the lower the parallel fluctuation and the higher the parallel transmission stability, the larger the parallel stable reference value is representing the higher the parallel fluctuation and the lower the parallel transmission stability.

The comprehensive detection processing unit is used for comprehensively processing the basic parameter processing result and the transmission parameter processing result to obtain a comprehensive processing result, and the comprehensive processing result is used for reflecting the matching degree of the basic parameter and the transmission parameter of the network component of the optical communication.

The comprehensive detection partThe processing unit is configured with a comprehensive detection processing strategy, and the comprehensive detection processing strategy comprises: substituting the basic parameter efficiency conversion value and the total parallel transmission reference value into a parameter transmission matching formula to obtain a parameter transmission matching value; the parameter transmission matching formula is configured as follows:

where Pcc is a parameter transmission match value and p1 is a transmission match conversion coefficient, where p1 is set with reference to network components of different configurations.

When the parameter transmission matching value is smaller than the first matching threshold value, outputting a parameter transmission low-level matching signal, and substituting the basic parameter transmission reference value and the total parallel transmission reference value into a basic parameter and total parallel transmission compensation formula to obtain a transmission compensation value; outputting a basic parameter compensation signal when the transmission compensation value is smaller than or equal to a first compensation threshold value; outputting a total parallel growth signal when the transmission compensation value is greater than or equal to a second compensation threshold value; wherein the first compensation threshold is less than the second compensation threshold;

when the parameter transmission matching value is larger than or equal to a first matching threshold value, outputting a parameter transmission normal matching signal, wherein the larger the parameter transmission matching value is, the higher the matching degree between the basic parameter and the total parallel transmission is; the basic parameters and the total parallel transmission compensation formula are configured as follows:

bcs is a transmission compensation value, and b1 is a transmission compensation coefficient, where b1 is set with reference to network components of different configurations.

Working principle: firstly, the basic parameters of the network component of optical communication and the transmission parameters generated in the transmission process of the network component of the optical communication can be respectively acquired through a basic parameter acquisition module and a transmission parameter acquisition module; then, the basic parameters of the network component of the optical communication can be processed through the basic detection processing unit, and a basic parameter processing result is obtained; the transmission parameters of the network component of the optical communication can be processed through the transmission detection processing unit, and a transmission parameter processing result is obtained; and finally, the comprehensive detection processing unit can comprehensively process the basic parameter processing result and the transmission parameter processing result to obtain a comprehensive processing result, and the comprehensive processing result can reflect the matching degree of the basic parameter and the transmission parameter of the network component of the optical communication.

Finally, it should be noted that: the above examples are only specific embodiments of the present invention, and are not intended to limit the scope of the present invention, but it should be understood by those skilled in the art that the present invention is not limited thereto, and that the present invention is described in detail with reference to the foregoing examples: any person skilled in the art may modify or easily conceive of the technical solution described in the foregoing embodiments, or perform equivalent substitution of some of the technical features, while remaining within the technical scope of the present disclosure; such modifications, changes or substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention, and are intended to be included in the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (1)

1. The parallel interconnection optical communication network component detection system is characterized by comprising a basic parameter acquisition module, a transmission parameter acquisition module and a detection processing module, wherein the basic parameter acquisition module is used for acquiring basic parameters of an optical communication network component, and the transmission parameter acquisition module is used for acquiring transmission parameters generated in a transmission process of the optical communication network component;

the detection processing module comprises a basic detection processing unit, a transmission detection processing unit and a comprehensive detection processing unit; the basic detection processing unit is used for processing basic parameters of the network component of the optical communication and obtaining a basic parameter processing result; the transmission detection processing unit is used for processing transmission parameters of the network component of the optical communication and obtaining a transmission parameter processing result; the comprehensive detection processing unit is used for comprehensively processing the basic parameter processing result and the transmission parameter processing result to obtain a comprehensive processing result, and the comprehensive processing result is used for reflecting the matching degree of the basic parameter and the transmission parameter of the network component of the optical communication;

the basic parameter acquisition module is configured with a basic parameter acquisition strategy, and the basic parameter acquisition strategy comprises: acquiring the bus width, the bus length and the number of parallel lines of the network component, and conveying the acquired bus width, bus length and number of parallel lines to a basic detection processing unit;

the basic detection processing unit is configured with a basic detection processing strategy, and the basic detection processing strategy comprises substituting the received bus width, bus length and parallel line quantity into a basic parameter transmission reference formula to obtain a basic parameter transmission reference value;

substituting the received bus width, bus length and parallel line number into a basic parameter cost reference formula to obtain a basic parameter cost reference value;

substituting the basic parameter transmission reference value and the basic parameter cost reference value into a basic parameter efficiency conversion formula to obtain a basic parameter efficiency conversion value;

the basic parameter transmission reference formula is configured as follows:

the base parameter cost reference formula is configured to: cjcb= (Kzx ×cdzx) ^Sbx The method comprises the steps of carrying out a first treatment on the surface of the The basic parameter efficiency conversion formula is configured to: />

Wherein Cjcs is basic parameter transmission reference value, kzx is bus width, CDzx is bus length, sbx is parallel line number, cjcb is basic parameter cost reference value, xjcz basic parameter efficiency conversion value, and X1 is parameter efficiency conversion reference coefficient;

the transmission parameter acquisition module is configured with a transmission parameter acquisition strategy: the transmission parameter acquisition strategy comprises the following steps: acquiring a bus maximum transmission frequency and a bus maximum transmission speed of a transmission bus in a first time period;

then, respectively acquiring the parallel maximum transmission frequency and the parallel maximum transmission speed of each parallel line in the first time period;

the transmission detection processing unit is configured with a transmission detection processing policy, the transmission detection processing policy comprising: substituting the maximum transmission frequency of the bus, the maximum transmission speed of the bus, the maximum transmission frequencies of the parallel and the maximum transmission speeds of the parallel into a parallel transmission reference formula to obtain a total parallel transmission reference value;

substituting the parallel maximum transmission frequencies and the parallel maximum transmission speeds into a parallel stable reference formula to obtain a parallel stable reference value;

outputting a total parallel high-efficiency transmission signal when the total parallel transmission reference value is smaller than or equal to a first total parallel reference threshold value; outputting a total parallel intermediate transmission signal when the total parallel transmission reference value is greater than the first total parallel reference threshold and less than or equal to the second intermediate parallel reference threshold; outputting a total parallel low-efficiency transmission signal when the total parallel transmission reference value is larger than a second total parallel reference threshold value; wherein the first total parallel reference threshold is less than the second total parallel reference threshold;

outputting a parallel high-stability signal when the parallel stability reference value is smaller than or equal to a first parallel stability reference threshold value; outputting a parallel medium-stability signal when the parallel stability reference value is greater than the first parallel stability reference threshold and less than the second parallel stability reference threshold; outputting a parallel low-stability signal when the parallel stability reference value is greater than a second parallel stability reference threshold value; the first parallel stability reference threshold is less than the second parallel stability reference threshold;

the parallel transmission reference formula is configured to:

the parallel stability reference formula is configured to:

wherein Czbc is the total parallel transmission reference value, pzx is the maximum transmission frequency of the bus, pbx ₁ To Pbx _n Respectively a plurality of parallel maximum transmission frequencies, vzx is the maximum transmission speed of the bus, and Vbx ₁ To Vbx _n The parallel transmission method comprises the steps of respectively obtaining a plurality of parallel maximum transmission speeds, wherein n is the number of a plurality of parallel lines, cbxw is a parallel stable reference value, w1 is a parallel transmission frequency stable conversion coefficient, and w2 is a parallel transmission speed stable conversion coefficient;

the comprehensive detection processing unit is configured with a comprehensive detection processing strategy, and the comprehensive detection processing strategy comprises: substituting the basic parameter efficiency conversion value and the total parallel transmission reference value into a parameter transmission matching formula to obtain a parameter transmission matching value;

when the parameter transmission matching value is smaller than the first matching threshold value, outputting a parameter transmission low-level matching signal, and substituting the basic parameter transmission reference value and the total parallel transmission reference value into a basic parameter and total parallel transmission compensation formula to obtain a transmission compensation value; outputting a basic parameter compensation signal when the transmission compensation value is smaller than or equal to a first compensation threshold value; outputting a total parallel growth signal when the transmission compensation value is greater than or equal to a second compensation threshold value; wherein the first compensation threshold is less than the second compensation threshold;

when the parameter transmission matching value is larger than or equal to a first matching threshold value, outputting a parameter transmission normal matching signal, wherein the larger the parameter transmission matching value is, the higher the matching degree of the basic parameter and the total parallel transmission is;

the parameter transmission matching formula is configured as follows:

the basic parameters and the total parallel transmission compensation formula are configured as follows: />

Wherein Pcc is a parameter transmission matching value, p1 is a transmission matching conversion coefficient, bcs is a transmission compensation value, and b1 is a transmission compensation coefficient.

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